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• W1849940984 abstract "Watch a video presentation of this article Answer questions and earn CME Our body is a planet populated by myriad microorganisms. Such companions are not casual bystanders or potential invaders when immunity fails to keep them away. Microbial colonizers constitute an important functional part of animals. This was clearly proven some decades ago by experiments using axenic (germ-free) rodents and birds.1 Microbial colonization is critical for nutrition, body growth, induction, and regulation of immunity, endocrine homeostasis, maturation of the central nervous system, and even behavior.1 Humans, after digestion and absorption of nutrients in the upper gastrointestinal tract, retain the residue in the large bowel for an average of 2 days under perfect conditions for feeding microbes. The human colon is by far the largest ecological niche for microbial communities in the human body and harbors more than 100 trillion microbial cells. But which microbes are to be credited for any of those functional contributions, and how do they work? We do not know. This knowledge is essentially needed for improving symbiosis between host and guests. Research on microbial communities in the human gut is progressing rapidly owing to the availability of novel and reliable tools for analysis. Culture-independent approaches are now being used to investigate microbial ecosystems combining molecular sequencing of nucleic acids with powerful bioinformatics for taxonomic identification and comparative analysis of datasets. The small subunit ribosomal RNA gene (16S rRNA) has become the standard in research into prokaryotes (Bacteria and Archea) for assessment of diversity within a given community. Studies have highlighted that only 7 to 9 of the 55 phyla of the domain Bacteria are detected in fecal or mucosal samples from the human gut.2 Around 90% of all taxa belong to just two phyla: Bacteroidetes and Firmicutes. Other phyla that have been consistently found in the human distal gut are Proteobacteria, Actinobacteria, Fusobacteria, and Verrucomicrobia (Fig. 1). Only a very few species of Archea (mostly Methanobrevibacter smithii) are represented. Common genera of the human gut microbiota. Genus abundance variation box plot for the 30 most abundant genera of the human gut microbiota as determined by metagenomic sequencing of human fecal samples. Genera are colored by their respective phylum (see inset for color key). Inset shows phylum abundance box plot (source: Figure 1b in Arumugam M, et al. Enterotypes of the human gut microbiome. Nature 2011;473:174–180). [Color figure can be viewed in the online issue, which is available at wileyonlinelibrary.com.] There are differences between fecal- and mucosa-associated communities within the same individual.2 Bacterial composition in the lumen varies from cecum to rectum, whereas the community of mucosa-associated bacteria is highly stable from terminal ileum to large bowel in a given individual.3 Factors such as diet, drug intake, traveling, or colonic transit time have an impact on the microbial composition of fecal samples over time in a unique host.4, 5 Intraindividual fluctuations in the composition of the microbiota can be remarkable, but the microbial ecosystem tends to return to its typical compositional pattern (Fig. 2). Most strains are resident for decades in a given individual.6 Intraindividual variation of microbiota composition. Temporal variation in genus abundance in fecal samples from a single human individual sampled daily for 15 months. Columns represent the microbial composition of each sample at genus level, and colors indicate genera as follows: Bacteroides, red; Faecalibacterium, beige; Akkermansia, pale green; Roseburia, light blue; Parabacteroides, yellow; other bacteroides, black; Bifidobacterium, gray (Source: additional file 8 in Caporaso JG, Lauber CL, Costello EK, et al Moving pictures of the human microbiome. Genome Biol 2011;12:R50). [Color figure can be viewed in the online issue, which is available at wileyonlinelibrary.com.] There are striking differences in composition and diversity between westernized and nonwesternized populations. Microbial diversity changes with age, but the fecal microbiota of adults is less diverse in metropolitan areas of North America than in rural nonwesternized populations of Africa and South America.7 The molecular approach is not limited to 16S rRNA sequencing. The decreasing cost and increasing speed of DNA sequencing, coupled with advances in computational analyses of large data sets, have made it feasible to analyze entire genomes with reasonable coverage. The resulting information describes the collective genetic content of the community from which functional and metabolic networks can be inferred. Importantly, whole-genome sequencing provides information about nonbacterial members in the community, including viruses, yeasts, and protists. Full metagenomic analysis of human fecal samples has identified up to 10 million nonredundant microbial genes.8 A large majority (95%) of the identifiable genes are bacterial, with a small proportion of virus-like or eukaryotic genes. Each individual carries an average of 600,000 nonredundant microbial genes in the gastrointestinal tract, and around 300,000 genes are common, in the sense that they are present in about 50% of individuals. At the strain level, each individual harbors a distinctive pattern of microbial communities. However, network analysis of fecal communities at the genus level across different individuals has suggested that the microbial ecosystem conforms to well-balanced microbial symbiotic states driven by groups of co-occurring genera. Multidimensional scaling and principal coordinates analysis of samples from American, European, and Japanese subjects revealed that all individual samples gathered around three robust clusters according to their similarity in composition. Clustering was not driven by age, sex, nationality, or body mass index. These clusters were designated as “enterotypes.”9 Each enterotype is identifiable by variation in the levels of one of three genera: Bacteroides (enterotype 1), Prevotella (enterotype 2), and Ruminococcus (enterotype 3). Enterotype partitioning suggests the existence of a limited number of well-balanced host-microbial symbiotic states. The discreteness of these balanced states suggests that the fundamental structure of the human gut microbiota is primarily determined by interactions within the community members (Fig. 3). Genome size and number of coding genes are much smaller in prokaryotes than in eukaryotes. Thus, single microbial species do not have enough genetic resources on their own and are likely to have obligate dependence on other species. Therefore, multispecies communities with complex nutritional and social interdependencies are the natural lifestyle for most prokaryotes. Enterotypes, Enterotypes are balanced host-microbial symbiotic states driven by groups of co-occurring genera. Three enterotypes have been described in Western individuals, each of which is identifiable by the variation in the levels of one of three genera: Bacteroides (enterotype 1), Prevotella (enterotype 2), and Ruminococcus (enterotype 3). Networks of genera in the three enterotypes are identified by positive and negative correlations among the dominant genera (Source: Figure 2e in Arumugam M, et al. Enterotypes of the human gut microbiome. Nature 2011;473:174–180). [Color figure can be viewed in the online issue, which is available at wileyonlinelibrary.com.] Clinical implications of enterotypes are under investigation. A study exploring the associations between diet and gut microbiota composition, based on food frequency questionnaires collected over long periods, indicated that diet affects the proportions of Prevotella versus Bacteroides in US populations.10 The presence of stable gut microbial communities can be linked to long-term dietary patterns. Functional screening relies on sequencing all genetic material in the community, including taxonomically unknown members, and matching the sequences to known functional genes. Such studies have generated fascinating information about functions within the microbial communities of the human gut. The extensive nonredundant catalogue of microbial genes encodes groups of proteins engaged in up to 20,000 biological functions related to life in the intestinal habitat.11 Some functions are common to free-living bacteria, like the main metabolic pathways (e.g., central carbon metabolism and amino acid synthesis), and some important protein complexes (RNA and DNA polymerases, ATP synthase, general secretory apparatus). Some other gene clusters encode functions that may be especially important for microbial life within the gut, such as those involved in adhesion to the host proteins (collagen, fibrinogen, fibronectin) or in harvesting sugars from the glycolipids secreted by epithelial cells. Interestingly, despite the highly divergent compositions of gut microbiota across individuals in terms of taxonomy, functional gene profiles are rather similar in healthy subjects. Most functional pathways are common and expressed in similar abundance among fecal microbiotas from different human individuals.12 Such data imply that there is functional redundance across taxonomic diversity, that is, same or similar functional pathways are present in different microbial species. This concept is likely to be very relevant for a definition of a “normal” or “healthy” gut microbial ecosystem in humans: functional profiling may eventually become the optimal approach rather than the listing of species or strains. Pathologies such as Clostridium difficile–associated diarrhea, inflammatory bowel diseases, obesity, type 2 diabetes, nonalcoholic steatohepatitis, advanced chronic liver disease, and others, have been linked to changes in the composition of the gut microbiota.13 Consistency among studies is still poor for some of these examples, possibly because of lack of fully standardized methodology. In addition, such associations do not necessarily indicate a causative role for the microbiota in the pathogenesis of a disease, as they could rather be a consequence of the disease. Follow-up studies and, particularly, intervention studies aimed at restoring the normal composition of the gut microbiota are needed. Richness of the gut microbial ecosystem appears to be a critical characteristic for a healthy gut microbiota. Low diversity is associated with an imbalance between pro- and anti-inflammatory species and may trigger host inflammation. Microbial gene counts can be used as an accurate biomarker of microbial diversity or richness, as this strategy can assess the presence and abundance of genes from known as well as unknown taxa, including not only bacteria but also viruses and eukaryotes. Interestingly, individuals with low microbial gene counts (below 480.000) are characterized by more marked overall adiposity, insulin resistance, leptin resistance, dyslipidemia, and a more pronounced inflammatory phenotype when compared with high-gene-count individuals.14 Moreover, several metabolic parameters were slightly altered in otherwise healthy individuals with low microbial gene counts. Obese individuals with low gene counts gained more weight over time and had a propensity toward metabolic comorbidities. Low diversity appears to be a risk factor for the development of metabolic syndrome (type 2 diabetes, dyslipidemia, steatohepatitis). From a functional point of view, low diversity is associated with a reduction in butyrate-producing bacteria, increased mucus degradation potential, and reduced hydrogen and methane production combined with increased hydrogen sulfide formation (Fig. 4). The gene-poor microbiota thus appears to be less healthy.14 Functional shifts associated with low diversity in the gut microbiome. Top, observed increase (red) or decrease (green) of functions and phylogenetic groups. Bottom, potential drivers (yellow) of inflammation related to decreased richness. Left, antibiotic-mediated perturbation of the richness; right, proteobacterial lipopolysaccharide-mediated perturbation of the richness. AB, antibiotic; IR, insulin resistance (source: from Figure 3 in: Le Chatelier E, Nielsen T, Qin J, et al. Richness of human gut microbiome correlates with metabolic markers. Nature 2013;500:541–546). [Color figure can be viewed in the online issue, which is available at wileyonlinelibrary.com.] Molecular studies provide spectral insight into the microbial communities that inhabit the human gut and allow the identification of changes that are associated with disease. Better knowledge of the contributions of microbial symbionts to host health will certainly help in the design of novel interventions to improve symbiosis and combat disease." @default.
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• W1849940984 title "The gut microbiome: What do we know?" @default.
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