Project description:The characteristics of electrical signals-mediated neural circuits reconstruction remain poorly understood. We initially developed a spinal-muscle synergistic bidirectional electrical stimulation (SBES) protocol to mimic feedforward and feedback electrical signals in spinal sensorimotor circuits. The results indicate that sensorimotor circuits could be precisely reassembled in structure and function levels by 10-20 Hz SBES. To gain mechanistic insights into the reassembly of the spinal sensorimotor circuits with 10-20 Hz SBES, we performed gene expression profiling analysis in motoneurons. Gene ontology (GO) analysis showed that one group of GO terms accounted for a large fraction of the upregulated transcripts. This group includes axon growth-related cellular functions, such as cell adhesion, regulation of cell growth, and cell projection assembly. Statistical analysis of the Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways revealed sixteen signaling pathways were involved, two of which were related to the regulation of axonal regeneration (PI3K-Akt signaling pathway and cAMP signaling pathway). This study provides insights into neural signal decoding during spinal sensorimotor circuit reconstruction.

Project description:Mammalian motor circuits control voluntary movements by transmitting signals from the central nervous system (CNS) to muscle targets. To form these circuits, motor neurons (MNs) must extend their axons out of the CNS. Although motor axon exit from the CNS is an indispensable phase of motor axon pathfinding, the underlying molecular mechanisms remain obscure. Here, we present the first identification of a genetic pathway that regulates motor axon exit from the vertebrate spinal cord, utilizing spinal accessory motor neurons (SACMN) as a model system. SACMN are a homogeneous population of spinal MNs whose axons leave the CNS through a discrete lateral exit point (LEP) and can be visualized by the expression of the cell surface protein, BEN. We show that the homeodomain transcription factor, Nkx2.9, is selectively required for SACMN axon exit and identify the Robo2 guidance receptor as a likely downstream effector of Nkx2.9; loss of Nkx2.9 leads to a reduction in Robo2 mRNA and protein within SACMN and SACMN axons fail to exit the spinal cord in Robo2-deficient mice. Consistent with short-range interactions between Robo2 and Slit ligands regulating SACMN axon exit, Robo2-expressing SACMN axons normally navigate through LEP-associated Slits as they emerge from the spinal cord, and fail to exit in Slit-deficient mice. Our studies support the view that Nkx2.9 controls SACMN axon exit from the mammalian spinal cord by regulating Robo-Slit signaling. We utilized microarray technology to identify novel downstream effectors of the homeodomain transcription factor, Nkx2.9, that regulate spinal accessory motor neuron development.

Project description:Electrical stimulation can augment or modify neuronal function and can have therapeutic benefits for certain neurological disorders. There is evidence that enhancing spinal excitability with either epidural or transcutaneous stimulation can restore some volitional motor output after spinal cord injury (SCI). Lumbosacral epidural stimulation temporarily improves locomotor and autonomic function in both rodents and humans with SCI. When combined with overground locomotor training enabled by a weight-supporting device, epidural electrical stimulation (EES) promotes extensive reorganization of residual neural pathways that improves locomotion after stopping stimulation. However, the exact mechanism underlying the reconstruction of spinal cord neural circuits with electrical stimulation is not yet known. Thus, we developed a epidural electrical and muscle stimulation(EEMS) system at the interface of the spinal cord and muscle to mimic feedforward and feedback electrical signals in spinal sensorimotor circuits. Using methods of motor function evaluation, neural circuit tracing and neural signal recording, we discovered a unique stimulus frequency of 10-20 Hz under EEMS conditions that was required for structural and functional reconstruction of spinal sensorimotor circuits. Single-cell transcriptome analysis of EEMS activated motoneurons characterized molecular networks involved in spinal sensorimotor circuit reconstruction. This study provides insights into neural signal decoding during spinal sensorimotor circuit reconstruction, and indicates a technological approach for the clinical treatment of SCI.

Project description:We performed micrarrays to investigate neuronal gene expression changes during acute inflammatory CNS axon injury using the murine myelin oligodendrocyte glycoprotein 35-55 (MOG35-55)-induced experimental autoimmune encephalomyelitis (EAE) model. The present study was assigned to assess the direct and indirect endogenous neuronal response to spinal axonal injury in the motor and sensory cortex. Gene expression in motor and sensory cortex enriched tissue was assessed from four healthy and six EAE female mice. Tissue was collected from mice with paraplegia or monoplegia, with contralateral hindlimb paresis (EAE day 18-21). The gene expression profiles of the EAE mice were compared to the motor or sensory cortex of healthy control mice, resulting in a list of differentially expressed genes in healthy and EAE mice.

Project description:The spinal cord contains neural networks that enable regionally-distinct motor outputs along the body axis. Nevertheless, it remains unclear how segment-specific motor computations are processed because the cardinal interneuron classes that control motor neurons appear uniform at each level of the spinal cord. V2a interneurons are essential to both fore and hindlimb movements and here we identified two major types that emerge during development: Type-I neurons marked by high Chx10 form recurrent networks with neighboring spinal neurons, and Type-II that downregulate Chx10 and project to supraspinal structures. Type-I and -II V2a interneurons are arrayed in counter-gradients and this network activates different patterns of motor output at cervical and lumbar levels. Single cell RNA-seq revealed Type-I and -II V2a neurons are each comprised of multiple subtypes. Our findings uncover a molecular and anatomical organization of V2a interneurons reminiscent of the orderly way motor neurons are divided into columns and pools.

Project description:The spinal cord contains neural networks that enable regionally-distinct motor outputs along the body axis. Nevertheless, it remains unclear how segment-specific motor computations are processed because the cardinal interneuron classes that control motor neurons appear uniform at each level of the spinal cord. V2a interneurons are essential to both fore and hindlimb movements and here we identified two major types that emerge during development: Type-I neurons marked by high Chx10 form recurrent networks with neighboring spinal neurons, and Type-II that downregulate Chx10 and project to supraspinal structures. Type-I and -II V2a interneurons are arrayed in counter-gradients and this network activates different patterns of motor output at cervical and lumbar levels. Single cell RNA-seq revealed Type-I and -II V2a neurons are each comprised of multiple subtypes. Our findings uncover a molecular and anatomical organization of V2a interneurons reminiscent of the orderly way motor neurons are divided into columns and pools.

Project description:Spinal motor atrophy mice (SMN delta 7 mice) and wild-type control hindlimb skeletal muscle tissue was used for transcriptome profiling by mRNA-seq.

Project description:Mammalian motor circuits control voluntary movements by transmitting signals from the central nervous system (CNS) to muscle targets. To form these circuits, motor neurons (MNs) must extend their axons out of the CNS. Although motor axon exit from the CNS is an indispensable phase of motor axon pathfinding, the underlying molecular mechanisms remain obscure. Here, we present the first identification of a genetic pathway that regulates motor axon exit from the vertebrate spinal cord, utilizing spinal accessory motor neurons (SACMN) as a model system. SACMN are a homogeneous population of spinal MNs whose axons leave the CNS through a discrete lateral exit point (LEP) and can be visualized by the expression of the cell surface protein, BEN. We show that the homeodomain transcription factor, Nkx2.9, is selectively required for SACMN axon exit and identify the Robo2 guidance receptor as a likely downstream effector of Nkx2.9; loss of Nkx2.9 leads to a reduction in Robo2 mRNA and protein within SACMN and SACMN axons fail to exit the spinal cord in Robo2-deficient mice. Consistent with short-range interactions between Robo2 and Slit ligands regulating SACMN axon exit, Robo2-expressing SACMN axons normally navigate through LEP-associated Slits as they emerge from the spinal cord, and fail to exit in Slit-deficient mice. Our studies support the view that Nkx2.9 controls SACMN axon exit from the mammalian spinal cord by regulating Robo-Slit signaling.

Project description:Gene expression analysis of motor cortex after spinal C3 lesion Dorsal column wire knife lesions: Adult female Fischer 344 rats weighing 150-200 gm were used. Animals underwent a laminectomy at spinal level C3. Dorsal funiculus lesions were made in the middle of C3 using a Kopf microwire device (Kopf Instruments, Tujunga, CA). After fixation in a spinal stereotaxic unit, a small dural incision was made. The wire knife was lowered into the spinal cord to a depth of 1.1 mm ventral to the dorsal cord surface and 1.1 mm to the left of the midline. The tip of the wireknife was extruded, forming a 2.25 mm-wide arc that was raised to the dorsal surface of the cord. To ensure complete axotomy of the dorsal funiculus, spinal tissue was compressed against the microwire knife surface using a microaspiration pipette until all visible white matter was transected. Cortical microdissection: The forelimb and hindlimb motor cortex were microdisected from rat cortices: Rostral to Bregma: an area from 2.0 to 4.5 mm mediolateral and from 0 to 2 mm anterior-posterior Caudal to Bregma: an area from 2.0 to 3.5 mediolateral and from 0 to 3 mm caudal to Bregma. Only the inferior half of the cortex containing layer V corticospinal motor neurons was sampled in each region.

Project description:To probe molecular distinctions in the specification of motor neurons innervating digit muscles we performed a screen for genetic markers that distinguish digit innervating motor neurons from other motor pools. Here, we compare the gene expression profiles of motor neurons that supply muscles with defined biomechanical functions.