Project description:The study aimed to make a molecular definition of myenteric neuron classes in the mouse small intestine and describe their differentiation from enteric stem cells during embryogenesis. Method: We performed single cell RNA-sequencing of enteric neurons from small intestine at the juvenile stage (postnatal day (P)21) and ENS cells from the small intestine at embryonic day (E)15.5 and E18.5. We confirmed novel marker genes for all classes using immunohistochemistry and characterised the morphology/axons of three of newly discovered ENS neuron types. Results: 12 unique enteric neuron classes (ENC1-12) were identified and confirmed in native tissue by histochemical methods. The communication machinery (ligand, receptors, adhesion molecules), axonal patterns and morphologies were presented to infer functional roles of the ENCs. Analysis of embryonic transcriptomes revealed that enteric stem cells differentiate into two neuronal branches, that successively diversify into ENC1-7 and ENC8-12, respectively. Conclusion: Utilizing single cell RNA-sequencing we conclude that murine small intestine consists of 12 major myenteric classes that emerge through a step-wise fashion during embryonic development. Reference: Morarach, Mikhailova et al., 2020. BioRxiv 2020.03.02.955757

Project description:Epigenetic regulatory mechanisms are underappreciated but critical for enteric nervous system (ENS) development and maintenance. We discovered that fetal loss of the epigenetic regulator Bap1 in the ENS lineage causes severe postnatal bowel dysfunction and early death in Tyrosinase-Cre; Bap1fl/fl mice. Bap1-depleted ENS appears normal in neonates, however, by postnatal day 15 (P15), Bap1-deficient enteric neurons are largely absent from the small and large intestine of Tyrosinase-Cre; Bap1fl/fl mice. Bowel motility becomes markedly abnormal with disproportionate loss of cholinergic neurons. Single-cell RNA sequencing at P5 shows that fetal Bap1 loss inTyrosinase-Cre; Bap1fl/fl mice markedly alters the composition and relative proportions of enteric neuron subtypes. In contrast, postnatal deletion of Bap1 did not cause enteric neuron loss or impaired bowel motility. These findings suggest that BAP1 is critical for postnatal enteric neuron differentiation and for enteric neuron survival.

Project description:Acquired or congenital disruption in enteric nervous system (ENS) development or function can lead to significant mechanical dysmotility. ENS restoration through cellular transplantation may provide a cure for enteric neuropathies. We have previously generated human pluripotent stem cell (hPSC)-derived tissue-engineered small intestine (TESI) from human intestinal organoids (HIO). However, HIO-TESI fails to develop an ENS. In a previous report of combined HIO with additional human enteric neural crest cells (ENCC), an ENS was established but lacked maturity. The purpose of our study is to establish a mature ENS derived exclusively from hPSC in HIO-TESI. hPSC-derived ENCC supplementation of HIO-TESI generates ENCC-HIO-TESI with mature submucosal and myenteric ganglia, repopulates excitatory, inhibitory, and sensory neurons, and restores the neuroepithelial circuit and neuron-dependent contractility and relaxation. Our findings validate a novel approach to restoring a functional hPSC-derived ENS in ENCC-HIO-TESI and implicate their potential for the treatment of enteric neuropathies.

Project description:Self-maintaining gMacs are present in the submucosal and myenteric plexus of the intestine where they maintain enteric neurons and submucosal vasculature YFP-positive and YFP-negative CD11b+, CD64+ macrophages were sorted from lamina propria and muscularis externa of Cx3cr1CreERT2.Rosa26-LSL-YFP animals, 35 weeks after tamoxifen administration. Four biological replicates each. YFP-positive and YFP-negative were compared within lamina propria and muscularis externa

Project description:Interstitial cells of Cajal (ICC) have important functions in regulation of motor activity in the gastrointestinal tract. In murine small intestine ICC are gathered in the region of the myenteric plexus (ICC-MY) and within the deep-muscular plexus near the submucosal surface of the circular muscle layer (ICC-DMP). These two classes of ICC have different physiological functions. ICC-MY are pacemaker cells and generate the slow wave electrical rhythmicity of gastrointestinal organs. ICC-DMP form synaptic connections with the varicose nerve terminals of enteric motor neurons and are involved in reception and transduction of motor neurotransmission. In the present study we used recently developed highly selective techniques to isolate the two classes of ICC from enzymatically dispersed intestinal muscles by fluorescence-activated cell sorting. Transcriptional expression of the two functional classes was investigated using DNA microarray analysis. Keywords: comparative transcriptional profiling

Project description:Interstitial cells of Cajal (ICC) have important functions in regulation of motor activity in the gastrointestinal tract. In murine small intestine ICC are gathered in the region of the myenteric plexus (ICC-MY) and within the deep-muscular plexus near the submucosal surface of the circular muscle layer (ICC-DMP). These two classes of ICC have different physiological functions. ICC-MY are pacemaker cells and generate the slow wave electrical rhythmicity of gastrointestinal organs. ICC-DMP form synaptic connections with the varicose nerve terminals of enteric motor neurons and are involved in reception and transduction of motor neurotransmission. In the present study we used recently developed highly selective techniques to isolate the two classes of ICC from enzymatically dispersed intestinal muscles by fluorescence-activated cell sorting. Transcriptional expression of the two functional classes was investigated using DNA microarray analysis. Experiment Overall Design: ICC-DMP and ICC-MY cells were isolated from the murine small intestinal tissues and their transcriptional expression was compared with that of the tunica muscularis tissues. Transcriptional expression profiles of ICC-DMP and ICC-MY were compared to each other also.

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:This study was undertaken to identify gene expression changes in enteric neurons of Hirschsprung disease mice. Methods: We performed single-cell RNA sequencing of enteric nervous system cells isolated from the small intestine of Ednrb-knockout mice at age P14. Results: Through comparisons with published datasets of WT small intestine enteric neurons, we identify a missing neuronal population in the ganglionated small intestine of Hirschsprung disease mice. Conclusion: Single-cell RNA sequencing permits identification of cellular perturbations in Hirschsprung disease models.

Project description:Conserved genetic signatures parcellate cardinal spinal neuron classes into local and projection subsets [P0NeuronData]

Project description:The small intestinal epithelium is composed of several defined epithelial cell lineages, which in turn exhibit marked transcriptional and functional diversity along the crypt-villus and proximal-to-distal length of the intestinal tract. While epithelial cell type and functional heterogeneity have been characterized in the adult intestinal epithelium, the temporal and spatial changes during the postnatal period, which accompany the transition from placental energy supply to enteral feeding and facilitate the establishment of the enteric microbiota and postnatal immune maturation, have not been systematically investigated. Here we analyzed the total small intestinal epithelium of 1-, 5-, 10-, and 25-day-old specific pathogen-free (SPF) and germ-free (GF) mice by bulk RNA-Seq and used differential gene expression and pathway analysis to identify age-specific expression patterns. In addition, the influence of enteric infection on the neonatal epithelium was investigated by bulk RNA-Seq. We identify gene clusters temporally expressed in the neonatal intestine and correlate their expression with the functional changes during postnatal tissue maturation and the neonate to adult transition.