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Table of contents :
Chapter: 1 (Page no: 1) The stomach and small and large intestinal microbiomes. Author(s): Riedel, C. U. Schwiertz, A. Egert, M. Chapter: 2 (Page no: 20) The oral microbiome. Author(s): Zaura, E. Koopman, J. E. y Mostajo, M. F. Crielaard, W. Chapter: 3 (Page no: 32) The human urogenital microbiome. Author(s): Bengtson, E. Forney, L. J. Nelson, D. E. Chapter: 4 (Page no: 57) The lung microbiome. Author(s): Rogers, G. B. Carroll, M. P. Bruce, K. D. Chapter: 5 (Page no: 72) The human skin microbiome. Author(s): Tong, J. Li, H. Y. Chapter: 6 (Page no: 90) Function of the human gut microbiota. Author(s): Matsuki, T. Tanaka, R. Chapter: 7 (Page no: 107) Models of the human microbiota and microbiome in vitro. Author(s): Marzorati, M. Abbeele, P. van den Grootaert, C. Weirdt, R. de Carcavilla, A. M. Vermeiren, J. Wiele, T. van de Chapter: 8 (Page no: 124) In vivo and animal models of the human gut microbiome. Author(s): Goodman, A. L. Chapter: 9 (Page no: 136) The gut microbiota in health and disease. Author(s): Ventura, M. Turroni, F. Strati, F. Sinderen, D. van Chapter: 10 (Page no: 147) Next-generation sequencing methods to investigate the human microbiome. Author(s): Xiao Liang Qin JunJie Shen DongQian Jiang ChenMing Chen WanTing Liu Chuan Wang Jun Chapter: 11 (Page no: 171) Metabonomics for understanding gut microbiome and host metabolic interplay. Author(s): Li, J. V. Holmes, E.
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Advances in Molecular and Cellular Microbiology 25

The Human Microbiota and Microbiome

Edited by

Julian R. Marchesi Cardiff University, Cardiff

Advances in Molecular and Cellular Microbiology

Through the application of molecular and cellular microbiology, we now recognize the diversity and dominance of microbial life forms on our planet, which exist in all environments. These microbes have many important planetary roles, but for us humans a major problem is their ability to colonize our tissues and cause disease. The same techniques of molecular and cellular microbiology have been applied to the problems of human and animal infection during the past two decades and have proved to be immensely powerful tools in elucidating how microorganisms cause human pathology. This series has the aim of providing information on the advances that have been made in the application of molecular and cellular microbiology to specific organisms and the diseases that they cause. The series is edited by researchers active in the application of molecular and cellular microbiology to human disease states. Each volume focuses on a particular aspect of infectious disease and will enable graduate students and researchers to keep up with the rapidly diversifying literature in current microbiological research.

Titles Available from CABI 17. Helicobacter pylori in the 21st Century Edited by Philip Su on and Hazel M. Mitchell 18. Antimicrobial Peptides: Discovery, Design and Novel Therapeutic Strategies Edited by Guangshun Wang 19. Stress Response in Pathogenic Bacteria Edited by Stephen P. Kidd 20. Lyme Disease: an Evidence-based Approach Edited by John J. Halperin 21. Tuberculosis: Laboratory Diagnosis and Treatment Strategies Edited by Timothy McHugh 22. Antimicrobial Drug Discovery: Emerging Strategies Edited by George Tegos and Eleftherios Mylonakis 24. Bacteriophages in Health and Disease Edited by Paul Hyman and Stephen T. Abedon 25. The Human Microbiota and Microbiome Edited by Julian Marchesi 26. Meningitis: Cellular and Molecular Basis Edited by Myron Christodoulides Titles Forthcoming from CABI Microbial Metabolomics Edited by Silas Villas-Bôas and Katya Ruggiero

Earlier titles in the series are available from Cambridge University Press (www.cup.cam.ac.uk).

CABI is a trading name of CAB International

CABI Nosworthy Way Wallingford Oxfordshire, OX10 8DE UK

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© CAB International 2014. All rights reserved. No part of this publication may be reproduced in any form or by any means, electronically, mechanically, by photocopying, recording or otherwise, without the prior permission of the copyright owners. A catalogue record for this book is available from the British Library, London, UK. Library of Congress Cataloging-in-Publication Data The human microbiota and microbiome / editor, Julian R. Marchesi. p. ; cm. -- (Advances in molecular and cellular microbiology ; 25) Includes bibliographical references and index. ISBN 978-1-78064-049-5 (alk. paper) I. Marchesi, Julian, editor of compilation. II. Series: Advances in molecular and cellular microbiology ; 25. [DNLM: 1. Metagenome--physiology. 2. Gastrointestinal Tract--microbiology. QU 470] QR46 616.9’041--dc23 2013040390 ISBN-13: 978 1 78064 049 5 Commissioning editor: Rachel Cu s Editorial assistant: Alexandra Lainsbury Production editor: Shankari Wilford Typeset by Columns Design XML Ltd, Reading, UK. Printed and bound in the UK by CPI Group (UK) Ltd, Croydon, CR0 4YY.

Contents

Contributors

vii

1

The Stomach and Small and Large Intestinal Microbiomes Christian U. Riedel, Andreas Schwier and Markus Egert

1

2

The Oral Microbiome Egija Zaura, Jessica E. Koopman, Mercedes Fernandez y Mostajo and Wim Crielaard

20

3

The Human Urogenital Microbiome Erika Bengtson, Larry J. Forney and David E. Nelson

32

4

The Lung Microbiome Geraint B. Rogers, Mary P. Carroll and Kenneth D. Bruce

57

5

The Human Skin Microbiome Jia Tong and Huiying Li

72

6

Function of the Human Gut Microbiota Takahiro Matsuki and Ryuichiro Tanaka

90

7

Models of the Human Microbiota and Microbiome In Vitro Massimo Marzorati, Pieter Van den Abbeele, Charlo e Grootaert, Rosemarie De Weirdt, Ane Marcos Carcavilla, Joan Vermeiren and Tom Van de Wiele

107

8

In Vivo and Animal Models of the Human Gut Microbiome Andrew L. Goodman

124

9

The Gut Microbiota in Health and Disease Marco Ventura, Francesca Turroni, Francesco Strati and Douwe van Sinderen

136

10

Next-generation Sequencing Methods to Investigate the Human Microbiome Liang Xiao, Junjie Qin, Dongqian Shen, Chenming Jiang, Wanting Chen, Chuan Liu and Jun Wang

147

v

vi

11

Contents

Metabonomics for Understanding Gut Microbiome and Host Metabolic Interplay Jia V. Li and Elaine Holmes

Index

171 191

Contributors

Erika Bengtson, Institute for Bioinformatics and Evolutionary Studies, and the Department of Biological Sciences, University of Idaho, Moscow, ID, USA. E-mail: ebengtson@vandals. uidaho.edu Kenneth D. Bruce, King’s College London, Molecular Microbiology Research Laboratory, Institute of Pharmaceutical Science, 150 Stamford Street, Franklin-Wilkins Building, London, SE1 9NH, UK. E-mail: [email protected] Mary P. Carroll, Cystic Fibrosis Unit, Southampton University Hospitals NHS Trust, Southampton, UK. E-mail: [email protected] Wanting Chen, BGI-Shenzhen, Beishan Industrial Zone, Yantian District, Shenzhen 518083, China. E-mail: [email protected] Wim Crielaard, Department of Preventive Dentistry, Academic Centre for Dentistry Amsterdam (ACTA), University of Amsterdam and VU University Amsterdam, the Netherlands. E-mail: [email protected] Rosemarie De Weirdt, Laboratory of Microbial Ecology and Technology (LabMET), Ghent University, B-9000 Ghent, Belgium. E-mail: [email protected] Markus Egert, Faculty of Medical and Life Sciences, Microbiology and Hygiene Group, Hochschule Furtwangen University, Campus Villingen-Schwenningen, Germany. E-mail: [email protected] Mercedes Fernandez y Mostajo, Department of Preventive Dentistry, Academic Centre for Dentistry Amsterdam (ACTA), University of Amsterdam and VU University Amsterdam, the Netherlands. E-mail: [email protected] Larry J. Forney, Institute for Bioinformatics and Evolutionary Studies, and the Department of Biological Sciences, University of Idaho, Moscow, ID, USA. E-mail: [email protected] Andrew L. Goodman, Microbial Diversity Institute and Department of Microbial Pathogenesis, Yale University School of Medicine, New Haven, CT, USA. E-mail: andrew.goodman@ yale.edu Charlo e Grootaert, Laboratory of Food Chemistry and Human Nutrition, Ghent University, B-9000 Ghent, Belgium. E-mail: charlo [email protected] Elaine Holmes, Division of Computational and Systems Medicine, Department of Surgery and Cancer, Faculty of Medicine, Sir Alexander Fleming Building, Imperial College London, London, SW7 2AZ, UK. E-mail: [email protected] Chenming Jiang, BGI-Shenzhen, Beishan Industrial Zone, Yantian District, Shenzhen 518083, China, and Department of Physics, Brown University, 69 Brown St, Providence, RI 02912, USA. E-mail: [email protected] and [email protected] vii

viii

Contributors

Jessica E. Koopman, Department of Preventive Dentistry, Academic Centre for Dentistry Amsterdam (ACTA), University of Amsterdam and VU University Amsterdam, the Netherlands. E-mail: [email protected] Huiying Li, Department of Molecular and Medical Pharmacology, University of California, Los Angeles, USA. E-mail: [email protected] Jia V. Li, Division of Computational and Systems Medicine, Department of Surgery and Cancer, Faculty of Medicine, Sir Alexander Fleming Building, Imperial College London, London, SW7 2AZ, UK. E-mail: [email protected] Chuan Liu, BGI-Shenzhen, Beishan Industrial Zone, Yantian District, Shenzhen 518083, China. E-mail: [email protected] Ane Marcos Carcavilla, BioMARIC, B-9052 Ghent, Belgium. E-mail: [email protected] Massimo Marzorati, Laboratory of Microbial Ecology and Technology (LabMET), Ghent University, B-9000 Ghent, Belgium. E-mail: [email protected] Takahiro Matsuki, Yakult Central Institute for Microbiological Research, 1796 Yaho, Kunitachishi, Tokyo 186-8650, Japan. E-mail: [email protected] David E. Nelson, Department of Microbiology and Immunology, Indiana University School of Medicine, Bloomington, IN, USA. E-mail: [email protected] Junjie Qin, BGI-Shenzhen, Beishan Industrial Zone, Yantian District, Shenzhen 518083, China. E-mail: [email protected] Christian U. Riedel, Institute of Microbiology and Biotechnology, University of Ulm, Ulm, Germany. E-mail: [email protected] Geraint B. Rogers, King’s College London, Molecular Microbiology Research Laboratory, Institute of Pharmaceutical Science, 150 Stamford Street, Franklin-Wilkins Building, London, SE1 9NH, UK. E-mail: [email protected] Andreas Schwier , Institute of Microecology, Herborn, Germany. E-mail: andreas.schwier @ mikrooek.de Dongqian Shen, BGI-Shenzhen, Beishan Industrial Zone, Yantian District, Shenzhen 518083, China. E-mail: [email protected] Francesco Strati, Laboratory of Probiogenomics, Department of Genetics, Biology of Microorganisms, Anthropology and Evolution, University of Parma, Italy. E-mail: [email protected] Ryuichiro Tanaka, Yakult Central Institute for Microbiological Research, 1796 Yaho, Kunitachishi, Tokyo 186-8650, Japan. E-mail: [email protected] Jia Tong, Department of Molecular and Medical Pharmacology, University of California, Los Angeles, USA. E-mail: [email protected] Francesca Turroni, Alimentary Pharmabiotic Centre and Department of Microbiology, Bioscience Institute, National University of Ireland, Western Road, Cork, Ireland. E-mail: [email protected] Tom Van de Wiele, Laboratory of Microbial Ecology and Technology (LabMET), Ghent University, B-9000 Ghent, Belgium. E-mail: [email protected] Pieter Van den Abbeele, ProDigest, B-9052 Ghent, Belgium. E-mail: pieter.vandenabbeele@ prodigest.eu Douwe van Sinderen, Alimentary Pharmabiotic Centre and Department of Microbiology, Bioscience Institute, National University of Ireland, Western Road, Cork, Ireland. E-mail: [email protected] Marco Ventura, Laboratory of Probiogenomics, Department of Genetics, Biology of Microorganisms, Anthropology and Evolution, University of Parma, Italy. E-mail: marco. [email protected], Joan Vermeiren, Laboratory of Microbial Ecology and Technology (LabMET), Ghent University, B-9000 Ghent, Belgium. E-mail: [email protected]

Contributors

ix

Jun Wang, BGI-Shenzhen, Beishan Industrial Zone, Yantian District, Shenzhen 518083, China. E-mail: [email protected] Liang Xiao, BGI-Shenzhen, Beishan Industrial Zone, Yantian District, Shenzhen 518083, China. E-mail: [email protected] Egija Zaura, Department of Preventive Dentistry, Academic Centre for Dentistry Amsterdam (ACTA), University of Amsterdam and VU University Amsterdam, the Netherlands. E-mail: [email protected]

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1

The Stomach and Small and Large Intestinal Microbiomes

Christian U. Riedel,1 Andreas Schwiertz2 and Markus Egert3* 1University

of Ulm, Ulm, Germany; 2Institute of Microecology, Herborn, Germany; Furtwangen University, Campus Villingen-Schwenningen, Germany

3Hochschule

1.1 Introduction This introductory chapter provides an updated overview on the composition of the microbiome in the human gastrointestinal tract (GIT); that is, the microbiota of the GIT together with its entire genetic information and the microbe–microbe and host–microbe interactions taking place in this habitat. More specifically, recent scientific advances on the microbiome of the upper (stomach and duodenum) and lower GIT (jejunum, ileum, caecum, colon, rectum), particularly of healthy adults, will be discussed. However, where necessary, some studies performed with diseased patients or animal models will also be presented and integrated into the state-ofthe-art-knowledge about the human GIT microbiome. In addition, an update on factors shaping the composition of the GIT microbiome will be given. For a more functional or physiological discussion of the human intestinal microbiome, the reader is referred to Chapter 6, this volume. The structure and function of the microbiome of the uppermost part of the human digestive system, i.e. the oral cavity, are presented and discussed in Chapter 2 of this volume. From a microbiological point of view, the human GIT can be regarded as the best

investigated ecological niche of the human body, although some di culties exist in obtaining representative samples from various parts of the GIT. Moreover, the human GIT probably represents one of the best investigated microbial ecosystems on earth. This fact can be explained due to the great importance of the GIT microbiota in maintaining and driving human health, disease and well-being: on a quantitative basis, humans can be regarded as a superorganism, consisting of 90% microbial cells and even 99% microbial genes, and the vast majority of the microbial diversity is located in the human GIT (Wilson, 2008). Consequently, the general importance of the GIT microbiome for human health and disease regarding digestion and general metabolism, gut development or immune status is undoubted. Hence, a wealth of literature on the human GIT micobiome is already available, including several current and comprehensive review articles and reviewing book chapters (Wilson, 2008; Doré and Corthier, 2010; Marchesi, 2010; Gerritsen et al., 2011; Walter and Ley, 2011; Willing and Jansson, 2011). For a complementary overview including some of the more classical literature about the human GIT microbiome, the reader is referred to these articles.

*[email protected] © CAB International 2014. The Human Microbiota and Microbiome (ed. J.R. Marchesi)

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C.U. Riedel et al.

1.2 The Microbiota of the Human Stomach

dependent on the actual gastric pH and range from 103 to 106/ml (Wilson, 2008; Walter and Ley, 2011).

1.2.1 Environmental conditions The human stomach (Fig. 1.1) is a J-shaped structure with a volume of approximately 1.5 l. It can be differentiated into an upper part (fundus), the main body (corpus) and a lower part (antrum), which is connected to the duodenum part of the small intestine via the pyloric sphincter. The folded stomach epithelium is covered by a protective mucus layer of up to 600 μm thickness. The main functions of the human stomach are temporary food storage, mixture of food and gastric juice to chyme, pre-digestion of proteins by acidic pH and pepsin, and disinfection of the ingested food. The environmental conditions in the stomach are eutrophic – due to ingested food, mucus, desquamated epithelial cells and dead microbes – aerobic and acidic, with a more or less constant temperature of 37°C, i.e. the body temperature of the host. Pronounced daily fluctuations in temperature, pH (from pH 1 to pH 5) and available nutrients are common and linked to ingestions of food and beverages. Bacterial viable counts are strongly

1.2.2 Composition of the stomach microbiota Data on the human stomach microbiome are usually collected by investigating biopsies, taken endoscopically after several of hours of fasting. Despite the harsh and antimicrobial environment, recent molecular diversity studies – in particular the widely cited study by Bik and co-workers – have shown, surprisingly, that the human stomach contains a diverse, unevenly distributed microbial community dominated by Proteobacteria, Firmicutes, Bacteroidetes and Actinobacteria (Bik et al., 2006). In endoscopic biopsies taken from 23 North American patients with symptomatic upper gastrointestinal disease, they identified 128 phylotypes from 8 phyla by a 16S rRNA gene clone library approach. Several more recent studies corroborated that a remarkable diversity of bacterial genes could be amplified and identified from the human stomach (Andersson et al., 2008; Dicksved et al., 2009; Li et al., 2009;

Current knowledge

Oesophagus

• remarkable undisputed bacterial diversity: 7–13 phyla, >> 100 phylotypes Fundus Lower oesophagus sphincter Corpus Pyloric sphincter

• presence of Helicobacter sp. dramatically reduces bacterial diversity • key genera: Helicobacter, Streptococcus, Prevotella Key questions • differentiation of truly resident from transient, i.e. food-, mouth- or oesophagus-derived species • functional relevance of the resident microbiota (other than Helicobacter sp.)

Antrum

• effect of presence/absence of Helicobacter sp., diet, ethnicity and gastric diseases (cancer) on community composition

Small intestine Fig. 1.1. Current knowledge and key questions regarding the microbial ecology of the human stomach.

Stomach and Intestinal Microbiomes

Maldonado-Contreras et al., 2011). While investigating ten Helicobacter pylori-free patients with a Chinese background, Li and co-workers quite clearly corroborated several key findings of the American-based study of Bik and colleagues (Li et al., 2009). With respect to the total number of detected phylotypes (133 versus 127), the number of phyla (8 versus 7) and the most abundant two genera (Streptococcus and Prevotella), both studies yielded strikingly similar results. Anderson and co-workers even detected 262 phylotypes representing 13 phyla in biopsies of the stomach of three H. pylori negative patients with peptic ulcers (Andersson et al., 2008). As a consequence, the human stomach can no longer be considered a monoassociated environment. In the thick mucous layer overlying the gastric epithelium, non-acidophilic bacteria can also be found, in particular H. pylori. When present, H. pylori usually dominates the stomach bacterial community (Andersson et al., 2008). So far, H. pylori is the only bacterium of the human stomach that can be considered unambiguously as a true resident and is considered to contribute to the development of gastritis, peptic ulcers and even gastric cancer (Dorer et al., 2009). Several recent studies have tried to unravel correlations between the composition of the microbial community in the stomach and the H. pylori status of patients. In a study by Maldonado-Contreras and colleagues, which was focused on patients from developing countries, a positive H. pylori status was correlated with increased relative abundances of (non-Helicobacter) Proteobacteria, Spirochetes and Acidobacteria, while Actinobacteria, Bacteroidetes and Firmicutes were less abundant (MaldonadoContreras et al., 2011). However, the study also showed that ethnicity had a stronger impact on the stomach community composition than the H. plyori status. Focusing on H. pylori negative patients, Li et al. detected significantly higher abundances of Firmicutes, in particular Streptococcus spp., in the stomach mucosa of patients with antral gastritis (Li et al., 2009). Interestingly, Streptococcus spp., together with bacteria of the genera Lactobacillus, Veillonella and Prevotella, were

3

also abundant members of the stomach community in a study on patients with gastric cancer and a low H. pylori abundance (Dicksved et al., 2009). However, no statistically significant differences were found between the stomach community of cancer and non-cancer patients.

1.2.3 Resident or transient microbiota? Approximately 1010 microorganisms enter the human stomach every day. As a consequence, a clear differentiation of truly resident from just transient (swallowed) microbial species is di cult. Indeed, the majority of the 33 phylotypes identified in the stomach of all three patients investigated by Andersson et al. were a liated with the genera Streptococcus, Actinomyces, Prevotella and Gemella, which were also abundant in the throat community (Andersson et al., 2008). However, streptococci were shown to survive in the stomach and to adhere tightly to the mucosa, suggesting they might truly represent resident stomach species (Li et al., 2009). Acid tolerance is clearly a prerequisite for (even just transient) microbial survival in the stomach lumen, and this is why particularly acid-tolerant streptococci, lactobacilli, staphylococci and Neisseria spp. have frequently been found in the stomach lumen. It was suggested that some of these bacteria be investigated in more detail for potentially beneficial (probiotic) properties (Ryan et al., 2008). A similar suggestion was recently also put forward for propionibacteria: Delgado and co-workers cultured propionibacteria – mostly a liated with P. acnes, but devoid of any clear pathogenic properties – from gastric mucosa samples of 8 out of 12 healthy patients and proposed them as true residents of the human stomach (Delgado et al., 2011). So far, the functional relevance of the surprisingly high microbial diversity in the human stomach is still largely obscure (Lawson and Coyle, 2010). Its elucidation will require more long-term, dynamics-orientated and comparative analyses of mouth, throat and stomach communities and linking of particular physiological conditions, for example those associated with certain gastric

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diseases and/or the presence/absence of H. pylori, with the composition of the microbiota of the stomach. Eventually, such studies might prepare a basis for the definition of novel therapeutic targets (Lawson and Coyle, 2010).

1.3 The Microbiota of the Small Intestine 1.3.1 Environmental conditions In the small intestine, the vast majority of food components are digested by mostly hostderived hydrolytic enzymes and subsequently absorbed by the intestinal mucosa. The small intestine can be divided into three major parts (Fig. 1.2), with a more or less constant diameter (~3 cm) but considerable differences in length: i.e. duodenum (~25 cm), jejunum (~1.0 m) and ileum (~2.0 m). The entire epithelium of the small intestine is covered with a thick (up to 250 μm) protective mucus layer, secreted by goblet cells. In order to facilitate digestion and absorption, the surface area of the small intestine is greatly increased to almost 300 m2 by the formation of villi and

Stomach

microvilli (‘brush border’). On transfer through the pyloric sphincter, chyme from the stomach is mixed with intestinal juice (combined excretion of epithelial cells), pancreatic juice and bile by peristaltic movements. Compared to the large intestine, microbial growth is hampered in the small intestine by relatively short food retention times, antimicrobial peptides secreted by paneth cells and bile salts. However, growth conditions for microorganisms improve towards the end of the small intestine. Consequently, the numbers of luminal microorganisms increase from approximately 102 ml–1 in the jejunum up to 108 ml–1 in the terminal ileum (Wilson, 2008; Walter and Ley, 2011).

1.3.2 Composition of the small intestinal microbiota Due to its restricted accessibility, the microbiota of the human stomach, and particularly of the small intestine, has been investigated much less intensively than that of the mouth and large intestine or faeces. In particular, data on the small intestinal microbiota of

Current knowledge • dominance of facultative and obligate anaerobes (Streptococcus sp., enterobacteria, Clostridium sp., Bacteroidetes)

Duodenum

• increasing cell numbers, microbial diversity and share of anaerobes from duodenum towards ileum

Jejunum

• significantly lower diversity but higher temporal variability of microbial community compared to colon • competition for carbohydrates with host

Large intestine

Ileum

Key questions • functional relevance of the resident microbiota for the host • suitability of stoma patients as models due to potential influx of oxygen • development of appropriate sampling techniques

Fig. 1.2. Current knowledge and key questions regarding the microbial ecology of the human small intestine.

Stomach and Intestinal Microbiomes

healthy individuals are scarce. Until a few years ago, it was common knowledge that the lumen and mucosa of duodenum and jejunum were colonized at low density by only a few microorganisms, including acid-tolerant streptococci and lactobacilli. Towards the end of the ileum, the lumen was described as being dominated by streptococci, enterococci and coliforms, while in the mucosa, obligate anaerobes (Bacteroides spp., Clostridium spp., Bifidobacterium spp.) could also be found (Wilson, 2008, and studies cited therein). This knowledge has been broadened during the past few years. In order to characterize the small intestinal microbiota in more detail by molecular means, Booijink and co-workers investigated the ileal e uent of patients with so-called Brooke ileostomies, i.e. patients with an ileum ending in an opening of the abdominal wall, mostly because the colon had to be removed due to colon cancer (Booijink et al., 2010). They showed that the small intestine was characterized by a less diverse and temporarily more fluctuating microbial community than the large intestine (Booijink et al., 2010). Based on community profiles obtained with a phylogenetic microarray, the average community similarity of four patients over 9 days was just 44%. Notably, no Archaea were detected in the e uent samples. Although the community of each patient was highly individual, a hypothetical common ‘core microbiota’ was defined based on these four patients. It comprised bacteria belonging to the genera Clostridium, Enterococcus, Oxalobacter, Streptococcus and Veillonella. By comparing small intestinal lumen samples obtained from healthy subjects by means of an extended oral catheter with ileal e uent samples, Zoetendal and co-workers very recently showed that the microbial composition of ileal e uent might rather resemble the community in the jejunum (Zoetendal et al., 2012). They identified bacteria belonging to the Bacteroidetes, Clostridium cluster XIVa and Proteobacteria as typical for the ileum. In line with previous studies (Booijink et al., 2010), they corroborated a lower species diversity and significant temporal fluctuations in com-

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munity composition, in comparison to the colon or faecal community. Additionally, using metagenomic, metatranscriptomic and metabolite profiling in addition to community profiling, Zoetendal and colleagues (2012) developed an ecological model of the small intestinal microbiota. They found genes coding for carbohydrate phosphotransferase system (PTS) transport mechanisms, central metabolism and biotin biosynthesis being over-represented in the small intestine. Interestingly, these genes were not only abundantly present in the metagenomic libraries, but also showed high-level in situ expression, as indicated by metatranscriptomic analysis. Apparently, the small intestine is a habitat where the microbiota has to compete vigorously with the human host for carbohydrates, and consequently microorganisms that possess rapid uptake and conversion mechanisms of simple carbohydrates become enriched. In a quantitative PCR (qPCR)-based study on the ileal lumen of 17 patients that had to undergo small bowel transplantation, Hartman et al. could show that the ileal community before and after surgical closure of an ileostomy differed considerably (Hartman et al., 2009). Before the closure, it was dominated by facultative anaerobes (Lactobacillus spp., enterobacteria), while following the closure it was dominated by obligate anaerobes. They concluded that oxygen penetration into the terminal ileum was responsible for the community shift, thereby questioning the relevance, for healthy individuals, of community data obtained with ileostomy patients. Interestingly, the function of the small intestine itself was apparently not affected by this dramatic shift in microbial community composition. Recent progress on disease-related changes in the small intestinal microbiota has been reviewed expertly by Co er (2011). For instance, elevated levels of Bacteroides spp., Clostridium leptum, Escherichia coli and Staphylococcus spp. and decreased levels of Bifidobacterium spp., two other clostridial species and Faecalibacterium prausni ii were detected in duodenal biopsy samples of patients suffering from paediatric coeliac disease (Sokol et al., 2008; Collado et al., 2009;

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De Palma et al., 2010; Schippa et al., 2010). Lower duodenal levels of Bifidobacterium catenulatum were found in patients with irritable bowel syndrome (Kerckhoffs et al., 2009). Finally, lower levels of F. prausni ii and Ruminococcus gnavus and elevated levels of E. coli and Roseburia spp. were found in patients with ileal Crohn’s disease (Willing et al., 2009, 2010). Clearly, more research is needed to differentiate which community changes are causes and which are effects of certain disease states. Moreover, the inventory of the small intestinal species and their longitudinal and transversal spatial distribution is still far from being fully understood. This is, however, a prerequisite to define a ‘normal’ or ‘healthy’ microbial community of the small intestine.

1.4 The Microbiota of the Large Intestine 1.4.1 Environmental conditions The large intestine consists of the caecum, colon (ascending, transverse, descending and sigmoid), rectum and anal canal

(Fig. 1.3). In total, it is about 1.5 m long, 6.5 cm in diameter and has a surface area of approximately 1200 cm2. As in the small intestine, the surface of the colon is covered entirely by mucus under normal conditions. Early studies suggested that the thickness of the colonic mucus layer increased from about 30 μm in the caecum to 90 μm and more in the rectum (Matsuo et al., 1997). However, a very recent analysis has indicated that these values were underestimated and that the mucus layer of the colon might even be up to 450 μm thick (Gustafsson et al., 2012). The morphology of the colonic mucosa differs strongly from that of the small intestine. Permanent folds or villi, as present in the small intestine, are absent. By contrast, the colonic crypts, consisting of absorptive epithelial cells, are lined by a large number of mucus-secreting goblet cells and harbour defensin-producing paneth cells (Me Boutigue et al., 2010). The main function of the colonic epithelium is the reabsorption of ions and water. As a result of water absorption, the chyme becomes solid approximately 3–10 h after having entered the large intestine and is then referred to as faeces. No digestive enzymes are secreted by the cells of the large intestine. Breakdown of

Current knowledge

Stomach

• maximum microbial diversity (collective human GIT microbiota: up to 1800 genera and 15,000 species) • suggestion of a core metagenome based on gene functions

Colon transversum

Colon ascendens

Small intestine

• definition of three human enterotypes: Bacteroides, Prevotella, Ruminococcus

Colon descendens

Sigmoid Rectum

Key questions • microheterogeneity of the microbiota along the colon (longitudinal and transversal) • effect of methodical biases on community composition results • changes in microbial community composition in intestinal or metabolic diseases: cause or consequence? • interactions of bacterial, archaeal, viral (phage) and eukaryotic (fungal) microbiomes with each other and with the host

Fig. 1.3. Current knowledge and key questions regarding the microbial ecology of the human large intestine.

Stomach and Intestinal Microbiomes

dietary constituents, as well as mucus, shed epithelial cells and digestive enzymes is carried out by the resident microbiota. Within the colon, the human microbiota reaches its numeral climax. The density of the microbial community in the colon is approximately 1012 cells per gram of intestinal content. The total microbial weight is estimated to be about 1.5 kg and totals 30% of the volume of the intestinal contents.

1.4.2 Composition of the large intestinal microbiota Of all microorganisms inhabiting the large intestine, bacteria are by far the dominating ones, although an archaeal, viral and eukaryotic community is also present (Wilson, 2008; Dridi et al., 2009; Marchesi, 2010; Minot et al., 2011). Results obtained from culture-dependent and -independent approaches show that the microbiota of the colon is very complex. Culture-based approaches show that many species are present in very small numbers and it has been estimated that only some 40 species, belonging to a handful of genera, make up almost 90% of the colonic microbiota. However, the use of molecular-based and high-throughput techniques revealed an astonishingly high diversity, with more than 800 species or phylotypes from almost 200 genera (Eckburg et al., 2005). Recent results from 16S rRNA gene-sequencing studies suggested even higher numbers, with up to 1800 genera and 15,000 species-level phylotypes, for the collective human GIT microbiota (Peterson et al., 2008). Regarding the proportions of the different organisms present, the microbiota of the colon is dominated by obligate anaerobes. Over the last years, it became evident that two taxa, representing more than 80% of all phylotypes, dominated the colonic microbiota. These taxa are the Firmicutes and the Bacteroidetes. The majority of colonic bacteria a liated with the Bacteroidetes belong to the genus Bacteroides, while the majority of the Firmicutes detectable in the human GIT fall mainly into two groups, the Clostridium coccoides group, also referred to as

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Clostridium cluster XIVa, and the C. leptum group, also referred to as Clostridium cluster IV. However, members of the Proteobacteria, Actinobacteria, Verrucomicrobia and Fusobacteria are also present, albeit in lower numbers (Nam et al., 2011). Even though the composition of the colonic microbiota varies considerably between healthy individuals in terms of absolute numbers and proportions of the different taxa, in a single person it remains relatively stable over time (Flint et al., 2007). Table 1.1 shows the major genera usually found in the human large intestine by means of culture-independent methods. However, it has to be taken into account that our perspective of the colonic microbiota may be blurred. Most of the hitherto obtained data still come from the analysis of faecal samples (Wilson, 2008). But evidence suggests that the composition of the microbiota associated with the mucosa surfaces differs from that of the faecal microbiota (Zoetendal et al., 2002). Unfortunately, due to the fingerprinting technique used by Zoetendal and co-workers (2002), no conclusions on spatial differences on the genus or species level could be obtained. Thus, results obtained from the analysis of faecal samples cannot be interpreted as being representative of the total colon microbiota. In addition, one should keep in mind that colonic biopsies are obtained mainly from humans undergoing colonoscopy, which in general is preceded by a laxative preparation in order to clean the lumen. Such a treatment has a great influence on the composition of the gut microbiota (Mai et al., 2006). However, more studies addressing the spatial differences of microbial communities in the colon of healthy individuals are needed. Assuming that the average genome size of a prokaryotic microorganism is 3.4 Mb and that approximately 92% of the genes of such a genome are coding for proteins, it has been estimated that the gastrointestinal microbiome is 47,000 Mb (Liolios et al., 2010), which is more than two orders of magnitude greater than the human genome. Thus, the microbiome is considered as an essential organ providing the host with enhanced metabolic capabilities, protection against pathogens, education of

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C.U. Riedel et al.

Table 1.1. Major groups of microorganisms detected in human faecal samples by molecular methods. Data compiled from Shen et al., 2010, and Arumugam et al., 2011. Domain

Phylum

Order

Family/genus

Eukarya Archaea Bacteria

Ascomycota Euryarchaeota Firmicutes

Saccharomycetales Methanobacteriales Clostridiales

Candida Methanobrevibacter Anaerostipes Clostridium Eubacterium Ruminococcus Roseburia Dorea Blautia Faecalibacterium Lachnospiraceae Streptococcus

Lactobacillales

Bacteroidetes

Bacteroidales

Proteobacteria Fusobacteria Verrucomicrobia Actinobacteria

Enterobacteriales Fusobacteriales Verrucomicrobiales Bifidobacteriales Coriobacteriales

the immune system and modulation of gastrointestinal (GI) development.

1.4.3 Core microbiota of the large intestine Several groups have recently proposed the concept of a ‘core microbiome’, which is supposed to be present in all humans (Tap et al., 2009; Turnbaugh and Gordon, 2009). This ‘core microbiome’ consists of the most abundant phylotypes and is hypothesized to maintain the functional stability and homeostasis necessary for a healthy ecosystem. Recent sequencing studies suggest that such a ‘core microbiome’ might exist at

Per cent of total