Enteropathogenic Escherichia coli Inhibits Type I Interferon- and RNase L-Mediated Host Defense To Disrupt Intestinal Epithelial Cell Barrier Function

Long, Tiha M.; Nisa, Shahista; Donnenberg, Michael S.; Hassel, Bret A.

doi:10.1128/iai.00105-14

Cited by 31 publications

(30 citation statements)

References 102 publications

(143 reference statements)

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“…While we show clearly that the production of IFN-β in vivo rapidly accelerates the spread of S T infection to secondary sites (Figure 1B), this is clearly not the case for all pathogenic bacteria (19, 38) nor even all Gram negative bacteria. Indeed, Y. entercolitica , which shares a common oral route of infection with S T, is suppressed by TRIF-dependent IFN production (57).…”

Section: Discussionmentioning

confidence: 71%

Salmonella Typhimurium Co-Opts the Host Type I IFN System To Restrict Macrophage Innate Immune Transcriptional Responses Selectively

Perkins

Rajesh

Tennant

et al. 2015

The Journal of Immunology

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Innate immune inflammatory responses are subject to complex layers of negative regulation at intestinal mucosal surfaces. While the type I interferon (IFN) system is critical for amplifying anti-viral immunity, it has been shown to play a homeostatic role in some models of autoimmune inflammation. Type I IFN is triggered in the gut by select bacterial pathogens, but whether and how the type I IFN might regulate innate immunity in the intestinal environment has not been investigated in the context of Salmonella enterica serovar Typhimurium (ST). ST infection of human or murine macrophages reveals that IFN-β selectively restricts the transcriptional responses mediated by both the Toll-Like Receptors (TLRs) and the NOD-Like Receptors (NLRs). Specifically, IFN-β potently represses ST-dependent innate induction of IL-1 family cytokines and neutrophil chemokines. This IFN-β-mediated transcriptional repression was independent of the effects of IFN-β on ST-induced macrophage cell death, but significantly dependent on IL-10 regulation. We further evaluated ST pathogenesis in vivo following oral inoculation of mice lacking IFN-β. We show that IFN-β−/− mice exhibit greater resistance to oral ST infection and a slower spread of ST to distal sterile sites. This work provides mechanistic insight into the relationship between ST and type I IFN, and demonstrates an additional mechanism by which IFN-β may promote spread of enteric pathogens.

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Section: Discussionmentioning

confidence: 71%

Salmonella Typhimurium Co-Opts the Host Type I IFN System To Restrict Macrophage Innate Immune Transcriptional Responses Selectively

Perkins

Rajesh

Tennant

et al. 2015

The Journal of Immunology

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“…The arrangement and density of these proteins determines the permeability of the epithelial barrier and act to confine local tissue infections (LeMessurier et al, 2013; Long et al, 2014). Type I IFNs, augmented by RNase-L, an ISG that mediates induction of type I IFNS, promote the expression of tight junction proteins (LeMessurier et al, 2013).…”

Section: Disparate Effector Mechanisms Of Type I Ifnsmentioning

confidence: 99%

The Roles of Type I Interferon in Bacterial Infection

Boxx

Cheng

2016

Cell Host & Microbe

284

247

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Type I interferons (IFNs) are pleiotropic cytokines well recognized for their role in the induction of a potent anti-viral gene program essential for host defense against viruses. They also modulate innate and adaptive immune responses. However, the role of type I IFNs in host defense against bacterial infections is enigmatic. Depending on the bacterium, they exert seemingly opposite and capricious functions. In this review we summarize the effect of type I IFNs on specific bacterial infections and highlight the effector mechanisms regulated by type I IFNs in an attempt to elucidate new avenues to understanding their role.

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“…The “leaky gut theory” postulates that an exceptionally increased permeability of the intestinal mucosa barrier represents a fundamental mechanism underlying autistic pathology (de Magistris et al, ; D'Eufemia et al, ; Horvath & Perman, ; Panksepp, ; Wakefield et al, ). Studies on subgroups of ASD subjects have revealed that this deficiency is partly contributed by (a) alterations in microbial composition, with an overrepresentation of bacterium Akkermansia muciniphila , known to degrade the mucus lining (Wang et al, ), (b) prevalence of Clostridia and reduced abundance of Bifidobacteria , increasing pro‐inflammatory cytokines production, which aggravates mucosa permeability (Heberling, Dhurjati, & Sasser, ), (c) elevated plasma levels of zonulin, a protein that regulates permeability (Esnafoglu et al, ), (d) decreased amounts of tight junction proteins at the intestinal barrier (Fiorentino et al, ), potentially due to increased toxins from Clostridia (Hecht, Pothoulakis, LaMont, & Madara, ), (e) infection by Escherichia coli , which leads to transformation of actin and tight junction structures (Long, Nisa, Donnenberg, & Hassel, ), (f) abundance of Candida fungi, which expresses root‐like formations that invade the intestinal wall (de Magistris et al, ), and (g) increased levels of claudin, a molecule that contributes to pores formation (Fiorentino et al, ). Individuals with both autistic and gastrointestinal disorders exhibit a distinct cytokine (Ashwood & Wakefield, ; Torrente et al, ) and regulatory (Ashwood, Anthony, Torrente, & Wakefield, ) profile.…”

Section: The Gut and Immuno‐inflammationmentioning

confidence: 99%

A systematic review of gut‐immune‐brain mechanisms in Autism Spectrum Disorder

Azhari

Azizan

Esposito

2018

Developmental Psychobiology

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Despite decades of research, the etiological origins of Autism Spectrum Disorder (ASD) remain elusive. Recently, the mechanisms of ASD have encompassed emerging theories involving the gastrointestinal, immune, and nervous systems. While each of these perspectives presents its own set of supporting evidence, the field requires an integration of these modular concepts and an overarching view of how these subsystems intersect. In this systematic review, we have synthesized relevant evidences from the existing literature, evaluating them in an interdependent manner and in doing so, outlining their possible connections. Specifically, we first discussed gastrointestinal and immuno‐inflammation pathways in‐depth, exploring the relationships between microbial composition, bacterial metabolites, gut mucosa, and immune system constituents. Accounting for temporal differences in the mechanisms involved in neurodevelopment, prenatal and postnatal phases were further elucidated, where the former focused on maternal immune activation (MIA) and fetal development, while the latter addressed the role of immune dysregulation in contributing to atypical neurodevelopment. As autism remains, foremost, a neurodevelopmental disorder, this review presents an integration of disparate modules into a “Gut‐Immune‐Brain” paradigm. Existing gaps in the literature have been highlighted, and possible avenues for future research with an integrated physiological perspective underlying ASD have also been suggested.

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Enteropathogenic Escherichia coli Inhibits Type I Interferon- and RNase L-Mediated Host Defense To Disrupt Intestinal Epithelial Cell Barrier Function

Cited by 31 publications

References 102 publications

Salmonella Typhimurium Co-Opts the Host Type I IFN System To Restrict Macrophage Innate Immune Transcriptional Responses Selectively

Salmonella Typhimurium Co-Opts the Host Type I IFN System To Restrict Macrophage Innate Immune Transcriptional Responses Selectively

The Roles of Type I Interferon in Bacterial Infection

A systematic review of gut‐immune‐brain mechanisms in Autism Spectrum Disorder

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