Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer 3030688437, 9783030688431

This book gives insight into the functional role of non-coding RNAs in central pathways contributing to the development

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Table of contents :
Preface
Acknowledgments
Introduction
The Move Towards Cellular Risk Markers
Why Non-coding RNA?
Objectives
Approach
Take Home Message
References
Contents
Abbreviations
1 Biogenesis and Modes of Action of miRs and Circular and Long Non-coding RNAs
1.1 MiRs
1.1.1 Biogenesis of miRs
1.1.2 MiR Modes of Action
1.1.3 Naming of miRs
1.1.4 Useful Resources on miRs
1.2 Circular RNAs
1.2.1 Biogenesis of Circular RNAs
1.2.2 Circular RNAs Modes of Action
1.2.3 Useful Resources on Circ-RNAs
1.3 lncRNAs
1.3.1 Biogenesis of lncRNAs
1.3.2 Modes of Action of lncRNAs
1.4 piRs
1.4.1 Biogenesis of piRs
1.4.2 Modes of Action of piRs
1.4.3 Useful Resources on piRs
References
2 Non-coding RNAs Related to Obesity
2.1 Mechanisms in White Adipogenesis
2.1.1 Role of Non-coding RNAs in White Adipogenesis
2.2 Inflammation and Insulin Resistance in Obese White Adipose Tissue
2.2.1 Role of Non-coding RNAs in Inflammation and Insulin Resistance in Obese White Adipose Tissue
2.3 Mechanisms in Brown Adipogenesis and Thermogenesis
2.3.1 Role of Non-coding RNAs in Brown Adipogenesis and Thermogenesis
2.4 Mechanisms in Browning of White Adipose Tissues
2.4.1 Role of Non-coding RNAs in Browning of White Adipose Tissue
2.5 Leptin and Insulin in the Hypothalamus
2.5.1 Non-coding RNAs Related to Leptin and Insulin in the Hypothalamus
References
3 Non-coding RNAS Related to Type 2 Diabetes
3.1 Mechanisms in β Cell Maturation
3.1.1 Non-coding RNAs Related to β Cell Maturation
3.2 Mechanisms in Insulin Signaling in the Pancreas
3.2.1 Non-coding RNAs in Insulin Signaling in Type 2 Diabetes
3.3 Inflammation in the Pancreas, Insulin Resistance, and Type 2 Diabetes
3.3.1 Non-coding RNAs Related to Inflammation in the Pancreas, with Insulin Resistance and Type 2 Diabetes
References
4 Non-coding RNAs Related to Lipid Metabolism and Non-alcoholic Fatty Liver Disease
4.1 Cholesterol and Lipids in the Liver
4.1.1 Non-coding RNAs and Cholesterol in the Liver
4.2 Fatty Acids and Triglycerides
4.2.1 Non-coding RNAs and Fatty Acids and Triglycerides
4.3 Non-alcoholic Fatty Liver Disease
4.3.1 Non-coding RNAs Related to Non-alcoholic Fatty Liver Disease
References
5 Non-coding RNAs Related to Atherosclerosis
5.1 Endothelial Injury, Inflammation, and Apoptosis
5.1.1 Non-coding RNAs in Endothelial Injury, Inflammation, and Apoptosis
5.2 Fibroproliferative Remodeling and Plaque Destabilization
5.2.1 Non-coding RNAs in Fibroproliferative Remodeling and Plaque Destabilization
References
6 Non-coding RNAs in Cardiomyopathy and Heart Failure
6.1 Mechanisms in Cardiomyopathy and Heart Failure
6.2 Non-coding RNAs in Cardiomyopathy and Heart Failure
6.2.1 Non-coding RNAs in Cardiac Hypertrophy
6.2.2 Non-coding RNAs in Cardiac Fibrosis and ECM Deposition
6.2.3 Non-coding RNAs in Cardiac Inflammation
6.2.4 Non-coding RNAs in Cardiac Angiogenesis
6.2.5 Non-coding RNAs in Cardiac Apoptosis
6.3 Metabolic Syndrome: The Link Between Metabolic and Cardiovascular Diseases
6.3.1 Definition of Metabolic Syndrome
6.3.2 Oxidative Stress and Metabolic Syndrome
6.3.3 Metabolic Syndrome and Cardiovascular Risk
6.3.4 Non-coding RNAs and Metabolic Syndrome Components
References
7 Non-coding RNAs Related to Cardiometabolic Diseases and Associated to Cancer
7.1 Mechanisms of Cancer Progression
7.1.1 Induction of Stemness
7.1.2 Induction of EMT
7.1.3 Induction of Insulin Sensitized State, Cancer Cell Proliferation, and Protection Against Apoptosis
7.1.4 Induction of Glycolysis
7.1.5 Induction of Angiogenesis
7.1.6 Repression of Anti-tumor Immunity and Apoptosis
7.1.7 Cancer Cell Proliferation
7.1.8 EGFR Signaling and Cancer Progression
7.1.9 BMI1 and EZH2 in Cancer Progression
7.2 Non-coding RNAs Related to Metabolic and Cardiovascular Diseases Are also Involved in Cancer Progression
7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic Diseases and Cancer
References
8 Regulation of Non-coding RNAs in Cardiometabolic Tissues and Tumors
8.1 Regulation of miRs
8.1.1 Hypoxia
8.1.2 Glucose
8.1.3 Oxidative Stress
8.1.4 Inflammation
8.1.5 TGF-β
8.1.6 MYC
8.1.7 Overview
8.2 Differences in miR-Profiles in Cardiometabolic Tissues and Tumors May be Due to the Typical Action of lncRNAs and circ-RNAs in Tumors
8.3 Action of piRs Particularly in Tumors
References
9 Communication Between Tumor-Adjacent Tissues and Tumors with Emphasis on Role of Inflammatory Cells
9.1 Exchange of miR-Enriched Microvesicles
9.2 MiR-155 as a Link Between M1 Macrophage-Mediated Inflammation in Tumor-Adjacent Tissue and Tumor Growth and Metastasis
References
10 The Impact of Non-coding RNA Networks on Disease Comorbidity: Cardiometabolic Diseases, Inflammatory Diseases, and Cancer
10.1 Identification of Non-coding RNAs at Cross-Road of Metabolic and Cardiovascular Diseases
10.2 Many Non-coding RNAs at Cross-Road of Metabolic and Cardiovascular Diseases are also Related to Inflammatory Diseases
10.3 Differences Between Non-coding RNAs in Cardiometabolic Tissues and Tumors
10.4 Expected Technical Developments Underlying the Use of Non-coding RNAs as Biomarkers
10.5 The Need for Measuring Fluctuation of Non-coding RNAs
References
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Paul Holvoet

Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer

Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer

Paul Holvoet

Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer

Paul Holvoet Experimental Cardiology KU Leuven Leuven, Belgium Illustrations by Pieterjan Ginckels Faculty of Architecture KU Leuven Ghent, Belgium

ISBN 978-3-030-68843-1 ISBN 978-3-030-68844-8 (eBook) https://doi.org/10.1007/978-3-030-68844-8 © The Editor(s) (if applicable) and The Author(s), under exclusive license to Springer Nature Switzerland AG 2021 This work is subject to copyright. All rights are solely and exclusively licensed by the Publisher, whether the whole or part of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilms or in any other physical way, and transmission or information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed. The use of general descriptive names, registered names, trademarks, service marks, etc. in this publication does not imply, even in the absence of a specific statement, that such names are exempt from the relevant protective laws and regulations and therefore free for general use. The publisher, the authors and the editors are safe to assume that the advice and information in this book are believed to be true and accurate at the date of publication. Neither the publisher nor the authors or the editors give a warranty, expressed or implied, with respect to the material contained herein or for any errors or omissions that may have been made. The publisher remains neutral with regard to jurisdictional claims in published maps and institutional affiliations. This Springer imprint is published by the registered company Springer Nature Switzerland AG The registered company address is: Gewerbestrasse 11, 6330 Cham, Switzerland

For: Catherine Tine & Pieterjan Xanne & Pol Polly Pau & Umi

Preface

Protein-coding sequences occupy less than 2% of the genome, and 98% of the genome is transcribed into non-coding RNAs, of which many display regulatory functions. Our first objective was to give insight into the functional role of non-coding RNAs in the development of cardiometabolic diseases: obesity, type 2 diabetes, non-alcoholic fatty liver disease, atherosclerosis, myocardial infarction, cardiomyopathy, and heart failure. Our second goal was to investigate the relationship of this cluster with cancer. We started this review because tumor growth and metastasis require tight regulation of oxidative stress, immune response and inflammation, glucose uptake, and insulin signaling. Our PubMed survey learned that the number of published non-coding RNArelated studies is overwhelming. More than 1,800 papers are related to non-coding RNAs with obesity, more than 1,400 with type 2 diabetes, more than 300 with nonalcoholic fatty liver disease, more than 2,000 with atherosclerosis (of which more than 200 related to acute myocardial infarction), and more than 1,400 with cardiomyopathy and heart failure. More than 80,000 papers dealt with the association of non-coding RNAs and cancer. Only when I became an emeritus professor, I got the time to embark on an exhaustive and time-consuming analysis of the literature about non-coding RNAs that are functionally and clinically related to metabolic and cardiovascular diseases, and metabolic diseases and cancer. We followed current guidance on producing high-quality systematic reviews and meta-analyses. In following these standards, we provided quality evidence for the rational choice of a cluster of non-coding RNAs to focus on in future research, identifying non-coding RNAs with high potential for clinical applicability. Bold, functional data further supported this rational choice. Most of the original studies claimed a single non-coding RNA’s unique role as a treatment or biomarker target. In healthy subjects, tight control of this cluster of non-coding RNAs regulates oxidative stress in adipose tissues, the pancreas, the liver, and vascular and cardiac tissues to the degree that is just enough to ignite immune response to resolve the infection and disease attacks. A proper balance of oxidative stress is needed to retain glucose uptake, insulin signaling, and energy homeostasis. However, this cluster’s dysregulation ignites the development of cardiometabolic diseases. Besides, these non-coding RNAs’ expression profiles in cardiometabolic diseases shared similarities vii

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Preface

with other inflammatory diseases like Alzheimer’s disease, asthma, arthritis, and renal failure. Interestingly, we found that tumor cells can regulate this cluster of non-coding RNAs to escape from oxidative stress and anti-tumor immunity and maintain insulin sensitivity by shifting oxidative phosphorylation to glycolysis, facilitating cancer progression. Notably, the depth and breadth of discussion of non-coding RNAs, presenting current mechanistic and clinical evidence, in a broad spectrum of diseases in one book expose researchers studying one disease to new knowledge or new ways of thinking from other fields of research. With this information, they may avoid claiming a novel mechanistic role or diagnostic property in their field, which was established long before in another field. Clinical staff and epidemiologists may test the proposed cluster’s strength in predicting disease progression from early to a late stage in large cohorts and in identifying new therapies using emerging machine learning approaches to predict disease risk. This book emphasizes the need to consider comorbidities, disease stages, and behavioral and therapeutic changes in assessing the clinical value of non-coding RNAs. Polypharmacy interactions should be considered, especially in older people. Leuven, Belgium

Paul Holvoet

Acknowledgments

I thank Karin Sipido, the head of the Experimental Cardiology group at KU Leuven, to support me in this endeavor and keep facilities available at KU Leuven after becoming an emeritus professor. Warm thanks to Tine for helping me get goals clear and keeping me on track. The illustrations within this book significantly differ from these in research papers or even most review papers. In the latter, only small fragments of pathways in which the target non-coding RNAs are active are illustrated. In contrast, in this book, we not only present each pathway with a full list of functionally characterized non-coding RNAs, but we also emphasize the interactions between different pathways involved in disease progression, very often in vicious circles. It was a difficult task to present vast amounts of data in yet eligible figures. For this, collaboration with Pieterjan has been essential. Because he is an artist/architect with no background in biomedicine, I had to educate him step-by-step, enhancing my insight in a very complicated matter. I thank Springer Nature for accepting this book for publication. Immensely, I thank Tanja Weyandt for editorial guidance and Divya Meiyazhagan for production assistance. Most of all I thank Catherine, my long-life partner, for putting up with me and letting me fill in retirement in a rather unexpected way.

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Introduction

The Move Towards Cellular Risk Markers According to the World Health Organization, the prevalence of obesity has nearly tripled since 1975. In 2016, more than 1.9 billion adults were overweight. Of these, over 650 million were obese; 340 million children and adolescents aged 5–19 were overweight or obese. This increasing prevalence of obesity has significant healthcare implications, mainly since it is a considerable risk factor for type 2 diabetes and non-alcoholic fatty liver disease [1, 2]. These metabolic diseases individually and interdependently increase the incidence of cardiovascular diseases and cancer [3, 4]. However, personalized risk estimation accounts for inter-individual differences in a complex interplay between high body mass index, high blood pressure, high glucose, high triglycerides, low HDL cholesterol, physical inactivity, and smoking. Even after addressing above mentioned conventional risk factors, some patients still have a high residual risk. In light of these limitations and to improve risk-predicting algorithms, proteins mainly associated with inflammation [5, 6] or oxidative stress [7, 8] were proposed as risk stratifying proteins. However, the inclusion of these protein markers still did not allow efficient individual risk estimation [9, 10]. Therefore, attention shifted from the coding RNA, which translates into the proteins, to noncoding RNA.

Why Non-coding RNA? Protein-coding sequences occupy less than 2% of the genome, and 98% of the genome is transcribed into non-coding RNAs, of which many display regulatory functions [11–13]. They compass small non-coding RNAs or microRNAs or miRs, circular (circ-) RNAs, and long non-coding (lnc)RNAs. MiRs are highly conserved non-coding RNA molecules of around 22 nucleotides that exert post-transcriptional effects on gene expression [14, 15]. Unlike the better known linear RNA, circ-RNAs form a covalently closed continuous loop so that the 3’ and 5’ ends are joined together. xi

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Although they are considered as non-coding RNAs, many circ-RNAs arise from protein-coding genes [16–20]. LncRNAs are longer than 200 nucleotides, which coincide with the cut-off for many RNA extraction protocols [21–25]. Upon exposure to stress conditions, non-coding RNAs’ expression changes more rapidly than protein transcription factors. A change in their expression levels is reversible in contrast to that of inherited genome mutations [26, 27]. PIWI-interacting RNAs (PiRs) derive from single-stranded RNA, like lncRNAs. Their activity may be more similar in cancer cells and germline and stem cells than in somatic cells in cardiometabolic tissues [28, 29]. The main message is that a single non-coding RNA is not specific for one target but may affect several targets within one or several crucial pathways in one cell type or several cell types within one or several tissues. The same target may also be affected by several non-coding RNAs, which may influence each other’s expression or action. Further, they may be secreted in extracellular vesicles or exosomes, contributing to the communication between several cell types within one tissue or between several tissues. The packing in microvesicles may prevent degradation and facilitate cell-specific delivery, thereby increasing intracellular levels without increasing the production by that cell type [30–40]. The immune response and inflammation are also tightly related to cancer. Therefore, we considered the role of tumor cell-derived microvesicles or oncosomes in cellular transformation, phenotypic reprogramming, and functional re-education of recipient cells [30]. This book now summarizes growing evidence in support of this hypothesis.

Objectives Our first goal was to give insight into the functional role of non-coding RNAs in central pathways contributing to the development of obesity, type 2 diabetes, non-alcoholic fatty liver disease, atherosclerosis, myocardial infarction, cardiomyopathy, and heart failure. We will demonstrate that tight control of a cluster of non-coding RNAs regulates oxidative stress in adipose tissues, the pancreas, the liver, and vascular and cardiac tissues to the degree that is just enough to ignite immune response to resolve the infection and disease attacks. However, this cluster’s dysregulation results in cells’ adverse metabolic programming in adipose tissues, the pancreas, liver, and vascular and cardiac tissues. Our second goal was to investigate the relationship of this cluster with cancer. We will demonstrate that tumor cells can regulate this cluster of non-coding RNAs to escape from oxidative stress and anti-tumor immunity and maintain insulin sensitivity by shifting oxidative phosphorylation to glycolysis, facilitating cancer progression. Overall, we will thus identify a cluster of non-coding RNAs that lay at the intersection between cancer and cardiovascular disease, contributing to the emerging field of cardio-oncology [41– 49]. Ultimately, this cluster of non-coding RNAs may be prospectively analyzed in extensive cohort studies to determine their value in risk-predicting algorithms.

Introduction

xiii

Approach In preparing this book, the authors followed current guidance on producing highquality systematic reviews and meta-analyses of diagnostic test accuracy by both the Cochrane Collaboration [50] and the QUADUAS Group [51], as we have done before [52]. When studies that lack methodological rigor or have a high risk of bias are combined in a meta-analysis, the uninformative or erroneous results can waste further resources on future research or even lead to a wrong diagnosis. In following these standards, we aimed at providing quality evidence for the rational choice of non-coding RNAs to focus on in future research, identifying the non-coding RNAs with high potential for clinical applicability. This rational choice was further supported by bold data strongly suggesting that non-coding RNAs take part in the pathogenesis of a single or a multitude of diseases. Thereby, the author’s expertise as an active scientist, reviewer, and editor of scientific journals was instrumental. He engaged in not withholding any information that could favor one or another non-coding RNA as a sensitive and specific disease marker or target for intervention. Given the massive amount of data available, the reference list of published papers is not exhaustive. However, the reader will find a fair review of all non-coding RNA functions concerning all target diseases. The original paper supporting a particular function was mostly selected, except when later articles gave a more detailed mechanistic insight. Also, the quality of the papers was considered. Performing this kind of retrospective meta-analysis allows us to propose a selected cluster of non-coding RNAs that clinicians and epidemiologists may include in their future large cohort studies. Machine-learning is needed to include extensive data in disease-predicting algorithms or algorithms that help improve treatment [53–55]. Notably, the dynamics of expression according to the disease stage, fluctuating risk factor profile, and changes in therapies have to be considered [52]. For example, fluctuation in non-coding RNAs with variation in body mass index may be substantial because this fluctuation rather than baseline body mass index is related to coronary atherosclerosis [56]. Therefore, we wanted to include available information about disease stage-specific expression of non-coding RNAs. This information is, however, very scarce. Disruptive in kind, this is not a traditional scientific paper written for academic peer review and Journal selection, but a generous invitation to experts across industries and specializations to solve a significant global challenge.

Take Home Message • Around 98% of all transcriptional output in humans is non-coding RNA. Although genome-wide analysis has identified thousands of non-coding RNAs, only a shortlist of non-coding RNAs have been adequately functionally characterized.

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• Every non-coding RNA has several functions, and several non-coding RNAs share the same function. • We did not find any single non-coding RNA with a unique role in developing metabolic and cardiovascular diseases or cancer. Importantly, we have identified a cluster of non-coding RNAs at the cross-road between metabolic and cardiovascular diseases and cancer (Fig. 1). • Differences in non-coding RNA profiles between cardiometabolic tissues and tumors are often related to energy homeostasis, insulin signaling, mitochondrial dysfunction, oxidative and endoplasmic reticulum stress, and macrophage polarization and inflammation. All together, they are responsible for differences in metabolic programming of cardiometabolic tissues and tumors.

Fig. 1 Cluster of non-coding RNAs of which the imbalance is related to cardiometabolic diseases and cancer development. Within the pink circle, we show a cluster of non-coding RNAs common in the progression of cardiometabolic diseases, which are also related to cancer. The non-coding RNAs within the blue circle, up-regulated explicitly in tumors, may be responsible for the different relationship miRs with cardiometabolic diseases and cancer, allowing a specific reprogramming of tumor cells directed to survival. The small dots represent microvesicles in which miRs are actively and specifically loaded, which play a critical role in the communication between tumor-adjacent tissue, inflammatory cells, and tumor

Introduction

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• PiR’s activities may be more similar in cancer cells and germline and stem cells than in somatic cells in cardiometabolic tissues. • A cell type’s behavior depends on non-coding RNAs expressed by this cell and non-coding RNAs enriched in microvesicles secreted by other cells, even in other tissues. Tumors secrete microvesicles containing non-coding RNAs, which induce healthy cells to convert to glycolysis. Inflammatory cells secrete microvesicles containing non-coding RNAs, which induce proliferation and migration of cancer cells. Finally, cancer cells may selectively shuttle anti-oncogenic noncoding RNAs to microvesicles and remove them to preserve proliferation and metastasis. • Overall, we present a list of non-coding RNAs, which are candidates for inclusion in machine learning approaches, considering changes in their expression profiles according to disease stage and behavioral and therapeutic changes. Considering all data, we present a model explaining why miR-155 is the main target for preventing cardiometabolic diseases and cancer.

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Bei, Y. et al. (2017). Extracellular Vesicles in Cardiovascular Theranostics. Theranostics, 7, 4168–4182, doi:10.7150/thno.21274. Chen, X. et al. (2008). Characterization of microRNAs in serum: a novel class of biomarkers for diagnosis of cancer and other diseases. Cell Research, 18, 997–1006, doi:10.1038/cr.2008.282. Lawrie, C. H. et al. (2008). Detection of elevated levels of tumour-associated microRNAs in serum of patients with diffuse large B-cell lymphoma. British Journal of Haematology, 141, 672–675, doi:10.1111/j.1365-2141.2008.07077.x. Mitchell, P. S. et al. (2008). Circulating microRNAs as stable blood-based markers for cancer detection. Proceedings of the National Academy of Sciences of the United States of America, 105, 10513–10518, doi:10.1073/pnas.0804549105. Small, E. M. & Olson, E. N. (2011). Pervasive roles of microRNAs in cardiovascular biology. Nature, 469, 336–342, doi:10.1038/nature09783. Vickers, K. C., Palmisano, B. T., Shoucri, B. M., Shamburek, R. D. & Remaley, A. T. (2011). MicroRNAs are transported in plasma and delivered to recipient cells by high-density lipoproteins. Nature Cell Biology, 13, 423–433, doi:10.1038/ncb2210. Nishimura, Y. et al. (2013). Targeting cancer cell-specific RNA interference by siRNA delivery using a complex carrier of affibody-displaying bio-nanocapsules and liposomes. Journal of Nanobiotechnology, 11, 19, doi:10.1186/1477-3155-11-19. Nazarenko, I., Rupp, A. K. & Altevogt, P. (2013). Exosomes as a potential tool for a specific delivery of functional molecules. Methods in Molecular Biology, 1049, 495–511, doi:10.1007/978-1-62703-547-7_37. Zarzour, A., Kim, H. W. & Weintraub, N. L. (2019). Epigenetic Regulation of Vascular Diseases. Arteriosclerosis, Thrombosis, and Vascular Biology, 39, 984–990, doi:10.1161/ATVBAHA.119.312193. Anker, M. S., von Haehling, S. & Anker, S. D. (2019). Novel biomarkers in heart failure and cardio-oncology. Kardiologia Polska, 77, 329–330, doi:10.5603/KP.2019.0051. Ameri, P. et al. (2018). Cancer diagnosis in patients with heart failure: epidemiology, clinical implications and gaps in knowledge. European Journal of Heart Failure, 20, 879–887, doi:10.1002/ejhf.1165. Argolo, D. F., Hudis, C. A. & Iyengar, N. M. (2018). The Impact of Obesity on Breast Cancer. Current Oncology Reports, 20, 47, doi:10.1007/s11912-018-0688-8. Mehta, L. S. et al. (2018). Cardiovascular Disease and Breast Cancer: Where These Entities Intersect: A Scientific Statement From the American Heart Association. Circulation, 137, e30–e66, doi:10.1161/CIR.0000000000000556. Kitson, S. et al. (2018). Interventions for weight reduction in obesity to improve survival in women with endometrial cancer. Cochrane Database of Systematic Reviews, 2, CD012513, doi:10.1002/14651858.CD012513.pub2. Leonardi, G. C., Accardi, G., Monastero, R., Nicoletti, F. & Libra, M. (2018). Ageing: from inflammation to cancer. Immunity & Ageing, 15, 1, doi:10.1186/s12979-017-0112-5. Mastropasqua, F., Girolimetti, G. & Shoshan, M. (2018). PGC1alpha: Friend or Foe in Cancer? Genes (Basel), 9, doi:10.3390/genes9010048. Xuan, Y. et al. (2019). Association of Serum Markers of Oxidative Stress With Incident Major Cardiovascular Events, Cancer Incidence and All-Cause Mortality in Type 2 Diabetes Patients: Pooled Results From Two Cohort Studies. Diabetes Care, doi:10.2337/dc19-0292. Cumpston, M. et al. (2019). Updated guidance for trusted systematic reviews: a new edition of the Cochrane Handbook for Systematic Reviews of Interventions. Cochrane Database of Systematic Reviews, 10, ED000142, doi:10.1002/14651858.ED000142. Whiting, P. F. et al. (2011). QUADAS-2: a revised tool for the quality assessment of diagnostic accuracy studies. Annals of Internal Medicine, 155, 529–536, doi:10.7326/0003-4819-1558-201110180-00009. Navickas, R. et al. (2016). Identifying circulating microRNAs as biomarkers of cardiovascular disease: a systematic review. Cardiovascular Research, 111, 322–337, doi:10.1093/cvr/cvw174.

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Introduction Goldstein, B. A., Navar, A. M. & Carter, R. E. (2017). Moving beyond regression techniques in cardiovascular risk prediction: applying machine learning to address analytic challenges. European Heart Journal, 38, 1805–1814, doi:10.1093/eurheartj/ehw302. Weng, S. F., Reps, J., Kai, J., Garibaldi, J. M. & Qureshi, N. (2017). Can machine-learning improve cardiovascular risk prediction using routine clinical data? PLoS One, 12, e0174944, doi:10.1371/journal.pone.0174944. Delgado-Rodriguez, M. & Sillero-Arenas, M. (2018). Systematic review and meta-analysis. Medicina Intensiva, 42, 444–453, doi:10.1016/j.medin.2017.10.003. Lee, D. H.et al. (2010). Differential associations of weight dynamics with coronary artery calcium versus common carotid artery intima-media thickness: The CARDIA Study. American Journal of Epidemiology, 172, 180–189, doi:10.1093/aje/kwq093.

Contents

1

2

Biogenesis and Modes of Action of miRs and Circular and Long Non-coding RNAs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.1 MiRs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.1.1 Biogenesis of miRs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.1.2 MiR Modes of Action . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.1.3 Naming of miRs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.1.4 Useful Resources on miRs . . . . . . . . . . . . . . . . . . . . . . . . . . 1.2 Circular RNAs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.2.1 Biogenesis of Circular RNAs . . . . . . . . . . . . . . . . . . . . . . . . 1.2.2 Circular RNAs Modes of Action . . . . . . . . . . . . . . . . . . . . . 1.2.3 Useful Resources on Circ-RNAs . . . . . . . . . . . . . . . . . . . . . 1.3 lncRNAs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.3.1 Biogenesis of lncRNAs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.3.2 Modes of Action of lncRNAs . . . . . . . . . . . . . . . . . . . . . . . . 1.4 piRs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4.1 Biogenesis of piRs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4.2 Modes of Action of piRs . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4.3 Useful Resources on piRs . . . . . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Non-coding RNAs Related to Obesity . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.1 Mechanisms in White Adipogenesis . . . . . . . . . . . . . . . . . . . . . . . . 2.1.1 Role of Non-coding RNAs in White Adipogenesis . . . . . . 2.2 Inflammation and Insulin Resistance in Obese White Adipose Tissue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.2.1 Role of Non-coding RNAs in Inflammation and Insulin Resistance in Obese White Adipose Tissue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.3 Mechanisms in Brown Adipogenesis and Thermogenesis . . . . . . . 2.3.1 Role of Non-coding RNAs in Brown Adipogenesis and Thermogenesis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.4 Mechanisms in Browning of White Adipose Tissues . . . . . . . . . . .

1 1 1 3 3 4 4 4 4 7 7 7 8 11 11 11 13 13 21 21 24 25

29 30 32 33 xix

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2.4.1 Role of Non-coding RNAs in Browning of White Adipose Tissue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.5 Leptin and Insulin in the Hypothalamus . . . . . . . . . . . . . . . . . . . . . 2.5.1 Non-coding RNAs Related to Leptin and Insulin in the Hypothalamus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3

4

Non-coding RNAS Related to Type 2 Diabetes . . . . . . . . . . . . . . . . . . . 3.1 Mechanisms in β Cell Maturation . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1.1 Non-coding RNAs Related to β Cell Maturation . . . . . . . . 3.2 Mechanisms in Insulin Signaling in the Pancreas . . . . . . . . . . . . . . 3.2.1 Non-coding RNAs in Insulin Signaling in Type 2 Diabetes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3 Inflammation in the Pancreas, Insulin Resistance, and Type 2 Diabetes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3.1 Non-coding RNAs Related to Inflammation in the Pancreas, with Insulin Resistance and Type 2 Diabetes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Non-coding RNAs Related to Lipid Metabolism and Non-alcoholic Fatty Liver Disease . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1 Cholesterol and Lipids in the Liver . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.1 Non-coding RNAs and Cholesterol in the Liver . . . . . . . . 4.2 Fatty Acids and Triglycerides . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2.1 Non-coding RNAs and Fatty Acids and Triglycerides . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3 Non-alcoholic Fatty Liver Disease . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3.1 Non-coding RNAs Related to Non-alcoholic Fatty Liver Disease . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

34 35 36 36 53 53 55 56 59 60

61 62 73 73 75 76 77 77 79 81

5

Non-coding RNAs Related to Atherosclerosis . . . . . . . . . . . . . . . . . . . . 89 5.1 Endothelial Injury, Inflammation, and Apoptosis . . . . . . . . . . . . . . 89 5.1.1 Non-coding RNAs in Endothelial Injury, Inflammation, and Apoptosis . . . . . . . . . . . . . . . . . . . . . . . . 94 5.2 Fibroproliferative Remodeling and Plaque Destabilization . . . . . . 98 5.2.1 Non-coding RNAs in Fibroproliferative Remodeling and Plaque Destabilization . . . . . . . . . . . . . . . 101 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102

6

Non-coding RNAs in Cardiomyopathy and Heart Failure . . . . . . . . . 6.1 Mechanisms in Cardiomyopathy and Heart Failure . . . . . . . . . . . . 6.2 Non-coding RNAs in Cardiomyopathy and Heart Failure . . . . . . . 6.2.1 Non-coding RNAs in Cardiac Hypertrophy . . . . . . . . . . . . 6.2.2 Non-coding RNAs in Cardiac Fibrosis and ECM Deposition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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6.2.3 Non-coding RNAs in Cardiac Inflammation . . . . . . . . . . . 6.2.4 Non-coding RNAs in Cardiac Angiogenesis . . . . . . . . . . . 6.2.5 Non-coding RNAs in Cardiac Apoptosis . . . . . . . . . . . . . . 6.3 Metabolic Syndrome: The Link Between Metabolic and Cardiovascular Diseases . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.3.1 Definition of Metabolic Syndrome . . . . . . . . . . . . . . . . . . . 6.3.2 Oxidative Stress and Metabolic Syndrome . . . . . . . . . . . . . 6.3.3 Metabolic Syndrome and Cardiovascular Risk . . . . . . . . . 6.3.4 Non-coding RNAs and Metabolic Syndrome Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7

8

Non-coding RNAs Related to Cardiometabolic Diseases and Associated to Cancer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1 Mechanisms of Cancer Progression . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.1 Induction of Stemness . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.2 Induction of EMT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.3 Induction of Insulin Sensitized State, Cancer Cell Proliferation, and Protection Against Apoptosis . . . . . . . . 7.1.4 Induction of Glycolysis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.5 Induction of Angiogenesis . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.6 Repression of Anti-tumor Immunity and Apoptosis . . . . . 7.1.7 Cancer Cell Proliferation . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.8 EGFR Signaling and Cancer Progression . . . . . . . . . . . . . . 7.1.9 BMI1 and EZH2 in Cancer Progression . . . . . . . . . . . . . . . 7.2 Non-coding RNAs Related to Metabolic and Cardiovascular Diseases Are also Involved in Cancer Progression . . . . . . . . . . . . . 7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic Diseases and Cancer . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Regulation of Non-coding RNAs in Cardiometabolic Tissues and Tumors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.1 Regulation of miRs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.1.1 Hypoxia . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.1.2 Glucose . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.1.3 Oxidative Stress . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.1.4 Inflammation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.1.5 TGF-β . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.1.6 MYC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.1.7 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.2 Differences in miR-Profiles in Cardiometabolic Tissues and Tumors May be Due to the Typical Action of lncRNAs and circ-RNAs in Tumors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.3 Action of piRs Particularly in Tumors . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

xxi

126 126 127 128 128 129 129 130 131 149 149 149 153 155 156 157 158 162 164 166 167 167 187 213 213 215 216 219 219 220 221 221

223 224 226

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Communication Between Tumor-Adjacent Tissues and Tumors with Emphasis on Role of Inflammatory Cells . . . . . . . . 9.1 Exchange of miR-Enriched Microvesicles . . . . . . . . . . . . . . . . . . . . 9.2 MiR-155 as a Link Between M1 Macrophage-Mediated Inflammation in Tumor-Adjacent Tissue and Tumor Growth and Metastasis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

10 The Impact of Non-coding RNA Networks on Disease Comorbidity: Cardiometabolic Diseases, Inflammatory Diseases, and Cancer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.1 Identification of Non-coding RNAs at Cross-Road of Metabolic and Cardiovascular Diseases . . . . . . . . . . . . . . . . . . . 10.2 Many Non-coding RNAs at Cross-Road of Metabolic and Cardiovascular Diseases are also Related to Inflammatory Diseases . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.3 Differences Between Non-coding RNAs in Cardiometabolic Tissues and Tumors . . . . . . . . . . . . . . . . . . . . . 10.4 Expected Technical Developments Underlying the Use of Non-coding RNAs as Biomarkers . . . . . . . . . . . . . . . . . . . . . . . . 10.5 The Need for Measuring Fluctuation of Non-coding RNAs . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

241 241

242 244

247 247

248 253 254 255 256

Abbreviations

4EBP2 ABC ACAT ACE2 ACSL1 AD ADAM ADINR ADIPOQ ADIPOR AFAP1-AS1 AGE AI AKT AMPK ANG II ANRIL AOX APO ARF3 AS160 or TBC1D4 ASC AT1R or AGTR1 ATP B4GALT1-AS1 BABAM2-AS1 or BRE-AS1

Eukaryotic translation initiation factor 4E binding protein ATP-binding cassette Acetyl-CoA C-acetyltransferase Angiotensin I converting enzyme 2 Acyl-CoA synthetase 1 Alzheimer’s disease ADAM metallopeptidase domain Adipogenic differentiation induced non-coding RNA Adiponectin Adiponectin receptor Actin filament associated protein 1 antisense RNA Advanced glycation end product Artificial intelligence AKT serine/threonine kinase AMP-Activated catalytic Angiotensinogen Cyclin-dependent kinase inhibitor 2B antisense RNA 1 Fatty acyl-CoA oxidase Apolipoprotein ADP-ribosylation factor 3 TBC1 domain family, member 4 Adipocyte stem cell Angiotensin II receptor type 1 Adenosine triphosphate Suppressor of hepatic gluconeogenesis and lipogenesis (lncSHGL in mice) BRISC and BRCA1 A complex member 2 antisense RNA 1 xxiii

xxiv

BACE1 BAK BANF or BAF BAT BAX BCL2 BCL2L11 or BIM bFGF BLACAT1 BMI1 BMP BRCA1 CASC11 CCL2 or MCP-1 CCN CCR2 or MCP-1 receptor CD206 or MRC1 CDK CDKN1A or P21 CDKN2B CDKN2B-AS1 CETP CHRF circ-ANAPC7 circ-CDR1as or ciRs-7 circCHFR circ-FOXM1 circ-HIPK3 circ-ITCH circ-MTO1 circ-RNA circ-WDR77 circ-ZNF609 CM COL COX1 or MTCOI CPE CREB

Abbreviations

Beta-site amyloid precursor protein cleaving enzyme 1 BCL2 antagonist/killer Barrier to autointegration factor 1 Brown adipose tissue Pro-apoptotic BCL2 associated X, apoptosis regulator BCL2 apoptosis regulator BCL2 like 11 Basic fibroblast growth factor Bladder cancer-associated transcript one BMI proto-oncogene, polycombing ring finger 1 Bone morphogenetic protein BRCA1 DNA repair associated protein 1 Cancer susceptibility 11 lncRNA C-C motif chemokine ligand 2 Cyclin C-C motif chemokine receptor 2 Mannose receptor Cyclin-dependent kinase Cyclin dependent kinase inhibitor 1A Cyclin-dependent kinase inhibitor 2B CDKN2B antisense RNA 1 Cholesteryl ester transfer protein Cardiac hypertrophy related factor Anaphase-promoting complex subunit 7 circ-RNA Circular cerebellar degeneration related protein 1 (CDR1) antisense RNA Checkpoint with forkhead and ring finger domains circ-RNA Forkhead box M1 circ-RNA Homeodomain interacting protein kinase three circ-RNA Itchy E3 ubiquitin-protein ligase circ-RNA Mitochondrial tRNA translation optimization one circ-RNA Circular RNA WD repeat domain 77 circ-RNA Zinc finger protein 609 circ-RNA Cardiomyocyte Collagen Cytochrome oxidase 1 Carboxypeptidase cAMP-responsive element-binding

Abbreviations

cSMARCA4

CXCL CXCR DAMP DKK2 DLK1 E2F1 EBF EC ECM EDN EGF EID EIF ELK EMT EPC ER ERK ERRα EZH2 FA FABP4 or aP2 FAT or CD36 FB FBXW7 FEZF1 FEZF1-AS1 FGD5-AS1 FGF FOXO G6PD GAS5 GH GLP GLUT GSK3β H19 HGF

xxv

SWI/SNF related, matrix associated, actin-dependent regulator of chromatin, subfamily a, member 4 C-X-C motif chemokine ligand C-X-C motif chemokine receptor; dendritic cell Danger-associated molecular pattern Dickkopf associated protein 2 Delta-like non-canonical NOTCH ligand E2F transcription factor 1 Early B cell factor Endothelial cell Extracellular matrix Endothelin-1 Epidermal growth factor EP300 interacting inhibitor of differentiation Eukaryotic translation initiation factor ETS transcription factor Epithelial-mesenchymal transition Endothelial progenitor cells Endoplasmic reticulum Extracellular signal-regulated kinase Estrogen related receptor alpha Enhancer of the zeste two polycomb repressive complex two subunit Fatty acids Fatty acid-binding protein four FA translocase Fibroblast F-box and WD repeat domain containing 7 Fasciculation and elongation protein zeta 1 FEZF1 antisense RNA 1 FYVE, RhoGEF and PH domain containing 5 antisense RNA 1 Fibroblast growth factor Forkhead box O3 Glucose-6-phosphate-dehydrogenase Growth arrest-specific 5 Growth hormone Glucagon-like peptide Solute carrier family or facilitated glucose transporter Glycogen synthase kinase three beta H19 imprinted maternally expressed transcript lncRNA Hepatocyte growth factor

xxvi

HIF HIPK HK2 HMGA, Formerly HMG-I/Y HMGB1 HMGCR HNF or MODY HNF1A-AS1 HOTAIR HOX HOXC-AS1 HSF HULC ICAM IDOL or MYLIP IFN Ig IGF IGFR IL ILC2 IR IRAK3 or IRAK-M IRF IRS ITCH ITG JAK KCNQ1OT1 KLF KRAS LCAT LDLR LIN28 LINC00341 lincRNA-p21 LINC-ROR lncARSR lnc-HC lncRNA

Abbreviations

Hypoxia-induced hypoxia-inducible factor Homeodomain interacting protein kinase Hexokinase two High mobility group AT-hook1 High-mobility group B1 Hydroxy-3-methylglutaryl coenzyme A reductase HNF homeobox HNF1 homeobox A antisense RNA 1 Homeobox transcript antisense lncRNA Homeobox HOXC cluster antisense RNA 1 Heat shock transcription factor Hepatocellular carcinoma up-regulated long non-coding RNA Intercellular adhesion molecule 1 Ubiquitin ligase inducible degrader of LDLR Interferon Immunoglobulin Insulin-like growth factor Insulin-like growth factor receptor Interleukin Innate lymphoid type 2 cells Insulin receptor Interleukin-1 receptor-associated kinase-3 Interferon regulatory factor Insulin substrate receptor Itchy E3 ubiquitin protein ligase Integrin Janus kinase Potassium voltage-gated channel subfamily Q member 1 opposite strand/antisense transcript 1 Krüppel-like zinc finger transcription factor KRAS proto-oncogene, GTPase Lecithin-cholesterol acyltransferase Low-density lipoprotein receptor Lin-28 homolog Spectrin-repeat containing nuclear envelope family member 3 Tumor protein p53 pathway corepressor 1 Long intergenic non-protein coding RNA regulator of reprogramming Regulator of Akt signaling associated with HCC and RCC lncRNA lncRNA derived from hepatocytes Long non-coding RNA

Abbreviations

lncRNA-ATB LncRNA-ES1 LOX-1 LXR MACC1-AS1 MAFA MALAT1 MAPK MCL1 MDSC MEG3 MetS MHC MIAT MIF miR MIR155HG MIR31HG MIRT1 MMP MPO MRPL39 MSC mTOR MYC MYF NAFLD NALP3 NANOG NEAT1 NFκB NIFK NIFK-AS1 NK NKX NLRP3 NOD2 NORAD NOS NOX NQO1

xxvii

Long non-coding RNA activated by TGF-β Long intergenic non-protein coding RNA 1108 Lectin-like oxidized low-density lipoprotein receptor-1 Liver X receptor MET transcriptional regulator MACC1 antisense Maf transcription factor Metastasis-associated lung adenocarcinoma transcript one Mitogen-activated protein kinase MCL1 apoptosis regulator, BCL2 family member M2 myeloid suppressor cell Maternally expressed 3 lncRNA Metabolic syndrome Major histocompatibility complex Myocardial infarction associated transcript Migration inhibitory factor MicroRNA MIR155 host gene MIR31 host gene Myocardial infarction associated with transcript 1 Metalloproteinases Myeloperoxidase Mitochondrial ribosomal protein L19 Mesenchymal cell Mammalian (or mechanistic) target of rapamycin MYC oncogene Myogenic factor Non-alcoholic fatty liver disease NACHT, LRR, and PYD domains containing protein Nanog homeobox Nuclear paraspeckle assembly transcript Nuclear factor kappa B Nucleolar protein interacting with the FHA domain of MKI67 NIFK antisense RNA 1 Natural killer NK6 homeobox NLR family pyrin domain containing 3 Nucleotide-binding oligomerization domain 2 Non-coding RNA activated by DNA damage Nitric oxide synthase NADPH oxidase NAD (P) H quinone dehydrogenase 1

xxviii

NRF OA ObR OCT4 OIP5-AS1 ox-LDL OXPHOS p70S6K or RPS6KB1 PCNA PCSK9 PD1 PDCD PDGF PDK PD-L1 PDX1 PFKFB3

PGC-1α PI3K PiR PIWIL PlGF PLUTO PNLDC1 POMC PPAR PRC2 PRDM PRL PTEN PVT1 RA RAAS Rab-GAP RALY RASSF1 RBP RF RISC ROS RUNX

Abbreviations

Necrosis related factor Osteoarthritis Leptin receptor POU class 5 homeobox one or POU5F1 Opa interacting protein 5 (OIP5) antisense RNA 1 Oxidized LDL Oxidative phosphorylation Ribosomal protein S6 kinase Proliferating cell nuclear antigen Proprotein convertase subtilisin/kexin type 9 Programmed cell death-1 Programmed cell death Platelet-derived growth factor Pyruvate dehydrogenase kinase Programmed death-ligand 1 Pancreatic and duodenal homeobox 1 6-phosphofructo-2-kinase/fructose-2,6biphosphatase 3 PPAR-γ co-activator 1α Phosphatidylinositol 3-kinase Piwi like RNA-mediated gene silencing PIWI-interacting RNA Placental growth factor PDX1 associated lncRNA, up-regulator of transcription PARN like, ribonuclease domain containing 1 Pro-opiomelanocortin Peroxisome proliferator-activated receptor Polycomb repressive complex 2 PR/SET domain Prolactin Phosphatase and tensin homolog PVT oncogene 1 Rheumatoid arthritis Renin-angiotensin-aldosterone system Rab-GTPase activating protein RALY heterogeneous nuclear ribonucleoprotein Ras association domain family member 1 RNA binding protein Regulatory factor Ribonucleoprotein RNA-induced silencing complex Reactive oxygen species RUNX family transcription factor

Abbreviations

SELENOW or SEPW1 SIRT SMARCA4 or BRG1

SMC SMMHC SNAI2 or SLUG SNAIL or SNAI1 SNHG SOCS3 SOD SOX SOX21-AS1 SPROUTY4 or SPRY4 SR-A SRA SR-B1 or SCARB1 SRC SREBF1 or SREBP1 STAT TAM TBX21 or TBET TDG TET TF TG TGF TIMP TINCR TLR TMEM26 TNF TRAF TRAIL TRIF or TICAM1 TUG1 TWIST UCA1 UCP UPR VCAM VEGF VSMC

xxix

Selenoprotein W pseudogene 1 Sirtuin SWI/SNF related, matrix associated, actin-dependent regulator of chromatin, subfamily a, member 4 Smooth muscle cell Smooth muscle myosin heavy chain Snail family transcriptional repressor 2 Snail family transcriptional repressor 1 Small nucleolar RNA host gene Suppressor of cytokine signaling 3 Superoxide dismutase SRY-box transcription factor SOX-21 antisense divergent transcript 1 Sprouty four Scavenger receptor A Steroid receptor RNA activator Scavenger receptor BI SRC proto-oncogene, non-receptor tyrosine kinase Sterol regulatory element-binding transcription factor 1 Signal transducer and activator of transcription Tumor-associated macrophage T-box transcription factor 21 Thymine DNA glycosylase Ten-eleven translocation Tissue factor Triglycerides Transforming growth factor TIMP metallopeptidase inhibitor TINCR ubiquitin domain-containing Toll-like receptor Transmembrane protein 26 Tumor necrosis factor TNF receptor associated factor TNF-related apoptosis-inducing ligand Toll-like receptor adaptor molecule 1 Taurine up-regulated 1 Twist family bHLH transcription factor Urothelial cancer-associated 1 Uncoupling proteinUCP Unfolded protein response Vascular cell adhesion molecule Vascular endothelial growth factor Vascular smooth muscle cell

xxx

WAT WISPER XIST ZEB ZEB1-AS1 ZFAS1 ZFR

Abbreviations

White adipose tissue WNT1 inducible signaling pathway protein 2 (WISP2) super-enhancer-associated RNA X inactive specific transcript zinc finger E-box binding homeobox zinc finger E-box-binding homeobox two antisense RNA 1 ZNFX1 antisense RNA 1 Zinc finger RNA binding protein

Chapter 1

Biogenesis and Modes of Action of miRs and Circular and Long Non-coding RNAs

Abstract Short non-coding miRs induce mRNA degradation or repress mRNA translation leading to less protein. Several long and circular non-coding RNAs target the same miR that targets several RNAs. Most circular RNAs silence different miRs; others may stimulate transcription or inhibit translation. Long non-coding RNAs act as signals not requiring mRNA translation; their action is like transcription factors. Alternatively, they act as decoys of miRs and proteins, or guide proteins to their target genes or act as scaffolds bringing proteins together. Their expression with temporal changes is most sensitive to pathophysiological stimuli. The short halflife of miRs and lncRNAs is like that of regulatory messenger RNAs. However, the packing of miRs in microvesicles avoids degradation and prolongs their half-life. PiRs are Dicer-independent, PIWI protein-associated small silencing RNAs derived from single-stranded, coding or non-coding RNA. They guide PIWI proteins to target sequences in the genome by sequence complementarity, where PIWI proteins silence transcription.

1.1 MiRs 1.1.1 Biogenesis of miRs MiRs are endogenous, non-coding, and small (18–22 nucleotides) RNA molecules produced by all cell types. Seventy percent of miRs locate in introns or exons, and approximately 30% in intergenic regions [1] (Fig. 1.1). Intronic and exonic miRs are part of annotated genes. They need to be spliced from the host by the spliceosome and a branching enzyme. Intergenic miRs are transcribed from intergenic regions or gene deserts; they form independent transcription units [2–4]. Tightly linked miRs are transcribed as polycistronic messengers. However, miR genes separated by more than 50 kb tend to represent independent transcription units [5]. Illustrations by Pieterjan Ginckels, Faculty of Architecture, KU Leuven, Ghent, Belgium. © The Author(s), under exclusive license to Springer Nature Switzerland AG 2021 P. Holvoet, Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer, https://doi.org/10.1007/978-3-030-68844-8_1

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Fig. 1.1 Biogenesis and mode of action of miRs. The majority of miRs are in introns or exons, derived from the processing of non-protein-coding regions of gene transcripts. Others are intergenic and are transcribed from non-coding DNA sequences between protein-coding genes as independent transcription units. Polycistronic miR genes may contain up to seven miR precursors. RNA polymerases II and III are responsible for miR transcription. MiRs with an ‘in sense’ orientation compared to annotated coding genes are transcribed as parts of longer molecules processed in the nucleus into hairpin RNAs of 70–100 nucleotides by the dsRNA-specific ribonuclease Drosha. The hairpin RNAs are transported to the cytoplasm by exportin 5, where they are digested by a second, double-strand specific ribonuclease called Dicer. The cleavage product becomes incorporated as single-stranded RNA into the ribonucleoprotein RNA-induced silencing complex RISC. In animals, single-stranded miR binds specific mRNA through sequences that, in most cases, are significant, though not wholly complementary to the target mRNA. As a result, these mRNA molecules are silenced by one or more of the following processes: cleavage of the mRNA strand into two pieces; destabilization of the mRNA through shortening of its poly(A) tail; and less efficient translation of the mRNA into proteins by ribosomes

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The specific half-life of each mRNA is closely related to its physiological function. Short-lived mRNAs are mostly regulatory genes, while long-lived mRNAs are often housekeeping genes. The half-life of miRs is comparable to that of regulatory mRNAs [6]. However, they may survive longer in the circulation when packed in exosomes or associated with lipoproteins [7–15]. RNA polymerase II transcribes miR genes [16–20]. In animals, the first step in miR maturation is the nuclear cleavage of the several-kb-long pri-miR, which releases an approximately 70 nucleotides, cropped, hairpin-shaped intermediate known as a miR precursor or pre-miR. The Drosha RNase III endonuclease is responsible for this nuclear processing [4, 21, 22]. Drosha is not active without a partner, forming a complex with the DiGeorge syndrome critical region gene 8, which contains two double-stranded RNA-binding domains [23, 24]. The hairpin precursor is actively transported from the nucleus to the cytoplasm by exportin 5 [25, 26]. A second enzyme, an RNase III endonuclease called Dicer, is responsible for generating a single-stranded RNA of about 21 nucleotides, the mature miR [27, 28]. After cleavage in the cytoplasm, the cleavage products become incorporated as single-stranded RNAs into the ribonucleoprotein RNA-induced silencing (RISC) complex [29]. RISC has been purified from human cells and contains a member of the Argonaute protein family, a core component of the complex [29, 30].

1.1.2 MiR Modes of Action Once incorporated in the cytoplasmic RISC complex, miRs regulate protein-coding genes’ output through diverse mechanisms [31]. The interaction of miRs with the 3 untranslated region (3 UTR) of protein-coding genes, considered the primary mechanism, leads to decreased protein output either by mRNA degradation or by translational repression [21] (Fig. 1.1). Interaction of miRs with the 5 UTR of protein-coding genes causes translational repression [32] or activation of the targeted proteins [33]. Besides targeting untranslated regions, miRs can also target the coding sequence and repress the translation of targeted genes [34]. Moreover, some miRs can interact with regulatory protein complexes, such as the argonaute RISC catalytic component 2 and fragile X mental retardation-related protein 1, and indirectly up-regulate the target’s translation gene [35].

1.1.3 Naming of miRs According to a standard nomenclature system, names are assigned to experimentally confirmed miRs before publication [36, 37]. A dash and a number follow the prefix “miR,” the latter often indicating the order of naming. For example, miR-124 was likely discovered and named before miR-126. A capitalized “miR-” refers to the mature form of the miR, while the uncapitalized “mir-” refers to the pre-miR and the pri-miR, and “MIR” refers to the gene that encodes them [38]. MiRs with nearly identical sequences except for one or two nucleotides are annotated with an additional

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lower-case letter. For example, miR-124a is closely related to miR-124b. When about the same amount of two mature miRs originate from the same pre-miR’s opposite arms, they are denoted with a -3p or -5p suffix. However, the mature miR from one arm of the hairpin is usually much more abundant than that from the other arm, in which case, an asterisk following the name indicates the mature species found at low levels from the opposite wing of a hairpin. For example, miR-124 and miR-124* share a pre-miR hairpin, but much more miR-124 is in a cell.

1.1.4 Useful Resources on miRs Tools 4 miRs (https://tools4mirs.org/software/target_prediction) predict targets of miRs in several species.

1.2 Circular RNAs 1.2.1 Biogenesis of Circular RNAs Circular (circ-) RNA is a type of RNA which, unlike the better known linear RNA, forms a covalently closed continuous loop, i.e., in circ-RNA, the 3 and 5 ends have been joined together [39–42]. Eukaryotic circ-RNA molecules are produced by splicing, catalyzed by the spliceosome machinery or ribozymes. Typically, the split coding exonic sequences are reattached together in a continuous coding transcript. Therefore, circ-RNAs are distinct from their linear counterparts because they are devoid of free ends and, therefore, resistant toward exonucleases and escape RNA degradation, thereby prolonging their half-life [43, 44]. The introns are removed through a spliceosome to generate circular RNA (Fig. 1.2). Circ-RNAs are often expressed at low levels, arguing for the possibility that the majority of circ-RNAs are inert splicing by-products [40, 41]. However, many circRNAs are expressed more abundantly than their linear isoforms in each examined cell line [45] and expressed in a cell type-specific or tissue-specific manner [46].

1.2.2 Circular RNAs Modes of Action Circ-RNAs may serve as sponges for miRs [42, 47]. A circ-RNA can act as a sponge and bind specific miR or groups of miRs, sequestering them and suppressing their function [48–50]. The circular cerebellar degeneration-related protein 1 (CDR1) antisense RNA (Circ-RNA CDR1as or ciRs-7) contains up to 74 binding sites for miR-7 and binds Argonaute proteins of RISC, which regulate miR production [42,

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Fig. 1.2 Biogenesis of circular RNA. The linear primary transcript contains exons (blue boxes), introns (black lines), and possibly repetitive elements or sequence motifs (red boxes). Circular exons are generated from back-splicing events between the splice donor site of a downstream exon and the splice acceptor site of an upstream exon mediated by specific sequence elements (red boxes) or interacting with RNA binding proteins (RBPs). The introns are removed through a spliceosome to generate circular RNA

51]. The circular RNA PVT1 oncogene (PVT1) silences miR-17 [52], miR-26b [53], miR-29a [54], miR-143 [55], miR-455 [56]. The homeodomain interacting protein kinase three circ-RNA (circ-HIPK3) and the mitochondrial tRNA translation optimization one circ-RNA (circ-MTO1) also silences miR-17 [57, 58]. PVT1 not only sponge miR-143 directly [55] but inhibits miR-143 indirectly through binding with the enhancer of the zeste two polycomb repressive complex two subunit (EZH2), a histone methyltransferase catalyzing histone H3K27me3 to mediate gene silence [59]. Circ-RNAs may also enhance the transcription of target genes by recruiting RNA polymerase II to the promoter region. For example, PVT1 functions as an oncogene in ovarian cancer via up-regulating SRY-box transcription factor 2 (SOX2) [60]. It also promotes the activation of the signal transducer and activator of transcription (STAT)-3, which leads to the transcriptional activation of downstream targets

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Fig. 1.3 Modes of action of circular RNAs. Circular RNAs acts as sponges of miRs, thereby inducing miR degradation. They recruit RNA polymerase to the promoter of cognate mRNA, thereby increasing transcription. In contrast, they may compete with cognate mRNA for RBPs, thereby inhibiting transcription. Finally, they may assist in protein binding, thereby increasing stability or prevent protein interactions

involved in cell cycle progression [61]. Alternatively, they compete for their cognate mRNA for RNA binding proteins and modulate target mRNAs’ translation rates. For example, the promoters of PVT1 and the MYC oncogene (MYC), located 55 kb apart on chromosome 8q24, compete for engagement with four intragenic enhancers in the PVT1 locus, thereby allowing the PVT1 promoter to regulate pause release of MYC transcription. Finally, they mediate protein binding. PVT1 binds to Krüppel-like zinc finger transcription factor (KLF)-5 and increases its stability via the deubiquitinase BRCA1 associated protein 1, promoting breast cancer cell proliferation and tumor metastasis [62, 63]. The forkhead box O3 circ-RNA (circ-Foxo3) binds cyclin-dependent kinase 2 (CDK2) and cyclin dependent kinase inhibitor 1A (CDKN1A or P21), forming an RNA–protein complex that disrupts the interactions of CDK2 with cyclins (CCN) A and E, required for cell cycle progression [64]. Some circ-RNAs containing internal ribosome entry site elements [65] or prokaryotic ribosome-binding sites [66] might encode proteins, unlike their canonical counterparts. Ribosome footprinting studies in vivo in Drosophila demonstrate that circ-RNAs are associated with translating polysomes. For example, the F-box and WD repeat domain containing 7 (FBXW7) circ-RNA encodes a protein that plays an essential role in tumorigenesis [67, 68] (Fig. 1.3).

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1.2.3 Useful Resources on Circ-RNAs CIRCexplorer2 (https://circexplorer2.readthedocs.io) is a comprehensive and integrative circular RNA analysis toolset.

1.3 lncRNAs 1.3.1 Biogenesis of lncRNAs LncRNAs are longer than 200 nucleotides, which coincide with the cut-off for many RNA extraction protocols [69–71]. LncRNAs show cell type-specific expression that varies with time and responds to diverse physiological stimuli, suggesting that their expression is under considerable transcriptional control [72–74]. Expression of lncRNAs seems to be more cell- and tissue-specific than protein-coding genes. Temporal changes in their expression correlate better with the differentiation and developmental stage than protein-coding genes. LncRNAs are developmentally regulated and operate in conserved gene regulatory networks [75]. Particular changes in lncRNA patterns underlie the differentiation of mesenchymal stem cells into cardiomyocyte-like cells [76]. Also, the interaction of several lncRNAs with differences in expression in time and space is needed to orchestrate development [77]. LncRNAs are transcribed from intergenic (indicated with linc) or intragenic regions of protein-coding genes. Intragenic lncRNAs overlap with the intron or exon of a protein-coding gene. Alternatively, they can be exonic, including sequences with the spliced mRNA of the overlapping protein-coding gene. Intergenic and intronic lncRNAs are transcribed in sense or antisense or both orientations relative to the protein-coding gene. Exonic lncRNAs are transcribed antisense. The tumor protein p53 pathway corepressor 1 (lincRNA-p21) is an intergenic lncRNA induced by p53, repressing the p21 gene in response to p53 [78, 79]. LincRNA-p21 predominantly functions in cis to activate the expression of its neighboring gene, p21. Mechanistically, lincRNAp21, in concert with the heterogeneous nuclear ribonucleoprotein K, coactivates p53dependent transcription of p21 (Fig. 1.4). The Ras association domain family member 1 (RASSF1) antisense lncRNA 1 (ANRASSF1) is an endogenous un-spliced lncRNA that is transcribed from the opposite strand on RASSF1 and binds the polycomb repressive complex 2 (PRC2). ANRASSF1 overexpression increases PRC2 occupancy and histone H3K27 methylase (H3K27me3) repressive marks, specifically at the RASSF1A promoter region [80] (Fig. 1.4). Like miRs, lncRNAs are relatively short-lived RNA molecules except when packed in microvesicles.

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Fig. 1.4 Classification of lncRNAs based on their genomic localization to protein-coding genes. a Intergenic lincRNAs are non-overlapping lncRNAs. LincRNA-p21 is a large intergenic noncoding RNA induced by p53 that mediates global gene expression in response to p53. For example, lincRNA-p21 predominantly functions in cis to activate the expression of its neighboring gene, p21. Mechanistically, lincRNA-p21 acts in concert with hnRNP-K as a coactivator for p53-dependent p21 transcription. P21 then regulates the expression of PRC2 that is important for maintaining the chromatin state. b Intragenic lncRNAs overlap with the intron or exon of a protein-coding gene. For example, ANRASSF1 is an endogenous unspliced lncRNA transcribed from the opposite strand on RASSF1. ANRASSF1 overexpression causes a marked increase in PRC2 occupancy and histone H3K27me3 repressive marks, specifically at the RASSF1A promoter region

1.3.2 Modes of Action of lncRNAs Compared to miRs, which act through mRNA degradation and translational repression, lncRNAs have more diverse modes of action [81] (Fig. 1.5). First, lncRNAs can serve as molecular signals that act in a time- and a site-dependent way to respond to diverse stimuli. The advantage of using RNA as a medium is that potential regulatory functions can be performed quickly without protein translation [82]. For

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Fig. 1.5 Classification of lncRNAs based on modes of action. Type I lncRNAs act as signals. LncRNA expression reflects one or more combinatorial actions of transcription factors (blue oval). Hypoxia-induced HIF-1α induces lincRNA-p21 that facilitates transcription of the GLUT1 gene promoting glucose transport inti pancreatic β cells. Type II lncRNAs act as decoys by titrating away transcription factors, regulatory proteins, or miRs. TGF-β-induced GAS5 acts as a sponge of SMAD3, thereby blocking the transcription of smooth muscle cell differentiation genes such as SMMHC. Type III lncRNAs act as guides recruiting chromatin-modifying enzymes to target genes that are in cis (near the site of lncRNA production) or trans. HOTAIR guides PRC2 that silences HOX transcription factors leading to repression of stem cell differentiation and cancer. Type IV lncRNAs act as scaffolds that bring together multiple proteins to form ribonucleoprotein complexes. The intergenic lincRNA-1614 is a specific partner of SOX2 and maintains pluripotency by repression of developmental genes. However, it is also a partner to PRC2 responsible for H3K27me3 modification, which primarily correlates with gene repression in embryonic stem cells

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example, hypoxia-induced hypoxia-inducible factor (HIF)-1α induces the expression of lincRNA-p21 required for transcription of the glucose transporter (GLUT) [83]. Second, lncRNAs can act as decoys. These lncRNAs are transcribed and then bind and titrate away a protein target but do not exert any additional regulatory function. The RNAs act as a “molecular sink” or sponge for RNA-binding proteins, transcription factors, chromatin modifiers, or other regulatory factors [84–86]. The transforming growth factor (TGF)-β induces the growth arrest-specific five lncRNA (GAS5), suppressing TGF-β/SMAD family member three (SMAD3) signaling in smooth muscle cells (SMC) by binding SMAD3 protein via multiple RNA SMADbinding elements. This binding prevents SMAD3 from binding to SBE DNA in the TGF-β-responsive smooth muscle myosin heavy chain (SMMHC) gene promoter [87]. Mostly this type of lncRNAs acts as sponges of miRs through near-perfect sequence complementarity [88]. Third, a lncRNA can act as a guide for recruiting chromatin-modifying enzymes to target genes. Thereby, lncRNAs can guide gene expression changes either in cis (on neighboring genes) or in trans (distantly located genes) in a manner that is not easily predicted based on lncRNA sequence [89]. They can even mediate the transcription of multiple genes by interacting with chromatin and recruiting the chromatin-modifying machinery [90, 91]. For example, the homeobox (HOX) transcript antisense lncRNA (HOTAIR) interacts with PRC2. This complex has histone methyltransferase activity. It primarily trimethylates histone three on lysine 27 (i.e., H3K27me3), a mark of transcriptionally silent chromatin. In this way, HOTAIR silences the transcription of homeobox (HOX) genes [92]. Fourth, lncRNAs can serve as scaffolds upon which relevant molecular components are assembled to precisely control the specificity and dynamics of intermolecular interactions and signaling events [93, 94]. These RNAs bring specific regulatory components into proximity with each other, resulting in the formation of a unique functional complex. These RNA regulatory complexes are formed by interaction with proteins and extend to RNA–DNA and RNA–RNA interactions [95, 96]. Such lncRNAs can even localize to two specific DNA sites by forming an RNA: DNA triplex, even at remote positions in the human genome [89, 96, 97]. Through extended base-pairing, lncRNAs stabilize or promote the translation of target mRNAs, while through partial base-pairing, they can facilitate mRNA decay or inhibit target mRNA translation [98]. The intergenic lincRNA-1614 coordinates SOX2/PRC2-mediated repression of developmental genes in pluripotency and thus maintains self-renewal. However, it is also a partner to PRC2 responsible for H3K27me3 modification, primarily repressing genes in embryonic stem cells [99]. In addition, PRC2-interacting sequences on maternally expressed 3 lncRNA (MEG3) lncRNA facilitate PRC2 recruitment. Chromatin-interacting sequences of MEG3 then guides MEG3 to G-A rich DNA sequences by DNA-RNA–DNA triplex formation, thereby establishing H3K27me3 marks to modulate the expression of genes important in cell differentiation [100, 101] (Fig. 1.5). As indicated above, lncRNAs can act as decoys of miRs, thereby indirectly inhibiting miR negative gene regulation by competing for binding to the 3 -UTR of

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target genes [102]. Also, dicer cleavage of lncRNAs can generate silencing RNAs, which serve as competitive ‘endogenous miRs.’ For example, HOTAIR functions as a sponge for miR-34a, miR-124, and miR-221–222 [103–105]. Thirdly, some lncRNAs are like protein-coding genes. The H19 imprinted maternally expressed transcript lncRNA (H19), located near the insulin-like growth factor (IGF)-2, gives rise to miR-675-3p and miR-675-5p [106]. Of interest, a single lncRNA may display several of these functions, which may differ according to the gene to be regulated. For example, the metastasis-associated lung adenocarcinoma transcript one lncRNA (MALAT1) regulates hyperglycemiainduced inflammatory processes [107], cell proliferation, and apoptosis [108].

1.4 piRs 1.4.1 Biogenesis of piRs PIWI-interacting RNAs (piRNAs or piRs) are large families of small (21–35 nucleotides in length), single-stranded, non-coding RNAs processed from long single-stranded precursor transcripts, for example, lncRNAs. In contrast, miRs derive from double-stranded RNA precursors [109, 110]. Vagin et al. demonstrated that they are Dicer-independent, PIWI protein-associated small silencing RNAs derived from single-stranded RNA and bearing a chemically modified 3 end [111]. PiR biogenesis requires specialized machinery that converts long single-stranded precursors into small RNAs of ∼25-nucleotides in length. These long precursor transcripts are fragmented by endonucleolytic cleavage—hypothesized to be catalyzed by the mitochondrial protein Zucchini/PLD6—producing tail-to-head, phased precursor piRs (pre-piRs) [112–114]. Each pre-piR begins with a 5 monophosphate, a prerequisite for loading nearly all Argonaute proteins [115–117]. Once bound to a PIWI protein, the 3 ends of pre-piRs are trimmed by the single-stranded-RNA exonuclease, Trimmer/ PARN like, ribonuclease domain containing 1 (PNLDC1) [118, 119]. Finally, Hen1/2 -O-methylates the 3 ends of the mature piRs [120, 121]. Alternatively, PIWI-catalyzed slicing of a target transcript creates an RNA fragment bearing a 5 monophosphate. This fragment acts as a pre-piR precursor (pre-pre-piR) and binds to a PIWI protein, ultimately generating a new secondary piRA [122, 123].

1.4.2 Modes of Action of piRs PiRs form a small RNA-based immune system that silences mobile genetic elements in animal germlines. Somatic piRs form complexes with the piwi-like RNA-mediated gene silencing 1 group of Argonaute proteins (PIWI). They guide these proteins to cleave target RNA, promote heterochromatin assembly, and methylate DNA [124].

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There are four human PIWIs: HIWI (also known as PIWIL1), HILI (also known as PIWIL2), HIWI2 (also known as PIWIL4), and HIWI3 (also known as PIWIL3). HIWI is expressed in human CD34(+) marrow cells. The human HIWI protein is 52% homologous to the Drosophila protein PIWI at the amino acid level. Hypermethylation of PIWIL1, PIWIL2, and PIWIL4 genes occurred in testicular cancer cells, associated with decreased piRNA expression [125]. The transient expression of HIWI in the human leukemia cell line KG1 resulted in a dramatic reduction in cellular proliferation and programmed cell death [126]. Figure 1.6 illustrates how piRs guide PIWI proteins to complementary gene sequences to silence their transcription. The oncogene OIP5 antisense RNA 1 (OIP5-AS1) lncRNA promotes cancer cell proliferation by inducing CCAAT/enhancer-binding protein alpha (c/EBP-α), phosphatidylinositol 3-kinase (PI3K)/ AKT serine/threonine kinase (AKT), and Wnt/βcatenin signaling [127, 128]. PiR-30188 may guide PIWIL3 to OIP5 antisense RNA 1 (OIP5-AS1), silencing it and reducing the sponging of miR-367-3p that silences c/EBP-α, which otherwise would induce proliferation, migration, and invasion, and protect against apoptosis by inducing TNF receptor associated factor 4 (TRAF4).

Fig. 1.6 Modes of action of piRNAs. PiRs guide PIWI proteins to coding RNA or lncRNA, resulting in their transcriptional silencing. a PiR-932 guides PIWIL2 to the GSK3β gene, silencing it. The silencing of GSK3β activates β-catenin, which induces cyclin CCND1, which increases the expression of miR-21 and miR-93. These miRs then activate the toll-like receptor (TLR)-8. Besides, CCND1 may induce the production of piR-016658 and piR-016975, which induce stemness. b PiR30188 guides PIWIL3 to the OIP5-AS1 lncRNA. Its silencing results in the de-repression of miR367-3p, which inhibits the expression of CCAAT enhancer-binding protein (c/EBP-α). Its silencing results in loss of activation of the TNF receptor-associated factor 4 (TRAF4), inhibiting proliferation and migration and inducing apoptosis. Besides, the decrease in c/EBP-α leads to overexpression of PIWIL3, closing a vicious circle

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The inhibition of c/EBP-α leads to over-expression of PIWIL3, forming a positive feedback loop in the growth regulation of glioma cells [128]. PiR-932 induces epithelial-mesenchymal transition (EMT) of breast cancer cells by guiding PIWIL2 to glycogen synthase kinase three beta (GSK3β), stabilizing β-catenin, and inducing the β-catenin/CCND1 pathway [129]. CCN1 induces miR-21 and miR-93, which bind Toll-Like Receptor 8 to trigger vascular endothelial growth factor (VEGF) and BCL2 apoptosis regulator (BCL-2) [130]. Besides, CCND1 induces the PIWI-interacting RNAs, piR-016658 piR-016975, related to stem cell expansion and increased the abundance of PIWIL2 in estrogen related receptor alpha (ERRα)- positive breast cancer cells [131].

1.4.3 Useful Resources on piRs PiRBase (https://www.regulatoryrna.org/database/piRNA/) aims to provide comprehensive piR sequence data, annotation, and targets.

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Chapter 2

Non-coding RNAs Related to Obesity

Abstract Obesity results from hampered stem cell proliferation and epithelialmesenchymal transition, and white and brown and beige adipocyte maturation. Obesity is associated with impaired glucose uptake and insulin signaling leading to adipocyte hypertrophy by lipid accumulation and oxidative stress and inflammation. Impaired beige and brown adipogenesis results in blunted thermogenesis, an important defense against obesity. Obesity results from and is associated with changes in expression of let-7, miR-9, miR-17, miR-21, miR-26a, miR-27a/b, miR29, miR-30a/b/c, miR-31, miR-32, miR-34a, miR-103, miR-124, miR-125, miR130a/b, miR-133, miR-138, miR-142, miR-143-145, miR-144, miR-146a/b, miR150, miR-155, miR-181, miR-193b, miR-196a, miR-199a-214, miR-206, miR-221, miR-223, miR-326, miR-335, miR-361-5p, miR-377, miR-378, miR-448, miR-455, miR-494-3p, miR-519d, miR-574-5p, NEAT1/miR-140/MEG3 paraspeckles, and lncRNAs βLINC, GAS5, HOTAIR, H19, PLNC1 and TNCR, and circular RNA PVT1. Importantly, no single non-coding RNA has a function that is not reinforced or hampered by other non-coding RNAs. Let-7a, miR-7, mir-9, mir-30b, mir-100a, mir-145, miR-200, miR-385, miR-384, miR-142, and miR-488 may be linked to leptin and insulin signaling in the hypothalamus, controlling weight.

2.1 Mechanisms in White Adipogenesis White adipocytes arise from myogenic factor 5 (MYF5)-negative precursor cells in the stromal vascular fraction of adipose tissue. Wnt/β-catenin signaling is crucial in maintaining adipocyte stem cells (ASC) and adipocyte differentiation. Wnt ligands stabilize β-catenin through inhibiting the destruction complex consisting of casein kinase 1α, glycogen synthase kinase 3β (GSK3β), and the tumor suppressor APC regulator of the Wnt signaling pathway. Then β-catenin enters the nucleus and turns on transcription via binding to members of the lymphoid enhancer factor family of transcription factors. Besides, β-catenin induces epithelial to mesenchymal transition (EMT) and retains pluripotency involving the snail family transcriptional repressor 1 Illustrations by Pieterjan Ginckels, Faculty of Architecture, KU Leuven, Ghent, Belgium. © The Author(s), under exclusive license to Springer Nature Switzerland AG 2021 P. Holvoet, Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer, https://doi.org/10.1007/978-3-030-68844-8_2

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(SNAI1 or SNAIL), snail family transcriptional repressor 2 (SLUG or SNAI2), and twist family bHLH transcription factor (TWIST) [1, 2]. However, in the absence of Wnts, cytoplasmic β-catenin is degraded [3]. Next, Wnt/β-catenin cooperates with fibroblast growth factor (FGF) to regulate the proliferation and differentiation of stem cells [4] (Fig. 2.1). FGF1 promotes proliferation and differentiation of preadipocytes. FGF2 induces self-renewal of ASCs and insulin sensitization [5–7]. However, FGF2 may also suppress the differentiation of ASCs by inducing TWIST2 and sprouty RTK signaling antagonist 4 (SPROUTY4 or SPRY4) in a concentration-dependent manner [8–10]. Further, cyclins (CCNs) induce proliferation of precursor cells and adipogenesis [11–15] (Fig. 2.1). Bone morphogenetic protein (BMP)-2 and BMP4 stimulate precursor cells to differentiate to committed white preadipocytes [16]. Peroxisome proliferatoractivated receptor (PPAR)-γ and CCAAT enhancer-binding protein (c/EBP)-α induce maturation of white adipocytes [17, 18]. The activation of the PPAR-γ and the c/EBP-α promoter depends on early B cell factor (EBF)-1, which exerts positive feedback on c/EBP-δ expression [19]. Krüppel-like zinc finger transcription factors (KLFs), especially KLF4, KLF5, and KLF15, regulate adipogenesis by transactivating c/EBP-β and c/EBP–δ [20–24]. EBF1 regulates white adipocyte differentiation and induces inflammation by inhibiting phosphatidylinositol 3-kinase (PI3K)/AKT serine/threonine kinase 1 (AKT)/mitogen-activated protein kinase (MAPK) signaling [25, 26]. Deregulation of PI3K/AKT/MAPK and protein kinase AMP-activated catalytic (AMPK) pathways essential for glucose homeostasis often results in obesity and type 2 diabetes [27]. Tumor necrosis factor (TNF-α), basic fibroblast growth factor (BFG), and transforming growth factor (TGF)-β down-regulate PPAR-γ expression, with a concomitant decrease in adipocyte-specific gene expression [28]. However, the steroid receptor RNA activator (SRA) restores adipocyte differentiation, improving insulin-stimulated glucose uptake, and inhibiting TNF-α-mediated inflammation [29, 30]. Mature adipocytes secrete the fatty acid-binding protein (FABP)-4, or adipocyte protein 2 (aP2), chaperoning lipids and maintaining glucose homeostasis. A population of aP2-expressing progenitors in the stromal vascular fraction of both WAT and BAT reside in the adipose stem cell niche and proliferate and differentiate into adipocytes upon induction. Conversely, ablation of the aP2 lineage significantly reduces the adipogenic potential of stromal vascular fraction cells [31]. However, calorie excess in obesity is associated with decreased FABP4 leading to endoplasmic reticulum (ER) stress and reactive oxygen species (ROS) secretion. However, a sustained increase of FABP4 under conditions of immune-metabolic stress exacerbates type 2 diabetes-associated atherosclerosis and cancer [32–35]. Another marker of mature adipocytes is the solute carrier family 2 (facilitated glucose transporter), member 4 (GLUT4) that is up-regulated by BMPs via PPAR-γ. BMPs thereby act as insulin sensitizers [36, 37]. Calorie excess decreases PPAR-γ coactivator 1α (PGC-1α)/GLUT4 signaling, while weight reduction is associated with increased PGC-1α/GLUT4 signaling [38]. Leptin-induced decrease of PGC-1α leads to the repression of the estrogen-related receptor (ERR)-α. FABP4 usually blocks this leptin action, however it is low in obesity [35, 39, 40]. Repression of ERR-α

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Fig. 2.1 Non-coding RNAs in white adipogenesis. White adipocytes derive from MYF5-negative precursor cells. Their proliferation depends on Wnt/β-catenin, FGF, TWIST and SPRY, and CCNs. Wnt/β-catenin signaling induces EMT involving SNAI1, SNAI2, and TWIST1, increasing the number of stem cells. However, Wnt/β-catenin signaling is low in obesity. Besides, high levels of let-7, miR-21, that needs to be balanced by GAS5, miR-34a, miR-145, and miR-146a, limit the number of white adipocyte precursors. MiR-124, miR-181a, miR-221, and HOTAIR may restore stem cell proliferation. Next, BMP2 and BMP4 stimulate adipocyte precursors to differentiate to committed white preadipocytes. The decrease of miR-181d impairs BMP action, reduces the number of committed preadipocytes, and reduces insulin sensitivity. In contrast, miR-30a retains insulin sensitivity. BMP2, BMP4, FGF1, FGF2, and c/EBPs and PPAR-γ differentiate preadipocytes to committed white adipocytes. PPAR-γ action depends on EBF1 and KLFs. The increase of miR-27b, miR-130a, miR-138, miR-361-5p, miR-519 d, miR-574-5p, and H19-miR-675, and the decrease of miR-103, miR-124, and miR-140/NEAT1/MEG3 paraspeckles inhibit adipocyte maturation. MiR-30a, miR-144, lncRNA PLNC1, and circ-RNA PVT1 and the decrease of miR-29 and miR-448 may partially prevent this impairment. Mature adipocytes release FABP4 (aP2) and GLUT4, and adiponectin (ADIPOQ), which regulate insulin signaling and glucose uptake. However, calorie excess decreases FABP4, GLUT4, and adiponectin, by reducing miR-103 and miR-124 and increasing miR-138. In obesity, increased leptin also reduces GLUT4, enhanced by the lack of FABP4 (aP2) that otherwise blocks this leptin action. The reduction of FABP4 leads to ER stress and ROS secretion. The decrease of GLUT4 reduces glucose uptake and decreases PGC-1α and ERR-α, resulting in mitochondrial ROS release and increased secretion by adipocytes of CCL2

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 that attracts monocytes and induces inflammation further enhanced by ERR-α’s target gene PDK2. Besides, calorie excess causes adipocyte hypertrophy and insulin resistance by increasing miR-155 and decreasing NEAT1/miR-140/MEG3 paraspeckles. MiR-34a may revert lipid accumulation. In healthy WAT, FABP4 and GLUT4 induce de-differentiation to aP2 progenitors, which become MYF5- precursors through the action of c/EBP-α, and CCNs, and CDKs. However, miR-34a inhibits this de-differentiation in obese WAT. The increase of EBF1, required for white adipogenesis, is also associated with impaired PI3K/AKT/MAPK signaling, leading to the release of inflammatory TNFα, which inhibits the maturation of β cells. However, SRA mediated activation of FOXO1 and the decrease of miR-361-5p and miR-574-5p inhibit inflammation may overcome this. Inflammatory cytokine-induced miR-34a accelerates cellular senescence. Increased non-coding RNAs are in red, decreased in green

results in higher levels of mitochondrial membrane potential, and ROS production, and secretion of the C-C motif chemokine ligand 2 (CCL2 or MCP-1) that exacerbates macrophage accumulation and inflammation [41–45]. When pyruvate dehydrogenase kinase 2 (PDK2), an ERR-α target, is suppressed, the tricarboxylic acid cycle is activated. This activation increases the mitochondrial membrane potential and the ROS release [41]. Further, the decrease of FABP4 may reduce hydrogen peroxide scavenging, resulting in increased ROS production [46]. Calorie excess is also associated with unhealthy expansion or hypertrophy of WAT by lipid accumulation that promotes the obesity-associated glucose intolerance and insulin resistance and inflammation [47] (Fig. 2.1).

2.1.1 Role of Non-coding RNAs in White Adipogenesis MiR-124 and miR-221 induce the differentiation of ASCs [48, 49]. High levels of expression let-7, miR-21, miR-34a, miR-145-5p and miR-146a-5p block ASC proliferation [50–53]. However, overexpression of growth arrest-specific 5 (GAS5) also impairs mesenchymal cells’ differentiation to adipocytes by silencing miR-21 [54, 55]. Thus, miR-21 needs to be tightly balanced. In contrast, miR-181a and homeobox transcript antisense RNA (HOTAIR) increase circadian rhythm-modulated proliferation of ASCs [56, 57]. A decrease in miR-181d is associated with the repression of BMP4-induced differentiation of precursors to committed white adipocytes [58]. MiR-30a is a crucial regulator of adipogenesis by targeting the principal regulator of osteogenesis, RUNX2 [59]. MiR-30a-5p and lncRNA PLNC1, transcribed from the PPAR-γ2 gene, contribute to adipocyte differentiation, reflected by the enrichment of PPAR-γ, c/EBP-α, and FABP4. Sirtuin (SIRT)-1 is another target of miR-30a-5p, and a supplement of SIRT1 blocks adipogenesis [60, 61]. In addition to miR-30a, miR-144-3p increases c/EBP-α activity by releasing corepressors KLF3 and C-terminal binding protein two from its promoter region [62]. MiR30a targets the transcription factor STAT1 to increase insulin sensitivity [63]. The circ-RNA derived from PVT1 oncogene (PVT1) up-regulates PPAR-γ, c/EBP-α, and adiponectin, promoting adipocyte differentiation [64]. Down-regulation of miR-29 and miR-448 increases the expression of c/EBP-α, PPAR-γ, and FABP4 and protects against loss of adipogenesis [65–67].

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The increase of miR-27b in obesity blunts the induction of PPAR-γ and c/EBP-α [68–70]. Overexpression of miR-130a in obesity only suppresses PPAR-γ expression, while that of miR-138 suppresses PPAR-γ and c/EBP and FABP4 expression [71– 73]. MiR-361-5p and miR-574-5p impair white adipocyte maturation by repressing EBF1 but thereby may inhibit inflammation [74, 75]. MiR-519d suppresses the translation of the PPAR-α protein [76]. Overexpression of the H19 imprinted maternally expressed transcript lncRNA (H19) and miR-675, encoded by H19, inhibits adipogenic differentiation. H19 blocks histone deacetylases, thereby mimicking the effects of hypoxia, leading to impairment of insulin-induced glucose uptake [77, 78]. Tumor necrosis factor (TNF)-α impairs adipocyte differentiation by decreasing miR-103, PPAR-γ and FABP4, GLUT4, and adiponectin [79, 80]. Downregulation of mir-124 and the miR-140/nuclear paraspeckle assembly transcript (NEAT1)/maternally expressed 3 (MEG3) also inhibits adipocyte maturation [81–84]. MiR-155 is associated with adipocyte hypertrophy and lipid deposition, WAT inflammation, and obesity-associated with calorie excess [85]. Also, repression of MEG3 in NEAT1/miR-140/MEG3 paraspeckles results in fat cell hypertrophy [86]. Unexpectedly, the deficiency of miR-34a in mice was associated with obesity-associated with increased lipid deposition in white adipocytes [87, 88] (Fig. 2.1). The adipogenic differentiation induced non-coding RNA (ADINR) is transcribed from a ∼450 bp upstream of the c/EBP-α gene. ADINR recruits histone methyltransferase complexes to increase histone modification in the c/EBP-α locus [89]. The knockdown of the MIR31 host gene (MIR31HG) inhibits adipocyte differentiation by reducing active histone markers in the promoter of FABP4 [90]. LncRNA RP1120G13.3 attenuates adipogenesis by blunting the expression of PPAR-γ, c/EBP-α, and adiponectin [91]. However, it is unknown how their expressions change during the development of obesity.

2.2 Inflammation and Insulin Resistance in Obese White Adipose Tissue White fat cells secrete important hormone-like molecules such as leptin and adiponectin, influencing food intake and insulin secretion to increase glucose and insulin sensitivity [92]. Obesity and higher WAT mass are associated with increased secretion of leptin but decreased expression of leptin receptors (ObRs), leading to leptin resistance. ObRb is the only receptor that includes binding domains for MAPK8 (or JNK) and signal-transducing and activator of transcription (STAT) [93]. Besides, it phosphorylates PI3K and MAPK1, and MAPK2 [94–96]. Thus, impairment of ObRb ultimately leads to insulin resistance, implying an essential association between food intake and maintenance of energy balance by leptin and glucose metabolism. Leptin directly inhibits insulin secretion from the pancreas, whereas

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prolonged exposure to high insulin stimulates leptin expression [97]. Further, leptin significantly increases the suppressor of cytokine signaling 3 (SOCS3), inhibiting autophosphorylation of insulin receptors (IRs) and responsiveness to leptin [98–100]. Leptin also increases local expression of the inflammatory TNF-α, which induces insulin resistance by downregulating the tyrosine kinase activity of IR and decreasing the expression of GLUT4 [101, 102]. Angiotensin I converting enzyme 2 (ACE2) deficiency in obesity leads to an increase of inflammatory angiotensinogen (ANG II or AGT) and up-regulation of Ras proteins, binary switches, cycling between ON and OFF states during signal transduction, associated with increased ROS, glucose intolerance, and insulin resistance (Fig. 2.2). Obesity is associated with increased infiltration in WAT of monocytes, which differentiate into macrophages. This infiltration is a normal response to the growing mass associated with WAT hyperplasia. Insulin resistance shifts the balance from proinflammatory to anti-inflammatory cytokines and M2 to M1 macrophage polarization [103–105]. However, one must be aware that these two macrophage phenotypes are extremes of a continuum of functional states [106, 107]. Classical M1 activation of macrophages occurs following injury or infection dependent on interferon (IFN)-γ or TNF-α. M1 macrophages produce pro-inflammatory cytokines like interleukin (IL)1β, and IL12, and TNF-α. They also produce high ROS and nitrogen species [108]. IL4 and IL13, toll-like receptor (TLR), induce M2 macrophage polarization [109], together with IL1 receptor ligands and IL10 [110]. M2 macrophages produce meager amounts of pro-inflammatory cytokines but abundantly secrete anti-inflammatory cytokines like IL10, CCL18, and CCL22. Besides, M2 macrophages express the mannose receptor CD206 (or MRC1), the scavenging receptor CD163, and dendritic cell (DC)-specific intercellular adhesion molecule-3-grabbing non-integrin [111]. Also, the metabolic signature of M2 macrophages is different from that in M1 macrophages. Hypoxia, inducing hypoxia-inducible factor (HIF)-1α, AMPK, and nuclear factor kappa B (NFκB) signaling in M1 macrophages favor glycolysis and inhibit oxidative phosphorylation (OXPHOS). On the contrary, M2 cells are more dependent on OXPHOS and fatty acid oxidation [112, 113] (Fig. 2.2). Infiltrated monocytes differentiate into macrophages or dendritic cells (DCs) in obese WAT [114, 115]. Adipose tissue-derived high-mobility group B1 (HMGB1) protein activates TLR9 in the adipose-recruited DCs by transporting extracellular DNA through receptor for advanced glycation end products (AGEs) and induces production of IFN-α and IFN-β. They, in turn, help in M1 macrophage polarization of adipose-resident macrophages [116]. Like M1 macrophages, DCs undergo metabolic reprogramming from a predominantly OXPHOS to glycolysis required to mount immune response [116, 117] (Fig. 2.2). This immune response also involves T cells [118], natural killer (NK) cells, possibly interacting with macrophages [119], type 2 innate lymphoid cells [120], and mast cells [121]. During obesity, WAT is infiltrated by T cells, which along with the adipocytes themselves, secrete various cytokines and chemokines [122– 124]. Th1 polarization is associated with increased IFN-α and IL2 and decreased Th2-specific cytokines IL4, IL5, IL10, and IL13 [125–127]. This change in cytokine profile leads to M1 macrophage polarization and inflammation. Reduced Th2-like

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Fig. 2.2 Non-coding RNAs in inflammation and insulin signaling in obese white adipose tissues. In obesity, the increase of lnc-leptin leads to a rise in leptin. In healthy white adipocytes, leptin, by interacting with ObR, induces JAK/STAT signaling, resulting in phosphorylation of PI3K and MAPK, and insulin receptor substrates IRS1 and IRS2 required for regulating food intake and energy expenditure and retaining insulin sensitivity. In obesity, the leptin/ObR interaction and downstream signaling is impaired, leading to leptin resistance and ultimately, insulin resistance. The increase of leptin also induces SOCS3 that reduces leptin signaling and induces inflammatory TNFα, thereby impairing GLUT4 expression and glucose uptake, forcing cells to use other energy sources like fatty acids. Increased leptin and ANG II are also associated with increased Ras and ROS, which increase insulin resistance. Insulin resistance is associated with increased infiltration of monocytes, macrophage accumulation, and macrophage M1 polarization, particularly induced by AGEs in patients with uncontrolled type 2 diabetes. Macrophage polarization and inflammation are due to the increase of miR-17, miR-27a, miR-34a, miR-103, miR-130b, miR-143-145, miR-146a/b, miR-155, miR-221, miR-335 and miR-377, and the decrease of miR-181b. The increase of miR-30a and miR223 may prevent this. Monocytes can also differentiate to DCs, dependent on miR-142. Activated M1 macrophages and DCs induce a shift in T cell immune response. The numbers of anti-inflammatory Th2, Treg, and ILC2 cells decrease while the numbers of inflammatory Th1 and Th17 cells increase. The latter is dependent on miR-326. The shift to inflammatory macrophages and T cells decreases

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 anti-inflammatory IL4, IL5, IL9, IL10, IL13, CCL18, and CCL22, and increases inflammatory IL-1β, IL2, IL17, and TNF-α and IFN-γ. The increase in inflammatory cells increases ROS release, exacerbating inflammation. TNF-α and AGEs impair SIRT1/FOXO1/c/EBP-α signaling in obese WAT and reduce adiponectin signaling. Adiponectin resistance may be due to increased miR-146b and miR-221 and decreased miR-21 and miR-193b. The reduction of adiponectin is associated with a decline of miR-146b and increased mitochondrial ROS and inflammation without affecting insulin sensitivity. The increase of miR-876-3p links insulin resistance to inflammation when adiponectin is low. Let-7 impairs mTORC1 in Tregs, leading to lipid deposition. Increased non-coding RNAs are in red, decreased in green

immune responses are also due to decreased innate lymphoid type 2 cells (ILC2), which upon activation by tissue-derived IL33 and IL25, secrete mostly IL4, IL5, IL9, and IL13 [128]. The lower number of T reg cells in obesity induces the infiltration of effector T cells and hampers the IL33-mediated shift from M1 to M2 macrophages in WAT and lipids’ metabolism [104, 129–139]. Besides, Th17 polarization increases IL17, impairing adipocyte differentiation, and causing glucose intolerance and insulin resistance [140, 141]. Activated DCs promote Th1/Th17 response by secreting IFN-γ, IL2, and IL17 [142–146] (Fig. 2.2). Natural Killer (NK) cells are a unique subset of T cells that recognize lipid antigens in the context of CD1d, which is mainly expressed by antigen-presenting cells, such as macrophages, DCs, and B cells [147–149]. Some groups reported a protective role of NK cells because obesity developed when invariant NK (iNK) cells were deficient. They demonstrated that iNK cells in adipose tissue produce anti-inflammatory cytokines, such as IL4 and IL10, in contrast to those in the spleen and liver [150– 152]. These Th2 cytokines induce M2 macrophages and suppress obesity-associated inflammation [153]. NK cells secrete the anti-inflammatory cytokine IL4, which substantially contributes to the improvement of glucose tolerance [154]. However, other groups have reported that obesity did not develop in the absence of NK cells. iNT cells produce pro-inflammatory cytokines, such as IFN-γ, associated with glucose intolerance in response to lipid excess in the body. Type II NK cells also exacerbate diet-induced obesity in the absence of iNKT cells [155, 156]. Finally, another study reported a neutral role of NK cells with no exact active role for skewing the environment toward either a Th1 or Th2 phenotype during the development of obesity [157] (Fig. 2.2). More mast cells occur in obese WAT, and lower mast cells protect against dietinduced obesity and diabetes. The deficiency of mast cells reduces body weight and inflammation, adipose angiogenesis, and apoptosis, thereby preventing diet-induced obesity and glucose intolerance [158]. In contrast, another study showed that mast cell number was not different between obese and lean humans, but that the degree of mast cell activation was only higher in patients with type 2 diabetes [159]. Also, mast cells may protect against obesity by stimulating WAT’s browning, discussed in the next section [160]. In contrast to leptin, adiponectin is inversely proportional to body fat content. Adiponectin levels already low in obese persons decreases further in subjects with diabetes and coronary artery disease. TNF-α and AGEs repress SIRT1, forkhead box (FOXO)-1, PGC-1α, adiponectin, and adiponectin receptor (ADIPOR1/R2).

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The resulting adiponectin resistance leads to obesity-associated hyperglycemia and insulin resistance and inflammation [161–167]. A decrease of adiponectin may also lead to mitochondrial dysfunction associated with decreased mitochondrial antioxidant enzyme cytochrome oxidase 1 (MTCOI or COX1), PGC-1α, and OXPHOS, impairing fatty acid oxidation and inducing ROS generation and inflammation even when insulin sensitivity is normal [168] (Fig. 2.2).

2.2.1 Role of Non-coding RNAs in Inflammation and Insulin Resistance in Obese White Adipose Tissue Lnc-leptin, which is transcribed from an enhancer region upstream of leptin, increases leptin expression [169]. Increased expression of miR-17 [170], miR-103 [171], miR143-145 cluster [172], miR-146a [173–175], miR-146b [176], miR-221 [177] and miR-377 [178] are associated with obesity-associated insulin resistance and inflammation. The ADP-ribosylation factor 3 circular RNA (circARF3) may act as an endogenous miR-103 sponge, thereby restraining the NFκB-signaling pathway and suppressing the NLR family pyrin domain containing 3 (NLRP3) inflammasome activation. However, as mentioned above, this results in impaired adipocyte maturation [171]. MiR-130b, up-regulated in macrophages of high-fat diet mice, and miR-27a especially increased in obese diabetic patients, induce M1 macrophage polarization and adipose tissue inflammation by targeting PPAR-γ that is associated with glucose intolerance [179, 180]. Adipocyte-derived exosomes enriched in miR-34a inhibit M2 macrophage polarization and induce inflammation [88]. MiR-155 induces adipocyte hypertrophy and WAT inflammation, and insulin resistance. However, it may inhibit the secondary wave inflammation induced by the adipokine resistin in obesity [85, 181, 182]. The decrease in miR-181b also induces macrophage activation in adipose tissue via inhibiting PPAR-γ associated with IR [183–186]. The increase of miR-335 by leptin, resistin, and TNF-α in mature adipocytes is associated with adipose tissue inflammation, closing a vicious circle [187]. MiR-30a targets the transcription factor STAT1 to limit the pro-inflammatory cytokine interferon-γ (IFN-γ) actions that would otherwise restrict WAT expansion and decrease insulin sensitivity [63]. The increase in miR-223 in macrophages in obese WAT reduced TLR4 response and protected against M1 macrophage polarization [188, 189] (Fig. 2.2). Dendritic cells undergo metabolic reprogramming from OXPHOS to glycolysis to mount an immunogenic response. MiR-142 increased in obesity, regulates the immunogenic responses of DCs [190]. In the absence of miR-142, DCs fail to switch and show reduced production of pro-inflammatory cytokines and the ability to activate T cells [191]. MiR-326 participates in the polarization towards Th17, promoting the inflammatory state in the obesity-induced adipose tissue [192] (Fig. 2.2). The decrease of miR-21 is associated with decreased adiponectin mRNA and protein expression [193]. The decrease of miR-193b is associated with a decrease

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of both adiponectin and adiponectin regulators [193, 194]. An increase of miR-146b may block SIRT1/FOXO signaling [176]. MiR-221, up-regulated by leptin, directly down-regulates ADIPOR1 and impairs adiponectin action [195]. The decrease of miR-146b-5p in monocytes is associated with loss of the anti-inflammatory but not insulin signaling action of adiponectin [168]. The increase of miR-876-3p causes inflammation by inducing insulin resistance when adiponectin is low [196]. Let-7 represses the mammalian (or mechanistic) target of rapamycin complex 1 (mTORC1). This repression causes insulin resistance with increased NLR family pyrin domain containing 3 (NLRP3) inflammasome activation [197] (Fig. 2.2).

2.3 Mechanisms in Brown Adipogenesis and Thermogenesis In contrast to WAT, BAT functions to dissipate energy in response to cold exposure or overfeeding. BAT oxidizes fatty acids for thermogenesis, and the induction of BAT is part of combating obesity and associated metabolic diseases. Brown adipocytes derive from MYF5-positive MSCs. BMP4 and BMP7 induce them to differentiate to committed brown preadipocytes [198–200]. BMP4 and BMP7 activate a full brown adipogenesis program, including induction of early regulators of the PR/SET domain (PRDM)-4 [201] and PRDM16 [202], and PGC-1α [203]. SRYbox transcription factor (SOX) genes, which in MSCs increase c/EBP-β expression and favor adipogenesis, explain part of the BMP 7 response [204]. Further differentiation depends on adipogenic transcription factors c/EBPs and PPAR-γ [205]. PPAR-γ is the master transcription regulator of the general differentiation program of both brown and white adipocytes and therefore needs a fat lineage-specific regulation. EBF2 regulates PPAR-γ binding activity, favoring brown adipogenesis. Adipose tissue from EBF2-deficient mice displayed a loss of brown-specific characteristics and thermogenic capacity [206]. Besides, EBF2 regulates chromatin remodeling by interacting with the SWI/SNF related, matrix associated, actin-dependent regulator of chromatin, subfamily a, member 4 (SMARCA4 or BRG1), and the barrier to autointegration factor 1 (BANF or BAF [206, 207]. The EP300 interacting inhibitor of differentiation (EID)-1 codes for the adenovirus E1A-associated cellular p300 transcriptional co-activator protein that remodels chromatin and differentiates brown adipocytes. It is essential in the processes of cell proliferation and differentiation. EID1 mediates 3 -5 -cyclic adenosine monophosphate (cyclic AMP or cAMP) gene regulation by binding phosphorylated cAMP-responsive element-binding (CREB) protein (Fig. 2.3). BAT oxidizes fatty acids produced by triglyceride hydrolysis to generate heat and protect against hypothermia and obesity through non-shivering thermogenesis. Mechanistically, EBF1 and EBF2 promote thermogenesis by increasing the expression and activity of ERR-α and PGC1-α [208]. ERR-γ contributes to mitochondrial biogenesis, mitochondrial maintenance, vascularity, energy expenditure, and

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Fig. 2.3 Non-coding RNAs in brown adipogenesis and thermogenesis. The decrease in miR193b-365 in obesity inhibits lineage determination to MYF5+ precursor cells. Precursors differentiate to committed brown preadipocytes through the action of BMP4, BMP7, ERR, PRDM16, PGC-1α, and SOX. Further differentiation to mature brown adipocytes involves BMP4, BMP7, SOX2, PRDM4 and PRDM16, PGC-1α, c/EBP-β, PPAR-γ, EBF2, EID1, and CREB, leading to the release of UCP1. In response to cold exposure, induction of β3-adrenergic signaling activates a thermogenesis program. This program involves NE/β-3 adrenergic receptor signaling and activation of PGC-1α, PPAR-γ, PRDM16, EBF1, EBF2, ERR-α, and ERR-γ, leading to the release of UCP1. UCP1 requires fatty acid oxidation to increase mitochondrial respiration. High levels of miR-27, miR-34a, miR-150, and miR-199a-214, and low miR-26a and miR30b/30c block full differentiation to brown adipocytes, including expression of UCP1. MiR-378, increased by leptin and TNF-α to block inflammation-associated obesity, miR-455, induced by BMP7, and the ROS-induced decrease of miR-133 restores full adipocyte differentiation. The increase of mir-32, miR-378, miR-455, and H19 responding to cold stimulates thermogenesis, while miR-199-214 block thermogenesis. Increased non-coding RNAs are in red, decreased in green

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mitochondrial uncoupling [209]. Mice deficient in ERR-γ in adipose tissue display whitening of BAT blunted thermogenic capacity, and failure to survive an acute cold challenge [210, 211]. Mechanistically, EBF1 and EBF2 promote thermogenesis by increasing the expression and activity of ERR-α and PGC1-α [208]. PGC-1α is the master regulator of mitochondrial biogenesis through its interaction with PPAR-γ [203, 212, 213]. Mice with a fat-specific knock-out of PGC-1α have increased cold sensitivity and decreased RNA expression of uncoupling protein (UCP)-1, mitochondrial genes, and substrate utilization genes [214]. PGC-1α is dependent on estrogenrelated receptors (ERRs). Thermogenesis is impaired in mice lacking adipose ERRs [211]. PRDM16 is another transcription factor required for thermogenesis. PPAR-γ stabilizes PRDM16 and diminishes responsiveness to IFN-α and IFN-β in adipose cells to promote thermogenic and mitochondrial function [215, 216]. Interestingly, brown adipocytes derived from PRDM16-knockout BAT had decreased expression of ERR-γ and BAT-selective ERR-γ target genes, including UCP1 and PPAR-α. Therefore, some PRDM16 effects are due to ERR-γ responsible for the synergy between PGC-1α and PRDM16 to maintain BAT identity (Fig. 2.3). Fatty acid oxidation is thus critical for this process as it increases mitochondrial respiration via the uncoupling of the mitochondrial electrochemical gradient via UCP1 [217, 218]. Fatty acids are required for UCP1-induced uncoupling. BAT thermogenesis and glucose uptake can, however, be uncoupled [219]. Consequently, mice with an adipose-specific deficit in fatty acid oxidation are severely cold intolerant, demonstrating an autonomous requirement for adipose fatty acid oxidation in cold-induced thermogenesis [220]. Cold exposure also increases UCP1-dependent thermogenesis. It involves OXPHOS, which ensures a higher supply of adenosine triphosphate (ATP) by increasing UCP1. [221] (Fig. 2.3).

2.3.1 Role of Non-coding RNAs in Brown Adipogenesis and Thermogenesis The decrease of miR-193b-365 impairs the differentiation of MSCs to brown adipocyte progenitor cells [222, 223]. MiR-27, up-regulated in obesity, represses PRDM16, PPAR-α, CREB, and in part, PGC-1α [224–226]. The increase of miR34a inhibits brown (and beige) fat formation in obesity by suppressing FGF21 and SIRT1 signaling leading to down-regulation of PRDM16, c/EBP-α, and c/EBP-β, PGC-1α, and UCP1 [87, 227]. MiR-150 increased in obesity directly represses PRDM16 and PGC-1α [228, 229]. The miR-199a-214 cluster suppresses PRDM16 and PGC-1α [230, 231]. MiR26a typically increases UCP1, down-regulated in obesity [232]. Decrease of miR30b and miR-30c leads to reduced UCP1 expression, without significant effects on the expression of PRDM16, PGC-1α, PPAR-γ, c/EBP-α, c/EBP-β, FABP4, and adiponectin [233, 234]. The ROS/NFκB-induced brown adipogenesis requires the down-regulation of miR-133, which results in increased expression of PRDM16

2.3 Mechanisms in Brown Adipogenesis and Thermogenesis

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[235]. MiR-378 increased by TNF-α and leptin in obesity promotes thermogenesis in BAT and controls classical brown fat expansion to counteract inflammationinduced obesity [236–238]. MiR-455 induced by cold and BMP7 enhances brown adipocyte differentiation and thermogenesis [239]. MiR-32 and H19 also increase cold-induced brown adipogenesis, oxidative metabolism, mitochondrial respiration, and thermogenesis [240–242] (Fig. 2.3).

2.4 Mechanisms in Browning of White Adipose Tissues In adult humans, BAT is mainly composed of brown-like or beige adipocytes. However, some data indicate the persistence of classical BAT at some anatomical sites [243]. The total mass and activity of BAT are tightly linked to systemic energy and nutrient homeostasis. Brown adipocytes arise from progenitors expressing transmembrane protein 26 (TMEM26) and CD137 [244]. A percentage of these beige cells derive from smooth muscle cell-like cells that once expressed myosin heavy chain 11. Other brown-like cells originate from white adipocytes following exposure to PPAR-γ ligands [245–247]. This differentiation depends on the SIRT1 dependent deacetylation of PPAR-γ [248]. As in BAT, the emergence of cold-induced brown adipocytes in WAT depends on the β3-adrenergic receptor signaling [249]. Caloric restriction may also lead to white adipocytes’ browning by inducing eosinophil infiltration, Th2 cytokine signaling, and M2 macrophage polarization. However, Th2 cytokine signaling and M2 macrophage polarization are low in obesity [250]. Repression of IFN-signaling and activation of hedgehog signaling promote a white-to-brown metabolic conversion in human adipocytes [251]. Prolonged glucocorticoid suppresses the function of human BAT [252]. Despite originating from distinct progenitors, brown and beige adipocytes acquire remarkably similar molecular and metabolic characteristics during further differentiation through the action of a network of transcription factors and cofactors. It involves PRDM16, c/EBP-β, PGC-1α, and PPAR-γ signaling as in BAT, but also blocking of TGF-β/SMAD family member (SMAD)-3 signaling [253]. Transfection of FABP4-EID1 matures white adipocytes to beige adipocytes with a higher expression of PGC1-α and UCP1 [254]. Activation of cAMP and AMPK signaling pathways results in the “browning” phenotype, with smaller increases in body weight under a high-fat diet, lower fat deposits, increased β-oxidation of fatty acids, and oxygen consumption [255] (Fig. 2.4). Brown and beige adipocytes are structurally different. Mature beige adipocytes are paucilocular; they contain only a few lipid droplets. In contrast, brown adipocytes are multilocular; they include multiple lipid droplets [256]. Besides, beige and brown adipocytes differ in gene expression patterns. Corneodesmosin, Rh family B glycoprotein, and glutathione peroxidase 8 are highly expressed in beige adipocytes. Tripartite motif-containing 17 is even beige cell-specific. MAGE family member A1, NLR family, pyrin domain-containing 9C, solute carrier family 22 member 29, and kininogen 2 are brown cell-specific (Fig. 2.4).

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Fig. 2.4 Non-coding RNAs in browning of white adipocyte differentiation and thermogenesis. Brown-like or beige adipocytes derive from TMEM26+ and CD137+ precursor cells, induced by miR-133b, miR-196a, and miR-206, which block TGF-β and induce c/EBP-β expression. Other brown-like cells originate from white adipocytes following exposure to PPAR-γ ligands and SIRT1. Cold exposure, caloric restriction, Th2, and M2 macrophage infiltration, and repression of IFNγ signaling stimulates those white adipocytes to undergo browning. However, Th2 cells and M2 macrophages are reduced in obesity, impairing brown adipogenesis. Maturation of beige adipocytes involves BMP4, BMP7, PRDM16, c/EBP-β, PGC-1α, PPAR-γ. Besides, TGF-β/SMAD3 signaling needs to be blocked since SMAD3 blocks PGC-1α. It also involves cAMP/AMK signaling, all leading to the release of UCP1 and activation of mitochondrial genes. MiR-9 and miR-31, increased by the loss of silencing TINCR, and miR-155 impairs brown/beige adipocytes’ differentiation. The reduction of miR-125 and miR-494-3p may restore this differentiation. Cold exposure induces thermogenesis in the same way as in brown adipocytes. Increased non-coding RNAs are in red, decreased in green

2.4.1 Role of Non-coding RNAs in Browning of White Adipose Tissue MiR-133b, miR-196a, and miR-206 induce TMEM26+ and CD137+ precursors to differentiate to beige adipocytes by indirectly decreasing TGF-β1 and inducing c/EBP-β signaling by inhibiting homeobox (HOX)-C8 and HOXC9, which are reduced by fasting [257–259]. The increase of miR-9 impairs β3-adrenergic stimulated browning of WAT, thereby decreasing UCP1 [260]. The decrease of the lncRNA TINCR ubiquitin domain-containing (TINCR) may increase miR-31 that blocks browning of WAT [261, 262]. The rise of miR-155 blocks browning of WAT by silencing c/EBP-β [263]. The decrease of miR-125b-5p in obesity may lead to β3adrenoceptor-mediated induction of UCP1 [180, 264]. Interestingly, it did not alter

2.4 Mechanisms in Browning of White Adipose Tissues

35

the number/frequency of macrophage and DCs in the total stromal vascular fraction or intraperitoneal fluid [239]. Mild cold exposure of mice induced PGC1-α along with UCP1 in inguinal WAT by downregulating miR-494-3p [265, 266] (Fig. 2.4).

2.5 Leptin and Insulin in the Hypothalamus The hypothalamus monitors the modifications in metabolic parameters (blood glucose and lipids) and hormones (insulin or leptin). It elicits adaptive responses like food intake regulation or autonomic nervous system modulation. Within the hypothalamus, pro-opiomelanocortin (POMC) neurons are the first to respond to the circulating signals of hunger and satiety such as leptin, insulin, ghrelin, or glucose [267]. Insulin and leptin directly act on POMC neurons [268, 269]. The steroid receptor coactivator-1 interacts with phosphorylated STAT3, an activator of the leptin receptor, to potentiate POMC transcription [270, 271]. Leptindependent STAT3 phosphorylation is low within POMC neurons of high fat diet-fed mice. The expression of leptin receptor and SOCS3 was elevated, associated with increased susceptibility to obesity [272]. Of interest, the anti-inflammatory IL10 may substitute for leptin to activating STAT3 in the case of leptin deficiency [273]. Besides, leptin acts through the PI3K/AKT/MAPK pathways within POMC neurons [274]. PI3K coordinates the actions of leptin and insulin on POMC neurons [275]. Activated dynamin-related protein (pDRP1) suppresses leptin and glucose sensing of POMC neurons. The deletion of DRP1 increased mitochondrial size, ROS production, and neuronal activation, involving PPAR [276, 277]. POMC-specific ablation of mitofusin 2 (Mfn2) in mice resulted in a loss of mitochondria-endoplasmic reticulum (ER) contacts, defective POMC processing, ER stress-induced leptin resistance, reduced energy expenditure, and obesity [278]. Loss of transient receptor potential cation 5 in POMC neurons decreases energy expenditure and increases food intake resulting in elevated body weight [279]. ROS and leptin require mTORC1 in POMC neurons to increase POMC neurons’ oxidant levels and consequently decrease food intake [280]. Chronic stimulation of the leptin receptor and saturated fatty acid-induced inflammation causes leptin resistance in the hypothalamus [281]. Insulin and leptin act together on POMC neurons to promote WAT browning and weight loss [282]. The neuronal inositol-requiring enzyme 1 in POMC neurons is necessary for protection against ER stress, insulin resistance, and thermogenesis in brown adipose tissue [283]. The response of POMC neurons to insulin depends on the number of insulin receptors [284]. Mitofusin 1-mediated mitochondrial activity in POMC neurons is required for glucose-sensing and insulin release control [285]. Besides, insulin receptor (IR) expression in POMC neurons is linked to insulin action in adipose tissue [286]. Attenuation of (HIF)-2α in the high fat diet-fed mice is associated with impaired activation of the hypothalamic IR/insulin receptor substrate 2 (IRS2)/AKT/FOXO1 pathway in response to insulin [287].

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2.5.1 Non-coding RNAs Related to Leptin and Insulin in the Hypothalamus The Dicer loss in POMC neurons causes metabolic defects, an age-dependent decline in the number of Pomc mRNA-expressing cells. Mainly, miR-103 and miR-107 may be involved in the maturation of POMC progenitors [288]. MiR-7a, highly expressed in hypothalamic neurons, may regulate genes involved in body weight control [289]. Let-7a, mir-9*, mir-30b, mir-100a, mir-145, miR-200, and miR-208 are increased in the hypothalamus of high fat diet-fed rats. Their targets regulate insulin, leptin, adiponectin signaling, fatty acid and lipid metabolism, and inflammation [290]. MiR-200a, miR-200b, and miR-429 were highly expressed in the hypothalamus of obese ob/ob mice, associated with decreased IRS2 and leptin receptor expression, but were decreased by leptin [291]. Leptin inhibits the expression of miR-383, miR-384-3p, and miR-488 that bind to the 3’ untranslated regions of POMC mRNA [292]. Mir-383, mir-384-3p, and mir-488 are increased in diabetic mice with a non-functional leptin receptor [293].

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Chapter 3

Non-coding RNAS Related to Type 2 Diabetes

Abstract Type 2 diabetes more often develops in obese persons. Impaired β cell precursor proliferation, β cell maturation, glucose uptake, and insulin secretion in response to high glucose result in mitochondrial and endoplasmic reticulum stress associated with ROS release, inflammation, and β cell death. The multiple-hit pathogenesis models of obesity and type 2 diabetes share an imbalance in the expression of let-7, miR-9, miR-17, miR-21, miR-26a, miR-27, miR-29, miR-30, miR-34a, miR124, miR-130, miR-138, miR-145, miR-146a, miR-150, miR-181, miR-221–222, miR-223, miR-375, miR-378 and miR-455, and lncRNAs βLINC, GAS5, HOTAIR, H19, MEG3, NEAT1 and TINCR, and circ-RNA PVT1. Typically for the pancreas, the up-regulation of miR-7 due to loss of silencing circular RNA ciRs-7 protects against diabetes by inducing differentiation of stem cells to β cells but exacerbates the diabetic phenotype by decreasing β cell mass and impairing insulin signaling. High glucose-induced miR-375 is essential for retaining β cell mass but inhibited PI3K and thereby insulin signaling. The PDX1 associated lncRNA, up-regulator of transcription (PLUTO), is a tissue-specific inhibitor of β cell maturation and insulin production.

3.1 Mechanisms in β Cell Maturation Insulin regulates the body’s energy. Well-functioning pancreatic β cells secrete insulin in response to increases in glucose after a meal [1]. Insulin instructs the body’s cells to translocate glucose transporters to the cell membrane to absorb the sugar for the cell’s energy needs and convert the excess into energy-storage molecules, such as glycogen in the liver. Insulin-producing β cells derive from progenitors co-expressing pancreatic and duodenal homeobox 1 (PDX1) and NK6 homeobox (NKX)-6.1, which have a high self-replicating capacity. Fibroblast growth factor (FGF) and epidermal growth factor (EGF) induce expansion of the PDX1 and NKX-6.1-expressing progenitor cells and islet neogenesis [2–9]. Differentiation of progenitor cells starts when sirtuin (SIRT)6 deacetylates forkhead box O1 (FOXO1) to trigger its nuclear export and releases Illustrations by Pieterjan Ginckels, Faculty of Architecture, KU Leuven, Ghent, Belgium. © The Author(s), under exclusive license to Springer Nature Switzerland AG 2021 P. Holvoet, Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer, https://doi.org/10.1007/978-3-030-68844-8_3

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Fig. 3.1 Non-coding RNAs in β cell maturation and insulin production. In response to increasing glucose, growth factors FGF and EGF induce proliferation of pancreatic progenitors co-expressing PDX1 and NKX6.1 in the pancreas. Typically, this response is impaired in type 2 diabetes, likely by down-regulation of miR-26a, but miR-7 and miR-130b may restore it. Differentiation of precursor cells to mature β cells requires the coordinated action of PDX1 and MAFA, RFX6, HNFs (or MODYs), and MEIS1. They are typically activated during the differentiation process as revealed by the active chromatin marker H3K27a and mRNA expression profiling, suggesting that autoregulatory feedback regulation maintains PDX1 expression and initiates a pancreatic transcription program. IGF1, GLP-1, exendin, EGF, and FGF21 cause the maturation of β cells, reverted by TGF-β and miR-9, and the decrease of miR-26a, GAS5, MEG3, PLUTO, and βLINC. MiR-223, miR-375, and H19 silencing let-7, and of lncRNA-3134 may prevent this inhibition. GH and IGF1 induce β cell proliferation involving Wnt/β-catenin and mediated by SIRT1 and BCL2, MAFA, CCNs, and CDKs. The increase of IL1-β, miR-9, miR-34a, miR-124a, and HOTAIR impair β cell proliferation. PDX1, MAFA, and KLF11 regulate insulin production. LncRNA-3134 facilitates insulin secretion, whereas the increase of PDGF, TGF-β, and miR-9, and the decrease of miR-26a, GAS5, MEG3, PLUTO, and βLINC impair insulin secretion in type 2 diabetes. OCT4, SOX2, MYC, and KLF4 de-differentiate β cells to pluripotent stem cells. This reprogramming is blocked by increased miR-145 due to decreased silencing LINC-ROR. Increased non-coding RNAs are in red, decreased in green

its transcriptional repression of critical glucose-sensing genes such as PDX1 [10]. PDX1 targets important pancreatic tissue factors such as PDX1 itself, the regulatory factor (RF)-X6, HNF homeobox (HNF)-1β (MODY 5), HNF-4α (MODY1), and HNF-1α (MODY3), and Meis homeobox (MEIS)-1 [11, 12] (Fig. 3.1).

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Several extrinsic factors such as insulin-like growth factor 1 (IGF1), glucagon-like peptide (GLP)-1 and exendin, and EGF and FGF21 contribute to β cell differentiation and proliferation [13–17]. GLP-1 promotes α to β cell differentiation and compensates for the stress-related loss of β cells [18]. Growth hormone (GH), prolactin (PRL), and IGF1 and their receptors (GHR, PRLR, and IGF1R) regulate the proliferation of mature β cells [19]. Like in adipocyte proliferation, Wnt signaling plays a significant role in β cell proliferation mediated by SIRT1 and the BCL2, apoptosis regulator (BCL2). Wnt signaling is activated by binding Wnt ligands to the Frizzled receptor and induced by the GLP-1 receptor activation. Still, this receptor is low in diabetic β cells. This impairment leads to reduced cyclin (CCN) and cyclin-dependent kinase (CDK) expression and impaired β cell proliferation [20–23]. Decreased insulin-regulated mitotic cell-cycle progression and reduced expression of the Maf transcription factor MAFA may reduce proliferation. These decreases impair not only CDK-1/2 expression in the pancreas of diabetic patients but also the interaction of p27 (Kip1) with CCND3 and its cognate kinase partners CDK4 and CDK6, leading to β cell quiescence [24–26] (Fig. 3.1). PDX1 and MAFA are crucial for insulin production [27–29]. Krüppel-like zinc finger transcription factor (KLF)-11 regulates insulin promoter activity only in β cells and not in non-β cells through PDX1 [30]. PDX1 even induces adipose-tissue derived stem cells to differentiate to insulin-producing cells in diabetic mice [31]. However, platelet-derived growth factor (PDGF) decreases insulin production in type 2 diabetes [32]. Further, inflammatory interleukin (IL)-1β inhibits β cell replication while transforming growth factor (TGF)-β inhibits β cell differentiation [33] (Fig. 3.1). The POU class 5 homeobox one or POU5F1 (OCT4), SRY-box transcription factor 2 (SOX2), MYC proto-oncogene (MYC), and KLF4 play an essential role in reprogramming pancreatic β cells in pluripotent stem cells [34, 35] (Fig. 3.1).

3.1.1 Non-coding RNAs Related to β Cell Maturation MiR-7 can induce differentiation of human embryonic stem cells into β cell precursors [36]. MiR-130b protects precursor cells against senescence induced by high glucose [37]. MiR-26a in mice increases islet cell number by inhibiting the teneleven translocation (TET) enzymes TET1 and TET2 and thymine DNA glycosylase (TDG). TET and TDG play crucial roles in early embryonic and germ cell development by mediating DNA demethylation [38]. MiR-26a increases insulin secretion and β cell replication in an autocrine manner. Exosomal miR-26a regulates peripheral insulin sensitivity in a paracrine manner [39]. TGF-β/Smad signaling triggers the differentiation of β cells from adult stem cells by enhancing the transcription of miR-375 and miR-26a [40]. However, miR-26a is reduced in obesity and hyperglycemia [39]. Up-regulation of miR-223 in islets from people with diabetes increases PDX1 and cell cycle-related genes such as CCND1 and CCNE1 [41]. Glucose upregulates mir-375, which is crucial for maintaining β cell mass [42, 43]. Increasing H19 imprinted maternally expressed transcript lncRNA (H19) may restore β cell

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expansion by antagonizing let-7 [44]. A glucose-induced increase of lncRNA-3134 in type 2 diabetes retains β cell maturation and insulin secretion by promoting PDX1 and MAFA in β cells [45]. In contrast, TGF-β and mir-9 impair β cells’ differentiation and reduce exocytosis of insulin elicited by glucose, while miR-9 also blocks proliferation [46–48]. The decrease of miR-26a and lncRNAs growth arrestspecific 5 (GAS5), maternally expressed three lncRNA (MEG3), the PDX1 associated lncRNA, up-regulator of transcription (PLUTO), and βLINC in the pancreas is associated with a significant decline in the differentiation of β cells and insulin secretion, mainly through loss of PDX1 and MAFA. Further, down-regulation of maternally expressed 3 (MEG3) renders β cells more sensitive to cytokine-mediated oxidative stress [49–59] (Fig. 3.1). IL-1β and miR-9 impair β cell proliferation. MiR-34a also impairs β cell proliferation by interacting with CCND1 and CCNE2 and CDK4 and CDK6 [60–63]. High levels of miR-124a in the diabetic pancreas decrease proliferation by blocking SIRT1 expression and increase release of reactive oxygen species (ROS) [64, 65]. Homeobox transcript antisense RNA (HOTAIR) induces preadipocyte differentiation but inhibits β cell proliferation and insulin secretion and promotes insulin resistance [66–68]. The decrease of long intergenic non-protein coding RNA regulator of reprogramming (LINC-ROR) up-regulates miR-145 that silences SOX2 essential for reprogramming pancreatic β cells in pluripotent stem cells [69, 70] (Fig. 3.1).

3.2 Mechanisms in Insulin Signaling in the Pancreas Proper insulin signaling requires the binding of insulin to insulin receptors (IRs). Optimal processing of proinsulin to insulin. However, the disruption of IR expression in diabetic β cells leads to low expression of the eukaryotic translation initiation factor (EIF)-4G1 mediated by the sterol regulatory element-binding transcription factor 1 (SREBF1 or SREBP1), carboxypeptidase (CPE) and PDX1, and reduced proinsulin processing and biosynthesis of insulin. Re-expression of IR or restoring CPE expression each independently restores proinsulin processing [71–75]. Inhibition of SREBF1 expression increases PDX1 and GLP-1-mediated insulin secretion from β cells [76, 77]. Metformin counteracts impairment of GLP-1 receptor signaling induced by saturated fatty acids [78, 79]. IGF1 is like insulin in function and structure and is a member of a family of proteins involved in mediating growth and development. In contrast to impaired insulin signaling resulting in a decrease in β cell mass, reduced IGF1 signaling lowers glucose-induced insulin secretion without loss of β cell mass [80] (Fig. 3.2). Insulin binding to IRs leads to phosphorylation and activation of insulin substrate receptor (IRS) proteins. Phosphorylated IRS proteins activate and target phosphatidylinositol 3-kinase (PI3K) to the plasma membrane. The phosphatase and tensin homolog (PTEN) and the suppressor of cytokine signaling (SOCS) family regulate PI3K [81–86]. PI3K generates phosphatidylinositol (3,4,5)-trisphosphate (PIP3 ) that recruits pyruvate dehydrogenase kinase (PDK)-1, which phosphorylates and activates AKT serine/threonine kinase 1 (AKT) [87, 88]. PIP3 mediates the

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Fig. 3.2 Non-coding RNAs in insulin signaling. Proper insulin signaling requires enough insulin to respond to high glucose levels and insulin to bind to IR molecules. However, in type 2 diabetes, the up-regulation of SREBF1 or SREBP1 leads to decreased EIF4G1, CPE, GLP-1, and PDX1, impairing proinsulin processing. The increase of miR-7 and miR-29a and the decrease of miR26a and miR-132 blocks the response of insulin production to glucose. When insulin binds to IR molecules in cell membranes, those receptors activate several IRS proteins by phosphorylating them. Upon tyrosine phosphorylation, IRS proteins interact with PI3K, leading to the enzyme’s activation and targeting the plasma membrane. The increase of miR-29a, miR-144, and miR-145a, possibly due to decreased LINC-ROR, blocks IRS signaling. The binding of growth factors and cytokines to IGF1R also activates IRS and PI3K. However, the increase of miR-223 and the decrease of miR181b inhibit IGF1R signaling. PI3K recruits PDK1, which phosphorylates and activates several downstream kinases, including AKT, that phosphorylates AS160. However, high levels of miR-375 inhibit PDK1, while miR-124a increased by the down-regulation of circ-HIPK3 and the decrease of miR-26a and PVT1 block AKT. MiR-378 and H19, silencing let-7, may prevent this. In the basal state, AS160 binds to GLUT4 vesicles, negatively regulating its target Rab(s). In response to insulin, AS160 dissociates from Rab/Rip11 vesicles, leading to the activation of the target Rab(s) necessary to translate GLUT4 vesicles. The increase of miR-17 impairs GLUT4 signaling. GLUT4 aids the translocation of glucose through Rag that activates mTORC1. The mTORC1 complex consists of mTOR, Raptor, and GβL. It induces proteasomal degradation of IRS1 to constitute a negative feedback loop to balance insulin signaling to glucose uptake. Also, mTOR phosphorylates and

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 activates the p70S6K accompanied by the release of free S6K1 that, together with EIF4B, induces β cell size and mass and insulin production, protecting against apoptosis. The mTORC1/4EBP2/EIF4E pathway regulates proinsulin processing. The increase of miR-7, possibly due to a decrease of ciRs7, blocks p70SK and EIF4E, leading to β cell loss, impaired proinsulin processing, and decreased insulin secretion. Additionally, glucose activates the mTORC2 complex. It consists of mTOR, GβL, and Rictor. It directly phosphorylates AKT resulting in translocation of GLUT4 to the plasma membrane and increased glucose transport, and regulates β cell proliferation and insulin secretion. However, mir-7 blocks mTORC2 signaling, thereby inhibiting β cell proliferation, insulin secretion, and glucose transport. The increase of proinsulin and inflammatory ANG II induces mitochondrial dysfunction through miR-15, compromising SIRTs, FOXO3a, and NQO1. Proinsulin and ANG II also cause ER stress and β cell death through miR-491-5p. MiR-24a may prevent ER stress, but at the same time, blocks MAFA and thereby insulin production by surviving β cells. ROS associated with mitochondrial and ER stress causes β cell death by increased miR-34a, due to loss of silencing NEAT1, miR-138, and miR-145, and decreased miR-19a-3p and the DLK-MEG3-miR-376a-miR432 complex. The increase of miR-21, due to reduced silencing GAS5 and the decrease of miR-181b, may prevent apoptosis. However, the reduction of miR-181b leads to insulin resistance. Increased non-coding RNAs are in red, decreased in green

translocation of AKT to the plasma membrane [89]. One of the substrates of AKT is the Rab-GTPase activating protein (Rab-GAP), which undergoes phosphorylation in response to insulin and is essential for the retention of the solute carrier family two-member four (GLUT4 or SLC2A4) in intracellular vesicles [90–92]. In the basal state, AS160 binds to GLUT4 vesicles, negatively regulating its target Rab(s). In response to insulin, AS160 dissociates from Rab/Rip11 vesicles leading to the activation of the target Rab(s) necessary to translocate GLUT4 vesicles [93–96]. However, insulin-stimulated AS160 phosphorylation and GLUT4 translocation are impaired in patients with type 2 diabetes [97] (Fig. 3.2). The mammalian target of rapamycin complex 1 (mTORC-1) regulates insulin signaling downstream of AKT. The mTORC-1 complex consists of the regulatory associated protein of mTOR complex 1 (Raptor) and the mTOR associated protein LST8 homolog (MLST8 or GβL) [98–102]. Activation of the mTORC1 complex induces proteasomal degradation of IRS1 to constitute a negative feedback loop [103]. Also, mTOR phosphorylates and activates the ribosomal protein S6 kinase (p70S6K or RPS6KB1) accompanied by the release of free S6K1 [104, 105]. S6K1 and the eukaryotic translation initiation factor 4B (EIF4B) control β cell size and mass and insulin production and protects β cells from apoptosis [106–108]. The mTORC1/eukaryotic translation initiation factor 4E binding protein (4EBP)-2 and EIF4E regulate proinsulin processing [109]. However, in type 2 diabetes, the activity of the mTORC1 complex is impaired. Additionally, glucose activates the rapamycin-insensitive protein complex formed by serine/threonine kinase mTOR (mTORC2), consisting of mTOR, GβL, and Raptor-independent companion of mTOR complex 2 (Rictor) [110]. It directly phosphorylates AKT and facilitates phosphorylation by PDK1, resulting in translocation of GLUT4 to the plasma membrane and increased glucose transport [111]. Besides, mTORC2 and, in particular, Rictor is essential for maintaining a balanced β cell proliferation and glucose-stimulated insulin secretion by regulation of cytoplasmic translocation of PDX1, the nuclear accumulation of FOXO1, and insulin exocytosis

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[112]. However, mTORC2 signaling is diminished in pancreatic islets from humans with type 2 diabetes [113]. Excessive proinsulin and inflammatory angiotensinogen (ANG) II, increased by a deficiency in angiotensin I converting enzyme (ACE)-2, cause mitochondrial dysfunction associated with impaired β cell proliferation and reduced β cell mass [114–117]. Mitochondrial dysfunction is associated with increased mitochondrial ROS production by compromising cellular defense systems such as SIRTs and NAD (P) H quinone dehydrogenase 1 (NQO1) [118–123]. SIRT1-3 and FOXO increase insulin and improve glucose uptake. Improved insulin signaling reduces mitochondrial oxidative stress, inflammation, and lipid accumulation. In addition to mitochondrial stress, β cells are susceptible to endoplasmic reticulum (ER) stress due to their high rate of proinsulin biosynthesis in response to glucose stimulation [124– 126]. Unfolded protein response (UPR), which is activated to restore ER homeostasis, is vital for maintaining the functional β cell mass [127]. However, in type 2 diabetes, UPR activation fails to restore ER homeostasis and leads to β cell dysfunction and death by activating pro-inflammatory and pro-apoptotic signaling pathways [128–130] (Fig. 3.2).

3.2.1 Non-coding RNAs in Insulin Signaling in Type 2 Diabetes MiR-7, abundantly expressed in islet cells and even higher in patients with type 2 diabetes, not only protects against diabetes by inducing differentiation of stem cell to β cells but exacerbates the diabetic phenotype by blocking insulin granule exocytosis [131–135]. MiR-29a inhibits glucose-stimulated insulin secretion by inhibiting Wnt/β-catenin signaling [136]. The decrease of miR-132 also impairs insulin response to high glucose [137, 138] (Fig. 3.2). Further, miR-29a impairs IRS signaling and GLUT4 mediated glucose uptake [139]. MiR-144 and miR-145, the latter possibly by a decrease of sponging LINCROR, impair insulin signaling by direct targeting of IRS1 [140–142]. Hyperglycemiainduced miR-223 represses IGF1R and downstream PI3K/AKT/mTOR/p70S6K signaling [143, 144]. The decrease of mir-181b in obesity reinforces this inhibition [51, 145]. The increase of miR-375 blocks PI3K by targeting PDK1 [146]. Higher expression of miR-124a, due to the loss of the homeodomain interacting protein kinase three circ-RNA (circ-HIPK3), decreases AKT [64, 65, 147, 148], which may be reverted by H19 that silences let-7 [44, 149, 150]. Decrease of miR-26a by high glucose reduced insulin-stimulated AKT activation by increasing phosphatase and tensin homolog (PTEN) [39, 151]. Down-regulation of PVT1 oncogene (PVT1) in type 2 diabetes also blocks PI3K/AKT signaling [152]. Overexpression of miR-378 restores PI3K/AKT signaling and down-regulates the pro-apoptotic BCL2 associated X, apoptosis regulator (BAX) [153]. High levels of miR-17 in diabetes decrease GLUT4-mediated glucose uptake [154] (Fig. 3.2).

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MiR-7 targets components of the mTORC1 complex, p70S6K, and EIF4E, thereby disrupting feedback on IRS signaling and reducing β cell size and mass, proinsulin processing, insulin production, and protection against cell death in type 2 diabetes. It also targets the mTORC2 complex, thereby stimulating the diabetic phenotype by repressing β cell proliferation and insulin production. The circular cerebellar degeneration-related protein 1 antisense RNA (Cdr1as or CiRs-7) may sponge miR-7, but it is low in diabetic β cells [132, 148] (Fig. 3.2). MiR-15 induces mitochondrial oxidative damage associated with increased ROS release, and miR-491-5p then causes mitochondrial dysfunction-associated β cell death [155, 156]. MiR-24a inhibits ER stress, but it also silences MAFA, thereby decreasing insulin secretion in surviving β cells [157] (Fig. 3.2). The increase of miR-34a-5p, by down-regulation of nuclear paraspeckle assembly transcript 1 (NEAT1), results in β cell death through the EIF2AK3 (or PERK)/p53dependent pathway [149]. Elevated expression levels of mir-138 and miR-145 induce cell senescence and death in insulin-producing β cells [158, 159]. A decrease of miR19a-3p leads to SOCS3 overexpression and apoptosis [160]. Repression of a delta-like non-canonical NOTCH ligand (DLK)-1-MEG3 miR cluster containing miR-376a and miR-432 is also associated with increased β cell apoptosis [161]. In contrast, the decrease of GAS5 and the resulting increase of miR-21 in type 2 diabetes reduce apoptosis by directly targeting programmed cell death (PDCD)-4. Still, it may also increase apoptosis by directly inhibiting the apoptosis regulator BCL2 [162–165]. The decrease of miR-181b may protect against cell death by increasing BCL2, and MCL1 apoptosis regulator, BCL2 family member (MCL1) proteins but may increase cell death by impairing insulin signaling [166] (Fig. 3.2).

3.3 Inflammation in the Pancreas, Insulin Resistance, and Type 2 Diabetes High levels of glucose and ROS impair IRS-mediated PI3K activity in macrophages resulting in overexpression of suppressor of cytokine signaling 3 (SOCS3). SOCS3 reduces energy expenditure and increases food intake and adiposity, insulin and leptin resistance, M1 macrophage polarization, and a state of cytokine resistance to IL4, leading to inflammation [167–169]. SOCS3 also increases food intake and decreases energy expenditure, and impairs leptin signaling in obesity [168]. High glucose and ROS disrupt the balance between pro-inflammatory Th17 and Th1 and antiinflammatory Treg and Th2 cells. They increase inflammatory cytokines IL-1β, tumor necrosis factor (TNF)-α, interferon (IFN)-γ, and IL6 and decrease anti-inflammatory cytokines IL4 and IL13 [170–173]. Impaired IL13 anti-inflammatory function in type 2 diabetes is associated with an additional increase of M1 macrophages and derived IL6, IL-1β, TNF-α, which induce β cell death [174–177] (Fig. 3.3).

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Fig. 3.3 Non-coding RNAs in inflammation and insulin resistance. Hyperglycemia and ROS in type 2 diabetes decrease IRS/PI3K/AKT signaling, likely due to an increase of miR-146a. The associated rise in SOCS3, possibly due to the decline of miR-19a-3p and miR-455-5p, impairs response to anti-inflammatory IL4 and increases M1 macrophage polarization and inflammation. SOCS3 also increases food intake and decreases energy expenditure, and reduces leptin signaling in obesity. Hyperglycemia and ROS in type 2 diabetes change the T cell profile. Th1 and Th17 cells increase, and Th2 and Treg cells decrease, thereby increasing pro-inflammatory TNF-α, IL6, IL-1β, and IFN-γ while decreasing anti-inflammatory IL4 and IL13. MiR-30a may temporally block IL1β and IFN-γ secretion. Ultimately, the excess of inflammatory cytokines causes M1 macrophage polarization due to increased expression of miR-221–222 and secretion of macrophage-derived inflammatory cytokines TNF-α, IL-1β, and IL6. Inflammatory cytokines induce miR-34a, possibly due to loss of sponging NEAT1, and miR-146a leading to decreased β cell proliferation and to β cell senescence and death. MiR-221/222 is associated with inflammation-induced insulin resistance. Increased non-coding RNAs are in red, decreased in green

3.3.1 Non-coding RNAs Related to Inflammation in the Pancreas, with Insulin Resistance and Type 2 Diabetes Mir-146a represses PI3K/AKT signaling indirectly by targeting C-X-C motif chemokine receptor 4 (CXCR4) [178]. The reduction of miR-19a-3p and miR-455 in type 2 diabetes increases SOCS3 expression [160, 179]. The increase of miR30a blocks inflammation-inducing IL-1β in immune cells and islet cells and IFN-γ in inflammatory cells, thereby retaining insulin sensitivity [180, 181]. However,

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high levels of miR-221–222 counteract this action of miR-30a associated with M1 macrophage polarization and inflammation, and insulin resistance [182, 183]. Further, M1 macrophage polarization up-regulates inflammatory mediators IL-1β, IL6, and TNF-α, which induce mir-34a and miR-146a, leading to increased cytokinetriggered cell death [53, 184–186]. The increase of miR-34a may be due to the repression of NEAT1 in type 2 diabetes [187, 188]. Because we showed above that it also impairs β cell proliferation, miR-34a is a crucial link between inflammation and a reduced number of β cells (Fig. 3.3).

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179. Chen, P., et al. (2019). MiR-455-5p ameliorates HG-induced apoptosis, oxidative stress and inflammatory via targeting SOCS3 in retinal pigment epithelial cells. Journal of Cellular Physiology, 234, 21915–21924. https://doi.org/10.1002/jcp.28755. 180. Jiang, X., et al. (2017). MiR-30a targets IL-1alpha and regulates islet functions as an inflammation buffer and response factor. Scientific Reports, 7, 5270. https://doi.org/10.1038/s41598017-05560-1. 181. Koh, E. H., et al. (2018). miR-30a remodels subcutaneous adipose tissue inflammation to improve insulin sensitivity in obesity. Diabetes, 67, 2541–2553. https://doi.org/10.2337/db171378. 182. Bao, F., Slusher, A. L., Whitehurst, M., & Huang, C. J. (2018). Circulating microRNAs are upregulated following acute aerobic exercise in obese individuals. Physiology & Behavior, 197, 15–21. https://doi.org/10.1016/j.physbeh.2018.09.011. 183. Yan, H. et al. (2016). Expression profile analysis of miR-221 and miR-222 in different tissues and head kidney cells of cynoglossus semilaevis, following pathogen infection. Mar Biotechnol (NY), 18, 37−48. doi:https://doi.org/10.1007/s10126-015-9668-2. 184. Roggli, E., et al. (2010). Involvement of microRNAs in the cytotoxic effects exerted by proinflammatory cytokines on pancreatic beta-cells. Diabetes, 59, 978–986. https://doi.org/ 10.2337/db09-0881. 185. Alipoor, B., et al. (2017). Association of MiR-146a expression and type 2 diabetes mellitus: A meta-analysis. International Journal of Molecular and Cellular Medicine, 6, 156–163. https:// doi.org/10.22088/acadpub.BUMS.6.3.156. 186. Choi, S. E., et al. (2013). Elevated microRNA-34a in obesity reduces NAD+ levels and SIRT1 activity by directly targeting NAMPT. Aging Cell, 12, 1062–1072. https://doi.org/10.1111/ acel.12135. 187. Ding, N., Wu, H., Tao, T., & Peng, E. (2017). NEAT1 regulates cell proliferation and apoptosis of ovarian cancer by miR-34a-5p/BCL2. Onco Targets Ther, 10, 4905–4915. https://doi.org/ 10.2147/OTT.S142446. 188. Kesherwani, V., Shahshahan, H. R., & Mishra, P. K. (2017). Cardiac transcriptome profiling of diabetic Akita mice using microarray and next generation sequencing. PLoS ONE, 12, e0182828. https://doi.org/10.1371/journal.pone.0182828.

Chapter 4

Non-coding RNAs Related to Lipid Metabolism and Non-alcoholic Fatty Liver Disease

Abstract MiR-24, miR-122, down-regulating miR-21, and lncARSR, and the decrease of miR-98 are associated with increased liver cholesterol synthesis. In contrast, miR-29a/b/c, miR-185, miR-195 and miR-223 inhibit cholesterol synthesis. MiR-140-5p, miR-148, and miR-185 block the uptake of LDL via the LDL receptor. MiR-27 up-regulates PCSK9, inducing the degradation of the LDL receptor. MiR223, CHROME, and MeXiS stimulate cholesterol efflux through ABCA1 and ABCG1. The decrease of miR-613 exacerbates cholesterol efflux. In contrast, miR19b, miR-26, miR-27, miR-33a/b, miR-34a, miR-101, miR-128-2, miR-144, miR145, miR-148, miR-302a, miR-758, and lnc-HC block this efflux. MiR-24, miR-96, miR-185, and miR-223 block uptake of HDL-cholesteryl esters via SR-B1. LeXiS increases LDL and HDL cholesterol. MiR-26a and miR-133a prevent CD36 lipid uptake. LncRNA HULC, silencing miR-9, induces FA oxidation inhibited by miR27a, miR-30a, miR-34a, and miR-222. Impaired expression of miR-17, miR-21, miR-29, miR-30a/b/c, miR-34a, miR-124, miR-130, miR-138, miR-150, miR-155, miR-181, miR-221, miR-223, miR-375, miR-378, and miR-455, and lncRNAs H19, MALAT1, MEG3, and NEAT1 is associated with non-alcoholic fatty liver disease. They are linking obesity and type 2 diabetes with non-alcoholic fatty liver disease.

4.1 Cholesterol and Lipids in the Liver A tightly regulated and complex mechanism involving de novo biosynthesis, internalization of exogenous cholesterol, and efflux of excess cholesterol determines cellular cholesterol levels. Cholesterol synthesis from acetyl-CoA involves a series of approximately 30 reactions. 3-hydroxy-3-methylglutaryl coenzyme A reductase (HMGCR) and squalene monooxygenase are the rate-limiting enzymes [1]. Another essential regulator is the endoplasmic reticulum (ER)-bound sterol regulatory element-binding protein (SREBP)-2 that coordinates cholesterol synthesis by activating HMGCR. SREBP2 also regulates the low-density lipoprotein receptor (LDLR), which imports cholesterol from the blood [1–3]. The forkhead box (FOXO)-3 down-regulates SREBP2 by recruiting sirtuin (SIRT)-6, which deacetylates histone H3 [4] (Fig. 4.1).

Illustrations by Pieterjan Ginckels, Faculty of Architecture, KU Leuven, Ghent, Belgium. © The Author(s), under exclusive license to Springer Nature Switzerland AG 2021 P. Holvoet, Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer, https://doi.org/10.1007/978-3-030-68844-8_4

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Fig. 4.1 Non-coding RNAs in cholesterol metabolism. LeXiS increases LDL and HDL cholesterol. SREBP2, HMGCR, and SM regulate cholesterol synthesis. The increase of miR-24, miR-122 by down-regulating miR-21, and lncARSR, and the decrease of miR-98 is associated with increased cholesterol synthesis. In contrast, miR-29a/b/c, miR-185, miR-195 and miR-223 inhibit cholesterol synthesis. MiR-140-5p, miR-148, and miR-185 block the uptake of LDL via the LDL receptor. MiR27a up-regulates PCSK9, which induces the degradation of the LDL receptor. MiR-223, CHROME, and MeXiS stimulate cholesterol efflux through ABCA1 and ABCG1. The decrease of miR-623 exacerbates this efflux. In contrast, miR-19b, miR-26, miR-27, miR-33a/b, miR-34a, miR-101, miR128-2, miR-144, miR-145, miR-148, miR-302a, miR-758, and lnc-HC block cholesterol efflux. LCAT esterifies cholesterol to cholesteryl esters, converting pre-β to mature HDL. Cholesteryl esters may be taken up through SR-B1. MiR-24, miR-96, miR-185, and miR-223 block uptake of HDL-cholesteryl esters via SR-B1. Alternatively, CETP transfers cholesteryl esters from HDL to (V)LDL, taken up via the LDL receptor. Finally, ER-bound ACAT esterifies cholesterol. Cholesteryl esters accumulate as lipid droplets. MiR-26a and miR-133a block the CD36-mediated uptake of FA, while miR-27a, miR-30a, miR-34a, and miR-222 block FA oxidation in the liver. HULC, silencing miR-9, may stimulate FA oxidation

Besides de novo biosynthesis, cholesterol in the blood can be taken up by LDLR at the hepatocytes’ basal surface. Lack of functional LDLR in the liver leads to a massive accumulation of LDL in the artery wall and atherosclerosis [5]. The FOXO3–SIRT6 complex represses proprotein convertase subtilisin/kexin type 9 (PCSK9). PCSK9 is an SREBP2 target that binds LDLR on the plasma membrane and is internalized with the LDLR protein in clathrin-coated vesicles, preventing LDLR from recycling back to the surface. The PCSK9–LDLR complex is eventually degraded in lysosomes,

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involving the ubiquitin ligase inducible degrader of LDLR (IDOL or MYLIP) and liver X receptor (LXR) [6, 7] (Fig. 4.1). Excess cholesterol in peripheral tissues is exported to the blood by ATP-binding cassette subfamily A member 1 (ABCA1) or ABCG1 or to the intestinal lumen and bile ducts by the ABCG5 and ABCG8 heterodimer [8]. Cholesterol blocks the nuclear entry of nuclear factor erythroid two related factor one (NRF1) and subsequently de-represses the activity of LXR, regulating the expression of ABCA1, ABCG1, ABCG5, and ABCG8. Lipid-poor pre-beta high-density lipoproteins (HDL), rich in apolipoprotein (APO)A1, are synthesized by the liver or intestinal mucosa and released into circulation. ABCA1 facilitates the efflux of phospholipids and cholesterol to APOA1 to generate nascent, discoidal HDL particles. Lecithin-cholesterol acyltransferase (LCAT) esterifies free cholesterol and converts pre-beta HDL to mature HDL. Mature HDL takes up ABCG1-effluxed cholesterol. Cholesteryl esters may also be taken up directly through scavenger receptor class B type 1 (SR-B1) (Fig. 4.1). Alternatively, esters are transferred to apoB-containing lipoproteins (VLDL/LDL) through cholesteryl ester transfer protein (CETP) and then transported to the liver through the LDL receptor [9–11]. Excess cholesterol can also allosterically activate acetyl-CoA C-acetyltransferase (ACAT) in the ER. Active ACAT esterifies cholesterol. Cholesteryl esters are stored as lipid droplets or secreted as chylomicrons and very-low-density lipoproteins (VLDLs) [12].

4.1.1 Non-coding RNAs and Cholesterol in the Liver Hepatic expression of lncRNAs LeXis elevated in response to a high fat and cholesterol diet, increases LDL and HDL cholesterol, independently of LDL receptor and ABCA1. LeXis interacts with and affects the DNA interactions of RALY heterogeneous nuclear ribonucleoprotein (RALY). This heterogeneous ribonucleoprotein acts as a transcriptional cofactor for cholesterol biosynthesis in the mouse liver [13]. Obesity-induced miR-24 increases the expression of HMGCR [14]. MiR-122 downregulates miR-21 increasing HMGCR transcription and translation [15, 16]. The lncRNA regulator of Akt signaling associated with HCC and RCC (lncARSR) activates the PI3K/AKT pathway and increases the expression of mature SREBP2 and HMGCR [17]. The decrease of miR-98 in hypercholesterolemic patients is associated with increased SREBP2 [18]. MiR-29a/b/c significantly suppresses HMGCR expression [19]. MiR-185 decreases the transcription of SREBP2 and HMGCR [20]. MiR-195 down-regulates SREBF2, HMGCR, and LDLR and up-regulates PCSK9 by reverting the action of nuclear factor kappa B (NFκB) [21]. MiR-223 inhibits cholesterol biosynthesis through the direct repression of sterol enzymes 3-hydroxy-3-methylglutaryl-CoA synthase 1 and methylsterol monooxygenase 1.

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MiR-27a induces PCSK9, degrading LDLR [22]. MiR-140-5p and miR-185 directly repress LDLR expression [23, 24]. MiR-148a decreases hepatic LDLR and ABCA1 expression [25]. MiR-223 indirectly promotes ABCA1 through Sp3 transcription factor (SP3) [26]. LncRNA CHROME promotes cholesterol efflux and HDL biogenesis by curbing the actions of miR-27b, miR-33a, miR-33b, and miR-128 [27]. LncRNA MeXis in mouse peritoneal macrophages increases ABCA1 transcript [28]. PPARγ suppresses miR-613, thereby increasing LXRα and ABCA1 [29]. MiR-19b, miR-26, miR-27, miR-33a/b, miR-34a, miR-101, miR-128-2, miR-144, miR-145, miR-148, miR-302a, and miR-758 repress ABCA1 and/or ABCG1 [30– 43]. The lncRNA derived from hepatocytes (lnc-HC) silences ABCA1 by binding to the heterogeneous nuclear ribonucleoprotein A2/B1 [44]. MiR-24, miR-96, miR-185, and miR-223 repress uptake of HDL-associated cholesteryl esters through SR-BI [14, 45] (Fig. 4.1). MiR-378a-3p stabilizes apoB100, the predominant lipoprotein in LDL [46].

4.2 Fatty Acids and Triglycerides Metabolism of fatty acids (FA) and their storage in triglycerides (TG) occurs primarily in hepatocytes. Daily, the liver processes large quantities of FA but stores less than 5% in TG [47]. Naturally, the FA oxidation rates and secretion balance FA’s acquisition by uptake from the plasma and de novo synthesis within the liver into plasma as TG-enriched VLDL. The relatively small quantities of TG are stored in cytoplasmic lipid droplets in the liver. FA within the liver originates from either dietary or endogenous sources. Insulin resistance in WAT increases lipolysis and the entry of non-esterified fatty acids in the liver. Hyperinsulinemia resulting from insulin resistance promotes hepatic de novo lipogenesis [48, 49]. Plasma insulin activates the ER-bound SREBP-1c that up-regulates all genes in the FA biosynthetic pathway [50]. The hepatic uptake of excess plasma glucose promotes the nuclear translocation of the carbohydrate response element-binding protein that up-regulates most FA biosynthetic genes plus pyruvate kinase that increases the availability of citrate for FA synthesis [51]. When plasma insulin concentrations are low under fasting conditions, a lipolytic program is initiated in WAT, which increases the plasma FA pool that is available for uptake by the liver [52]. Bile acids emulsify dietary TG within the intestinal lumen following their hydrolysis primarily by pancreatic lipase, yielding sn-2-monoacylglycerols, and free FA [53]. Following emulsification, these lipid molecules are taken by enterocytes and resynthesized into TG. TG are packaged into chylomicrons, secreted into the lymphatic system, and ultimately reach the plasma [54]. TG remaining within the chylomicron remnants undergo receptor-mediated endocytosis in the liver, releasing FA [55]. Hepatocytes take up FA via plasma membrane-associated FA-binding

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protein, FA translocase (FAT)/CD36, caveolin-1, and FATP/solute carrier family 27A1–6) [56–58]. In the outer membrane of mitochondria, long-chain acyl-CoA synthetase 1 (ACSL1) converts long-chain FA to acyl-coAs. ACSL1 interacts with carnitine palmitoyltransferase. Additionally, acyl-coAs can undergo β oxidation in peroxisomes regulated by the fatty acyl-CoA oxidase (AOX), or α and ω oxidation in ERmediated by family members. The expression of genes involved in mitochondrial and extramitochondrial FA oxidation is regulated by PPARα [59–62] (Fig. 4.1).

4.2.1 Non-coding RNAs and Fatty Acids and Triglycerides MiR-26a and miR-133a suppress CD36-mediated FA uptake [63, 64]. The hepatocellular carcinoma up-regulated long non-coding RNA (HULC) correlates positively with ACSL1 by silencing miR-9, thereby de-repressing PPARα that induces ACSL1 [65]. MiR-27a-3p, miR-34a-5p and miR-205, silencing ACSL1, miR-30a-3p and miR-34a, silencing CPT1, and miR-222, silencing ACOX1 expression, inhibit FA oxidation and promote TG accumulation [66–71] (Fig. 4.1).

4.3 Non-alcoholic Fatty Liver Disease Above, we have discussed the contribution of nutrient excess and low physical activity in obesity and type 2 diabetes. Nutrient excess and low physical activity are also associated with increased lipid uptake and lipogenesis in the liver. Increased intrahepatic triglyceride levels leading to hepatic steatosis are the hallmark features of non-alcoholic fatty liver disease (NAFLD). Increased gluconeogenesis is associated with increased intrahepatic glucose and insulin resistance. Weight loss reduces NAFLD [72, 73] (Fig. 4.2). The deposition of glucose and lipids in the liver is associated with mitochondrial dysfunction and increased mitochondrial reactive oxygen species (ROS), promoting inflammation, insulin resistance, and cell death, thereby aggravating NAFLD development [74–80]. Lipotoxic hepatocellular injury attracts inflammatory cells, mainly activated M1 macrophages. They surround ballooned hepatocytes as crown-like structures. Some macrophages derive from circulating monocytes, but Kupffer cells are the most highly represented macrophages in the liver [81–83]. An increase of M1-polarized macrophages, possibly induced by interferon regulatory factor (IRF)-5, promotes or exacerbates fibrosis, cirrhosis, and eventual liver failure [84, 85]. The 12lipoxygenase converts polyunsaturated fatty acids to oxidized pro-inflammatory lipid intermediates. The latter link inflammation, oxidative stress, and insulin resistance [86, 87] (Fig. 4.2). Lipotoxicity is also associated with the release of danger-associated molecular patterns (DAMPs). They stimulate innate immunity by binding Toll-like receptor

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Fig. 4.2 Non-coding RNAs in non-alcoholic fatty liver disease, a comorbid complication of obesity, and type 2 diabetes. Nutrient excess and low physical activity lead to obesity and type 2 diabetes, associated with increased liver uptake of lipids and de novo lipogenesis, increasing blood triglyceride levels. Lipid accumulation is facilitated by the increase of miR-17, miR-21, miR-29, miR-30a, miR-34a, miR-124, by loss of sponging NEAT1, miR-141-200c, miR-150, miR-181a/b, miR-190b, miR-221-222, ARSR, HULC, and NEAT1/miR-140 paraspeckles. The decrease of miR30c-5p, miR-130a, silenced by H19, miR-138, miR-455, and lncRNA B4GALT1 exacerbates lipid accumulation. Nutrient excess and low physical activity are also associated with increased gluconeogenesis and glucose uptake induced by the increase of miR-21, miR-150, and miR-190b, and the decrease of B4GALT1, leading to high glucose levels. High lipid and glucose levels induced miR-34a expression associated with mitochondrial stress and increased ROS. High glucose and lipids also induce ER stress-mediated by miR-17 and miR-155, associated with increased ROS. ROS causes M1 macrophage polarization exacerbated by miR-141 and miR-155, and inflammation by an increase of miR-34a, miR-122, miR-141-200c, miR-155, miR-221-222, and HULC. Low levels of miR-146a and miR-223 exacerbate inflammation, possibly reverted by the decrease of miR-375. The rise of miR-17, miR-21, miR-150, miR-190b, and MALAT1 causes inflammationassociated insulin resistance. MiR-378 may prevent insulin resistance. Further, ROS induce cell death mediated by miR-34a, miR-150, and HULC. Inflammation, apoptosis, and ECM deposition lead to liver fibrosis. The miR-130-miR-301 family, miR-221-222, and HULC induce fibrosis, while overexpression of miR-378 may prevent it. Increased non-coding RNAs are in red, decreased in green

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4 (TLR4) and release pro-inflammatory chemokines and cytokines through NLR family pyrin domain containing 3 (NLRP3) activation leading to cell death [88]. High lipids often coincide with insulin resistance in steatotic livers and are associated with ER stress in hepatocytes. As in the pancreas and adipose tissue, chronic ER stress can lead to an adaptive unfolded protein response, causing inflammation and cell death [89]. The p53 ortholog p63 and Janus kinase (JAK) link ER stress to inflammation, partially by interplay with nuclear factor kappa B (NFκB) [90–92]. BCL2 family members, BCL2 antagonist/killer (BAK), and BCL2 associated X, apoptosis regulator (BAX) promote apoptosis in response to ER stress [93] (Fig. 4.2). Activated stellate cells in injured liver differentiate to proliferating α smooth muscle actin-expressing contractile myofibroblasts, increasing vascular resistance, and promoting portal hypertension. Besides, the connective tissue growth factor and TGF-β1 drive fibrogenesis, amplify inflammation and increase extracellular matrix deposition and degradation [94]. All these processes and apoptosis contribute to liver fibrosis [95].

4.3.1 Non-coding RNAs Related to Non-alcoholic Fatty Liver Disease Type 2 diabetes with NAFLD complication is associated with increased expression of miR-17 and thereby increased free fatty acids-induced hepatocyte steatosis and decreased insulin sensitivity [96]. MiR-17 also contributes to steatosis by reducing the expression of cytochrome P450 family seven subfamily A member 1, an ER membrane protein that converts cholesterol to bile acids [97]. High miR-21 and low peroxisome proliferator-activated receptor (PPAR)-α increases fatty acid uptake, lipogenesis, gluconeogenesis, and insulin resistance [98–100]. MiR-29 increases lipogenesis in the liver and increases circulating triglyceride levels in a SIRT1dependent manner [101]. The rise of miR-30a is associated with a decrease of PPAR-α and lipid deposition [102]. MiR-34a that is induced in the liver by the inflammatory adipokine resistin is associated with increased triglyceride content, decreased mitochondrial content, and impaired mitochondrial function [103]. Direct and indirect targets of miR-34a are SIRT1, receptor tyrosine kinase, KLF4, and FGFR1 and FGFR4, which are all decreased by saturated fatty acids [104]. MiR-124, no longer silenced by NEAT1, silences tribbles homolog 3, resulting in increased AKT signaling and activation of lipogenic genes [105, 106]. High levels of hepatic miR-141 and miR-200c are related to higher liver weights and triglyceride levels and activation of pro-inflammatory and pro-fibrotic genes [107]. MiR-150 is associated with hepatic steatosis and insulin resistance by regulating the expression of genes related to gluconeogenesis, fatty acid uptake, and FA oxidation [108]. MiR-181a/b overexpression decreases PPAR-α and SIRT1, thereby increasing lipid accumulation in hepatocytes [109, 110]. MiR-190b increases triglyceride and total cholesterol levels and induces glucose intolerance and insulin resistance by repressing IRS2/AKT signaling [111].

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Up-regulated expression of miR-221-222 is associated with lipid deposition, inflammation, extracellular matrix (ECM) deposition, and fibrosis by targeting TIMP metallopeptidase inhibitor 3 (TIMP3) [112]. The regulator of AKT signaling associated with HCC and RCC (ARSR) lncRNA up-regulates SREBP-1c and enhances hepatic lipogenesis. NEAT1/miR-140 paraspeckles decrease the phosphorylation of protein kinase AMP-activated catalytic (AMPK) and increase the expression of SREBP1 and fatty acid synthase [113–115]. The hepatocellular carcinoma up-regulated lncRNA (HULC) stimulates lipid deposition, hepatic fibrosis, and apoptosis [116]. MiR-378 increases epithelial-to-mesenchymal transition (EMT), improves insulin sensitivity and inhibits liver fibrosis [117–119] (Fig. 4.2). Lipid accumulation may also result from a decrease of miR-30c-5p that directly targets fatty acid synthase [120]. MiR-130a has the potential to inhibit lipid accumulation by down-regulating NAFLD-related genes PPAR-γ, SREBP1, and fatty acid synthase, but H19 silences miR-130a [121, 122]. Low miR-138 elevates the leptinregulated carnitine palmitoyltransferase, limiting fatty acid β-oxidation [123, 124]. Low levels of expression of miR-455 are associated with increased lipid deposition by up-regulating SOCS3. Of interest, miR-19a and miR-125a could replace miR-455 in targeting SOCS3 [125–127]. Low levels of the suppressor of hepatic gluconeogenesis and lipogenesis (lncSHGL in mice or B4GALT1-AS1 in humans) associate with gluconeogenesis and lipogenesis [128] (Fig. 4.2). Next to miR-34a and miR-141-200c, high levels of miR-122 in NAFLD patients’ liver are also associated with inflammation [129]. MiR-155 is associated with decreased binding of peroxisome proliferator-activated receptor response element (PPRE) and PPAR-α and increased C-C motif chemokine ligand 2 (CCL2 or MCP1) production. Alcohol causes M1 macrophage polarization by inducing miR-155 and repressing CCAAT enhancer-binding protein (c/EBP)-β [130]. Low levels of miR146a are associated with obesity-induced inflammation [131], in which the decrease of anti-inflammatory miR-223 exacerbates [132]. In contrast, the decrease of miR375 during NAFLD progression may be an anti-inflammatory protective mechanism [133, 134]. High glucose and insulin levels induce MALAT1. MALAT1 up-regulates C-X-C motif chemokine ligand 5 (CXCL5) that blocks insulin signaling by activating the Janus kinase signal transducer and activator of transcription (JAK/STAT)/SOCS2 pathway [135, 136] (Fig. 4.2). Next to HULC and miR-221-222, the miR-130/301 family prevents hepatitis C virus infection but induces ECM deposition and fibrosis [121, 137]. As indicated above, miR-378 inhibits fibrosis.

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Chapter 5

Non-coding RNAs Related to Atherosclerosis

Abstract The onset of atherosclerosis is caused by endothelial dysfunction through mechanical shear stress and chemical stress induced by high glucose, ox-LDL, and ANG II. Injured endothelium attracts inflammatory cells. Among them, macrophages that accumulate lipids and differentiate into foam cells. Cytokines induce vascular smooth muscle cell proliferation and secretion of matrix proteins. Disrupted angiogenesis leads to oxygen deprivation. However, angiogenesis also facilitates the infiltration of inflammatory cells. They secrete cytokines and ROS, which induce cell death, thereby destabilizing atherosclerotic plaques. The multiple-hit pathogenesis model of atherosclerosis shares with obesity and type 2 diabetes an imbalance in the expression of let-7, miR-7, miR-9, miR-17, miR-21, miR-26, miR-27, miR29, miR-30, miR-33, miR-34, miR-124, miR-130, miR-132, miR-133, miR-143– 145, miR-146a, miR-150, miR-181, miR-221–222, miR-223, and miR-378, and lncRNAs GAS5, H19, HOTAIR, MALAT1, MEG3 and NEAT1, and circ-RNA PVT1. Typically, lncRNAs ATB, CASC11, HOXC-AS1, LEF1-AS1, lincRNA-p21, MANTIS, MIAT, TUG1, UCA1, and ZEB1-AS1, and circ-RNAs ANRIL regulate miR-expression in atherosclerotic plaques, in addition to lncRNAs and circ-RNAs related to metabolic diseases.

5.1 Endothelial Injury, Inflammation, and Apoptosis Endothelial cells (ECs) prefer not to maximize energy (ATP) production by shunting all glucose they take up into oxidative phosphorylation (OXPHOS) but rely on glycolysis instead of OXPHOS [1]. This shift results in a low-level release of mitochondrial reactive oxygen species (ROS)[2], enough to enhance EC migration and sprouting, ROS inducing VEGF [2]. VEGF increases glycolysis by increasing 6-phosphofructo2-kinase/fructose-2,6-biphosphatase 3 (PFKFB3), and fibroblast growth factor (FGF) activates hexokinase 2 (HK2) and PFKFB3 [3, 4]. VEGF also induces glucose transporter 1 (GLUT1), improving glucose uptake [5].

Illustrations by Pieterjan Ginckels, Faculty of Architecture, KU Leuven, Ghent, Belgium. © The Author(s), under exclusive license to Springer Nature Switzerland AG 2021 P. Holvoet, Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer, https://doi.org/10.1007/978-3-030-68844-8_5

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Besides, the monocyte cross-talk to ECs triggers tissue factor (TF) expression by ECs, resulting in microvessel formation, involving Wnt signaling, the release of intracellular Ca (2 + ), and an increase of inflammatory NFκB activity [6–10]. Atherosclerosis develops in medium and large arteries at sites of high shear stress. Exposure of endothelial cells (ECs) to shear stress, high glucose, angiotensinogen (ANG II), and oxidized LDL (ox-LDL) causes endothelium dysfunction. Dysfunction is due to impaired non-canonical Wnt and phosphatidylinositol 3-kinase (PI3K) / AKT serine/threonine kinase 1 (AKT) / nitric oxide synthase (NOS) signaling, [11–13]. Reduced PI3K/AKT signaling leads to insulin resistance [14] Endothelial dysfunction is associated with the secretion of adhesion molecules: vascular cell adhesion molecule 1 (VCAM-1), intercellular adhesion molecule 1 (ICAM-1), and the C–C motif chemokine receptor 2 (CCR2; or MCP-1 receptor). They facilitate adhesion and infiltration of monocytes, which differentiate into macrophages [6, 15]. They release pro-angiogenic factors, such as VEGF, hepatocyte growth factor (HGF), fibroblast growth factor (FGF), tumor necrosis factor (TNF)-α, and interleukin (IL)-8. Angiogenesis may thus be beneficial because pro-angiogenic factors stimulate the proliferation of ECs and mobilize and home bone-marrowderived endothelial progenitor cells allowing repair of the endothelium. However, angiogenesis may be harmful because it facilitates the infiltration and accumulation of inflammatory cells (Fig. 5.1). Infiltrated monocytes differentiate into anti-inflammatory M2 macrophages. They secrete transforming growth factor (TGF)-β and interleukin (IL)-10, which counteract vascular inflammation and immune cell activation. Endothelial injury and subsequent adhesion of inflammatory cells result in ROS release, which polarizes M2 towards pro-inflammatory M1 macrophages [16–19]. This activation involves increased expression of toll-like receptors (TLRs) and downstream nuclear factor kappa B (NFκB), which elicit the release of pro-inflammatory cytokines, such as IL6 and tumor necrosis factor (TNF)-α [20]. Negative regulation of macrophage activation and cytokine secretion primarily occurs at the TLR signaling level, for example, by the interleukin-1 receptor-associated kinase-3 (IRAK3 or IRAK-M) [21–24]. IRAK3 negatively regulates signaling by preventing dissociation of IRAK1 and IRAK4 from MyD88 and the formation of IRAK - TNF receptor-associated factor-6 (TRAF6) complexes [25]. Low IRAK3 is associated with high superoxide dismutase (SOD)-2, a mitochondrial oxidative stress marker [24] (Fig. 5.1). Activated macrophages secrete myeloperoxidase (MPO) and NADPH oxidase (NOX), oxidizing LDL. Ox-LDL damages the endothelium, closing a vicious circle [26–30]. Macrophages express scavenger receptors such as scavenger receptor A (SR-A), scavenger receptor BI (SR-B1 or SCARB1), CD36, and lectin-like oxidized low-density lipoprotein receptor-1 (LOX-1) [31–33]. Uptake of ox-LDL via these scavenger receptors is not harmful if levels of ATP-binding cassette transporters ABCA1 and ABCG1 are adequate. Then macrophages can transfer the surplus of cholesterol to HDL that facilitates further transport from the arterial wall to the liver, ultimately leading to bile release. Suppose this reverse cholesterol transport is not adequate. In that case, excess lipid accumulation leads to foam cell formation, ultimately leading to cell burst exposing extracellular debris that causes microthrombi,

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Fig. 5.1 Non-coding RNAs in endothelial injury, inflammation, and apoptosis. ECs prefer not to maximize energy (ATP) production by shunting all glucose they take up into oxidative phosphorylation (OXPHOS) but rely on glycolysis instead of OXPHOS. This shift results in a low-level release of mitochondrial reactive oxygen species (ROS), enough to enhance EC migration and sprouting, ROS inducing VEGF induced by the hypoxia-inducible factor (HIF)-1α. VEGF increases glycolysis by increasing PFKFB3 and FGF. VEGF also induces GLUT1, increasing glucose uptake. Shear stress and chemical stress caused by high glucose, ox-LDL, and ANG II initiate atherosclerosis. These stresses impair Wnt/PI3K/AKT/NOS signaling and cause endothelial dysfunction, mediated by the increase of lncRNA ZEB-AS1 and the decrease of MALAT1, subsequently increasing miR-155 and miR-200c. High levels of miR-130a and circ-0068087 by silencing miR-197 may prevent this. Decreased PI3K/AKT signaling reduces insulin sensitivity, involving miR-7, associated with cell death. The repair of endothelium depends on EC progenitor attraction to the injury site and EC differentiation and proliferation. MiR-9, miR-21, miR-29, and XIST promote repair. In contrast, the increase of H19 and the decrease of MALAT1 and MEG3 impairs this. EC proliferation and angiogenesis maintain O2 supply into the growing atherosclerotic plaque. The increase

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 of let-7a, miR-9, miR-17, miR-21, miR-27b, miR-132, miR-210, lncRNA-ATB, silencing miR195, MIAT, and SNHG12, silencing miR-150, and XIST and PVT1, silencing miR-26b, and the decrease of miR-221–222 in late lesions induce angiogenesis. The increase of miR-16, miR-34a, miR-92, miR-221–222 in early atherosclerotic plaques, miR-223, miR-424, and miR-615-5p blocks angiogenesis. The decrease of miR-126 and MANTIS further inhibits angiogenesis. Angiogenesis may thus allow repair of the endothelium. However, angiogenesis may be harmful because it facilitates the infiltration and accumulation of inflammatory cells. They release pro-angiogenic factors, such as VEGF, hepatocyte growth factor (HGF), fibroblast growth factor (FGF), tumor necrosis factor (TNF)-α, and interleukin (IL)-8. However, angiogenesis also facilitates the infiltration of inflammatory cells. High levels of miR-17a and miR-20a and low levels of NEXN-AS1 facilitate the recruitment of monocytes by increasing the expression of ICAM-1, VCAM-1, and MCP-1, which may be blocked by LINC00341. MiR-21 and MiR-424 and miR-503 induce the differentiation of infiltrated monocytes to M2 macrophages by lowering miR-9, exacerbated by the decrease of miR-223. ANRIL may, however, prevent the decrease of miR-9. Activation of macrophages in the vascular wall is associated with rapid changes in the expression of numerous inflammationrelated genes to undergo polarization from the M2 towards the M1 phenotype. High levels of let-7e, miR-9, miR-29b-1-5p, miR-34a, miR-155, HOTAIR, silencing miR-330-5p, TUG1, silencing miR133, and ZFAS1 induce M1 macrophage polarization and inflammation. The decrease of let-7d, inhibited by LIN28, miR-10a, miR-124a, miR-126, miR-132, miR-150, miR-223, and MALAT1, exacerbates M1 macrophage polarization and inflammation. Let7-c-1-3p, miR-125b, miR-146a, and miR-181a inhibit M1 macrophage polarization. Activated macrophages release oxidative enzymes such as MPO and NOX resulting in oxidation of infiltrated LDL producing ox-LDL. Activated macrophages express scavenger receptors SR-A, SR-B1, CD36, and LOX-1, through which they take up ox-LDL leading to intracellular lipid accumulation in foam cells. Ox-LDL induces LOX-1, thereby inducing miR-146a that represses inflammation. The decrease of NEAT induces CD36 and foam cells. Usually, ABCA1 and ABCG1 offload the excess of cholesterol by mediating the reverse cholesterol transport to the liver, thereby neutralizing ox-LDL’s hazardous effects. The increase of miR-9, miR-378, and ZFAS1 and the decrease of lncRNAs HOXC-AS1 block the reverse cholesterol transport. However, this inhibition may be prevented by let-7 g, which silences miR-33 and by lncRNA CDKN2B-AS1. Impaired reverse cholesterol transport and unregulated lipid accumulation covert macrophages to foam cells, which ultimately burst, exposing extracellular debris that induces microthrombi formation, possibly due to a decrease of miR-181b, leading to even more inflammation. Monocytes may also differentiate into DCs. DC differentiation occurs in association with impaired PI3K/AKT/ERK signaling and an increase of let-7c and miR-17, miR-20a, and miR-106a. Activated DCs release IFN-γ that induces M2 to M1 polarization and secretion of inflammatory cytokines, inducing apoptosis of ECs. Microvesicles secreted by DCs deliver miR-155 to enhance M1 macrophage polarization and inflammation. However, miR-146a and MALAT1 may block miR-155. IL12 and IL18 released by M1 macrophages induce a shift from anti-inflammatory Treg and Th2 to inflammatory Th1 and Th17 cells. MiR-146a increases inflammatory Th1 cells, while the lack of miR-146a and the increase of miR-155 and CASC11 promotes Th17 cell differentiation. High levels of miR-21 may decrease Tregs, but let-7 g may block this decrease by silencing miR-33. NEAT1 prevents the decrease of Th2 cells. Th1 and Th17 cells activate DCs, but T-cell derived extracellular vesicles enriched in miR-150-5p and miR-142-3p may block this. Inflammatory cytokines induce cell senescence and death in ECs and macrophages involving the increase of miR-34a, miR-124a, miR-155, GAS5, H19, silencing let-7b, and TUG1, silencing mir-125, and the decrease of miR-126. MiR-21, miR-130a, and MIAT by sponging miR-150 and miR-181b, may prevent apoptosis. Increased non-coding RNAs are in red, decreased in green

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which exacerbate inflammatory cells’ infiltration. Scavenger receptors are, however, not only present at the surface of macrophages but also on the surface of ECs. For example, the scavenger receptor class F member 1 cooperates with TLRs to trigger inflammatory innate immune responses [34] (Fig. 5.1). The activation of monocytes/macrophages in the vessel wall initiates the innate immune response. Specific adaptive responses mediated by T and B cells follow this innate response [35, 36]. The presence of auto-antibodies against ox-LDL in the lesions of atherosclerotic humans and animal models provided initial evidence of the involvement of adaptive immunity in the development of atherosclerosis [37–40]. As in other inflamed tissues, Th1 cells exceed the number of Th2 cells in atherosclerotic plaques [41, 42]. Th1-skewing, dependent on T-box transcription factor 21 (TBX21 or TBET), is accomplished by IL12 and IL18, produced by activated macrophages and interaction with dendritic cells (DCs), leading to interferon (IFN)-γ secretion by Th1 cells [43–46]. TBET deficiency reduces atherosclerosis by increasing Th2 cytokines, IL4, IL5, and IL10 [46–48]. IL4 produced by Th2 cells counteracts the production of IFN-γ. Also, Treg cells produce IL4, IL5, IL10, and IL13 [49, 50]. Natural Treg cells are unique because they do not require antigen exposure to gain their immunosuppressive activities. In contrast, inducible Treg cells derive from effector T-cell populations in the periphery only after exposure to antigen. They are also CD4+ CD25+ cells, which do not require forkhead box P3 to be functional (64). Among them, Treg1 cells secrete IL10, while Th3 cells secrete TGF-β. Natural and inducible Treg cells compete with other T cell subsets for antigen complexes and the major histocompatibility complex class II, preventing autoimmunity. They increase the inhibitory cytotoxic T-lymphocyte-associated protein 4 by down-regulating costimulatory CD80/CD86 and through direct cytotoxic and inhibitory effects on other effector cells [51]. Other inflammatory T cells are Th17 cells, which secrete IL17 and IL22. The IL17 family of cytokines consists of six members—IL17A, IL17B, IL17C, IL17D, IL17E, and IL17F. All IL17 interleukins activate NFκB, mitogen-activated protein kinase (MAPK or ERK)-1 and MAPK2, CCAAT enhancer-binding protein (c/EBP)-β, and c/EBP-δ in target macrophages resulting in secretion of inflammatory TNF-α, IL-1β, and IFN-γ [52–57] (Fig. 5.1). NKT cells are a unique subset of T cells with NK-specific (NK1.1 and Ly49) and T-cell-specific (CD4) surface markers. These cells recognize antigen in the context of CD1d, not MHC, expressed on antigen-presenting cells. Their ligands are glycolipid antigens. They are abundant in the liver and most lymphoid tissues. The invariant NKT cells secrete large amounts of anti-inflammatory cytokines IL4, IL10, and IL13 and pro-inflammatory IFN-γ [58]. They are autoregulatory cells capable of inducing tolerance by communicating with Treg cells [59]. Although they may play a tolerogenic role in some diseases like type 1 diabetes, they are likely to be proatherogenic [60–65] (Fig. 5.1).

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5.1.1 Non-coding RNAs in Endothelial Injury, Inflammation, and Apoptosis 5.1.1.1

Endothelial Cells

Zinc finger E-box-binding homeobox two antisense RNA 1 (ZEB1-AS1) mediates ox-LDL-induced EC injury. Ox-LDL sequesters p53 from binding to the ZEB-AS1 promoter, thereby up-regulating ZEB-AS1 and the nucleotide-binding oligomerization domain 2 (NOD2) through recruitment of leucine-rich pentatricopeptide repeat motif-containing protein to stabilize NOD2 mRNA [66]. The metastasis-associated lung adenocarcinoma transcript one lncRNA (MALAT1) is lower in human plaques than in normal arteries. It is also lower in symptomatic than in asymptomatic plaques. Low MALAT1 is associated with endothelial dysfunction and loss of protection against ox-LDL-induced cytokine release and apoptosis via up-regulation of miR155 that is increased by hypertension and inflammation [67–73]. Also, the decrease of MALAT1 and the up-regulation of miR-200c-3p is associated with oxygen–glucose deprivation [74.] In contrast, miR-130a activates PI3K/AKT/eNOS signaling and thereby retains EC viability and NO release, while it decreases inflammatory cytokine levels and cell apoptosis [75, 76]. The increase of circ-RNA circ_0068087 in diabetes protects against high glucose-induced endothelial dysfunction and inflammation by silencing miR-197, thereby suppressing the TLR4/NFκB/ NLR family pyrin domain containing 3 (NLRP3) inflammasome pathway [77]. Endothelial dysfunction is associated with decreased insulin sensitivity, involving miR-7 [14] (Fig. 5.1). The repair of endothelium requires the attraction of endothelial progenitor cells (EPC s) and EC proliferation. MiR-9 promotes migration and invasion of EPCs [78]. Resveratrol can reduce neointimal formation in a vascular graft model by promoting progenitor cells’ differentiation to endothelial cells through a miR-21/AKT/β-catenin dependent mechanism [79]. MiR-29 targets the teneleven translocation-1 (TET1), which converts 5-methylcytosine (5mC) to 5hydroxymethycytosine (5hmC), contributing to early differentiation of stem cells [80]. X inactive specific transcript (XIST) stimulates hypoxia-induced EC proliferation [81]. In contrast, the H19 imprinted maternally expressed transcript lncRNA (H19) decreases EC proliferation and increases apoptosis by up-regulating MAPKs and NFkB [82, 83]. Ablation of MALAT1 and maternally expressed 3 lncRNA (MEG3), particularly in type 2 diabetes, is associated with reduced EC proliferation [84, 85]. Several miRs correlate positively with angiogenesis. Among them: let-7a, high in patients with hypertension, atherosclerosis, and cardiac hypertrophy and fibrosis [86]; miR-9, high in patients with hyperglycemia [87]; miR-21 up-regulated by ANG II [88]; miR-27b induced by shear stress [89]; miR-132, high in patients with heart failure [90]; and miR-210, increased in patients with aortic stenosis [91]. Two members of the miR-17–92 cluster have opposite effects on angiogenesis. MiR-17 potentiates angiogenesis by facilitating the expression of HIF-1α and VEGF, which regulate each other. However, miR-92 blocks angiogenesis by silencing

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integrin subunit alpha 5 [92–95]. The increase of myocardial infarction associated transcript (MIAT) in diabetes partially abolished the miR-150-5p–mediated repression on VEGF [96]. Overexpression of small nucleolar RNA host gene 12 (SNHG12) improved the recovery of neurological function by targeting miR-150, increasing vascular density, and VEGF expression in the infarct border zone of mice [97]. The increase of miR-221/222 in initial atherosclerotic plaques inhibits angiogenesis [98]. However, in advanced plaques, chronic inflammation downregulates miR-221/222 in ECs and decreases the growth arrest-specific homeobox by decreased repression of zinc finger E-box binding homeobox (ZEB)-2, resulting in increased angiogenesis [75, 99–101]. The long non-coding RNA activated by TGF-β (LncRNA-ATB) induces angiogenesis by sponging miR-195, thereby de-repressing PI3K/AKT/MAPK signaling [102]. PVT1 oncogene (PVT1) binds and degrades miR-26b and promotes angiogenesis [103] (Fig. 5.1). Functionally, miR-16 and miR-424 inhibit angiogenesis via blocking VEGF [104–107]. MiR-34a inhibits angiogenesis by targeting NOTCH and VEGF [108, 109]. Metformin, or the inhibition of miR-34a with an anti-miR-34a, increases the expression of sirtuin1 and attenuates the impairment in angiogenesis in high glucose-exposed endothelial cells [110]. Recombinant HDL increased miR-223 and suppressed the initial induction of angiogenesis post-ischemia when capillary and arteriolar density allowed adequate perfusion [111]. The increase of miR-615-5p in response to vascular tissue injury inhibits VEGF/AKT/eNOS signaling [112]. The decrease of miR-126 and MANTIS (LOC107985770) inhibits angiogenic sprouting and alignment of ECs in response to shear stress and inflammation [75, 93, 113–118] (Fig. 5.1).

5.1.1.2

Monocytes and Macrophages

Endothelial injury is associated with increased infiltration of monocytes, which differentiate into macrophages. MiR-17a and miR-20a induce hypoxia-induced infiltration of monocytes and activation of macrophages [119–121]. Repression of nexilin F-actin binding protein antisense RNA 1 (NEXN)-AS1 and NEXN increase NFκB activity associated with the up-regulation of monocyte-specific adhesion molecules and inflammatory cytokines by ECs [122]. In contrast, the athero-protective pulsatile shear flow induces the spectrin-repeat containing nuclear envelope family member 3 (LINC00341), which represses VCAM1 [123] (Fig. 5.1). MiR-21 enriched exosomes produced by IL-1β-primed mesenchymal cells induced M2 macrophage polarization [124]. MiR-424 and miR-503 synergistically induce the integrins (ITG)-B2, ITG-7, and ITGAL (or Cd11a), and endoglin (ENG or Cd105), and promote differentiation of monocytes to M2 macrophages. They also induce cyclin (CCN)-E1, CCND1, CCND3, and cyclin-dependent kinase (CDK)-6 [107, 125, 126]. They act through the down-regulation of miR-9 that blocks monocyte differentiation, but the silencing of miR-9 may be overturned by cyclin-dependent kinase inhibitor 2B (CDKN2B) antisense RNA 1 (ANRIL) [127–129] (Fig. 5.1).

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Specifically, miR-155-3p, miR-155-5p, miR-147-3p and miR-9-5p, all have significantly higher expression levels in M1 cells, whereas miR-27a-5p, let-7c-13p, miR-23a-5p and miR-23b-5p, all have higher expression levels in M2 cells. Besides, two sub-clusters of M1 macrophage-specific miRs can be discerned. The first sub-cluster 1 includes early response miRs like miR-29b-1-5p, miR-222-5p, miR-1931, miR-3473b, miR-3473e, and miR-5128, all of which are tightly correlated. The late response miRs let-7e-3p, miR-9-5p/3p, miR-125a-3p, miR-147-5p/3p, miR-155-3p, and let-7e-3p belong to the second sub-cluster [130]. Ox-LDL significantly up-regulates let-7e in ECs. Let-7e promotes NFκB activation and translocation to the nucleus by inhibiting its target gene IκBβ and increasing inflammatory and adhesion molecules’ expression. The long intergenic non-protein coding RNA 1826 (LINC01826 or Lnc-MKI67IP-3) may sponge let-7e, thereby suppressing its pro-inflammatory effects [131]. MiR-9 enhances M1 macrophage polarization by inducing peroxisome proliferator-activated receptor (PPAR)-δ [132]. MiR-34a silences p53-small interfering RNA that attenuates high-glucose-induced endothelial inflammation and oxidative stress by repressing sirtuin (SIRT)-1 [133]. OxLDL induces toll-like receptor adaptor molecule one that up-regulates miR-155 in macrophages, associated with activation of the MAPK1/2 and suppressor of cytokine signaling 1 (SOCS1) / signal transducing and activator of transcription (STAT)-3 /NFκB signaling and elevation of IL6 and TNF-α levels [134]. Homeobox (HOX) transcript antisense lncRNA (HOTAIR), higher in obesity and type 2 diabetes, stimulates oxidative stress and inflammation in macrophages by silencing miR-330-5p [135]. Ox-LDL-induced taurine up-regulated 1 (TUG1) enhances inflammation and apoptosis by silencing miR-133, increasing fibroblast growth factor (FGF) [136]. The silencing of let-7d by lin-28 homolog (LIN28)-b in diabetic human plaques activates NFκB [137]. The decrease of miR-10a in patients with kidney disease and miR-132 in patients with metabolic syndrome induces inflammation, particularly by IL8 [138–149]. Repression of Krüppel-like zinc finger transcription factor (KLF)2 in macrophages leads to a decrease of miR-124a and miR-150 associated with augmented expression of inflammatory mediators C–C motif chemokine ligand 2 (CCL2 or MCP1) and C-X-C motif chemokine ligand 1 [150]. The decrease of miR-124 also induces KLF6 that restrains miR-223, thereby enhancing the secretion of IL-1β by macrophages [151, 152]. Decrease of mir-126 by TNF-α and ROS in hyperglycemia is associated with inflammation by de-repression of high-mobility group box 1 [153, 154]. Low MALAT1 is associated with high IFN-γ and TNF-α and accelerated atherosclerosis [155] (Fig. 5.1). The increase of miR-125b in patients with type 2 diabetes and stroke protects against M1 macrophage polarization [156–158]. ApoE in HDL induces miR-146a in monocytes and macrophages, thereby inhibiting pro-inflammatory responses [159]. Further, inhibition of inflammation by miR-146a suppresses ox-LDL accumulation and foam cell formation [160]. However, aging lowers miR-146a causing pronounced inflammation [161]. MiR-181a-5p and miR-181a-3p cooperatively recede inflammation by blocking the NFκB [162] (Fig. 5.1).

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5.1.1.3

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Foam Cells

Ox-LDL by up-regulating LOX-1 induces miR-146a via the JNK and NF-κB pathways in macrophages, preventing inflammation [163]. The decrease of nuclear paraspeckle assembly transcript (NEAT1) increases the expression of CD36 and lipid accumulation in foam cells [164]. The increase of miR-9-5p inhibits expression of ABCA1, thereby decreasing reverse cholesterol transport [165]. MiR-378 directly targets ABCG1, and loss of miR-378 suppression resulted in increased cholesterol efflux and atheroprotection in mice [166]. ZNFX1 antisense RNA 1 (ZFAS1) induces inflammation and reduces cholesterol efflux in atherosclerotic plaques [167]. Reduction of the lincRNA HOXC cluster antisense RNA 1 (HOXC-AS1) in atherosclerotic plaques increases cholesterol accumulation by ox-LDL [168]. In contrast, let-7 g prevents foam cell formation by silencing miR-33 that otherwise would inhibit the expression of ABCA1 and ABCG1 [169–171]. LncRNA CDKN2B antisense RNA 1 (CDKN2B-AS1) increases cholesterol efflux and reduces lipid accumulation by silencing ADAM metallopeptidase domain 10 (ADAM10) [172]. Foam cells excessively accumulate lipids leading to cell burst and release of thrombogenic particles. Reduced levels of miR-181b in vascular cells increase TF associated with thrombogenicity associated with endothelial injury [173] (Fig. 5.1).

5.1.1.4

Dendritic and T Cells

Let-7c is essential for ox-LDL-mediated monocytes’ differentiation to DCs and DC maturation, cytokine production, and subsequent T-cell proliferation [174]. MiR-17, miR-20a, and miR-106a inhibit monocytic differentiation to macrophages but induce maturation of DCs [107, 175, 176]. DCs secrete exosomes that contain miR-155 that enhances and miR-146a that reduces inflammatory gene expression [177]. MALAT1 may block this action of miR-155 [178]. MiR-21, significantly up-regulated in acute myocardial infarction patients, reduces the number of circulating Treg cells through a TGF-β1 / SMAD family member (SMAD)-independent signaling pathway in mononuclear cells [179]. Let7, silencing miR-33, retains the Treg and M2 macrophage phenotype [180]. NEAT targets STAT6 for ubiquitination and elevates Th2 cytokines IL4, IL5, and IL13 by regulating the enhancer of zeste 2 polycomb repressive complex 2 (EZH2) / itchy E3 ubiquitin protein ligase (ITCH) axis [181]. MiR-146a induces Th1 differentiation by enhancing T-bet in mononuclear cells [159, 182, 183]. However, miR-146a deficiency in CD4 cells enhances IL21 and induces Th17 differentiation, further enhanced by the inflammation-related miR-155 [134, 184–186]. The down-regulation of the cancer susceptibility 11 lncRNA (CASC11) increases TGF-β, inducing IL17 secretion by inflammatory Th17 cells, and increasing IL9 [187–189]. T-cell derived extracellular vesicles enriched in miR-150-5p and miR-142-3p may block DC activation [190] (Fig. 5.1).

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5 Non-coding RNAs Related to Atherosclerosis

Apoptosis of Endothelial Cells and Plaque Destabilization

Atherosclerotic plaque rupture and subsequent acute events such as acute myocardial infarction and stroke are due to uncontrolled apoptosis in ECs, macrophages, and VSMCs [191]. Apoptosis in ECs, induced by inflammatory cytokines and ox-LDL, leads to endothelial erosion. Apoptosis in VSMCs leads to thinning of fibrous cap and plaque instability [187, 192, 193]. MiR-34a enhances oxidative stress-associated EC apoptosis [194, 195]. MiR-124a, increased in smokers susceptible to atherosclerosis, induces EC apoptosis by blocking PI3K/AKT signaling and promoting ROS release [196]. Transfer of miR-155 from VSMCs to ECs causes endothelial cell death [197]. The growth arrest-specific five lncRNA (GAS5)-enriched microvesicles secreted by macrophages induce apoptosis of ECs and macrophages [198]. H19 increases apoptosis by silencing let-7b. Naturally, let-7b inhibits the ox-LDL-induced EC apoptosis, NO deficiency, and ROS secretion [82, 137]. The decrease of mir-125 and the increase of taurine up-regulated 1 (TUG1) promotes apoptosis [142, 199–203]. The decrease of miR-126 in response to tissue damage may also decrease chemokine CXCL-12 and its receptor CXCR-4, which counteract apoptosis and recruit endothelial progenitor cells [204]. MiR-21, mechanistically increased by shear stress, protects ECs cells against apoptosis induced by ROS and inflammation by increasing eNOS and NO production and silencing the programmed cell death 4 (PDCD4) gene [205–210]. MiR-181 enhances TNF-α-induced cell death, while MIAT decreases apoptosis by sponging of miR-181b [211, 212]. MIAT also sponges miR-150 that promotes plaque growth via increased macrophage infiltration and lipid accumulation and destabilizes plaques by increasing EC apoptotic cell death mediated by ox-LDL [213–215].(Fig. 5.1).

5.2 Fibroproliferative Remodeling and Plaque Destabilization Atherosclerotic plaque formation also results from VSMC fibroproliferative remodeling in the vascular wall. The recruitment of progenitor cells to the blood vessel wall and the proliferation of VSMCs is regulated by platelet-derived growth factor (PDGF)-B, functioning as dimer PDGF-BB secreted by ECs [216]. Insulin-like growth factor 1 (IGF1) enhances VSMC by acting synergistically with PDGF-BB [217]. TGF-β induces VSMC differentiation involving SMAD2, 3, and 4. SMADs bind directly to the regulatory elements of myocardin, one of the central transcriptional regulators of the VSMC lineage. Differentiated VSMCs express various SMCspecific contractile and contractile-associated proteins, including SM myosin heavy chain, SM22, calponin, and SM α-actin [218, 219]. The effects of TGF-β on VSMCspecific gene expression are mediated via NOX4, suggesting that ROS regulates SMC-specific gene transcription [220] (Fig. 5.2). When shear stress and vessel damage occur, mature VSMCs de-differentiate associated with decreased VSMC differentiation marker gene expression and increased

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Fig. 5.2 Non-coding RNAs in fibroproliferative remodeling and plaque destabilization. Atherosclerotic plaque formation also results from VSMC fibroproliferative remodeling in the vascular wall. PDGF secreted by ECs attracts progenitor cells that differentiate to VSMCs. PDGF and IGF1 induce VSMC proliferation. However, miR-34a enriched in microvesicles secreted by VSMCs in atherosclerotic plaques induces senescence in progenitor cells. MiR-143–145, induced by TGF-β in early lesions, acts as communication molecules between VSMCs and ECs to modulate the angiogenic and vessel stabilization properties of ECs, which are impaired by a decrease of GAS5. The increase of miR-21, miR-92a, and miR-378a-5p, and the decrease of miR-26a, silenced by UCA1, miR-124a, silenced by circWDR77, miR-214, silenced by LINC00341, miR-370, silenced by circCHFR, and miR-544a, silenced by lncRNA LEF1-AS1, induce VSMC proliferation. In contrast, miR-638 and miR-663 inhibit proliferation. Shear stress and inflammation up-regulate miR-26a, which may be blocked by UCA1, miR-146a, miR-155, and miR-221–222. They dedifferentiate contractile to proliferative VSMCs. Cholesterol loading in VSMCs converts VSMCs to macrophage-like cells driven by the decrease of miR-143–145. TF induces macrophage-like cells to secrete MIF that inhibits VSMC migration and changes ECM composition deposited by VSMCs, characterized by decreased laminin and collagen. The decrease of miR-124 exacerbates this, while miR-143–145 prevents it. LincRNA-p21 and PVT1 cause VSMC senescence and death, but miR21, miR-25, MIAT, silencing miR-150 and miR-181b, and ANRIL, silencing miR-181a may inhibit this. VSMC-derived macrophage-like cells also have reduced phagocytic capacity compared with activated peritoneal macrophages. Reduced phagocytosis, for example, of apoptotic cells, is evident in advanced atherosclerosis and directly promotes the formation of the ‘necrotic’ core of advanced plaques, inhibited by miR-29. Apoptosis is also associated with the calcification of plaques due to the increase of miR-221–222. Increased non-coding RNAs are in red, decreased in green

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proliferation, migration, and matrix synthesis [221]. VSMC (de-)differentiation depends on the matrix composition whereby fibronectin supports SMC proliferation, while collagen (COL)- IV and laminin promote VSMC differentiation. Matrix degradation and re-expression of fibronectin and other growth-promoting matrix components such as COLI also occurs following vessel injury and likely contribute to VSMC phenotypic modulation [222, 223]. Pro-inflammatory markers contribute to this de-differentiation leading to extensive accumulation of immature VSMCs that fail to re-differentiate [224]. Especially, macrophage migration inhibitory factor (MIF) induced by tissue factor (TF) causes de-differentiation and migration of immature VSMCs [225, 226] (Fig. 5.2). Also, VSMCs switch to macrophage-like cells driven by lipid accumulation. However, in contrast to classical macrophages, VSMC-derived macrophage-like cells lack phagocytic capacity, promoting necrotic core formation that exacerbates inflammation [227, 228] (Fig. 5.2). The shoulder area of a plaque is most vulnerable to rupture because it contains fewer VSMCs and more macrophages. This co-localization suggests that preferentially macrophages induce VSMC apoptosis through death-ligand/death receptor interactions [229–231]. Apoptotic VSMCs show a thickened basal lamina surrounding the cytoplasmic remnants of the VSMC. Inefficient clearance of apoptotic VSMCs results in secondary necrosis and subsequent inflammation [232]. Metalloproteinases (MMPs), secreted by inflammatory cells, degrade the fibrous cap and increase plaque’s vulnerability [187]. Another form of cell death is autophagy. Autophagy is the lysosome-dependent degradation of cytoplasm and damaged cell organelles like mitochondria, ER, and peroxisomes [232–234]. Various stimuli and stressors, including ROS, lipid species, and inflammatory cytokines associated with metabolic stress, induce autophagy. Although autophagy is a survival mechanism, excessive autophagic activity destructs ER and mitochondria, ultimately causing cell death [235, 236] (Fig. 5.2). VSMC apoptosis also induces calcification of plaques [237]. Calcification may depend on systemic factors, including hyperlipidemia, inflammation, and type 2 diabetes. Local VSMCs and circulating hematopoietic stem cells calcify. Matrix vesicles derived from macrophages that undergo apoptosis serve as a nidus for calcification [238]. Fragmented calcification spreads into the surrounding collagen-rich extracellular matrix (ECM) in fibrocalcific plaques. The calcified sheets may break into nodules with fibrin deposition associated with thrombosis [239]. Therefore, intraplaque calcification may not be a stabilizing factor per se [240, 241]. While extensive calcifications may stabilize the plaque, small microcalcifications may cause plaque rupture. These microcalcifications are derived from matrix vesicles enriched in calcium-binding proteins [242]. Finally, the total amount of calcium does not seem related to plaque vulnerability, but there was an association between hydroxyapatite content and plaque instability [243] (Fig. 5.2).

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5.2.1 Non-coding RNAs in Fibroproliferative Remodeling and Plaque Destabilization PDGF secreted by ECs attracts progenitor cells that differentiate to VSMCS. However, miR-34a enriched in microvesicles secreted by VSMCs induces stem cell senescence by silencing SIRT1 [244]. MiR-143–145 induced by TGF-β acts as communication molecules between VSMCs and ECs to modulate the angiogenic and vessel stabilization properties of ECs [245]. However, GAS5 knockdown aggravates hypertension-induced microvascular dysfunction by inhibiting EC and VSMC cross-talk [246]. MiR-21, higher in type 2 diabetes and related to systemic inflammation, stimulates VSMC proliferation by increasing MAPK7 and KRAS proto-oncogene GTPase (KRAS) signaling [247–253]. Up-regulation of miR-92a inhibits KLF4 expression, thereby promoting proliferation and migration of VSMCs and inhibiting differentiation of VSMCs to macrophage-like cells. PDGF-BB-induced miR-378a-5p promotes VSMC proliferation and migration by targeting the CDK1/p21 signaling pathway [254–256]. The urothelial cancer-associated 1 (UCA1) sponges miR-26a and thereby increases VSMC proliferation and migration [257]. The circular RNA derived from WD repeat domain 77 (circWDR77) induces VSMC proliferation and migration via targeting miR-124/FGF2 [258]. The lncRNA derived from spectrin repeat-containing nuclear envelope family member 3 (LINC00341) promotes VSMC proliferation and migration via a miR-214/FOXO4 feedback loop [259]. The circ-RNA derived from the checkpoint with forkhead and ring finger domains (circCHFR) facilitates the proliferation and migration of VSMCs by acting as a sponge of miR-370, thereby increasing the expression of the forkhead box O1 (FOXO1) that binds the promoter region of CCND1 mRNA [260]. LEF1-AS1 silences miR-544a, thereby stimulating the phosphatase and tensin homolog (PTEN) pathway, resulting in enhanced VSMC proliferation and migration [261]. MiR-638, induced by PDGF-BB, inhibits VSMC proliferation, and migration by targeting the orphan nuclear receptor NOR1 [262]. MiR-663, induced by a shear stress-associated inflammatory response in ECs, inhibits PDGF-induced VSMC proliferation and migration and increases VSMC differentiation [263]. MiR-424 may inhibit VSMC proliferation, but this inhibition is overwhelmed by inflammation in pathological situations such as injury-induced restenosis [264]. MiR-26a, miR-146a, and miR-155 de-differentiate contractile to synthetic VSMCs, but UCA1 may block this action of miR-26a [257, 265–268]. MiR-221–222 also de-differentiate contractile VSMCs and induce their calcification [98, 269, 270] (Fig. 5.2). The decrease of miR-124 is associated with a decrease of collagen, shifting contractile to proliferating VSMCS [271]. MiR-145 counteracts this shift [204, 272]. Cholesterol loading in VSMCs downregulates miR-143/145 and the master VSMC differentiation transcription factor myocardin, thereby converting VSMCs to dysfunctional macrophage-like cells [273].

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Asthma-induced IgE activates the tumor protein p53 pathway corepressor 1 lncRNA (lincRNA-p21) pathway to induce VSMC senescence [274]. The ANG II-induced PVT1 up-regulates matrix metalloproteinase (MMP)-2 and MMP-9 and represses TIMP metallopeptidase inhibitor 1 (TIMP1), facilitating VSMC apoptosis and ECM degradation. It promotes a switch from the contractile to synthetic VSMC phenotype [275]. In contrast, miR-21, miR-25, and MIAT silencing miR-150 and miR-181 protect VSMCs against apoptosis [276]. ANRIL in atherosclerotic plaques protects VSMC from senescence, possibly by downregulating miR-181a and upregulating SIRT1 [277, 278]. MiR-29 silences COL-1A and COL-3A, reducing lesion size, enhancing fibrous cap thickness, and reducing necrotic zones [279] (Fig. 5.2).

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Chapter 6

Non-coding RNAs in Cardiomyopathy and Heart Failure

Abstract Cardiac hypertrophy is the thickening of the myocardium, particularly the left ventricle. Cardiac hypertrophy may occur physiologically because of athletic training and is usually a uniform increase in ventricular wall thickness. At the early stage of pathological hypertrophy, the increased size of cardiomyocytes is initially a compensatory mechanism. However, sustained hypertrophy may lead to maladaptive cardiac remodeling, including fibrosis, inflammation, and cell death. This remodeling increases the risk for dilated cardiomyopathy, arrhythmia, heart failure, and even sudden death. Imbalance in let-7, miR-1, miR-7, miR-9, miR-17-92, miR18, miR-21, miR-22, miR-25, miR-26a, miR-29, miR-30a, miR-31, miR-33, miR34a, miR-92, miR-98, miR-101a, miR-106a, miR-124, miR-125, miR-130, miR133, miR-143-145, miR-146a, miR-150, miR-155, miR-181, miR-199, miR-208, miR-214, miR-221-222, miR-223, miR-433, miR-455 and miR-489, and lncRNAs CHFR, HOTAIR, H19, LINC-ROR, MALAT1, MEG3, MIAT, MIRT1, NEAT1, TINCR, TUG1, UCA1, XIST and WISPER, and circ-RNAs ANRIL are associated with cardiomyopathy. The let-7 family and miR-1, miR-7, miR-9, miR-17, miR-21, miR-26a/b, miR-29, miR-30a, miR-34a, miR-124, miR-130, miR-133, miR-143145, miR-146a, miR-150, miR-155, miR-181 family, miR-221-222, miR-223, miR378 and miR-455, and lncRNAs GAS5, HOTAIR, H19, lincRNA-p21, LINC-ROR, MALAT1, MEG3, MIAT, NEAT1, TUG1 and UCA1, and circ-RNAs ANRIL and PVT1 link metabolic to cardiovascular diseases.

6.1 Mechanisms in Cardiomyopathy and Heart Failure A third of the cells in the heart are cardiomyocytes (CMs). The heart also contains stem cells, endothelial cells (ECs), immune-system-related macrophages, T cells, fibroblasts (FBs), smooth muscle cells (SMCs), and sympathetic and parasympathetic neuronal cells. A tight balance between these cell types is needed to maintain the integrity of the heart [1]. Pathological stimuli such as aging, myocardial injury, pressure overload, volume overload, neurohormonal activation, and inflammation cause cardiac remodeling [2, 3] (Fig. 6.1).

Illustrations by Pieterjan Ginckels, Faculty of Architecture, KU Leuven, Ghent, Belgium. © The Author(s), under exclusive license to Springer Nature Switzerland AG 2021 P. Holvoet, Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer, https://doi.org/10.1007/978-3-030-68844-8_6

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Fig. 6.1 Non-coding RNAs and cardiometabolic risk components in the development of cardiomyopathy. Silencing of miR-1 and miR-133 impairs the differentiation of stem cells to CMs. M1 macrophages secrete ANG II, IGF1, IL6, IFN-γ, PDGF, and VEGF, which induce CMs to undergo hypertrophy, involving Ras/STAT3 signaling. High levels of let-7, miR-9, miR-21, miR-25, repressing MALAT1, miR-29, miR-106a, miR-146a, miR-208, miR-223, and NEAT1, silencing miR-378, induce cardiac hypertrophy. Low levels of miR-1, sponged by UCA1, miR92b-3p, miR-98, miR-133, sponged by LINC-ROR and XIST, miR-150, silenced by MIAT, and miR-199 exacerbate hypertrophy. MiR-26a, miR-214-3p, increased by a decrease of TINCR, and a decrease of let-7, silenced by H19, and miR-489 silenced by lncRNA CHFR may prevent hypertrophy. Inflammatory molecules secreted by M1 macrophages also induce activation of fibroblasts and fibrosis involving TGF-β/SMAD/Wnt signaling. Increased let-7, miR-9, miR-17, miR-21, miR25, miR-29, miR-31, miR-34a, miR-125 due to decreased MEG3, miR-130, miR-146a, miR-155, miR-433, H19, silencing miR-455, TUG1, silencing miR-29c, and WISPER are associated with cardiac fibrosis. The decrease of miR-1, miR-18a, miR-24 silenced by MIAT, miR-30a silenced by MALAT1, miR-101a, and miR-133, silenced by LINC-ROR, exacerbates fibrosis. The increase of miR-221-222 and miR-378 and the decrease of miR-223 may block fibrosis. ANG II, IGF1, TGF-β, and TNF-α secreted by M1 macrophages induce ECM remodeling and wound repair associated with increased collagen, elastin, and fibrillin. High levels of miR-17, miR-146a, miR-155, and WISPER, and low levels of miR-1, miR-24, silenced by MIAT, miR-101a, and miR-133 are associated with increased ECM deposition. MiR-26a may prevent this. Wound repair is associated with monocytes’ infiltration, induced by the decrease of miR-150. Monocytes may differentiate

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 into fibroblasts, induced by miR-21, thereby augmenting fibrosis. Monocytes also differentiate into M1 macrophages. This differentiation depends on the interaction between let-7, miR-146a, H19, and MALAT1. Increased miR-155, miR-223, and MIRT1, and decreased miR-30a and miR-133 are associated with M1 macrophage polarization and inflammation. MiR-21, miR-29, miR-181, and the decrease of miR-223 may revert inflammation. MiR-33 mediates lipid accumulation and foam cell deposition. The decrease of miR-133 is associated with an increase in inflammatory T cells. HIF-1α, VEGF, PlGF secreted by inflammatory cells cause endothelial dysfunction with impaired angiogenesis. The increase of miR-9, miR-17, miR-26a, miR-124, and miR-223 impairs angiogenesis. MiR-9 blocks the angiogenic capacity of CMs by blocking PDGF action. The increase of let7b-5p, let-7f, miR-21, miR-30b/c, miR-126, miR-130a, miR-133, miR-143, miR-221, and miR378 may restore angiogenesis. Besides, CM-derived exosomes induced by ischemia and enriched in miR-143 and miR-221 may restore angiogenesis. Inflammatory cells and injured ECs secrete ROS and DAMPS, causing cell death. MiR-181 protects against ROS and DAMPS. The increase of miR-9, miR-34a, miR-223, and ANRIL mediates cell death. The decrease of miR-1, miR-7, miR-133, and miR-873, silenced by lncRNA NRF, exacerbates cell death. However, high miR-21, NEAT1 silencing miR-34a, TUG1 silencing miR-145, miR-378, and UCA1 protect against apoptosis. Silencing of miR-17 by H19, HOTAIR, and MALAT1, silencing miR-150 and miR-181 by MIAT, and a decrease of miR-223 also prevents cell death. However, the decrease of miR-181b is associated with increased ROS. Increased non-coding RNAs are in red, decreased in green

Cardiac hypertrophy is the thickening of the myocardium, particularly the left ventricle. This thickening may occur physiologically because of athletic training and is usually a uniform increase in ventricular wall thickness. At the early stage of pathological hypertrophy, the increased size of cardiomyocytes is a compensatory mechanism. However, sustained hypertrophy may eventually lead to maladaptive cardiac remodeling, including fibrosis and inflammation. Angiotensinogen (ANG) II-induced cardiomyopathy results in part from the angiotensin II receptor type 1 (AT1R or AGTR1)-mediated Janus kinase (JAK)/signal transducing and activator of transcription (STAT)-3 signaling and STAT3-dependent activation of local Ras [4, 5]. Latent STATs reside in the cytoplasm until activated via tyrosine phosphorylation leading to their dimerization and nuclear translocation [6–8]. However, unphosphorylated STATs are also involved. Unphosphorylated STAT1 and interferon regulatory factor (IRF)-1 support transcription of proteasome subunit β9 (PSMB9 or LMP2). LMP2 is a member of the class II region of the major histocompatibility complex (MHC) induced by interferon (IFN)-γ. Unphosphorylated STAT3 is induced by and up-regulates E2F transcription factor 1 (E2F1) that controls cyclin (CCN)-D1 and CCNE expression [9–11]. Mechanical stretch locally activates myocyte AT1R signaling even through an ANG-II-independent mechanism by integrating G proteins into the cytosol [12]. In addition to the G protein GQ, AT1R stimulates several tyrosine kinases, including JAK, SRC proto-oncogene, non-receptor tyrosine kinase (SRC), and epidermal growth factor receptor (EGFR) [5, 13] (Fig. 6.1). Activated FBs called myofibroblasts are the effector cells of fibrosis. Myofibroblasts originate from quiescent tissue FBs, circulating CD34 + fibrocytes, and epithelial cells, and ECs [14, 15]. Myofibroblasts are fibroblast-like in terms of extracellular matrix (ECM) synthesis and SMC-like in terms of migration. Cross-talk between macrophages and myofibroblasts leads to their activation. ANG II activates toll-like receptor adaptor molecule 1 (TRIF or TICAM1), transforming growth

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factor (TGF)-β, insulin-like growth factor 1 (IGF1), TGF-β/SMAD family member (SMAD)signaling. This increases Wnt proteins, vascular endothelial growth factor (VEGF)-α, endothelin-1 (EDN-1), and platelet-derived growth factor (PDGF). In fibrotic conditions, there are changes in the composition and arrangement of ECM proteins, including type I and type III fibrillar collagens (COL1 and COL3) regulated by several growth factors such as ANG II, TGF-β1, IGF1, and tumor necrosis factor (TNF)-α [16–23]. Besides COL, ECM components like elastin, fibrillin, fibronectin, and proteoglycans change. Myofibroblasts modify the balance of metalloproteinases (MMPs) and TIMP metallopeptidase inhibitors (TIMPs) to promote fibrosis [16, 24]. Dynamic ECM changes activate myofibroblasts and induce inflammatory leukocytes, driving wound repair [3, 25–28]. The renin-angiotensin-aldosterone system (RAAS) is activated, increasing levels of active TGF-β1. SMCs, monocytes, and FBs are recruited, and ECM proteins are deposited [29]. Besides activated myofibroblasts, a subset of monocytes/macrophages may thus contribute to the fibrotic response [22, 30] (Fig. 6.1). The initial inflammatory response consists of the infiltration of monocytes, which differentiate into macrophages. Recruited monocytes express the chemokine receptor CCR2 and infiltrate the infarcted myocardium in response to the up-regulation of C-C motif chemokine ligand 2 (CCL2 or MCP1) [31]. This inflammatory response also augments damage-associated molecular patterns (DAMPs) [32]. DAMPs are not only secreted by activated leukocytes but also by stressed cardiomyocytes and fibroblasts [33–36]. Several DAMPs can trigger the inflammatory response and, together with mitochondrial reactive oxidant species (ROS), induce CM death [33–39] (Fig. 6.1). During the later phase of the immune response, T lymphocytes infiltrate. Cardiac T cells are primed to induce cardiac injury and remodeling and retain this memory on adoptive transfer [40–42]. Thereby, Th1 and Th17 cells increase, while Th2 and Treg cells decrease. This shift to TH1 and Th17 cells results in increased inflammatory interleukin (IL)-1β, IL6, IL-17, IL-23, and decreased anti-inflammatory IL4, IL5, IL10, and IL13 [43–46]. Treg cells’ suppressive function plays a key role in controlling both innate and adaptive immune responses through secretion of IL10 and TGF-β and attenuation of interstitial fibrosis, myocardial MMP2 activity, and cardiac apoptosis [47–50] (Fig. 6.1). During the development of cardiac hypertrophy, capillary ECs undergo a phenotypic change favoring angiogenesis. The latter is needed to support the contractile function of the myocardium [51, 52]. The myocardium secretes VEGF and placental growth factor (PlGF), which coordinates vascular growth to meet demands for blood supply to sustain the increase in myocardial mass and performance. VEGF mainly interacts with the VEGF receptor 1 (VEGFR-1, also known as FMS-like tyrosine kinase 1) and VEGFR-2 (also known as FLK-1/kinase insert domain protein receptor) [53, 54]. VEGFR-1 and its soluble form VEGFR-1 are up-regulated in the heart. The soluble form of VEGFR-1 prevents capillary growth by trapping VEGF in pressureoverloaded hearts. Inhibition of the soluble form of VEGFR-1 by PlGF causes the release of VEGF to induce angiogenesis [55–57]. Endothelium-derived NO mediates angiogenesis-induced myocardial hypertrophy by promoting proteasomal

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degradation of regulators of G-protein signaling. NO potentiates G-protein–mediated hypertrophic signaling involving the phosphatidylinositol 3-kinase (PI3K)/AKT serine/threonine kinase 1 (AKT)/mechanistic target of rapamycin kinase (mTOR) pathway [58]. However, angiogenesis is repressed at the transition from compensated hypertrophy to decompensated heart failure [59–61]. In the pressure-overloaded heart, the myocardium becomes ischemic, and the DNA-binding activity of HIF-1 increases. HIF-1α stabilizes in hypoxic conditions and transactivates genes encoding hypoxia- and angiogenesis- associated VEGF and erythropoietin. However, during prolonged pathological hypertrophy, HIF-1α and VEGF are down-regulated despite persistent myocardial hypoxia in the hypertrophied myocardium. This harmful HIF-1 down-regulation, involving the tumor suppressor p53 in hypertrophied hearts, exacerbates myocardial hypoxia and accelerated myocardial damage and dysfunction [62– 65]. Impaired angiogenesis may lead to oxidative stress-induced injury. However, the restoration of blood flow may further augment tissue damage via reperfusion injury due to abrupt re-oxygenation, ROS generation, and activation of the complement pathway [33, 37, 66] (Fig. 6.1).

6.2 Non-coding RNAs in Cardiomyopathy and Heart Failure Figure 6.1 illustrates the role of non-coding RNAs in several mechanisms contributing to cardiomyopathy and heart failure development.

6.2.1 Non-coding RNAs in Cardiac Hypertrophy MiR-1 and miR-133 induce cardiogenesis in mesenchymal cells by targeting NOTCH signaling [67, 68]. Let-7 mediates ANG II-induced cardiac hypertrophy [69]. The H19 imprinted maternally expressed transcript lncRNA (H19) inhibits cardiomyopathy by silencing let-7 [70]. High miR-9 is associated with cardiac hypertrophy and remodeling [71, 72]. MiR-21, which is increased selectively in fibroblasts of the failing heart, augments mitogen-activated protein kinase (MAPK or ERK) activity through inhibition of sprouty RTK signaling antagonist (SPRY1), thereby inducing the extent of cardiac hypertrophy and fibrosis [73]. High miR-25 is associated with pressureoverload-induced hypertrophy and cardiac fibrosis [74, 75] and causes degradation of the metastasis-associated lung adenocarcinoma transcript one lncRNA (MALAT1) [76]. Oxidative stress, TGF-β, and IGF1 induce miR-29, related to hypertrophic cardiomyopathy [77–81]. In contrast, miR-29 deficiency prevents cardiac hypertrophy and fibrosis [82]. MiR-106a promotes cardiac hypertrophy by silencing mitofusin 2 [83]. MiR-146a, up-regulated in left ventricular biopsies of patients with

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aortic stenosis, provokes cardiac hypertrophy and left ventricular dysfunction [84]. The increase of miR-208a associated with cardiac injury after acute myocardial infarction induces cardiac hypertrophy through pathological myosin switching and cardiac remodeling [85–87]. MiR-223 causes cardiac hypertrophy but not fibrosis by directly interacting with 3’-UTRs of F-box and WD repeat domain containing 7 and activin A receptor type 2A, two negative regulators of the AKT signaling, and by directly silencing IGF1R and β1-integrin, two positive regulators of AKT signaling [88–90]. High levels of nuclear paraspeckle assembly transcript (NEAT1) promote hypoxia-induced CM proliferation and migration and ischemia-induced apoptosis by silencing miR-378a-3p [91, 92] (Fig. 6.19). MiR-1, a member of the muscle-specific myomiR family, is highly abundant in the heart. Its decrease is related to cardiac dysfunction, particularly in type 2 diabetes in association with oxidative stress [93, 94]. Urothelial cancer associated 1 (UCA1) promotes cardiac hypertrophy by silencing miR-1 and miR-184 [95]. Cardiac-targeted delivery of miR-1 reversed pressure overload-induced cardiac hypertrophy and reduced myocardial fibrosis [96]. ANG II decreases miR-92b-3p, associated with cardiac hypertrophy due to increased myocyte-specific enhancer factor 2D [97]. Decrease of miR-98 in infarcted and ischemic myocardium augments ANG II-induced cardiac hypertrophy by de-repressing CCND2 [69]. MiR-98 attenuates cardiac hypertrophy through down-regulation of mTOR and inhibits TGF-β1induced ECM deposition and apoptosis by regulating Fas/CASP-3 signaling [98– 100]. The long intergenic non-protein coding RNA regulator of reprogramming (LINC-ROR) induces hypertrophy by silencing miR-133 [94, 101–103]. Inhibition of X inactive specific transcript (XIST) improved myocardial injury due to the derepression of miR-133. Silencing of miR-150 is associated with cardiac hypertrophy but may ameliorate TGF-β1/SMAD-induced cardiac fibrosis [104, 105]. Downregulation of miR-199 is associated with cardiac hypertrophy, characterized by an increased heart weight and cardiomyocyte size, but with normal cardiac morphology and function, by targeting PGC1-α [106, 107]. High miR-26a inhibits cardiac hypertrophy and ECM deposition and attenuates cardiac apoptosis but impairs angiogenesis [108–112]. MiR-214-3p, active due to the down-regulation of the TINCR ubiquitin domain-containing lncRNA (TINCR), particularly in diabetes, attenuates myocardial hypertrophy by silencing calcium/calmodulin-dependent protein kinase II [113–117]. The lncRNA cardiac hypertrophy related factor (CHRF) sponges miR-489 and reduces hypertrophy [118, 119] (Fig. 6.1).

6.2.2 Non-coding RNAs in Cardiac Fibrosis and ECM Deposition Let-7, increased after myocardial infarction, induces fibrosis by decreasing the recruitment of transcription factor 21-positive epicardial cells [120]. MiR-17 is

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associated with TGF-β1-induced FB proliferation and COL secretion [121]. MiR21 promotes cardiac fibrosis by reducing the phosphatase and tensin homolog (PTEN)/AKT phosphorylation-dependent pathway leading to a decrease of the SMAD family member 7 (SMAD7) [122–124]. Further, the reduction of PTEN activates a fibrotic gene program and promotes monocyte-to-fibrocyte transition together with activation of CCL2 (MCP-1) [125]. Oxidative stress and hypoxia up-regulate miR-31, inducing cardiac troponin-T, E2F transcription factor 6, mineralocorticoid receptor, and TIMP4 [126]. Mir-31 may be competed out by lnc-31 originating from the same nuclear precursor of miR-31. Lnc-31 counteracts the differentiation of proliferating myoblasts [127]. MiR-34a, up-regulated by TGF-β1, increases fibrosis through silencing SMAD4 [128]. The down-regulation of maternally expressed 3 lncRNA (MEG3) increases miR-125b leading to cardiac fibrosis by inhibiting p53 [129, 130]. Deficiency of differentiated embryonic chondrocyte gene 1 in mice increased M1 to M2 macrophage polarization. It decreased fibrosis and apoptosis, likely by repressing miR-130 associated with ECM remodeling [131, 132] MiR-146a induces fibrosis by enhancing COL1α1 and COL4α1 [133]. High miR-155 stimulates ANG II/TGF-β1/SMAD3 signaling, increases COL1 deposition associated with decreased SOCS1 expression and inflammation, inducing fibrosis [77, 134]. MALAT1 may silence miR-155 but miR-25 down-regulates MALAT1 [135]. MiR433 elevated in fibroblasts compared to cardiomyocytes activates TGF-β1, MAPKs, p38 kinase, and SMAD3, ultimately inducing cardiac fibrosis [136]. Taurine upregulated 1 (TUG1) promotes differentiation of cardiac fibroblasts to myofibroblasts by silencing miR-29c [137]. The WNT1 inducible signaling pathway protein 2 (WISP2) super-enhancer-associated RNA (WISPER) enriched in cardiac fibroblasts collagen cross-linking, stabilization of ECM, and fibrosis [138]. Low miR-1 de-represses fibullin-2 implicated in ECM remodeling [139–144]. Lower levels of miR-18a-5p are associated with cardiac fibrosis through the upregulation of NOTCH2 signaling [145]. Lower miR-22 is associated with fibrosis because of increased TGF-β receptor expression. MiR-22 abrogates the action of MALAT1, but H19 sponges miR-22 [146–149]. Cardiac fibrosis also occurs when H19 silences miR-455, thereby inducing the connective tissue growth factor [70, 150, 151]. ANG II-induced myocardial infarction associated transcript (MIAT) downregulates miR-24 in cardiac fibroblasts and up-regulates TGF-β1, thereby promoting fibroblast proliferation and COL accumulation [152]. Sponging of miR-30a by MALAT1 in myocardial tissues induces myocardial fibrosis through the snail family transcriptional repressor 1 [153, 154]. Low levels of miR-101a are associated with cardiac fibrosis de-repression of TGF-β receptor on cardiac fibroblasts [155, 156]. MiR-101a and TGF-β are mutually inhibitory and co-direct the activation, proliferation, and COL synthesis of FBs [157]. Sponging of miR-133 by LINC-ROR increases cardiac fibrosis by inducing ERK1/2 and SMAD2 phosphorylation and increasing COL4A1 and COL1A1 deposition [158–160]. The increase of miR-221/222 levels in aortic stenosis patients correlated negatively with the extent of myocardial fibrosis and with left ventricular stiffness. Inhibition of both miRs in mice led to increased fibrosis and left ventricular dilation

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and dysfunction by de-repressing TGF-β and SMAD2 signaling [161]. Cardiomyocytes exposed to mechanical stress secrete miR-378, inhibiting cardiac fibrosis [162]. Inhibition of miR-223 suppresses the NLRP3 inflammasome activation and alleviates myocardial fibrosis and apoptosis [163] (Fig. 6.1).

6.2.3 Non-coding RNAs in Cardiac Inflammation Silencing miR-150 by MIAT may result in increased infiltration of monocytes [105, 164]. Let-7 induces inflammation. H19 represses let-7, but LINC-ROR competes out this repression [165–167]. Also, miR-146a blocks H19 [168, 169]. The repression of H19 by miR-146a may, however, be reverted by MALAT1 [168, 170, 171]. MiR-146a activates Th1 cells [172]. MiR-33 increases lipid accumulation and inflammation by lowering the expression of ATP binding cassette subfamily A member 1 (ABCA1) [173, 174]. Increased expression of miR-223 due to the decrease of sponging MEG3 leads to the activation of the NLR family pyrin domain containing 3 (NLRP3) inflammasome [175]. The myocardial infarction associated with transcript 1 (MIRT1) is increased in response to MI and induces inflammation and apoptosis [176, 177]. The ANG II-induced decrease of miR-30a causes inflammation by increasing the expression of intercellular adhesion molecule (ICAM)-1 and vascular cell adhesion molecule (VCAM) by ECs [178]. MALAT1 enhances inflammation by sponging miR-133 [179–181]. MiR-21 attenuates inflammation by inhibiting p38 and NFκB signaling activation [182]. SMAD7 up-regulates miR-29, thereby decreasing pro-inflammatory cytokines IL-1β and TNF-α, and infiltration of CD3(+) T cells and F4/80(+) macrophages [183]. The increase of miR-181a in LPS-stimulated bone marrow-derived mesenchymal cells inhibited cardiomyocyte inflammation and oxidative stress [184] (Fig. 6.1).

6.2.4 Non-coding RNAs in Cardiac Angiogenesis High levels of miR-9 in cardiac tissues block PDGF, reducing the paracrine angiogenic capacity of cardiomyocytes [185, 186]. Synthetic microparticles conjugated with VEGF165 improved the survival of endothelial progenitor cells via miR-17 inhibition [187]. MiR-124 suppresses CD151-facilitated angiogenesis in the heart [188]. MiR-223 inhibits angiogenesis by targeting the ribosomal protein S6 kinase B1/HIF-1a signaling pathway [189]. Let-7b-5p, let-7f, miR-21, miR-30b, miR-30c, miR-126, miR-130a-3p, miR132, miR-133, and miR-378 protect against myocardial ischemia through inducing cardiac angiogenesis and vascular regeneration resulting in the increased blood flow

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to ischemic myocardium [190]. MiR-133-enriched EPC-derived exosomes transmitted to cardiac fibroblasts increased the angiogenesis potential of cardiac fibroblasts [191]. Exosomes enriched in miR-143 and miR-221 may restore angiogenesis [192] (Fig. 6.1).

6.2.5 Non-coding RNAs in Cardiac Apoptosis MiR-9 induces CM apoptosis by targeting the Yes1 associated transcriptional regulator (YAP1), thereby inducing caspase-3/7 activity [193]. MiR-34a aggravates hypoxia-induced apoptosis by silencing protein phosphatase one regulatory subunit 10, which reduces telomere shortening, DNA damage responses, and cardiomyocyte apoptosis, and improves functional recovery after AMI [194, 195]. Although NEAT1 may inhibit apoptosis by silencing miR-34a, hypoxia-induced NEAT1 may by itself induce apoptosis [196]. Cyclin-dependent kinase inhibitor 2B (CDKN2B) antisense RNA 1 (ANRIL) by itself induces apoptosis by degrading IL33 [197]. MiR-223 also mediates hypoxia-induced apoptosis [198] (Fig. 6.1). The decrease of miR-1 promotes the release of reactive oxygen species (ROS) by decreasing the NAD+ to NADH ratio and the NAD+ -dependent deacetylase activity of sirtuin (SIRT)-3. The decrease of miR-7 following ischemic reperfusion injury is related to CM apoptosis by activating the hypoxia-inducible factor-1/p-p38 pathway [199, 200]. P53 induces necrosis-related factor (NRF) that binds miR-873 and increases necrotic cell death in CMs [201]. β carvedilol inhibited apoptosis in the heart via up-regulating miR-133, which is, however, decreased in the failing heart [202] (Fig. 6.1). Bone marrow-derived mesenchymal and cardiac progenitor cells secrete miR-21enriched microvesicles protecting cardiomyocytes against ROS-mediated apoptosis by targeting programmed cell death 4 (PDCD4), [203–206]. High levels of TUG1 protect against apoptosis by silencing miR-145 [207]. Overexpression of miR-378 inhibits cardiac apoptosis by reducing caspase 3 protein levels [92, 208]. Also, UCA1 protects cardiomyocytes from hypoxia/reoxygenation apoptosis [209]. Sponging of miR-17 by the homeobox (HOX) transcript antisense lncRNA (HOTAIR), H19, and MALAT1 protect against ECM degradation and apoptosis in the heart [210–212]. As in other tissues, the silencing of miR-150 and miR-181 by MIAT blocks apoptosis. Reduction of the miR-181 family members harms myocardium because of increased myocardial response to oxidative stress. However, it is protective because it increases the expression of AKT3 and the phosphoinositide-3-kinase regulatory subunit 3, thereby reducing apoptosis of CMs [213–216] (Fig. 6.1).

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6.3 Metabolic Syndrome: The Link Between Metabolic and Cardiovascular Diseases 6.3.1 Definition of Metabolic Syndrome Obesity often clusters with dyslipidemia, hypertension, and hyperglycemia in metabolic syndrome (MetS). Non-alcoholic fatty liver disease (NAFLD) is also a manifestation of end-organ damage of MetS. The National Cholesterol Education Program Adult Treatment Panel III defined MetS components as (1) waist circumference ≥ 102 cm in men and ≥ 88 cm in women; (2) fasting triglycerides ≥ 150 mg/dL (1.70 mmol/L); (3) HDL-cholesterol < 40 mg/dL (1.03 mmol/L) in men and < 50 mg/dL (1.29 mmol/L) in women; (4) blood pressure ≥ 130/85 mmHg; (5) fasting glucose ≥ 100 mg/dL (5.55 mmol/L). Persons with at least three of these components have MetS [217–220]. The American Heart Association (AHA) and the National Heart Lung and Blood Institute (NHLBI) slightly modified the ATP III criteria by not including abdominal obesity as an essential risk factor [221] (Fig. 6.2).

Fig. 6.2 Non-coding RNAs linking metabolic and cardiovascular diseases. Metabolic syndrome components are hypertension, hyperglycemia, dyslipidemia, and obesity. Blood pressure, glucose, lipids, ox-LDL, and inflammatory cytokines and adipokines determine the expression of the let-7 family, miR-1, miR-7, miR-9, miR-17, miR-21, miR-26, miR-29, miR-30a, miR-34a, miR-124, miR-130, miR-133, miR-143-145, miR-146a, miR-150, miR-155, miR-181 family, miR-221-222, miR-223, miR-378, miR-455, GAS5, HOTAIR, H19, lincRNA-p21, LINC-ROR, MALAT1, MEG3, MIAT, NEAT1, TUG1, UCA1, ANRIL, and PVT1. They link metabolic to cardiovascular diseases

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6.3.2 Oxidative Stress and Metabolic Syndrome Elevated oxidized LDL (ox-LDL), but not elevated LDL-cholesterol, was associated with a higher risk of future MetS in the Cardiovascular Risk Development in Young Adults (CARDIA) Study [222, 223]. Elevated ox-LDL was significantly associated with the incidence of abdominal obesity, hyperglycemia, and hypertriglyceridemia. Ox-LDL may be related to obesity because it induces WAT growth. Experimental data showing that ox-LDL induces adipocyte proliferation directly or indirectly by increasing the infiltration of inflammatory monocytes/macrophages supports this hypothesis [224, 225]. As discussed above, the increase in WAT mass may also be explained by cellular hypertrophy due to the increased lipid accumulation in the pre-existing adipocytes rather than an increase in cell number or differentiation. Ox-LDL also decreases adiponectin and increases ROS production, especially when glucose is high [226]. Ox-LDL activates c-Jun N-terminal kinase (JNK) and disrupts insulin signaling in both adipocytes and macrophages in a CD36-dependent manner. Macrophages isolated from Cd36(−/−) mice elicited less JNK activation after highfat diet feeding and restored insulin signaling [227]. Not only CD36 but also LOX-1 is independently associated with insulin resistance in WAT [228].

6.3.3 Metabolic Syndrome and Cardiovascular Risk The coronary event rate was higher among subjects with diabetes and with MetS in the Health, Aging, and Body Composition Study. Subjects with both diabetes and MetS had the highest cardiovascular risk [229]. The Mayo Clinic cohort study revealed an increase in CHD and CVD risk and all-cause mortality across exercise electrocardiographic categories with an increasing number of MetS components [230]. Patients with a higher number of MetS criteria have a higher risk of developing cardiac allograft vasculopathy after heart transplantation [231]. MetS is associated with lower cardiorespiratory fitness [232]. In the Taiwan Survey of Hypertension, Hyperglycaemia, and Hyperlipidaemia cohort, the MetS-attributed risk for CVD was 39% in men and 44% in women. Of all MetS components, central obesity had the highest population attributable risk in women (57%), whereas hypertension had the highest population attributable risk in men (57%) [233]. Also, we demonstrated that participants in the Health ABC study with high ox-LDL had a 2.0-fold higher adjusted risk of myocardial infarction even after adjusting for MetS [234].

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6.3.4 Non-coding RNAs and Metabolic Syndrome Components Increased levels of miR-130, miR-140-5p, miR-142-3p, miR-143, and miR-222, and decreased concentrations of miR-15a, miR-146a, miR-423-5p, and miR-520c3p are strongly linked to measures of BMI, waist circumference, leptin, insulin, HOMA-IR, TG, and HDL-cholesterol [235]. Let-7 g is inversely related to low levels of HDL-cholesterol, associated with impaired reverse cholesterol transport [236, 237]. Type 2 diabetes patients have lower levels of miR-1-3p, miR-133a-3p, and growth arrest-specific five lncRNA (GAS5) levels [238, 239]. MiR-7 levels are low in islets from obese and moderately diabetic individuals, and increases after bariatric surgery and correlate with diabetes remission [240]. MiR-9, up-regulated in CD14 + cells of MetS patients, positively correlates to BMI, the Homeostasis Model Assessment of insulin resistance, triglycerides, and negatively to ABCA1 and HDL-cholesterol levels [241]. Increased expression of miR-17-5p in omental fat tissue reflects obesity and hyperglycemia [242]. Serum levels of miR-21 and miR-34a are elevated in NAFLD patients with non-alcoholic fatty liver disease [243, 244]. TNF-α and inflammatory cytokines, leptin, and resistin down-regulate miR-26b expression in adipocytes [245]. MiR-26a regulates glucose and lipid metabolisms and insulin signaling but is low in overweight subjects’ liver. MiR-26a has a beneficial effect on insulin sensitivity, hepatic glucose production, and fatty acid synthesis, thereby preventing obesity-induced metabolic complications [246]. MiR-29a and miR-29c increased in skeletal muscle from patients with type 2 diabetes, attenuate insulin signaling and expression of insulin substrate receptor (IRS)-1 and PI3K, and decreases glucose uptake by silencing GLUT4 [247]. MiR-29 is inversely related to glucocorticoid resistance [248]. MiR-30a in subcutaneous WAT corresponds with low insulin sensitivity in obese subjects, and restoration of miR-30a in WAT of obese mice improved insulin sensitivity and increased energy expenditure, decreased fat in the liver, and prevented WAT inflammation [249]. Circulating miR-34a is higher, while miR-146a and miR-150 are lower in obese subjects [250]. MiR-34a also increases with insulin resistance, while miR-146a is lower in pre-diabetic individuals, type 2 diabetes patients with insulin treatment, and type 2 diabetes patients with nephropathy and diabetic foot [251]. Circulating miR34a relates positively, while miR-21 and miR-146a are inversely related to blood pressure [252, 253]. The increase of miR-124 determines the overall metabolic, proliferative, and inflammatory state of cells [254]. MiR-143 and miR-222 correlate positively, while miR-146a is inversely related to obesity [235]. Circulating levels of miR-143-3p correlate with levels of leptin and are associated with insulin resistance in MetS patients due to decreased expression of IGF2R [255, 256]. MiR-145a and miR223, together with miR-101 and miR-125b-5p, are members of a regulatory network in lipid and lipoprotein metabolism and insulin signaling [257]. Low miR-181a in monocytes of obese patients is associated with insulin resistance, MetS, and coronary artery disease [258]. Increased levels of miR-223 in serum microvesicles are associated with progression from prediabetes to type 2 diabetes [259]. Mir-378 induces

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adiponectin expression, while ANRIL represses expression of AdipoR1, a key regulator of glucose metabolism [260, 261]. TGF-β-induced miR-455 is associated with brown and white adipogenesis, lipid accumulation in liver associated with diabetes, and with high glucose-induced oxidative stress and inflammation [262–266]. The expression of miR-26a, GAS5, HOTAIR, H19, LINC-ROR, MALAT1, MEG3, NEAT1, and TUG1 depends on ox-LDL and hypoxia [267–275]. ANRIL, H19, MALAT1, MEG3, MIAT, NEAT1, and PVT1 oncogene (PVT1) mediated the response to inflammatory cytokines [276–284]. H19 is a regulator of adiponectin expression [285]. Low levels of the tumor protein p53 pathway corepressor 1 lncRNA (lincRNA-p21) are associated with high oxidative stress and increased TNF-α, IL1β, and IL-6 [286]. TGF-β1 and the macrophage-derived CCL18 induce UCA1, and thereby glucose uptake [287, 288]. Non-coding RNAs HOTAIR and MIAT and their target miRs, such as miR-150 and miR-155, are crucial in the sepsis/MetS cross-talk [289] (Fig. 6.2).

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267. Tang, Y., et al. (2015). The lncRNA MALAT1 protects the endothelium against ox-LDLinduced dysfunction via upregulating the expression of the miR-22-3p target genes CXCR2 and AKT. FEBS Letters, 589, 3189–3196. https://doi.org/10.1016/j.febslet.2015.08.046. 268. Chen, L., et al. (2017). Exosomal lncRNA GAS5 regulates the apoptosis of macrophages and vascular endothelial cells in atherosclerosis. PLoS ONE, 12, e0185406. https://doi.org/ 10.1371/journal.pone.0185406. 269. Han, Y., Ma, J., Wang, J., & Wang, L. (2018). Silencing of H19 inhibits the adipogenesis and inflammation response in ox-LDL-treated Raw264.7 cells by up-regulating miR-130b. Molecular Immunology, 93, 107–114. https://doi.org/10.1016/j.molimm.2017.11.017. 270. Yan, L., Liu, Z., Yin, H., Guo, Z., & Luo, Q. (2019). Silencing of MEG3 inhibited oxLDL-induced inflammation and apoptosis in macrophages via modulation of the MEG3/miR204/CDKN2A regulatory axis. Cell Biology International, 43, 409–420. https://doi.org/10. 1002/cbin.11105. 271. Pang, J. L., Wang, J. W., Hu, P. Y., Jiang, J. S., & Yu, C. (2018). HOTAIR alleviates oxLDL-induced inflammatory response in Raw264.7 cells via inhibiting NF-kappaB pathway. European Review for Medical and Pharmacological Sciences, 22, 6991–6998. https://doi.org/ 10.26355/eurrev_201810_16170. 272. Wang, L., Xia, J. W., Ke, Z. P., & Zhang, B. H. (2019). Blockade of NEAT1 represses inflammation response and lipid uptake via modulating miR-342-3p in human macrophages THP-1 cells. Journal of Cellular Physiology, 234, 5319–5326. https://doi.org/10.1002/jcp. 27340. 273. Zhang, L., et al. (2018). TUG1 knockdown ameliorates atherosclerosis via up-regulating the expression of miR-133a target gene FGF1. Cardiovascular Pathology, 33, 6–15. https://doi. org/10.1016/j.carpath.2017.11.004. 274. Tian, S., et al. (2018). LncRNA UCA1 sponges miR-26a to regulate the migration and proliferation of vascular smooth muscle cells. Gene, 673, 159–166. https://doi.org/10.1016/j.gene. 2018.06.031. 275. Takahashi, K., Yan, I. K., Haga, H., & Patel, T. (2014). Modulation of hypoxia-signaling pathways by extracellular linc-RoR. Journal of Cell Science, 127, 1585–1594. https://doi. org/10.1242/jcs.141069. 276. Luo, R., Xiao, F., Wang, P., & Hu, Y. X. (2020). lncRNA H19 sponging miR-93 to regulate inflammation in retinal epithelial cells under hyperglycemia via XBP1s. Inflammation Research, 69, 255–265. https://doi.org/10.1007/s00011-019-01312-1. 277. Xu, Y., et al. (2019). Long non-coding RNA NEAT1 alleviates acute-on-chronic liver failure through blocking TRAF6 mediated inflammatory response. Frontiers in Physiology, 10, 1503. https://doi.org/10.3389/fphys.2019.01503. 278. Li, Y., Zhang, S., Zhang, C., & Wang, M. (2020). LncRNA MEG3 inhibits the inflammatory response of ankylosing spondylitis by targeting miR-146a. Molecular and Cellular Biochemistry, 466, 17–24. https://doi.org/10.1007/s11010-019-03681-x. 279. Li, J., & Liu, S. (2020). LncRNA GAS5 suppresses inflammatory responses and apoptosis of alveolar epithelial cells by targeting miR-429/DUSP1. Experimental and Molecular Pathology, 113, 104357. https://doi.org/10.1016/j.yexmp.2019.104357. 280. Song, B., Ye, L., Wu, S., & Jing, Z. (2020). Long non-coding RNA MEG3 regulates CSEinduced apoptosis and inflammation via regulating miR-218 in 16HBE cells. Biochemical and Biophysical Research Communications, 521, 368–374. https://doi.org/10.1016/j.bbrc. 2019.10.135. 281. Liang, W. J., et al. (2019). Long non-coding RNA MALAT1 sponges miR-149 to promote inflammatory responses of LPS-induced acute lung injury by targeting MyD88. Cell Biology International. https://doi.org/10.1002/cbin.11235. 282. Sun, G., Li, Y., & Ji, Z. (2019). Up-regulation of MIAT aggravates the atherosclerotic damage in atherosclerosis mice through the activation of PI3K/Akt signaling pathway. Drug Delivery, 26, 641–649. https://doi.org/10.1080/10717544.2019.1628116. 283. Zhao, Y., Zhao, J., Guo, X., She, J., & Liu, Y. (2018). Long non-coding RNA PVT1, a molecular sponge for miR-149, contributes aberrant metabolic dysfunction and inflammation

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Chapter 7

Non-coding RNAs Related to Cardiometabolic Diseases and Associated to Cancer

Abstract Low miR-1, miR-7, miR-17, miR-26a, miR-29a, miR-30a, miR-34a, miR-124, miR-133, miR-143-145, miR-150, miR-378, miR-455, lincRNA-p21, and MEG3 are related to cancer. In contrast, high miR-9, miR-21, miR-130, miR-155, miR-221, HOTAIR, H19, LINC-ROR, MALAT1, MIAT, NEAT1, TUG1, UCA1, XIST, ZFAS1, ANRIL, ciRs-7, and PVT1 are related to cancer. High and low let-7, miR-146a, miR-181, miR-223, and GAS5 are associated with cancer. These noncoding RNA profiles allow a metabolic reprogramming in tumors to retain stemness and epithelial-mesenchymal transition, insulin sensitized state and angiogenesis. It also explains the shift from OXPHOS to glycolysis, the immune escape, and the prevention of apoptosis in tumors.

7.1 Mechanisms of Cancer Progression 7.1.1 Induction of Stemness Hypoxia induces transforming growth factor (TGF)-β that activates sirtuin (SIRT)-1, which induces MYC proto-oncogene, bHLH transcription factor (MYC), POU class 5 homeobox one or POU5F1 (OCT4), Nanog homeobox (NANOG), SRY-box transcription factor 2 (SOX2), and lin-28 homolog (LIN28) [1–5]. Loss of E-cadherin promotes Wnt signaling and β-catenin accumulation in the nucleus, inducing stemness. MYC, NANOG, OCT4, and SOX2 regulate stemness. Stemness is also induced by snail family transcriptional repressor 1 (SNAIL or SNAI) and twist family bHLH transcription factor (TWIST), also involved in epithelial to mesenchymal transition (EMT) [6–10]. SIRT2, however, inhibits β-catenin signaling and downregulates expression of Wnt target genes, while SIRT6 represses Wnt target genes by interacting with lymphoid enhancer-binding factor 1 and deacetylating histone 3 (Fig. 7.1.) Importantly, retaining stem cells is critical to maintaining the M2 phenotype of tumor-associated macrophages (TAMs). M2 TAMs promote the growth and motility Illustrations by Pieterjan Ginckels, Faculty of Architecture, KU Leuven, Ghent, Belgium. © The Author(s), under exclusive license to Springer Nature Switzerland AG 2021 P. Holvoet, Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer, https://doi.org/10.1007/978-3-030-68844-8_7

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Fig. 7.1 Role of non-coding RNAs in hypoxia-induced cancer progression. Hypoxia-mediated up-regulation of TGF-β via CASC11 induces SIRT1. SIRT1 maintains stemness by upregulating MYC, OCT4, NANOG, SOX2, and LIN28. The up-regulation of miR-9, miR-221, lncRNAs ES1, MALAT1, and MIAT promotes stemness. The inactivation of let-7 by LIN28 and the silencing of miR-1, miR-7, miR-29a, miR-30a by FEZF1-AS1, miR-34a by HOTAIR, NEAT1 and XIST, miR124, miR-133, miR-143, and miR-146a by PVT1 exacerbates stemness. NIFK-AS1 may revert the latter. In contrast, Let7-i-5p and miR-181a-2-3p repress stemness. TGF-β and SIRTs activate EMT inducers SMAD-2, -3, and 4, and transcription factors SNAIL, SLUG, TWIST, and ZEB. TGF-β also induces EMT through pathways that do not involve SMAD, like PI3K/AKT/mTOR signaling. The up-regulation of miR-21, miR-155, miR-221, H19, TUG1, UCA1, XIST, ZFAS1, and PVT1 induces EMT. Silencing of miR-1, miR-7 by SOX21-AS1, miR-17 by LINC01939, miR-26a by MALAT1, miR-30a by LINC00460, MALAT1 and XIST, miR-34a by CASC11 and HOTAIR, miR-124 by H19, MALAT1, NEAT1, UCA1, XIST and circ-HIPK3, miR-130, miR143-145 by LINC-ROR and SOX21-AS1, miR-150, miR-378, miR-455, lincRNA-p21, and MEG3 also enhances EMT. Besides, high miR-9 and low miR-29, silenced by H19, MIAT, and TUG1, promote EMT by repressing E-cadherin. In contrast, miR-181 b and lincRNA-p21 inhibit EMT. SIRT1 activates Wnt/β catenin signaling that activates stemness genes MYC, NANOG, OCT4, and SOX2, and induces EMT genes SNAIL and TWIST, closing a vicious circle. Further, Wnt/β catenin signaling leads to insulin sensitized state by activating IGF1/IGF1R and IRS signaling and downregulation of PTEN, leading to activation of PI3K/AKT signaling. Up-regulation of miR-155 and silencing of miR-7 by circ-HIPK3, miR-26a by TUG1, miR-30a by MALAT1, XIST and PVT1, miR-126 by XIST, miR-145 by circ-ZNF609, miR-455 and GAS5 activate IGF1/IGF1R and IRS signaling. MiR-9 and miR-17 block IGF1/IGF1R signaling. Up-regulation of miR-9, miR-17, miR21, miR-26a, miR-29, miR-130, miR-155, miR-221-222 by decreased circ-MTO1, and miR-223,

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 and decreased miR-145, and GAS5 inhibit PTEN, thereby activating PI3K/AKT. PTEN may be de-repressed by TUG1, silencing miR-26a, and UCA1. Increased PI3K/AKT signaling promotes glycolysis. The up-regulation of miR-155, LINC-ROR, and MACC1-AS1, both silencing miR145, MALAT1, TUG1, UCA1 silencing miR-125 and miR-143, and PVT1 silencing miR-143 facilitates glycolysis. The down-regulation of miR-1, miR-34a, and MEG3 exacerbates glycolysis. MiR-378 and lincRNA-p21 inhibit glycolysis and favor transition from glycolysis to OXPHOS. Glycolysis may be induced in a VEGF-dependent or VEGF-independent way, the latter involving DKK2. Increased PI3K/AKT signaling also induces angiogenesis. The increase of miR-9, miR-21, miR-130b, and XIST stimulates angiogenesis. The down-regulation of miR-26a, miR-29, silenced by PVT1, miR-34a, miR-124, miR-145, miR-150, silenced by ZFAS1, and miR-223 silenced by lncRNA F63 and circRNA_001587, and GAS5 exacerbates angiogenesis. An increase of miR-1792 and a decrease of miR-146a blocks angiogenesis. Insulin sensitized state is associated with decreased cell senescence and apoptosis. MiR-130a, miR-146a, HOTAIR, MALAT1, and ANRIL protect against apoptosis. The inactivation of let-7 by LIN28 and the silencing of miR-9 by MEG3, NEAT1, and TUG1, miR-17, miR-26a, miR-29 by H19, miR-30a by NORAD and PVT1, miR34a by LINC-ROR, miR-133 by MIAT, NEAT1 and XIST, miR-145 by TUG1 and BRE-AS1, and miR-150 by MIAT, ZFAS1, and PVT1 decreases cancer cell senescence and death. In contrast, the up-regulation of miR-124, miR-181a/d and miR-378, due to the down-regulation of GAS5, and the down-regulation of miR-146a induces apoptosis. The survival of cancer cells is also due to their immune escape. Anti-tumor immunity is suppressed by inducing M2 macrophages, MDSCs, and Treg cells and reducing cytotoxic T cells. The increase of let-7e, miR-9, miR-21, miR-30a, miR125, miR-146a/b, miR-181a, miR-223, and HOTAIR lower anti-tumor immunity. The silencing of let-7 by H19 and ANRIL, miR-17, miR-26a, miR-34a, miR-150 by PVT1, and miR-181b, also lowers anti-tumor immunity. MiR-33, miR-130, and miR-155 decrease immune escape by shifting M2 to M1 macrophages. Inflammatory cytokines change the composition of ECM related to EMT. EMT, insulin-sensitized state, low anti-tumor immunity, and high angiogenesis induce cancer cell proliferation. MiR-21, miR-130, miR-181a/d, miR-221-222, miR-223, by down-regulation of GAS5 or vice versa, H19, MALAT1, NEAT1, TUG1, UCA1, XIST, ZFAS1, and PVT1 increases cancer cell proliferation. Silencing of let-7a by ANRIL, miR-17 by BLACAT1, HNF1A-AS1, HOTAIR, H19, NEAT and cSMARCAS, or the up-regulation of miR-17 by NEAT1 and down-regulation of circ-RNAs circ-ITCH and circ-MTO1 may induce proliferation pending on the tumor type. Silencing of miR-26a by MALAT1, miR-29, miR-126 by PVT1, miR-145 by KCNQ1OT1, TUG1, and ZEB1-AS1, miR-146a, miR-181a by circ-ANAPC7, and miR-378 exacerbate proliferation. Increased non-coding RNAs are in red; decreased in green

of mesenchymal cells, tumor angiogenesis, immune escape. Similarly, hypoxia induces the differentiation of M2 myeloid suppressor cells (MDSCs). They facilitate immune escape by promoting Treg cell proliferation and phenotypic switch from M1 toward M2 macrophages [11]. Signal transducing and activator of transcription (STAT)-3 drives MDSC expansion, preventing differentiation of monocytic MDSC to macrophages and dendritic cells (DCs) [12, 13]. Leptin and fatty acid metabolism induce MDSCs, which promote tumor progression but prevent dysregulation of glucose uptake and insulin signaling associated with obesity [14] (Fig. 7.1).

7.1.1.1

Non-coding RNAs and Stemness

LncRNA cancer susceptibility 11 (CASC11) promotes TGF-β1, increasing cancer cell stemness [15]. Induction of miR-9 and miR-221 maintained the mesenchymal stem-cell potential in non-invasive MCF-7 breast cancer cells [16]. The polycomb

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repressive complex 1 (PRC1) maintains the stem cell markers OCT4 and CD133 in gastric cancer tissues by up-regulating miR-21 [17]. The long intergenic non-protein coding RNA 1108 (LncRNA ES1) induces stemness and reduces cellular senescence using OCT4/SOX2. The latter down-regulate miR-302 and miR-106b [18, 19]. Metastasis-associated lung adenocarcinoma transcript 1 (MALAT1) enhances the stability of SOX2 and silences miR-20b-5p, derepressing OCT4, increasing stemness. Stemness is reinforced by the up-regulation of urothelial cancer-associated 1 (UCA1) [20–22]. High levels of myocardial infarction associated transcript (MIAT) are associated with an increase of OCT4 [23]. Wnt/β-catenin up-regulates the stemness inducer lin-28 homolog (LIN28), which suppresses mature let-7 by post-transcriptional repression [24, 25]. Downregulation of miR-7 induces stemness through activation of the Krüppel-like zinc finger transcription factor (KLF)-4/phosphatidylinositol 3-kinase (PI3K)/AKT serine/threonine kinase 1 (AKT)/p21 pathway [26, 27]. The down-regulation of miR-29a in triple-negative breast cancer is associated with increased expression of stemness regulators OCT4, NANOG, and SOX2 [28]. TGF-β1-induced decrease of miR-30a, possibly silenced by the fasciculation and elongation protein zeta 1 (FEZF1) antisense RNA 1 (FEZF1-AS1), is associated with induction of NANOG, activation of Wnt/β-catenin and PI3K/AKT pathway, resulting in insulin-sensitized state and cancer cell proliferation [29–31]. Low miR-34a-5p, silenced by the nuclear paraspeckle assembly transcript 1 (NEAT1) and X inactive specific transcript (XIST), correlates with high stemness inducer LIN28B, high expression of SIRT1, and activation of Wnt/β-catenin pathway [32–35]. Let-7i-5p and miR-181a-2-3p inhibited cervical cancer stem cells by silencing SOX2 [36]. MiR-145 represses SOX2, NANOG, and OCT4, usually related to cancer cells’ pluripotency [37] (Fig. 7.1). HOX transcript antisense RNA (HOTAIR) up-regulates SOX2, which is targeted by miR-34a [38]. Low miR-124 is associated with the maintenance of stemness with the expression of CD44 and SOX9 [39]. The decrease of miR-133, like the decrease of miR-1, induces the RUNX family transcription factor 1 (RUNX1 or EVI-1), associated with the proliferation of stem cells [40, 41]. Low miR-143 is associated with stemness by inducing SOX2 [42]. Circ-RNA derived from PVT1 oncogene (PVT1) silences miR-146a and increases the expression of 5-lipoxygenase activating protein and cytochrome c oxidase subunit II (COX2), thereby increasing stemness. Restoration of miR-146a also resulted in decreased cancer cell leukotriene B4 production. Thus, miR-146a is an endogenous dual inhibitor of amino acid metabolism in lung cancer cells by regulating both prostaglandin and leukotriene production through direct targeting of the COX2 [43, 44]. The silencing of miR-146a may be reverted by the nucleolar protein interacting with the FHA domain of MKI67 (NIFK) antisense RNA 1 (NIFK-AS1), especially in tumor-associated macrophages [45]. Overexpression of miR-146b attenuates stemness by inhibiting the tumor protein p53 pathway corepressor 1 (lincRNA-p21)/β-catenin pathway [46]. MiR-221-3p and miR-221-5p act as anti-stemness miRNAs by targeting OCT4, NANOG, and SOX2 mRNAs in embryonic stem cells [47] (Fig. 7.1).

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7.1.2 Induction of EMT Hypoxia induces TGF-β that activates SIRT1, which is a positive regulator of EMT in tumors. EMT is the conversion of epithelial cells to mesenchymal cells, contributing to tissue remodeling during development, wound repair, and cancer metastasis. TGFβ signaling induces EMT through SMAD family member (SMAD). Upon ligand binding, cell surface complexes of type-II and two type-I receptors phosphorylate and activate SMAD2 and SMAD43. Activated SMADS form complexes with SMAD4 and regulate transcription of EMT-inducing transcription factors, SNAIL and snail family transcriptional repressor 2 (SLUG or SNAI2), the zinc-finger E-box-binding homeobox (ZEB), and TWIST. They promote the transcription of genes typically expressed in mesenchymal cells, such as N-cadherin, vimentin, and fibronectin. On the contrary, epithelial markers E-cadherin, claudins, occludins, and cytokeratins are suppressed. SIRT1 is recruited by ZEB1 to the E-cadherin promoter to cause transcriptional repression [48, 49]. Similarly, SIRT1 interacts with TWIST to silence the E-cadherin promoter [50]. SIRT1 may mediate the recruitment of SIRT7 to the E cadherin promoter and thereby repress E-cadherin, in addition to direct up-regulation of SLUG expression by SIRT7 [51, 52]. In contrast, SIRT1 has been identified as an EMT repressor by inhibiting TGF-β signaling by deacetylating SMAD4, thereby decreasing metalloproteinase (MMP) transcription and E-cadherin degradation [53]. SIRT2 activates AKT/glycogen synthase kinase 3β (GSK3β)/β-catenin signaling to promote EMT in hepatocellular carcinoma. Deacetylation of SLUG by SIRT2 promotes SLUG protein stability and repression of SLUG target genes, including E-cadherin [54]. SIRT4 up-regulates E-cadherin and decreases vimentin expression, inhibiting EMT [55]. Importantly, activation of EMT programs confers stem-like traits on healthy and neoplastic cells [56, 57]. TGF-β also activates other signaling pathways that do not involve SMADS, like the PI3K/AKT/mechanistic target of rapamycin kinase (mTOR) pathway and small GTPases [49] (Fig. 7.1).

7.1.2.1

Non-coding RNAs and EMT

Higher levels of miR-21, due to down-regulation of the maternally expressed 3 (MEG3), induce EMT by up-regulating SNAI1 or SNAIL, N-cadherin β-catenin, and down-regulating E-cadherin [58]. TGF-β1 elevates the expression of miR-155 in cancer cells through SMAD3 and SMAD4, associated with miR-155-mediated loss of c/EBP-β shifting TGF-β action from growth inhibition to EMT [59]. SLUG/βcatenin increases miR-221 in hypoxic cancer stem cells, thereby increasing IL8 and TNF-α, enhancing TGF-β-mediated EMT [60–63]. H19 promotes TGF-β-induced EMT by silencing miR-29, miR-194, miR-370-3p, and miR-484 and increasing expression of β-catenin, MYC, CCN (CCN)-D1, and CDK14 [64–70]. Taurine upregulated 1 (TUG1) promotes EMT and stemness through up-regulating SIRT1 and Wnt/β-catenin signaling by sponging miR-138-5p. Besides, TUG1 activates the Janus kinase 2 (JAK2)/STAT3 pathway, up-regulates ZEB1, induces SMAD2 and SMAD3

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phosphorylation, TGF-β, TGF-β receptor, MMP-2, and MMP9, and decreases Ecadherin expression, possibly by sponging miR-29. TGF-1β, H19, and MIAT also repress miR-29 [71–74]. UCA1 promotes EMT and tumor metastasis by silencing miR-203, thereby inducing ZEB2, and by sponging miR-185-5p, thereby increasing Wnt/β-catenin signaling [75, 76]. XIST induces EMT by silencing miR-200b and miR-429, thereby increasing expression of ZEB1 and activating the notch receptor 1 (NOTCH1) signaling by silencing miR-137 [77]. High ZNFX1 antisense RNA 1 (ZFAS1) in tumors also induces ZEB1 expression and promotes EMT [78]. PVT1 promotes EMT by inducing TGF-β/SMAD signaling and increasing SNAIL, SLUG, β-catenin, N-cadherin, and vimentin while decreasing E-cadherin [79]. The silencing of miR-1 by MALAT1 is associated with increased proliferation and viability of cancer cells and EMT by activation of PI3K/AKT/mTOR signaling [80–82], an increase of Wnt/β-catenin signaling via induction of the E2F transcription factor 5 that interacts with tumor suppressor proteins p130 and p107, and by inducing cyclin-dependent kinase (CDK)-14 [83–86]. The silencing of miR-7 by SOX21 antisense divergent transcript 1 (SOX21-AS1), miR-17 by the long intergenic non-protein coding RNA 1939 (LINC01939), and miR-26a by MALAT1 increases EMT [87–89]. The hypoxia-sensitive long intergenic non-protein coding RNA 460 (LINC00460), MALAT1, and XIST silence miR-30a, inducing EMT by up-regulating ZEB2 [90–94]. Silencing of miR-34a and miR-143-145 by CASC11 promotes EMT by suppressing the degradation of SNAIL mRNA. HOTAIR also silences miR-34a, resulting in increased Wnt/TGF-β/SMAD3/4 signaling [95– 98]. The H19 imprinted maternally expressed transcript (H19), MALAT1, NEAT1, UCA1, XIST, and the homeodomain interacting protein kinase 3 circ-RNA (circHIPK3) silence miR-124, increasing TRAF6 and SNAIL, promoting EMT [99– 106]. In particular, macrophage-derived IL8 induces MALAT1 that promotes EMT and metastasis by inducing PI3K/AKT signaling through the sponging of miR-124 [107–110]. P53 promotes EMT by directly binding to the promoter of miR-130b that otherwise would silence ZEB1 [111]. Long intergenic non-protein coding RNA, a regulator of reprogramming (LINC-ROR), and SOX21-AS1 also silence miR-145 and de-repress ZEB2 [112, 113]. Decreased expression of miR-150 is associated with the up-regulation of GLI family zinc finger one and SNAIL, which promote EMT [114]. Low miR-378 expression results in de-repression of BMP2 associated with gastric cancer cell invasion and EMT [115, 116]. Low miR-455 increases TGF-β signaling and EMT by up-regulating ZEB1 [117, 118]. The decrease of lincRNA-p21 increases EMT, cell proliferation, migration and invasion, and transition of the cell cycle from G1, and inhibits apoptosis by changing the p21/p53 ratio [119–121]. Overexpression of lincRNA-p21 inhibits tumor invasion through mediating NOTCH-induced EMT [122]. TGF-β-induced repression of maternally expressed 3 (MEG3) in breast cancer tissues is associated with EMT and lymph node metastasis resulting from decreased E-cadherin and increased ZEB [123, 124]. MiR-9 downregulates E-cadherin. This repression results in the activation of Wnt/β-catenin signaling and the promotion of EMT and tumor angiogenesis by

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vascular endothelial growth factor (VEGF) [125]. However, miR-9 may inhibit EMT by targeting TWIST [126]. MiR-181b may repress EMT by silencing NFκB-targeting genes [127]. High miR-223 in tumors induces or inhibits EMT in a context-dependent manner [128] (Fig. 7.1).

7.1.3 Induction of Insulin Sensitized State, Cancer Cell Proliferation, and Protection Against Apoptosis Hypoxia-induced insulin-like growth factor 1 (IGF1R) signaling increases phosphorylation of insulin substrate receptors (IRS) and PI3K/AKT and increases glucose uptake and insulin signaling. Phosphorylated AKT enhances cell proliferation and cell survival and reduces apoptosis [4, 129]. Activation of the Wnt signaling pathway is associated with reduced phosphatase and tensin homolog (PTEN) and increased PI3K/AKT signaling, thereby favoring an insulin-sensitized state [130–132]. PTEN blocks the PI3K/AKT pathway by GSK3β-regulated degradation of β-catenin, rendering cancer cells more sensitive to apoptosis [133, 134]. PTEN inhibits Wnt signaling by blocking the AKT pathway and reducing the expression of IGF1R [135] (Fig. 7.1).

7.1.3.1

Non-coding RNAs and Insulin Sensitized State

MiR-155 promotes insulin-like growth factor 1 (IGF1) signaling, decreases GSK3β, and increases β-catenin [136]. MYB proto-oncogene, transcription factor (MYB)induced circHIPK3 silences miR-7, while TUG1 silences miR-26a, and PVT1 silences miR-30a, thereby inducing IGF1/IGF1R signaling [137–140]. The decrease of miR-455-5p up-regulates IGF1R and is associated with increased solute carrier family two member one (SLC2A1 or GLUT1) expression and glucose uptake [141]. Down-regulation of growth arrest-specific 5 (GAS5) in lung adenocarcinoma increases IGF1R proteins’ expression [142]. Silencing of miR-30a by the hypoxia-sensitive LINC00460 and by MALAT1 and XIST is associated with activation of the LIN28B/ insulin substrate receptor (IRS)-1 and up-regulating ZEB2 [90]. XIST also acts as a ceRNA of miR-126, thereby inducing IRS1/PI3K/AKT pathway in glioblastoma cells [143]. The circRNA derived from zinc finger protein 609 (circ-ZNF609) sponges miR-145-5p, thereby elevating p70S6K1 expression that plays a crucial role in activating the IRS [144]. MiR-9 and miR-155 down-regulate PTEN, leading to insulin sensitivity by activating PI3K/AKT/mTOR signaling [125]. However, glucose-induced miR-9 may block IGF1R and, thereby, insulin signaling [145]. MiR-17 inhibits PTEN, thereby activating AKT/mTOR signaling [146]. However, mir-17-5p completely abrogated

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IGF1R-mediated, anchorage-independent growth of breast cancer cells by targeting the amplified in breast cancer 1 [147]. MiR-21, miR-26a, and miR-29 also repress PTEN [148–152]. TUG1 may, however, revert the action of miR-26a [153]. The miR-130 family directly targets PTEN, increasing pAKT [154, 155]. Higher miR-221-222 due to lower expression of circ-MTO1 inhibits PTEN [156]. However, the HIF-1α- and TGF-β1 up-regulated UCA1 reverts this inhibition [157]. Macrophage-derived exosomes enriched in miR-223 induce cancer cell proliferation through the PTEN–PI3K/AKT axis [158]. A decrease of miR-145, miR-125b, miR-136, and miR-381, leads to loss of PTEN and enhanced expression of MYC and PI3K, and β-catenin signaling [159]. Downregulation of GAS5 is associated with an increase of miR-205 that blocks PTEN, associated with increased PI3K/AKT signaling [160]. MiR-181a/d promotes growth factor-induced AKT phosphorylation [161]. H19 induces PI3K/AKT signaling by silencing miR-106b-5p [162]. LINC-ROR induces AKT signaling [163]. UCA1 facilitates phosphorylation of the cAMP-responsive element-binding protein and activates PI3K/AKT signaling [164]. The decrease of MEG3 down-regulates p53 and activates PI3K/AKT/mTOR signaling [165, 166]. Besides, down-regulation of MEG3 increases miR-27 and miR-125b, thereby decreasing the expression of the PH domain and leucine-rich repeat protein phosphatase 2 and activating AKT signaling and cancer cell proliferation (Fig. 7.1).

7.1.4 Induction of Glycolysis Cancer cells use glycolysis instead of oxidative phosphorylation (OXPHOS) to sustain their energy demand even when oxygen supply is adequate. This phenomenon is known as aerobic glycolysis or the “Warburg effect” [167, 168]. This low dependence on cancer cells’ mitochondrial activity avoids mitochondrial dysfunction in cancer cells, favoring an increased uptake of glucose through GLUT1 and conversion of pyruvate into lactate to generate energy, which correlates with a poorer prognosis and more aggressive phenotypes [169, 170]. Overall, Wnt/SNAIL/βcatenin signaling is implicated in increased glucose uptake and suppressed mitochondrial respiration through the Wnt/β-catenin target gene MYC. Herein, Wnt controls pyruvate dehydrogenase kinase (PDK)-1, an enzyme that inhibits mitochondrial OXPHOS by reducing pyruvate’s conversion into acetyl-CoA and thereby maintaining the glycolysis dependent nature of tumor cells [171, 172]. The loss of repression of glucose-6-phosphate-dehydrogenase (G6PD) activates glycolytic genes. Besides, the oncogenes p53, MYC and KRAS proto-oncogene, GTPase (KRAS); the PI3K/AKT, protein kinase AMP-activated catalytic (AMPK), and HIF-1α signaling pathways; and sirtuins participate in the regulation of glycolysis that is associated with cancer cell proliferation and metastasis and is inhibited by FOXO3a [173–175]. G6PD is also associated with activation of NOTCH signaling and proliferation and migration by affecting EMT [176].

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VEGF stimulation led to a metabolic transition from mitochondrial OXPHOS to glycolysis in pancreatic cancer. HIF1α and NRP1 protein levels were both increased after VEGF stimulation. The down-regulation of neuropilin 1 (NRP1 or VEGF165R) reduced glycolysis in pancreatic cancer cells [177, 178]. The Dickkopf associated protein 2 (DKK2) promotes tumor metastasis and angiogenesis through a VEGFindependent but glycolysis-dependent pathway [179] (Fig. 7.1).

7.1.4.1

Non-coding RNAs and Glycolysis

The increased miR-155 expression is associated with decreased GSK3β and increased β-catenin expression, thereby increasing glycolysis and inhibiting apoptosis by targeting SOCS3 [136, 180]. Hypoxia-responsive LINC-ROR sponges miR-145, thereby enhancing HIF-1α and pyruvate dehydrogenase kinase 1 (PDK1) linked to glycolysis [181, 182]. The silencing of miR-145-5p by the TGF-β1-induced lncRNA MET transcriptional regulator MACC1 antisense (MACC1-AS1) enhances glycolysis and anti-oxidation, coordinated by the AMPK/LIN28 pathway [183–186]. MALAT1 up-regulates glycolytic genes and downregulates gluconeogenic enzymes [187]. TUG1 silences miR-600 and thereby triggers the AMPK/GSK3-β/β-catenin cascade resulting in enhanced glycolysis [188, 189]. UCA1 promotes glycolysis by activating mTOR and HK2 by activating STAT3 and repression of miR-125 and miR143 [157, 190–196]. PVT1 positively regulates hexokinase 2 expression by acting as a ceRNA of miR-143, which may be reinforced by the forkhead box M1 circ-RNA (circ-FOXM1) [197, 198]. A decrease of miR-1 and miR-122 results in loss of repression of glucose-6phosphate-dehydrogenase and an increased glycolysis [199]. A decrease of miR-34a leads to the de-repression of LDHA, thereby inducing glycolysis [200]. A decrease of MEG3 is associated with enhanced aerobic glycolysis by induction of MYC [201]. MiR-378* causes a shift from glycolysis to OXPHOS by inhibiting the expression of the estrogen-related receptor (ERR)-γ [202]. LincRNA-p21 inhibits β-catenin signaling activity, thereby attenuating the viability, self-renewal, and glycolysis of colorectal cancer cells [203] (Fig. 7.1).

7.1.5 Induction of Angiogenesis Hypoxia induces angiogenesis through the HIF-1α/VEGF axis, involving Wnt ligands [204]. Low oxygen levels promote angiogenesis by inducing angiopoietin, basic fibroblast growth factor (bFGF), hepatocyte growth factor (HGF), and plateletderived growth factor (PDGF) [205, 206]. Angiogenesis is necessary for providing O2 to a growing tumor and for metastasis [206]. PDK1 not only inhibits mitochondrial respiration and induces Wnt-mediated glycolysis, but it also induces vessel growth [172] (Fig. 7.1).

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Non-coding RNAs and Angiogenesis

MiR-9 induces VEGF and thereby promotes tumor angiogenesis [125]. MiR-21 suppresses transforming growth factor-induced mRNA, enhancing endothelial tube formation and angiogenesis [175]. MiR-130b-3p promotes angiogenesis by targeting homeobox that otherwise induces CD31 and CD34 [207]. XIST promotes angiogenesis by silencing miR-429 [208]. PVT1 promotes angiogenesis by silencing miR-29 and miR-128, thereby upregulating VEGF [209, 210]. MYC also downregulates miR-29, up-regulating the B7 family of immune checkpoint homolog 3 (B7-H3), increasing angiogenesis [211]. TGF-β1 secreted by tumor macrophages down-regulates miR-34a, thereby inducing angiogenesis and invasion of colorectal cancer cells via up-regulating VEGF [212]. Decrease of miR-124 in bladder cancer increased CDK4 associated with increased cancer cell viability and angiogenesis rate [213]. Low miR-145 is associated with increased HIF-2α and angiogenesis in neuroblastoma [214]. MiR-150-5p inactivated VEGFA/VEGFR2 and the downstream AKT/mTOR signaling pathway in CRC [215]. Down-regulation of miR-150 by ZFAS1, MYC, and miR-155 is associated with cancer cell proliferation, migration, invasion, and angiogenesis through increased VEGFA/VEGFR2 expression and downstream AKT/mTOR signaling [215–217]. Lnc-RNA F630028O10Rik (RIKEN cDNA F630028O10; abbreviated as F63) silenced miR-223, down-regulating VEGFA- mediated angiogenesis [218]. CircRNA_001587 inhibits prostate cell angiogenesis and tumorigenesis by impairing miR-223-mediated inhibition of solute carrier family 4 member 4 [219]. A decrease of GAS5 leads to the activation of the Wnt/β-catenin signaling pathway, associated with more angiogenesis, tumor growth, and metastasis [220]. MiR-17-92 targets HIF1α and VEGFA and suppresses tumor progression by inhibiting angiogenesis [221]. MiR-26a/b directly binds to the 3 -UTR of HGF mRNA, repressing the HGF-VEGF pathway and inhibiting angiogenesis [222]. The decrease of miR-26a in gastric cancer cells de-represses the HGF-VEGF pathway and restores angiogenesis [222]. Injection of a miR-146a-5p antagomir inhibited tumor growth by reducing angiogenesis and inducing apoptosis. Thus, miR-146a-5p functions as a control switch between angiogenesis and cell death [223] (Fig. 7.1).

7.1.6 Repression of Anti-tumor Immunity and Apoptosis The tumor comprises tumor cells and fibroblasts, stromal, vascular, immune cells, and extracellular matrix (ECM) [224]. The infiltration of immune cells both promote and delay tumor progression. Anti-tumor immunity is mostly dependent on CD8+ cytotoxic T lymphocytes, which produce cytokines, cytotoxic perforins, and granzymes, promoting cancer cell apoptosis [225]. Cancer cells evade immune suppression by down-regulating tumor antigenicity, suppressing cytokines, and increasing Treg cells [226, 227]. Activation of Wnt/β-catenin ablate CD8+ T-cell function and suppress anti-cancer immunity [228]. NKT cells also cause anti-tumor activity by releasing

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interferon (IFN)-γ and interleukin (IL)-4. NKT cells share properties with adaptive T cells, and their maturation again depends on Wnt ligands and β-catenin, which suppress IFN-γ production [229–231]. Further, Wnt signaling is involved in immune evasion in tumors by driving the expression of programmed death-ligand 1 (PD-L1), which is recognized by inhibitory immune checkpoint receptor PD-1 on activated T cells [232]. Further, the Wnt/β-catenin pathway is closely associated with chronic inflammation and oxidative stress in cancers by opposing the peroxisome proliferator-activated receptor (PPAR)-γ signaling [233]. IL-1β, IL2, and tumor necrosis factor (TNF)-α render the inflammatory microenvironment more tumorigenic. The pro-inflammatory mediators released during the chronic inflammation induce NFκB, MAPK, nuclear factor erythroid 2-related factor 2, PI3K, JAK/STAT, and Wnt/β-catenin [234]. Induction of Wnt is associated with Wnt ligands’ secretion that stimulates tumor-associated macrophages to produce IL-1β, thus driving systemic inflammation [235]. TAMs are mainly alternatively activated M2 macrophages with immunosuppressive and tumorpromoting capabilities. Hypoxic environment and hypoxia-treated glioma cell supernatants can polarize macrophages toward an M2 phenotype through TGF-β [236]. TNF-α derived from M2 tumor-associated macrophages promotes EMT and cancer stemness through the Wnt/β-catenin pathway. Reprogramming TAMs towards classically activated M1 macrophages may thwart tumor-associated immunosuppression and unleash anti-tumor immunity [237] (Fig. 7.1). The up-regulation of Wnt/β-catenin signaling may be due to NOTCH blockade, promoting the proliferation and pro-oncogenic cytokine production of Kupffer cell-like TAMs in the liver, facilitating cancer progression and metastasis [238]. Tumor-infiltrating MDSCs reduce NOTCH1/2 [239]. MDSCs are immature myeloid cells recruited by VEGF and IL-1β to sites of inflammation and the tumor microenvironment to prevent immune-mediated damage [240, 241] (Fig. 7.1).

7.1.6.1

Non-coding RNAs and Anti-tumor Immunity

Low levels of miR-181b are associated with EGFR-dependent vascular cell adhesion molecule (VCAM)-1 expression and monocyte infiltration [242]. The increase of let-7e, miR-125, miR-146a, miR-146b, and miR-155 induces differentiation of monocytes to MDSCs, increasing the resistance to immunotherapy in melanoma patients [243]. Besides, miR-146a is involved in the induction by STAT3 of tumor-derived factors, such as IL-6, IL-10, and VEGF, to ensure persistent STAT3 activation in the tumor microenvironment through cross-talk between tumor cells and tumor-associated immune cells. Activated STAT3 by this “positive feedback loop” further promotes the expression of growth factors and angiogenic factors, which then represses the effects of the host anti-tumor responses and accelerates tumor growth and metastasis [244]. MiR-9 also induces the differentiation of MDSCs by targeting RUNX1 [245]. Exosome-derived miR-9, miR30a, and miR-181a activate the JAK/STAT signaling pathway via targeting SOCS3, thereby promoting the expansion of MDSCs [246, 247]. By down-regulating JAK2

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and STAT1, miR-21 inhibits the IFN-γ-induced STAT1 signaling pathway required for macrophage M1 polarization. Inhibition of STAT1 by miR-21 also results in the down-regulation of programmed cell death-1 (PD1)/PD-L1, which induces the immune system to escape [248, 249]. MiR-21-5p-enriched exosomes from hypoxiaprimed mesenchymal cells promoted lung cancer development by reducing apoptosis and promoting macrophage M2 polarization [250]. Also, miR-21 induces MDSC differentiation [251]. MiR-155 inhibits the expression of p38 in DCs, and thereby their anti-tumor response. MiR-155 also inhibits CD8+ T cells’ anti-tumor activity by targeting FOXO3A, up-regulating AKT and STAT5, and suppressing T cells’ proliferative and invasive activities. Further, the interaction between STAT5 and mTOR is crucial for maintaining FoxO3a-positive Treg cells [252–254]. MiR-223, enriched in microvesicles of IL4 activated M2 macrophages, induces the accumulation of M2 macrophages [255, 256]. HOTAIR also attracts macrophages, which induce cancer cell proliferation, and differentiates MDSCs, allowing immune escape and decreasing cancer cell death [257, 258]. Small LIN28 inhibitors increased let-7 leading to reactivation of anti-tumor immunity. Besides, they inhibited cancer cell proliferation, migration, and invasion by inhibiting downstream gene MYC [259–262]. Suppression of let-7 increased M2 macrophages and abated recruitment of activated cytotoxic T lymphocytes [263]. Reciprocally, Wnt pathway activation leads to an increase of H19, which in turn decreases Let-7c bioavailability. In contrast to H19, miR-146a increases the Let-7c level through degrading LIN28 [264, 265]. ANRIL in prostate cancer is associated with increased TGF-β1 and pSMAD2 and decreased pSMAD7 by suppressing let-7a [266]. The decrease of miR-17 results in increased reactive oxygen species (ROS) and STAT3, thereby inducing MDSCs [267]. UCA1 represses miR-26a/b, miR-193a, and miR-214, thereby inducing PD-L1 and cancer cell immune escape [268]. Further, the activation of NFκB signaling and inflammation in non-small cell lung cancer cells decreases mir-26a [269]. The actin filament associated protein 1 (AFAP1) antisense RNA (AFAP1-AS1) silenced miR-26a, retaining the M2 macrophage phenotype [270]. The inhibition of protein tyrosine phosphatase-1B induces M2 macrophage polarization via reducing miR-26a, enhancing mitogen-activated protein kinase phosphatase-1 (MKP1) expression [271]. Low miR-34a is also associated with decreased anti-tumor immunity by increasing C–C motif chemokine ligand 22 (CCL22), which recruits Treg cells to facilitate immune escape [272–274]. PVT1 silences miR-150 resulting in overexpression of hypoxia-inducible protein 2 that promotes the immune escape from NK cells through an IL13/STAT3 signaling pathway [275, 276]. Low expression of miR-150 is also associated with tumor invasion induced by CCL20 and IL22, which also lowers anti-tumor immunity and protects stemness [277, 278]. PVT1 also increases the production of inflammatory cytokines IL8, TNF-α, and IL-1β by sponging miR-149 [279]. Overexpression of miR-130 and miR-33 in exosomes decreases tumor progression by shifting macrophage polarization from M2 to M1 phenotype [280]. MiR-155 reprograms TAMs to pro-inflammatory, anti-tumor macrophages, possibly through the targeting of CCAAT enhancer-binding protein (c/EBP)-β [281] (Fig. 7.1).

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Non-coding RNAs and Cancer Cell Apoptosis

MiR-107/miR-130a impeded apoptosis through targeting PTEN. Circ-ZFR promoted apoptosis by sponging miR-130a/miR-107 [282]. MiR-146a silences the DNA damage-inducible transcript 3, a mediator of endoplasmic reticulum stress that usually promotes stress-induced apoptosis [283]. Down-regulation of miR-146a induces apoptosis by inducing TRAF6 and NF-κB protein expression, increased IL6, IL17A, IL21 levels, and enhanced p-STAT3 protein expression. The inhibition of TRAF6 attenuated anti-miR-146a effects on Th17 cell differentiation’s function to modulate apoptosis [284]. HOTAIR silences miR-218, thereby inducing cancer cell viability by upregulating VOPP1 WW domain-binding protein and preventing apoptosis through oxidative cellular injury [285, 286]. MALAT1 increases β-catenin by silencing miR142-3p, increasing proliferation and migration, and inhibiting apoptosis of non-small cell lung cancer cells [287]. ANRIL inhibits apoptosis by silencing miR-144 [288]. Stemness-inducers LIN28a and LIN28B inhibit let-7 and promote an insulinsensitized state that protects against cell senescence [289, 290]. MiR-9 induces apoptosis. However, MEG3, NEAT1, and TUG1 silence miR-9, protecting cancer cells against apoptosis. The silencing of miR-9 also promotes the invasion of cancer cells by inducing β-galactoside α-2,6-sialyltransferase 1 that increases the expression of IL8 [291–294]. Suppression of miR-17–92 and miR-106b up-regulates BCL2 like 11 (BCL2L11 or BIM), which is a significant determinant for initiating the intrinsic apoptotic pathway. Under physiological conditions, BIM is essential for shaping immune responses where its absence promotes autoimmunity. However, too early BIM induction eliminates cytotoxic T cells prematurely, resulting in chronic inflammation and tumor progression [295]. The decrease of miR-26a in hepatocellular carcinoma is associated with reduced p53-induced mitochondrial apoptosis, contributing to chronic lymphocytic leukemia development [296, 297]. H19 inhibits apoptosis by sponging miR-29b-3p, thereby enhancing the MCL1 apoptosis regulator, BCL2 family member [298]. Further, the decrease of miR-29 up-regulates FGF2, thereby inhibiting apoptosis [299]. Non-coding RNA activated by DNA damage (NORAD) and PVT1 inhibit apoptosis by silencing miR-30a and miR-16-5p and up-regulating ADAM metallopeptidase domain 19 (ADAM19) [138, 300]. MiR-34a induces apoptosis by targeting high mobility group box 1 [301]. However, LINC-ROR may prevent apoptosis by silencing miR-34a, thereby decreasing NOTCH1 and BCL2 expression [302]. MIAT, NEAT1, and XIST silence miR-133 in tumors [303–306]. Decrease of miR-133, together with that of miR-1 and miR-218, is associated with overexpression of TNF-related apoptosis-inducing ligand (TRAIL). TRAIL is a potent anti-cancer agent specifically targeting cancerous cells while sparing healthy cells. However, resistance to TRAIL occurs. Tumors become resistant to TRAIL-induced apoptosis by the effect of TRAIL on T cells [307]. Low miR-133 is also associated with increased p21, thereby increasing mRNA and protein expressions of proliferating cell nuclear antigen, antigen identified by monoclonal antibody Ki 67 (Ki67), CCNE, CDK2, and BCL2, and decreasing expression of BCL2 associated X, apoptosis regulator (BAX), resulting in increased proliferation and decreased apoptosis [308–311].

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Further, a low miR-143-145 expression is associated with reducing caspase 3 and 7 activity and induction of BCL2, protects against apoptosis, and cellular cytotoxicity [312, 313]. TUG1 increases cancer cell viability, proliferation, and migration and decreases apoptosis through the silencing of miR-145-5p that inhibits Rho-associated coiled-coil containing protein kinase 1 [314, 315]. In contrast, overexpression of the BRISC and BRCA1 A complex member 2 (BABAM2) antisense RNA 1 (BABAM2AS1 or BRE-AS1) induces miR-145 to inhibit proliferation and promote apoptosis of prostate cancer cells [316, 317]. MIAT, ZFAS1, and PVT1 silence miR-150, associated with increased expression of the MYB proto-oncogene, transcription factor and the RAB9A member Ras oncogene family resulting in increased proliferation, migration, and invasion of cancer cells, and protection against apoptosis by de-repression of NOTCH3 [217, 318–322]. MiR-124 suppresses programmed cell death (PDCD)-6 expression, inducing apoptosis [323]. MiR-181a/b induce apoptosis by targeting BCL2 [324, 325]. The decrease of GAS5 induces apoptosis because of the up-regulation of miR-378 [326] (Fig. 7.1).

7.1.7 Cancer Cell Proliferation Above, we showed that EMT, insulin sensitivity, escape of anti-tumor immunity, and increased angiogenesis contributed to cancer cell proliferation.

7.1.7.1

Non-coding RNAs and Cancer Cell Proliferation

Up-regulation of STAT3/miR-21 signaling induces Wnt/β-catenin and represses cellcycle arrest by down-regulating MEG3 and increasing miR-141, silencing PDCD4 [327–329]. The PDCD4 antisense RNA 1 (PDCD4-AS1) de-represses PDCD4, but its expression is low in cancer cells [330, 331]. MiR-130 enhances cancer cell proliferation by targeting transforming growth factor-beta receptor 2 [332]. MiR-130 may, however, be silenced by the mitochondrial ribosomal protein L19 lncRNA (lncRNA MRPL39) and the FYVE, RhoGEF, and PH domain containing 5 (FGD5) antisense RNA 1 (FGD5-AS1) [333, 334]. MiR-181a and miR-181d promote cancer cell proliferation through E2F transcription factor 1 (E2F1) [335], but miR-181a inhibits cancer cell proliferation by targeting CDK1 [336]. The high mobility group AT-hook 1 (HMGA1, formerly HMG-I/Y) induces the expression of miR-221-222, exacerbating tumor growth through regulating the cell cycle by increasing CCND1 and CCNE1 and migration by silencing TIMP metallopeptidase inhibitor 3 (TIMP3) [337]. MiR-223 is either endogenously expressed by myeloid cells or secreted in extracellular vesicles targeting cancer cells. There, miR-223 acts either as a tumor promoter or as a tumor suppressor in a context-dependent manner. For example, the NFκB-dependent stimulation of miR-223-3p promotes the proliferation and migration of gastric cancer cells by directly targeting the AT-rich interaction domain 1A

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[338]. However, miR-223-3p-induced up-regulation of p53 expression in a feedback loop inhibits proliferation and migration of squamous cell carcinoma cells [339]. The decrease of miR-223-5p in non-small cell lung cancer tissues enhances proliferation and migration by up-regulating E2F8 [340]. The increase or decrease of miR-223 depends on GAS5 expression [341]. H19 promotes proliferation, migration, and invasion of breast cancer and colorectal cancer cells by sponging miR-93-5p, thereby enhancing the expression of STAT3, as was shown for miR-17 [342]. MALAT1 inhibits the binding of miR-497 to eukaryotic translation initiation factor 4E (EIF4E), leading to increased translation of mRNAs encoding proteins required for cell cycle progression, survival, and proliferation and increased nuclear transport of mRNA encoding CCND1 [343, 344]. NEAT1 induced by hypoxia and LIN28B induces cancer cells’ proliferation by activating TGF-β and Wnt/β-catenin signals through silencing miR-101-p, miR-139-5p, miR-339-5p, miR-495-3p, and miR-506 [345– 350]. TUG1 increases proliferation by increasing CCND1 expression and induces migration by increasing MMP-9 expression [351]. UCA1 promotes tumor growth via sponging miR-28-5p and upregulating homeobox B3 by silencing miR-204 and up-regulating C-X-C motif chemokine receptor 4 (CXCR4), by sponging miR-298 and increasing CDK6 expression, and by binding to miR-495-3p and up-regulating particular AT-rich-binding protein 1 [352–356]. Messenger RNA of the insulin-like growth factor 2 binding protein binds on the ACACCC motifs within UCA1 and prevents the association of miR-122-5p with UCA1, thereby shifting the availability of miR-122-5p from UCA1 to the target mRNAs and reducing the UCA1-mediated cell invasion [357]. XIST promotes proliferation and migration of non-small cell lung cancer cells via sponging miR-16, thereby up-regulating CDK8 expression, and by inducing TGF-β2 expression by targeting miR-141-3p [358, 359]. However, the down-regulation of XIST promotes tumor growth by increasing the expression of miR-497-5p that silences PDCD4 [360, 361]. ZFAS1 induces cancer cell proliferation via silencing miR-200b-3p and miR-484, thereby inducing the Wnt signal [362, 363]. Also, CDKN2B antisense RNA 1 (ANRIL) promotes proliferation and migration of prostate cancer cells by silencing let-7a, thereby inducing the TGF-β/SMAD pathway and by silencing miR-122-5p, thereby inducing the miR-125a-3p/fibroblast growth factor receptor 1/mitogen-activated protein kinase (MAPK) pathway [266, 364, 365]. However, in many tumors, ANRIL correlates positively with tumor suppressors cyclin-dependent kinase inhibitor 2A (p16-CDKN2A), cyclin-dependent kinase inhibitor 2B (p15-CDKN2B), and a splice variant of CDKN2A (p14-ARF). ANRIL and p14-ARF correlated the most through the activation of a bidirectional p14-ARF/ANRIL promoter [366]. The bladder cancer-associated transcript one lncRNA (BLACAT1), HNF1A antisense RNA 1 (HNF1A-AS1), HOTAIR, and H19, and the circ-RNA derived from exons 15 and 16 of the SWI/SNF related, matrix associated, actin-dependent regulator of chromatin, subfamily a, member 4 (cSMARCA4) silence the miR-17 family, increasing cancer cell proliferation [367–373]. In contrast, SOX4 up-regulates the miR-17-92 cluster by downregulating Rb1 protein expression in prostate cancer

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cells, thereby inducing proliferation, migration, and invasion [374, 375]. High miR17, due to the increase of NEAT1 and the decrease of circ-MTO1 and the itchy E3 ubiquitin-protein ligase circ-RNA (circ-ITCH), activates NOTCH signaling [376, 377]. Low miR-26 induces cancer cell growth by up-regulating MYC and MAPK6 [378–380]. A forkhead box O1 (FOXO1)-MALAT1-miR-26a-5p feedback loop mediates the proliferation and migration of osteosarcoma cells [381]. The decrease of miR-29 in hepatocellular cancer increases the expression of CCNA and CCND1 [382]. PVT1 induces the proliferation of cervical cancer cells by silencing miR-140 and up-regulating SMAD3, by silencing miR-31 and up-regulating CDK1, and by silencing miR-126 up-regulating solute carrier family 7 member 5 (SLC7A5) [137, 383–385]. The potassium voltage-gated channel subfamily Q member 1 (KCNQ1) opposite strand/antisense transcript 1, TUG1, and zinc finger E-box-binding homeobox two antisense RNA 1 (ZEB1-AS1) induce cancer cell proliferation by sponging miR-145, thereby inducing HIF-1α, CCNE2, ER-α, and Rho-associated coiled-coil containing protein kinase 1 [314, 315, 386–388]. Down-regulation of miR-146a-5p is also induced by MYC and associated with increased proliferation, invasion, and migration of breast cancer cells by upregulating IRAK1 [389, 390]. Silencing of miR-181a by the anaphase-promoting complex subunit 7 circ-RNA (circ-ANAPC7) induces cancer cell proliferation, colony formation, and cell invasion capacities by increasing CCNB1 and CCND1 [336, 391, 392]. Metformin induces miR-378 that silences CDK1, leading to suppression of cell proliferation in hepatocellular carcinoma [393] (Fig. 7.1).

7.1.8 EGFR Signaling and Cancer Progression TGF-β transactivates the epidermal growth factor receptor (EGFR) and facilitates cancer progression through Ras. Ras is a membrane-associated guanine nucleotidebinding protein activated in response to growth factors and T-cell receptors. Ras activates several signaling pathways involving extracellular signal-regulated kinases (ERKs), which promote cell detachment from the ECM and motility. Most of the indirect ERK targets localize in the nucleus. The ERKs modulate the activity of proteins implicated in RNA transport/metabolism. They regulate MYC, Fos proto-oncogene, AP-1 transcription factor subunit (FOS), and Jun proto-oncogene, AP-1 transcription factor subunit (JUN) involved in stemness [394–397]. Other common ERK targets include proteins implicated in cell cycle regulation, apoptosis, and signaling pathways involving TGF-β, PI3K/AKT, MAPK, insulin, and FOXO, contributing to cross-talk and feedback regulation [398]. ER-α36 mediates estrogen-stimulated MAPK/ERK activation and regulates migration, invasion, proliferation in cervical cancer cells [399]. Estrogen and insulin synergistically promote endometrial cancer progression via cross-talk between PI3K/AKT, MAPK, and ERK [400] (Fig. 7.2).

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Fig. 7.2 BMI1, EZH2, and ERK in cancer. TGF-β, UCA1, ZFAS1, circ-HIPK3, and ciRs-7 all silencing miR-7, and PVT1, silencing miR-455, induce EGF/EGFR signaling. The decrease of miR133 and GAS5 enhances this. MiR-221-222 inhibits EGFR signaling. Increased EGF/EGFR leads to Ras/Raf/MAPK/ERK signaling, possibly by increasing miR-9 and LINC-ROR and decreasing miR-29a, miR-30a, and miR-34a and miR-150, both silenced by MIAT. Induction of ERK causes detachment of cancer cells from ECM, activation of PI3K/AKT signaling, and stemness via MYC, FOS, and JUN, inducing stemness. ERK signaling is further activated through insulin and estrogen but inhibited by miR-221-222. TGF-β interacts with cytokine receptors and induces PI3K/AKT signaling by activating BMI1 and EZH2, which inhibit PTEN. The increase in BMI1 is due to the increase of HOTAIR. High HOTAIR and MALAT1, and low miR-26a, miR-34a, silenced by TUG1, and miR-124 induce EZH2 and recruit EZH2 to its target genes, thereby inducing stemness. Increased non-coding RNAs are in red; decreased in green

7.1.8.1

Non-coding RNAs and EGFR Signaling

A decrease of miR-7 is associated with increased proliferation and decreased apoptosis by increasing PI3K and EGFR, the thyroid receptor interactor protein 6, and MAP3K9 that activates the MAP2K7 (or MEK)/ERK and the NFκB pathway [401– 405]. UCA1 up-regulation promotes hypoxia-resistant gastric cancer cells’ migration through the miR-7-5p/EGFR axis and increased PI3K/AKT/mTOR signaling

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[406, 407]. ZFAS1 in colorectal cancer cells silences miR-7-5p, increasing proliferation, migration, and invasion, and inhibiting apoptosis [408]. c-MYB-induced circ-HIPK3 promotes colorectal cancer growth and metastasis by sponging miR7, thereby increasing the expression of miR-7 target EGFR [139]. Up-regulation of the circular cerebellar degeneration related protein 1 antisense RNA (ciRs7 or CDR1-AS) abrogated the tumor-suppressive roles of miR-7, including cell proliferation, migration, and invasion by de-repressing the homeobox 13-mediated NFκB/p65 pathway, inducing PTEN/PI3K/AKT pathway, and increasing expression of EGFR and CCNE1 [409–411]. Down-regulation of miR-133 induces EGFR [412, 413]. RUNX2-mediated up-regulation of PVT1 silenced miR-455, associated with increased expression of EGFR promoting proliferation and migration of cancer cells [414, 415]. Down-regulation of GAS5 in lung adenocarcinoma associated with increased expression of EGFR [142]. The increase of miR-9 activates the Ras/Raf/MAPK/ERK signaling that, together with activation of the PI3K/AKT/mTOR pathway, leads to cancer cell proliferation and chemoresistance [416]. LINC-ROR induces phosphorylated MAPK/ERK signaling by stabilizing the ERK-specific phosphatase dual-specificity phosphatase 7, also known as MKP-X, activating estrogen receptor signaling [417]. Downregulation of miR-29a is associated with activation of MAPK8 (or JNK) and p38MAPK/ERK and CDK6, thereby promoting cancer cell migration and inhibiting apoptosis [418]. A decrease of miR-30a was associated with the activation of the Ras/Raf/MEK/ERK signaling pathway in hepatocellular carcinoma [419]. MIAT silences miR-34a, increasing ERK and phosphorylated PI3K/AKT resulting in enhanced lymph node metastasis [301, 420]. MIAT also silences miR-150, associated with cancer cell proliferation by inducing AKT/ERK signaling and expression of CCND1, CDK4, and CDK6 [421, 422]. In contrast, miR-221 silences ADAMTS6, suppressing cell migration by inhibiting EGFR and ERK1/2 [423] (Fig. 7.2).

7.1.9 BMI1 and EZH2 in Cancer Progression Oncogenes such as the BMI1 proto-oncogene, polycombing ring finger 1 (BMI1), and enhancer of zeste 2 polycomb repressive complex 2 (EZH2) are upstream regulators and downstream targets of the PI3K/AKT pathway. TGF-β induces BMI1 and EZH2 [424]. BMI1 downregulates PTEN that antagonizes the PI3K/AKT signaling pathway [425]. However, in prostate cancer cells, PTEN reduces the function of BMI1 to prevent tumorigenesis, indicating that a PTEN/BMI-1 double-negative feedback loop may occur and govern EMT in certain types of cancer [426]. EZH2 induces cancer cell stemness and EMT [427, 428]. Further, inhibition of EZH2 may increase PTEN expression, thereby decreasing pAKT expression and inducing cell apoptosis [428]. However, PTEN loses its ability to inhibit PI3K/AKT signaling by phosphorylation, ubiquitination, acetylation, and oxidation [429]. PI3K/AKT, as in the pancreas, activates mTORC1 and mTORC2, inducing cancer

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cell growth, proliferation, migration, and invasion. But mTORC1 hyperactivation also leads to feedback inhibition of the PI3K/AKT signaling (Fig. 7.2).

7.1.9.1

Non-coding RNAs and BMI1 and EZH2

HOTAIR silences miR-148b, thereby increasing the expression of BMI1 that favors cancer stemness [430, 431]. Also, HOTAIR interacts with EZH2 and recruits it to the target gene promoters/loci. EZH2 introduces H3K27-trimethylation, and LSD1 demethylates H3K4 and contributes to gene silencing (Fig. 1.5). CDK1/2 favors the interaction between EZH2 and HOTAIR and not between BRCA1 DNA repair associated (BRCA1) and EZH2 [432]. MALAT1 upregulates EZH2 by sponging miR-217, miR-218, and miR-363-3p [433, 434]. The small nucleolar RNA host gene 6 (SNHG6) lncRNA promotes EMT by silencing miR-26a, thereby upregulating the EZH2 axis, which inhibits the production of Th1 type chemokines such as the chemokine C-X-C motif ligand (CXCL)-9 and CXCL10, thereby compromising the trafficking of tumor-specific T cells, which mediate cytotoxic effects on cancer cells and promote anti-tumor function [435]. TUG1 promotes EMT with cell proliferation and migration by suppressing miR-34a and miR-382 via recruiting EZH2 in adriamycin-resistant acute myeloid leukemia tissues suppressing PDCD4 expression [436–438]. Down-regulation of miR-124 enhances growth and inhibits radiation-induced apoptosis and cisplatin-resistance of lung cancer by inducing the EZH2-STAT3 signaling axis [439] (Fig. 7.2).

7.2 Non-coding RNAs Related to Metabolic and Cardiovascular Diseases Are also Involved in Cancer Progression Above, we identified let-7, miR-1, miR-7, miR-9, miR-17, miR-21, miR-26a, miR29, miR-30a, miR-34a, miR-124, miR-130, miR-143/145, miR-146a, miR-150, miR155, miR-181, miR-221/222, miR-223, miR-378 and miR-455 as pre-dominant miRs linking metabolic to cardiovascular diseases. GAS5, HOTAIR, H19, lincRNA-p21, LINC-ROR, MALAT1, MEG3, MIAT, NEAT1, TUG1, UCA1, ANRIL, and PVT1 regulate this cluster of miRs related to cancer.

7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic Diseases and Cancer Table 7.1 gives an overview of the actions of non-coding RNAs in the development of cardiometabolic diseases and cancer. Low miR-1, miR-26a, miR-133, miR-378, and miR-455, and high miR-155, HOTAIR, LINC-ROR, TUG1, and XIST are typically

Low

Cancer

• Induces cardiac hypertrophy • Induces cardiogenesis and cardiac fibrosis with ECM deposition • Increases CM death

• Increases CM cell death

miR-1

miR-7

• Increases the number of stem cells which differentiate to β cells • Reduces mature β cell mass, blocks insulin secretion and reduces insulin sensitivity

• Promotes β cell expansion • Let7-d: promotes M2 to M1 macrophage polarization • Let7-b: promotes apoptosis

• Induces stemness • Induces EMT • Induces IGF1R and EGFR signaling

• Induces stemness • Increases EMT • Promotes glycolysis

• Reduces the number of • Induces stemness, except adipocyte precursors and let7i-5p that inhibits stemness • Promotes M2 macrophage impaired white adipogenesis accumulation and represses • Let-7a: promotes angiogenesis cytotoxic T-cell-mediated • Let7-b: induces NO and anti-tumor immunity decreases ROS • Let-7c: promotes monocyte to dendritic cell differentiation • Let-7e: promotes M2 to M1 macrophage polarization • Let-7 g: protects from the miR-21-induced reduction of Treg cells and reduces foam cell generation • Let-7 family: cardiac hypertrophy and fibrosis

High

Let-7

MiRs

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 Overview of the role of non-coding RNAs in the pathogenesis of cardiometabolic diseases and cancer

(continued)

• Let-7 induces MDSCs and immune escape

High

168 7 Non-coding RNAs Related to Cardiometabolic Diseases …

miR-9

• Induces monocyte to M2 macrophage differentiation

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• Represses beige adipocyte maturation • Increases EPC migration and angiogenesis • Reduces maturation and proliferation of insulin-secreting β cells • Induces M1 macrophage polarization and foam cell generation • Induces cardiac hypertrophy and remodeling

High

Low

Cancer

(continued)

• Maintains stemness and increases EMT by inhibiting E-cadherin, but may inhibit EMT by targeting TWIST • Blocks PTEN, thereby increasing PI3K/AKT signaling • Blocks IGF1R signaling • Reduces anti-tumor immunity by increasing MDSCs • Increases angiogenesis • Induces apoptosis

High

7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic … 169

miR-17

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued) Low

Cancer High

• Impairs IGF1 signaling, • Increases EMT and cancer cell • Induces cancer cell glucose transport and Induces proliferation proliferation by inhibiting • Reduces anti-tumor immunity inflammation-associated PTEN, thereby activating by inducing MDSCs insulin resistance AKT/mTOR signaling, and by • Regulates EC proliferation but • Reduces cancer cell targeting the Rb family, and by senescence and death inhibits angiogenesis mediating MYB • Increases recruitment of • Hampers IGF1-driven tumor monocytes and differentiation growth • miR-17-92: impairs of monocytes to dendritic cells and M1 macrophages. angiogenesis Reduces T reg cells • Promotes hepatic steatosis and cardiac fibrosis • Causes mitochondrial dysfunction and ROS release; induces apoptosis (continued)

High

170 7 Non-coding RNAs Related to Cardiometabolic Diseases …

miR-21

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• Reduces the number of white adipocyte precursors but increases adiponectin signaling and improves insulin sensitivity • Induces differentiation of stem cells to ECs, and increases angiogenesis • Reduces the number of Treg cells and induces differentiation of monocytes to macrophages and fibroblasts, but prevents extreme inflammation by retaining M2 macrophage phenotype • Induces VSMC proliferation • Promotes cardiac hypertrophy and fibrosis and hepatic steatosis • Reduces cell death

High

Low

Cancer • • • •

(continued)

Induces EMT Inhibits PTEN Increases angiogenesis Reduces anti-tumor immunity by favoring M2 macrophage polarization and MDSC differentiation

High

7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic … 171

• Increases white adipogenesis

miR-29a

• Impairs insulin secretion and IRS signaling • Reverts reduction of anti-inflammatory Th2 and Treg cells resulting from a decrease of miR-133 • Induces fibrous cap formation but prevents necrotic core formation in atherosclerotic plaques • Induces cardiac hypertrophy and fibrosis and hepatic steatosis

• Impairs brown adipogenesis • Induces maturation of • Impairs maturation of insulin-secreting β cells and insulin-secreting β cells and insulin secretion in response to insulin secretion in response to high glucose high glucose • Impairs angiogenesis • Increases angiogenesis • Converts contractile to • Increases VSMC proliferation synthetic VSMCs • Reduces cardiac hypertrophy and ECM deposition • Suppresses FA uptake in the liver • Attenuates apoptosis

High

miR-26a

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• Induces stemness • Increases EMT • Activation of ERK and PI3K signaling • Increases angiogenesis • Reduces cancer cell death

• Promotes EMT • Increases IGF1, leading to PI3K/AKT activation • Increases angiogenesis • Reduces anti-tumor immunity • Reduces apoptosis

Low

Cancer

(continued)

• Inhibits PTEN, activating PI3K

• Decreases PTEN, leading to PI3K/AKT activation

High

172 7 Non-coding RNAs Related to Cardiometabolic Diseases …

miR-30

• Induces cardiac hypertrophy and fibrosis

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• miR-30a: promotes white adipogenesis • miR-30b/c: promotes brown adipogenesis • Blocks M1 macrophage polarization and reduces inflammatory T cells and inflammation-associated insulin resistance • Prevents inflammation but induces lipid deposition in the liver

High • miR-30a: Induces stemness • Increases EMT • Induces IGF1R/IRS1 and ERK signaling • Reduced cancer cell death

Low

Cancer

(continued)

• Induces MDSCs and immune escape

High

7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic … 173

miR-34a

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• Reduces the number of white adipocyte and VSMC precursors • Impairs white and brown adipogenesis but inhibits lipid deposition in WAT • Represses maturation and proliferation of insulin-secreting β cells • Impairs angiogenesis • Induces M1 macrophage polarization and impairs cholesterol efflux • Induces cardiac fibrosis and hepatic steatosis; limits FA oxidation • Increases cell senescence and death

High • Induces stemness • Promotes EMT • Increases PI3K/AKT signaling; increase of EZH2, inhibiting PTEN • Increases glycolysis • Increases angiogenesis • Increases the number of Treg cells and reduces anti-tumor immunity

Low

Cancer • Increases apoptosis

High

(continued)

174 7 Non-coding RNAs Related to Cardiometabolic Diseases …

miR-130

miR-124a

• Decreases FABP4 • Increases M1 macrophage polarization • Induces de-differentiation of contractile to synthetic VSMCs with increased proliferation

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• Represses white adipocyte maturation and induces inflammation in WAT • miR-130b: protects precursor cells in the pancreas • Increases angiogenesis and NO release • miR-130: decreases inflammatory cytokines and inhibits lipid accumulation • Induces cardiac fibrosis

• Differentiates stem cells in adipose tissue • Impairs maturation of white adipocytes and β cell proliferation and AKT and insulin signaling • Impairs angiogenesis • Blocks ROS release • Increases cell senescence and death

High Induces stemness Promotes EMT Increases angiogenesis Inhibits apoptosis

• miR-130b: induces EMT

• • • •

Low

Cancer

(continued)

• miR-130b: induces angiogenesis • Induces M1 macrophage polarisation, increases immune response • Represses apoptosis

High

7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic … 175

• Brown adipogenesis requires the down-regulation of miR-133, which results in increased expression of PRDM16 • Increases M1 macrophage polarization and number of inflammatory T cells • Promotes cardiac hypertrophy and fibrosis • Increased apoptosis

• Converts VSMCs to macrophage-like cells with an impaired phagocytic capacity

miR-133

miR-143-145

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• Blocks the proliferation of white adipocyte precursors • Blocks reprogramming of mature β cells to proliferating pluripotent stem cells • Impairs insulin signaling • Increases angiogenesis • Activates EC and VSMC cross-talk and maintains VSM contractility • Induces M1 macrophage polarization • Impairs cholesterol efflux and promotes hepatic steatosis

• miR-133a: increases differentiation of beige adipocytes in response to cold exposure • Induces cardiogenesis

High

• • • •

Induces stemness Promotes EMT Increases glycolysis Represses apoptosis

• Induces EMT by up-regulation of EGFR

Low

Cancer High

(continued)

176 7 Non-coding RNAs Related to Cardiometabolic Diseases …

• miR-146b: impairs adiponectin signaling and induces mitochondrial dysfunction and inflammation without insulin resistance when adiponectin is low • MiR-146a: increases lipid accumulation in liver and hepatic steatosis

• Increases monocyte infiltration in the heart and associated with cardiac hypertrophy fibrosis • Decreases cell death

miR-146

miR-150

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• Impairs brown adipogenesis • Impairs angiogenesis • Blocks DC activation induced by inflammatory T cells • Promotes hepatic steatosis and insulin resistance • Increases cell death

• miR-146a: blocks white adipocyte precursor proliferation • miR-146a: blocks reprogramming of β cells to pluripotent stem cells • Impairs PI3K/AKT signaling • miR-146a: blocks M1 macrophage polarization and scavenger-receptor-mediated uptake of ox-LDL; increases the number of Th1 but decreases the number of Th17 cells • Induces de-differentiation of contractile to synthetic proliferating VSMCs • Promotes cardiac hypertrophy and cardiac fibrosis • Increases cell senescence and death

High

• Induces EMT • Induces ERK and cancer cell proliferation • Increases angiogenesis • Reduces anti-tumor immunity • Decreases cancer cell death

• miR-146a: induces stemness • miR-146b; blocks stemness • miR-146a and miR-146b: reduce anti-tumor immunity by inducing MDSCs • Inhibits angiogenesis

Low

Cancer

(continued)

• miR-146a: increases apoptosis

High

7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic … 177

• Induces lipid accumulation in WAT; impairs beige adipogenesis • Impairs reprogramming of β cells to pluripotent stem cells and reduces insulin signaling • Causes oxidative and endoplasmic reticulum stress and inflammation • Impairs VSMC contractility and NO vasorelaxation • Promotes cardiac hypertrophy and fibrosis • Induces apoptosis

• miR-181d: impairs white • miR-181a: increases withe adipocyte maturation adipocyte precursor • miR-181b: reduces IGF1R and proliferation insulin signaling • miR-181a: reverts M1 • miR-181b: increases ROS and macrophage polarization and M1 macrophage polarization reduces cardiac inflammation • miR-181b: induces and oxidative stress microthrombus formation • miR-181a/b: blocks M1 macrophage polarization but • Decreases cell death induces lipid deposition in the liver

miR-181

High

miR-155

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• miR-181b: increases monocyte infiltration in tumors

Low

Cancer Induces EMT Induces IGF1 signaling Induces glycolysis Promotes angiogenesis Induces MDSCs and immune escape

(continued)

• miR-181b: suppresses EMT • miR-181b: increases AKT signaling • miR-181a: induces MDSCs • Induces apoptosis

• • • • •

High

178 7 Non-coding RNAs Related to Cardiometabolic Diseases …

miR-221-222

• Increased angiogenesis in advanced plaques

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• Induces insulin resistance and inflammation in WAT • Decreases insulin secretion • Reduces angiogenesis in new plaques • Induces shift from M1 to M2 macrophages and suppresses ox-LDL-induced inflammation • Induces de-differentiation of contractile to synthetic proliferating VSMCs • Induces atherosclerotic plaque calcification • Induces hepatic steatosis but blocks cardiac fibrosis

High

Low

Cancer

(continued)

• Maintains stemness • Promotes EMT • Represses PTEN and induces PI3K/AKT signaling but acts anti-oncogenic by repressing EGFR and ERK

High

7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic … 179

• Increases brown adipogenesis • Ices EMT and thermogenesis to counteract inflammation-induced obesity • Restores PI3K/AKT signaling • Promotes reverse cholesterol transport • Increases VSMC proliferation • Protects from cardiac and liver fibrosis • Inhibits apoptosis by maintaining insulin signaling

miR-378

Low

Cancer • De-represses maturation of β cells but represses IGF1R and insulin signaling • Impairs angiogenesis • Blocks M1 macrophage polarization • Blocks cholesterol biosynthesis and uptake of HDL-associated cholesteryl esters; promotes cholesterol efflux • Induces cardiac hypertrophy and inflammation • Increases cell death

High

miR-223

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

(continued)

• Induces shift from glycolysis to OXPHOS, reducing cancer cell proliferation and migration • Induces cancer cell death

• Induces or inhibits cancer cell proliferation in a context-dependent manner • Inhibits PTEN and induces PI3K/AKT signaling and cancer cell proliferation. However, it inhibits proliferation by up-regulating p53 • Increases the number of M2 macrophages

High

180 7 Non-coding RNAs Related to Cardiometabolic Diseases …

HOTAIR

GAS5

LncRNAs

miR-455

• Suppresses EC and VSMC cross-talk • Reduces cell death by up-regulation of miR-21

• Induces M1 macrophage polarization • Induces hepatic steatosis

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• Increases EMT • Induces IGF1R and EGFR signaling

Low

Cancer

• Increases white adipocyte differentiation • Impairs β cell proliferation and induces insulin resistance • Increases M1 macrophage polarization

• Impairs white adipocyte • Induces IGF1R and EGFR precursor proliferation and signaling adipogenesis but maintains β • Induces cancer cell death through miR-378 cell maturation and insulin secretion • Suppresses VSMC proliferation by silencing miR-21 • Inhibits cardiac remodeling by silencing miR-21 • Increases cell death

• Increases brown adipogenesis and thermogenesis

High

(continued)

• Increases stemness • Promotes EMT • Increases IGF2 signaling and insulin trough BMI1 and silencing of PTEN • Recruits EZH2 • Attracts macrophages in tumors and increases the number of MDSCs • Decreases cancer cell death

• Reverses EMT • Promotes NK cell-mediated cytotoxicity • Prevents angiogenesis

High

7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic … 181

• Impairs differentiation of mesenchymal cells to white adipocytes • Increases brown adipogenesis • Restores β cell mass and insulin signaling • Prevents repair of endothelium and reduces angiogenesis • Promotes lipid deposition in the liver • Protects against cardiac hypertrophy but induces cardiac fibrosis • Increases cell death • Increases inflammation and liver fibrosis • Increases cell senescence • Blocks reprogramming of β cells to pluripotent precursor cells

LincRNA-p21

LINC-ROR

High

H19

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• Increases stemness • Induces EMT • Induces glycolysis

Low

Cancer

• • • •

• • • •

(continued)

Promotes stemness and EMT Induces AKT signaling Promotes glycolysis Inhibits apoptosis

Promotes EMT Induces PI3K/AKT signaling Reduces anti-tumor immunity Reduces cancer cell death

High

182 7 Non-coding RNAs Related to Cardiometabolic Diseases …

• Promotes pathological angiogenesis • Promotes cardiac hypertrophy and fibrosis • Reduces cell death

• Induces insulin resistance • Limits lipid accumulation in the liver

• Impairs β cell maturation and insulin secretion • Induces EC proliferation and angiogenesis • Protects from cardiac fibrosis and ER stress-induced apoptosis

MEG3

MIAT

• Activates NLRP3 inflammasome in the heart by silencing miR-133 • Increases glucose and lipids in the liver; blocks insulin signaling • Cardiac hypertrophy and fibrosis

• EC dysfunction and M1 macrophage polarization is associated with a decrease of MALAT1 in atherosclerotic plaques

High

MALAT1

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• Increases EMT • Induces PI3K/AKT/mTOR signaling • Induces glycolysis • Decreases cancer cell death

Low

Cancer Induces stemness Promotes EMT Increases IRS1 signaling Promotes glycolysis Is induced by M2 TAMs Inhibits apoptosis

(continued)

• Induces stemness • Promotes EMT • Induces ERK and PI3K/AKT signaling • Reduces cancer cell death

• • • • • •

High

7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic … 183

• Facilitates progenitor cell differentiation in WAT • Protects ECs from oxidative stress • Promotes Th2 cell differentiation • NEAT1-paraspeckles facilitate lipid accumulation of lipids in macrophages, activate inflammasomes, and induce apoptosis • Induces liver fibrosis • Increases M1 macrophage polarization • Induces cardiac fibrosis • Increases cell death • Increases angiogenesis • Converts contractile to synthetic proliferating VSMCs • Induces cardiac hypertrophy and fibrosis • Reduces apoptosis

TUG1

UCA1

High

NEAT1

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued) Low

Cancer

• • • • • •

• • • •

(continued)

Increases stemness Promotes EMT Reverts inhibition of PTEN Induces glycolysis Reduces anti-tumor immunity Reduces cancer cell death

Induces stemness Promotes EMT Induces glycolysis Reduces cancer cell death

• Induces stemness and EMT • Reduces cancer cell death

High

184 7 Non-coding RNAs Related to Cardiometabolic Diseases …

• Increases inflammation • Reduces cholesterol efflux • Protects from ischemia/reperfusion-related myocardial injury

ZFAS1

• Reduces cell death by silencing miR-181 but increases cell death by activating NFκB • Blocks progenitor cell proliferation but improves insulin secretion by silencing miR-7

ANRIL

CiRs-7

Circ-RNAs

• Promotes hypoxia-induced angiogenesis • Mediates ox-LDL-induced EC injury and ischemia/reperfusion related myocardial injury

High

XIST

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued) Low

Cancer Induces stemness Promotes EMT Increases IRS1 signaling Promotes angiogenesis Reduces cancer cell death

(continued)

• Induces PI3K/AKT and EGFR

• Increases immune escape • Reduces cancer cell death

• Promotes EMT • Increases angiogenesis • Reduces cancer cell death

• • • • •

High

7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic … 185

PVT1

• Decreases AKT signaling

Low

Non-coding RNA Cardiometabolic diseases

Table 7.1 (continued)

• Induces differentiation of white preadipocytes, increases the fatty acid synthesis, and blocks fatty acid oxidation • Increases angiogenesis • Promotes ANG II-induced increase of inflammatory cytokines, thickening of adventitia, loss of elastin, and apoptosis

High

Low

Cancer • Promotes EMT • Induces EGFR signaling

High

186 7 Non-coding RNAs Related to Cardiometabolic Diseases …

7.3 Comparison of the Role of Non-coding RNAs in Cardiometabolic …

187

related to the development of cardiometabolic diseases and cancer. High miR-34a and lincRNA-p21 are mostly related to cardiometabolic diseases, while low levels are related to cancer. High and low let-7, miR-146a, miR-181, miR-223, and GAS5 are associated with cardiometabolic diseases and cancer. Both high and low miR-9, miR-21, miR-130, miR-221-222, H19, MALAT1, MIAT, NEAT1, UCA1, ZFAS1, ANRIL, ciRs-7, and PVT1 are related to cardiometabolic diseases, while high levels are typically related to cancer. However, silencing of miR-9 is required to avoid cancer cell senescence. High and low miR-7, miR-17, miR-29a, miR-30a, miR-124, miR-143-145, miR-150, and MEG3 are related to cardiometabolic diseases, while low levels are typically related to cancer. However, in some tumors, high miR-17 may induce proliferation, the decrease of miR-26a and miR-29a inhibits PTEN, and the increase of miR-30a protects against immune response by expanding MDSCs. Overall, more non-coding RNAs are driven to either higher or lower levels in tumors than cardiometabolic tissues.

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Chapter 8

Regulation of Non-coding RNAs in Cardiometabolic Tissues and Tumors

Abstract MiR-1, miR-26a, miR-133, miR-378, and miR-455 tend to be downregulated, while miR-155, HOTAIR, LINC-ROR, TUG1, and XIST tend to be up-regulated in cardiometabolic tissues and tumors. Compared to cardiometabolic tissues, miR-7, miR-17, miR-29a, miR-30a, miR-34a, miR-124, miR-143–145, miR150, lincRNA-p21, and MEG3 tend to be down-regulated in tumors. In contrast, miR-9, miR-21, miR-130, miR-221, H19, MALAT1, MIAT, NEAT1, UCA1, ZFAS1, ANRIL, ciRs-7, and PVT1 tend to be up-regulated. The interaction between hypoxia, glucose, oxidative stress, inflammation, TGF-β, and MYC largely determine their expression profiles. Additional decrease of miRs in tumors may be due to silencing by specific lncRNA and circ-RNAs. BLACAT1 silences miR-17 and miR-150; CASC11 silences miR-150 and up-regulates TGF-β; FEZ1-AS1silences miR-30a, upregulating stemness genes; HNF1A-AS1 silences miR-34a, but up-regulating miR124; MACC1-AS1 silences miR-34a and miR-145; NIFK-AS1 silences miR-146a; NORAD silences miR-30a and up-regulates TGF-β; lncRNA-SNHG6 silences let7c, and miR-26a, and up-regulates MYC; SOX21-AS1 silences miR-7 and miR-145; ZEB1-AS1 silences miR-133, miR-181, and miR-455; circ-ANAPC7 silences miR181; circ-HIPK3 silences miR-7; circ-ITCH up-regulates and circ-MTO1 silences miR-17; circ-ZNF609 silences miR-145. Non-coding RNAs operate in complex networks. Significantly, hypoxia induces NORAD that induces TGF-β. The latter silences miR-181, resulting in increased ZEB-AS1 and ZEB1. TGF-β also induces MACC1-AS1 that induces MYC. MYC directly sponges miR-34a and silences miR34a indirectly by inducing lncRNA-SNHG7. Differences in gene expression may also be due to tumor-specific piRs.

8.1 Regulation of miRs Table 8.1 shows the regulation of miRs by hypoxia, glucose, oxidative stress, inflammation, TGF-β, and MYC.

Illustrations by Pieterjan Ginckels, Faculty of Architecture, KU Leuven, Ghent, Belgium. © The Author(s), under exclusive license to Springer Nature Switzerland AG 2021 P. Holvoet, Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer, https://doi.org/10.1007/978-3-030-68844-8_8

213

214

8 Regulation of Non-coding RNAs in Cardiometabolic Tissues and Tumors

Table 8.1 Regulation of non-coding RNAs Hypoxia

Glucose

Let-7 miR-1

X

miR-7

X

miR-9

X

X

miR-17

X

X

miR-21

X

miR-26a

X

miR-29a

Oxidative stress

Inflammation

X

X

X

X

X

X

X

X

X

X

X

miR-34a

X

X

miR-124

X

X

miR-130

X

X

X

X

X X X

X

X

X

X

X

X

X

X

X

X

X

miR-133

X

miR-143–145

X

X

X

miR-146a/b

X

X

X

miR-150

X

miR-155

X

miR-181

X

miR-221–222

X

X

X X

X

X

X

X

X

X

miR-223

X X

X

X X

X

miR-455

X X

X

HOTAIR

X

X

X

X

H19

X

LincRNA-p21

X

LINC-ROR

X

MALAT1

X

X

MEG3

X

X

MIAT NEAT1

X

X X

X

GAS5

MYC

X X

miR-30a

miR-378

TGF-β

X

X X X

X

X

X X

X

X

TUG1

X

X X

X

X

X

UCA1

X

XIST

X

ANRIL

X

X

X X (continued)

8.1 Regulation of miRs

215

Table 8.1 (continued) Hypoxia PVT1

X

Glucose

Oxidative stress

Inflammation

TGF-β

MYC X

Bold crosses indicate up-regulated non-coding RNAs; italic crosses indicate down-regulated noncoding RNAs. There is no robust data yet about the regulation of ZFAS1 and ciRs-7

8.1.1 Hypoxia Cardiometabolic tissues Hypoxia induces miR-9 in VSMCs, thereby causing a phenotypic switch from contractile to proliferative cells [1]. Hypoxia induces miR-17, and hypoxia-inducible factor 1 (HIF-1α) and VEGF regulate each other through miR-17 [2, 3]. Hypoxia and transforming growth factor, beta (TGF-β) induce miR-21, preventing ischemia reperfusion-induced apoptosis, down-regulating PTEN, and increasing AKT phosphorylation. However, PPAR-γ ligands mediate proliferative response to hypoxia by increasing miR-21 [4–9]. Hypoxia induces a protective response to mitochondria via HIF-1α-mediated up-regulation of miR-26a [10]. Hypoxia-induced miR-130 silences DEAD-box helicase 6. This RNA helicase is found in P-bodies and stress granules, inhibiting translation, and degrading mRNA. The silencing of the DEAD-box helicase 6 by the miR-130 family enhanced the translation of HIF-1α [11]. Hypoxia increases miR-143 and miR-145, but this may be alleviated by hypoxia-induced LINC-ROR [12–15]. Hypoxia, very small-sized particles (PM2.5 ), high glucose, IL-1β and TNF-α, and apolipoprotein E induce miR-146a [16–24]. Hypoxia also increases miR-150 [25]. Hypoxia-induced miR-378 promotes mesenchymal stem cell survival [26]. Hypoxia-induced H19 antagonizes Y-box-binding protein (YB)-1, thereby derepressing collagen 1A1 expression and inducing cardiac fibrosis [27]. Hypoxiainduces NEAT1 and, together with ox-LDL, increases MALAT1 [28–33]. LINCROR silences miR-145 and induces HIF-1α signaling [15]. Hypoxia-induced XIST promotes angiogenesis via miR-485-3p/SOX7 axis [34]. Hypoxia-induced ANRIL protects endothelial cells by modulating the miR-7-5p/SIRT1 axis [35]. Hypoxia down-regulates miR-1 and miR-7, thereby losing the miR-7-mediated inhibition of ischemia–reperfusion-induced apoptosis by targeting the HIF-1α/p-p38 pathway [36–38]. Tumors Hypoxia-induced miR-130 silences tumor suppressor p21 (CDKN1A) [11, 39]. Hypoxia induces miR-146a by stimulating its promoter, thereby sponging CADM2 and inducing proliferation, migration, and invasion of cancer cells [19]. Hypoxia-induced miR-155-5p forms a double-negative regulatory loop with ETS transcription factor ELK3 (ELK3); ELK3 depletion induces miR-155-5p that silences ELK3 whereby miR-155 is further enhanced [40]. Snail family transcriptional

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8 Regulation of Non-coding RNAs in Cardiometabolic Tissues and Tumors

repressor 2 (SNAI2 or SLUG) / β-catenin induced by hypoxia enhances miR-221 expression [41]. Hypoxia promotes EMT by downregulating miR-34a [42] and mesenchymal transition of glioma cells by down-regulating miR-124-3p [43, 44]. Hypoxia-induces GAS5 that silences miR-221–222 related to apoptosis [45]. H19 sequesters let-7, thereby releasing HIF-1α, leading to an increased expression of pyruvate dehydrogenase kinase 1 (PDK1), glycolysis, and stemness [46]. Hypoxia induces H19 that sponges miR-181d, relieving inhibition of β-catenin expression in glioblastoma cells [47]. Hypoxia-sensitive long intergenic non-protein coding RNA 1436 (LINC01436) sponges miR-30a-3p, promoting lung cancer cell growth, migration, and invasion [48]. Chromatin-chromatin interactions are formed at the MALAT1 locus under hypoxia, resulting in the up-regulation of MALAT1 [49]. Hypoxiainduced MEG3 regulates p53 pathway members such as HIF-1α [50]. NEAT1 is a direct transcriptional target of HIF-2, and the hypoxic induction of NEAT1 induces paraspeckle formation [51]. Hypoxia induces ANRIL, thereby suppressing hypoxia-induced apoptosis [52, 53], and lincRNA-p21, increasing glycolysis [54]. Hypoxia-induced PVT1 silences miR-150 [55] (Table 8.2).

8.1.2 Glucose Cardiometabolic tissues High glucose up-regulates miR-17 that decreases VEGFA and angiogenesis [56]. Hyperglycemia increases NFκB, p38 mitogen-activated protein kinase (MAPK) activation, the release of inflammatory IL-1β, TNF-α, and C–C motif chemokine ligand 2 (CCL2 or MCP1), and miR-21. High glucose up-regulates miR-34a and downregulates miR-126, elevating superoxide dismutase 2 [57]. High glucose-induced miR-155 induces cardiac fibrosis via the TGF-β signaling pathway [58]. Glucose up-regulates miR-221–222, which silences IGF1 [59, 60]. High glucose-induced miR-455-5p represses the secretion of inflammatory cytokines IL-1β and TNF-α [61]. High glucose and inflammatory cytokines induce HOTAIR in a p65-dependent manner, and MALAT1, protecting ECs against ox-LDL-induced cytokine release [62–68]. Glucose-induced TUG1 protects the pancreas against apoptosis [69]. High glucose lowers miR-1 [70], while insulin ameliorates miR-1 expression in cells under oxidative stress [71]. High glucose promotes oxidative stress and apoptosis by downregulating miR-26a [72]. High glucose decreases miR-29a/b and increases α-smooth muscle actin and fibronectin [73]. Glucose-induced circular RNA derived from WD repeat domain 77 (circ-WDR77) sponges miR-124 that targets FGF-2 to regulate VSMC proliferation and migration [74]. Glucose silences miR145, thereby activating the PI3K/AKT/mTOR pathway [75, 76]. High glucose and LPS down-regulate GAS5 and MEG3 [77–81] while increasing MALAT1 [82–84]. High glucose promotes the binding of NFκB to MIAT [85–87].

X

X

X

X

X

X

miR-181

X

miR-155

X

miR-150

miR-146a

X

X

X

X

X

X

miR-143–145

X

miR-130

X

miR-133

X

miR-124

X

X

X

miR-34a

X

X

X

X

X

X

X

X

miR-30a

X

X

miR-29a

X

miR-26a/b

miR-21

X

X

miR-9

miR-17

X

X

miR-7

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X X

(continued)

X

X

X

X

X

LincRNA-p21 MEG3 H19 HOTAIR LINC-ROR MALAT1 MIAT NEAT1 TUG1 UCA1 ZFAS1 XIST ANRIL CiRs-7 PVT1

miR-1

Let-7

Table 8.2 Expected changes of miR expression profiles due to changed expression of lncRNAs and circ-RNAs

8.1 Regulation of miRs 217

X X

Bold crosses indicate up-regulated non-coding RNAs; italic crosses indicate down-regulated non-coding RNAs

miR-455

miR-378

X X

miR-223

X

miR-221–222 X

X

LincRNA-p21 MEG3 H19 HOTAIR LINC-ROR MALAT1 MIAT NEAT1 TUG1 UCA1 ZFAS1 XIST ANRIL CiRs-7 PVT1

Table 8.2 (continued)

218 8 Regulation of Non-coding RNAs in Cardiometabolic Tissues and Tumors

8.1 Regulation of miRs

219

Tumors High glucose downregulates miR-9 in colorectal cancer cells, thereby increasing IGF1R signaling [88]. Insulin increases pyruvate kinase M2 and glycolysis in hepatocellular carcinoma cells by suppressing miR-145 [89] (Table 8.2).

8.1.3 Oxidative Stress Cardiometabolic tissues Oxidative stress induces miR-9 through NFkB [90]. Ox-LDL increases miR-21 and PI3K/ AKT/MAPK signaling [91] and increases miR-29a, thereby inducing STAT1/ Janus kinase (JAK) signaling [92]. Oxidative stress increases miR-34a, associated with premature aging [93–95]. Ox-LDL increases miR-155 in DCs and ECs [96, 97]. Ox-LDL-induced MALAT1 promotes autophagy in human ECs by silencing miR216a-5p and induces EMT through the Wnt/β-catenin pathway [28, 98]. Ox-LDL induces MIAT that silences miR-181b [99] and increases TUG1 [100]. Tumors Oxidative stress increases peroxidase peroxiredoxin 1, which binds to forkhead box O3 (FOXO3), decreasing pro-apoptotic let-7b [101] (Table 8.2).

8.1.4 Inflammation Cardiometabolic tissues Activation of toll-like receptor (TLR)-2 and release of pro-inflammatory cytokines TNF-α and IL-1β, but not IFN-γ induce miR-9 in inflammatory cells [102]. IL-1β, palmitate, and stearic acid up-regulate miR-34a [103–105]. TNF-α induces miR-130, miR-145, miR-150, and miR-155 [106–112]. IL-12, IL-18, and CD16 also increase miR-155 [113, 114]. TNF-α, IL-6, and leptin increase miR-378 in adipocytes, thereby silencing IL4R/PI3K/AKT and limiting macrophage proliferation [115, 116]. ANG II up-regulates miR-21 by targeting the SMAD family member 7 (SMAD7) and sprouty RTK signaling antagonist 1 (SPROUTY1 or SPRY1) in primary hepatic stellate cells, associated with NLRP3 inflammasome activation [117, 118]. ANG II also up-regulates MIAT, up-regulating TGF-β [119]. Leukotriene B4, an inflammation mediator, derived from arachidonic acid by 5-lipoxygenase and 5-lipoxygenase–activating protein, activates macrophages by inducing miR-155, miR-146b, and miR-125b [120, 121]. MiR-26a and miR-30a levels inversely correlate to IL1-β [122]. Further, IL22 inhibits miR-26a in T cells [123]. IFN-γ suppresses miR-181 in activated human

220

8 Regulation of Non-coding RNAs in Cardiometabolic Tissues and Tumors

CD4 lymphocytes [124] and miR-221 in DCs [125]. IFN-α also decreases miR378 and miR-30e, suppressors of human NK cell cytotoxicity [126]. IL10 decreases the expression of miR-223, together with miR-19a, miR-21, miR-31, miR-101, and miR-155 [127–129]. Tumors IL6 increases miR-17, but IFN-γ suppresses miR-17, thereby reverting antiinflammatory and anti-oxidative action in breast tumors [130–132]. Inflammation and prostaglandin E2 inhibits programmed cell death 4 (PDCD4) in prostate cancer cells through up-regulating miR-21 [133, 134]. Inflammatory C-X-C motif chemokine ligand 12 (CXCL12) / C-X-C motif chemokine receptor 4 (CXCR4) up-regulate XIST that silences miR-133a-3p, thereby de-repressing RhoA in colorectal cancer cells [135]. Mitochondrially encoded cytochrome c oxidase II (COX2) induces methylation of the promoter of let-7, down-regulating let-7 and up-regulating SOX2 [136]. MiR-7 in human gastric cancer is inversely related to IL-1β and TNF-α [137]. TNF-α also silences miR-1-3p, miR-26a, miR-133a-3p, and miR-133b [138–140]. Activation of NFκB down-regulates miR-124 in non-small-cell lung cancer cells [141] (Table 8.2).

8.1.5 TGF-β Cardiometabolic tissues TGF-β-induced lincRNA-p21 promotes liver inflammation and fibrosis by inhibiting miR-30a [142]. TGF-β suppresses miR-223 by up-regulating circular RNA derived from PWWP domain containing 2A, promoting hepatic fibrosis [143]. TGF-β also induces EGF, suppressing miR-124 through the transcription factor ETS proto-oncogene 2 to maintain proper β cell function and insulin secretion through PI3K cascades [144]. Tumors TGF-β1 up-regulates miR-9 and down-regulates E-cadherin, thereby inducing EMT, but IL10 represses this action by down-regulating miR-9 [145, 146]. TGF- β reduces miR-29a, but miR-29 blocks TGF-β function [147]. TGF-β elevates the MIR155 host gene (MIR155HG) lncRNA and miR-155, attenuating miR-143. TGF-β induces miR221 and miR-455-5p, inhibiting RUNX2 [8, 148]. TGF-β-induced EMT is associated with increased expression of MEG3 [149]. TGF-β up-regulates TUG1, which may act as a miRNA “sponge” to protect the HIF-1α mRNA 3 UTR from miR-143-5p [150]. TGF-β secreted by tumor-associated macrophages promotes proliferation and invasion of colorectal cancer by silencing miR-34a, thereby up-regulating VEGF [151]. However, the up-regulation of miR-34a reverses TGF-β-induced EMT through suppression of SMAD4 [152]. TGF-β enhances DNA methyltransferase

8.1 Regulation of miRs

221

3 alpha, repressing miR-124 promoter by hypermethylation. This loss of miR-124 enhances SMAD4, inducing SNAIL, SLUG, and ZEB2 [153]. TGF-β1 secreted by mesenchymal cells shifts macrophages to the M2 phenotype [154, 155] by downregulating miR-34a [156] or miR-124 [157]. TGF-β1 decreases miR-133a/b, while miR-133 mimics attenuate the action of TGF-β and down-regulates p-SMAD3 [158] (Table 8.2).

8.1.6 MYC MYC and POU class 5 homeobox 1 (OCT4) bind to the promoter region of miR-9 to trigger its transcription, associated with tumor metastasis [159, 160]. MYC induces miR-17-19b [161, 162], and miR-150, inducing autophagy in cancer cells [163]. MXI1, an MYC antagonist, inhibits miR-155 [164]. MYC promotes non-small-cell lung cancer by up-regulating ANRIL [165]. MYC induces H19, [166–168], and PVT1, enhancing cancer cells’ proliferation. However, PVT1 may induce or inhibit the expression of MYC [169–172]. MYC down-regulates let-7a, let-7d, and let-7 g by binding to their promoters [173]. MYC represses miR-29 through a co-repressor complex with EZH2 stimulated by repressing miR-26a by MYC [174–178]. Overexpression of miR-26a suppresses hepatocellular cancer metastasis by downregulating MYC [179]. MYC sponges miR-34a and silences miR-34a indirectly by the small nucleolar RNA host gene 7 lncRNA (lncRNA-SNHG7) [180, 181]. Besides, MYC silences miR-124, causing a shift towards the M2 macrophage phenotype [157, 182–186]. Further, the decrease of miR-124 improves insulin signaling by de-repressing AKT [187–189]. MYC up-regulates ANRIL, GAS5, MEG3, HOTAIR, H19, PVT1, and down-regulates MALAT1, NEAT1, and UCA1 [190].

8.1.7 Overview Low miR-1, miR-26a, miR-133, miR-378, and miR-455, and high miR-155, HOTAIR, LINC-ROR, TUG1, and XIST are typically related to the development of cardiometabolic diseases and cancer (Fig. 8.1). The interaction between hypoxia, glucose, oxidative stress, inflammation, TGFβ, and MYC explains the down-regulation of miR-1, miR-26a, and miR-133. They all are inversely associated with cardiometabolic diseases and cancer (Table 8.1). While inflammation down-regulates miR-378, hypoxia induces it. Glucose and TGF-β induce miR-455. Induction of miR-378 and miR-455 may protect against cardiometabolic diseases and cancer. The interaction between hypoxia, glucose, oxidative stress, inflammation, TGF-β, and MYC also explains the up-regulation of miR-155, HOTAIR, LINC-ROR, TUG1, and XIST. They all are positively related to cardiometabolic diseases and cancer. Table 8.2 shows that the increase in HOTAIR,

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8 Regulation of Non-coding RNAs in Cardiometabolic Tissues and Tumors

Fig. 8.1 Differences in the expression of non-coding RNAs with cardiometabolic diseases and cancer. Low miR-1, miR-26a, miR-133, miR-378, and miR-455, and high miR-155, HOTAIR, LINC-ROR, TUG1, and XIST are typically related to the development of cardiometabolic diseases and cancer. High miR-34a and lincRNA-p21 are mostly related to cardiometabolic diseases, while low levels are related to cancer. High and low let-7, miR-146a, miR-181, miR-223, and GAS5 are associated with cardiometabolic diseases and cancer. Both high and low miR-9, miR-21, miR130, miR-221–222, H19, MALAT1, MIAT, NEAT1, UCA1, ZFAS1, ANRIL, ciRs-7, and PVT1 are related to cardiometabolic diseases, while high levels are typically related to cancer. However, silencing of miR-9 is required to avoid cancer cell senescence. High and low miR-7, miR-17, miR-29a, miR-30a, miR-124, miR-143–145, miR-150, and MEG3 are related to cardiometabolic diseases, while low levels are typically related to cancer. However, in some tumors, high miR-17 may induce proliferation, the decrease of miR-26a and miR-29a inhibits PTEN, and the increase of miR-30a protects against immune response by expanding MDSCs. Overall, more non-coding RNAs are driven to either higher or lower levels in tumors than cardiometabolic tissues. Thus tumors are characterized by more extreme expressions of non-coding RNAs. Additional decrease of miRs in tumors may be due to silencing by specific lncRNA and circ-RNAs. BLACAT1 silences miR-17 and miR-150; CASC11 silences miR-150 and up-regulates TGF-β; FEZ1-AS1silences miR30a; HNF1A-AS1 silences miR-34a, but up-regulating miR-124; MACC1-AS1 silences miR-34a and miR-145; NIFK-AS1 silences miR-146a; NORAD silences miR-30a and up-regulates TGF-β; lncRNA-SNHG6 silences let-7c, and miR-26a, and up-regulates MYC; SOX21-AS1 silences miR-7 and miR-145; ZEB1-AS1 silences miR-133, miR-181, and miR-455; circ-ANAPC7 silences miR181; circ-HIPK3 silences miR-7; circ-ITCH up-regulates and circ-MTO1 silences miR-17; circZNF609 silences miR-145. Differences in expression of these non-coding RNAs underly differences in metabolic reprogramming of cells in cardiometabolic tissues and tumors in response to stress factors

LINC-ROR, TUG1, and XIST may further down-regulate miR-1 and miR-133. Also, they silence miR-7, miR-9, miR-17, miR-21, miR-30a, miR-34a, miR-124, miR143–145, miR-221, miR-223, and miR-455. Importantly, the decrease of miR-7, miR-17, miR-30a, miR-34a, miR-124, and miR-143–145 is more representative for expression profiles in tumors than in cardiometabolic tissues. Indeed, while high miR-34a is related to cardiometabolic diseases, low levels are related to cancer.

8.1 Regulation of miRs

223

While high and low miR-7, miR-17, miR-30a, miR-124, and miR143-145 are related to cardiometabolic diseases, low levels are typically related to cancer. Both high and low miR-9, miR-21, miR-130, miR-221–222, H19, MALAT1, MIAT, NEAT1, UCA1, ZFAS1, ANRIL, and PVT1 are related to cardiometabolic diseases, while high levels are typically related to cancer. However, silencing of miR-9 is required to avoid cancer cell senescence. In some tumors, high miR-17 may induce proliferation, the decrease of miR-26a and miR-29a inhibits PTEN, and the increase of miR-30a protects against immune response by expanding MDSCs. Table 1 shows the up-regulation of miR-9 (except for glucose), miR-21, miR-130, miR-221–222 (except for inflammation), H19, MALAT1, MIAT, ANRIL, and PVT1, mainly representative for tumors. The up-regulation of lncRNAs and circ-RNAs may explain the silencing of miR-1, miR-9, miR-17, miR-26a, miR-29a, miR-30a, miR34a, miR-124, miR-130, miR-133, miR-143–145, miR-146a, miR-150, miR-155, miR-181, and miR-455. Silencing of miR-9, miR-21, and miR-130 may protect against tumor growth. In contrast, silencing of miR-1, miR-17, miR-26a, miR-29a, miR-30a, miR-34a, miR-124, miR-133, miR-143–145, miR-150, miR-155, and miR455 may enhance tumor growth. High and low let-7, miR-146a, miR-181, miR-223, and GAS5 are related to cardiometabolic diseases and cancer. Table 1 supports a decrease of let-7, miR-181, and miR-223, and an increase of miR-146a. H19, MALAT1, and ANRIL silence let7. H19, MALAT1, and PVT1 silence miR-146a. H19 and MIAT silence miR-181. TUG1 silences miR-223. So far, we do not explain the decrease of lincRNA-p21 and MEG3, mainly in tumors. However, this decrease may explain the up-regulation of miR-9, miR-21, and miR-221–222 as in tumors. However, silencing these two lncRNAs would also increase miR-7, miR-26a, miR-29a, miR-34a, miR-143–145, miR-181, and miR223.

8.2 Differences in miR-Profiles in Cardiometabolic Tissues and Tumors May be Due to the Typical Action of lncRNAs and circ-RNAs in Tumors Differences may be due to the tumor-specific action of lnc-RNAs and circ-RNAs. In tumors, the bladder cancer-associated transcript 1 (BLACAT1) activates Wnt signaling and induces autophagy and chemoresistance by silencing miR-17 [191, 192]. BLACAT1 also silences miR-150, thereby inducing CCR2 [193]. Cancer susceptibility 11 lncRNA (CASC11) silences miR-150 in cancer cells, while miR150 overexpression does not significantly alter CASC11 expression [194]. CASC11, associated with HIF1α, up-regulates of TGF-β and induces stemness [195, 196]. The fasciculation and elongation protein zeta one lncRNA (FEZ1-AS1) increases stemness by silencing miR-30a, up-regulating Nanog homeobox (NANOG), OCT4, and SOX2 [197]. HNF1A antisense RNA 1 (HNF1A-AS1) silences miR-34a in tumors,

224

8 Regulation of Non-coding RNAs in Cardiometabolic Tissues and Tumors

thereby up-regulating sirtuin (SIRT)-1 and down-regulating p53, leading to a higher Wnt signaling [95, 198–202]. HNF1A-AS1 binds to the promoter of miR-124 to promote its expression [203]. Overall, the HNF1 homeobox A (HNF1A) antisense RNA 1 (HNF1A-AS1) activates the Wnt/β-catenin signaling pathway activity by up-regulating the expression of β catenin, cyclinD1, and c-MYC [204]. TGF-β1 secreted by mesenchymal cells activates SMAD family member (SMAD)-2 and SMAD3 through TGF-β receptors and induces lncRNA MET transcriptional regulator MACC1 antisense (MACC1-AS1) that stabilizes the MET transcriptional regulator MACC1 and induces CDK6, thereby promoting cancer cell proliferation by sponging miR-34a. It also silences miR-145, thereby inducing c-MYC [205–208]. The nucleolar protein interacting with the FHA domain of MKI67 (NIFK) antisense RNA 1 (NIFK-AS1) inhibits M2 macrophage polarization by targeting miR-146a [209]. The non-coding RNA activated by DNA damage (NORAD) silences miR30a, inhibiting tumor cells’ apoptosis [210]. Hypoxia-activated NORAD induces cancer cell proliferation and migration by inducing TGF-β/RUNX2 signaling [211– 214]. The small nucleolar RNA host gene six lncRNA (SNHG6) up-regulates MYC by sponging let-7c [215] and promotes EMT through the miR-26a / EZH2 axis [216, 217]. SRY-box transcription factor (SOX)-21 antisense divergent transcript 1 (SOX21-AS1) inhibits the expression of miR-7 and miR-145 in tumors [218, 219]. Zinc finger E-box-binding homeobox two antisense RNA 1 (ZEB1-AS1) induces stemness and EMT and activates PI3K/AKT signaling by silencing miR-133 in tumors [220, 221]. ZEB1-AS1 also promotes colon adenocarcinoma malignant progression in tumors by silencing miR-455 [222]. TGF-β and ox-LDL decrease miR-181 in tumors, thereby inducing ZEB1-AS1 that silences miR-181, thereby inducing Wnt/ β-catenin signaling [223–225]. SNHG6 and ZEB1-AS1 mediate TGF-β/Smad signaling and induce EMT via regulating ZEB1 [224, 226, 227]. The anaphase-promoting complex subunit 7 circ-RNA (circ-ANAPC7) silences miR-181 in tumors [228]. High levels of the homeodomain interacting protein kinase three circ-RNA (circ-HIPK3) in tumors induce EMT [229]. Circ-HIPK3 sponges miR-7, thereby increasing the expression of miR-7 target EGFR [230]. The circRNA generated from itchy E3 ubiquitin-protein ligase (circ-ITCH) silences miR-17 [231]. The mitochondrial tRNA translation optimization one circ-RNA (circ-MTO1) may regulate cancer cell proliferation by silencing miR-17 [232]. Circ-ZNF609 sponges miR-145-5p, thereby elevating p70S6K1 [233]. Thus these additional lncRNAs and circ-RNAS may explain further decreases in let-7, miR-7, miR-17, miR-26a, miR-30a, miR-34a, miR-133, miR-145, miR-146a, miR-150, miR-181, and miR-455.

8.3 Action of piRs Particularly in Tumors Pi-sno75, derived from GAS5, potently up-regulates the transcription of tumor necrosis factor (TNF)-related apoptosis-inducing ligand (TRAIL), a pro-apoptotic protein. The piR-sno75/ piwi like RNA-mediated gene silencing 1 (PIWIL1) or

8.3 Action of piRs Particularly in Tumors

225

piR/PIWIL4 complex interacted explicitly with the TRAIL promoter [234]. PiR651 inhibited proliferation, migration, invasion, induced apoptosis in cancer cells, and arrested cell cycle at the G(2)/M phase [235, 236]. PiR-598 also affected the expression of genes related to cell death and survival and cell-cycle progression [237]. PiR-823 increased the transcriptional activity of heat shock transcription factor 1 (HSF1) by binding to HSF1 and promoting its phosphorylation at Ser326, thereby promoting binding by heat shock protein 90 [238]. Transfection with piR-823 mimic or treatment with myeloma-derived-EVs enriched in piR823 promoted the proliferation, tube formation, and invasion of tumor endothelial cells by enhancing the expression of VEGF, IL-6, and intercellular adhesion molecule 1 (ICAM1) and attenuating apoptosis [239, 240]. PiR-004800, increased in multiple myeloma cells, protected against autophagic cell death. Its expression depends on the sphingosine-1-phosphate receptor 1 signaling pathway, which regulates the PI3K/Akt/mTOR pathway through control of piRNA-004800 expressions [241]. PiR-DQ722010 downregulation promoted activation of PI3K/AKT signaling pathway inducing prostate hyperplasia [242]. PiR-8041 reduced glioma cell line proliferation and induced apoptosis [243]. PiR-39980 repressed the ribonucleotide reductase regulatory subunit M2, promoting apoptosis and inhibiting fibrosarcoma cells’ proliferation [244]. Inhibition of piR-39980 induced senescence of neuroblastoma cells without affecting the classical apoptosis pathway by binding to Janus kinase 3 (JAK3) [245]. PiR-1245 is inversely related to tumor suppressor genes in colorectal cancer [246]. PiR-36,712 interacted with RNAs produced by selenoprotein W pseudogene 1 (SELENOW or SEPW1), and subsequently inhibited SEPW1 expression through competition of SEPW1 mRNA with SEPW1P RNA for miR-7 and miR-324. Higher SEPW1 due to down-regulation of piRNA-36,712 in breast cancer may suppress P53, inducing SLUG and decreasing P21 and E-cadherin levels, thus promoting cancer cell proliferation, invasion, and migration [247]. The heat shock protein DNAJA1 retains the stability of proteins in the S. mediterranea genome SMEDWI-1 and SMEDWI-2. Besides, DNAJA1 binds to PIWIL1, required for PIWIL1 stability in human gastric cancer cells [248]. The PIWIL1/piR-DQ593109 complex, increased in glioma endothelial cells, decreased the blood–brain barrier permeability. PIWIL1 and piR-DQ593109 form a piR-induced silencing complex, which degrades MEG3 that normally sponges miR-330-5p that silences RUNX3 [249]. PiR-54265 binds to PIWIL2, forming a PIWIL2/STAT3/phosphorylated SRC proto-oncogene, nonreceptor tyrosine kinase SRC complex. This complex activates STAT3 and promotes proliferation [250]. Higher piR-932 is associated with EMT of breast cancer cells. It may form an immune complex with piwi like RNA-mediated gene silencing 2 (PIWIL2) that suppresses glycogen synthase kinase 3 beta (GSK3β)–induced phosphorylation and ubiquitination of β-catenin, thereby stabilizing β-catenin and inducing the β-catenin/CCND1 pathway [251]. CCN1 induces miR-21 and miR-93, which bind Toll-Like Receptor 8 to trigger VEGF and Bcl-2 [252]. Besides, CCND1 induces the PIWI-interacting RNAs, piR-016658 piR-016975, related to stem cell expansion and increased the abundance of PIWIL2 in Erα- positive breast cancer cells [253]. PIWIL2 stabilizes histone deacetylase 3 and enhances the interaction

226

8 Regulation of Non-coding RNAs in Cardiometabolic Tissues and Tumors

between histone deacetylase 3 and casein kinase 2, regulating cell cycle, apoptosis, and circadian rhythms [254]. The oncogene Opa interacting protein 5 (OIP5) antisense RNA 1 (OIP5-AS1) lncRNA promotes cancer cell proliferation by inducing CCAAT/enhancer-binding protein alpha (c/EBP-α), PI3K/AKT, and Wnt/β-catenin signaling through high mobility group AT-hook 2 (HMGA2) [255, 256]. PiR-30188 may guide PIWIL3 to OIP5-AS1, degrading it and reducing the sponging of miR367-3p that silences c/EBP-α, which otherwise would induce proliferation, migration, and invasion, and protect against apoptosis by inducing TRAF4. The inhibition of c/EBP-α leads to over-expression of PIWIL3, forming a positive feedback loop in the growth regulation of glioma cells [256].

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Chapter 9

Communication Between Tumor-Adjacent Tissues and Tumors with Emphasis on Role of Inflammatory Cells

Abstract The exchange of microvesicles between cells in tumor-adjacent tissues, particularly inflammatory cells, changes non-coding RNA profiles and, thereby, tumor phenotype. Typically, microvesicles enriched in let-7, miR-9, miR-17, miR-21, miR-29, miR-150, miR-155, miR-221-222, and miR-223 contribute to tumorigenesis. In particular, miR-155 enriched in microvesicles secreted by M1 macrophages in inflamed tumor-adjacent tissue change the action of TGF-β from growth inhibition to EMT induction. MiR-155 and TGF-β also change the expression of noncoding RNAs, thereby inducing stemness, EMT, insulin-sensitized state, angiogenesis, immune escape, and escape from death. Notably, the induction of HOTAIR will attract macrophages from inflamed tumor-adjacent tissue, thereby closing a vicious circle.

9.1 Exchange of miR-Enriched Microvesicles Microvesicles facilitate the communication between several tissues and cell types within these tissues. They are involved in the development of cardiometabolic diseases [1–13]. Typically, the let-7 and miR-17/92 families, together with miR21, miR-126, miR-146, miR-155, and miR-223, are enriched in M1 macrophagederived inflammatory microvesicles [1, 14]. Besides, microvesicles secreted by immature dendritic cells (DCs) contain more miR-21, miR-34a, miR-221, and miR222. Microvesicles secreted by mature DCs contain more miR-146a and miR-155 [15]. Microvesicles secreted by M1 macrophages in tumor-adjacent tissue and enriched in miR-17 and miR-221 may convert M2 tumor-associated macrophages (TAMs) into M1 macrophages and increase anti-tumor immunity. In contrast, tumor cells may inhibit M1 polarization and promote cancer growth by selective shuttling of miR21 enriched microvesicles [16, 17]. Tumor-adjacent tissue secretes microvesicles

Illustrations by Pieterjan Ginckels, Faculty of Architecture, KU Leuven, Ghent, Belgium. © The Author(s), under exclusive license to Springer Nature Switzerland AG 2021 P. Holvoet, Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer, https://doi.org/10.1007/978-3-030-68844-8_9

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enriched in miR-29a/c that suppresses angiogenesis and metastasis [18]. Microvesicles from TAMs selectively transfer miR-221-222 and miR-223 to tumors, promoting proliferation and invasion of cancer cells [19–22]. They also deliver miR-150, upregulating VEGF, and promoting angiogenesis [23]. MiR-223 in exosomes released by macrophages decreases phosphatase and tensin homolog (PTEN) and increases phosphatidylinositol 3-kinase (PI3K)/AKT serine/threonine kinase 1 (AKT) [22, 24] (Fig. 9.1). MiR-9 secreted in exosomes from triple-negative breast cancer cells induces differentiation of fibroblasts to cancer-associated fibroblasts, increasing cell motility [25]. Cancer-associated fibroblasts may then secrete miR-21-enriched exosomes to facilitate epithelial to mesenchymal transition (EMT) and cancer cell migration and invasion of breast cancer cells [26, 27]. Exosomes secreted by melanoma and pancreatic cancer cells enriched in miR-155 convert normal fibroblasts to cancer-associated fibroblasts. MiR-155-enriched exosomes induce vascular endothelial growth factor A (VEGFA), fibroblast growth factor 2 (FGF2), metalloproteinase (MMP9), suppressor of cytokine signaling 1 (SOCS1), and the Janus kinase (JAK)-2/signal transducing and activator of transcription (STAT)-3 signaling pathway [28, 29]. Enrichment of miR-155 contributes to the metabolic reprogramming of cancer cells by inducing the reverse Warburg effect. Thereby, tumor cells onset not only aerobic glycolysis in themselves but also corrupt stroma cells to produce energy-rich metabolites, allowing cancer cells to generate ATP, increase proliferation, and reduce cell death [30–32] (Fig. 9.1). Finally, tumors may enhance oncogenesis by releasing microvesicles enriched in anti-oncogenic miRs. The release of the tumor-suppressive let-7, selectively enriched in exosomes from metastatic gastric cancer cells, protects them from apoptosis [33] (Fig. 9.1). In conclusion, cancer cells’ behavior may be determined by changes in their intracellular non-coding RNA content and non-coding RNAs selectively packed in microvesicles released by tumor-adjacent tissue and inflammatory cells.

9.2 MiR-155 as a Link Between M1 Macrophage-Mediated Inflammation in Tumor-Adjacent Tissue and Tumor Growth and Metastasis M1 macrophages mediate inflammation in cardiometabolic tissue. M1 macrophages secrete inflammatory cytokines. In particular, tumor necrosis factor (TNF)-α, interleukin (IL)-8, and interferon (IFN)-γ, together with inflammation-associated ROS and high glucose, induce the secretion of miR-155 enriched microvesicles. These microvesicles transport miR-155 to the primary tumor. There, miR-155 acts on transforming growth factor (TGF)-β, thereby shifting growth inhibition to EMT with cancer cell proliferation and metastasis. TGF-β silences miR-1, miR-26a, miR-34a,

9.2 MiR-155 as a Link Between M1 Macrophage-Mediated Inflammation …

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Fig. 9.1 Selective packing of miRs in microvesicles. M1 macrophages in inflamed tumor-adjacent tissue secrete microvesicles enriched in the miR-17/92, miR-21, miR-34a, miR-143-145, miR146a, miR-150, miR-155, miR-221-222, and miR-223. Typically, microvesicles enriched in miR-17 and miR-221 induce the migration of M2 TAMs into the tumor and convert M2 TAMs into M1 macrophages, increasing anti-tumor immunity. However, tumor cells secrete microvesicles enriched in miR-21, which inhibit M1 macrophage polarization. Primary tumor cells secrete microvesicles enriched in miR-9 and miR-155, which convert stromal fibroblasts to cancer-associated fibroblasts. The latter secrete microvesicles enriched in miR-21, preventing M2 to M1 macrophage polarization, and inducing EMT. Cancer-associated fibroblasts release microvesicles enriched in miR-155, which cause the Warburg effect in cancer cells and reverse the Warburg effect in neighboring stromal cells. TAMs secrete microvesicles enriched in miR-150, miR-221-222, and miR-223, inducing angiogenesis, invasion, and metastasis. In contrast, miR-29-enriched microvesicles block tumor growth. MiR-223 in exosomes released by TAMs inhibits PTEN, thereby increasing PI3K/AKT signaling and insulin-sensitized state. Tumors protect themselves from apoptosis by secreting let-7enriched microvesicles. However, when the let-7-enriched microvesicles reach the tumor-adjacent tissue, they reinforce M1-macrophage mediated inflammation in the latter, closing a vicious circle

miR-133 and miR-143-145. Besides, TGF-β induces the homeobox (HOX) transcript antisense lncRNA (HOTAIR), the tumor protein p53 pathway corepressor one lncRNA (lincRNA-p21), the metastasis-associated lung adenocarcinoma transcript one lncRNA (MALAT1), and urothelial cancer-associated 1 (UCA1). By upregulating these lncRNAs, TGF-β silences additional miRs: miR-7, miR-9, miR-21, miR-30a, miR-124, miR-150, miR-181, miR-221-222, and miR-223. The expression of miR-155 may also be inhibited but restored by transfer from microvesicles. The expression profile changes of non-coding RNAs induce stemness, EMT, insulin sensitized state, angiogenesis, and reduce anti-tumor immunity and apoptosis. In particular, the increase in HOTAIR attracts macrophages to the tumor, closing a vicious circle (Fig. 9.2).

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Fig. 9.2 MiR-155 links M1 macrophage-mediated inflammation in adjacent tissue and tumor growth and metastasis. High glucose, TNF-α, IL8, IFN-γ, and ROS induce the secretion of miR155 enriched microvesicles by M1 macrophages in tumor-adjacent tissue. These microvesicles transport miR-155 to the tumor. MiR-155 acts on TGF-β, thereby shifting growth inhibition to EMT with cancer cell proliferation and metastasis. TGF-β induces changes in non-coding RNA expression, which induce stemness, EMT, insulin sensitized state, angiogenesis, and reduce antitumor immunity and apoptosis. In particular, the increase in HOTAIR attracts macrophages to the tumor, closing a vicious circle

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23. Liu, Y., et al. (2013). Microvesicle-delivery miR-150 promotes tumorigenesis by up-regulating VEGF, and the neutralization of miR-150 attenuate tumor development. Protein & Cell, 4, 932–941. https://doi.org/10.1007/s13238-013-3092-z. 24. Zhu, X., et al. (2019). Macrophages derived exosomes deliver miR-223 to epithelial ovarian cancer cells to elicit a chemoresistant phenotype. Journal of Experimental & Clinical Cancer Research, 38, 81. https://doi.org/10.1186/s13046-019-1095-1. 25. Baroni, S., et al. (2016). Exosome-mediated delivery of miR-9 induces cancer-associated fibroblast-like properties in human breast fibroblasts. Cell Death & Disease, 7, e2312. https:// doi.org/10.1038/cddis.2016.224. 26. Nouraee, N., et al. (2013). Expression, tissue distribution and function of miR-21 in esophageal squamous cell carcinoma. PLoS ONE, 8, e73009. https://doi.org/10.1371/journal.pone.007 3009. 27. Donnarumma, E., et al. (2017). Cancer-associated fibroblasts release exosomal microRNAs that dictate an aggressive phenotype in breast cancer. Oncotarget, 8, 19592–19608. https://doi. org/10.18632/oncotarget.14752. 28. Zhou, X., et al. (2018). Melanoma cell-secreted exosomal miR-155-5p induce proangiogenic switch of cancer-associated fibroblasts via SOCS1/JAK2/STAT3 signaling pathway. Journal of Experimental & Clinical Cancer Research, 37, 242. https://doi.org/10.1186/s13046-0180911-3. 29. Pang, W., et al. (2015). Pancreatic cancer-secreted miR-155 implicates in the conversion from normal fibroblasts to cancer-associated fibroblasts. Cancer Science, 106, 1362–1369. https:// doi.org/10.1111/cas.12747. 30. Wilde, L., et al. (2017). Metabolic coupling and the Reverse Warburg effect in cancer: Implications for novel biomarker and anticancer agent development. Seminars in Oncology, 44, 198–203. https://doi.org/10.1053/j.seminoncol.2017.10.004. 31. Jiang, E., et al. (2019). Tumoral microvesicle-activated glycometabolic reprogramming in fibroblasts promotes the progression of oral squamous cell carcinoma. The FASEB Journal, 33, 5690–5703. https://doi.org/10.1096/fj.201802226R. 32. Shu, S., et al. (2018). Metabolic reprogramming of stromal fibroblasts by melanoma exosome microRNA favours a pre-metastatic microenvironment. Scientific Reports, 8, 12905. https:// doi.org/10.1038/s41598-018-31323-7. 33. Ohshima, K., et al. (2010). Let-7 microRNA family is selectively secreted into the extracellular environment via exosomes in a metastatic gastric cancer cell line. PLoS ONE, 5, e13247. https:// doi.org/10.1371/journal.pone.0013247.

Chapter 10

The Impact of Non-coding RNA Networks on Disease Comorbidity: Cardiometabolic Diseases, Inflammatory Diseases, and Cancer

Abstract Notably, a cluster of non-coding RNAs is at the cross-road between metabolic and cardiovascular diseases and the cross-road of metabolic diseases and cancer. This cluster consists of the let-7 family, miR-1, miR-7, miR-9, miR-17, miR-21, miR-26, miR-29, miR-30a, miR-34a, miR-124, miR-130, miR-133, miR143–145, miR-146a, miR-150, miR-155, miR-181 family, miR-221–222, miR-223, miR-378, miR-455, GAS5, HOTAIR, H19, lincRNA-p21, LINC-ROR, MALAT1, MEG3, MIAT, NEAT1, TUG1, UCA1, XIST, ZFAS1, ANRIL, PVT1. This cluster of non-coding RNAs are candidates for inclusion in machine learning approaches. However, their expression profiles may be affected by other inflammatory diseases like Alzheimer’s disease, asthma, arthritis, and renal failure. These comorbidities should be included in risk predicting algorithms. Changes in their expression profiles according to disease stage and behavioral and therapeutic changes should also be considered. Although the same non-coding RNAs are involved in cancer’s pathogenesis, opposite changes in their expression occur in tumors than in cardiometabolic tissues. The opposite changes in expression of miRs may be especially due to the specific action of lncRNAs and circ-RNAs in tumors. They include BLACAT1, CASC11, HNF1A-AS1, MACC1-AS1, NIFK-AS1, NORAD, SOX21-AS1, ZEB1AS1, circ-ANAPC7, circ-ITCH, and circ-MTO1. Besides, piRs with PIWI proteins may silence single-stranded RNAs, like lncRNAs, particularly in cancer cells. With many shared modifiable risk factors, cancer and cardiometabolic diseases often coexist in the same individuals. Therefore, combined risk assessments for cancer and cardiometabolic diseases should account for opposite non-coding RNA expression changes. Combined cardiovascular and hemato-oncological risk prediction may have synergistic, preventive public health benefits.

10.1 Identification of Non-coding RNAs at Cross-Road of Metabolic and Cardiovascular Diseases We did not find any single non-coding RNA with a unique role in developing metabolic and cardiovascular diseases or cancer. Every discussed non-coding RNA has several functions, and several non-coding RNAs share the same function. Illustrations by Pieterjan Ginckels, Faculty of Architecture, KU Leuven, Ghent, Belgium. © The Author(s), under exclusive license to Springer Nature Switzerland AG 2021 P. Holvoet, Non-coding RNAs at the Cross-Road of Cardiometabolic Diseases and Cancer, https://doi.org/10.1007/978-3-030-68844-8_10

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Notably, a cluster of non-coding RNAs is at the cross-road between metabolic and cardiovascular diseases. This cluster consists of the let-7 family, miR-1, miR-7, miR-9, miR-17, miR-21, miR-26, miR-29, miR-30a, miR-34a, miR-124, miR-130, miR-133, miR-143–145, miR-146a, miR-150, miR-155, miR-181 family, miR-221– 222, miR-223, miR-378 and miR-455, growth arrest-specific five lncRNA (GAS5), the homeobox (HOX) transcript antisense lncRNA (HOTAIR), the H19 imprinted maternally expressed transcript lncRNA (H19), the tumor protein p53 pathway corepressor 1 lncRNA (lincRNA-p21), long intergenic non-protein coding RNA, regulator of reprogramming (LINC-ROR), the metastasis-associated lung adenocarcinoma transcript one lncRNA (MALAT1), maternally expressed 3 lncRNA (MEG3), myocardial infarction associated transcript (MIAT), nuclear paraspeckle assembly transcript (NEAT1), taurine up-regulated 1 (TUG1) and urothelial cancer associated 1 (UCA1), X inactive specific transcript (XIST), ZNFX1 antisense RNA 1 (ZFAS1), and circ-RNAs cyclin dependent kinase inhibitor 2B antisense RNA 1 (ANRIL) and PVT1 oncogene (PVT1) link metabolic to cardiovascular diseases. Changes in their expression profiles decrease the number of stem/precursor cells, hamper differentiation to full active cells. These changes impair insulin signaling, glucose uptake, glucose, and fatty acid metabolism. They cause a shift from oxidative phosphorylation (OXPHOS) to glycolysis. They stimulate lipid deposition and increase inflammation, mainly mediated by M1 macrophages, Th1 and Th17 cells, and oxidative stress, ultimately leading to cell death. They may induce angiogenesis restoring O2 supply, but also causing infiltration of the inflammatory cells discussed above.

10.2 Many Non-coding RNAs at Cross-Road of Metabolic and Cardiovascular Diseases are also Related to Inflammatory Diseases Because the pathogenesis of cardiometabolic diseases largely depends on inflammation is not a surprise that the same non-coding RNAs participate in their development. Alzheimer’s disease Let7-a facilitates the amyloid-β-induced autophagy and neurotoxicity [1]. High levels of let-7b are associated with neurodegeneration by activating the toll-like receptor (TLR)-7 in Alzheimer’s disease (AD) [2]. MiR-7 overexpressed in the brains of dietinduced obese mice and AD patients impairs insulin signaling, increases the levels of extracellular amyloid-β (Aβ) [3]. Overexpression of ciRs-7, silencing miR-7, reduces Aβ and beta-site amyloid precursor protein cleaving enzyme 1 (BACE1) levels in a nuclear factor-κB (NFκB)-dependent manner [4]. High miR-9-5p reduced Aβ plaque formation in mice. MiR-9 inhibited NOTCH and glycogen synthase kinase-3 beta (GSK-3β) and increased the nuclear factor, erythroid 2 like 2 (Nrf2 or NFE2L2),

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and superoxide dismutase 1 (SOD1) [5, 6]. MiR-9 also reduced Aβ42-triggered activation of calcium/calmodulin-dependent protein kinase kinase 2 and adenosine monophosphate-activated protein kinase [7]. MiR-29 overexpression down-regulated BACE1 and BCL-2 interacting mediator of cell death (BCL2-like 11 or BIM) [8]. Overexpression of MALAT1 reduced IL-6 and TNF-α levels, increased IL-10, and inhibited neuron apoptosis, possibly by sponging miR-30b and miR-125 [9–11]. Decreased miR-124 is associated with increased expression of BACE1 and caveolin 1. Besides, low miR-124 is associated with increased phosphoinositide 3-kinase (PI3K), AKT, and GSK-3β hyperphosphorylation. Also, low miR-124 is associated with impaired angiogenesis in mice [12–16]. Silencing of NEAT and XIST upregulates miR-124 and down-regulates BACE1 in mice [17, 18]. MiR-146a and miR181a were inversely related to the risk of Alzheimer’s disease in subjects with mild cognitive impairment [19]. Inhibition of the miR-143-3p reduced Aβ1-42-induced cell apoptosis by decreasing cleaved caspase-3 and cleaved caspase-9 levels [20]. Increased expression of miR-155 in the hippocampus of AD rats induces IL-1β, IL6, TNF-α, and apoptotic caspase-3 and causes a shift to inflammatory T cells [21, 22]. Increased HIF-1α and hypoxia-induced apoptosis in an AD cell model are associated with the down-regulation of miR-223, resulting in increased phosphatase and tensin homolog (PTEN), inhibiting the PI3K/Akt pathway [23]. Restoring MEG3 expression inhibited hippocampal neurons’ apoptosis, decreased Aβ expression, inhibited oxidative stress, and inflammatory injury [24]. TUG1 silencing, elevating miR-15a, increased viability, and limited apoptosis of amyloid β-25–35-treated hippocampal neurons [25]. The knockdown of UCA1 suppressed the neural stem cell differentiation to astrocytes and promoted the neural stem cell differentiation to neurons by increasing the expression of miR-1 [26]. Asthma Increased let 7a, 7b, and 7c is associated with infants’ asthma [27]. MiR-1 levels are inversely related to sputum eosinophilia, airway obstruction, and the number of hospitalizations in asthmatic patients, possibly by inhibiting IL-13-induced eosinophil binding to endothelial cells [28]. Non-immune IgE activates the signal transducer and activator of transcription 3 (STAT3), leading to the up-regulation of miR21-5p, down-regulating PTEN. Reduced PTEN results in the activation of PI3K, the mammalian target of rapamycin (mTOR), ribosomal protein S6 kinase beta1 (p70s6k), peroxisome proliferator-activated receptor- γ coactivator 1-α (PGC1α), peroxisome proliferator-activated receptor-γ (PPAR-γ) and cyclooxygenase-2 (COX2). The outcome is increased mitochondrial activity and extracellular matrix deposition [29]. MiR-21 promotes airway remodeling through the tumor growth factor (TGF)-β / SMAD signaling pathway[ [30]. MiR-29b alleviated total inflammatory cell infiltration, reversed the imbalance of T helper 1 cell (Th1)/Th2 responses, and decreased eosinophils recruitment in the airway [31]. MiR-145-5p induces the release of chemokines and inflammatory factors, the Th1/Th2 ratio, the epithelial barrier dysfunction, and suppresses epithelial repair [32, 33]. In contrast, miR-1433p may inhibit asthma airway remodeling [34]. The activation of group 2 innate lymphoid (ILC2) cells and increased inflammation is associated with an increase of

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miR-146a that directly blocks the proliferation of ILC2 cells and reduces the number of neutrophils in bronchoalveolar lavage. Modulation of ILC2 function by miR-146a may depend on IL-33/interleukin 1 receptor-like 1 (IL1RL1 or ST2) signaling through inhibiting interleukin 1 receptor-associated kinase 1 (IRAK1) and TNF receptorassociated factor 6 (TRAF6) [35–37]. MiR-146b reinforces the inhibitory action of miR-146a on cyclo-oxygenase (COX)-2 and IL-1β [38]. MiR-155, increased by environmental tobacco smoke and small PM2.5 particles, is associated with allergeninduced airway epithelial damage and heightened oxidant stress in asthma [39, 40]. Low levels of miR-181b in patients with eosinophilic asthma are associated with inflammation. Dexamethasone reverts this by preventing IL13-induced miR-181b-5p down-regulation and suppressing IL13-induced expression of IL-1β and chemokine eotaxin-1 [41, 42]. In contrast, TGF-β1 may induce airway smooth muscle cell proliferation and airway remodeling of asthma by up-regulating miR-181a [43]. Airway overexpression of miR-221-3p exacerbates eosinophilic inflammation [44, 45]. MiR-223 suppresses insulin-like growth factor 1 receptor (IGF1R) expression and decreases the downstream phosphorylation of AKT, reducing extracellular matrix deposition in airway smooth muscle cells [46]. GAS5 promotes airway smooth muscle cell proliferation by sponging miR10a [47]. MALAT1, sponging miR-150, derepresses EIF4E expression, activates AKT signaling, and PDGF-BB-induced airway smooth muscle cell proliferation and migration [48]. NEAT1 is associated with increased exacerbation and inflammation and decreased lung function by sponging miR-124, maintaining the M2 macrophage phenotype [49, 50]. TUG1 increased in asthma patients, promotes the airway smooth muscle cell proliferation and migration, and reduces apoptosis by sponging miR-5905p [51]. PVT1 is associated with corticosteroid-insensitive asthma by increasing inflammation and airway smooth muscle cell proliferation [52]. In contrast, MEG3 protects by restoring the Treg/Th17 imbalance in asthma by sponging miR-17 [53]. LncRNA-CASC7 increases steroid response in asthma by sponging miR-21 and inhibiting PI3K signaling [54]. Arthritis MiR-9-5p suppressed chondrocytes apoptosis and promoted cartilage remodeling in mice with osteoarthritis (OA) [55]. Up-regulation of miR-34a-5p inhibited proliferation and promoted apoptosis and autophagy in OA cells [56]. GAS5 overexpression could counteract apoptosis by sponging miR-34a that may also be inhibited by miR-145–5 [57, 58]. Up-regulation of H19 in OA samples may protect chondrocytes from IL-1β-induced apoptosis by sponging miR-106a-5p but aggravate LPSinduced injury by sponging miR-130a and increase inflammation and collagen by sponging miR-124a [59–61]. High levels of MALAT1 in OA chondrocytes inhibited their viability and promoted cartilage ECM degradation in response to IL-1β by sponging miR-145 and induced inflammation and apoptosis by sponging miR-146a. Overexpression of miR-145 blocked this MALAT1 action, possibly by preventing MALAT1 from interacting with the disintegrin and metalloproteinase with thrombospondin motifs (ADAMTS)-5 [62, 63]. MiR-145-5p repressed TNF-α-mediated

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signaling activation and consequently cartilage degradation by silencing mitogenactivated protein kinase kinase 4 [64]. XIST promoted OA chondrocytes’ proliferation by sponging miR-211, up-regulating the C-X-C motif chemokine receptor (CXCR)-4 [65], and increased osteopontin, a cytokine, and a matrix protein involved in arthritis and chondrocyte apoptosis by sponging miR-376c-5p [66]. Low levels of NEAT1 in OA tissues were associated with increased miR-181a expression, apoptotic rate, and inflammatory cytokines [67, 68]. High levels of PVT1 in OA patients’ cartilage and IL-1β-stimulated chondrocytes contributed to their metabolic dysfunction by elevating matrix metalloproteinase (MMP)-3, MMP-9, and MMP-13, and inflammatory prostaglandin E2, IL6, IL8, and TNF-α [69], and induced apoptosis by sponging miR-488-3p [70]. Maresin 1, a macrophage-derived mediator of inflammation that prevents mitochondrial dysfunction, increased Treg cells’ number while decreasing Th17 cells by up-regulating miR-21 [71, 72]. Myostatin inhibited miR-21-5p expression, and miR21-5p mimic prevented the myostatin-induced enhancement of IL-1β and collageninduced arthritis [73]. High levels of miR-34a were associated with an increased number of Th 1 and Th17 cells, inflammatory cytokines, and bone loss in rheumatoid arthritis (RA) model [74]. The decrease of miR-21 resulted in the activation of the Janus kinase/signal transducer and activator of transcription (JAK/STAT) signaling pathway in systematic juvenile idiopathic arthritis [75]. TGFβ1-induced decrease of miR-29a, b, and c in primary chondrocytes was related to increased SMAD, NFκB, and canonical WNT signaling [76]. High levels of miR-143 and miR-145 rendered RA fibroblast-like synoviocytes susceptible to TNFα and VEGF165 stimuli by downregulating insulin-like growth factor binding protein 5 and protected against LPSinduced apoptosis and inflammation [77, 78]. Mice deficient in miR-146a developed gouty arthritis via up-regulation of IRAK1 and the NACHT, LRR, and PYD domains containing protein (NALP3) inflammasome [79]. Injection of exosomes enriched in miR-150 reduced the clinical arthritic scores in collagen-induced arthritis mice and joint destruction by inhibiting synoviocyte hyperplasia and angiogenesis [80]. High levels of miR-155 were associated with fewer M2-like-macrophages, more Th17 cells, and increased tumor necrosis factor α (TNF) in RA models [81–83]. The transcription factor PU.1 lowered TNF-α-induced proliferation and cytokine release of rheumatoid arthritis fibroblast-like synoviocytes by suppressing miR-155, thereby reducing the production of antibodies [84, 85]. Overexpression of miR-181 silenced PTEN and inhibited proliferation, and induced apoptosis of chondrocytes in OA [86]. High miR-221-3p was associated with cartilage degeneration, while miR-223-3p protected against IL-1β-induced ECM degradation in chondrocytes via the stromal cell-derived factor 1/ C-X-C motif chemokine receptor 4 signaling and prevented the accumulation of NLR family pyrin domain containing 3 (NLRP3) protein, and inhibited IL-1β [87, 88]. NOTCH signaling down-regulated miR-223 associated with increased secretion of inflammatory cytokine by RA macrophages [89]. However, NOTCH may be blocked by overexpressing miR-9 [90]. Overexpression of miR455-3p promoted TGF-β/SMAD signaling in chondrocytes and inhibited cartilage degeneration in mice by directly suppressing p21 activated kinase 2 [91].

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Down-regulation of ciRs-7 and up-regulation of miR-7 in IL-1β-induced chondrocytes enhanced the IL-1β-induced inflammation [92]. The decrease of HOTAIR, associated with an increase in miR-17, induced the osteogenic differentiation markers RUNX family transcription factor (RUNX)-2 and collagen (COL)-1A1 [93]. Downregulation of the HOTAIRM1-1 variant in OA cartilages inhibits mesenchymal cell viability, induces apoptosis, and suppresses differentiation by up-regulating miR125b [94]. De-repressing MEG3 in fibroblast-like synoviocytes of RA patients inhibited inflammation and apoptosis by sponging miR-141, activating AKT/mTOR signaling, and sponging miR-361-5p, up-regulating forkhead box O1 (FOXO1) [95, 96]. The increase of ZFAS1 in RA patients ZFAS1 expression was associated with increased fibroblast-like synoviocyte migration, possibly by sponging miR-27a [97]. Renal failure Let-7, miR-21, miR-29, and miR-126 are implicated in renal fibrosis [98]. Hypertension- and TGF-β1-induced increase of miR-21 is associated with renal inflammation, fibrosis, and failure [99, 100]. GAS5 may retard renal fibrosis by sponging miR-21 [101]. However, exosomal miR-21 protects against apoptosis by targeting programmed cell death 4 (PDCD4)/NFκB [102]. The silencing of MEG3 is required for optimal miR-21 action [103]. The TGF-β/Smad3-interacting lncRNA lnc-TSI may revert this [104]. A miR-30c-5p agomir decreased renal ischemia/reperfusion injury by transforming M1 macrophages to M2 macrophages and decreasing inflammatory cytokines [105]. TGF- β -induced miR-145 sponges fibroblast growth factor 10 (FGF10), intensifying renal epithelial-mesenchymal transition (EMT) [106]. Overexpression of miR-146 protected against caspase3-mediated apoptosis and increased PI3K / AKT signaling [107]. High levels of pro-pyroptotic activity of miR-155 up-regulated apoptotic caspase-1 and the inflammatory cytokines IL-1β and IL18 [108, 109]. In contrast, MALAT1 inhibited hyperglycemia-induced renal cell pyroptosis by sponging miR-23c [110, 111]. However, MALAT1 may cause NFκB-mediated renal injury by sponging miR146a [112]. High levels of NEAT1 were associated with low miR-27a-3p and hypoxia-induced renal tubular epithelial apoptosis [113]. Overexpression of ANRIL increased apoptosis and promoted TLR4, NFκB phosphorylation, and downstream inflammatory factors [114]. GAS5 overexpression decreased the NLRP3-mediated inflammation, decreasing TNF-α, IL-1β and IL6, MCP-1, and ROS [115]. HOTAIR-mediated sponging of miR34a level in kidney tissues decreased TNF-α and IL-1β and reduced the apoptotic rate [116].

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10.3 Differences Between Non-coding RNAs in Cardiometabolic Tissues and Tumors All non-coding RNAs which relate to metabolic syndrome components are involved in cancer. Although the same non-coding RNAs are involved in the pathogenesis of cancer and cardiometabolic diseases, often opposite changes in expression profile occur in tumors than in cardiometabolic tissues. These changes allow cancer cells to retain stemness and epithelial-mesenchymal transition (EMT), inducing cancer cell proliferation and migration. These changes retain insulin signaling and angiogenesis, stimulating tumor growth. Increased angiogenesis in tumors is less harmful than in cardiometabolic tissues. Indeed, tumor-specific changes in non-coding RNA profiles are associated with M2 macrophage and Treg polarization and induction of M2 myeloid suppressor cells (MDSCs), allowing the immune system to escape. All these changes decrease cell senescence and cell death. Additional decrease of miRs in tumors may be due to silencing by specific lncRNA and circ-RNAs. Typically lncRNAs bladder cancer-associated transcript one lncRNA (BLACAT1; silencing miR-17 and miR-150), cancer susceptibility 11 lncRNA (CASC11; silencing miR-150), HNF1A antisense RNA 1 (HNF1A-AS1; silencing miR-34a, but up-regulating miR-124), lncRNA MET transcriptional regulator MACC1 antisense MACC1 antisense RNA 1 (MACC1-AS1; silencing miR34a and miR-145), NIFK antisense RNA 1 (NIFK-AS1; silencing miR-146a), noncoding RNA activated by DNA damage (NORAD; silencing miR-30a), SRY-box transcription factor 21 antisense 1 (SOX21-AS1; silencing miR-7 and miR-145), zinc finger E-box-binding homeobox two antisense RNA 1 (ZEB1-AS1; silencing miR-133, miR-181, and miR-455), and anaphase-promoting complex subunit 7 circRNA (circ-ANAPC7; silencing miR-181), itchy E3 ubiquitin-protein ligase circRNA (circ-ITCH; up-regulating miR-17), mitochondrial tRNA translation optimization one circ-RNA (circ-MTO1; silencing miR-17) may be responsible for differences in miR expression level in tumors compared to cardiometabolic tissues. Besides, piRs with PIWI proteins may silence single-stranded RNAs, like lncRNAs, particularly in cancer cells. Besides, a cell’s behavior depends not only on non-coding RNAs expressed by this cell but also on non-coding RNAs enriched in microvesicles secreted by other cell types, even in other tissues their communication. The packing of mainly miRs in microvesicles may prevent degradation but also facilitate cell-specific delivery. Tumors secrete microvesicles containing non-coding RNAs, which induce healthy cells to convert to glycolysis. Inflammatory cells secrete microvesicles containing non-coding RNAs, which induce proliferation and migration of cancer cells. Finally, cancer cells may selectively shuttle anti-oncogenic non-coding RNAs to microvesicles and remove them to preserve proliferation and metastasis. Finally, we present a model proposing the link between miR-155-enriched microvesicles secreted by M1 macrophages in the tumor-adjacent tissues and tumor cells in a vicious circle, preventing silencing miR-155 in the tumor despite potentially inhibiting lncRNAs.

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10.4 Expected Technical Developments Underlying the Use of Non-coding RNAs as Biomarkers Overall, we present a list of non-coding RNAs, which are candidates for inclusion in machine learning approaches, considering changes in their expression profiles according to disease stage and behavioral and therapeutic changes. This list of well-characterized non-coding RNAs is timely because of two recent technical developments facilitating the evaluation of vast amounts of various omics data. First, the number of applications utilizing real-time PCR is expanding rapidly. The improved accuracy of results relative to end-point PCR, multiplexing capability, and reduced time are factors contributing to qPCR’s growth. Microchips’ use will lead to even more rapid and sensitive detection of multiple targets, possibly within 20 min [117, 118]. Portable microfluidic platforms may accelerate the production of point-of-care diagnostics [119]. Second, several artificial intelligence (AI) or machine-learning methods may be applied to classify patients for several known outcomes, like obesity, type 2 diabetes, type of cardiovascular disease, or cancer type. The goal of artificial intelligence (AI) in biomedicine is to fit vast amounts of omics data and phenotypic, therapeutic, behavioral, and social data in a predicting model. Data may be derived from traditional health records and small wearable monitoring devices for electronic medical recording, such as cell phones and fitness trackers. Tasks of AI involve computer vision, time series analysis, speech recognition, and natural language processing [120]. Computer vision is used not only for image analysis in radiology and pathology [121–124] but also in genomics for identifying alternative splicing and predicting non-coding RNA – RNA and non-coding RNA—protein interactions [125, 126]. Time series analysis is useful for continuously monitoring health data, such as blood pressure and electrocardiograms measured continuously using small wearable monitoring systems [127]. Speech-recognition techniques are used to detect neurological disorders [128]. An AI-based natural language processing is used for extracting information from electronic health record data [4]. Machine learning methods may be supervised or unsupervised. A supervised learning model predicts an item’s property, called its label, target, response variable, or output, using various features known about the item, called input features, explanatory variables, or input [129]. In short, supervised learning is applied when one already knows which outcome one wants to predict. Supervised learning requires first a set of training inputs for which the desired predictions, or training labels, are known. Once training is complete, the model can be applied to new input conditions. Examples of supervised machine learning methods are the decision tree, the support vector machine (SVM), and the neural network [130]. SVM is the most widely used supervised machine learning method in the cardiovascular [131–138] and the cancer domain [139–141] because it is relatively straightforward, yet it can capture complex nonlinear relationships. However, from the start, the precision of predictive models

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obtained by supervised learning may be reduced because of improper dichotomization of the output. Further, although SVMs select the variables necessary for the model, the relation between the variables and the regression (or class separation) is not visualized [142, 143]. In contrast, unsupervised learning algorithms infer patterns from data without a dependent variable or known labels. So the system organizes the data, searching for common characteristics among them and clustering according to internal knowledge. In short, its forte lies in discovering new patterns in data. Cluster and principal component analysis are two unsupervised learning methods. Deep learning may be supervised or unsupervised [144–147]. It originates from artificial neural networks (ANN) as in the brain, is very flexible in how it allows the labels to relate to the input features: labels are functions of intermediate variables (also known as hidden variables, intermediate features, nodes, or neurons), which are in turn functions of other intermediate variables, and so on until some intermediate variables are functions of the input features. In medicine, unsupervised deep learning has been applied mainly in the imaging field [148, 149]. Whereas unsupervised learning methods allow classification, they do not map a new sample, and extensive variation in proposed models may result from outliers’ inclusion. That is why supervised learning mostly follows unsupervised learning. Further, multicollinearity, as in logistic regression [150] and overfitting, is challenging to avoid when handling omics datasets, although increasing the sample size prevents these problems [151]. Moreover, to increase data sets, it may be necessary to combine data from multiple sources, but differences in experimental methodologies can confound analyses. Previously, we already highlighted the potential bias inherent in the case–control design, patient recruitment with differences in inclusion and exclusion criteria, and the use of different reference standards in analyzing noncoding RNAs [152, 153]. However, its primary disadvantage is that the biological interpretation of models derived from machine learning approaches such as deep learning is difficult without additional functional information. Therefore, even in the era of AI, a comprehensive review of the biological functions of non-coding RNAs, which likely may be introduced in machine learning algorithms, is relevant. It may also decrease the number of confounding factors leading to overfitting in the model.

10.5 The Need for Measuring Fluctuation of Non-coding RNAs According to the disease stage, the dynamics of expression fluctuating risk factor profile, and changes in therapies will have to be considered [152]. For example, fluctuation in non-coding RNAs with variation in body mass index may be substantial because this fluctuation rather than baseline body mass index is related to coronary

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atherosclerosis [154]. Therefore, we will have to take care to include information about disease stage-specific expression of non-coding RNAs. This information is, however, very scarce.

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