Your search keyword '"Enteric Nervous System microbiology"' showing total 40 results

1. Role of enteric glia and microbiota-gut-brain axis in parkinson disease pathogenesis.

Author

Claudino Dos Santos JC, Lima MPP, Brito GAC, and Viana GSB

Subjects

Humans, alpha-Synuclein metabolism, Brain metabolism, Inflammation metabolism, Neuroglia metabolism, Neuroglia pathology, Brain-Gut Axis physiology, Parkinson Disease metabolism, Parkinson Disease pathology, Enteric Nervous System microbiology, Enteric Nervous System pathology

Abstract

The microbiota-gut-brain axis or simple gut-brain axis (GBA) is a complex and interactive bidirectional communication network linking the gut to the brain. Alterations in the composition of the gut microbiome have been linked to GBA dysfunction, central nervous system (CNS) inflammation, and dopaminergic degeneration, as those occurring in Parkinson's disease (PD). Besides inflammation, the activation of brain microglia is known to play a central role in the damage of dopaminergic neurons. Inflammation is attributed to the toxic effect of aggregated α-synuclein, in the brain of PD patients. It has been suggested that the α-synuclein misfolding might begin in the gut and spread "prion-like", via the vagus nerve into the lower brainstem and ultimately to the midbrain, known as the Braak hypothesis. In this review, we discuss how the microbiota-gut-brain axis and environmental influences interact with the immune system to promote a pro-inflammatory state that is involved in the initiation and progression of misfolded α-synuclein proteins and the beginning of the early non-motor symptoms of PD. Furthermore, we describe a speculative bidirectional model that explains how the enteric glia is involved in the initiation and spreading of inflammation, epithelial barrier disruption, and α-synuclein misfolding, finally reaching the central nervous system and contributing to neuroinflammatory processes involved with the initial non-motor symptoms of PD., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest. All authors read and approved the final manuscript., (Copyright © 2022 Elsevier B.V. All rights reserved.)

Published

2023

2. Enteric pathogens induce tissue tolerance and prevent neuronal loss from subsequent infections.

Author

Ahrends T, Aydin B, Matheis F, Classon CH, Marchildon F, Furtado GC, Lira SA, and Mucida D

Subjects

Animals, Eosinophils metabolism, Hematopoietic Stem Cells metabolism, Immunity, Infections immunology, Interleukin-13 metabolism, Interleukin-4 metabolism, Macrophages metabolism, Mice, Inbred BALB C, Mice, Inbred C57BL, Strongyloides physiology, Strongyloidiasis genetics, Strongyloidiasis immunology, Strongyloidiasis parasitology, Transcriptome genetics, Yersinia pseudotuberculosis Infections genetics, Yersinia pseudotuberculosis Infections immunology, Yersinia pseudotuberculosis Infections microbiology, Mice, Enteric Nervous System microbiology, Enteric Nervous System parasitology, Infections microbiology, Infections parasitology, Neurons pathology, Neuroprotection, Organ Specificity, Yersinia pseudotuberculosis physiology

Abstract

The enteric nervous system (ENS) controls several intestinal functions including motility and nutrient handling, which can be disrupted by infection-induced neuropathies or neuronal cell death. We investigated possible tolerance mechanisms preventing neuronal loss and disruption in gut motility after pathogen exposure. We found that following enteric infections, muscularis macrophages (MMs) acquire a tissue-protective phenotype that prevents neuronal loss, dysmotility, and maintains energy balance during subsequent challenge with unrelated pathogens. Bacteria-induced neuroprotection relied on activation of gut-projecting sympathetic neurons and signaling via β 2 -adrenergic receptors (β2AR) on MMs. In contrast, helminth-mediated neuroprotection was dependent on T cells and systemic production of interleukin (IL)-4 and IL-13 by eosinophils, which induced arginase-expressing MMs that prevented neuronal loss from an unrelated infection located in a different intestinal region. Collectively, these data suggest that distinct enteric pathogens trigger a state of disease or tissue tolerance that preserves ENS number and functionality., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

3. Interactions between the microbiota and enteric nervous system during gut-brain disorders.

Author

Fried S, Wemelle E, Cani PD, and Knauf C

Subjects

Animals, Enteric Nervous System microbiology, Humans, Neurodegenerative Diseases psychology, Brain-Gut Axis, Enteric Nervous System physiopathology, Gastrointestinal Microbiome, Neurodegenerative Diseases microbiology, Neurodegenerative Diseases physiopathology

Abstract

For the last 20 years, researchers have focused their intention on the impact of gut microbiota in healthy and pathological conditions. This year (2021), more than 25,000 articles can be retrieved from PubMed with the keywords "gut microbiota and physiology", showing the constant progress and impact of gut microbes in scientific life. As a result, numerous therapeutic perspectives have been proposed to modulate the gut microbiota composition and/or bioactive factors released from microbes to restore our body functions. Currently, the gut is considered a primary site for the development of pathologies that modify brain functions such as neurodegenerative (Parkinson's, Alzheimer's, etc.) and metabolic (type 2 diabetes, obesity, etc.) disorders. Deciphering the mode of interaction between microbiota and the brain is a real original option to prevent (and maybe treat in the future) the establishment of gut-brain pathologies. The objective of this review is to describe recent scientific elements that explore the communication between gut microbiota and the brain by focusing our interest on the enteric nervous system (ENS) as an intermediate partner. The ENS, which is known as the "second brain", could be under the direct or indirect influence of the gut microbiota and its released factors (short-chain fatty acids, neurotransmitters, gaseous factors, etc.). Thus, in addition to their actions on tissue (adipose tissue, liver, brain, etc.), microbes can have an impact on local ENS activity. This potential modification of ENS function has global repercussions in the whole body via the gut-brain axis and represents a new therapeutic strategy. This article is part of the special Issue on 'Cross Talk between Periphery and the Brain'., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

4. Microbial Modulation of the Development and Physiology of the Enteric Nervous System.

Author

Joly A, Leulier F, and De Vadder F

Subjects

Enteric Nervous System immunology, Enteric Nervous System microbiology, Gastrointestinal Microbiome physiology, Humans, Intestines microbiology, Neurons physiology, Enteric Nervous System physiology, Gastrointestinal Microbiome genetics, Gene Expression Regulation, Bacterial, Homeostasis

Abstract

The gastrointestinal tract harbors an intrinsic neuronal network, the enteric nervous system (ENS). The ENS controls motility, fluid homeostasis, and blood flow, but also interacts with other components of the intestine such as epithelial and immune cells. Recent studies indicate that gut microbiota diversification, which occurs alongside postnatal ENS maturation, could be critical for the development and function of the ENS. Here we discuss the possibility that this functional relationship starts in utero, whereby the maternal microbiota would prime the developing ENS and shape its physiology. We review ENS/microbiota interactions and their modulation in physiological and pathophysiological contexts. While microbial modulation of the ENS physiology is now well established, further studies are required to understand the contribution of the gut microbiota to the development and pathology of the ENS and to reveal the precise mechanisms underlying microbiota-to-ENS communications., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2021

5. Targeting the gut to treat multiple sclerosis.

Author

Ghezzi L, Cantoni C, Pinget GV, Zhou Y, and Piccio L

Subjects

Animals, Autoimmunity, Disease Models, Animal, Dysbiosis immunology, Dysbiosis physiopathology, Endocrine System immunology, Endocrine System physiopathology, Enteric Nervous System immunology, Enteric Nervous System microbiology, Enteric Nervous System physiopathology, Fecal Microbiota Transplantation, Humans, Intestinal Mucosa immunology, Intestinal Mucosa microbiology, Intestinal Mucosa physiopathology, Models, Neurological, Multiple Sclerosis etiology, Multiple Sclerosis microbiology, Neuroimmunomodulation, Probiotics therapeutic use, Gastrointestinal Microbiome drug effects, Gastrointestinal Microbiome immunology, Gastrointestinal Microbiome physiology, Multiple Sclerosis therapy

Abstract

The gut-brain axis (GBA) refers to the complex interactions between the gut microbiota and the nervous, immune, and endocrine systems, together linking brain and gut functions. Perturbations of the GBA have been reported in people with multiple sclerosis (pwMS), suggesting a possible role in disease pathogenesis and making it a potential therapeutic target. While research in the area is still in its infancy, a number of studies revealed that pwMS are more likely to exhibit altered microbiota, altered levels of short chain fatty acids and secondary bile products, and increased intestinal permeability. However, specific microbes and metabolites identified across studies and cohorts vary greatly. Small clinical and preclinical trials in pwMS and mouse models, in which microbial composition was manipulated through the use of antibiotics, fecal microbiota transplantation, and probiotic supplements, have provided promising outcomes in preventing CNS inflammation. However, results are not always consistent, and large-scale randomized controlled trials are lacking. Herein, we give an overview of how the GBA could contribute to MS pathogenesis, examine the different approaches tested to modulate the GBA, and discuss how they may impact neuroinflammation and demyelination in the CNS.

Published

2021

6. Review: Occurrence and Distribution of Galanin in the Physiological and Inflammatory States in the Mammalian Gastrointestinal Tract.

Author

Brzozowska M and Całka J

Subjects

Animals, Brachyspira hyodysenteriae immunology, Colitis immunology, Colitis microbiology, Colitis pathology, Enteric Nervous System microbiology, Enteric Nervous System pathology, Gastrointestinal Tract microbiology, Gastrointestinal Tract pathology, Gram-Negative Bacterial Infections immunology, Gram-Negative Bacterial Infections microbiology, Gram-Negative Bacterial Infections pathology, Humans, Inflammation immunology, Inflammation microbiology, Inflammation pathology, Swine, Enteric Nervous System immunology, Galanin immunology, Gastrointestinal Tract immunology

Abstract

Galanin (GAL) is a broad-spectrum peptide that was first identified 37 years ago. GAL, which acts through three specific receptor subtypes, is one of the most important molecules on an ever-growing list of neurotransmitters. Recent studies indicate that this peptide is commonly present in the gastrointestinal (GI) tract and GAL distribution can be seen in the enteric nervous system (ENS). The function of the GAL in the gastrointestinal tract is, inter alia , to regulate motility and secretion. It should be noted that the distribution of neuropeptides is largely dependent on the research model, as well as the part of the gastrointestinal tract under study. During the development of digestive disorders, fluctuations in GAL levels were observed. The occurrence of GAL largely depends on the stage of the disease, e.g., in porcine experimental colitis GAL secretion is caused by infection with Brachyspira hyodysenteriae . Many authors have suggested that increased GAL presence is related to the involvement of GAL in organ renewal. Additionally, it is tempting to speculate that GAL may be used in the treatment of gastroenteritis. This review aims to present the function of GAL in the mammalian gastrointestinal tract under physiological conditions. In addition, since GAL is undoubtedly involved in the regulation of inflammatory processes, and the aim of this publication is to provide up-to-date knowledge of the distribution of GAL in experimental models of gastrointestinal inflammation, which may help to accurately determine the role of this peptide in inflammatory diseases and its potential future use in the treatment of gastrointestinal disorders., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Brzozowska and Całka.)

Published

2021

7. Early life interaction between the microbiota and the enteric nervous system.

Author

Foong JPP, Hung LY, Poon S, Savidge TC, and Bornstein JC

Subjects

Animals, Enteric Nervous System microbiology, Environment, Humans, Mice, Microbiota, Enteric Nervous System growth & development, Enteric Nervous System physiology, Gastrointestinal Microbiome physiology

Abstract

Recent studies on humans and their key experimental model, the mouse, have begun to uncover the importance of gastrointestinal (GI) microbiota and enteric nervous system (ENS) interactions during developmental windows spanning from conception to adolescence. Disruptions in GI microbiota and ENS during these windows by environmental factors, particularly antibiotic exposure, have been linked to increased susceptibility of the host to several diseases. Mouse models have provided new insights to potential signaling factors between the microbiota and ENS. We review very recent work on maturation of GI microbiota and ENS during three key developmental windows: embryogenesis, early postnatal, and postweaning periods. We discuss advances in understanding of interactions between the two systems and highlight research avenues for future studies.

Published

2020

8. Influence of bacterial components on the developmental programming of enteric neurons.

Author

Popov J, Bandura J, Markovic F, Borojevic R, Anipindi VC, Pai N, and Ratcliffe EM

Subjects

Animals, Apoptosis, Cell Differentiation physiology, Cells, Cultured, Enteric Nervous System metabolism, Female, Mice, Mice, Inbred C57BL, Nerve Tissue Proteins genetics, Neurons metabolism, Pregnancy, Bacteria metabolism, Enteric Nervous System cytology, Enteric Nervous System microbiology, Nerve Tissue Proteins metabolism, Neurons cytology, Neurons microbiology

Abstract

Background: Intestinal bacteria have been increasingly shown to be involved in early postnatal development. Previous work has shown that intestinal bacteria are necessary for the structural development and intrinsic function of the enteric nervous system in early postnatal life. Furthermore, colonization with a limited number of bacteria appears to be sufficient for the formation of a normal enteric nervous system. We tested the hypothesis that common bacterial components could influence the programming of developing enteric neurons., Methods: The developmental programming of enteric neurons was studied by isolating enteric neural crest-derived cells from the fetal gut of C57Bl/6 mice at embryonic day 15.5. After the establishment of the cell line, cultured enteric neuronal precursors were exposed to increasing concentrations of a panel of bacterial components including lipopolysaccharide, flagellin, and components of peptidoglycan., Key Result: Exposure to bacterial components consistently affected proportions of enteric neuronal precursors that developed into nitrergic neurons. Furthermore, flagellin and D-gamma-Glu-mDAP were found to promote the development of serotonergic neurons. Proportions of dopaminergic neurons remained unchanged. Proliferation of neuronal precursor cells was significantly increased upon exposure to lipopolysaccharide and flagellin, while no significant changes were observed in the proportion of apoptotic neuronal precursors compared to baseline with exposure to any bacterial component., Conclusions and Interfaces: These findings suggest that bacterial components may influence the development of enteric neurons., (© 2020 The Authors. Physiological Reports published by Wiley Periodicals, Inc. on behalf of The Physiological Society and the American Physiological Society.)

Published

2020

9. Neural Immune Communication in the Control of Host-Bacterial Pathogen Interactions in the Gastrointestinal Tract.

Author

Ramirez V, Swain S, Murray K, and Reardon C

Subjects

Animals, Calcitonin Gene-Related Peptide genetics, Calcitonin Gene-Related Peptide immunology, Citrobacter growth & development, Citrobacter immunology, Enteric Nervous System microbiology, Enterobacteriaceae Infections genetics, Enterobacteriaceae Infections microbiology, Enterobacteriaceae Infections pathology, Gastrointestinal Tract innervation, Gastrointestinal Tract microbiology, Gene Expression Regulation immunology, Host-Pathogen Interactions genetics, Host-Pathogen Interactions immunology, Humans, Pathogen-Associated Molecular Pattern Molecules immunology, Pathogen-Associated Molecular Pattern Molecules metabolism, Sensory Receptor Cells microbiology, TRPA1 Cation Channel genetics, TRPA1 Cation Channel immunology, TRPV Cation Channels genetics, TRPV Cation Channels immunology, Toll-Like Receptors genetics, Toll-Like Receptors immunology, Enteric Nervous System immunology, Enterobacteriaceae Infections immunology, Gastrointestinal Microbiome immunology, Gastrointestinal Tract immunology, Neuroimmunomodulation genetics, Sensory Receptor Cells immunology

Abstract

The orchestration of host immune responses to enteric bacterial pathogens is a complex process involving the integration of numerous signals, including from the nervous system. Despite the recent progress in understanding the contribution of neuroimmune interactions in the regulation of inflammation, the mechanisms and effects of this communication during enteric bacterial infection are only beginning to be characterized. As part of this neuroimmune communication, neurons specialized to detect painful or otherwise noxious stimuli can respond to bacterial pathogens. Highlighting the complexity of these systems, the immunological consequences of sensory neuron activation can be either host adaptive or maladaptive, depending on the pathogen and organ system. These are but one of many types of neuroimmune circuits, with the vagus nerve and sympathetic innervation of numerous organs now known to modulate immune cell function and therefore dictate immunological outcomes during health and disease. Here, we review the evidence for neuroimmune communication in response to bacterial pathogens, and then discuss the consequences to host morbidity and mortality during infection of the gastrointestinal tract., (Copyright © 2020 American Society for Microbiology.)

Published

2020

10. Chronic Intra-Uterine Ureaplasma parvum Infection Induces Injury of the Enteric Nervous System in Ovine Fetuses.

Author

Heymans C, de Lange IH, Hütten MC, Lenaerts K, de Ruijter NJE, Kessels LCGA, Rademakers G, Melotte V, Boesmans W, Saito M, Usuda H, Stock SJ, Spiller OB, Beeton ML, Payne MS, Kramer BW, Newnham JP, Jobe AH, Kemp MW, van Gemert WG, and Wolfs TGAM

Subjects

Animals, Animals, Newborn, Chorioamnionitis chemically induced, Chorioamnionitis microbiology, Chronic Disease veterinary, Disease Models, Animal, Enteric Nervous System drug effects, Enterocolitis, Necrotizing chemically induced, Enterocolitis, Necrotizing microbiology, Female, Intestinal Mucosa drug effects, Intestinal Mucosa microbiology, Lipopolysaccharides pharmacology, Pregnancy, Premature Birth veterinary, S100 Calcium Binding Protein beta Subunit metabolism, Sheep microbiology, Ubiquitin Thiolesterase metabolism, Ureaplasma Infections microbiology, Chorioamnionitis veterinary, Enteric Nervous System injuries, Enteric Nervous System microbiology, Enterocolitis, Necrotizing veterinary, Fetus microbiology, Sheep embryology, Ureaplasma, Ureaplasma Infections complications, Ureaplasma Infections veterinary

Abstract

Background: Chorioamnionitis, inflammation of the fetal membranes during pregnancy, is often caused by intra-amniotic (IA) infection with single or multiple microbes. Chorioamnionitis can be either acute or chronic and is associated with adverse postnatal outcomes of the intestine, including necrotizing enterocolitis (NEC). Neonates with NEC have structural and functional damage to the intestinal mucosa and the enteric nervous system (ENS), with loss of enteric neurons and glial cells. Yet, the impact of acute, chronic, or repetitive antenatal inflammatory stimuli on the development of the intestinal mucosa and ENS has not been studied. The aim of this study was therefore to investigate the effect of acute, chronic, and repetitive microbial exposure on the intestinal mucosa, submucosa and ENS in premature lambs. Materials and Methods: A sheep model of pregnancy was used in which the ileal mucosa, submucosa, and ENS were assessed following IA exposure to lipopolysaccharide (LPS) for 2 or 7 days (acute), Ureaplasma parvum (UP) for 42 days (chronic), or repetitive microbial exposure (42 days UP with 2 or 7 days LPS). Results: IA LPS exposure for 7 days or IA UP exposure for 42 days caused intestinal injury and inflammation in the mucosal and submucosal layers of the gut. Repetitive microbial exposure did not further aggravate injury of the terminal ileum. Chronic IA UP exposure caused significant structural ENS alterations characterized by loss of PGP9.5 and S100β immunoreactivity, whereas these changes were not found after re-exposure of chronic UP-exposed fetuses to LPS for 2 or 7 days. Conclusion: The in utero loss of PGP9.5 and S100β immunoreactivity following chronic UP exposure corresponds with intestinal changes in neonates with NEC and may therefore form a novel mechanistic explanation for the association of chorioamnionitis and NEC., (Copyright © 2020 Heymans, de Lange, Hütten, Lenaerts, de Ruijter, Kessels, Rademakers, Melotte, Boesmans, Saito, Usuda, Stock, Spiller, Payne, Kramer, Newnham, Jobe, Kemp, van Gemert and Wolfs.)

Published

2020

11. Enteric Neuromodulation for the Gut and Beyond.

Author

Patel YA and Pasricha PJ

Subjects

Animals, Enteric Nervous System microbiology, Homeostasis, Humans, Intestine, Small microbiology, Enteric Nervous System physiology, Gastrointestinal Microbiome physiology, Intestine, Small physiology

Abstract

The small intestine is the longest organ in the human body, spanning a length of ∼5 m and compartmentalized into three distinct regions with specific roles in maintenance of comprehensive homeostasis. Along its length exists as a unique and independent system-called the enteric nervous system (ENS)-which coordinates the multitude of functions continuously around the clock. Yet, with so many vital roles played, the functions, relationships, and roles of the small intestine and ENS remain largely elusive. This fundamental hole in the physiology of the small intestine and ENS introduces a substantial number of challenges when attempting to create bioelectronic approaches for treatment of various disorders originating in the small intestine. Here, we review existing therapeutic options for modulating the small intestine, discuss fundamental gaps that must be addressed, and highlight novel methods and approaches to consider for development of bioelectronic approaches aiming to modulate the small intestine., (Copyright © 2020 Cold Spring Harbor Laboratory Press; all rights reserved.)

Published

2020

12. The Microbiota-Gut-Brain Axis.

Author

Cryan JF, O'Riordan KJ, Cowan CSM, Sandhu KV, Bastiaanssen TFS, Boehme M, Codagnone MG, Cussotto S, Fulling C, Golubeva AV, Guzzetta KE, Jaggar M, Long-Smith CM, Lyte JM, Martin JA, Molinero-Perez A, Moloney G, Morelli E, Morillas E, O'Connor R, Cruz-Pereira JS, Peterson VL, Rea K, Ritz NL, Sherwin E, Spichak S, Teichman EM, van de Wouw M, Ventura-Silva AP, Wallace-Fitzsimons SE, Hyland N, Clarke G, and Dinan TG

Subjects

Age Factors, Aging, Animals, Bacteria immunology, Bacteria pathogenicity, Behavior, Brain immunology, Brain metabolism, Brain physiopathology, Brain Diseases metabolism, Brain Diseases physiopathology, Brain Diseases psychology, Dysbiosis, Enteric Nervous System metabolism, Enteric Nervous System microbiology, Enteric Nervous System physiopathology, Host-Pathogen Interactions, Humans, Intestines immunology, Neuroimmunomodulation, Neuronal Plasticity, Risk Factors, Bacteria metabolism, Brain microbiology, Brain Diseases microbiology, Gastrointestinal Microbiome, Intestines microbiology

Abstract

The importance of the gut-brain axis in maintaining homeostasis has long been appreciated. However, the past 15 yr have seen the emergence of the microbiota (the trillions of microorganisms within and on our bodies) as one of the key regulators of gut-brain function and has led to the appreciation of the importance of a distinct microbiota-gut-brain axis. This axis is gaining ever more traction in fields investigating the biological and physiological basis of psychiatric, neurodevelopmental, age-related, and neurodegenerative disorders. The microbiota and the brain communicate with each other via various routes including the immune system, tryptophan metabolism, the vagus nerve and the enteric nervous system, involving microbial metabolites such as short-chain fatty acids, branched chain amino acids, and peptidoglycans. Many factors can influence microbiota composition in early life, including infection, mode of birth delivery, use of antibiotic medications, the nature of nutritional provision, environmental stressors, and host genetics. At the other extreme of life, microbial diversity diminishes with aging. Stress, in particular, can significantly impact the microbiota-gut-brain axis at all stages of life. Much recent work has implicated the gut microbiota in many conditions including autism, anxiety, obesity, schizophrenia, Parkinson's disease, and Alzheimer's disease. Animal models have been paramount in linking the regulation of fundamental neural processes, such as neurogenesis and myelination, to microbiome activation of microglia. Moreover, translational human studies are ongoing and will greatly enhance the field. Future studies will focus on understanding the mechanisms underlying the microbiota-gut-brain axis and attempt to elucidate microbial-based intervention and therapeutic strategies for neuropsychiatric disorders.

Published

2019

13. The role of the gut microbiota in development, function and disorders of the central nervous system and the enteric nervous system.

Author

Heiss CN and Olofsson LE

Subjects

Animals, Central Nervous System growth & development, Central Nervous System physiopathology, Enteric Nervous System growth & development, Enteric Nervous System physiopathology, Humans, Central Nervous System microbiology, Central Nervous System Diseases microbiology, Enteric Nervous System microbiology, Gastrointestinal Microbiome physiology

Abstract

The gut microbiota has emerged as an environmental factor that modulates the development of the central nervous system (CNS) and the enteric nervous system (ENS). Before obtaining its own microbiota, eutherian foetuses are exposed to products and metabolites from the maternal microbiota. At birth, the infants are colonised by microorganisms. The microbial composition in early life is strongly influenced by the mode of delivery, the feeding method, the use of antibiotics and the maternal microbial composition. Microbial products and microbially produced metabolites act as signalling molecules that have direct or indirect effects on the CNS and the ENS. An increasing number of studies show that the gut microbiota can modulate important processes during development, including neurogenesis, myelination, glial cell function, synaptic pruning and blood-brain barrier permeability. Furthermore, numerous studies indicate that there is a developmental window early in life during which the gut microbial composition is crucial and perturbation of the gut microbiota during this period causes long-lasting effects on the development of the CNS and the ENS. However, other functions are readily modulated in adult animals, including microglia activation and neuroinflammation. Several neurobehavioural, neurodegenerative, mental and metabolic disorders, including Parkinson disease, autism spectrum disorder, schizophrenia, Alzheimer's disease, depression and obesity, have been linked to the gut microbiota. This review focuses on the role of the microorganisms in the development and function of the CNS and the ENS, as well as their potential role in pathogenesis., (© 2019 British Society for Neuroendocrinology.)

Published

2019

14. Interplay among gut microbiota, intestinal mucosal barrier and enteric neuro-immune system: a common path to neurodegenerative diseases?

Author

Pellegrini C, Antonioli L, Colucci R, Blandizzi C, and Fornai M

Subjects

Animals, Enteric Nervous System pathology, Humans, Intestinal Mucosa pathology, Neurodegenerative Diseases pathology, Enteric Nervous System microbiology, Gastrointestinal Microbiome physiology, Intestinal Mucosa microbiology, Neurodegenerative Diseases microbiology

Abstract

Neurological diseases, such as Parkinson's disease, Alzheimer's disease, amyotrophic lateral sclerosis (ALS) and multiple sclerosis, are often associated with functional gastrointestinal disorders. These gastrointestinal disturbances may occur at all stages of the neurodegenerative diseases, to such an extent that they are now considered an integral part of their clinical picture. Several lines of evidence support the contention that, in central neurodegenerative diseases, changes in gut microbiota and enteric neuro-immune system alterations could contribute to gastrointesinal dysfunctions as well as initiation and upward spreading of the neurologic disorder. The present review has been intended to provide a comprehensive overview of the available knowledge on the role played by enteric microbiota, mucosal immune system and enteric nervous system, considered as an integrated network, in the pathophysiology of the main neurological diseases known to be associated with intestinal disturbances. In addition, based on current human and pre-clinical evidence, our intent was to critically discuss whether changes in the dynamic interplay between gut microbiota, intestinal epithelial barrier and enteric neuro-immune system are a consequence of the central neurodegeneration or might represent the starting point of the neurodegenerative process. Special attention has been paid also to discuss whether alterations of the enteric bacterial-neuro-immune network could represent a common path driving the onset of the main neurodegenerative diseases, even though each disease displays its own distinct clinical features.

Published

2018

15. Gut microbiota regulates maturation of the adult enteric nervous system via enteric serotonin networks.

Author

De Vadder F, Grasset E, Mannerås Holm L, Karsenty G, Macpherson AJ, Olofsson LE, and Bäckhed F

Subjects

Animals, Enteric Nervous System metabolism, Female, Gastrointestinal Motility physiology, Intestine, Small metabolism, Mice, Mice, Inbred C57BL, Microbiota physiology, Neurogenesis physiology, Neurons metabolism, Neurons microbiology, Receptors, Serotonin, 5-HT4 metabolism, Enteric Nervous System microbiology, Enteric Nervous System physiology, Gastrointestinal Microbiome physiology, Intestine, Small microbiology, Serotonin metabolism

Abstract

The enteric nervous system (ENS) is crucial for essential gastrointestinal physiologic functions such as motility, fluid secretion, and blood flow. The gut is colonized by trillions of bacteria that regulate host production of several signaling molecules including serotonin (5-HT) and other hormones and neurotransmitters. Approximately 90% of 5-HT originates from the intestine, and activation of the 5-HT 4 receptor in the ENS has been linked to adult neurogenesis and neuroprotection. Here, we tested the hypothesis that the gut microbiota could induce maturation of the adult ENS through release of 5-HT and activation of 5-HT 4 receptors. Colonization of germ-free mice with a microbiota from conventionally raised mice modified the neuroanatomy of the ENS and increased intestinal transit rates, which was associated with neuronal and mucosal 5-HT production and the proliferation of enteric neuronal progenitors in the adult intestine. Pharmacological modulation of the 5-HT 4 receptor, as well as depletion of endogenous 5-HT, identified a mechanistic link between the gut microbiota and maturation of the adult ENS through the release of 5-HT and activation of the 5-HT 4 receptor. Taken together, these findings show that the microbiota modulates the anatomy of the adult ENS in a 5-HT-dependent fashion with concomitant changes in intestinal transit., Competing Interests: Conflict of interest statement: F.B. is cofounder of and shareholder in Metabogen AB., (Copyright © 2018 the Author(s). Published by PNAS.)

Published

2018

16. Clostridium difficile-related postinfectious IBS: a case of enteroglial microbiological stalking and/or the solution of a conundrum?

Author

Bassotti G, Macchioni L, Corazzi L, Marconi P, and Fettucciari K

Subjects

Bacterial Proteins metabolism, Bacterial Toxins metabolism, Clostridioides difficile metabolism, Host-Pathogen Interactions, Humans, Intestinal Mucosa innervation, Intestinal Mucosa microbiology, Models, Theoretical, Neuroglia microbiology, Risk Factors, Clostridioides difficile physiology, Clostridium Infections microbiology, Enteric Nervous System microbiology, Irritable Bowel Syndrome microbiology

Abstract

Post-infectious irritable bowel syndrome is a well-defined pathological entity that develops in about one-third of subjects after an acute infection (bacterial, viral) or parasitic infestation. Only recently it has been documented that an high incidence of post-infectious irritable bowel syndrome occurs after Clostridium difficile infection. However, until now it is not known why in some patients recovered from this infection the gastrointestinal disturbances persist for months or years. Based on our in vitro studies on enteric glial cells exposed to the effects of C. difficile toxin B, we hypothesize that persistence of symptoms up to the development of irritable bowel syndrome might be due to a disturbance/impairment of the correct functions of the enteroglial intestinal network.

Published

2018

17. Regulation of glucagon-like peptide-1 sensitivity by gut microbiota dysbiosis.

Author

Yamane S and Inagaki N

Subjects

Animals, Enteric Nervous System metabolism, Enteric Nervous System microbiology, Humans, Nitric Oxide metabolism, Nitric Oxide Synthase Type I metabolism, Dysbiosis metabolism, Gastrointestinal Microbiome, Glucagon-Like Peptide 1 metabolism

Abstract

Gut microbiota dysbiosis reduces expression of GLP-1 receptor (GLP-1R) and neuronal nitric oxide synthase (nNOS) in the enteric nervous system and hampers GLP-1-induced nitric oxide (NO) production through a pattern recognition receptor (PRR)-dependent mechanism, hence preventing activation of the gut-brain-periphery axis for control of insulin secretion and gastric emptying., (© 2017 The Authors. Journal of Diabetes Investigation published by Asian Association for the Study of Diabetes (AASD) and John Wiley & Sons Australia, Ltd.)

Published

2018

18. The Gut and Parkinson's Disease: Hype or Hope?

Author

Scheperjans F, Derkinderen P, and Borghammer P

Subjects

Biomarkers, Brain metabolism, Enteric Nervous System metabolism, Humans, Parkinson Disease metabolism, alpha-Synuclein metabolism, Enteric Nervous System microbiology, Gastrointestinal Microbiome physiology, Parkinson Disease microbiology

Abstract

In the last two decades it has become clear that Parkinson's disease (PD) is associated with a plethora of gastrointestinal symptoms originating from functional and structural changes in the gut and its associated neural structures. This is of particular interest not only because such symptoms have a major impact on the quality of life of PD patients, but also since accumulating evidence suggests that in at least a subgroup of patients, these disturbances precede the motor symptoms and diagnosis of PD by years and may thus give important insights into the origin and pathogenesis of the disease. In this mini-review we attempt to concisely summarize the current knowledge after two decades of research on the gut-brain axis in PD. We focus on alpha-synuclein pathology, biomarkers, and the gut microbiota and envision the development and impact of these research areas for the two decades to come.

Published

2018

19. Saccharomyces boulardii CNCM I-745 supplementation reduces gastrointestinal dysfunction in an animal model of IBS.

Author

Brun P, Scarpa M, Marchiori C, Sarasin G, Caputi V, Porzionato A, Giron MC, Palù G, and Castagliuolo I

Subjects

Animals, Colon metabolism, Colon microbiology, Colon virology, Cytokines metabolism, Diarrhea metabolism, Diarrhea microbiology, Diarrhea virology, Disease Models, Animal, Enteric Nervous System metabolism, Enteric Nervous System microbiology, Enteric Nervous System virology, Herpes Simplex metabolism, Herpes Simplex microbiology, Herpes Simplex virology, Herpesvirus 1, Human pathogenicity, Ileum metabolism, Ileum microbiology, Ileum virology, Inflammation metabolism, Inflammation microbiology, Inflammation virology, Interleukin-10 metabolism, Interleukin-1beta metabolism, Interleukin-4 metabolism, Irritable Bowel Syndrome metabolism, Irritable Bowel Syndrome virology, Male, Mice, Mice, Inbred C57BL, Muscles metabolism, Muscles microbiology, Muscles virology, Myenteric Plexus metabolism, Myenteric Plexus microbiology, Myenteric Plexus virology, Tumor Necrosis Factor-alpha metabolism, Gastrointestinal Motility drug effects, Irritable Bowel Syndrome microbiology, Irritable Bowel Syndrome therapy, Probiotics pharmacology, Saccharomyces boulardii growth & development

Abstract

Background: We evaluated the effect of Saccharomyces boulardii CNCM I-745 on intestinal neuromuscular anomalies in an IBS-type mouse model of gastrointestinal motor dysfunctions elicited by Herpes Simplex Virus type 1 (HSV-1) exposure., Methods: Mice were inoculated intranasally with HSV-1 (102 PFU) or vehicle at time 0 and 4 weeks later by the intragastric (IG) route (108 PFU). Six weeks after IG inoculum, mice were randomly allocated to receive oral gavage with either S. boulardii (107 CFU/day) or vehicle. After 4 weeks the following were determined: a) intestinal motility using fluorescein-isothiocyanate dextran distribution in the gut, fecal pellet expulsion, stool water content, and distal colonic transit of glass beads; b) integrity of the enteric nervous system (ENS) by immunohistochemistry on ileal whole-mount preparations and western blot of protein lysates from ileal longitudinal muscle and myenteric plexus; c) isometric muscle tension with electric field and pharmacological (carbachol) stimulation of ileal segments; and d) intestinal inflammation by levels of tumor necrosis factor α, interleukin(IL)-1β, IL-10 and IL-4., Results: S. boulardii CNCM I-745 improved HSV-1 induced intestinal dysmotility and alteration of intestinal transit observed ten weeks after IG inoculum of the virus. Also, the probiotic yeast ameliorated the structural alterations of the ENS induced by HSV-1 (i.e., reduced peripherin immunoreactivity and expression, increased glial S100β protein immunoreactivity and neuronal nitric oxide synthase level, reduced substance P-positive fibers). Moreover, S. boulardii CNCM I-745 diminished the production of HSV-1 associated pro-inflammatory cytokines in the myenteric plexus and increased levels of anti-inflammatory interleukins., Conclusions: S. boulardii CNCM I-745 ameliorated gastrointestinal neuromuscular anomalies in a mouse model of gut dysfunctions typically observed with irritable bowel syndrome.

Published

2017

20. A Specific Gut Microbiota Dysbiosis of Type 2 Diabetic Mice Induces GLP-1 Resistance through an Enteric NO-Dependent and Gut-Brain Axis Mechanism.

Author

Grasset E, Puel A, Charpentier J, Collet X, Christensen JE, Tercé F, and Burcelin R

Subjects

Animals, Brain pathology, Diabetes Mellitus, Type 2 microbiology, Diabetes Mellitus, Type 2 pathology, Dysbiosis microbiology, Dysbiosis pathology, Enteric Nervous System microbiology, Enteric Nervous System pathology, Gastrointestinal Tract metabolism, Gastrointestinal Tract microbiology, Gastrointestinal Tract pathology, Glucagon-Like Peptide 1 metabolism, Glucagon-Like Peptide-1 Receptor metabolism, Male, Mice, Mice, Inbred C57BL, Brain metabolism, Diabetes Mellitus, Type 2 metabolism, Dysbiosis metabolism, Enteric Nervous System metabolism, Gastrointestinal Microbiome, Nitric Oxide metabolism

Abstract

Glucagon-like peptide-1 (GLP-1)-based therapies control glycemia in type 2 diabetic (T2D) patients. However, in some patients the treatment must be discontinued, defining a state of GLP-1 resistance. In animal models we identified a specific set of ileum bacteria impairing the GLP-1-activated gut-brain axis for the control of insulin secretion and gastric emptying. Using prediction algorithms, we identified bacterial pathways related to amino acid metabolism and transport system modules associated to GLP-1 resistance. The conventionalization of germ-free mice demonstrated their role in enteric neuron biology and the gut-brain-periphery axis. Altogether, insulin secretion and gastric emptying require functional GLP-1 receptor and neuronal nitric oxide synthase in the enteric nervous system within a eubiotic gut microbiota environment. Our data open a novel route to improve GLP-1-based therapies., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

21. XIVth Little Brain Big Brain: next-generation enteric neuroscience.

Author

Beyder A, de Lartigue G, Ghia JE, and Hoffman JM

Subjects

Brain physiopathology, Congresses as Topic, Enteric Nervous System embryology, Enteric Nervous System microbiology, Gastrointestinal Microbiome, Gastrointestinal Motility, Humans, Intestinal Diseases etiology, Intestinal Diseases physiopathology, Metabolic Diseases etiology, Metabolic Diseases physiopathology, Neurosciences, Enteric Nervous System physiopathology

Abstract

Little Brain Big Brain has been a biannual meeting organized and attended exclusively by young investigators in neurogastroenterology since 1989. The XIVth meeting featured cutting-edge work advancing several novel hypotheses in the main themes of motility, inflammation and metabolism.

Published

2017

22. The mucosal immune system: master regulator of bidirectional gut-brain communications.

Author

Powell N, Walker MM, and Talley NJ

Subjects

Adaptive Immunity, Brain physiology, Enteric Nervous System immunology, Enteric Nervous System microbiology, Enteric Nervous System physiology, Gastrointestinal Diseases microbiology, Gastrointestinal Diseases physiopathology, Gastrointestinal Diseases psychology, Gastrointestinal Microbiome physiology, Homeostasis physiology, Humans, Immunity, Innate, Intestinal Mucosa microbiology, Intestinal Mucosa physiology, Signal Transduction physiology, Stress, Psychological, Brain immunology, Gastrointestinal Diseases immunology, Intestinal Mucosa immunology

Abstract

Communication between the brain and gut is not one-way, but a bidirectional highway whereby reciprocal signals between the two organ systems are exchanged to coordinate function. The messengers of this complex dialogue include neural, metabolic, endocrine and immune mediators responsive to diverse environmental cues, including nutrients and components of the intestinal microbiota (microbiota-gut-brain axis). We are now starting to understand how perturbation of these systems affects transition between health and disease. The pathological repercussions of disordered gut-brain dialogue are probably especially pertinent in functional gastrointestinal diseases, including IBS and functional dyspepsia. New insights into these pathways might lead to novel treatment strategies in these common gastrointestinal diseases. In this Review, we consider the role of the immune system as the gatekeeper and master regulator of brain-gut and gut-brain communications. Although adaptive immunity (T cells in particular) participates in this process, there is an emerging role for cells of the innate immune compartment (including innate lymphoid cells and cells of the mononuclear phagocyte system). We will also consider how these key immune cells interact with the specific components of the enteric and central nervous systems, and rapidly respond to environmental variables, including the microbiota, to alter gut homeostasis.

Published

2017

23. The Effect of Microbiota and the Immune System on the Development and Organization of the Enteric Nervous System.

Author

Obata Y and Pachnis V

Subjects

Enteric Nervous System embryology, Enteric Nervous System physiology, Homeostasis physiology, Humans, Intestinal Mucosa embryology, Intestinal Mucosa immunology, Intestinal Mucosa microbiology, Intestinal Mucosa physiology, Parkinson Disease etiology, Enteric Nervous System immunology, Enteric Nervous System microbiology, Gastrointestinal Microbiome immunology, Gastrointestinal Microbiome physiology

Abstract

The gastrointestinal (GI) tract is essential for the absorption of nutrients, induction of mucosal and systemic immune responses, and maintenance of a healthy gut microbiota. Key aspects of gastrointestinal physiology are controlled by the enteric nervous system (ENS), which is composed of neurons and glial cells. The ENS is exposed to and interacts with the outer (microbiota, metabolites, and nutrients) and inner (immune cells and stromal cells) microenvironment of the gut. Although the cellular blueprint of the ENS is mostly in place by birth, the functional maturation of intestinal neural networks is completed within the microenvironment of the postnatal gut, under the influence of gut microbiota and the mucosal immune system. Recent studies have shown the importance of molecular interactions among microbiota, enteric neurons, and immune cells for GI homeostasis. In addition to its role in GI physiology, the ENS has been associated with the pathogenesis of neurodegenerative disorders, such as Parkinson's disease, raising the possibility that microbiota-ENS interactions could offer a viable strategy for influencing the course of brain diseases. Here, we discuss recent advances on the role of microbiota and the immune system on the development and homeostasis of the ENS, a key relay station along the gut-brain axis., (Copyright © 2016 AGA Institute. Published by Elsevier Inc. All rights reserved.)

Published

2016

24. Microbiota-gut-brain signalling in Parkinson's disease: Implications for non-motor symptoms.

Author

Felice VD, Quigley EM, Sullivan AM, O'Keeffe GW, and O'Mahony SM

Subjects

Animals, Enteric Nervous System metabolism, Enteric Nervous System microbiology, Gastrointestinal Tract metabolism, Gastrointestinal Tract microbiology, Humans, Mental Disorders metabolism, Mental Disorders microbiology, Mental Disorders psychology, Microbiota physiology, Parkinson Disease microbiology, Parkinson Disease psychology, Gastrointestinal Microbiome physiology, Parkinson Disease metabolism, Signal Transduction physiology

Abstract

Parkinson's disease is the second most common neurodegenerative disorder, affecting 1-2% of the population over 65 years of age. The primary neuropathology is the loss of midbrain dopaminergic neurons, resulting in characteristic motor deficits, upon which the clinical diagnosis is based. However, a number of significant non-motor symptoms (NMS) are also evident that appear to have a greater impact on the quality of life of these patients. In recent years, it has become increasingly apparent that neurobiological processes can be modified by the bi-directional communication that occurs along the brain-gut axis. The microbiota plays a key role in this communication throughout different routes in both physiological and pathological conditions. Thus, there has been an increasing interest in investigating how microbiota changes within the gastrointestinal tract may be implicated in health and disease including PD. Interestingly α-synuclein-aggregates, the cardinal neuropathological feature in PD, are present in both the submucosal and myenteric plexuses of the enteric nervous system, prior to their appearance in the brain, indicating a possible gut to brain route of "prion-like" spread. In this review we highlight the potential importance of gut to brain signalling in PD with particular focus on the role of the microbiota as major player in this communication., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016

25. T cells regulate intestinal motility and shape enteric neuronal responses to intestinal microbiota.

Author

Marques de Souza PR, Keenan CM, Wallace LE, Habibyan YB, Davoli-Ferreira M, Ohland C, Vicentini FA, McCoy KD, and Sharkey KA

Subjects

Animals, Mice, T-Lymphocytes immunology, Colon microbiology, Colon immunology, Neurogenesis, Neurons physiology, Neurons microbiology, Specific Pathogen-Free Organisms, Male, Interleukin-17 metabolism, Nestin metabolism, Nestin genetics, Germ-Free Life, Th17 Cells immunology, Bacteria classification, Gastrointestinal Microbiome, Enteric Nervous System physiology, Enteric Nervous System immunology, Enteric Nervous System microbiology, Gastrointestinal Motility physiology, Mice, Inbred C57BL, Ileum microbiology, Ileum immunology

Abstract

How the gut microbiota and immune system maintain intestinal homeostasis in concert with the enteric nervous system (ENS) remains incompletely understood. To address this gap, we assessed small intestinal transit, enteric neuronal density, enteric neurogenesis, intestinal microbiota, immune cell populations and cytokines in wildtype and T-cell deficient germ-free mice colonized with specific pathogen-free (SPF) microbiota, conventionally raised SPF and segmented filamentous bacteria (SFB)-monocolonized mice. SPF microbiota increased small intestinal transit in a T cell-dependent manner. SPF microbiota increased neuronal density in the myenteric and submucosal plexuses of the ileum and colon, similar to conventionally raised SPF mice, independently of T cells. SFB increased neuronal density in the ileum in a T cell-dependent manner, but independently of T cells in the colon. SPF microbiota stimulated enteric neurogenesis (Sox2 expression in enteric neurons) in the ileum in a T cell-dependent manner, but in the colon this effect was T cell-independent. T cells regulated nestin expression in the ENS. SPF colonization increased Th17 cells, RORγT + Treg cells, and IL-1β and IL-17A levels in the ileum and colon. By neutralizing IL-1β and IL-17A, we observed that they control microbiota-mediated enteric neurogenesis but were not involved in the regulation of motility. Together, these findings provide new insights into the microbiota-neuroimmune dialog that regulates intestinal physiology.

Published

2025

26. Current concepts in functional gastrointestinal disorders.

Author

Kovacic K

Subjects

Abdominal Pain etiology, Abdominal Pain microbiology, Enteric Nervous System microbiology, Feeding Behavior, Gastrointestinal Diseases microbiology, Gastrointestinal Motility, Gastrointestinal Tract microbiology, Humans, Abdominal Pain physiopathology, Cognitive Behavioral Therapy trends, Enteric Nervous System physiopathology, Gastrointestinal Diseases physiopathology, Gastrointestinal Tract innervation, Psychotropic Drugs therapeutic use

Abstract

Purpose of Review: Functional gastrointestinal disorders (FGIDs) are some of the most common and challenging disorders in pediatrics. Recurrent abdominal pain is the central feature of pain-associated FGIDs such as irritable bowel syndrome. A thorough understanding of current pathophysiological concepts is essential to successful management., Recent Findings: The brain-gut axis, role of microbiota and the biopsychosocial model are emerging concepts in FGIDs. The biopsychosocial model focuses on the interplay between genes, environment, and physical and psychosocial factors. Interactions between microbiota and the central, enteric and autonomic nervous systems form the link between gut functions and conscious perceptions. Irritable bowel syndrome is the most extensively studied and prototypical pain-associated FGIDs. An aberrant processing of pain or physiologic signals originating from the gut causes a state of visceral hypersensitivity - a central mechanism of functional pain. Psychosocial and autonomic influences also play large roles. Therapy is tailored to the individual patient and comorbid symptoms., Summary: This review highlights the complex mechanisms and the aberrant brain-gut neural connections forming the basis of FGIDs. Successful management of FGIDs requires knowledge of the underlying pathophysiology coupled with a multidisciplinary treatment approach. Management should focus on cognitive behavioral therapy, dietary factors along with gastrointestinal motility and psychotropic drug therapy.

Published

2015

27. Autoimmunity Links Vinculin to the Pathophysiology of Chronic Functional Bowel Changes Following Campylobacter jejuni Infection in a Rat Model.

Author

Pimentel M, Morales W, Pokkunuri V, Brikos C, Kim SM, Kim SE, Triantafyllou K, Weitsman S, Marsh Z, Marsh E, Chua KS, Srinivasan S, Barlow GM, and Chang C

Subjects

Animals, Campylobacter Infections microbiology, Campylobacter Infections physiopathology, Campylobacter jejuni pathogenicity, Cross Reactions, Disease Models, Animal, Enteric Nervous System immunology, Enteric Nervous System microbiology, Enteritis microbiology, Enteritis physiopathology, Ganglia immunology, Ganglia microbiology, Humans, Interstitial Cells of Cajal immunology, Interstitial Cells of Cajal microbiology, Intestine, Small innervation, Intestine, Small microbiology, Intestine, Small physiopathology, Mice, Phenotype, Rats, Antibodies, Bacterial immunology, Autoimmunity, Bacterial Toxins immunology, Campylobacter Infections immunology, Campylobacter jejuni immunology, Enteritis immunology, Intestine, Small immunology, Vinculin immunology

Abstract

Background: Acute gastroenteritis can precipitate irritable bowel syndrome (IBS) in humans. Cytolethal distending toxin is common to all pathogens causing gastroenteritis. Its active subunit, CdtB, is associated with post-infectious bowel changes in a rat model of Campylobacter jejuni infection, including small intestinal bacterial overgrowth (SIBO)., Aim: To evaluate the role of host antibodies to CdtB in contributing to post-infectious functional sequelae in this rat model., Methods: Ileal tissues from non-IBS human subjects, C. jejuni-infected and control rats were immunostained with antibodies to CdtB, c-Kit, S-100, PGP 9.5 and vinculin. Cytosolic and membrane proteins from mouse enteric neuronal cell lysates were immunoprecipitated with anti-CdtB and analyzed by mass spectrometry. ELISAs were performed on rat cardiac serum using CdtB or vinculin as antigens., Results: Anti-CdtB antibodies bound to a cytosolic protein in interstitial cells of Cajal (ICC) and myenteric ganglia in C. jejuni-infected and naïve rats and human subjects. Mass spectrometry identified vinculin, confirmed by co-localization and ELISAs. Anti-CdtB antibodies were higher in C. jejuni-infected rats (1.27 ± 0.15) than controls (1.76 ± 0.12) (P < 0.05), and rats that developed SIBO (2.01 ± 0.18) vs. rats that did not (1.44 ± 0.11) (P = 0.019). Vinculin expression levels were reduced in C. jejuni-infected rats (0.058 ± 0.053) versus controls (0.087 ± 0.023) (P = 0.0001), with greater reductions in rats with two C. jejuni infections (P = 0.0001) and rats that developed SIBO (P = 0.001)., Conclusions: Host anti-CdtB antibodies cross-react with vinculin in ICC and myenteric ganglia, required for normal gut motility. Circulating antibody levels and loss of vinculin expression correlate with number of C. jejuni exposures and SIBO, suggesting that effects on vinculin are important in the effects of C. jejuni infection on the host gut.

Published

2015

28. Actions of probiotics on trinitrobenzenesulfonic acid-induced colitis in rats.

Author

Shiina T, Shima T, Naitou K, Nakamori H, Sano Y, Horii K, Shimakawa M, Ohno H, and Shimizu Y

Subjects

Administration, Oral, Animals, Colitis chemically induced, Enteric Nervous System microbiology, Male, Rats, Rats, Wistar, Treatment Outcome, Trinitrobenzenesulfonic Acid, Colitis physiopathology, Colitis therapy, Enteric Nervous System physiopathology, Enterococcus faecalis, Gastrointestinal Motility, Probiotics administration & dosage

Abstract

We investigated the actions of probiotics, Streptococcus faecalis 129 BIO 3B (SF3B), in a trinitrobenzenesulfonic acid- (TNBS-) induced colitis model in rats. After TNBS was administered into the colons of rats for induction of colitis, the rats were divided into two groups: one group was given a control diet and the other group was given a diet containing SF3B for 14 days. There were no apparent differences in body weight, diarrhea period, macroscopic colitis score, and colonic weight/length ratio between the control group and SF3B group, suggesting that induction of colitis was not prevented by SF3B. Next, we investigated whether SF3B-containing diet intake affects the restoration of enteric neurotransmissions being damaged during induction of colitis by TNBS using isolated colonic preparations. Recovery of the nitrergic component was greater in the SF3B group than in the control group. A compensatory appearance of nontachykininergic and noncholinergic excitatory components was less in the SF3B group than in the control group. In conclusion, the present study suggests that SF3B-containing diet intake can partially prevent disruptions of enteric neurotransmissions induced after onset of TNBS-induced colitis, suggesting that SF3B has therapeutic potential.

Published

2015

29. Harnessing the antibacterial and immunological properties of mucosal-associated invariant T cells in the development of novel oral vaccines against enteric infections.

Author

Abautret-Daly AE, Davitt CJ, and Lavelle EC

Subjects

Adaptive Immunity drug effects, Administration, Oral, Animals, Anti-Bacterial Agents administration & dosage, Bacterial Vaccines administration & dosage, Enteric Nervous System microbiology, Humans, Intestinal Mucosa drug effects, Intestinal Mucosa microbiology, Adaptive Immunity immunology, Anti-Bacterial Agents immunology, Bacterial Vaccines immunology, Enteric Nervous System immunology, Intestinal Mucosa immunology, Natural Killer T-Cells immunology

Abstract

Enteric infections are a major cause of mortality and morbidity with significant social and economic implications worldwide and particularly in developing countries. An attractive approach to minimizing the impact of these diseases is via the development of oral vaccination strategies. However, oral vaccination is challenging due to the tolerogenic and hyporesponsive nature of antigen presenting cells resident in the gastrointestinal tract. The inclusion of adjuvants in oral vaccine formulations has the potential to overcome this challenge. To date no oral adjuvants have been licenced for human use and thus oral adjuvant discovery remains a key goal in improving the potential for oral vaccine development. Mucosal-associated invariant T (MAIT) cells are a recently discovered population of unconventional T cells characterized by an evolutionarily conserved αβ T cell receptor (TCR) that recognizes antigens presented by major histocompatibility complex (MHC) class I-related (MR1) molecule. MAIT cells are selected intra-thymically by MR1 expressing double positive thymocytes and enter the circulation with a naïve phenotype. In the circulation they develop a memory phenotype and are programmed to home to mucosal tissues and the liver. Once resident in these tissues, MAIT cells respond to bacterial and yeast infections through the production of chemokines and cytokines that aid in the induction of an adaptive immune response. Their abundance in the gastrointestinal tract and ability to promote adaptive immunity suggests that MAIT cell activators may represent attractive novel adjuvants for use in oral vaccination., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

30. Gut microbiota, the pharmabiotics they produce and host health.

Author

Patterson E, Cryan JF, Fitzgerald GF, Ross RP, Dinan TG, and Stanton C

Subjects

Animals, Disease Models, Animal, Enteric Nervous System microbiology, Humans, Immune System microbiology, Intestines microbiology, Linoleic Acids, Conjugated, Gastrointestinal Tract microbiology, Microbiota, Prebiotics, Probiotics administration & dosage

Abstract

A healthy gut microbiota plays many crucial functions in the host, being involved in the correct development and functioning of the immune system, assisting in the digestion of certain foods and in the production of health-beneficial bioactive metabolites or 'pharmabiotics'. These include bioactive lipids (including SCFA and conjugated linoleic acid) antimicrobials and exopolysaccharides in addition to nutrients, including vitamins B and K. Alterations in the composition of the gut microbiota and reductions in microbial diversity are highlighted in many disease states, possibly rendering the host susceptible to infection and consequently negatively affecting innate immune function. Evidence is also emerging of microbially produced molecules with neuroactive functions that can have influences across the brain-gut axis. For example, γ-aminobutyric acid, serotonin, catecholamines and acetylcholine may modulate neural signalling within the enteric nervous system, when released in the intestinal lumen and consequently signal brain function and behaviour. Dietary supplementation with probiotics and prebiotics are the most widely used dietary adjuncts to modulate the gut microbiota. Furthermore, evidence is emerging of the interactions between administered microbes and dietary substrates, leading to the production of pharmabiotics, which may directly or indirectly positively influence human health.

Published

2014

31. Brain-gut axis in the pathogenesis of Helicobacter pylori infection.

Author

Budzyński J and Kłopocka M

Subjects

Acute Disease, Animals, Appetite Regulation, Body Weight, Brain immunology, Chronic Disease, Cognition, Enteric Nervous System immunology, Feeding Behavior, Gastrointestinal Motility, Gastrointestinal Tract immunology, Helicobacter Infections immunology, Helicobacter Infections psychology, Helicobacter pylori immunology, Host-Pathogen Interactions, Humans, Mast Cells microbiology, Synaptic Transmission, Brain physiopathology, Enteric Nervous System microbiology, Enteric Nervous System physiopathology, Gastrointestinal Tract innervation, Gastrointestinal Tract microbiology, Helicobacter Infections microbiology, Helicobacter Infections physiopathology, Helicobacter pylori pathogenicity

Abstract

Helicobacter pylori (H. pylori) infection is the main pathogenic factor for upper digestive tract organic diseases. In addition to direct cytotoxic and proinflammatory effects, H. pylori infection may also induce abnormalities indirectly by affecting the brain-gut axis, similar to other microorganisms present in the alimentary tract. The brain-gut axis integrates the central, peripheral, enteric and autonomic nervous systems, as well as the endocrine and immunological systems, with gastrointestinal functions and environmental stimuli, including gastric and intestinal microbiota. The bidirectional relationship between H. pylori infection and the brain-gut axis influences both the contagion process and the host's neuroendocrine-immunological reaction to it, resulting in alterations in cognitive functions, food intake and appetite, immunological response, and modification of symptom sensitivity thresholds. Furthermore, disturbances in the upper and lower digestive tract permeability, motility and secretion can occur, mainly as a form of irritable bowel syndrome. Many of these abnormalities disappear following H. pylori eradication. H. pylori may have direct neurotoxic effects that lead to alteration of the brain-gut axis through the activation of neurogenic inflammatory processes, or by microelement deficiency secondary to functional and morphological changes in the digestive tract. In digestive tissue, H. pylori can alter signaling in the brain-gut axis by mast cells, the main brain-gut axis effector, as H. pylori infection is associated with decreased mast cell infiltration in the digestive tract. Nevertheless, unequivocal data concerning the direct and immediate effect of H. pylori infection on the brain-gut axis are still lacking. Therefore, further studies evaluating the clinical importance of these host-bacteria interactions will improve our understanding of H. pylori infection pathophysiology and suggest new therapeutic approaches.

Published

2014

32. Intestinal microbiota influence the early postnatal development of the enteric nervous system.

Author

Collins J, Borojevic R, Verdu EF, Huizinga JD, and Ratcliffe EM

Subjects

Animals, Animals, Newborn, Duodenum cytology, Duodenum microbiology, Enteric Nervous System cytology, Enteric Nervous System microbiology, Female, Ileum cytology, Ileum microbiology, Jejunum cytology, Jejunum microbiology, Mice, Pregnancy, Duodenum growth & development, Enteric Nervous System growth & development, Gastrointestinal Motility physiology, Ileum growth & development, Jejunum growth & development, Microbiota physiology

Abstract

Background: Normal gastrointestinal function depends on an intact and coordinated enteric nervous system (ENS). While the ENS is formed during fetal life, plasticity persists in the postnatal period during which the gastrointestinal tract is colonized by bacteria. We tested the hypothesis that colonization of the bowel by intestinal microbiota influences the postnatal development of the ENS., Methods: The development of the ENS was studied in whole mount preparations of duodenum, jejunum, and ileum of specific pathogen-free (SPF), germ-free (GF), and altered Schaedler flora (ASF) NIH Swiss mice at postnatal day 3 (P3). The frequency and amplitude of circular muscle contractions were measured in intestinal segments using spatiotemporal mapping of video recorded spontaneous contractile activity with and without exposure to lidocaine and N-nitro-L-arginine (NOLA)., Key Results: Immunolabeling with antibodies to PGP9.5 revealed significant abnormalities in the myenteric plexi of GF jejunum and ileum, but not duodenum, characterized by a decrease in nerve density, a decrease in the number of neurons per ganglion, and an increase in the proportion of myenteric nitrergic neurons. Frequency of amplitude of muscle contractions were significantly decreased in the jejunum and ileum of GF mice and were unaffected by exposure to lidocaine, while NOLA enhanced contractile frequency in the GF jejunum and ileum., Conclusions & Inferences: These findings suggest that early exposure to intestinal bacteria is essential for the postnatal development of the ENS in the mid to distal small intestine. Future studies are needed to investigate the mechanisms by which enteric microbiota interact with the developing ENS., (© 2013 John Wiley & Sons Ltd.)

Published

2014

33. Voices from within: gut microbes and the CNS.

Author

Forsythe P and Kunze WA

Subjects

Animals, Brain metabolism, Brain physiology, Central Nervous System growth & development, Germ-Free Life, Humans, Inflammation microbiology, Metagenome, Mice, Neuropeptides metabolism, Neuropeptides physiology, Signal Transduction, Stress, Physiological, Vagus Nerve metabolism, Vagus Nerve physiology, Central Nervous System microbiology, Enteric Nervous System microbiology, Intestines microbiology, Models, Biological

Abstract

Recent advances in research have greatly increased our understanding of the importance of the gut microbiota. Bacterial colonization of the intestine is critical to the normal development of many aspects of physiology such as the immune and endocrine systems. It is emerging that the influence of the gut microbiota also extends to modulation of host neural development. Furthermore, the overall balance in composition of the microbiota, together with the influence of pivotal species that induce specific responses, can modulate adult neural function, peripherally and centrally. Effects of commensal gut bacteria in adult animals include protection from the central effects of infection and inflammation as well as modulation of normal behavioral responses. There is now robust evidence that gut bacteria influence the enteric nervous system, an effect that may contribute to afferent signaling to the brain. The vagus nerve has also emerged as an important means of communicating signals from gut bacteria to the CNS. Further understanding of the mechanisms underlying microbiome-gut-brain communication will provide us with new insight into the symbiotic relationship between gut microbiota and their mammalian hosts and help us identify the potential for microbial-based therapeutic strategies to aid in the treatment of mood disorders.

Published

2013

34. Gut microbial products regulate murine gastrointestinal motility via Toll-like receptor 4 signaling.

Author

Anitha M, Vijay-Kumar M, Sitaraman SV, Gewirtz AT, and Srinivasan S

Subjects

Analysis of Variance, Animals, Anti-Bacterial Agents pharmacology, Apoptosis, Cell Survival drug effects, Cells, Cultured, Cholinergic Neurons physiology, Colon physiology, Defecation, Eating, Endotoxins blood, Enteric Nervous System microbiology, Feces microbiology, Female, Lipopolysaccharides blood, Lipopolysaccharides pharmacology, Male, Mice, Mice, Knockout, Models, Animal, Muscle Contraction, Muscle, Smooth physiology, Myeloid Differentiation Factor 88 genetics, Nitrergic Neurons microbiology, Nitrergic Neurons physiology, Phenotype, Signal Transduction, Toll-Like Receptor 4 genetics, Enteric Nervous System metabolism, Gastrointestinal Motility drug effects, Metagenome, Myeloid Differentiation Factor 88 metabolism, Nitrergic Neurons metabolism, Toll-Like Receptor 4 metabolism

Abstract

Background & Aims: Altered gastrointestinal motility is associated with significant morbidity and health care costs. Toll-like receptors (TLR) regulate intestinal homeostasis. We examined the roles of TLR4 signaling in survival of enteric neurons and gastrointestinal motility., Methods: We assessed changes in intestinal motility by assessing stool frequency, bead expulsion, and isometric muscle recordings of colonic longitudinal muscle strips from mice that do not express TLR4 (Tlr4(Lps-d) or TLR4(-/-)) or Myd88 (Myd88(-/-)), in wild-type germ-free mice or wild-type mice depleted of the microbiota, and in mice with neural crest-specific deletion of Myd88 (Wnt1Cre(+/-)/Myd88(fl/fl)). We studied the effects of the TLR4 agonist lipopolysaccharide (LPS) on survival of cultured, immortalized fetal enteric neurons and enteric neuronal cells isolated from wild-type and Tlr4(Lps-d) mice at embryonic day 13.5., Results: There was a significant delay in gastrointestinal motility and reduced numbers of nitrergic neurons in TLR4(Lps-d), TLR4(-/-), and Myd88(-/-) mice compared with wild-type mice. A similar phenotype was observed in germ-free mice, mice depleted of intestinal microbiota, and Wnt1Cre(+/-)/Myd88(fl/fl) mice. Incubation of enteric neuronal cells with LPS led to activation of the transcription factor nuclear factor (NF)-κB and increased cell survival., Conclusions: Interactions between enteric neurons and microbes increases neuron survival and gastrointestinal motility in mice. LPS activation of TLR4 and NF-κB appears to promote survival of enteric neurons. Factors that regulate TLR4 signaling in neurons might be developed to alter gastrointestinal motility., (Copyright © 2012 AGA Institute. Published by Elsevier Inc. All rights reserved.)

Published

2012

35. Unraveling mechanisms of action of probiotics.

Author

Sherman PM, Ossa JC, and Johnson-Henry K

Subjects

Animals, Enteric Nervous System microbiology, Epithelial Cells immunology, Epithelial Cells microbiology, Humans, Intestinal Mucosa immunology, Intestinal Mucosa microbiology, Gastrointestinal Tract immunology, Gastrointestinal Tract microbiology, Probiotics pharmacology

Abstract

Probiotics are defined as living organisms that, when administered in sufficient numbers, are of benefit to the host. Current evidence indicates that varying probiotic strains mediate their effects by a variety of different effects that are dependent on the dosage employed as well as the route and frequency of delivery. Some probiotics act in the lumen of the gut by elaborating antibacterial molecules such as bacteriocins; others enhance the mucosal barrier by increasing the production of innate immune molecules, including goblet cell-derived mucins and trefoil factors and defensins produced by intestinal Paneth cells; and other probiotics mediate their beneficial effects by promoting adaptive immune responses (secretory immune globulin A, regulatory T cells, interleukin-10). Some probiotics have the capacity to activate receptors in the enteric nervous system, which could be used to promote pain relief in the setting of visceral hyperalgesia. Future development of the effective use of probiotics in treating various gastroenterological disorders in human participants should take advantage of this new knowledge. The creation of novel formulations of probiotics could be directed to effectively target certain mechanisms of actions that are altered in specific disease states.

Published

2009

36. Evidence for neuromodulation of enteropathogen invasion in the intestinal mucosa.

Author

Schreiber KL, Price LD, and Brown DR

Subjects

Animals, Anti-Bacterial Agents pharmacology, Drug Resistance, Bacterial, Enteric Nervous System drug effects, Enteric Nervous System immunology, Enteropathogenic Escherichia coli drug effects, Enteropathogenic Escherichia coli immunology, Female, Ileum immunology, Ileum metabolism, Ileum microbiology, Intestinal Mucosa drug effects, Intestinal Mucosa immunology, Intestinal Mucosa metabolism, Male, Neuroimmunomodulation drug effects, Neurotransmitter Agents pharmacology, Neurotransmitter Agents physiology, Salmonella Infections, Animal drug therapy, Salmonella Infections, Animal immunology, Salmonella Infections, Animal microbiology, Swine, Enteric Nervous System microbiology, Intestinal Mucosa microbiology, Neuroimmunomodulation immunology, Salmonella enterica pathogenicity

Abstract

The extensively innervated intestinal mucosa encompasses a vast surface exposed to an array of potentially infectious microorganisms. We investigated the role of enteric nerves in modulating intracellular internalization of a multidrug-resistant Salmonella typhimurium DT104 field isolate in mucosa-submucosa sheets from the porcine ileum, a biomedical model for the human intestine. The effects of transmural electrical stimulation and drugs on intracellular internalization of Salmonella over 90 min was determined by a gentamicin-resistance assay relative to untreated tissues from the same animal serving as controls. The actin inhibitor cytochalasin D reduced internalization of Salmonella, and the mucus-disrupting agent dithiothreitol decreased its mucosal adherence. Transmural electrical stimulation increased, and neuronal conduction blockers saxitoxin and lidocaine decreased Salmonella internalization in stimulated and unstimulated tissues. Furthermore, the alpha-adrenergic/imidazoline receptor ligand phentolamine and the 5-HT(3) receptor antagonist tropisetron decreased internalization in stimulated tissues. Based on these findings, enteric neural activity appears to modulate interactions between the intestinal mucosa and pathogenic bacteria.

Published

2007

37. Effects of bacteria on the enteric nervous system: implications for the irritable bowel syndrome.

Author

Wood JD

Subjects

Animals, Bacterial Infections immunology, Bacterial Infections pathology, Bacterial Infections physiopathology, Colitis, Ulcerative microbiology, Colonic Neoplasms microbiology, Enteric Nervous System immunology, Enteric Nervous System pathology, Enteric Nervous System physiopathology, Humans, Immunity, Mucosal, Intestinal Mucosa innervation, Intestinal Mucosa microbiology, Intestinal Mucosa pathology, Irritable Bowel Syndrome immunology, Irritable Bowel Syndrome pathology, Irritable Bowel Syndrome physiopathology, Mast Cells, Pain Threshold, Signal Transduction, Stress, Psychological complications, Stress, Psychological physiopathology, Bacterial Infections microbiology, Enteric Nervous System microbiology, Irritable Bowel Syndrome microbiology

Abstract

A unified scenario emerges when it is considered that a major impact of stress on the intestinal tract is reflected by symptoms reminiscent of the diarrhea-predominant form of irritable bowel syndrome. Cramping abdominal pain, fecal urgency, and explosive watery diarrhea are hallmarks not only of diarrhea-predominant irritable bowel syndrome, but also of infectious enteritis, radiation-induced enteritis, and food allergy. The scenario starts with stress-induced compromise of the intestinal mucosal barrier and continues with microorganisms or other sensitizing agents crossing the barrier and being intercepted by enteric mast cells. Mast cells signal the presence of the agent to the enteric nervous system (ie, the brain-in-the-gut), which uses one of the specialized programs from its library of programs to remove the "threat." This is accomplished by stimulating mucosal secretion, which flushes the threatening agent into the lumen and maintains it in suspension. The secretory response then becomes linked to powerful propulsive motility, which propels the secretions together with the offending agent rapidly in the anal direction. Cramping abdominal pain accompanies the strong propulsive contractions. Urgency is experienced when arrival of the large bolus of liquid distends the recto-sigmoid region and reflexly opens the internal anal sphincter, with continence protection now provided only by central reflexes that contract the puborectalis and external anal sphincter muscles. Sensory information arriving in the brain from receptors in the rapidly distending recto-sigmoid accounts for the conscious sensation of urgency and might exacerbate the individual's emotional stress. The symptom of explosive watery diarrhea becomes self-explanatory in this scenario.

Published

2007

38. Intestinal epithelial cell signalling and host-derived negative regulators under chronic inflammation: to be or not to be activated determines the balance towards commensal bacteria.

Author

Haller D

Subjects

Animals, Chronic Disease, Enteric Nervous System immunology, Enteric Nervous System microbiology, Enteric Nervous System physiology, Epithelial Cells microbiology, Humans, Intestines pathology, Models, Immunological, Receptor Cross-Talk immunology, Receptors, Pattern Recognition immunology, Signal Transduction physiology, Enterobacteriaceae immunology, Epithelial Cells immunology, Inflammation, Intestines immunology, Intestines microbiology

Abstract

Advancing knowledge regarding the cellular mechanisms of intestinal inflammation has led to a better understanding of the disease pathology in patients with chronic disorders of the gut including inflammatory bowel disease, coeliac disease, lymphocytic colitis and irritable bowel syndrome. An emerging new paradigm suggests that changes in the homeostasis of bacteria- and host-derived signal transduction at the epithelial cell level may lead to functional and immune disturbances of the intestinal epithelium. It has become clear from numerous studies that enteric bacteria are a critical component in the development and prevention/treatment of chronic intestinal inflammation. Signal-specific activation of mitogen-activated protein kinases (MAPK), interferon-regulated factors (IRF) and the transcription factor NF-kappaB through pattern recognition receptor signalling effectively induce inflammatory defence mechanisms. Unbalanced activation of these innate signalling pathways because of host genetic predispositions and/or the lack of adequate anti-inflammatory feedback mechanisms may turn a physiological response into a pathological situation including failure of bacterial clearance and development of chronic inflammation. Host-derived regulators from the immune and enteric nerve system crosstalk to the innate signalling network of the intestinal epithelium in order to shape the extent and duration of inflammatory processes.

Published

2006

39. Immune-mediated neural dysfunction in a murine model of chronic Helicobacter pylori infection.

Author

Bercík P, De Giorgio R, Blennerhassett P, Verdú EF, Barbara G, and Collins SM

Subjects

Acetylcholine metabolism, Animals, Calcitonin Gene-Related Peptide analysis, Disease Models, Animal, Enteric Nervous System chemistry, Enteric Nervous System metabolism, Enteric Nervous System microbiology, Female, Gastritis pathology, Helicobacter Infections pathology, Immunohistochemistry, Macrophages immunology, Mice, Mice, Inbred BALB C, Mice, SCID, Muscle Contraction physiology, Specific Pathogen-Free Organisms, Spinal Cord chemistry, Stomach pathology, Substance P analysis, Vasoactive Intestinal Peptide analysis, Gastritis immunology, Helicobacter Infections immunology, Helicobacter pylori, Stomach innervation, Stomach physiopathology

Abstract

Background & Aims: Neuromuscular changes producing dysmotility and hyperalgesia may underlie symptom generation in functional gastrointestinal disorders. We investigated whether chronic Helicobacter pylori-induced gastritis causes neuromuscular dysfunction., Methods: In vitro muscle contractility and acetylcholine release were evaluated in mice before and after H. pylori eradication. H. pylori colonization and gastritis were graded histologically. Substance P (SP)-, vasoactive intestinal polypeptide (VIP)-, and calcitonin gene-related peptide (CGRP) immunoreactivity (IR) and macrophages were studied by immunohistochemistry., Results: In Balb/c mice, chronic H. pylori infection did not affect muscle function but augmented antral relaxation after nerve electric field stimulation. Infected mice had lower acetylcholine release by electric field stimulation and had higher density of SP-, CGRP-, and VIP-IR nerves in the stomach and of SP- and CGRP-IR in the spinal cord. Cholinergic nerve dysfunction worsened progressively and was associated with increasing macrophage and mononuclear but not polymorphonuclear infiltrate or bacterial colonization. SCID mice had unchanged acetylcholine release despite high H. pylori colonization and macrophage infiltration. Eradication of H. pylori normalized functional and morphologic abnormalities except for increased density of gastric SP- and CGRP-IR nerves., Conclusions: H. pylori infection induces functional and morphologic changes in the gastric neural circuitry that are progressive and lymphocyte dependent, and some persist after H. pylori eradication. The data have direct implications regarding the role of H. pylori infection in functional dyspepsia.

Published

2002

40. Extrinsic surgical denervation inhibits Clostridium difficile toxin A-induced enteritis in rats.

Author

Mantyh CR, McVey DC, and Vigna SR

Subjects

Animals, Enteric Nervous System microbiology, Enteric Nervous System surgery, Enterocolitis, Pseudomembranous chemically induced, Enterocolitis, Pseudomembranous prevention & control, Ileum enzymology, Ileum innervation, Ileum microbiology, Peroxidase metabolism, Rats, Rats, Sprague-Dawley, Substance P metabolism, Autonomic Denervation, Bacterial Toxins pharmacology, Clostridioides difficile, Enterocolitis, Pseudomembranous surgery, Enterotoxins pharmacology

Abstract

Clostridium difficile enteritis is caused by toxin A (TA) which stimulates substance P release and subsequent receptor activation. This receptor stimulation results in secretion, inflammation, and structural damage. However, it is unclear as to which subset of neurons is required to initiate substance P release following toxin stimulation. Five centimeter ileal segments were surgically denervated. After 10 days, three ileal loops were constructed in each rat: the denervated loop was injected intraluminally with 5 microg of TA and two intact loops were injected with TA or vehicle, respectively. Ileal secretion, myeloperoxidase activity, and histology were then assessed. Denervated ileal loops injected with TA had a 75% reduction in ileal secretion (P < 0.001), 92% reduction in myeloperoxidase activity (P < 0.01) and 96% reduction in histologic damage (P < 0.001) compared to innervated loops. There were no significant differences between the denervated loops injected with TA and those injected with vehicle. Extrinsic surgical denervation results in protection of ileal loops from TA enteritis. Furthermore, these results exclude the participation of intrinsic enteric nerves in TA-induced ileal damage. Finally, this suggests that extrinsic primary sensory neurons mediate the effects of intraluminal TA in the ileum.

Published

2000