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1. Invasion of microglia/macrophages and granulocytes into the Mauthner axon myelin sheath following spinal cord injury of the adult goldfish, Carassius auratus

   https://doi.org/10.1002/jmor.21086  

   Koganti, Lahari ; Liu, Jun ; DeMajewski, Andrea ; Agostini, Mark A. ; Wong, Tina W. ; Faber, Donald S. ; Zottoli, Steven J. ( November 2019 , Journal of Morphology)

   Rapid activation of resident glia occurs after spinal cord injury. Somewhat later, innate and adaptive immune responses occur with the invasion of peripheral immune cells into the wound site. The activation of resident and peripheral immune cells has been postulated to play harmful as well as beneficial roles in the regenerative process. Mauthner cells, large identifiable neurons located in the hindbrain of most fish and amphibians, provided the opportunity to study the morphological relationship between reactive cells and Mauthner axons (M‐axons) severed by spinal cord crush or by selective axotomy. After crossing in the hindbrain, the M‐axons of adult goldfish,Carassius auratus, extend the length of the spinal cord. Following injury, the M‐axon undergoes retrograde degeneration within its myelin sheath creating an axon‐free zone (proximal dieback zone). Reactive cells invade the wound site, enter the axon‐free dieback zone and are observed in the vicinity of the retracted M‐axon tip as early as 3 hr postinjury. Transmission electron microscopy allowed the detection of microglia/macrophages and granulocytes, some of which appear to be neutrophil‐like, at each of these locations. We believe that this is the first report of the invasion of such cells within the myelin sheath of an identifiable axon in the vertebrate central nervous system (CNS). We speculate that microglia/macrophages and granulocytes that are attracted within a few hours to the damaged M‐axon are part of an inflammatory response that allows phagocytosis of debris and plays a role in the regenerative process. Our results provide the baseline from which to utilize immunohistochemical and genetic approaches to elucidate the role of non‐neuronal cells in the regenerative process of a single axon in the vertebrate CNS.

    

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2. Cortical stimulation leads to shortened myelin sheaths and increased axonal branching in spared axons after cervical spinal cord injury

   https://doi.org/10.1002/glia.24376  

   Kondiles, B. R. ; Murphy, R. L. ; Widman, A. J. ; Perlmutter, S. I. ; Horner, P. J. ( April 2023 , Glia)

   Neural activity and learning lead to myelin sheath plasticity in the intact central nervous system (CNS), but this plasticity has not been well‐studied after CNS injury. In the context of spinal cord injury (SCI), demyelination occurs at the lesion site and natural remyelination of surviving axons can take months. To determine if neural activity modulates myelin and axon plasticity in the injured, adult CNS, we electrically stimulated the contralesional motor cortex at 10 Hz to drive neural activity in the corticospinal tract of rats with sub‐chronic spinal contusion injuries. We quantified myelin and axonal characteristics by tracing corticospinal axons rostral to and at the lesion epicenter and identifying nodes of Ranvier by immunohistochemistry. Three weeks of daily stimulation induced very short myelin sheaths, axon branching, and thinner axons outside of the lesion zone, where remodeling has not previously been reported. Surprisingly, remodeling was particularly robust rostral to the injury which suggests that electrical stimulation can promote white matter plasticity even in areas not directly demyelinated by the contusion. Stimulation did not alter myelin or axons at the lesion site, which suggests that neuronal activity does not contribute to myelin remodeling near the injury in the sub‐chronic period. These data are the first to demonstrate wide‐scale remodeling of nodal and myelin structures of a mature, long‐tract motor pathway in response to electrical stimulation. This finding suggests that neuromodulation promotes white matter plasticity in intact regions of pathways after injury and raises intriguing questions regarding the interplay between axonal and myelin plasticity.

    

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3. Generating intravital super-resolution movies with conventional microscopy reveals actin dynamics that construct pioneer axons

   https://doi.org/10.1242/dev.171512  

   Zhang, Yide ; Nichols, Evan L. ; Zellmer, Abigail M. ; Guldner, Ian H. ; Kankel, Cody ; Zhang, Siyuan ; Howard, Scott S. ; Smith, Cody J. ( March 2019 , Development)

   Super-resolution microscopy is broadening our in-depth understanding of cellular structure. However, super-resolution approaches are limited, for numerous reasons, from utilization in longer-term intravital imaging. We devised a combinatorial imaging technique that combines deconvolution with stepwise optical saturation microscopy (DeSOS) to circumvent this issue and image cells in their native physiological environment. Other than a traditional confocal or two-photon microscope, this approach requires no additional hardware. Here, we provide an open-access application to obtain DeSOS images from conventional microscope images obtained at low excitation powers. We show that DeSOS can be used in time-lapse imaging to generate super-resolution movies in zebrafish. DeSOS was also validated in live mice. These movies uncover that actin structures dynamically remodel to produce a single pioneer axon in a “top-down” scaffolding event. Further, we identify an F-actin population – stable base clusters – that orchestrate that scaffolding event. We then identify that activation of Rac1 in pioneer axons destabilizes stable base clusters and disrupts pioneer axon formation. The ease of acquisition and processing with this approach provides a universal technique for biologists to answer questions in living animals. 

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4. Individual neuronal subtypes control initial myelin sheath growth and stabilization

   https://doi.org/10.1186/s13064-020-00149-3  

   Nelson, Heather N. ; Treichel, Anthony J. ; Eggum, Erin N. ; Martell, Madeline R. ; Kaiser, Amanda J. ; Trudel, Allie G. ; Gronseth, James R. ; Maas, Samantha T. ; Bergen, Silas ; Hines, Jacob H. ( December 2020 , Neural Development)

   null (Ed.)

   Abstract Background In the developing central nervous system, pre-myelinating oligodendrocytes sample candidate nerve axons by extending and retracting process extensions. Some contacts stabilize, leading to the initiation of axon wrapping, nascent myelin sheath formation, concentric wrapping and sheath elongation, and sheath stabilization or pruning by oligodendrocytes. Although axonal signals influence the overall process of myelination, the precise oligodendrocyte behaviors that require signaling from axons are not completely understood. In this study, we investigated whether oligodendrocyte behaviors during the early events of myelination are mediated by an oligodendrocyte-intrinsic myelination program or are over-ridden by axonal factors. Methods To address this, we utilized in vivo time-lapse imaging in embryonic and larval zebrafish spinal cord during the initial hours and days of axon wrapping and myelination. Transgenic reporter lines marked individual axon subtypes or oligodendrocyte membranes. Results In the larval zebrafish spinal cord, individual axon subtypes supported distinct nascent sheath growth rates and stabilization frequencies. Oligodendrocytes ensheathed individual axon subtypes at different rates during a two-day period after initial axon wrapping. When descending reticulospinal axons were ablated, local spinal axons supported a constant ensheathment rate despite the increased ratio of oligodendrocytes to target axons. Conclusion We conclude that properties of individual axon subtypes instruct oligodendrocyte behaviors during initial stages of myelination by differentially controlling nascent sheath growth and stabilization. 

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5. Axon determination of subtype specific myelin ensheathment and pruning

   Nelson, HN ; Treichel, AJ ; Eggum, EN ; Martell, MR ; Kaiser, AJ ; Trudel, AG ; Gronseth, JR ; Maas, ST ; Bergen, S ; Hines, JH ( January 2019 , Annual meeting of the Society for Neuroscience)

   In the developing central nervous system, pre-myelinating oligodendrocytes contact and sample candidate nerve axons by extending and retracting process extensions. Some contacts stabilize and mature, leading to the initiation of axon wrapping, myelin sheath formation, and sheath elongation by oligodendrocytes. Although axonal signals influence the overall process of myelination, which precise steps and oligodendrocyte cell behaviors require signaling from axons is incompletely understood. In this study, we investigated whether cell behaviors during the early events of myelination involve input from axons or are mediated by an oligodendrocyte-autonomous myelination program. To address this, we utilized in vivo time-lapse imaging in embryonic and larval zebrafish during the initial hours and days of axon wrapping and myelination. Transgenic reporter lines marked individual axon subtypes or oligodendrocyte membranes. In the larval zebrafish spinal cord, individual axon subtypes supported distinct nascent sheath growth rates and pruning frequencies. Oligodendrocytes ensheathed individual axon subtypes at different rates during a two-day period after initial axon wrapping. When the ratio of oligodendrocytes to target axons was increased by ablating spinal projection axons, local spinal neuron axons supported a constant ensheathment rate despite the increased ratio of oligodendrocytes to target axons. We conclude that properties of individual axon subtypes instruct oligodendrocyte behaviors during initial stages of myelination by differentially controlling nascent sheath growth and stabilization. 

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