Social interaction-induced activation of RNA splicing in the amygdala of microbiome-deficient mice

Stilling, Roman M.; Moloney, Gerard M.; Ryan, Feargal J.; Hoban, Alan E.; Bastiaanssen, Thomaz F.S.; Shanahan, Fergus; Clarke, Gerard; Claesson, Marcus J.; Dinan, Timothy G.; Cryan, John F.

doi:10.7554/elife.33070

Cited by 75 publications

(67 citation statements)

References 90 publications

(136 reference statements)

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“…Moreover, social stimulus evoked an increase in transcripts of genes involved in neuronal activity, which includes induction of several well established immediate early genes such as Fos or Arc, the MAP-K pathway and neurotrophic signalling via Bdnf. Moreover, we find upregulation of complement components, which have lately been established to be necessary for synaptic rearrangements and plasticity upon neuronal activity [6].…”

mentioning

confidence: 67%

“…Transcriptomic analysis demonstrated an upregulation of several immediate early response genes such as Fos, Fosb, Egr2 or Nr4a1 in association with increased CREB signalling in GF mice (see [5] for full details). Moreover, when a germ-free mouse is introduced to a social stimulus the normal transcriptional pathway recruitment is absent but instead genes involved in alternative splicing are enriched (see [6] for full details of genes affected)…”

Section: Novel Models Of Drug Relapse and Craving After Voluntary Absmentioning

confidence: 99%

“…However, GF mice displayed a strikingly different pattern of amygdala gene activity in response to social interaction [6] (Fig. 1).…”

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confidence: 99%

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Decoding the role of the microbiome on amygdala function and social behaviour

Cryan

Dinan

2018

Neuropsychopharmacol

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confidence: 67%

Section: Novel Models Of Drug Relapse and Craving After Voluntary Absmentioning

confidence: 99%

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Decoding the role of the microbiome on amygdala function and social behaviour

Cryan

Dinan

2018

Neuropsychopharmacol

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“…Perhaps the strongest evidence for microbial modulation of cognition and behavior in animal models comes from studies of social interactions (Sherwin et al, 2019). Germ-free rodents typically exhibit deficits in both sociability and memory for social stimuli (indexed by preference for a novel social partner; Buffington et al, 2016;Desbonnet et al, 2014;Sgritta et al, 2019;Stilling et al, 2018; but see also Arentsen et al, 2015). Similar effects are observed following antibiotic depletion of the microbiota during development (Degroote et al, 2016;Desbonnet et al, 2015), while administration of certain probiotic species can enhance social behavior in various murine models of autism (Buffington et al, 2016;Hsiao et al, 2013;Sgritta et al, 2019) and inflammation-induced social withdrawal (D'Mello et al, 2015).…”

Section: Behavioral and Cognitive Developmentmentioning

confidence: 99%

Annual Research Review: Critical windows – the microbiota–gut–brain axis in neurocognitive development

Cowan

Dinan

Cryan

2019

Child Psychology Psychiatry

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107

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The gut microbiota is a vast, complex, and fascinating ecosystem of microorganisms that resides in the human gastrointestinal tract. As an integral part of the microbiota–gut–brain axis, it is now being recognized that the microbiota is a modulator of brain and behavior, across species. Intriguingly, periods of change in the microbiota coincide with the development of other body systems and particularly the brain. We hypothesize that these times of parallel development are biologically relevant, corresponding to ‘sensitive periods’ or ‘critical windows’ in the development of the microbiota–gut–brain axis. Specifically, signals from the microbiota during these periods are hypothesized to be crucial for establishing appropriate communication along the axis throughout the life span. In other words, the microbiota is hypothesized to act like an expected input to calibrate the development of the microbiota–gut–brain axis. The absence or disruption of the microbiota during specific developmental windows would therefore be expected to have a disproportionate effect on specific functions or potentially for regulation of the system as a whole. Evidence for microbial modulation of neurocognitive development and neurodevelopmental risk is discussed in light of this hypothesis, finishing with a focus on the challenges that lay ahead for the future study of the microbiota–gut–brain axis during development.

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“…Early studies showed that germ-free mice (i.e. mice that are raised completely sterile with no internal or external microbiome) have marked deficits in social behaviors and in gene expression profiles in multiple brain regions related to regulation of these behaviors [12][13][14] . Additionally, mice who have had their microbiomes depleted with antibiotics show deficits in social behavior, cognitive flexibility, and multiple other ASD-like behaviors 6,15,16 .…”

Section: Introductionmentioning

confidence: 99%

Acetate supplementation rescues social deficits and alters transcriptional regulation in prefrontal cortex of Shank3 deficient mice

Osman

Mervosh

Strat

et al. 2020

Preprint

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Autism spectrum disorder (ASD) is a serious neurodevelopmental disorder with a very high prevalence rate and a chronic disease course beginning in early childhood. Despite the tremendous burden of ASD, there are currently no disease-modifying treatments. Like many neuropsychiatric illnesses ASD has a complex pathophysiology driven by genetic and environmental factors. There is interest in identifying modifiable environmental factors as potential translational research strategies for development of therapeutics for ASD. A rapidly growing body of research demonstrates that the resident bacteria of the gastrointestinal tract, collectively the gut microbiome, have profound influence on brain and behavior. This gut-brain signaling pathway is highly relevant to ASD as the microbiome begins to form at birth, is heavily influenced by environmental factors throughout early life, and begins to stabilize at the same stage of development that symptoms of ASD begin to develop. To investigate potential gene x microbiome interactions in a model of ASD, we utilized mutant mice carrying a deletion of the ASD-associated Shank3 gene (Shank3 KO ), which clinically manifests as Phelan-McDermid syndrome, as a model for genetic risk of ASD. Analysis of the gut microbiome of Shank3 KO mice demonstrated genotype effects on both microbiome composition and metabolite production. Behaviorally, Shank3 KO mice demonstrate decreased social interactions and have altered anxiety and compulsive-like behaviors. Disruption of the microbiome with broad spectrum antibiotics lead to an exacerbation of all behavioral phenotypes in Shank3 KO mice. Additionally, we found that Shank3 KO mice had markedly increased changes in gene expression in the prefrontal cortex following microbiome depletion. Taken together, our results suggest a gene x microbiome interaction in this mouse model for ASD and raise the possibility that targeting the microbiome may be a valid translational research strategy in developing therapeutics for ASD.

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Social interaction-induced activation of RNA splicing in the amygdala of microbiome-deficient mice

Cited by 75 publications

References 90 publications

Decoding the role of the microbiome on amygdala function and social behaviour

Decoding the role of the microbiome on amygdala function and social behaviour

Annual Research Review: Critical windows – the microbiota–gut–brain axis in neurocognitive development

Acetate supplementation rescues social deficits and alters transcriptional regulation in prefrontal cortex of Shank3 deficient mice

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