Project description:Functional switching of the peritumoral cutaneous Schwann cells in melanoma

Project description:Here we provide sequencing data derived from our efforts to identify SOX10-regulated promoters in Schwann cells genome-wide. We assess the activity of SOX10-bound promoters using Tn5Prime to identify and quantify transcription start sites in adult peripheral nerve, in differentiating primary Schwann cells, and upon ablation of SOX10 in vitro. Tn5Prime libraries were prepared essentially as described by Cole and colleagues (NAR, 2018). Analyses focused on transcription start sites associated with H3K4me3 and SOX10 ChIP-Seq peaks from sciatic nerve (ChIP-Seq data derived from previously published datasets).

Project description:Peripheral glial Schwann cells switch to a repair state after nerve injury, proliferate to supply lost cell population, migrate to form regeneration tracks, and generates a permissive microenvironment for nerve regeneration. Exploring essential regulators of the repair responses of Schwann cells may benefit the clinical treatment for peripheral nerve injury. In the present study, FOSL1 regulates Schwann cell phenotype modulation and provided a novel therapeutic approach to orchestrate the regeneration and functional recovery of injured peripheral nerves.

Project description:After peripheral nerve injury, adult Schwann cells convert to progenitor cell-like repair Schwann cells, which are pivotal for nerve regeneration. We show that Schwann cell-specific deletion of TFEB/3 disrupts the transcriptomic reprogramming necessary for injury-induced repair Schwann cell generation in mice. The mutant mice fail to generate proliferating repair Schwann cells to populate the injured nerves. Distal Schwann cells fail to express injury-responsive genes and continue to maintain the expression of myelin-associated genes. TFEB/3 binding motifs are enriched in injury-induced enhancers, suggesting their role in repair gene activation. Autophagy-dependent myelin breakdown is not impaired in the mutant mice despite the known function of TFEB/3 as autophagy activators. However, the mutant mice exhibit defects in axon regeneration, target reinnervation, and functional recovery. Therefore, TFEB/3 play a critical role in orchestrating transcriptional changes essential for repair Schwann cell generation and function necessary for peripheral nerve regeneration.

Project description:Schwann cell (Büngner) repair cells play a critical role in orchestrating nerve repair after injury, but the reprogramming process that generates them is poorly understood. We present the first combined whole genome coding and non-coding RNA and CpG methylation study after nerve injury. We show that genes involved in epithelial to mesenchymal transition are enriched in repair cells and we identify long non-coding RNAs in Schwann cells. We demonstrate that the AP-1 transcription factor c-Jun regulates the expression of certain micro RNAs in repair cells, in particular miR-21 and miR-34. Surprisingly, changes in CpG methylation are limited in injury, unlike development, and restricted to specific locations, such as enhancer regions of novel Schwann cell specific genes, such as Nedd4l, and near to local enrichment of AP-1 motifs. These epigenetic changes significantly broaden our understanding of Schwann cell reprogramming in peripheral nervous system tissue repair. To identify epigenetic regulators underlying successful nerve regeneration we generated RNA-Seq, small-RNA-Seq and whole genome bisulfite sequencing libraries for uninjured nerve versus three and/or seven day post nerve transection sciatic nerves of adult C57BL/6J mice crush.

Project description:Schwann cells are important glial cells in peripheral nervous system. In this study, we performed single cell RNA-sequencing (scRNA-seq) analysis of Schwann cells exist in both dorsal root ganglion(DRG) and sciatic nerve.We categorized DRG and sciatic nerve Schwann cells into different subtypes,and found common subtypes and different subtypes.In addition, we discovered the proliferation and migration ability of Schwann cells were distinct in different tissues.Our current study revealed the distinctive characteristics of Schwann cells in DRG and sciatic nerve.

Project description:After nerve injury, myelin and Remak Schwann cells reprogram to repair cells specialized for regeneration. Normally providing strong regenerative support, these cells fail in aging animals, and during the chronic denervation that results from slow axon growth. This impairs axonal regeneration and causes a significant clinical problem. We find that aging and chronically denervated repair cells express reduced c-Jun protein and the regenerative support provided by these cells is also reduced. In both cases, genetically restoring Schwann cell c-Jun levels restores regeneration to that in controls. We identify potential gene candidates mediating this effect and implicate Shh in the control of Schwann cell c-Jun levels. These experiments reveal that a common mechanism, reduced c-Jun in repair cells, underlies two major reasons for regeneration failure in the PNS. They underscore the central importance of Schwann cell c-Jun as a regulator of nerve repair, and point to molecular pathways that can be manipulated for improving the clinical outcome of nerve injuries.

Project description:Analysis of gene expression in LKB1(Stk11)-depleted sciatic nerves (LKB1-SCKO) vs control nerves from age-matched mice. Gene expression profiles are predominantly derived from Schwann cell glia and provide important information about the response of peripheral nerve Schwann cells to inactivation of the metabolic regulator protein LKB1(aka Stk11). Total RNA obtained from sciatic nerve segments from 6 LKB1-SCKO mutant mice compared to RNA from nerve segments from 6 control mice (floxed LKB1 mutant mice that do not express Cre recombinase).

Project description:The striking PNS regenerative response to injury rests on the plasticity of adult Schwann cells and their ability to transit between differentiation states, a highly unusual feature in mammals. Using mice with inactivation of Schwann cell c-Jun, we show that the injury response involves c-Jun dependent natural reprograming of differentiated cells to generate a distinct Schwann cell state specialized to promote regeneration. Transected distal stumps of c-Jun mutants show 172 disregulated genes, resulting in abnormal expression of growth factors, adhesion molecules and cytoskeletal changes that lead to neuronal death, inhibition of axon growth and striking failures of functional repair after injury. These observations provide a molecular basis for understanding Schwann cell plasticity and nerve regeneration. They offer conclusive support for the notion that Schwann cells control repair in the PNS, using dedicated transcriptional controls to generate a distinct repair cell, a transition that shows similarities to transdifferentiation seen in other systems. Total RNA was purified from a 10mm segment of the distal stump and uninjured contralateral nerve from c-Jun mutants and control mice 7 days after nerve cut. For each condition (injured/uninjured) and genotype (control/ knock-out) 2 independent samples (replicates) were generated from pooled nerves of 4/6 mice resulting in a total of 8 samples: CTRL.cut.R1, CTRL.cut.R2, CTRL.uncut.R1, CTRL.uncut.R2, KO.cut.R1, KO.cut.R2, KO.uncut.R1,KO.uncut.R2.

Project description:Schwann cells (SCs) proliferation is crucial for axonal guidance and nerve regeneration following nerve injury. This study aims to investigate the in vitro effects of interleukin-22 (IL-22) on SCs and the corresponding mechanism.