Project description:To identify the gene expression profile of enteric glia and assess the transcriptional similarity between enteric and extraenteric glia, we performed RNA sequencing analysis on PLP1-expressing cells in the mouse intestine. This analysis shows that enteric glia are transcriptionally unique and distinct from other cell types in the nervous system. Enteric glia express many genes characteristic of the myelinating glia, Schwann cells and oli- godendrocytes, although there is no evidence of myelination in the murine ENS. Total RNA expression profiles of PLP1 expressing enteric glial cells (GFP+) and non-glial cells (GFP-negative) were obtained from the ileum and colon of juvenile PLP1-eGFP transgenic mice.

Project description:Glial cells have been proposed as an endogenous source of progenitors for the treatment of neural deficits. However, the cellular and molecular mechanisms underpinning the neurogenic potential of certain populations of adult glial cells, are not known. Previous studies have indicated that chemical injury of the gut by benzalkonium chloride (BAC) of the gut can activate neuronal markers. To examine whether gut injury can induce in EGCs neurogenic programs similar to those expressed by early ENS progenitors in vivo, we performed bulk RNA-seq of enteric glia isolated from mouse guts 48 hours after BAC treatment. We isolated tdT+ cells (=EGCs) and tdT- cells (=non-glia cells) from the TM of control and BAC-treated Sox10CreERT2;Rosa26tdTomato mice and subjected the samples to bulk RNAseq analysis.

Project description:To investigate and compare the lncRNA and mRNA expression in HSCR from the aganglionic and normal aganglionic

Project description:Tissue maintenance and repair depend on the integrated activity of multiple cell types. Whereas the contributions of epithelial, immune and stromal cells in intestinal tissue integrity are well understood, the role of intrinsic neuroglia networks remains largely unknown. Here, we uncover pivotal roles of enteric glial cells (EGCs) in intestinal homeostasis, immunity and tissue repair. We demonstrate that infection of mice with Heligmosomoides polygyrus (H. poly) leads to enteric gliosis and upregulation of the interferon gamma (IFN-γ) gene signature. Single-cell transcriptomics of tunica muscularis (TM) showed that glia-specific abrogation of IFN-γ signaling leads to tissue-wide activation of pro-inflammatory transcriptional programs. In addition, disruption of the IFN-γ-EGC signaling axis enhanced the inflammatory and granulomatous response of TM to helminths. Mechanistically, we show that upregulation of Cxcl10 is an early immediate response of EGCs to IFN-γ signaling and provide evidence that this chemokine and the downstream amplification of IFN-γ signaling in the TM are required for a measured inflammatory response to helminths and resolution of granulomatous pathology. Our study demonstrates that IFN-γ signaling in enteric glia is central to intestinal homeostasis and reveals critical roles of the IFN-γ-EGC-Cxcl10 axis in immune response and tissue repair following infectious challenge. To characterize the response of enteric glia to helminth infection, we performed bulk RNAseq of tdT+ cells (=EGCs) and tdT- cells (=non-glia cells) from the TM of naïve and H. poly-infected Sox10CreERT2;Rosa26tdTomato mice.

Project description:The crosstalk of glial cells and other components of the tumor microenvironment is a complex process, suggested to exacerbate tumor development. Here, we treated murine primary enteric glial cells (EGCs) with IL-1β, a cytokine that has been shown to be upregulated in many solid tumors. Mass spectrometry was performed to detect the factors secreted by glial cells. Diverse proteins were found differentially regulated upon IL-1β treatment.

Project description:Objective Hirschsprung disease (HSCR) is a severe congenital disorder affecting 1:5000 live births. HSCR results from failure of enteric nervous system (ENS) progenitors to fully colonise the gastrointestinal tract during embryonic development. This leads to aganglionosis in the distal bowel, resulting in disrupted motor activity and impaired peristalsis. Currently, the only viable treatment option is surgical resection of the aganglionic bowel. However, patients frequently suffer debilitating, lifelong symptoms, with multiple surgical procedures often necessary. Hence, alternative treatment options are crucial. An attractive strategy involves the transplantation of ENS progenitors generated from human pluripotent stem cells (hPSCs). Design ENS progenitors were generated from hPSCs using an accelerated protocol and characterised, in detail, through a combination of single cell RNA-sequencing, protein expression analysis and calcium imaging. We tested ENS progenitors’ capacity to integrate and restore functional responses in HSCR colon, after ex vivo transplantation to organotypically cultured patient-derived colonic tissue, using organ bath contractility. Results We found that our protocol consistently gives rise to high yields of cell populations exhibiting transcriptional and functional hallmarks of early ENS progenitors. Following transplantation, hPSC-derived ENS progenitors integrate, migrate and form neurons within explanted human HSCR colon samples. Importantly, the transplanted HSCR tissue displayed increased basal contractile activity and increased responses to electrical stimulation compared to control tissue. Conclusion Our findings demonstrate, for the first time, the potential of hPSC-derived ENS progenitors to repopulate and restore functional responses in human HSCR patient colonic tissue.

Project description:Despite extensive genetic heterogeneity, 72% of pathogenic alleles for Hirschsprung disease (HSCR) arise from coding and regulatory variants in genes of the RET and EDNRB gene regulatory network (GRN) in the enteric nervous system (ENS). Reduced signaling of these two receptors below a threshold in enteric neural crest-derived cells (ENCDCs) leads to a molecular tipping point at which otherwise lesser cellular defects result in aganglionosis. To elucidate the mechanisms leading to enteric neuronal loss from these genetic defects, we generated four strains of mice carrying reduced function alleles at Ret or Ednrb or both, along with their wildtype alleles. ENS tissue- and single-cell gene expression profiling of the developing and postnatal gastrointestinal tract in five mouse models, with various combinations of mutant alleles, revealed 3 major insights: (i) Ret and Ednrb deficiency, rather than complete loss, is sufficient to induce HSCR, (ii) Ret and Ednrb demonstrate strong trans interactions, and (iii) disruption of this interaction leads to cellular fate changes to compensate for neuronal loss. This study of targeted mouse models of a multifactorial disorder reveals how increasing dosage of genetic defects within a GRN leads to quantifiably increasing dysregulation from genotype to gene expression to cellular identity to function. Importantly, our studies establish that aganglionosis results only with severely reduced gene expression at both receptor genes and their consequent disruption of normal and compensatory cell fate trajectories.

Project description:Despite extensive genetic heterogeneity, 72% of pathogenic alleles for Hirschsprung disease (HSCR) arise from coding and regulatory variants in genes of the RET and EDNRB gene regulatory network (GRN) in the enteric nervous system (ENS). Reduced signaling of these two receptors below a threshold in enteric neural crest-derived cells (ENCDCs) leads to a molecular tipping point at which otherwise lesser cellular defects result in aganglionosis. To elucidate the mechanisms leading to enteric neuronal loss from these genetic defects, we generated four strains of mice carrying reduced function alleles at Ret or Ednrb or both, along with their wildtype alleles. ENS tissue- and single-cell gene expression profiling of the developing and postnatal gastrointestinal tract in five mouse models, with various combinations of mutant alleles, revealed 3 major insights: (i) Ret and Ednrb deficiency, rather than complete loss, is sufficient to induce HSCR, (ii) Ret and Ednrb demonstrate strong trans interactions, and (iii) disruption of this interaction leads to cellular fate changes to compensate for neuronal loss. This study of targeted mouse models of a multifactorial disorder reveals how increasing dosage of genetic defects within a GRN leads to quantifiably increasing dysregulation from genotype to gene expression to cellular identity to function. Importantly, our studies establish that aganglionosis results only with severely reduced gene expression at both receptor genes and their consequent disruption of normal and compensatory cell fate trajectories.

Project description:This study investigates the phenomenon of postnatal plasticity within the enteric nervous system (ENS), specifically investigating the reinnervation potential of post-mitotic enteric neurons. Employing BAF53b-Cre for selective tracing, the reinnervation capabilities of postnatal enteric neurons in multiple model systems are shown. Denervated enteric neurons exhibit the ability to regenerate neurites in vitro, with neurite complexity and direction notably influenced by contact with enteric glial cells (EGCs). In vivo nerve fibers from transplanted enteric neurons exclusively interface with EGCs. Resident EGCs are sustained after Cre dependent ablation of enteric neurons and govern the architecture of the ENS by reinnervating enteric neurons. Transplantation experiments underscore the swift reintegration and reinnervation potential of post-mitotic neurons, leading to restored muscle function within two weeks. Optogenetic investigations further delineate time-dependent functional recovery via transplantation of isolated enteric ganglia. These revelations demonstrate the structural and functional reinnervation capacity of post-mitotic enteric neurons, underscored by EGC guidance.

Project description:Tissue maintenance and repair depend on the integrated activity of multiple cell types. Whereas the contributions of epithelial, immune and stromal cells in intestinal tissue integrity are well understood, the role of intrinsic neuroglia networks remains largely unknown. Here, we uncover pivotal roles of enteric glial cells (EGCs) in intestinal homeostasis, immunity and tissue repair. We demonstrate that infection of mice with Heligmosomoides polygyrus (H. poly) leads to enteric gliosis and upregulation of the interferon gamma (IFN-γ) gene signature. Single-cell transcriptomics of tunica muscularis (TM) showed that glia-specific abrogation of IFN-γ signaling leads to tissue-wide activation of pro-inflammatory transcriptional programs. In addition, disruption of the IFN-γ-EGC signaling axis enhanced the inflammatory and granulomatous response of TM to helminths. Mechanistically, we show that upregulation of Cxcl10 is an early immediate response of EGCs to IFN-γ signaling and provide evidence that this chemokine and the downstream amplification of IFN-γ signaling in the TM are required for a measured inflammatory response to helminths and resolution of granulomatous pathology. Our study demonstrates that IFN-γ signaling in enteric glia is central to intestinal homeostasis and reveals critical roles of the IFN-γ-EGC-Cxcl10 axis in immune response and tissue repair following infectious challenge. To characterize the response of enteric glia to helminth infection at single cell resolution, we next performed scRNAseq (C1 Fluidigm platform) of tdT+ cells from the TM of naïve and H. poly-infected mice.