Project description:Brain and spinal injury often impair sensorimotor processing in the spinal cord and reduce mobility. Cortical stroke in rats leads to long-term deficits in dexterity and walking. Subcutaneous neurotrophin-3 infusion initiated at a clinically-feasible time-point after injury improved walking and dexterity. We discovered that Neurotrophin-3 is transported in sensory afferents from muscles to the dorsal root ganglia. Using genome-wide RNA sequencing of the whole cervical level 6-8 dorsal root ganglia, we sought gene changes in afferent neurons that were present at two timepoints after stroke.

Project description:To elicit a dystonia-like phenotype in a genetically predisposed DYT-TOR1A mouse model (DYT1KI) by performing a right sciatic nerve crush injury. To identify novel pathophysiological pathways and possible biomarker, we performed a multi-omic analysis of three dystonia-relevant brain regions

Project description:To elicit a dystonia-like phenotype in a genetically predisposed DYT-TOR1A mouse model (DYT1KI) by performing a right sciatic nerve crush injury. To identify novel pathophysiological pathways and possible biomarker, we performed a multi-omic analysis of three dystonia-relevant brain regions

Project description:The flexibility of motor actions is ingrained in the diversity of neurons and how they are organized into functional circuit modules, yet our knowledge of the molecular underpinning of motor circuit modularity remains limited. Locomotion is a motor behavior characterized by sudden changes in speed and strength enabled by the coordinated recruitment of different motoneuron subtypes. Here we use adult zebrafish to link the molecular diversity of motoneurons and the rhythm-generating V2a interneurons with their modular circuit organization that is responsible for changes in locomotor speed. We show that the molecular diversity of motoneurons and V2a interneurons reflects their functional segregation into slow, intermediate or fast subtypes. Furthermore, we reveal shared molecular signatures between V2a interneurons and motoneurons of the three speed circuit modules. Overall, by characterizing how the molecular diversity of motoneurons and V2a interneurons relates to their function, connectivity and behavior, our study provides important insights not only into the molecular mechanisms for neuronal and circuit diversity for locomotor flexibility but also for charting circuits for motor actions in general.

Project description:DYT-TOR1A dystonia is a movement disorder characterized by involuntary muscle contractions. Despite being the most common monogenetic form of dystonia, its pathophysiolofy remains unclear. With a reduced penetrance of about 30%, there is a suggestion that extragenetic factors are needed to develeop a dystonic phenotype. In the present study, we induced a sciatic nerve crush injury in a genetically predisposed DYT-TOR1A mouse model (DYT1KI) to evoke a dystonic phenotype. Subsequently, we employed a multi-omic approach to uncover novel pathophysiological pathways associated with DYT-TOR1A dystonia. Utilizing a deep-learning-based characterization of the dystonic phenotype, we observed that nerve-injured DYT1KI animals exhibited significantly more dystonia-like movement (DLM) compared to naive DYT1KI animals, with noticeable effects as early as two weeks post-surgery. Moreover, nerve-injured DT1KI mice displayed significantly more DLM than their wildtype (wt) counterparts starting 6 weeks post-injury. In the cerebellum of nerve-injured wt mice, multi-omice analysis indicated regulatory changes in translation-related processes, a phenomenon not observed in the cerebellum of nerve-injured DYT1KI mice; instead, these changes were localized to the cortex and striatum. Our findings suggest a failure of translational compensatory mechanisms in the cerebellum of phenotypic DY1KI mice displaying DLM, while dysregulations in translation in the cortex and striatum likely contribute to the promotion of the dystonic phenotype.

Project description:Dystonia Consortium TOR1A Exon 5 Screening

Project description:Dystonia Consortium TOR1A Exon 5 Screening

Project description:Astrocytes, the most abundant cells in the central nervous system, promote synapse formation and help refine neural connectivity. Although they are allocated to spatially distinct regional domains during development, it is unknown whether region-restricted astrocytes are functionally heterogeneous. Here we show that postnatal spinal cord astrocytes express several region-specific genes, and that ventral astrocyte-encoded Semaphorin3a (Sema3a) is required for proper motor neuron and sensory neuron circuit organization. Loss of astrocyte-encoded Sema3a led to dysregulated α−motor neuron axon initial segment orientation, markedly abnormal synaptic inputs, and selective death of α−but not of adjacent γ−motor neurons. Additionally, a subset of TrkA+ sensory afferents projected to ectopic ventral positions. These findings demonstrate that stable maintenance of a positional cue by developing astrocytes influences multiple aspects of sensorimotor circuit formation. More generally, they suggest that regional astrocyte heterogeneity may help to coordinate postnatal neural circuit refinement. 12 total samples consisting of three biological replicates each of flow sorted postnatal day 7 dorsal spinal cord astrocytes, ventral spinal cord astrocytes, dorsal SC non astrocytes, and ventral SC non astrocytes

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:Experience-dependent plasticity of synapses modulates information processing in neural circuits and is essential for cognitive functions. Genomic enhancers are thought to modulate specific sets of synapses by regulating experience-induced transcription to thereby promote neural circuit plasticity. However, this idea remains untested. Thus, here we analyze the cellular and circuit functions of the genomic mechanisms that control the experience-induced transcription of Igf1 (Insulin-like growth factor 1) in disinhibitory VIP interneurons in the adult visual cortex. We find that two sensory-induced enhancers selectively and cooperatively drive sensory-induced Igf1 transcription and that these enhancers homeostatically control the ratio between excitation and inhibition (E/I-ratio) and neural activity in VIP interneurons to thereby restrict visual acuity. Thus, single experience-regulated enhancers are essential for maintaining sensory processing. Since cortical plasticity scales with neural activity in VIP interneurons, this also suggests that experience-induced transcription restricts plasticity in adult neural circuits to preserve the brain’s functional integrity.