Browsing by Subject "Peripheral nervous system"

Now showing 1 - 8 of 8
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    Cell adhesion molecule cadherin-6 function in zebrafish cranial and lateral line ganglia development
    (Wiley, 2011-07) Liu, Q.; Dalman, M.R.; Sarmah, S.; Chen, S.; Chen, Y.; Hurlbut, A. K.; Spencer, M.A.; Pancoe, L.; Marrs, J. A.; Biology, School of Science
    Cadherins regulate the vertebrate nervous system development. We previously showed that cadherin-6 message (cdh6) was strongly expressed in the majority of the embryonic zebrafish cranial and lateral line ganglia during their development. Here, we present evidence that cdh6 has specific functions during cranial and lateral line ganglia and nerve development. We analyzed the consequences of cdh6 loss-of-function on cranial ganglion and nerve differentiation in zebrafish embryos. Embryos injected with zebrafish cdh6 specific antisense morpholino oligonucleotides (MOs, which suppress gene expression during development; cdh6 morphant embryos) displayed a specific phenotype, including (i) altered shape and reduced development of a subset of the cranial and lateral line ganglia (e.g., the statoacoustic ganglion and vagal ganglion) and (ii) cranial nerves were abnormally formed. These data illustrate an important role for cdh6 in the formation of cranial ganglia and their nerves.
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    Cleaved TMEM106B forms amyloid aggregates in central and peripheral nervous systems
    (Springer Nature, 2024-06-17) Bacioglu, Mehtap; Schweighauser, Manuel; Gray, Derrick; Lövestam, Sofia; Katsinelos, Taxiarchis; Quaegebeur, Annelies; van Swieten, John; Jaunmuktane, Zane; Davies, Stephen W.; Scheres, Sjors H. W.; Goedert, Michel; Ghetti, Bernardino; Grazia Spillantini, Maria; Biochemistry and Molecular Biology, School of Medicine
    Filaments made of residues 120-254 of transmembrane protein 106B (TMEM106B) form in an age-dependent manner and can be extracted from the brains of neurologically normal individuals and those of subjects with a variety of neurodegenerative diseases. TMEM106B filament formation requires cleavage at residue 120 of the 274 amino acid protein; at present, it is not known if residues 255-274 form the fuzzy coat of TMEM106B filaments. Here we show that a second cleavage appears likely, based on staining with an antibody raised against residues 263-274 of TMEM106B. We also show that besides the brain TMEM106B inclusions form in dorsal root ganglia and spinal cord, where they were mostly found in non-neuronal cells. We confirm that in the brain, inclusions were most abundant in astrocytes. No inclusions were detected in heart, liver, spleen or hilar lymph nodes. Based on their staining with luminescent conjugated oligothiophenes, we confirm that TMEM106B inclusions are amyloids. By in situ immunoelectron microscopy, TMEM106B assemblies were often found in structures resembling endosomes and lysosomes.
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    Correction: Cleaved TMEM106B forms amyloid aggregates in central and peripheral nervous systems
    (Springer Nature, 2024-08-14) Bacioglu, Mehtap; Gray, Derrick; Lövestam, Sofia; Katsinelos, Taxiarchis; Quaegebeur, Annelies; van Swieten, John; Jaunmuktane, Zane; Davies, Stephen W.; Scheres, Sjors H. W.; Goedert, Michel; Ghetti, Bernardino; Grazia Spillantini, Maria; Pathology and Laboratory Medicine, School of Medicine
    Correction: Acta Neuropathologica Communications (2024) 12:99 10.1186/s40478-024-01813-z Following publication of the original article [1], the sentence “It remains to be determined if the formation of TMEM106B filaments can influence the risk of developing neurodegenerative diseases” in the paragraph starting with “Abundant filaments made of residues” under Discussion heading gives the relevant meaning of the previous sentence. The author wants to delete the sentence. The original article has been corrected.
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    Do Not Lose Your Nerve, Be Callus: Insights Into Neural Regulation of Fracture Healing
    (Springer, 2024) Nazzal, Murad K.; Morris, Ashlyn J.; Parker, Reginald S.; White, Fletcher A.; Natoli, Roman M.; Kacena, Melissa A.; Fehrenbacher, Jill C.; Orthopaedic Surgery, School of Medicine
    Purpose of review: Fractures are a prominent form of traumatic injury and shall continue to be for the foreseeable future. While the inflammatory response and the cells of the bone marrow microenvironment play significant roles in fracture healing, the nervous system is also an important player in regulating bone healing. Recent findings: Considerable evidence demonstrates a role for nervous system regulation of fracture healing in a setting of traumatic injury to the brain. Although many of the impacts of the nervous system on fracture healing are positive, pain mediated by the nervous system can have detrimental effects on mobilization and quality of life. Understanding the role the nervous system plays in fracture healing is vital to understanding fracture healing as a whole and improving quality of life post-injury. This review article is part of a series of multiple manuscripts designed to determine the utility of using artificial intelligence for writing scientific reviews.
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    Endogenous Glycoprotein GPM6a Is Involved in Neurite Outgrowth in Rat Dorsal Root Ganglion Neurons
    (MDPI, 2023-03-25) Aparicio, Gabriela I.; León, Antonella; Gutiérrez Fuster, Rocío; Ravenscraft, Baylen; Monje, Paula V.; Scorticati, Camila; Neurological Surgery, School of Medicine
    The peripheral nervous system (PNS) has a unique ability for self-repair. Dorsal root ganglion (DRG) neurons regulate the expression of different molecules, such as neurotrophins and their receptors, to promote axon regeneration after injury. However, the molecular players driving axonal regrowth need to be better defined. The membrane glycoprotein GPM6a has been described to contribute to neuronal development and structural plasticity in central-nervous-system neurons. Recent evidence indicates that GPM6a interacts with molecules from the PNS, although its role in DRG neurons remains unknown. Here, we characterized the expression of GPM6a in embryonic and adult DRGs by combining analysis of public RNA-seq datasets with immunochemical approaches utilizing cultures of rat DRG explants and dissociated neuronal cells. M6a was detected on the cell surfaces of DRG neurons throughout development. Moreover, GPM6a was required for DRG neurite elongation in vitro. In summary, we provide evidence on GPM6a being present in DRG neurons for the first time. Data from our functional experiments support the idea that GPM6a could contribute to axon regeneration in the PNS.
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    Human organ donor-derived vagus nerve biopsies allow for well-preserved ultrastructure and high-resolution mapping of myelinated and unmyelinated fibers
    (Springer Nature, 2021) Havton, Leif A.; Biscola, Natalia P.; Stern, Esther; Mihaylov, Plamen V.; Kubal, Chandrashekhar A.; Wo, John M.; Gupta, Anita; Baronowsky, Elizabeth; Ward, Matthew P.; Jaffey, Deborah M.; Powley, Terry L.; Surgery, School of Medicine
    The vagus nerve provides motor, sensory, and autonomic innervation of multiple organs, and electrical vagus nerve stimulation (VNS) provides an adjunctive treatment option for e.g. medication-refractory epilepsy and treatment-resistant depression. The mechanisms of action for VNS are not known, and high-resolution anatomical mapping of the human vagus nerve is needed to better understand its functional organization. Electron microscopy (EM) is required for the detection of both myelinated and unmyelinated axons, but access to well-preserved human vagus nerves for ultrastructural studies is sparse. Intact human vagus nerve samples were procured intra-operatively from deceased organ donors, and tissues were immediately immersion fixed and processed for EM. Ultrastructural studies of cervical and sub-diaphragmatic vagus nerve segments showed excellent preservation of the lamellated wall of myelin sheaths, and the axolemma of myelinated and unmyelinated fibers were intact. Microtubules, neurofilaments, and mitochondria were readily identified in the axoplasm, and the ultrastructural integrity of Schwann cell nuclei, Remak bundles, and basal lamina was also well preserved. Digital segmentation of myelinated and unmyelinated axons allowed for determination of fiber size and myelination. We propose a novel source of human vagus nerve tissues for detailed ultrastructural studies and mapping to support efforts to refine neuromodulation strategies, including VNS.
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    Magnetic separation of peripheral nerve-resident cells underscores key molecular features of human Schwann cells and fibroblasts: an immunochemical and transcriptomics approach
    (Nature Publishing Group, 2020-10-28) Peng, Kaiwen; Sant, David; Andersen, Natalia; Silvera, Risset; Camarena, Vladimir; Piñero, Gonzalo; Graham, Regina; Khan, Aisha; Xu, Xiao-Ming; Wang, Gaofeng; Monje, Paula V.; Neurological Surgery, School of Medicine
    Nerve-derived human Schwann cell (SC) cultures are irreplaceable models for basic and translational research but their use can be limited due to the risk of fibroblast overgrowth. Fibroblasts are an ill-defined population consisting of highly proliferative cells that, contrary to human SCs, do not undergo senescence in culture. We initiated this study by performing an exhaustive immunological and functional characterization of adult nerve-derived human SCs and fibroblasts to reveal their properties and optimize a protocol of magnetic-activated cell sorting (MACS) to separate them effectively both as viable and biologically competent cells. We next used immunofluorescence microscopy imaging, flow cytometry analysis and next generation RNA sequencing (RNA-seq) to unambiguously characterize the post-MACS cell products. High resolution transcriptome profiling revealed the identity of key lineage-specific transcripts and the clearly distinct neural crest and mesenchymal origin of human SCs and fibroblasts, respectively. Our analysis underscored a progenitor- or stem cell-like molecular phenotype in SCs and fibroblasts and the heterogeneity of the fibroblast populations. In addition, pathway analysis of RNA-seq data highlighted putative bidirectional networks of fibroblast-to-SC signaling that predict a complementary, yet seemingly independent contribution of SCs and fibroblasts to nerve regeneration. In sum, combining MACS with immunochemical and transcriptomics approaches provides an ideal workflow to exhaustively assess the identity, the stage of differentiation and functional features of highly purified cells from human peripheral nerve tissues.
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    Rapid, automated nerve histomorphometry through open-source artificial intelligence
    (Springer, 2022-04-08) Daeschler, Simeon Christian; Bourget, Marie-Hélène; Derakhshan, Dorsa; Sharma, Vasudev; Asenov, Stoyan Ivaylov; Gordon, Tessa; Cohen-Adad, Julien; Borschel , Gregory Howard; Surgery, School of Medicine
    We aimed to develop and validate a deep learning model for automated segmentation and histomorphometry of myelinated peripheral nerve fibers from light microscopic images. A convolutional neural network integrated in the AxonDeepSeg framework was trained for automated axon/myelin segmentation using a dataset of light-microscopic cross-sectional images of osmium tetroxide-stained rat nerves including various axonal regeneration stages. In a second dataset, accuracy of automated segmentation was determined against manual axon/myelin labels. Automated morphometry results, including axon diameter, myelin sheath thickness and g-ratio were compared against manual straight-line measurements and morphometrics extracted from manual labels with AxonDeepSeg as a reference standard. The neural network achieved high pixel-wise accuracy for nerve fiber segmentations with a mean (± standard deviation) ground truth overlap of 0.93 (± 0.03) for axons and 0.99 (± 0.01) for myelin sheaths, respectively. Nerve fibers were identified with a sensitivity of 0.99 and a precision of 0.97. For each nerve fiber, the myelin thickness, axon diameter, g-ratio, solidity, eccentricity, orientation, and individual x -and y-coordinates were determined automatically. Compared to manual morphometry, automated histomorphometry showed superior agreement with the reference standard while reducing the analysis time to below 2.5% of the time needed for manual morphometry. This open-source convolutional neural network provides rapid and accurate morphometry of entire peripheral nerve cross-sections. Given its easy applicability, it could contribute to significant time savings in biomedical research while extracting unprecedented amounts of objective morphologic information from large image datasets.