Your search keyword '"Spinal Cord cytology"' showing total 10,717 results

1. Structural characteristics and regenerative potential: Insights from the molly fish spinal cord.

Author

Awad M, Sayed RKA, Mohammadin D, Hussein MM, and Mokhtar DM

Subjects

Animals, Spinal Cord Regeneration physiology, Microscopy, Neurons physiology, Spinal Cord physiology, Spinal Cord cytology, Astrocytes physiology, Oligodendroglia physiology, Oligodendroglia cytology

Abstract

Unlike mammals, species such as fish and amphibians can regenerate damaged spinal cords, offering insights into potential therapeutic targets. This study investigates the structural features of the molly fish spinal cord through light and electron microscopy. The most notable characteristic was the presence of Mauthner cells (M-cells), which exhibited large cell bodies and processes, as well as synaptic connections with astrocytes. These astrocytic connections contained synaptic vesicles, suggesting electrical transmission at the M-cell endings. Astrocytes, which were labeled with glial fibrillary acidic protein (GFAP), contained cytoplasmic glycogen granules, potentially serving as an emergency fuel source. Two types of oligodendrocytes were identified: a small, dark cell and a larger, lighter cell, both of which reacted strongly with oligodendrocyte transcription factor 2 (Olig2). The dark oligodendrocyte resembled human oligodendrocyte precursors, while the light oligodendrocyte was similar to mature human oligodendrocytes. Additionally, proliferative neurons in the substantia grisea centralis expressed myostatin, Nrf2, and Sox9. Collectively, these findings suggest that the molly fish spinal cord has advanced structural features conducive to spinal cord regeneration and could serve as an excellent model for studying central nervous system regeneration. Further studies on the functional aspects of the molly fish spinal cord are recommended. RESEARCH HIGHLIGHTS: Mauthner cells (M-cell), with their typical large cell body and processes, were the most characteristic feature in Molly fish spinal cord, where it presented synaptic connections with astrocytes and their ends contained synaptic vesicles indicating an electrical transmission in the M-cells endings. Two types of oligodendrocytes could be recognized; both reacted intensely with Oligodendrocyte transcription factor 2 (Olig2). The proliferative neurons of the substantia grisea centralis expressed myostatin, Nrf2, and Sox9. The findings of this study suggest that molly fish possess highly developed structural features conducive to spinal cord regeneration. Consequently, they could be deemed an exemplary model for investigating central nervous system regeneration., (© 2024 Wiley Periodicals LLC.)

Published

2024

2. A NSC-34 cell line-derived spheroid model: Potential and challenges for in vitro evaluation of neurodegeneration.

Author

Arnaldi P, Casarotto E, Relucenti M, Bellese G, Gagliani MC, Crippa V, Castagnola P, and Cortese K

Subjects

Animals, Mice, Cell Line, Motor Neurons pathology, Cell Survival, Neurodegenerative Diseases pathology, Cell Culture Techniques methods, Spinal Cord cytology, Spinal Cord pathology, Hydrogels chemistry, Humans, Mitochondria metabolism, Spheroids, Cellular pathology, DNA-Binding Proteins metabolism, Amyotrophic Lateral Sclerosis pathology, Amyotrophic Lateral Sclerosis metabolism

Abstract

Three-dimensional (3D) spheroid models aim to bridge the gap between traditional two-dimensional (2D) cultures and the complex in vivo tissue environment. These models, created by self-clustering cells to mimic a 3D environment with surrounding extracellular framework, provide a valuable research tool. The NSC-34 cell line, generated by fusing mouse spinal cord motor neurons and neuroblastoma cells, is essential for studying neurodegenerative diseases like amyotrophic lateral sclerosis (ALS), where abnormal protein accumulation, such as TAR-DNA-binding protein 43 (TDP-43), occurs in affected nerve cells. However, NSC-34 behavior in a 3D context remains underexplored, and this study represents the first attempt to create a 3D model to determine its suitability for studying pathology. We generated NSC-34 spheroids using a nonadhesive hydrogel-based template and characterized them for 6 days. Light microscopy revealed that NSC-34 cells in 3D maintained high viability, a distinct round shape, and forming stable membrane connections. Scanning electron microscopy identified multiple tunnel-like structures, while ultrastructural analysis highlighted nuclear bending and mitochondria alterations. Using inducible GFP-TDP-43-expressing NSC-34 spheroids, we explored whether 3D structure affected TDP-43 expression, localization, and aggregation. Spheroids displayed nuclear GFP-TDP-43 expression, albeit at a reduced level compared with 2D cultures and generated both TDP-35 fragments and TDP-43 aggregates. This study sheds light on the distinctive behavior of NSC-34 in 3D culture, suggesting caution in the use of the 3D model for ALS or TDP-43 pathologies. Yet, it underscores the spheroids' potential for investigating fundamental cellular mechanisms, cell adaptation in a 3D context, future bioreactor applications, and drug penetration studies. RESEARCH HIGHLIGHTS: 3D spheroid generation: NSC-34 spheroids, developed using a hydrogel-based template, showed high viability and distinct shapes for 6 days. Structural features: advanced microscopy identified tunnel-like structures and nuclear and mitochondrial changes in the spheroids. Protein dynamics: the study observed how 3D structures impact TDP-43 behavior, with altered expression but similar aggregation patterns to 2D cultures. Research implications: this study reveals the unique behavior of NSC-34 in 3D culture, suggests a careful approach to use this model for ALS or TDP-43 pathologies, and highlights its potential in cellular mechanism research and drug testing applications., (© 2024 Wiley Periodicals LLC.)

Published

2024

3. Atp13a5 Marker Reveals Pericyte Specification in the Mouse Central Nervous System.

Author

Guo X, Xia S, Ge T, Lin Y, Hu S, Wu H, Xie X, Zhang B, Zhang S, Zeng J, Chen JF, Montagne A, Gao F, Ma Q, and Zhao Z

Subjects

Animals, Mice, Spinal Cord metabolism, Spinal Cord cytology, Spinal Cord embryology, Blood-Brain Barrier metabolism, Blood-Brain Barrier cytology, Mice, Inbred C57BL, Male, Biomarkers metabolism, Female, Mice, Transgenic, Brain metabolism, Brain cytology, Brain embryology, Retina metabolism, Retina cytology, Retina embryology, Pericytes metabolism, Central Nervous System metabolism, Central Nervous System cytology, Central Nervous System embryology

Abstract

Perivascular mural cells including vascular smooth cells (VSMCs) and pericytes are integral components of the vascular system. In the central nervous system (CNS), pericytes are also indispensable for the blood-brain barrier (BBB), blood-spinal cord barrier, and blood-retinal barrier and play key roles in maintaining cerebrovascular and neuronal functions. However, the functional specifications of pericytes between CNS and peripheral organs have not been resolved at the genetic and molecular levels. Hence, the generation of reliable CNS pericyte-specific models and genetic tools remains very challenging. Here, we report a new CNS pericyte marker in mice. This putative cation-transporting ATPase 13A5 ( Atp13a5 ) marker was identified through single-cell transcriptomics, based on its specificity to brain pericytes. We further generated a knock-in model with both tdTomato reporter and Cre recombinase. Using this model to trace the distribution of Atp13a5- positive pericytes in mice, we found that the tdTomato reporter reliably labels the CNS pericytes, including the ones in spinal cord and retina but not peripheral organs. Interestingly, brain pericytes are likely shaped by the developing neural environment, as Atp13a5- positive pericytes start to appear around murine embryonic day 15 (E15) and expand along the cerebrovasculature. Thus, Atp13a5 is a specific marker of CNS pericyte lineage, and this Atp13a5- based model is a reliable tool to explore the heterogeneity of pericytes and BBB functions in health and diseases., Competing Interests: The authors declare no competing financial interests., (Copyright © 2024 Guo et al.)

Published

2024

4. Lineage tracing of Shh+ floor plate cells and dynamics of dorsal-ventral gene expression in the regenerating axolotl spinal cord.

Author

Arbanas LI, Cura Costa E, Chara O, Otsuki L, and Tanaka EM

Subjects

Animals, Spinal Cord Regeneration genetics, Spinal Cord Regeneration physiology, Gene Expression Regulation, Developmental, Cell Lineage genetics, Hedgehog Proteins metabolism, Hedgehog Proteins genetics, Ambystoma mexicanum genetics, Spinal Cord metabolism, Spinal Cord cytology, Spinal Cord embryology

Abstract

Both development and regeneration depend on signaling centers, which are sources of locally secreted tissue-patterning molecules. As many signaling centers are decommissioned before the end of embryogenesis, a fundamental question is how signaling centers can be re-induced later in life to promote regeneration after injury. Here, we use the axolotl salamander model (Ambystoma mexicanum) to address how the floor plate is assembled for spinal cord regeneration. The floor plate is an archetypal vertebrate signaling center that secretes Shh ligand and patterns neural progenitor cells during embryogenesis. Unlike mammals, axolotls continue to express floor plate genes (including Shh) and downstream dorsal-ventral patterning genes in their spinal cord throughout life, including at steady state. The parsimonious hypothesis that Shh+ cells give rise to functional floor plate cells for regeneration had not been tested. Using HCR in situ hybridization and mathematical modeling, we first quantified the behaviors of dorsal-ventral spinal cord domains, identifying significant increases in gene expression level and floor plate size during regeneration. Next, we established a transgenic axolotl to specifically label and fate map Shh+ cells in vivo. We found that labeled Shh+ cells gave rise to regeneration floor plate, and not to other neural progenitor domains, after tail amputation. Thus, despite changes in domain size and downstream patterning gene expression, Shh+ cells retain their floor plate identity during regeneration, acting as a stable cellular source for this regeneration signaling center in the axolotl spinal cord., (© 2024 The Author(s). Development, Growth & Differentiation published by John Wiley & Sons Australia, Ltd on behalf of Japanese Society of Developmental Biologists.)

Published

2024

5. Inter-Strain Differences in the Lumbar Spinal Cord Anatomy and Neuromorphology: Wistar Versus Dark Agouti Rats.

Author

Veshchitskii A, Shkorbatova P, Efimova E, and Merkulyeva N

Subjects

Animals, Rats, Male, Neurons cytology, Neurons metabolism, Lumbar Vertebrae anatomy & histology, Spinal Cord cytology, Spinal Cord anatomy & histology, Rats, Wistar, Species Specificity

Abstract

Rat strains differ in physiology, behavior, and recovery after central nervous system injury. To assess these differences, we compared the gross and local anatomy and neuromorphology of the lumbar spinal cord of the Wistar and Dark Agouti (DA) strains. The key findings include (i) distinct spatial relationships between vertebrae and spinal segments in the two strains; (ii) Wistar rats have larger volumes of spinal cord gray and white matter; (iii) DA rats have smaller total neuronal populations, thus indicating an expectation of smaller local neuronal populations; (iv) this expectation was confirmed for interneurons expressing calbindin 28 kDa. But contrary to expectations, (v) DA rats had more numerous populations of the interneurons expressing parvalbumin and a population of α-motoneurons. Consequently, these strains displayed divergent ratios in specific spinal neuronal populations. Researchers should consider these inter-strain differences when comparing data across different strains., (© 2024 Wiley Periodicals LLC.)

Published

2024

6. Neural circuit mechanisms underlying context-specific halting in Drosophila.

Author

Sapkal N, Mancini N, Kumar DS, Spiller N, Murakami K, Vitelli G, Bargeron B, Maier K, Eichler K, Jefferis GSXE, Shiu PK, Sterne GR, and Bidaye SS

Subjects

Animals, Female, Cholinergic Neurons physiology, Feeding Behavior physiology, GABAergic Neurons physiology, Grooming physiology, Models, Neurological, Spinal Cord cytology, Spinal Cord physiology, Brain physiology, Brain cytology, Connectome, Drosophila melanogaster cytology, Drosophila melanogaster physiology, Neural Pathways cytology, Neural Pathways physiology, Walking physiology

Abstract

Walking is a complex motor programme involving coordinated and distributed activity across the brain and the spinal cord. Halting appropriately at the correct time is a critical component of walking control. Despite progress in identifying neurons driving halting 1-6 , the underlying neural circuit mechanisms responsible for overruling the competing walking state remain unclear. Here, using connectome-informed models 7-9 and functional studies, we explain two fundamental mechanisms by which Drosophila implement context-appropriate halting. The first mechanism ('walk-OFF') relies on GABAergic neurons that inhibit specific descending walking commands in the brain, whereas the second mechanism ('brake') relies on excitatory cholinergic neurons in the nerve cord that lead to an active arrest of stepping movements. We show that two neurons that deploy the walk-OFF mechanism inhibit distinct populations of walking-promotion neurons, leading to differential halting of forward walking or turning. The brake neurons, by constrast, override all walking commands by simultaneously inhibiting descending walking-promotion neurons and increasing the resistance at the leg joints. We characterized two behavioural contexts in which the distinct halting mechanisms were used by the animal in a mutually exclusive manner: the walk-OFF mechanism was engaged for halting during feeding and the brake mechanism was engaged for halting and stability during grooming., (© 2024. The Author(s).)

Published

2024

7. Endogenous opioid signalling regulates spinal ependymal cell proliferation.

Author

Yue WWS, Touhara KK, Toma K, Duan X, and Julius D

Subjects

Animals, Female, Male, Mice, Mice, Inbred C57BL, Motor Skills drug effects, Neurons metabolism, Neurons drug effects, Paracrine Communication drug effects, Protein Precursors metabolism, Receptors, Opioid, kappa metabolism, Cerebrospinal Fluid metabolism, Cell Proliferation drug effects, Cicatrix drug therapy, Cicatrix etiology, Cicatrix metabolism, Cicatrix pathology, Ependyma cytology, Ependyma drug effects, Ependyma metabolism, Opioid Peptides agonists, Opioid Peptides antagonists & inhibitors, Opioid Peptides metabolism, Signal Transduction drug effects, Spinal Cord cytology, Spinal Cord drug effects, Spinal Cord metabolism, Spinal Cord pathology, Spinal Cord Injuries complications, Spinal Cord Injuries metabolism, Spinal Cord Injuries pathology

Abstract

After injury, mammalian spinal cords develop scars to confine the lesion and prevent further damage. However, excessive scarring can hinder neural regeneration and functional recovery 1,2 . These competing actions underscore the importance of developing therapeutic strategies to dynamically modulate scar progression. Previous research on scarring has primarily focused on astrocytes, but recent evidence has suggested that ependymal cells also participate. Ependymal cells normally form the epithelial layer encasing the central canal, but they undergo massive proliferation and differentiation into astroglia following certain injuries, becoming a core scar component 3-7 . However, the mechanisms regulating ependymal proliferation in vivo remain unclear. Here we uncover an endogenous κ-opioid signalling pathway that controls ependymal proliferation. Specifically, we detect expression of the κ-opioid receptor, OPRK1, in a functionally under-characterized cell type known as cerebrospinal fluid-contacting neuron (CSF-cN). We also discover a neighbouring cell population that expresses the cognate ligand prodynorphin (PDYN). Whereas κ-opioids are typically considered inhibitory, they excite CSF-cNs to inhibit ependymal proliferation. Systemic administration of a κ-antagonist enhances ependymal proliferation in uninjured spinal cords in a CSF-cN-dependent manner. Moreover, a κ-agonist impairs ependymal proliferation, scar formation and motor function following injury. Together, our data suggest a paracrine signalling pathway in which PDYN + cells tonically release κ-opioids to stimulate CSF-cNs and suppress ependymal proliferation, revealing an endogenous mechanism and potential pharmacological strategy for modulating scarring after spinal cord injury., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

8. A human-specific progenitor sub-domain extends neurogenesis and increases motor neuron production.

Author

Jang S, Gumnit E, and Wichterle H

Subjects

Humans, Animals, Mice, Forkhead Transcription Factors metabolism, Forkhead Transcription Factors genetics, Zebrafish Proteins metabolism, Zebrafish Proteins genetics, Repressor Proteins metabolism, Repressor Proteins genetics, Cell Differentiation physiology, Homeodomain Proteins metabolism, Homeodomain Proteins genetics, Spinal Cord cytology, Gene Expression Regulation, Developmental, Nuclear Proteins metabolism, Nuclear Proteins genetics, Basic Helix-Loop-Helix Transcription Factors metabolism, Basic Helix-Loop-Helix Transcription Factors genetics, Motor Neurons physiology, Motor Neurons metabolism, Neurogenesis physiology, Homeobox Protein Nkx-2.2, Transcription Factors metabolism, Transcription Factors genetics, Oligodendrocyte Transcription Factor 2 metabolism, Neural Stem Cells metabolism, Neural Stem Cells physiology, Neural Stem Cells cytology

Abstract

Neurogenesis lasts ~10 times longer in developing humans compared to mice, resulting in a >1,000-fold increase in the number of neurons in the CNS. To identify molecular and cellular mechanisms contributing to this difference, we studied human and mouse motor neurogenesis using a stem cell differentiation system that recapitulates species-specific scales of development. Comparison of human and mouse single-cell gene expression data identified human-specific progenitors characterized by coexpression of NKX2-2 and OLIG2 that give rise to spinal motor neurons. Unlike classical OLIG2 + motor neuron progenitors that give rise to two motor neurons each, OLIG2 + /NKX2-2 + ventral motor neuron progenitors remain cycling longer, yielding ~5 times more motor neurons that are biased toward later-born, FOXP1-expressing subtypes. Knockout of NKX2-2 converts ventral motor neuron progenitors into classical motor neuron progenitors. Such new progenitors may contribute to the increased production of human motor neurons required for the generation of larger, more complex nervous systems., (© 2024. The Author(s), under exclusive licence to Springer Nature America, Inc.)

Published

2024

9. Development and characterization of primary cell culture from the spinal cord of Asian seabass, Lates calcarifer.

Author

Mithra S, Abdul Majeed S, Taju G, Vimal S, and Sahul Hameed AS

Subjects

Animals, Bass virology, Nodaviridae, Neurons cytology, Neurons virology, Cryopreservation, Cells, Cultured, Spinal Cord cytology, Primary Cell Culture methods

Abstract

Asian seabass, Lates calcarifer, is one of the most important fish species in aquaculture. An attempt was made to develop a primary cell culture from the spinal cord of Lates calcarifer by the enzymatic and mechanical dissociation method. The primary cell culture was sub-cultured for 20 times in Leibovitz's L-15 medium with 20% fetal bovine serum (FBS) and 0.5 nM of human neurotrophin-3 at 28°C. The primary cell culture was cryopreserved at different passage levels and recovery of cells after long-term storage was estimated about 75-85%. The authenticity of origin of primary cell culture from L. calcarifer was confirmed by polymerase chain reaction assay using species-specific mitochondrial 12S rRNA primer. The primary cell culture was designated as seabass spinal cord cells (SBSC). The cells morphologically resembled the neurons due to their neural-like prolongations and star-like structure. Immunophenotypic analysis of the SBSC revealed that they are of neuronal origin. The SBSC were found to be highly susceptible to striped jack nervous necrosis virus (SJNNV) and infection in the cells was confirmed by RT-PCR. In conclusion, this is the first innovative euryhaline fish neuronal primary cell culture of L. calcarifer now available for neurophysiological and neurotoxicological studies., (© 2024. The Society for In Vitro Biology.)

Published

2024

10. Exploring the Therapeutic Potential of Mesenchymal Stem Cells-derived conditioned medium: An In-depth Analysis of Pain Alleviation, Spinal CCL2 Levels, and Oxidative Stress.

Author

Jaleh Z, Rahimi B, Shahrezaei A, Sohani M, Sagen J, and Nasirinezhad F

Subjects

Animals, Culture Media, Conditioned pharmacology, Rats, Male, Hyperalgesia therapy, Hyperalgesia metabolism, Sciatic Nerve injuries, Amniotic Fluid cytology, Oxidative Stress, Mesenchymal Stem Cells cytology, Mesenchymal Stem Cells metabolism, Rats, Wistar, Chemokine CCL2 metabolism, Neuralgia therapy, Neuralgia metabolism, Spinal Cord metabolism, Spinal Cord cytology

Abstract

Neuropathic pain, a debilitating condition, remains a significant challenge due to the lack of effective therapeutic solutions. This study aimed to evaluate the potential of mesenchymal stromal cell (MSC)-derived conditioned medium in alleviating neuropathic pain induced by sciatic nerve compression injury in adult male rats. Forty Wistar rats were randomly assigned to four groups: control, nerve injury, nerve injury with intra-neural injection of conditioned medium, and nerve injury with intra-neural injection of culture medium. Following sciatic nerve compression, the respective groups received either 10 µl of conditioned medium from amniotic fluid-derived stem cells or an equal volume of control culture medium. Behavioral tests for cold allodynia, mechanical allodynia, and thermal hyperalgesia were conducted, and the spinal cord was analyzed using Western Blot and oxidative stress assays. The behavioral experiments showed a decrease in mechanical hyperalgesia and cold allodynia in the group receiving conditioned medium compared to the injury group and the control medium group. Western blot data revealed a decrease in the expression of the CCL2 protein and an increase in GAD65. Oxidative stress tests also showed increased levels of SOD and glutathione in conditioned media-treated animals compared to animals with nerve injury. The findings suggest that conditioned medium derived from amniotic fluid-derived stem cells can effectively reduce neuropathic pain, potentially through the provision of supportive factors that mitigate oxidative stress and inflammation in the spinal cord., (© 2024. The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2024

11. Folate-mediated transgenerational inheritance of sperm DNA methylation patterns correlate with spinal axon regeneration.

Author

Madrid A, Koueik J, Papale LA, Chebel R, Renteria I, Cannon E, Hogan KJ, Alisch RS, and Iskandar BJ

Subjects

Animals, Male, Mice, Spinal Cord Injuries genetics, Spinal Cord Injuries metabolism, CpG Islands, Female, Nerve Regeneration drug effects, Epigenesis, Genetic, Spinal Cord metabolism, Spinal Cord drug effects, Spinal Cord cytology, DNA Methylation, Folic Acid pharmacology, Folic Acid administration & dosage, Spermatozoa drug effects, Spermatozoa metabolism, Axons metabolism, Axons drug effects

Abstract

In mammals, the molecular mechanisms underlying transgenerational inheritance of phenotypic traits in serial generations of progeny after ancestral environmental exposures, without variation in DNA sequence, remain elusive. We've recently described transmission of a beneficial trait in rats and mice, in which F0 supplementation of methyl donors, including folic acid, generates enhanced axon regeneration after sharp spinal cord injury in untreated F1 to F3 progeny linked to differential DNA methylation levels in spinal cord tissue. To test whether the transgenerational effect of folic acid is transmitted via the germline, we performed whole-genome methylation sequencing on sperm DNA from F0 mice treated with either folic acid or vehicle control, and their F1, F2, and F3 untreated progeny. Transgenerational differentially methylated regions (DMRs) are observed in each consecutive generation and distinguish folic acid from untreated lineages, predominate outside of CpG islands and in regions of the genome that regulate gene expression, including promoters, and overlap at both the differentially methylated position (DMP) and gene levels. These findings indicate that molecular changes between generations are caused by ancestral folate supplementation. In addition, 29,719 DMPs exhibit serial increases or decreases in DNA methylation levels in successive generations of untreated offspring, correlating with a serial increase in the phenotype across generations, consistent with a 'wash-in' effect. Sibship-specific DMPs annotate to genes that participate in axon- and synapse-related pathways.

Published

2024

12. Axonal Growth and Fasciculation of Spinal Neurons Promoted by Aldynoglia in Alkaline Fibrin Hydrogel: Influence of Tol-51 Sulfoglycolipid.

Author

Buzoianu-Anguiano V, Arriero-Cabañero A, Fernández-Mayoralas A, Torres-Llacsa M, and Doncel-Pérez E

Subjects

Animals, Hydrogels chemistry, Hydrogels pharmacology, Rats, Glycolipids pharmacology, Neural Stem Cells drug effects, Neural Stem Cells metabolism, Neural Stem Cells cytology, Neurons metabolism, Neurons drug effects, Cells, Cultured, Coculture Techniques, Spinal Cord Injuries metabolism, Spinal Cord Injuries drug therapy, Spinal Cord Injuries pathology, Neuroglia drug effects, Neuroglia metabolism, Astrocytes drug effects, Astrocytes metabolism, Spinal Cord metabolism, Spinal Cord drug effects, Spinal Cord cytology, Cell Movement drug effects, Ganglia, Spinal drug effects, Ganglia, Spinal metabolism, Ganglia, Spinal cytology, Axons metabolism, Axons drug effects, Fibrin metabolism

Abstract

Traumatic spinal cord injury (tSCI) has complex pathophysiological events that begin after the initial trauma. One such event is fibroglial scar formation by fibroblasts and reactive astrocytes. A strong inhibition of axonal growth is caused by the activated astroglial cells as a component of fibroglial scarring through the production of inhibitory molecules, such as chondroitin sulfate proteoglycans or myelin-associated proteins. Here, we used neural precursor cells (aldynoglia) as promoters of axonal growth and a fibrin hydrogel gelled under alkaline conditions to support and guide neuronal cell growth, respectively. We added Tol-51 sulfoglycolipid as a synthetic inhibitor of astrocyte and microglia in order to test its effect on the axonal growth-promoting function of aldynoglia precursor cells. We obtained an increase in GFAP expression corresponding to the expected glial phenotype for aldynoglia cells cultured in alkaline fibrin. In co-cultures of dorsal root ganglia (DRG) and aldynoglia, the axonal growth promotion of DRG neurons by aldynoglia was not affected. We observed that the neural precursor cells first clustered together and then formed niches from which aldynoglia cells grew and connected to groups of adjacent cells. We conclude that the combination of alkaline fibrin with synthetic sulfoglycolipid Tol-51 increased cell adhesion, cell migration, fasciculation, and axonal growth capacity, promoted by aldynoglia cells. There was no negative effect on the behavior of aldynoglia cells after the addition of sulfoglycolipid Tol-51, suggesting that a combination of aldynoglia plus alkaline fibrin and Tol-51 compound could be useful as a therapeutic strategy for tSCI repair.

Published

2024

13. Self-organizing models of human trunk organogenesis recapitulate spinal cord and spine co-morphogenesis.

Author

Gribaudo S, Robert R, van Sambeek B, Mirdass C, Lyubimova A, Bouhali K, Ferent J, Morin X, van Oudenaarden A, and Nedelec S

Subjects

Humans, Models, Biological, Body Patterning genetics, Morphogenesis, Pluripotent Stem Cells cytology, Organoids growth & development, Organoids cytology, Organogenesis, Spinal Cord embryology, Spinal Cord cytology, Spinal Cord growth & development, Cell Differentiation, Spine embryology, Spine growth & development

Abstract

Integrated in vitro models of human organogenesis are needed to elucidate the multi-systemic events underlying development and disease. Here we report the generation of human trunk-like structures that model the co-morphogenesis, patterning and differentiation of the human spine and spinal cord. We identified differentiation conditions for human pluripotent stem cells favoring the formation of an embryo-like extending antero-posterior (AP) axis. Single-cell and spatial transcriptomics show that somitic and spinal cord differentiation trajectories organize along this axis and can self-assemble into a neural tube surrounded by somites upon extracellular matrix addition. Morphogenesis is coupled with AP patterning mechanisms, which results, at later stages of organogenesis, in in vivo-like arrays of neural subtypes along a neural tube surrounded by spine and muscle progenitors contacted by neuronal projections. This integrated system of trunk development indicates that in vivo-like multi-tissue co-morphogenesis and topographic organization of terminal cell types can be achieved in human organoids, opening windows for the development of more complex models of organogenesis., (© 2023. The Author(s), under exclusive licence to Springer Nature America, Inc.)

Published

2024

14. Adhesion and proliferation of bone marrow stromal cells on acellular spinal cord scaffolds.

Author

Li C, Song J, Wang Y, Shi Y, Ji J, Lin Q, and Liu Y

Subjects

Animals, Rats, Cells, Cultured, Extracellular Matrix physiology, Extracellular Matrix metabolism, Cell Movement physiology, Cell Proliferation physiology, Tissue Scaffolds, Mesenchymal Stem Cells physiology, Cell Adhesion physiology, Spinal Cord physiology, Spinal Cord cytology, Rats, Sprague-Dawley

Abstract

Objectives: This study aimed to produce an acellular spinal cord scaffold-bone marrow stromal cell (ASCS-BMSC) complex in which the growth of BMSCs transplanted into the spinal cord of rats could be simulated in vitro , facilitating the observation and evaluation of the growth of BMSCs on the ASCS for the first time., Methods: Freeze-thaw, chemical extraction and mechanical shaking approaches were used to remove the cellular components and prepare a rat ASCS containing only the extracellular matrix (ECM) structure from the rat spinal cord. BMSCs were embedded into ASCSs and freeze-dried agarose scaffolds (FASs), and cell migration and proliferation were observed via fluorescence microscopy and the MTT assay., Results: Compared with the normal rat spinal cord, the ASCS had no cell structure and retained ECM components such as type IV collagen, fibronectin and laminin, showing a three-dimensional network structure with good voids. The growth and proliferation of BMSCs on the ASCS was good, as shown by the MTT assay. Scanning electron microscopy showed that BMSCs covered 65% of the ASCS surface, and the mitochondria of BMSCs were developed and adhered to collagen fibres, as demonstrated by transmission electron microscopy. HE staining showed that BMSCs could grow inside the ASCS, and immunohistochemical staining showed that BMSCs still expressed CD44 and CD90 on the ASCS and had stem cell characteristics., Conclusions: The results of the experiment indicate that the ASCS has the ability to improve cell adhesion and proliferation. Thus, the ASCS-BMSC combination may be used to treat spinal cord injury.

Published

2024

15. Molecular Organization of Autonomic, Respiratory, and Spinally-Projecting Neurons in the Mouse Ventrolateral Medulla.

Author

Schwalbe DC, Stornetta DS, Abraham-Fan RJ, Souza GMPR, Jalil M, Crook ME, Campbell JN, and Abbott SBG

Subjects

Animals, Mice, Male, Female, Mice, Inbred C57BL, Autonomic Nervous System physiology, Autonomic Nervous System cytology, Medulla Oblongata cytology, Medulla Oblongata physiology, Neurons physiology, Spinal Cord cytology, Spinal Cord physiology

Abstract

The ventrolateral medulla (VLM) is a crucial region in the brain for visceral and somatic control, serving as a significant source of synaptic input to the spinal cord. Experimental studies have shown that gene expression in individual VLM neurons is predictive of their function. However, the molecular and cellular organization of the VLM has remained uncertain. This study aimed to create a comprehensive dataset of VLM cells using single-cell RNA sequencing in male and female mice. The dataset was enriched with targeted sequencing of spinally-projecting and adrenergic/noradrenergic VLM neurons. Based on differentially expressed genes, the resulting dataset of 114,805 VLM cells identifies 23 subtypes of neurons, excluding those in the inferior olive, and five subtypes of astrocytes. Spinally-projecting neurons were found to be abundant in seven subtypes of neurons, which were validated through in situ hybridization. These subtypes included adrenergic/noradrenergic neurons, serotonergic neurons, and neurons expressing gene markers associated with premotor neurons in the ventromedial medulla. Further analysis of adrenergic/noradrenergic neurons and serotonergic neurons identified nine and six subtypes, respectively, within each class of monoaminergic neurons. Marker genes that identify the neural network responsible for breathing were concentrated in two subtypes of neurons, delineated from each other by markers for excitatory and inhibitory neurons. These datasets are available for public download and for analysis with a user-friendly interface. Collectively, this study provides a fine-scale molecular identification of cells in the VLM, forming the foundation for a better understanding of the VLM's role in vital functions and motor control., Competing Interests: The authors declare no competing financial interests., (Copyright © 2024 the authors.)

Published

2024

16. β-arrestins Are Scaffolding Proteins Required for Shh-Mediated Axon Guidance.

Author

Sauvé R, Morin S, Yam PT, and Charron F

Subjects

Animals, Rats, Arrestins metabolism, Arrestins genetics, Female, Axons physiology, Axons metabolism, Rats, Sprague-Dawley, Cells, Cultured, Smoothened Receptor metabolism, Smoothened Receptor genetics, src-Family Kinases metabolism, Male, Spinal Cord metabolism, Spinal Cord embryology, Spinal Cord cytology, Chick Embryo, Humans, Hedgehog Proteins metabolism, Axon Guidance physiology, beta-Arrestins metabolism

Abstract

During nervous system development, Sonic hedgehog (Shh) guides developing commissural axons toward the floor plate of the spinal cord. To guide axons, Shh binds to its receptor Boc and activates downstream effectors such as Smoothened (Smo) and Src family kinases (SFKs). SFK activation requires Smo activity and is also required for Shh-mediated axon guidance. Here we report that β-arrestin1 and β-arrestin2 (β-arrestins) serve as scaffolding proteins that link Smo and SFKs in Shh-mediated axon guidance. We found that β-arrestins are expressed in rat commissural neurons. We also found that Smo, β-arrestins, and SFKs form a tripartite complex, with the complex formation dependent on β-arrestins. β-arrestin knockdown blocked the Shh-mediated increase in Src phosphorylation, demonstrating that β-arrestins are required to activate Src kinase downstream of Shh. β-arrestin knockdown also led to the loss of Shh-mediated attraction of rat commissural axons in axon turning assays. Expression of two different dominant-negative β-arrestins, β-arrestin1 V53D which blocks the internalization of Smo and β-arrestin1 P91G-P121E which blocks its interaction with SFKs, also led to the loss of Shh-mediated attraction of commissural axons. In vivo, the expression of these dominant-negative β-arrestins caused defects in commissural axon guidance in the spinal cord of chick embryos of mixed sexes. Thus we show that β-arrestins are essential scaffolding proteins that connect Smo to SFKs and are required for Shh-mediated axon guidance., Competing Interests: The authors declare no competing financial interests., (Copyright © 2024 the authors.)

Published

2024

17. Lhx4 surpasses its paralog Lhx3 in promoting the differentiation of spinal V2a interneurons.

Author

Renaux E, Baudouin C, Marchese D, Clovis Y, Lee SK, Gofflot F, Rezsohazy R, and Clotman F

Subjects

Animals, Chick Embryo, Mice, Motor Neurons metabolism, Motor Neurons cytology, Humans, Gene Expression Regulation, Developmental, LIM-Homeodomain Proteins metabolism, LIM-Homeodomain Proteins genetics, Transcription Factors metabolism, Transcription Factors genetics, Interneurons metabolism, Interneurons cytology, Spinal Cord cytology, Spinal Cord metabolism, Spinal Cord embryology, Cell Differentiation

Abstract

Paralog factors are considered to ensure the robustness of biological processes by providing redundant activity in cells where they are co-expressed. However, the specific contribution of each factor is frequently underestimated. In the developing spinal cord, multiple families of transcription factors successively contribute to differentiate an initially homogenous population of neural progenitors into a myriad of neuronal subsets with distinct molecular, morphological, and functional characteristics. The LIM-homeodomain transcription factors Lhx3, Lhx4, Isl1 and Isl2 promote the segregation and differentiation of spinal motor neurons and V2 interneurons. Based on their high sequence identity and their similar distribution, the Lhx3 and Lhx4 paralogs are considered to contribute similarly to these processes. However, the specific contribution of Lhx4 has never been studied. Here, we provide evidence that Lhx3 and Lhx4 are present in the same cell populations during spinal cord development. Similarly to Lhx3, Lhx4 can form multiproteic complexes with Isl1 or Isl2 and the nuclear LIM interactor NLI. Lhx4 can stimulate a V2-specific enhancer more efficiently than Lhx3 and surpasses Lhx3 in promoting the differentiation of V2a interneurons in chicken embryo electroporation experiments. Finally, Lhx4 inactivation in mice results in alterations of differentiation of the V2a subpopulation, but not of motor neuron production, suggesting that Lhx4 plays unique roles in V2a differentiation that are not compensated by the presence of Lhx3. Thus, Lhx4 could be the major LIM-HD factor involved in V2a interneuron differentiation during spinal cord development and should be considered for in vitro differentiation of spinal neuronal populations., (© 2024. The Author(s).)

Published

2024

18. Applying Spinal Cord Organoids as a quantitative approach to study the mammalian Hedgehog pathway.

Author

Holzner M, Wutz A, and Di Minin G

Subjects

Animals, Mice, Neural Stem Cells metabolism, Neural Stem Cells cytology, Patched-1 Receptor metabolism, Patched-1 Receptor genetics, Hedgehog Proteins metabolism, Hedgehog Proteins genetics, Organoids metabolism, Organoids cytology, Spinal Cord metabolism, Spinal Cord cytology, Signal Transduction

Abstract

The Hedgehog (HH) pathway is crucial for embryonic development, and adult homeostasis. Its dysregulation is implicated in multiple diseases. Existing cellular models used to study HH signal regulation in mammals do not fully recapitulate the complexity of the pathway. Here we show that Spinal Cord Organoids (SCOs) can be applied to quantitively study the activity of the HH pathway. During SCO formation, the specification of different categories of neural progenitors (NPC) depends on the intensity of the HH signal, mirroring the process that occurs during neural tube development. By assessing the number of NPCs within these distinct subgroups, we are able to categorize and quantify the activation level of the HH pathway. We validate this system by measuring the effects of mutating the HH receptor PTCH1 and the impact of HH agonists and antagonists on NPC specification. SCOs represent an accessible and reliable in-vitro tool to quantify HH signaling and investigate the contribution of genetic and chemical cues in the HH pathway regulation., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Holzner et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

19. Longitudinal Magnetic Resonance Imaging Tracking of Transplanted Neural Progenitor Cells in the Spinal Cord Utilizing the Bright-Ferritin Mechanism.

Author

Luo Z, Zhuang K, Kim SJ, Vollett KDW, Lou Z, Wang J, Cheng HM, Khazaei M, Fehlings MG, and Cheng HM

Subjects

Animals, Humans, Rats, Cell Differentiation, Rats, Nude, Spinal Cord Injuries therapy, Stem Cell Transplantation, Cell Tracking methods, Ferritins metabolism, Magnetic Resonance Imaging, Neural Stem Cells cytology, Neural Stem Cells transplantation, Neural Stem Cells metabolism, Spinal Cord cytology, Spinal Cord metabolism

Abstract

Human neural progenitor cells (hNPCs) hold promise for treating spinal cord injury. Studies to date have focused on improving their regenerative potential and therapeutic effect. Equally important is ensuring successful delivery and engraftment of hNPCs at the injury site. Unfortunately, no current imaging solution for cell tracking is compatible with long-term monitoring in vivo. The objective of this study was to apply a novel bright-ferritin magnetic resonance imaging (MRI) mechanism to track hNPC transplants longitudinally and on demand in the rat spinal cord. We genetically modified hNPCs to stably overexpress human ferritin. Ferritin-overexpressing (FT) hNPCs labeled with 0.2 mM manganese provided significant T1-induced bright contrast on in vitro MRI, with no adverse effect on cell viability, morphology, proliferation, and differentiation. In vivo, 2 M cells were injected into the cervical spinal cord of Rowett nude rats. MRI employed T1-weighted acquisitions and T1 mapping on a 3 T scanner. Conventional short-term cell tracking was performed using exogenous Mn labeling prior to cell transplantation, which displayed transient bright contrast on MRI 1 day after cell transplantation and disappeared after 1 week. In contrast, long-term cell tracking using bright-ferritin allowed on-demand signal recall upon Mn supplementation and precise visualization of the surviving hNPC graft. In fact, this new cell tracking technology identified 7 weeks post-transplantation as the timepoint by which substantial hNPC integration occurred. Spatial distribution of hNPCs on MRI matched that on histology. In summary, bright-ferritin provides the first demonstration of long-term, on-demand, high-resolution, and specific tracking of hNPCs in the rat spinal cord., (© The Author(s) 2024. Published by Oxford University Press.)

Published

2024

20. Exploring Ca 2+ Dynamics in Myelinating Oligodendrocytes through rAAV-Mediated jGCaMP8s Expression in Developing Spinal Cord Organ Cultures.

Author

Pachetti M, Palandri A, de Castro Reis F, Recupero L, and Ballerini L

Subjects

Animals, Calcium Signaling physiology, Mice, Inbred C57BL, Mice, Cells, Cultured, Female, Rats, Oligodendroglia metabolism, Spinal Cord metabolism, Spinal Cord cytology, Organ Culture Techniques, Calcium metabolism, Dependovirus genetics, Myelin Sheath metabolism

Abstract

Oligodendrocytes, the myelin-producing glial cells of the central nervous system (CNS), crucially contribute to myelination and circuit function. An increasing amount of evidence suggests that intracellular calcium (Ca 2+ ) dynamics in oligodendrocytes mediates activity-dependent and activity-independent myelination. Unraveling how myelinating oligodendrocytes orchestrate and integrate Ca 2+ signals, particularly in relation to axonal firing, is crucial for gaining insights into their role in the CNS development and function, both in health and disease. In this framework, we used the recombinant adeno-associated virus/Olig001 capsid variant to express the genetically encoded Ca 2+ indicator jGCaMP8s, under the control of the myelin basic protein promoter. In our study, this tool exhibits excellent tropism and selectivity for myelinating and mature oligodendrocytes, and it allows monitoring Ca 2+ activity in myelin-forming cells, both in isolated primary cultures and organotypic spinal cord explants. By live imaging of myelin Ca 2+ events in oligodendrocytes within organ cultures, we observed a rapid decline in the amplitude and duration of Ca 2+ events across different in vitro developmental stages. Active myelin sheath remodeling and growth are modulated at the level of myelin-axon interface through Ca 2+ signaling, and, during early myelination in organ cultures, this phase is finely tuned by the firing of axon action potentials. In the later stages of myelination, Ca 2+ events in mature oligodendrocytes no longer display such a modulation, underscoring the involvement of complex Ca 2+ signaling in CNS myelination., Competing Interests: The authors declare no competing financial interests., (Copyright © 2024 Pachetti et al.)

Published

2024

21. Deep sequencing of Phox2a nuclei reveals five classes of anterolateral system neurons.

Author

Bell AM, Utting C, Dickie AC, Kucharczyk MW, Quillet R, Gutierrez-Mecinas M, Razlan ANB, Cooper AH, Lan Y, Hachisuka J, Weir GA, Bannister K, Watanabe M, Kania A, Hoon MA, Macaulay IC, Denk F, and Todd AJ

Subjects

Animals, Mice, Spinal Cord cytology, Spinal Cord metabolism, Neurons metabolism, High-Throughput Nucleotide Sequencing, Male, Cell Nucleus metabolism, Cell Nucleus genetics, Transcription Factors genetics, Transcription Factors metabolism, Homeodomain Proteins genetics, Homeodomain Proteins metabolism

Abstract

The anterolateral system (ALS) is a major ascending pathway from the spinal cord that projects to multiple brain areas and underlies the perception of pain, itch, and skin temperature. Despite its importance, our understanding of this system has been hampered by the considerable functional and molecular diversity of its constituent cells. Here, we use fluorescence-activated cell sorting to isolate ALS neurons belonging to the Phox2a-lineage for single-nucleus RNA sequencing. We reveal five distinct clusters of ALS neurons (ALS1-5) and document their laminar distribution in the spinal cord using in situ hybridization. We identify three clusters of neurons located predominantly in laminae I-III of the dorsal horn (ALS1-3) and two clusters with cell bodies located in deeper laminae (ALS4 and ALS5). Our findings reveal the transcriptional logic that underlies ALS neuronal diversity in the adult mouse and uncover the molecular identity of two previously identified classes of projection neurons. We also show that these molecular signatures can be used to target groups of ALS neurons using retrograde viral tracing. Overall, our findings provide a valuable resource for studying somatosensory biology and targeting subclasses of ALS neurons., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

22. Culture of cerebrospinal fluid-contacting neurons from neonatal mouse spinal cord.

Author

Cao L, Zhang HQ, He YQ, An PJ, Yang LL, Tan W, Liu G, Wang CQ, Dou XW, and Li Q

Subjects

Animals, Mice, Cells, Cultured, Cell Culture Techniques, Neural Stem Cells metabolism, Neural Stem Cells cytology, Biomarkers cerebrospinal fluid, Biomarkers metabolism, Spinal Cord cytology, Neurons metabolism, Neurons cytology, Cerebrospinal Fluid cytology, Cerebrospinal Fluid metabolism, Animals, Newborn

Abstract

Cerebrospinal fluid-contacting neurons (CSF-cNs) act crucial role in chemosensory and mechanosensory function in spinal cord. Recently, CSF-cNs were found to be an immature neuron and may be involved in spinal cord injury recovery. But how to culture it and explore its function in vitro are not reported in previous research. Here, we first reported culture and identification of CSF-cNs in vitro. We first established a protocol for in vitro culture of CSF-cNs from the cervical spinal cord of mice within 24 h after birth. Polycystic kidney disease 2-like 1 (PKD2L1) + cells were isolated by fluorescence-activated cell sorting and expressed the neuron marker β-tubulin III and CSF-cNs marker GABA. Intriguingly, PKD2L1 + cells formed neurosphere and expressed neural stem cell markers Nestin, Sox2 and GFAP. Thus, our research provided culture and isolation of CSF-cNs and this facilitate the investigation the CSF-cNs function in vitro., (© 2023. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2024

23. An improved method for generating human spinal cord neural stem cells.

Author

Li Y, Kumamaru H, Vokes TJ, Tran AN, Shevinsky CA, Graham L, Archuleta K, Limon KR, Lu P, Blesch A, Tuszynski MH, and Brock JH

Subjects

Humans, Animals, Cell Culture Techniques methods, Cells, Cultured, Mice, Stem Cell Transplantation methods, Neural Stem Cells cytology, Spinal Cord cytology, Spinal Cord Injuries therapy, Cell Differentiation physiology

Abstract

Neural stem cells have exhibited efficacy in pre-clinical models of spinal cord injury (SCI) and are on a translational path to human testing. We recently reported that neural stem cells must be driven to a spinal cord fate to optimize host axonal regeneration into sites of implantation in the injured spinal cord, where they subsequently form neural relays across the lesion that support significant functional improvement. We also reported methods of deriving and culturing human spinal cord neural stem cells derived from embryonic stem cells that can be sustained over serial high passage numbers in vitro, providing a potentially optimized cell source for human clinical trials. We now report further optimization of methods for deriving and sustaining cultures of human spinal cord neural stem cell lines that result in improved karyotypic stability while retaining anatomical efficacy in vivo. This development improves prospects for safe human translation., Competing Interests: Declaration of competing interest The authors declare no competing interests., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

24. Krause corpuscles are genital vibrotactile sensors for sexual behaviours.

Author

Qi L, Iskols M, Greenberg RS, Xiao JY, Handler A, Liberles SD, and Ginty DD

Subjects

Animals, Female, Male, Mice, Ejaculation physiology, Optogenetics, Penile Erection physiology, Spinal Cord physiology, Spinal Cord cytology, Vagina physiology, Neurons physiology, Clitoris innervation, Clitoris physiology, Mechanoreceptors metabolism, Mechanoreceptors physiology, Penis innervation, Penis physiology, Sexual Behavior, Animal physiology, Touch physiology, Vibration

Abstract

Krause corpuscles, which were discovered in the 1850s, are specialized sensory structures found within the genitalia and other mucocutaneous tissues 1-4 . The physiological properties and functions of Krause corpuscles have remained unclear since their discovery. Here we report the anatomical and physiological properties of Krause corpuscles of the mouse clitoris and penis and their roles in sexual behaviour. We observed a high density of Krause corpuscles in the clitoris compared with the penis. Using mouse genetic tools, we identified two distinct somatosensory neuron subtypes that innervate Krause corpuscles of both the clitoris and penis and project to a unique sensory terminal region of the spinal cord. In vivo electrophysiology and calcium imaging experiments showed that both Krause corpuscle afferent types are A-fibre rapid-adapting low-threshold mechanoreceptors, optimally tuned to dynamic, light-touch and mechanical vibrations (40-80 Hz) applied to the clitoris or penis. Functionally, selective optogenetic activation of Krause corpuscle afferent terminals evoked penile erection in male mice and vaginal contraction in female mice, while genetic ablation of Krause corpuscles impaired intromission and ejaculation of males and reduced sexual receptivity of females. Thus, Krause corpuscles of the clitoris and penis are highly sensitive mechanical vibration detectors that mediate sexually dimorphic mating behaviours., (© 2024. The Author(s).)

Published

2024

25. A method for selective and efficient isolation of gray matter astrocytes from the spinal cord of adult mice.

Author

Iwasaki R, Kohro Y, and Tsuda M

Subjects

Animals, Mice, Inbred C57BL, Mice, Male, RNA, Messenger metabolism, RNA, Messenger genetics, Aging, Astrocytes metabolism, Astrocytes cytology, Gray Matter, Spinal Cord cytology, Cell Separation methods

Abstract

A growing body of evidence indicates intra- and inter-regional heterogeneity of astrocytes in the brain. However, because of a lack of an efficient method for isolating astrocytes from the spinal cord, little is known about how much spinal cord astrocytes are heterogeneous in adult mice. In this study, we developed a new method for isolating spinal astrocytes from adult mice using a cold-active protease from Bacillus licheniformis with an astrocyte cell surface antigen-2 (ACSA-2) antibody. Using fluorescence-activated cell sorting, isolated spinal ACSA-2 + cells were divided into two distinct populations, ACSA-2 high and ACSA-2 low . By analyzing the expression of cell-type marker genes, the ACSA-2 high and ACSA-2 low populations were identified as astrocytes and ependymal cells, respectively. Furthermore, ACSA-2 high cells had mRNAs encoding genes that were abundantly expressed in the gray matter (GM) but not white matter astrocytes. By optimizing enzymatic isolation procedures, the yield of GM astrocytes also increased. Therefore, our newly established method enabled the selective and efficient isolation of GM astrocytes from the spinal cord of adult mice and may be useful for bulk- or single-cell RNA-sequencing under physiological and pathological conditions., (© 2024. The Author(s).)

Published

2024

26. Human Placenta Decellularized Extracellular Matrix Hydrogel Promotes the Generation of Human Spinal Cord Organoids with Dorsoventral Organization from Human Induced Pluripotent Stem Cells.

Author

Wang Z, Liu R, Liu Y, Zhao Y, Wang Y, Lu B, Li H, Ju C, Wu W, Gao X, Xu H, Cheng S, Cao Y, Jia S, Hu C, Zhu L, and Hao D

Subjects

Humans, Female, Pregnancy, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Laminin pharmacology, Laminin chemistry, Organoids cytology, Organoids metabolism, Organoids drug effects, Placenta cytology, Induced Pluripotent Stem Cells cytology, Induced Pluripotent Stem Cells drug effects, Induced Pluripotent Stem Cells metabolism, Hydrogels chemistry, Hydrogels pharmacology, Spinal Cord cytology, Spinal Cord metabolism, Cell Differentiation drug effects, Decellularized Extracellular Matrix pharmacology, Decellularized Extracellular Matrix chemistry

Abstract

Spinal cord organoids are of significant value in the research of spinal cord-related diseases by simulating disease states, thereby facilitating the development of novel therapies. However, the complexity of spinal cord structure and physiological functions, along with the lack of human-derived inducing components, presents challenges in the in vitro construction of human spinal cord organoids. Here, we introduce a novel human decellularized placenta-derived extracellular matrix hydrogel (DPECMH) and, combined with a new induction protocol, successfully construct human spinal cord organoids. The human placenta-sourced decellularized extracellular matrix (dECM), verified through hematoxylin and eosin staining, DNA quantification, and immunofluorescence staining, retained essential ECM components such as elastin, fibronectin, type I collagen, laminin, and so forth. The temperature-sensitive hydrogel made from human placenta dECM demonstrated good biocompatibility and promoted the differentiation of human induced pluripotent stem cell (hiPSCs)-derived spinal cord organoids into neurons. It displayed enhanced expression of laminar markers in comparison to Matrigel and showed higher expression of laminar markers compared to Matrigel, accelerating the maturation process of spinal cord organoids and demonstrating its potential as an organoid culture substrate. DPECMH has the potential to replace Matrigel as the standard additive for human spinal cord organoids, thus advancing the development of spinal cord organoid culture protocols and their application in the in vitro modeling of spinal cord-related diseases.

Published

2024

27. Decellularized Brain Extracellular Matrix Hydrogel Aids the Formation of Human Spinal-Cord Organoids Recapitulating the Complex Three-Dimensional Organization.

Author

Wu W, Liu Y, Liu R, Wang Y, Zhao Y, Li H, Lu B, Ju C, Gao X, Xu H, Cao Y, Cheng S, Wang Z, Jia S, Hu C, Zhu L, and Hao D

Subjects

Humans, Animals, Rats, Decellularized Extracellular Matrix chemistry, Decellularized Extracellular Matrix pharmacology, Extracellular Matrix metabolism, Extracellular Matrix chemistry, Laminin pharmacology, Laminin chemistry, Proteoglycans chemistry, Rats, Sprague-Dawley, Drug Combinations, Collagen, Organoids drug effects, Organoids cytology, Organoids metabolism, Spinal Cord cytology, Induced Pluripotent Stem Cells cytology, Induced Pluripotent Stem Cells drug effects, Hydrogels chemistry, Hydrogels pharmacology, Brain metabolism

Abstract

The intricate electrophysiological functions and anatomical structures of spinal cord tissue render the establishment of in vitro models for spinal cord-related diseases highly challenging. Currently, both in vivo and in vitro models for spinal cord-related diseases are still underdeveloped, complicating the exploration and development of effective therapeutic drugs or strategies. Organoids cultured from human induced pluripotent stem cells (hiPSCs) hold promise as suitable in vitro models for spinal cord-related diseases. However, the cultivation of spinal cord organoids predominantly relies on Matrigel, a matrix derived from murine sarcoma tissue. Tissue-specific extracellular matrices are key drivers of complex organ development, thus underscoring the urgent need to research safer and more physiologically relevant organoid culture materials. Herein, we have prepared a rat decellularized brain extracellular matrix hydrogel (DBECMH), which supports the formation of hiPSC-derived spinal cord organoids. Compared with Matrigel, organoids cultured in DBECMH exhibited higher expression levels of markers from multiple compartments of the natural spinal cord, facilitating the development and maturation of spinal cord organoid tissues. Our study suggests that DBECMH holds potential to replace Matrigel as the standard culture medium for human spinal cord organoids, thereby advancing the development of spinal cord organoid culture protocols and their application in in vitro modeling of spinal cord-related diseases.

Published

2024

28. An in vivo drug screen in zebrafish reveals that cyclooxygenase 2-derived prostaglandin D 2 promotes spinal cord neurogenesis.

Author

González-Llera L, Sobrido-Cameán D, Quelle-Regaldie A, Sánchez L, and Barreiro-Iglesias A

Subjects

Animals, Drug Evaluation, Preclinical methods, Cyclooxygenase 2 Inhibitors pharmacology, Zebrafish Proteins metabolism, Zebrafish Proteins genetics, Signal Transduction drug effects, Cyclooxygenase Inhibitors pharmacology, Zebrafish metabolism, Neurogenesis drug effects, Spinal Cord metabolism, Spinal Cord cytology, Spinal Cord drug effects, Cyclooxygenase 2 metabolism, Cyclooxygenase 2 genetics

Abstract

The study of neurogenesis is essential to understanding fundamental developmental processes and for the development of cell replacement therapies for central nervous system disorders. Here, we designed an in vivo drug screening protocol in developing zebrafish to find new molecules and signalling pathways regulating neurogenesis in the ventral spinal cord. This unbiased drug screen revealed that 4 cyclooxygenase (COX) inhibitors reduced the generation of serotonergic interneurons in the developing spinal cord. These results fitted very nicely with available single-cell RNAseq data revealing that floor plate cells show differential expression of 1 of the 2 COX2 zebrafish genes (ptgs2a). Indeed, several selective COX2 inhibitors and two different morpholinos against ptgs2a reduced the number of serotonergic neurons in the ventral spinal cord and led to locomotor deficits. Single-cell RNAseq data and different pharmacological manipulations further revealed that COX2-floor plate-derived prostaglandin D 2 promotes neurogenesis in the developing spinal cord by promoting mitotic activity in progenitor cells. Rescue experiments using a phosphodiesterase-4 inhibitor suggest that intracellular changes in cAMP levels underlie the effects of COX inhibitors on neurogenesis and locomotion. Our study provides compelling in vivo evidence showing that prostaglandin signalling promotes neurogenesis in the ventral spinal cord., (© 2023 The Authors. Cell Proliferation published by Beijing Institute for Stem Cell and Regenerative Medicine and John Wiley & Sons Ltd.)

Published

2024

29. Excitatory Spinal Lhx9-Derived Interneurons Modulate Locomotor Frequency in Mice.

Author

Bertho M, Caldeira V, Hsu LJ, Löw P, Borgius L, and Kiehn O

Subjects

Animals, Mice, Male, Female, Glutamic Acid metabolism, Animals, Newborn, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, Interneurons physiology, LIM-Homeodomain Proteins genetics, LIM-Homeodomain Proteins metabolism, Locomotion physiology, Spinal Cord physiology, Spinal Cord cytology, Transcription Factors genetics, Transcription Factors metabolism

Abstract

Locomotion allows us to move and interact with our surroundings. Spinal networks that control locomotion produce rhythm and left-right and flexor-extensor coordination. Several glutamatergic populations, Shox2 non-V2a, Hb9-derived interneurons, and, recently, spinocerebellar neurons have been proposed to be involved in the mouse rhythm generating networks. These cells make up only a smaller fraction of the excitatory cells in the ventral spinal cord. Here, we set out to identify additional populations of excitatory spinal neurons that may be involved in rhythm generation or other functions in the locomotor network. We use RNA sequencing from glutamatergic, non-glutamatergic, and Shox2 cells in the neonatal mice from both sexes followed by differential gene expression analyses. These analyses identified transcription factors that are highly expressed by glutamatergic spinal neurons and differentially expressed between Shox2 neurons and glutamatergic neurons. From this latter category, we identified the Lhx9-derived neurons as having a restricted spinal expression pattern with no Shox2 neuron overlap. They are purely glutamatergic and ipsilaterally projecting. Ablation of the glutamatergic transmission or acute inactivation of the neuronal activity of Lhx9-derived neurons leads to a decrease in the frequency of locomotor-like activity without change in coordination pattern. Optogenetic activation of Lhx9-derived neurons promotes locomotor-like activity and modulates the frequency of the locomotor activity. Calcium activities of Lhx9-derived neurons show strong left-right out-of-phase rhythmicity during locomotor-like activity. Our study identifies a distinct population of spinal excitatory neurons that regulates the frequency of locomotor output with a suggested role in rhythm-generation in the mouse alongside other spinal populations., Competing Interests: The authors declare no competing financial interests., (Copyright © 2024 Bertho et al.)

Published

2024

30. Motor learning changes the axon initial segment of the spinal motoneuron.

Author

Wang Y, Chen Y, Chen L, Herron BJ, Chen XY, and Wolpaw JR

Subjects

Animals, Rats, Male, Learning physiology, Spinal Cord physiology, Spinal Cord cytology, Axons physiology, Neuronal Plasticity physiology, Conditioning, Operant physiology, Ankyrins metabolism, Motor Neurons physiology, H-Reflex physiology, Rats, Sprague-Dawley, Axon Initial Segment physiology

Abstract

We are studying the mechanisms of H-reflex operant conditioning, a simple form of learning. Modelling studies in the literature and our previous data suggested that changes in the axon initial segment (AIS) might contribute. To explore this, we used blinded quantitative histological and immunohistochemical methods to study in adult rats the impact of H-reflex conditioning on the AIS of the spinal motoneuron that produces the reflex. Successful, but not unsuccessful, H-reflex up-conditioning was associated with greater AIS length and distance from soma; greater length correlated with greater H-reflex increase. Modelling studies in the literature suggest that these increases may increase motoneuron excitability, supporting the hypothesis that they may contribute to H-reflex increase. Up-conditioning did not affect AIS ankyrin G (AnkG) immunoreactivity (IR), p-p38 protein kinase IR, or GABAergic terminals. Successful, but not unsuccessful, H-reflex down-conditioning was associated with more GABAergic terminals on the AIS, weaker AnkG-IR, and stronger p-p38-IR. More GABAergic terminals and weaker AnkG-IR correlated with greater H-reflex decrease. These changes might potentially contribute to the positive shift in motoneuron firing threshold underlying H-reflex decrease; they are consistent with modelling suggesting that sodium channel change may be responsible. H-reflex down-conditioning did not affect AIS dimensions. This evidence that AIS plasticity is associated with and might contribute to H-reflex conditioning adds to evidence that motor learning involves both spinal and brain plasticity, and both neuronal and synaptic plasticity. AIS properties of spinal motoneurons are likely to reflect the combined influence of all the motor skills that share these motoneurons. KEY POINTS: Neuronal action potentials normally begin in the axon initial segment (AIS). AIS plasticity affects neuronal excitability in development and disease. Whether it does so in learning is unknown. Operant conditioning of a spinal reflex, a simple learning model, changes the rat spinal motoneuron AIS. Successful, but not unsuccessful, H-reflex up-conditioning is associated with greater AIS length and distance from soma. Successful, but not unsuccessful, down-conditioning is associated with more AIS GABAergic terminals, less ankyrin G, and more p-p38 protein kinase. The associations between AIS plasticity and successful H-reflex conditioning are consistent with those between AIS plasticity and functional changes in development and disease, and with those predicted by modelling studies in the literature. Motor learning changes neurons and synapses in spinal cord and brain. Because spinal motoneurons are the final common pathway for behaviour, their AIS properties probably reflect the combined impact of all the behaviours that use these motoneurons., (© 2024 The Authors. The Journal of Physiology © 2024 The Physiological Society. This article has been contributed to by U.S. Government employees and their work is in the public domain in the USA.)

Published

2024

31. Electrophysiological Properties of Proprioception-Related Neurons in the Intermediate Thoracolumbar Spinal Cord.

Author

Espinosa F, Pop IV, and Lai HC

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors metabolism, Basic Helix-Loop-Helix Transcription Factors genetics, Mice, Transgenic, Mice, Male, Female, Action Potentials physiology, Sensory Receptor Cells physiology, Patch-Clamp Techniques, Mice, Inbred C57BL, Thoracic Vertebrae, Proprioception physiology, Spinal Cord physiology, Spinal Cord cytology

Abstract

Proprioception, the sense of limb and body position, is required to produce accurate and precise movements. Proprioceptive sensory neurons transmit muscle length and tension information to the spinal cord. The function of excitatory neurons in the intermediate spinal cord, which receive this proprioceptive information, remains poorly understood. Using genetic labeling strategies and patch-clamp techniques in acute spinal cord preparations in mice, we set out to uncover how two sets of spinal neurons, Clarke's column (CC) and Atoh1 -lineage neurons, respond to electrical activity and how their inputs are organized. Both sets of neurons are located in close proximity in laminae V-VII of the thoracolumbar spinal cord and have been described to receive proprioceptive signals. We find that a majority of CC neurons have a tonic-firing type and express a distinctive hyperpolarization-activated current (I h ). Atoh1 -lineage neurons, which cluster into two spatially distinct populations, are mostly a fading-firing type and display similar electrophysiological properties to each other, possibly due to their common developmental lineage. Finally, we find that CC neurons respond to stimulation of lumbar dorsal roots, consistent with prior knowledge that CC neurons receive hindlimb proprioceptive information. In contrast, using a combination of electrical stimulation, optogenetic stimulation, and transsynaptic rabies virus tracing, we find that Atoh1 -lineage neurons receive heterogeneous, predominantly local thoracic inputs that include parvalbumin-lineage sensory afferents and local interneuron presynaptic inputs. Altogether, we find that CC and Atoh1 -lineage neurons have distinct membrane properties and sensory input organization, representing different subcircuit modes of proprioceptive information processing., Competing Interests: The authors declare no competing financial interests., (Copyright © 2024 Espinosa et al.)

Published

2024

32. Apoptosis in Postmortal Tissues of Goat Spinal Cords and Survival of Resident Neural Progenitors.

Author

Mikhailov A and Sankai Y

Subjects

Animals, Cell Differentiation, Cell Survival, Caspase 3 metabolism, Neural Stem Cells cytology, Neural Stem Cells metabolism, Goats, Spinal Cord metabolism, Spinal Cord cytology, Apoptosis

Abstract

Growing demand for therapeutic tissue repair recurrently focusses scientists' attention on critical assessment of postmortal collection of live cells, especially stem cells. Our study aimed to assess the survival of neuronal progenitors in postmortal spinal cord and their differentiation potential. Postmortal samples of spinal cords were obtained from human-sized animals (goats) at 6, 12, 24, 36, and 54 h after slaughter. Samples were studied by immunohistology, differentiation assay, Western blot and flow cytometry for the presence and location of GD2-positive neural progenitors and their susceptibility to cell death. TUNEL staining of the goat spinal cord samples over 6-54 h postmortem revealed no difference in the number of positive cells per cross-section. Many TUNEL-positive cells were located in the gray commissure around the central canal of the spinal cord; no increase in TUNEL-positive cells was recorded in either posterior or anterior horns of the gray matter where many GD2-positive neural progenitors can be found. The active caspase 3 amount as measured by Western blot at the same intervals was moderately increasing over time. Neuronal cells were enriched by magnetic separation with antibodies against CD24; among them, the GD2-positive neural progenitor subpopulation did not overlap with apoptotic cells having high pan-caspase activity. Apoptotic cell death events are relatively rare in postmortal spinal cords and are not increased in areas of the neural progenitor cell's location, within measured postmortal intervals, or among the CD24/GD2-positive cells. Data from our study suggest postmortal spinal cords as a valuable source for harvesting highly viable allogenic neural progenitor cells.

Published

2024

33. Topographical and cell type-specific connectivity of rostral and caudal forelimb corticospinal neuron populations.

Author

Carmona LM, Thomas ED, Smith K, Tasic B, Costa RM, and Nelson A

Subjects

Animals, Spinal Cord physiology, Spinal Cord cytology, Mice, Motor Cortex physiology, Neurons physiology, Motor Neurons physiology, Female, Male, Axons physiology, Synapses physiology, Forelimb physiology, Pyramidal Tracts physiology

Abstract

Corticospinal neurons (CSNs) synapse directly on spinal neurons, a diverse assortment of cells with unique structural and functional properties necessary for body movements. CSNs modulating forelimb behavior fractionate into caudal forelimb area (CFA) and rostral forelimb area (RFA) motor cortical populations. Despite their prominence, the full diversity of spinal neurons targeted by CFA and RFA CSNs is uncharted. Here, we use anatomical and RNA sequencing methods to show that CSNs synapse onto a remarkably selective group of spinal cell types, favoring inhibitory populations that regulate motoneuron activity and gate sensory feedback. CFA and RFA CSNs target similar spinal neuron types, with notable exceptions that suggest that these populations differ in how they influence behavior. Finally, axon collaterals of CFA and RFA CSNs target similar brain regions yet receive highly divergent inputs. These results detail the rules of CSN connectivity throughout the brain and spinal cord for two regions critical for forelimb behavior., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

34. Long-Term Mouse Spinal Cord Organotypic Slice Culture as a Platform for Validating Cell Transplantation in Spinal Cord Injury.

Author

Merighi F, De Vincentiis S, Onorati M, and Raffa V

Subjects

Animals, Mice, Humans, Organ Culture Techniques methods, Stem Cell Transplantation methods, Spinal Cord Injuries therapy, Neural Stem Cells cytology, Neural Stem Cells transplantation, Spinal Cord cytology

Abstract

Resolutive cures for spinal cord injuries (SCIs) are still lacking, due to the complex pathophysiology. One of the most promising regenerative approaches is based on stem cell transplantation to replace lost tissue and promote functional recovery. This approach should be further explored better in vitro and ex vivo for safety and efficacy before proceeding with more expensive and time-consuming animal testing. In this work, we show the establishment of a long-term platform based on mouse spinal cord (SC) organotypic slices transplanted with human neural stem cells to test cellular replacement therapies for SCIs. Standard SC organotypic cultures are maintained for around 2 or 3 weeks in vitro. Here, we describe an optimized protocol for long-term maintenance (≥30 days) for up to 90 days. The medium used for long-term culturing of SC slices was also optimized for transplanting neural stem cells into the organotypic model. Human SC-derived neuroepithelial stem (h-SC-NES) cells carrying a green fluorescent protein (GFP) reporter were transplanted into mouse SC slices. Thirty days after the transplant, cells still show GFP expression and a low apoptotic rate, suggesting that the optimized environment sustained their survival and integration inside the tissue. This protocol represents a robust reference for efficiently testing cell replacement therapies in the SC tissue. This platform will allow researchers to perform an ex vivo pre-screening of different cell transplantation therapies, helping them to choose the most appropriate strategy before proceeding with in vivo experiments.

Published

2024

35. Potential Roles of Specific Subclasses of Premotor Interneurons in Spinal Cord Function Recovery after Traumatic Spinal Cord Injury in Adults.

Author

Dominguez-Bajo A and Clotman F

Subjects

Adult, Animals, Humans, Spinal Cord cytology, Spinal Cord pathology, Interneurons metabolism, Recovery of Function, Spinal Cord Injuries therapy, Spinal Cord Injuries physiopathology

Abstract

The differential expression of transcription factors during embryonic development has been selected as the main feature to define the specific subclasses of spinal interneurons. However, recent studies based on single-cell RNA sequencing and transcriptomic experiments suggest that this approach might not be appropriate in the adult spinal cord, where interneurons show overlapping expression profiles, especially in the ventral region. This constitutes a major challenge for the identification and direct targeting of specific populations that could be involved in locomotor recovery after a traumatic spinal cord injury in adults. Current experimental therapies, including electrical stimulation, training, pharmacological treatments, or cell implantation, that have resulted in improvements in locomotor behavior rely on the modulation of the activity and connectivity of interneurons located in the surroundings of the lesion core for the formation of detour circuits. However, very few publications clarify the specific identity of these cells. In this work, we review the studies where premotor interneurons were able to create new intraspinal circuits after different kinds of traumatic spinal cord injury, highlighting the difficulties encountered by researchers, to classify these populations.

Published

2024

36. A patterned human neural tube model using microfluidic gradients.

Author

Xue X, Kim YS, Ponce-Arias AI, O'Laughlin R, Yan RZ, Kobayashi N, Tshuva RY, Tsai YH, Sun S, Zheng Y, Liu Y, Wong FCK, Surani A, Spence JR, Song H, Ming GL, Reiner O, and Fu J

Subjects

Humans, Cell Culture Techniques, Three Dimensional, Cell Differentiation, Neural Crest cytology, Neural Crest embryology, Pluripotent Stem Cells cytology, Prosencephalon cytology, Prosencephalon embryology, Spinal Cord cytology, Spinal Cord embryology, Body Patterning, Microfluidics, Neural Tube cytology, Neural Tube embryology

Abstract

The human nervous system is a highly complex but organized organ. The foundation of its complexity and organization is laid down during regional patterning of the neural tube, the embryonic precursor to the human nervous system. Historically, studies of neural tube patterning have relied on animal models to uncover underlying principles. Recently, models of neurodevelopment based on human pluripotent stem cells, including neural organoids 1-5 and bioengineered neural tube development models 6-10 , have emerged. However, such models fail to recapitulate neural patterning along both rostral-caudal and dorsal-ventral axes in a three-dimensional tubular geometry, a hallmark of neural tube development. Here we report a human pluripotent stem cell-based, microfluidic neural tube-like structure, the development of which recapitulates several crucial aspects of neural patterning in brain and spinal cord regions and along rostral-caudal and dorsal-ventral axes. This structure was utilized for studying neuronal lineage development, which revealed pre-patterning of axial identities of neural crest progenitors and functional roles of neuromesodermal progenitors and the caudal gene CDX2 in spinal cord and trunk neural crest development. We further developed dorsal-ventral patterned microfluidic forebrain-like structures with spatially segregated dorsal and ventral regions and layered apicobasal cellular organizations that mimic development of the human forebrain pallium and subpallium, respectively. Together, these microfluidics-based neurodevelopment models provide three-dimensional lumenal tissue architectures with in vivo-like spatiotemporal cell differentiation and organization, which will facilitate the study of human neurodevelopment and disease., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

37. From signalling to form: the coordination of neural tube patterning.

Author

Frith TJR, Briscoe J, and Boezio GLM

Subjects

Animals, Humans, Gene Regulatory Networks, Spinal Cord embryology, Spinal Cord cytology, Spinal Cord metabolism, Cell Differentiation, Cell Movement, Neural Tube embryology, Neural Tube metabolism, Neural Tube cytology, Body Patterning genetics, Gene Expression Regulation, Developmental, Signal Transduction

Abstract

The development of the vertebrate spinal cord involves the formation of the neural tube and the generation of multiple distinct cell types. The process starts during gastrulation, combining axial elongation with specification of neural cells and the formation of the neuroepithelium. Tissue movements produce the neural tube which is then exposed to signals that provide patterning information to neural progenitors. The intracellular response to these signals, via a gene regulatory network, governs the spatial and temporal differentiation of progenitors into specific cell types, facilitating the assembly of functional neuronal circuits. The interplay between the gene regulatory network, cell movement, and tissue mechanics generates the conserved neural tube pattern observed across species. In this review we offer an overview of the molecular and cellular processes governing the formation and patterning of the neural tube, highlighting how the remarkable complexity and precision of vertebrate nervous system arises. We argue that a multidisciplinary and multiscale understanding of the neural tube development, paired with the study of species-specific strategies, will be crucial to tackle the open questions., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

38. In Ovo Electroporation of Embryonic Chicken Spinal Cord in Combination with Ex Vivo Slice Culture for Live Imaging of Vertebrate Neuronal Differentiation.

Author

Higgs VE, Toro-Tapia G, Burbidge HB, and Das RM

Subjects

Animals, Chick Embryo, Chickens, Neurogenesis, Electroporation methods, Spinal Cord cytology, Spinal Cord embryology, Neurons cytology, Neurons metabolism, Cell Differentiation

Abstract

To investigate the cell behavior underlying neuronal differentiation in a physiologically relevant context, differentiating neurons must be studied in their native tissue environment. Here, we describe an accessible protocol for fluorescent live imaging of differentiating neurons within ex vivo embryonic chicken spinal cord slice cultures, which facilitates long-term observation of individual cells within developing tissue., (© 2024. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2024

39. A transcriptomic taxonomy of mouse brain-wide spinal projecting neurons.

Author

Winter CC, Jacobi A, Su J, Chung L, van Velthoven CTJ, Yao Z, Lee C, Zhang Z, Yu S, Gao K, Duque Salazar G, Kegeles E, Zhang Y, Tomihiro MC, Zhang Y, Yang Z, Zhu J, Tang J, Song X, Donahue RJ, Wang Q, McMillen D, Kunst M, Wang N, Smith KA, Romero GE, Frank MM, Krol A, Kawaguchi R, Geschwind DH, Feng G, Goodrich LV, Liu Y, Tasic B, Zeng H, and He Z

Subjects

Animals, Mice, Hypothalamus, Neuropeptides, Neurotransmitter Agents, Mesencephalon cytology, Reticular Formation cytology, Electrophysiology, Cerebellum cytology, Cerebral Cortex cytology, Gene Expression Profiling, Neurons metabolism, Spinal Cord cytology, Spinal Cord metabolism, Brain cytology, Brain metabolism, Neural Pathways

Abstract

The brain controls nearly all bodily functions via spinal projecting neurons (SPNs) that carry command signals from the brain to the spinal cord. However, a comprehensive molecular characterization of brain-wide SPNs is still lacking. Here we transcriptionally profiled a total of 65,002 SPNs, identified 76 region-specific SPN types, and mapped these types into a companion atlas of the whole mouse brain 1 . This taxonomy reveals a three-component organization of SPNs: (1) molecularly homogeneous excitatory SPNs from the cortex, red nucleus and cerebellum with somatotopic spinal terminations suitable for point-to-point communication; (2) heterogeneous populations in the reticular formation with broad spinal termination patterns, suitable for relaying commands related to the activities of the entire spinal cord; and (3) modulatory neurons expressing slow-acting neurotransmitters and/or neuropeptides in the hypothalamus, midbrain and reticular formation for 'gain setting' of brain-spinal signals. In addition, this atlas revealed a LIM homeobox transcription factor code that parcellates the reticulospinal neurons into five molecularly distinct and spatially segregated populations. Finally, we found transcriptional signatures of a subset of SPNs with large soma size and correlated these with fast-firing electrophysiological properties. Together, this study establishes a comprehensive taxonomy of brain-wide SPNs and provides insight into the functional organization of SPNs in mediating brain control of bodily functions., (© 2023. The Author(s).)

Published

2023

40. Spatial atlas of the mouse central nervous system at molecular resolution.

Author

Shi H, He Y, Zhou Y, Huang J, Maher K, Wang B, Tang Z, Luo S, Tan P, Wu M, Lin Z, Ren J, Thapa Y, Tang X, Chan KY, Deverman BE, Shen H, Liu A, Liu J, and Wang X

Subjects

Animals, Mice, Brain anatomy & histology, Brain cytology, Brain metabolism, Spinal Cord anatomy & histology, Spinal Cord cytology, Spinal Cord metabolism, Single-Cell Gene Expression Analysis, Viral Tropism, Datasets as Topic, Transgenes genetics, Central Nervous System anatomy & histology, Central Nervous System cytology, Central Nervous System metabolism, Single-Cell Analysis methods, Transcriptome genetics, Imaging, Three-Dimensional methods

Abstract

Spatially charting molecular cell types at single-cell resolution across the 3D volume is critical for illustrating the molecular basis of brain anatomy and functions. Single-cell RNA sequencing has profiled molecular cell types in the mouse brain 1,2 , but cannot capture their spatial organization. Here we used an in situ sequencing method, STARmap PLUS 3,4 , to profile 1,022 genes in 3D at a voxel size of 194 × 194 × 345 nm 3 , mapping 1.09 million high-quality cells across the adult mouse brain and spinal cord. We developed computational pipelines to segment, cluster and annotate 230 molecular cell types by single-cell gene expression and 106 molecular tissue regions by spatial niche gene expression. Joint analysis of molecular cell types and molecular tissue regions enabled a systematic molecular spatial cell-type nomenclature and identification of tissue architectures that were undefined in established brain anatomy. To create a transcriptome-wide spatial atlas, we integrated STARmap PLUS measurements with a published single-cell RNA-sequencing atlas 1 , imputing single-cell expression profiles of 11,844 genes. Finally, we delineated viral tropisms of a brain-wide transgene delivery tool, AAV-PHP.eB 5,6 . Together, this annotated dataset provides a single-cell resource that integrates the molecular spatial atlas, brain anatomy and the accessibility to genetic manipulation of the mammalian central nervous system., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

41. The neurons that restore walking after paralysis.

Author

Kathe C, Skinnider MA, Hutson TH, Regazzi N, Gautier M, Demesmaeker R, Komi S, Ceto S, James ND, Cho N, Baud L, Galan K, Matson KJE, Rowald A, Kim K, Wang R, Minassian K, Prior JO, Asboth L, Barraud Q, Lacour SP, Levine AJ, Wagner F, Bloch J, Squair JW, and Courtine G

Subjects

Animals, Humans, Mice, Electric Stimulation, Lumbosacral Region innervation, Neurological Rehabilitation, Sequence Analysis, RNA, Gene Expression Profiling, Neurons physiology, Paralysis genetics, Paralysis physiopathology, Paralysis therapy, Spinal Cord cytology, Spinal Cord physiology, Spinal Cord physiopathology, Spinal Cord Injuries genetics, Spinal Cord Injuries physiopathology, Spinal Cord Injuries therapy, Walking physiology

Abstract

A spinal cord injury interrupts pathways from the brain and brainstem that project to the lumbar spinal cord, leading to paralysis. Here we show that spatiotemporal epidural electrical stimulation (EES) of the lumbar spinal cord 1-3 applied during neurorehabilitation 4,5 (EES REHAB ) restored walking in nine individuals with chronic spinal cord injury. This recovery involved a reduction in neuronal activity in the lumbar spinal cord of humans during walking. We hypothesized that this unexpected reduction reflects activity-dependent selection of specific neuronal subpopulations that become essential for a patient to walk after spinal cord injury. To identify these putative neurons, we modelled the technological and therapeutic features underlying EES REHAB in mice. We applied single-nucleus RNA sequencing 6-9 and spatial transcriptomics 10,11 to the spinal cords of these mice to chart a spatially resolved molecular atlas of recovery from paralysis. We then employed cell type 12,13 and spatial prioritization to identify the neurons involved in the recovery of walking. A single population of excitatory interneurons nested within intermediate laminae emerged. Although these neurons are not required for walking before spinal cord injury, we demonstrate that they are essential for the recovery of walking with EES following spinal cord injury. Augmenting the activity of these neurons phenocopied the recovery of walking enabled by EES REHAB , whereas ablating them prevented the recovery of walking that occurs spontaneously after moderate spinal cord injury. We thus identified a recovery-organizing neuronal subpopulation that is necessary and sufficient to regain walking after paralysis. Moreover, our methodology establishes a framework for using molecular cartography to identify the neurons that produce complex behaviours., (© 2022. The Author(s).)

Published

2022

42. Movement is governed by rotational neural dynamics in spinal motor networks.

Author

Lindén H, Petersen PC, Vestergaard M, and Berg RW

Subjects

Muscle, Skeletal innervation, Muscle, Skeletal physiology, Walking physiology, Movement, Spinal Cord cytology, Spinal Cord physiology, Motor Neurons physiology, Rotation

Abstract

Although the generation of movements is a fundamental function of the nervous system, the underlying neural principles remain unclear. As flexor and extensor muscle activities alternate during rhythmic movements such as walking, it is often assumed that the responsible neural circuitry is similarly exhibiting alternating activity 1 . Here we present ensemble recordings of neurons in the lumbar spinal cord that indicate that, rather than alternating, the population is performing a low-dimensional 'rotation' in neural space, in which the neural activity is cycling through all phases continuously during the rhythmic behaviour. The radius of rotation correlates with the intended muscle force, and a perturbation of the low-dimensional trajectory can modify the motor behaviour. As existing models of spinal motor control do not offer an adequate explanation of rotation 1,2 , we propose a theory of neural generation of movements from which this and other unresolved issues, such as speed regulation, force control and multifunctionalism, are readily explained., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022

43. Vulnerability of the spinal motor neuron presynaptic terminal sub-proteome in ALS.

Author

Lum JS, Berg T, Chisholm CG, Vendruscolo M, and Yerbury JJ

Subjects

Animals, Mice, Presynaptic Terminals metabolism, Proteome metabolism, Spinal Cord cytology, Spinal Cord metabolism, Spinal Cord pathology, Synapses metabolism, Humans, Amyotrophic Lateral Sclerosis metabolism, Amyotrophic Lateral Sclerosis pathology, Motor Neurons metabolism, Motor Neurons pathology

Abstract

Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disorder, characterised by the loss of motor neurons and subsequent paralysis. Evidence indicates that synaptic alterations are associated with the early stages of ALS pathogenesis. A hallmark of ALS postmortem tissue is the presence of proteinaceous inclusions, indicative of disturbed protein homeostasis, particularly in spinal cord motor neurons. We recently demonstrated that spinal cord motor neurons contain a supersaturated proteome, as they possess proteins at concentrations that exceed their solubility limits, resulting in a metastable proteome conducive to protein misfolding and aggregation. Recent evidence indicates metastable sub-proteomes within neuronal compartments, such as the synapse, may be particularly vulnerable and underlie their involvement in the initial stages of neurodegenerative diseases. To investigate if the motor neuron presynaptic terminal possesses a metastable sub-proteome, we used human and mouse spinal cord motor neuron expression data to calculate supersaturation scores. Here, we found that both the human and mouse presynaptic terminal sub-proteomes have higher supersaturation scores than the entire motor neuron proteome. In addition, we observed that proteins down-regulated in ALS were over-represented in the synapse. These results provide support for the notion that the metastability of the sub-proteome within the motor neuron presynaptic terminal may be particularly susceptible to protein homeostasis disturbances in ALS, and may contribute to explaining the observed synaptic dysfunction in ALS., (Copyright © 2022 Elsevier B.V. All rights reserved.)

Published

2022

44. Toll-like receptors 2 and 4 differentially regulate the self-renewal and differentiation of spinal cord neural precursor cells.

Author

Sanchez-Petidier M, Guerri C, and Moreno-Manzano V

Subjects

Animals, Mice, Neurons cytology, Spinal Cord cytology, Cell Differentiation, Neural Stem Cells cytology, Toll-Like Receptor 2 genetics, Toll-Like Receptor 2 metabolism, Toll-Like Receptor 4 genetics, Toll-Like Receptor 4 metabolism

Abstract

Background: Toll-like receptors (TLRs) represent critical effectors in the host defense response against various pathogens; however, their known function during development has also highlighted a potential role in cell fate determination and neural differentiation. While glial cells and neural precursor cells (NPCs) of the spinal cord express both TLR2 and TLR4, their influence on self-renewal and cell differentiation remains incompletely described., Methods: TLR2, TLR4 knock-out and the wild type mice were employed for spinal cord tissue analysis and NPCs isolation at early post-natal stage. Sox2, FoxJ1 and Ki67 expression among others served to identify the undifferentiated and proliferative NPCs; GFAP, Olig2 and β-III-tubulin markers served to identify astrocytes, oligodendrocytes and neurons respectively after NPC spontaneous differentiation. Multiple comparisons were analyzed using one-way ANOVA, with appropriate corrections such as Tukey's post hoc tests used for comparisons., Results: We discovered that the deletion of TLR2 or TLR4 significantly reduced the number of Sox2-expressing NPCs in the neonatal mouse spinal cord. While TLR2-knockout NPCs displayed enhanced self-renewal, increased proliferation and apoptosis, and delayed neural differentiation, the absence of TLR4 promoted the neural differentiation of NPCs without affecting proliferation, producing long projecting neurons. TLR4 knock-out NPCs showed significantly higher expression of Neurogenin1, that would be involved in the activation of this neurogenic program by a ligand and microenvironment-independent mechanism. Interestingly, the absence of both TLR2 and TLR4, which induces also a significant reduction in the expression of TLR1, in NPCs impeded oligodendrocyte precursor cell maturation to a similar degree., Conclusions: Our data suggest that Toll-like receptors are needed to maintain Sox2 positive neural progenitors in the spinal cord, however possess distinct regulatory roles in mouse neonatal spinal cord NPCs-while TLR2 and TLR4 play a similar role in oligodendrocytic differentiation, they differentially influence neural differentiation., (© 2022. The Author(s).)

Published

2022

45. Transcription factor Zfp276 drives oligodendroglial differentiation and myelination by switching off the progenitor cell program.

Author

Aberle T, Piefke S, Hillgärtner S, Tamm ER, Wegner M, and Küspert M

Subjects

Animals, Cell Differentiation, Mice, Myelin Sheath physiology, Neurogenesis, Spinal Cord metabolism, Stem Cells, Oligodendroglia cytology, Oligodendroglia metabolism, Spinal Cord cytology, Transcription Factors genetics, Transcription Factors metabolism

Abstract

In oligodendrocytes of the vertebrate central nervous system a complex network of transcriptional regulators is required to ensure correct and timely myelination of neuronal axons. Here we identify Zfp276, the only mammalian ZAD-domain containing zinc finger protein, as a transcriptional regulator of oligodendrocyte differentiation and central myelination downstream of Sox10. In the central nervous system, Zfp276 is exclusively expressed in mature oligodendrocytes. Oligodendroglial deletion of Zfp276 led to strongly reduced expression of myelin genes in the early postnatal mouse spinal cord. Retroviral overexpression of Zfp276 in cultured oligodendrocyte precursor cells induced precocious expression of maturation markers and myelin genes, further supporting its role in oligodendroglial differentiation. On the molecular level, Zfp276 directly binds to and represses Sox10-dependent gene regulatory regions of immaturity factors and functionally interacts with the transcriptional repressor Zeb2 to enable fast transition of oligodendrocytes to the myelinating stage., (© The Author(s) 2022. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2022

46. The histone demethylase Kdm6b regulates subtype diversification of mouse spinal motor neurons during development.

Author

Wang W, Cho H, Lee JW, and Lee SK

Subjects

Animals, Cell Differentiation genetics, DNA Demethylation, Embryo, Mammalian, Female, Gene Knockout Techniques, HEK293 Cells, Histone Demethylases genetics, Histone Demethylases metabolism, Humans, Jumonji Domain-Containing Histone Demethylases genetics, LIM-Homeodomain Proteins metabolism, Mice, Mice, Transgenic, RNA-Seq, Single-Cell Analysis, Spinal Cord cytology, Transcription Factors metabolism, Jumonji Domain-Containing Histone Demethylases metabolism, Motor Neurons physiology, Neurogenesis genetics, Spinal Cord growth & development

Abstract

How a single neuronal population diversifies into subtypes with distinct synaptic targets is a fundamental topic in neuroscience whose underlying mechanisms are unclear. Here, we show that the histone H3-lysine 27 demethylase Kdm6b regulates the diversification of motor neurons to distinct subtypes innervating different muscle targets during spinal cord development. In mouse embryonic motor neurons, Kdm6b promotes the medial motor column (MMC) and hypaxial motor column (HMC) fates while inhibiting the lateral motor column (LMC) and preganglionic motor column (PGC) identities. Our single-cell RNA-sequencing analyses reveal the heterogeneity of PGC, LMC, and MMC motor neurons. Further, our single-cell RNA-sequencing data, combined with mouse model studies, demonstrates that Kdm6b acquires cell fate specificity together with the transcription factor complex Isl1-Lhx3. Our study provides mechanistic insight into the gene regulatory network regulating neuronal cell-type diversification and defines a regulatory role of Kdm6b in the generation of motor neuron subtypes in the mouse spinal cord., (© 2022. The Author(s).)

Published

2022

47. Melatonin ameliorates bupivacaine-induced spinal neurotoxicity in rats by suppressing neuronal NLRP3 inflammasome activation.

Author

Lai J, Ji JM, Chen MY, Luo YP, Yu Y, Zhou G, Wei LL, Huang LS, and Liu JC

Subjects

Animals, Anti-Inflammatory Agents pharmacology, Antioxidants pharmacology, Bupivacaine toxicity, Male, Melatonin pharmacology, Microglia drug effects, Microglia metabolism, Neurons drug effects, Neurons metabolism, Neurotoxicity Syndromes etiology, Neurotoxicity Syndromes metabolism, Rats, Rats, Sprague-Dawley, Spinal Cord cytology, Spinal Cord drug effects, Spinal Cord metabolism, Anti-Inflammatory Agents therapeutic use, Antioxidants therapeutic use, Melatonin therapeutic use, NLR Family, Pyrin Domain-Containing 3 Protein metabolism, Neurotoxicity Syndromes drug therapy

Abstract

Bupivacaine is a common local anesthetic that causes neurotoxicity when used at clinical concentrations. Melatonin (MT), is a potent neuroprotective molecule. The study aimed to characterize the neuroprotective effects of MT on spinal neurotoxicity induced by bupivacaine in rats. It showed that bupivacaine, by intrathecal injection, induced spinal injury, and that the protein levels of Nod-like receptor protein 3 (NLRP3), cleaved caspase-1, and the N-terminal region of gasdermin D (GSDMD-N) were significantly increased. NLRP3 was expressed mainly in neurons and microglia. MT treatment ameliorated bupivacaine-induced spinal cord injury in rats by suppressing activation of neuronal NLRP3 inflammasomes., (Copyright © 2022 Elsevier B.V. All rights reserved.)

Published

2022

48. Single-cell RNA sequencing reveals Nestin + active neural stem cells outside the central canal after spinal cord injury.

Author

Shu M, Xue X, Nie H, Wu X, Sun M, Qiao L, Li X, Xu B, Xiao Z, Zhao Y, Fan Y, Chen B, Zhang J, Shi Y, Yang Y, Lu F, and Dai J

Subjects

Animals, Gene Expression Profiling, Humans, Mice, Mice, Transgenic, Nestin genetics, Neural Stem Cells cytology, Neurogenesis genetics, Single-Cell Analysis, Spinal Cord cytology, Spinal Cord metabolism, Spinal Cord Injuries genetics, Spinal Cord Injuries pathology, Nestin metabolism, Neural Stem Cells metabolism, Spinal Cord Injuries metabolism

Abstract

Neural stem cells (NSCs) in the spinal cord hold great potential for repair after spinal cord injury (SCI). The ependyma in the central canal (CC) region has been considered as the NSCs source in the spinal cord. However, the ependyma function as NSCs after SCI is still under debate. We used Nestin as a marker to isolate potential NSCs and their immediate progeny, and characterized the cells before and after SCI by single-cell RNA-sequencing (scRNA-seq). We identified two subgroups of NSCs: the subgroup located within the CC cannot prime to active NSCs after SCI, while the subgroup located outside the CC were activated and exhibited the active NSCs properties after SCI. We demonstrated the comprehensive dynamic transcriptome of NSCs from quiescent to active NSCs after SCI. This study reveals that Nestin + cells outside CC were NSCs that activated upon SCI and may thus serve as endogenous NSCs for regenerative treatment of SCI in the future., (© 2022. Science China Press and Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2022

49. Regulation of stem cell identity by miR-200a during spinal cord regeneration.

Author

Walker SE, Sabin KZ, Gearhart MD, Yamamoto K, and Echeverri K

Subjects

3' Untranslated Regions, Ambystoma mexicanum metabolism, Animals, Antagomirs metabolism, Cell Differentiation, Fetal Proteins genetics, Fetal Proteins metabolism, Mesoderm cytology, Mesoderm metabolism, MicroRNAs antagonists & inhibitors, MicroRNAs genetics, Neural Stem Cells cytology, Neural Stem Cells metabolism, Neuroglia cytology, Neuroglia metabolism, SOXB1 Transcription Factors genetics, SOXB1 Transcription Factors metabolism, Spinal Cord cytology, Spinal Cord Injuries metabolism, Spinal Cord Injuries pathology, Stem Cells cytology, Stem Cells metabolism, T-Box Domain Proteins genetics, T-Box Domain Proteins metabolism, Tail physiology, Wnt Signaling Pathway, beta Catenin antagonists & inhibitors, beta Catenin chemistry, beta Catenin metabolism, MicroRNAs metabolism, Spinal Cord metabolism, Spinal Cord Regeneration genetics

Abstract

Axolotls are an important model organism for multiple types of regeneration, including functional spinal cord regeneration. Remarkably, axolotls can repair their spinal cord after a small lesion injury and can also regenerate their entire tail following amputation. Several classical signaling pathways that are used during development are reactivated during regeneration, but how this is regulated remains a mystery. We have previously identified miR-200a as a key factor that promotes successful spinal cord regeneration. Here, using RNA-seq analysis, we discovered that the inhibition of miR-200a results in an upregulation of the classical mesodermal marker brachyury in spinal cord cells after injury. However, these cells still express the neural stem cell marker sox2. In vivo cell tracking allowed us to determine that these cells can give rise to cells of both the neural and mesoderm lineage. Additionally, we found that miR-200a can directly regulate brachyury via a seed sequence in the 3'UTR of the gene. Our data indicate that miR-200a represses mesodermal cell fate after a small lesion injury in the spinal cord when only glial cells and neurons need to be replaced., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2022. Published by The Company of Biologists Ltd.)

Published

2022

50. Structure of Long-Range Direct and Indirect Spinocerebellar Pathways as Well as Local Spinal Circuits Mediating Proprioception.

Author

Pop IV, Espinosa F, Blevins CJ, Okafor PC, Ogujiofor OW, Goyal M, Mona B, Landy MA, Dean KM, Gurumurthy CB, and Lai HC

Subjects

Animals, Animals, Newborn, Cerebellum chemistry, Cerebellum cytology, Mice, Mice, Inbred C57BL, Mice, Transgenic, Nerve Net chemistry, Nerve Net cytology, Spinal Cord chemistry, Spinal Cord cytology, Spinocerebellar Tracts chemistry, Spinocerebellar Tracts cytology, Cerebellum physiology, Nerve Net physiology, Proprioception physiology, Spinal Cord physiology, Spinocerebellar Tracts physiology

Abstract

Proprioception, the sense of limb and body position, generates a map of the body that is essential for proper motor control, yet we know little about precisely how neurons in proprioceptive pathways are wired. Defining the anatomy of secondary neurons in the spinal cord that integrate and relay proprioceptive and potentially cutaneous information from the periphery to the cerebellum is fundamental to understanding how proprioceptive circuits function. Here, we define the unique anatomic trajectories of long-range direct and indirect spinocerebellar pathways as well as local intersegmental spinal circuits using genetic tools in both male and female mice. We find that Clarke's column neurons, a major contributor to the direct spinocerebellar pathway, has mossy fiber terminals that diversify extensively in the cerebellar cortex with axons terminating bilaterally, but with no significant axon collaterals within the spinal cord, medulla, or cerebellar nuclei. By contrast, we find that two of the indirect pathways, the spino-lateral reticular nucleus and spino-olivary pathways, are in part, derived from cervical Atoh1 -lineage neurons, whereas thoracolumbar Atoh1 -lineage neurons project mostly locally within the spinal cord. Notably, while cervical and thoracolumbar Atoh1 -lineage neurons connect locally with motor neurons, no Clarke's column to motor neuron connections were detected. Together, we define anatomic differences between long-range direct, indirect, and local proprioceptive subcircuits that likely mediate different components of proprioceptive-motor behaviors. SIGNIFICANCE STATEMENT We define the anatomy of long-range direct and indirect spinocerebellar pathways as well as local spinal proprioceptive circuits. We observe that mossy fiber axon terminals of Clarke's column neurons diversify proprioceptive information across granule cells in multiple lobules on both ipsilateral and contralateral sides, sending no significant collaterals within the spinal cord, medulla, or cerebellar nuclei. Strikingly, we find that cervical spinal cord Atoh1 -lineage neurons form mainly the indirect spino-lateral reticular nucleus and spino-olivary tracts and thoracolumbar Atoh1 -lineage neurons project locally within the spinal cord, whereas only a few Atoh1 -lineage neurons form a direct spinocerebellar tract., (Copyright © 2022 the authors.)

Published

2022