The complex and ancient relationships between animal hosts and the microbial communities
that inhabit their digestive tracts have become the focus of intense research in recent
years. As a result, our understanding of gut microbial ecology and of the evolutionary
and physiologic impacts of gut microbial communities in animal hosts has grown markedly.
Indeed, members of the gut microbiota have now been implicated as environmental factors
in a wide range of human disease states.
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This Special Issue of Gut Microbes is written by leading researchers in the field
and is intended to provide an overview of several important areas of ongoing research
on gut microbial communities during health and disease in humans and other animals.
Although gut microbiota has important relevance for human health today, microbial
colonization of the gut and other body sites is an ancient and pervasive feature of
animal ontogeny.
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The advent of a primitive gut in early metazoan body plans permitted the capture,
concentration, and digestion of exogenous nutrients, and it also provided an attractive
nutrient-rich habitat for otherwise free-living microbes. As a result, all animal
lineages have established complex strategies for defending against and collaborating
with members of their gut microbiota. While some of these strategies can be unique
to a specific animal host lineage, others are shared among different animals including
humans. For this reason, experimental analyses of gut microbiota in diverse animal
host models are essential for providing insights into the evolution of gut microbial
ecology and host-microbiota interactions, and for identifying conserved mechanisms
that might be translatable to humans and other animal hosts. Because our current information
on gut microbial ecology and host-microbiota interactions is derived largely from
vertebrate hosts, this Special Issue highlights contributions from several important
invertebrate host model systems. Cnidaria possess a primitive gastric cavity and serve
as important models for understanding how primitive animals might have interacted
with their microbial world. A review article by Thomas Bosch in this Special Issue
presents the advantages of Hydra as an experimentally tractable Cnidarian, as well
as recent insights into the assembly, composition, and function of Hydra-associated
microbiota.
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The complexity of vertebrate gut microbiotas can pose significant challenges to understanding
these natural co-evolved host-microbe relationships. Therefore, animals such as the
medicinal leech Hirudo verbana that possesses a simple natural microbial community
provide useful models to investigate co-evolved symbioses. A review article by Nelson
and Graf in this Special Issue describes the anatomy and feeding behavior of the medicinal
leech, the composition and roles of its microbiota, and recent insights into the bacterial
genetic determinants of gut colonization.
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Another important invertebrate host model that possesses a relatively simple gut microbiota
coupled with excellent genetic tools is Drosophila. Broderick and Lemaitre present
a review article in this Special Issue describing our current understanding of Drosophila
gut microbiota composition, the factors shaping microbiota composition, and the impact
of the microbiota on Drosophila hosts.
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The study of these animals, together with other major invertebrate and vertebrate
host model systems,
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is leading to important insights into the evolution, ecology, and physiology of gut
microbes that will be beneficial in our effort to understand the microbiota’s roles
in human health and disease.
Our new appreciation for the contributions of gut microbiota to human health and disease
in recent years has fueled intense interest in understanding how gut microbial communities
assemble and influence host health during the earliest stages of the life cycle. In
this Special Issue, Collado and colleagues review our current understanding of the
early ontogeny of the human gut microbiota and the diverse factors that influence
gut microbiota composition during early life stages.
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Using probiotic interventions as an example, they also discuss how manipulations of
the gut microbial community during early stages of life can be used to promote later
health.
The etiology of many human diseases is known to involve both genetic and environmental
factors. The incidence of some human diseases, including obesity, diabetes and atherosclerosis,
has increased alarmingly in recent decades, suggesting a particularly strong environmental
contribution. In this Special Issue, Kelsen and Wu review the growing body of evidence
that dietary and other environmental alterations can influence the composition and
activity of the gut microbiota in mammalian hosts and that such alterations in the
gut microbiota might constitute major environmental factors in these human diseases.
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Obesity is ultimately caused by an imbalance between energy intake and expenditure;
however, recent studies have also strongly implicated the gut microbiota in obesity-associated
metabolic disease. A review by Cani and colleagues in this Special Issue discusses
the mechanisms by which the gut microbiota can contribute to host energy balance,
endocrine signaling, and obesity-associated metabolic disorders such as metabolic
endotoxemia.
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The impact of the gut microbiota on host nutrition is perhaps best understood in the
context of the microbial degradation of complex carbohydrates. The degradation of
complex non-digestible dietary plant polysaccharides and host glycans in ruminants
and hindgut fermenting mammals liberates calories for use by host and microbe and
also has a profound impact on the fitness and radiation of these animal lineages.
An article by Flint and colleagues in this Special Issue reviews our current understanding
of the bacterial gene families that contribute these important metabolic activities,
the specific capabilities of implicated bacterial taxa, and the impact of these activities
on the gut habitat.
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A constant tension within host-microbiota relationships in the gut is created by the
host’s need to defend itself from potentially invasive and pathogenic microbes while
tolerating the persistence of commensal microbial communities within the gut lumen.
Although this task is effectively performed by the mucosal immune system in healthy
individuals, it is now generally accepted that the inflammatory bowel diseases (IBD)
are caused by aberrant host responses to the microbiota. A review by Elson and Cong
in this Special Issue provides a framework for understanding IBD pathogenesis by discussing
our current understanding of the diverse immune responses to the microbiota that maintain
homeostasis and the human genetic variations and underlying mechanisms that confer
susceptibility to IBD.
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The identified contributions of the gut microbiota to IBD, obesity, diabetes, and
atherosclerosis have underscored its potential to impact intestinal as well as extra-intestinal
physiologies. A review by Al-Asmakh and colleagues in this Special Issue presents
an intriguing body of evidence indicating that the gut microbiota can affect, and
be affected by, the communication between the digestive tract and the central nervous
system (CNS).
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The authors discuss recent studies suggesting that this “microbiota-gut-brain” axis
impacts upon a variety of CNS functions, including behavior and mood, and might also
contribute to human diseases such as autism.
As exemplified by the diverse animal model systems and biological processes presented
in this Special Issue of Gut Microbes, the study of gut microbial communities is a
vibrant and highly interdisciplinary field that holds great potential for identifying
new ways to promote health in humans and other animals. The collective insights provided
by this field in recent years have captured the interest and imagination of scientists
and the public alike and have revealed intriguing new realms of biological complexity
within the digestive tract of every animal. The transformation of these new perspectives
into safe and effective approaches for shaping gut microbial communities to promote
health will continue to require the integrated and creative contributions of diverse
experimental systems and scientific disciplines.
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