Multicellular organisms have co-evolved with complex consortia of viruses, bacteria, fungi and parasites, collectively referred to as the microbiota. In mammals, changes in the composition of the microbiota can influence a wide range of physiologic processes (including development, metabolism, and immune cell function) and are associated with susceptibility to multiple diseases. Alterations in the microbiota can also modulate host behaviors such as social activity, stress, and anxiety-related responses that are linked to diverse neuropsychiatric disorders. However, the mechanisms through which the microbiota influence neuronal activity and host behavior remain poorly defined. Here we demonstrate that manipulation of the microbiota in either antibiotictreated or germ-free adult mice results in significant deficits in fear extinction learning. Single nucleus RNA-sequencing of the medial prefrontal cortex of the brain revealed significant alterations in gene expression in multiple cell types including excitatory neurons and glial cells. Transcranial two-photon imaging following deliberate manipulation of the microbiota demonstrated that extinction learning deficits were associated with defective learning-related remodeling of postsynaptic dendritic spines and reduced activity in cue-encoding neurons in the medial prefrontal cortex. In addition to effects of manipulating the microbiota on behavior in adult mice, selective re-establishment of the microbiota revealed a limited neonatal developmental window in which microbiota-derived signals can restore normal extinction learning in adulthood. Lastly, unbiased metabolomic analysis identified four metabolites that were significantly downregulated in germ-free mice and were previous reported to be related to human and mouse models of neuropsychiatric disorders, suggesting that microbiota-derived compounds may directly affect brain function and behavior. Together, these data indicate that fear extinction learning requires microbiota-derived signals during both early postnatal neurodevelopment and in adult mice, with implications for our understanding of how diet, infection, and lifestyle influence brain health and subsequent susceptibility to neuropsychiatric disorders.
Interleukin (IL)-2 is a pleiotropic cytokine that is necessary to prevent chronic inflammation in the gastrointestinal tract 1 – 4 . The protective effects of IL-2 involve the generation, maintenance and function of regulatory T cells (Tregs) 4 – 8 , and low-dose IL-2 has emerged as a potential therapeutic strategy in inflammatory bowel disease (IBD) patients 9 . However, the cellular and molecular pathways that control the production of IL-2 in the context of intestinal health are undefined. Here we identify that IL-2 is acutely required to maintain Tregs and immunologic homeostasis throughout the gastrointestinal tract. Strikingly, lineage-specific deletion of IL-2 in T cells did not recapitulate these phenotypes in the small intestine. Unbiased analyses revealed that group 3 innate lymphoid cells (ILC3) are the dominant cellular source of IL-2 in the small intestine, which is selectively induced by IL-1β. Macrophages produce IL-1β in the small intestine and activation of this pathway involves MyD88- and Nod2-dependent sensing of the microbiota. Loss-of-function studies defined that ILC3-derived IL-2 is essential to maintain Tregs, immunologic homeostasis and oral tolerance to dietary antigens uniquely in the small intestine. Furthermore, ILC3 production of IL-2 was significantly reduced in the small intestine of Crohn’s disease patients, and this correlated with diminished Tregs. Collectively, these results reveal a previously unappreciated pathway whereby a microbiota- and IL-1β-dependent axis promotes ILC3 production of IL-2 to orchestrate immune regulation in the intestine.
The ability of the nervous system to sense environmental stimuli and to relay these signals to immune cells via neurotransmitters and neuropeptides is indispensable for effective immunity and tissue homeostasis. Depending on the tissue microenvironment and distinct drivers of a certain immune response, the same neuronal populations and neuro-mediators can exert opposing effects, promoting or inhibiting tissue immunity. Here, we review the current understanding of the mechanisms that underlie the complex interactions between the immune and the nervous systems in different tissues and contexts. We outline current gaps in knowledge and argue for the importance of considering infectious and inflammatory disease within a conceptual framework that integrates neuro-immune circuits both local and systemic, so as to better understand effective immunity to develop improved approaches to treat inflammation and disease.
SUMMARYThe intestinal tract is constantly exposed to various stimuli. Group 3 innate lymphoid cells (ILC3s) reside in lymphoid organs and in the intestinal tract and are required for immunity to enteric bacterial infection. However, the mechanisms that regulate the ILC3s in vivo remain incompletely defined. Here, we show that GPR183, a chemotactic receptor expressed on murine and human ILC3s, regulates ILC3 migration toward its ligand 7α,25-dihydroxycholesterol (7α,25-OHC) in vitro, and GPR183 deficiency in vivo leads to a disorganized distribution of ILC3s in mesenteric lymph nodes and decreased ILC3 accumulation in the intestine. GPR183 functions intrinsically in ILC3s, and GPR183-deficient mice are more susceptible to enteric bacterial infection. Together, thes1e results reveal a role for the GPR183-7α,25-OHC pathway in regulating the accumulation, distribution, and anti-microbial and tissue-protective functions of ILC3s and define a critical role for this pathway in promoting innate immunity to enteric bacterial infection.
Group 3 innate lymphoid cells (ILC3s) critically orchestrate host-microbe interactions in the healthy mammalian intestine and become substantially impaired in the context of inflammatory bowel disease (IBD). However, the molecular pathways controlling the homeostasis of ILC3s remain incompletely defined. Here, we identify that intestinal ILC3s are highly enriched in expression of genes involved in the circadian clock and exhibit diurnal oscillations of these pathways in response to light cues. Classical ILC3 effector functions also exhibited diurnal oscillations, and lineage-specific deletion of BMAL1, a master regulator of the circadian clock, resulted in markedly reduced ILC3s selectively in the intestine. BMAL1-deficient ILC3s exhibit impaired expression of Nr1d1 and Per3, hyperactivation of RORγt-dependent target genes, and elevated proapoptotic pathways. Depletion of the microbiota with antibiotics partially reduced the hyperactivation of BMAL1-deficient ILC3s and restored cellular homeostasis in the intestine. Last, ILC3s isolated from the inflamed intestine of patients with IBD exhibit substantial alterations in expression of several circadian-related genes. Our results collectively define that circadian regulation is essential for the homeostasis of ILC3s in the presence of a complex intestinal microbiota and that this pathway is disrupted in the context of IBD.
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