Project description:B-RAF activation in mature corticospinal neurons upregulated a discrete set of transcription factors overlapping with a set induced early in axotomized zebrafish retina ganglion cells which can fully regenerate their axons. Conditional genetic activation of B-RAF promoted robust regeneration and sprouting of corticospinal tract axons after experimental spinal cord injury. Newly sprouting axon collaterals formed synaptic connections, correlating with recovery of skilled motor function. We also found that non-invasive suprathreshold high-frequency repetitive transcranial magnetic stimulation activates the RAF effector MEK and promotes regeneration and sprouting of corticospinal tract axons, dependent on MEK signaling. Our findings demonstrate a central role of neuron-intrinsic RAF–MEK signaling in enhancing the growth capacity of mature corticospinal neurons and propose transcranial magnetic stimulation as a potential therapy for spinal cord injury.

Project description:Functional deficits persist after spinal cord injury (SCI) because axons in the adult mammalian central nervous system (CNS) fail to regenerate. However, modest levels of spontaneous functional recovery are typically observed after trauma, and are thought to be mediated by the plasticity of intact circuits. The mechanisms underlying intact circuit plasticity are not delineated. Here, we characterize the in vivo transcriptome of sprouting intact neurons from ngr1 null mice after partial SCI. We identify the lysophosphatidic acid signaling modulators Lppr1 and Lpar1 as intrinsic axon growth modulators for intact corticospinal motor neurons after adjacent injury. Furthermore, in vivo Lpar1 inhibition or Lppr1 overexpression enhances sprouting of intact corticospinal tract axons and yields greater functional recovery after unilateral brainstem lesion in wild type mice. Thus, the transcriptional profile of injury-induced sprouting of intact neurons reveals targets for therapeutic enhancement of axon growth initiation and new synapse formation.

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.

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.

Project description:Depending on the severity of a CNS injury, in humans as well as in experimental animal models certain degrees of functional recovery are observed. Rodent studies have provided much evidence for underlying anatomical changes involving neurite outgrowth of both spared and axotomized fiber tracts, also referred to as sprouting. Following a thoracic spinal cord injury (SCI) in adult rats, axotomized fibers of the hindlimb corticospinal tract (CST) were found to sprout into the cervical spinal cord at different rostrocaudal levels. Anterograde tracings showed that these new collaterals of motor cortical hindlimb fibers project into the intermediate laminae of the cervical grey matter, particularly pronounced at the level of cervical segment three (C3). The molecular cues which induce the growth and guide these sprouts of hindlimb CST fibers are unknown. We hypothesize that sectreted factors and guidance and adhesion molecules are specifically expressed in the intermediate laminae of the cervical spinal cord to direct and target the ingrowth of the sprouting hindlimb CST fibers. To test our hypothesis the transcription profile of the target region of sprouts was investigated with RNA sequencing of total RNA extracted from the intermediate laminae (IV-VII) of the spinal gray matter at cervical level C3. Four major comparisons were performed, which were then again compared to each other. The first comparison was between samples of animals with an SCI sacrificed at four different time points after injury (1, 3, 6, 12 weeks after injury). The second and third comparison was between samples of rats with a SCI compared to their sham controls sacrificed at the same time point after surgery (1 week or 12 weeks respectively). The fourth comparison was between samples from animals of the two control groups, rats with a sham surgery which were either sacrificed at one or at twelve weeks after injury. We found that most changes in gene expression ocurred at one week after SCI and least changes occured at twelve weeks after SCI, suggesting that the largest effects on a global level of gene expression occur during early time points after injury. Interestingly, also we also found changes in gene expression when comparing the samples from the two control groups, which suggests that sham surgery consisting of a laminectomy is sufficient to induce transcriptional changes in the spinal cord. This is the first study to provide insight into transcriptional changes in the target region of sprouts investigating the role of the cervical spinal cord (target region) for sprouting of hindlimb CST fibers.

Project description:This study aimed to quantify the regulation of transcripts in the hairy skin of the back of adult rats in the condition of loss of sensory and autonomic (sympathetic) innervation (i.e., denervated). Denervated skin has reduced wound healing capacity, reduced proliferation of epidermal progenitor cells, and also expresses factors that regulate ingrowth of sensory and sympathetic axons from neighboring regions of innervated skin. It was expected that this quantification f transcript regulation would offer insight into the general and specific mechanisms that may contribute to these important biological processes.

Project description:This study aimed to quantify the regulation of transcripts in the hairy skin of the back of adult rats in the condition of loss of sensory and autonomic (sympathetic) innervation (i.e., denervated). Denervated skin has reduced wound healing capacity, reduced proliferation of epidermal progenitor cells, and also expresses factors that regulate ingrowth of sensory and sympathetic axons from neighboring regions of innervated skin. It was expected that this quantification f transcript regulation would offer insight into the general and specific mechanisms that may contribute to these important biological processes. All animals were adult (200-250g) Sprague-Dawley female rats. Three conditions were examined. Groups were naive (n=6), 7-day denervated skin (n=5), and 14-day (n=5) denervated skin. Denervation preparations: Full-thickness incision along long-axis of the body 1cm to right of midline (to avoid injuring skin to be sampled). Incision was centered rostro-caudally on the T13 (thoracic 13) costo-vertebral angle so as to allow access to the T9-L2 (lumbar 2) cutaneous nerves. Skin was reflected to the left and the left T9, T10, L1, and L2 dorsal and lateral cutaneous nerves were isolated, ligated with 7-0 monofilament suture close to their exit from the body wall, and transected. Approximately 5mm of the distal portion of the nerve was resected. The T11 nerves were left unperturbed and were not isolated from the surrounding fascia. This generated two strips of skin that were devoid of sensory and autonomic innervation (those strips served by the T9 and T10 nerves, and by the L1 and L2 nerves). Between these denervated strips of skin was a strip of skin that retained the sensory and autonomic axons supplied by T11 nerves. The denervated zones were identified by mapping the cutaneous trunk muscle (CTM) reflex (see Petruska-JC et al. (2013) Journal of Comparative Neurology; Diamond-J et al., (1992) J Neuroscience), and the border marked with pen and remarked every few days. The samples were taken from the rostral (T9/10) denervated zone. Samples from naive animals (no denervation) were taken from the same region, using the dorsal cutaneous nerves as registration landmarks. Animals displayed no signs of overgrooming of the denervated skin. Because the CTM inserts onto the dermis of this region of skin, samples necessarily include both skin and underlying CTM (which is innervated from another source so was not denervated in the experiment).

Project description:Role of GDF10 for axonal sprouting and functional recovery after stroke

Project description:In familial forms of amyotrophic lateral sclerosis (ALS) caused by mutations in superoxide dismutase-1 (SOD1) gene, both cell-autonomous and non-cell-autonomous mechanisms lead to the selective degeneration of motoneurons. Gene-targeted deletion of mutated SOD1 in mature astrocytes has been shown to slow down disease progression. However, the potential therapeutic application of targeting astrocytes has not been evaluated yet. Here, an AAV vector encoding an artificial microRNA is used to deliver RNA interference against mutated SOD1 by targeting astrocytes in ALS mice. In mice expressing the mutated SOD1G93A protein, we found that the treatment leads to the progressive rescue of neuromuscular junction occupancy, to the recovery of the compound muscle action potential in the gastrocnemius muscle, and significantly improves neuromuscular function. In the spinal cord, gene therapy targeting astrocytes protects a small pool of fast-fatigable motoneurons until disease end stage. In the gastrocnemius muscle of the treated SOD1G93A mice, the fast-twitch type IIb muscle fibers are preserved from atrophy. Axon collateral sprouting is observed together with muscle fiber type grouping indicative of denervation/re-innervation events. The transcriptome profiling of spinal cord motoneurons shows changes in the expression levels of factors regulating the dynamics of microtubules. Gene therapy delivering RNA interference against mutated SOD1 in astrocytes provides therapeutic effects enhancing motoneuron plasticity and improving neuromuscular function in ALS mice.

Project description:Treatments that stimulate neuronal excitability enhance motor performance after stroke.cAMP-response-element binding protein (CREB) is a transcription factor that plays a key rolein neuronal excitability. Increasing the levels of CREB with a viral vector in a small pool ofmotor neurons enhances motor recovery after stroke, while blocking CREB signaling preventsstroke recovery. Silencing CREB-transfected neurons in the peri-infarct region with thehM4di-DREADD blocks motor recovery. Reversing this inhibition allows recovery to continue,demonstrating that it is possible to turn off and on stroke recovery by manipulating theactivity of CREB-transfected neurons. CREB transfection enhances re-mapping of injuredsomatosensory and motor circuits, and induces the formation of new connections withinthese circuits. CREB is a central molecular node in the circuit responses after stroke that leadto recovery from motor deficits.