Browsing by Subject "Nerves, Peripheral"
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Item The function of ASCL1 in pregnancy-induced maternal liver growth(2014) Lee, Joonyong; Dai, Guoli; Belecky-Adams, Teri; Meyer, Jason S.The maternal liver shows marked growth during pregnancy to accommodate the development and metabolic needs of the placenta and fetus. Previous study has shown that the maternal liver grows proportionally to the increase in body weight during gestation by hyperplasia and hypertrophy of hepatocytes. As the maternal liver is enlarged, the transcript level of Ascl1, a transcription factor essential to progenitor cells of the central nervous system and peripheral nervous system, is highly upregulated. The aims of the study were to (1) identify hepatic Ascl1-expressing cells, and (2) study the functions of Ascl1 in maternal liver during pregnancy. In situ hybridization shows that most cell types (parenchymal, nonparenchymal, and mesothelial cells) express Ascl1 mRNA in maternal livers during gestation and in male regenerating livers. Notably, hepatic mesothelial cells abundantly express Ascl1 during pregnancy and liver regeneration. Inducible ablation of Ascl1 gene during pregnancy results in maternal liver enlargement, litter size reduction, and fetal growth retardation. In addition, maternal hepatocytes deficient in Ascl1 gene lack majority of their cytosols and exhibit β-catenin nuclear translocation, while maintaining their cellular boundary and identity. In summary, in both maternal liver during pregnancy and regenerating liver, the expression of Ascl1 is induced in most cell types. Mesothelial cells are potential origin of Ascl1-expressing cells. Ascl1 gene is essential for the progression of normal pregnancyItem An in vitro study of the mechanisms that underlie changes in neuronal sensitivity and neurite morphology following treatment with microtubule targeting agents(2014-11) Pittman, Sherry Kathleen; Fehrenbacher, Jill C.; Cummins, Theodore R.; Hingtgen, Cynthia M.; Hudmon, Andrew; Vasko, Michael R.Microtubule targeting agents (MTAs) are chemotherapeutics commonly used in the treatment of breast, ovarian, lung, and lymphoma cancers. There are two main classes of MTAs based upon their effects on microtubule stability. The two classes are the destabilizing agents, which include the drug vincristine, and the stabilizing agents, which include paclitaxel and epothilone B. These drugs are highly effective antineoplastics, but their use is often accompanied by several side effects, one of which is peripheral neuropathy. Peripheral neuropathy can be characterized by burning pain, tingling, loss of proprioception, or numbness in the hands and feet. In some patients, the MTA-induced peripheral neuropathy is debilitating and dose-limiting; however, there are no effective prevention strategies or treatment options for peripheral neuropathy as the mechanisms mediating this side effect are unknown. The goal of this work was to investigate MTA-induced effects on neuronal activity and morphology in order to elucidate the underlying mechanisms involved in the development of MTA-induced peripheral neuropathy. As an indicator of sensory neuronal activity, the basal and stimulated release of the putative nociceptive peptide, calcitonin gene-related peptide (CGRP), was measured from sensory neurons in culture after exposure to the MTAs paclitaxel, epothilone B, and vincristine. Neurite length and branching were also measured in sensory neuronal cultures after treatment with these MTAs. The results described in this thesis demonstrate that MTAs alter the stimulated release of CGRP from sensory neurons in differential ways depending on the MTA agent employed, the CGRP evoking-stimulus used, the concentration of the MTA agent, the duration of exposure to the MTA agent, and the presence of NGF. It was also observed that MTA agents decrease neurite length and branching, independent of the concentration of NGF in the culture media. Thus, this thesis describes MTA-induced alterations of sensory neuronal sensitivity and neurite morphology and begins to elucidate the underlying mechanisms involved in MTA-induced alterations of sensory neurons. These findings will undoubtedly be used to help elucidate the mechanisms underlying MTA-induced peripheral neuropathy.Item The role of high mobility group box 1 and toll like receptor 4 in a rodent model of neuropathic pain(2013-11-20) Feldman, Polina; Oxford, Gerry S.; White, Fletcher A.; Khanna, Rajesh; Jones, Kathryn J.; Shi, RiyiNeuropathic pain is a serious health problem that greatly impairs quality of life. The International Association for the Study of Pain (IASP) defines neuropathic pain as ‘pain arising as a direct consequence of a lesion or disease affecting the nervous system’. It is important to note that with neuropathy the chronic pain is not a symptom of injury, but rather the pain is itself a disease process. Novel interactions between the nervous system and elements of the immune system may be key facets to a chronic disease state. One of particular note is the recent finding supporting an interaction between an immune response protein high mobility group box 1 (HMGB1) and Toll like receptor 4 (TLR4). HMGB1 is an endogenous ligand for TLR4 that influences the induction of cytokines in many non-neuronal cells. After tissue damage or injury, HMGB1 may function as a neuromodulatory cytokine and influence the production of pro-nociceptive mediators altering the state of sensory neurons. Very little is known about the HMGB1-TLR4 interaction in sensory neurons and whether chronic changes in endogenous HMGB1 signaling influence the establishment of neuropathic pain. This thesis aims to determine whether a physiologically relevant neuroimmune interaction involving endogenous HMGB1 and TLR4 in the dorsal root ganglia is altered following a tibial nerve injury model of neuropathic pain. I hypothesized that sensitization of sensory neurons following a peripheral nerve injury is dependent on endogenous HMGB1 and TLR4. The studies presented here demonstrate that HMGB1 undergoes subcellular redistribution from the nucleus to the cytoplasm in primary afferent neurons following peripheral nerve injury. Further, the presence of extracellular HMGB1 may directly contribute to peripheral sensitization and injury-induced tactile hyperalgesia. Though thought to be important as a pivotal receptor for HMGB1 activation, neuronal protein expression of TLR4 does not appear to influence the effects of HMGB1-dependent behavioral changes following peripheral nerve injury. Taken together, these findings suggest that extracellular HMGB1 may serve as an important endogenous cytokine that contributes to ongoing pain hypersensitivity in a rodent model of neuropathic pain.Item Synthesis and axoplasmic transport of proteins and glycoproteins in peripheral nerve(1980) Stromska, Daniel Peter