Project description:Peripheral sensory neurons with cell body in dorsal root ganglia (DRG) switch to a regenerative state after nerve injury to enable axon regeneration and functional recovery. Studies of nerve injury responses in sensory neurons have revealed signaling and transcriptional mechanisms that increase their intrinsic regenerative capacity. However, the extent to which satellite glial cells (SGC), which completely surround the neuronal soma contribute to these responses remains unexplored. Using single cell RNA-seq, we defined the transcriptional profile of SGC in naïve and injured conditions and identified Fabp7, also known as BLBP, as a novel marker of SGC. We report that nerve injury elicits gene expression changes in SGC, which are mostly related to lipid metabolism, specifically fatty acid synthesis and the peroxisome proliferator-activated receptor (PPAR) signaling. Conditional deletion of Fatty acid synthase (Fasn), the key enzyme in de novo fatty acid synthesis, specifically in SGC, impairs axon regeneration. Treatment with fenofibrate, a PPARa agonist, rescues the impaired regeneration, suggesting that PPRAa, which belongs to a family of lipid regulated transcription factors, functions downstream of fatty acid synthesis in SGC to promote axon regeneration. These results unravel fatty acid synthesis in SGC as a fundamental novel mechanism mediating axon regeneration in mature peripheral nerves.

Project description:Axon regeneration in the central nervous system (CNS) requires reactivating injured neurons’ intrinsic growth state and enabling growth in an inhibitory environment. Using an inbred mouse neuronal phenotypic screen, we find that CAST/Ei mouse adult dorsal root ganglion neurons extend axons more on CNS myelin than the other eight strains tested, especially when pre-injured. Injury-primed CAST/Ei neurons also regenerate markedly in the spinal cord and optic nerve more than those from C57BL/6 mice and show greater spouting following ischemic stroke. Heritability estimates indicate that extended growth in CAST/Ei neurons on myelin is genetically determined, and two whole-genome expression screens yield the Activin transcript Inhba as most correlated with this ability. These screens are presented here. Biological quadruplicate - Mouse tissue - Naïve Dorsal Root Ganglia (DRG) and 5 day post sciatic nerve crush DRG - x9 strains.

Project description:Injured sensory neurons successfully activate a pro-regenerative transcriptional program to enable axon regeneration and functional recovery, but the roles of genes that are inactivated after injury remain poorly understood. Analysis of the miRNA expression profile triggered by axon injury revealed down-regulation of the neural development associated miRNA, miR-9. A target of miR-9 is the critical epigenetic regulator involved in DNA methylation, ubiquitin-like containing PHD ring finger 1 (UHRF1), which increased after injury to promote axon regeneration. UHRF1 is known to repress the transcription of tumor suppressor genes through DNA methylation and we show that UHRF1 interacts with DNMT1 to methylate the promoter region of the tumor suppressors PTEN and CDKN1A, thereby triggering their inactivation. We also reveal that UHRF1 represses the transcriptional regulator REST. Our findings define an epigenetic mechanism that silences the transcription of axon growth suppressors to promote axon regeneration in sensory neurons.

Project description:Injured sensory neurons successfully activate a pro-regenerative transcriptional program to enable axon regeneration and functional recovery, but the roles of genes that are inactivated after injury remain poorly understood. Analysis of the miRNA expression profile triggered by axon injury revealed down-regulation of the neural development associated miRNA, miR-9. A target of miR-9 is the critical epigenetic regulator involved in DNA methylation, ubiquitin-like containing PHD ring finger 1 (UHRF1), which increased after injury to promote axon regeneration. UHRF1 is known to repress the transcription of tumor suppressor genes through DNA methylation and we show that UHRF1 interacts with DNMT1 to methylate the promoter region of the tumor suppressors PTEN and CDKN1A, thereby triggering their inactivation. We also reveal that UHRF1 represses the transcriptional regulator REST. Our findings define an epigenetic mechanism that silences the transcription of axon growth suppressors to promote axon regeneration in sensory neurons.

Project description:The developmental maturation of a neuron requires the completion of neuronal polarization preceding the formation of a synapse. Whether neuronal polarization marks the decline in growth competence in the injured mammalian adult nervous system remains elusive. Here we show that gene expression and epigenetic signatures associated with the regenerative growth ability of dorsal root ganglia (DRG) sensory neurons are lost during the transition from a non-polarized to a polarized state. The transcriptional co-factor Cited2 was found to be epigenetically upregulated in immature DRG and following a regenerative injury, but it remained unchanged by a non-regenerative spinal cord injury (SCI). Next, Cited2 was overexpressed in DRG neurons in a model of SCI in mice where it promoted sensory axon growth and reversed the gene expression signatures associated with neuronal maturation. Importantly, Cited2 expression stirred the maturation of DRG neurons towards a non-polarized state. Together, these data suggest that the transition from a non-polarized to a polarized state marks the reversible loss of the regenerative ability of a neuron, thus paving the way to targeted repair strategies relying on neuronal de-maturation.

Project description:The developmental maturation of a neuron requires the completion of neuronal polarization preceding the formation of a synapse. Whether neuronal polarization marks the decline in growth competence in the injured mammalian adult nervous system remains elusive. Here we show that gene expression and epigenetic signatures associated with the regenerative growth ability of dorsal root ganglia (DRG) sensory neurons are lost during the transition from a non-polarized to a polarized state. The transcriptional co-factor Cited2 was found to be epigenetically upregulated in immature DRG and following a regenerative injury, but it remained unchanged by a non-regenerative spinal cord injury (SCI). Next, Cited2 was overexpressed in DRG neurons in a model of SCI in mice where it promoted sensory axon growth and reversed the gene expression signatures associated with neuronal maturation. Importantly, Cited2 expression stirred the maturation of DRG neurons towards a non-polarized state. Together, these data suggest that the transition from a non-polarized to a polarized state marks the reversible loss of the regenerative ability of a neuron, thus paving the way to targeted repair strategies relying on neuronal de-maturation.

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:Injured peripheral neurons successfully activate a pro-regenerative transcriptional program to enable axon regeneration and functional recovery. How transcriptional regulators coordinate the expression of such programs remains unclear. Here we show that hypoxia-inducible factor 1α (HIF-1α) controls multiple injury-induced genes in sensory neurons and contribute to the pre-conditioning lesion effect. Knockdown of HIF-1α in vitro or conditional knockout in vivo impairs sensory axon regeneration. The HIF-1α target gene Vascular Endothelial Growth Factor A (VEGFA) is expressed in injured neurons and contributes to stimulate axon regeneration. Induction of HIF-1α using hypoxia enhances axon regeneration in vitro and in vivo in sensory neurons. Hypoxia also stimulates motor neuron regeneration and accelerates neuromuscular junction reinnervation. This study demonstrates that HIF-1α represents a critical transcriptional regulator in regenerating neurons and suggests hypoxia as a tool to stimulate axon regeneration.

Project description:Axon regeneration of dorsal root ganglia (DRG) neurons after peripheral axotomy involves epigenetic reconfigurations that rewire gene regulatory circuits to establish regenerative gene program. However, the mechanisms and transcriptional regulators remain poorly understood. Here, we conducted an unbiased survey of DNA differentially hydroxymethylated regions (DhMRs) in DRG after peripheral lesion, which identified enriched binding motif for Bmal1, a transcription factor and a central regulator of the circadian clock. Through applying conditional deletion of Bmal1, in vitro and in vivo models of axon regrowth, and transcriptomic profiling, we showed that Bmal1 inhibits axon regeneration in part through Tet3-dependent manner. Mechanistically, Bmal1 functions as a gatekeeper of neuroepigenetic injury responses by limiting Tet3 expression and restricting 5hmC modifications. Notably, Bmal1-regulated genes after axotomy not only concern axon guidance and axon regrowth, but also stress responses, energy homeostasis, and neuroinflammation. Furthermore, we uncovered diurnal oscillation of Tet3 and 5hmC in DRG neurons, and this epigenetic rhythm corresponded to time-of-day effect on axon growth potential. Collectively, our studies showed that Bmal1 deletion mimics the conditioning lesion in lifting epigenetic barriers to enhance axon regeneration.

Project description:Primary afferent collateral sprouting (PACS) is a process whereby non-injured primary afferent neurons respond to some stimulus by extending new branches from existing axons. In the model used here (spared dermatome), the intact sensory neurons respond to the denervation of adjacent areas of skin by sprouting new axon branches into that adjacent denervated territory. Neurons of both the central and peripheral nervous systems undergo this process, which contributes to both adaptive and maladaptive plasticity. Investigations of gene expression changes associated with PACS can provide a better understanding of the molecular mechanisms controlling this process. Consequently, it can be used to develop treatment for spinal cord injury to promote functional recovery. In this study, we sought to identify gene expression changes in PACS using 20 Affymetrix Rat Genome 230 2.0 microarrays. The experiments were designed to discover global gene expression changes in non-injured DRG neurons undergoing PACS. T11 DRG neurons remained intact and undergo PACS after the cutaneous nerves of the adjacent segments (T9, T10, T12, and T13) were injured and regeneration of those injured nerves prevented by ligation. Thus, the T9, T10, T12, and T13 dermatomes were denervated, but the T11 dermatome remained intact. Axons of the T11dermatome (and thus housed in the T11 dorsal root ganglion (DRG)), extended new branches to innervate the T9, T10, T12, and T13 dermatomes. N.B.: This is NOT a spared root experiment. ALL spinal roots were non-injured. Peripheral nerves were used. A total of 20 Affymetrix Rat Genome 230 2.0 microarrays were analyzed: six naïve controls, seven replicates at day 7 post-surgery (presumed to represent an â??initiation phaseâ??), and seven replicates at day 14 post-surgery (presumed to represent a â??maintenance phaseâ??). DRGs were NOT pooled onto microarrays. Each animal had its own microarray with T11 DRG sample which underwent 2-round amplification. After quality control analysis, one of the naïve control microarrays was removed from further analysis.