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Item Identification of a resilient mouse facial motoneuron population following target disconnection by injury or disease(IOS, 2018) Setter, Deborah O.; Haulcomb, Melissa M.; Beahrs, Taylor; Meadows, Rena M.; Schartz, Nicole D.; Custer, Sara K.; Sanders, Virginia M.; Jones, Kathryn J.; Anatomy and Cell Biology, IU School of MedicineBackground: When nerve transection is performed on adult rodents, a substantial population of neurons survives short-term disconnection from target, and the immune system supports this neuronal survival, however long-term survival remains unknown. Understanding the effects of permanent axotomy on cell body survival is important as target disconnection is the first pathological occurrence in fatal motoneuron diseases such as amyotrophic lateral sclerosis (ALS) and spinal muscular atrophy (SMA). Objective: The goal of this study was to determine if facial motoneurons (FMN) could survive permanent target disconnection up to 26 weeks post-operation (wpo) after facial nerve axotomy (FNA). In addition, the potentially additive effects of immunodeficiency and motoneuron disease on post-axotomy FMN survival were examined. Methods: This study included three wild type (WT) mouse strains (C57BL/6J, B6SJL, and FVB/NJ) and three experimental models (RAG-2-/-: immunodeficiency; mSOD1: ALS; Smn-/-/SMN2+/+: SMA). All animals received a unilateral FNA, and FMN survival was quantified at early and extended post-operative timepoints. Results: In the C57BL/6J WT group, FMN survival significantly decreased at 10 wpo (55 ± 6%), and then remained stable out to 26 wpo (47 ± 6%). In the RAG-2-/- and mSOD1 groups, FMN death occurred much earlier at 4 wpo, and survival plateaued at approximately 50% at 10 wpo. The SMA model and other WT strains also exhibited approximately 50% FMN survival after FNA. Conclusion: These results indicate that immunodeficiency and motoneuron disease accelerate axotomy-induced neuron death, but do not increase total neuron death in the context of permanent target disconnection. This consistent finding of a target disconnection-resilient motoneuron population is prevalent in other peripheral nerve injury models and in neurodegenerative disease models as well. Characterization of the distinct populations of vulnerable and resilient motoneurons may reveal new therapeutic approaches for injury and disease.Item SOD1G93A transgenic mouse CD4+ T cells mediate neuroprotection after facial nerve axotomy when removed from a suppressive peripheral microenvironment(Elsevier B.V., 2014-08) Mesnard-Hoaglin, Nichole A.; Xin, Junping; Haulcomb, Melissa M.; Batka, Richard J.; Sanders, Virginia M.; Jones, Kathryn J.; Department of Anatomy & Cell Biology, IU School of MedicineAmyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease involving motoneuron (MN) axonal withdrawal and cell death. Previously, we established that facial MN (FMN) survival levels in the SOD1G93A transgenic mouse model of ALS are reduced and nerve regeneration is delayed, similar to immunodeficient RAG2-/- mice, after facial nerve axotomy. The objective of this study was to examine the functionality of SOD1G93A splenic microenvironment, focusing on CD4+ T cells, with regard to defects in immune-mediated neuroprotection of injured MN. We utilized the RAG2-/- and SOD1G93A mouse models, along with the facial nerve axotomy paradigm and a variety of cellular adoptive transfers, to assess immune-mediated neuroprotection of FMN survival levels. We determined that adoptively transferred SOD1G93A unfractionated splenocytes into RAG2-/- mice were unable to support FMN survival after axotomy, but that adoptive transfer of isolated SOD1G93A CD4+ T cells could. Although WT unfractionated splenocytes adoptively transferred into SOD1G93A mice were able to maintain FMN survival levels, WT CD4+ T cells alone could not. Importantly, these results suggest that SOD1G93A CD4+ T cells retain neuroprotective functionality when removed from a dysfunctional SOD1G93A peripheral splenic microenvironment. These results also indicate that the SOD1G93A central nervous system microenvironment is able to re-activate CD4+ T cells for immune-mediated neuroprotection when a permissive peripheral microenvironment exists. We hypothesize that dysfunctional SOD1G93A peripheral splenic microenvironment may compromise neuroprotective CD4+ T cell activation and/or differentiation, which, in turn, results in impaired immune-mediated neuroprotection for MN survival after peripheral axotomy in SOD1G93A mice.