Project description:The somatosensory nervous system surveils external stimuli at barrier tissues, regulating innate immune cells under infection and inflammation. The roles of sensory neurons in controlling the adaptive immune system, and more specifically immunity to the microbiota, however, remain elusive. Here, we identified a novel mechanism for direct neuroimmune communication between commensal-specific T lymphocytes and somatosensory neurons mediated by the neuropeptide calcitonin gene-related peptide (CGRP) in the skin. Intravital imaging revealed that commensal-specific T cells are in close proximity to cutaneous nerve fibers in vivo. Correspondingly, we observed upregulation of the receptor for the neuropeptide CGRP, RAMP1, in CD8+ T lymphocytes induced by skin commensal colonization. Neuroimmune CGRP-RAMP1 signaling axis functions in commensal-specific T cells to constrain Type 17 responses and moderate the activation status of microbiota-reactive lymphocytes at homeostasis. As such, modulation of neuroimmune CGRP-RAMP1 signaling in commensal-specific T cells shapes the overall activation status of the skin epithelium, thereby impacting the outcome of responses to insults such as wounding. The ability of somatosensory neurons to control adaptive immunity to the microbiota via the CGRP-RAMP1 axis underscores the various layers of regulation and multisystem coordination required for optimal microbiota-reactive T cell functions under steady state and pathology.

Project description:The somatosensory nervous system surveils external stimuli at barrier tissues, regulating innate immune cells under infection and inflammation. The roles of sensory neurons in controlling the adaptive immune system, and more specifically immunity to the microbiota, however, remain elusive. Here, we identified a novel mechanism for direct neuroimmune communication between commensal-specific T lymphocytes and somatosensory neurons mediated by the neuropeptide calcitonin gene-related peptide (CGRP) in the skin. Intravital imaging revealed that commensal-specific T cells are in close proximity to cutaneous nerve fibers in vivo. Correspondingly, we observed upregulation of the receptor for the neuropeptide CGRP, RAMP1, in CD8+ T lymphocytes induced by skin commensal colonization. Neuroimmune CGRP-RAMP1 signaling axis functions in commensal-specific T cells to constrain Type 17 responses and moderate the activation status of microbiota-reactive lymphocytes at homeostasis. As such, modulation of neuroimmune CGRP-RAMP1 signaling in commensal-specific T cells shapes the overall activation status of the skin epithelium, thereby impacting the outcome of responses to insults such as wounding. The ability of somatosensory neurons to control adaptive immunity to the microbiota via the CGRP-RAMP1 axis underscores the various layers of regulation and multisystem coordination required for optimal microbiota-reactive T cell functions under steady state and pathology.

Project description:In this study, a quantitative proteomic technique based on isobaric tags for relative and absolute quantitation (iTRAQ) was used to compare the proteome of cultured sensory and motor nerve fibroblasts (Fbs). Among a total of 2597 overlapping proteins identified, we obtained 148 differentially expressed proteins, of which 116 proteins were significantly higher expressed in sensory Fbs, and 32 proteins were significantly higher expressed in motor Fbs. Western blot and qPCR analysis were applied to validate differentially expressed proteins. Functional categorization indicated that differentially expressed proteins were linked to a diverse array of biological processes , including regeneration, axon guidance, cytoskeleton organization, cell proliferation, cell migration, cell adhesion, and tissue remodeling, which might play a critical role in the specificity of peripheral nerve regeneration. Furthermore, following co-culture of motor neurons with motor or sensory Fbs , motor Fbs significantly enhanced neurite growth than sensory Fbs. These findings indicated that nerve Fbs expressed the distinct motor and sensory phenotypes involved in different patterns of protein expression, biological processes, and effects on neurons.

Project description:Peripheral nerve injuries due to physical insults or chronic diseases are quite common, yet no pharmacological therapies are available for the effective repair of injured nerves. The slow growth rate of adult nerves and insufficient access to growth factors pose major hurdles in timely reinnervating target tissues and restoring functions after nerve injuries. A better understanding of the molecular changes that occur during the immediate regenerative reprogramming of neurons, stated here as in vivo priming, following nerve injury may reveal ideal candidates for future therapies. Hence, molecular profiling of neuronal soma within the first week of nerve injury has been the gold standard for revealing molecular candidates critical for nerve regeneration. A complementary in vitro regenerative priming approach was recently shown to induce enhanced outgrowth in adult sensory neurons. In this work, we exploited the in vitro priming model to reveal novel candidates for adult nerve regeneration. We performed the whole tissue proteomics analysis of in vitro primed DRGs and compared their molecular profile with that of the in vivo primed, and control DRGs. Through this approach, we identified several commonly and uniquely altered molecules in the in vitro and in vivo primed DRGs that have the potential to modulate adult nerve regrowth. We further validated the growth inducing potential of mesencephalic astrocyte-derived neurotrophic factor (MANF), one of the hits identified in our proteomics analysis, in primary adult sensory neurons. Overall, this study showed that in vitro priming partially reproduces the molecular features in in vivo primed adult sensory neurons. The shortlisted candidates presented here from the two priming approaches may serve as potential therapeutic targets for adult nerve regeneration.

Project description:Retrograde signaling from axon to soma activates intrinsic regeneration mechanisms in lesioned peripheral sensory neurons; however, the links between axonal injury signaling and the cell body response are not well understood. Here, we used phosphoproteomics and microarrays to implicate ~900 phosphoproteins in retrograde injury signaling in rat sciatic nerve axons in vivo and ~4500 transcripts in the in vivo response to injury in the dorsal root ganglia. Computational analyses of these data sets identified ~400 redundant axonal signaling networks connected to 39 transcription factors implicated in the sensory neuron response to axonal injury. Experimental perturbation of individual overrepresented signaling hub proteins, including Abl, AKT, p38, and protein kinase C, affected neurite outgrowth in sensory neurons. Paradoxically, however, combined perturbation of Abl together with other hub proteins had a reduced effect relative to perturbation of individual proteins. Our data indicate that nerve injury responses are controlled by multiple regulatory components, and suggest that network redundancies provide robustness to the injury response Microarrays were run on mRNA extracted from adult rat L4 and L5 DRGs cells after 1,3,8,12,16,18,24, and 28 hours after a sciatic nerve (proximal and distal) lesion.

Project description:Primary sensory neurons with cell soma in dorsal root ganglia (DRG) project axons in both the peripheral nervous system and the spinal cord. Whereas the peripheral axon can regenerate after injury, the central axon cannot, providing an opportunity to identify the mechanisms that promote axon regeneration. Using this system, multiple intrinsic mechanisms operating in sensory neurons have been shown to promote axon regeneration. Peripheral sensory neurons also benefit from a supportive environment. In particular, macrophages play important roles in nerve regeneration by clearing debris and regulating Schwann cell function at the site of injury in the nerve. Nerve macrophages have been characterized at the molecular level and derive for the most part from infiltrating monocytes. However, the role and origin of macrophages in the DRG remains poorly understood. Following a 14-days treatment with a CSF1R inhibitor, less than 10% of macrophages remained in the DRG. Recovery from this treatment resulted in a dramatic macrophage repopulation, with the number of DRG macrophages reaching level similar to untreated mice three days post injury. These repopulated DRG macrophages contribute to promote axon regeneration. Our scRNA-seq analysis allow in-depth characterization of the repopulated DRG macrophages in response to nerve injury. These data will provide a better understanding of DRG macrophages and the molecular mechanisms by which they contribute to peripheral nerve repair. These studies may lead to new potential targets to promote axon regeneration.

Project description:Peripheral nerve repair and functional recovery depend on the rate of nerve regeneration and the quality of target reinnervation. It is important to fully understand the cellular and molecular basis underlying the specificity of peripheral nerve regeneration, which means the achieving of respective correct pathfinding and accurate target reinnervation for regrowing motor and sensory axons. In this study, a quantitative proteomic technique, based on isobaric tags for relative and absolute quantitation (iTRAQ) was used to profile the protein expression pattern between single motor and sensory nerves at 14 days after peripheral nerve transection. Among a total of 1259 proteins identified, 176 proteins showed the differential expressions between injured motor and sensory nerves. Quantitative real-time RT-PCR and Western blot analysis were applied to validate the proteomic data on representative differentially expressed proteins. Functional categorization indicated that differentially expressed proteins were linked to a diverse array of molecular functions, including axonogenesis, response to axon injury, tissue remodeling, axon ensheathment, cell proliferation and adhesion, vesicle-mediated transport, response to oxidative stress, internal signal cascade, and macromolecular complex assembly, which might play an essential role in peripheral motor and sensory nerve regeneration. Overall, we hope that the proteomic database obtained in this study could serve as a solid foundation for the comprehensive investigation of differentially expressed proteins between injured motor and sensory nerves and for the mechanism elucidation of the specificity of peripheral nerve regeneration.

Project description:We reported the gene expression analysis of different types of sensory neuron with peripheral nerve transection treatment on single cell level. We found substantial variation between myelinated large diameter neurons and small diameter nonpeptidergic nociceptors, in both terms of regeneration response genes regulation as well as fraction of cells respond to nerve injury.

Project description:The gastrointestinal tract of mammals is inhabited by hundreds of distinct species of commensal microorganisms that exist in a mutualistic relationship with the host. The process by which the commensal microbiota influence the host immune system is poorly understood. We show here that colonization of the small intestine of mice with a single commensal microbe, segmented filamentous bacterium (SFB), is sufficient to induce the appearance of CD4+ T helper cells that produce IL-17 and IL-22 (Th17 cells) in the lamina propria. SFB adhere tightly to the surface of epithelial cells in the terminal ileum of mice with Th17 cells but are absent from mice that have few Th17 cells. Colonization with SFB was correlated with increased expression of genes associated with inflammation, anti-microbial defenses, and tissue repair, and resulted in enhanced resistance to the intestinal pathogen Citrobacter rodentium. Control of Th17 cell differentiation by SFB may thus establish a balance between optimal host defense preparedness and potentially damaging T cell responses. Manipulation of this commensal-regulated pathway may provide new opportunities for enhancing mucosal immunity and treating autoimmune disease. Experiment Overall Design: We compared the gene expression profiles in the terminal ileum of Swiss-Webster GF mice before and after colonization with SFB, which induced robust Th17 cell differentiation. To sieve out host effects, the role of other microbiota, as well as other factors, we also evaluated the transcriptional program induced in Jackson C57BL/6 mice after co-housing with Taconic B6 animals, which also induces Th17 cell differentiation. 0.5 cm of the most distal part of the small intestine was dissected. Total RNA was extracted with TRIzol. RNA was labeled and hybridized to GeneChip Mouse Genome 430 2.0 arrays following the Affymetrix protocols. Data were analyzed in GeneSpring GX10.

Project description:Under steady state conditions, the immune system is poised to sense and respond to the microbiota. As such, immunity to the microbiota, including T cell responses, is expected to precede any inflammatory trigger. How this pool of preformed microbiota-specific T cells contributes to tissue pathologies remains unclear. Here, using an experimental model of psoriasis, we show that recall responses to commensal skin fungi can significantly aggravate tissue inflammation. Enhanced pathology caused by fungi pre-exposure depends on Th17 responses and neutrophil extracellular traps and recapitulates features of the transcriptional landscape of human lesional psoriatic skin. Together, our results propose that recall responses directed to skin fungi can directly promote skin inflammation and that exploration of tissue inflammation should be assessed in the context of recall responses to the microbiota.