Browsing by Author "Hingtgen, Cynthia M., 1966-"
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Item Dissecting Neurofibromatosis Type 1 Related Vasculopathy(2009-12) Lasater, Elisabeth A.; Ingram, David A., Jr.; Conway, Simon J.; Kapur, Reuben; Clapp, D. Wade; Hingtgen, Cynthia M., 1966-Neurofibromatosis type 1 (NF1) is a genetic disorder resulting from mutations in the tumor suppressor gene NF1. NF1 encodes the protein neurofibromin, which functions to negatively regulate p21Ras signaling. NF1 has a wide range of clinical manifestations, including vascular disease, which is characterized by neointima formation and subsequent vessel occlusion. Despite numerous clinical observations of NF1 vasculopathy, the pathogenesis of vascular lesion formation remains unclear. To determine the consequence of Nf1 haploinsufficiency in vascular disease, we generated an in vivo model for dissecting vascular lesion formation. In response to mechanical arterial injury, Nf1+/- mice have significantly enhanced neointima formation characterized by an accumulation of vascular smooth muscle cells (VSMCs) and excessive cellular proliferation and Ras activation. Further, using the pharmacological antagonist, imatinib mesylate, we identified that neointima formation in Nf1+/- mice was directly dependent on Ras signaling through either the platelet derived growth factor β receptor (PDGF-βR) and/or the C-kit receptor activation. These observations identify a molecular mechanism of neointima formation given that our group has previously demonstrated that Nf1+/- VSMCs have hyperactive Ras signaling through PDGF-βR activation and Nf1+/- bone marrow derived cells (BMDCs) have increased recruitment and survival in response to C-kit activation compared to WT controls. In order to dissect the cellular contribution to neointima formation, we utilized cre/lox technology and adoptive hematopoietic stem cell transfer techniques to genetically delete one allele of Nf1 in endothelial cells, VSMCs or BMDCs individually to test which cell lineage is predominant in NF1 vasculopathy. Surprisingly, in response to carotid artery injury, heterozygous inactivation of Nf1 in BMDCs alone was necessary and sufficient for neointima formation. Specifically, Nf1 haploinsufficiency in BMDCs resulted in an infiltration of macrophages into the neointima, providing evidence of “vascular inflammation” as factor in NF1 vasculopathy. Further, we demonstrate for the first time that NF1 patients have evidence of chronic inflammation determined by increased concentrations of circulating monocytes and pro-inflammatory cytokines. In sum, we provide genetic and cellular evidence of vascular inflammation in NF1 patients and Nf1+/- mice and provide a framework for understanding the pathogenesis of NF1 vasculopathy and potential therapeutic and diagnostic interventions.Item Elucidating mechanisms that lead to persistent anxiety-like behavior in rats following repeated activation of corticotropin-releasing factor receptors in the basolateral amygdala(2012-03-16) Gaskins, Denise; Shekhar, Anantha, 1957-; Harris, Robert A. (Robert Allison), 1939-; Hingtgen, Cynthia M., 1966-; Truitt, William A.Anxiety disorders are estimated to impact 1 in 4 individuals within their lifetime. For some individuals, repeated episodes of the stress response leads to pathological anxiety and depression. The stress response is linked to increased levels of corticotropin-releasing factor (CRF) in the basolateral nucleus of the amygdala (BLA), a putative site for regulating anxiety and associative processes related to aversive emotional memories, and activation of CRF receptors in the BLA of rats produces anxiety-like behavior. Mimicking repeated episodes of the stress response, sub-anxiogenic doses of urocortin 1 (Ucn1), a CRF receptor agonist, are microinjected into the BLA of rats for five consecutive days, a procedure called priming. This results in 1) behavioral sensitization, such that a previously non-efficacious dose of Ucn1 will elicit anxiety-like response after the 3rd injection and 2) the development of a persistent anxiety-like phenotype that lasts at least five weeks after the last injection without any further treatment. Therefore, the purpose of this thesis was to identify mechanisms involved in the Ucn1-priming-induced anxiogenesis. The first a set of experiments revealed that the anxiety-like behavior was not due to aversive conditioning to the context or partner cues of the testing environment. Next, Ucn1-priming-induced gene expression changes in the BLA were identified: mRNA expression for Sst2, Sst4, Chrna4, Chrma4, and Gabrr1 was significantly reduced in Ucn1-primed compared to Vehicle-primed rats. Of these, Sst2 emerged as the primary receptor of interest. Subsequent studies found that antagonizing the Sstr2 resulted in anxiety-like behavior and activation of Sstr2 blocked acute Ucn1-induced anxiety-like responses. Furthermore, pretreatment with a Sstr2 agonist delayed the behavioral sensitization observed in Ucn1-induced priming but did not stop the development of persistent anxiety-like behavior or the Ucn1-priming-induced decrease in the Sstr2 mRNA. These results suggest that the decrease in Sstr2 mRNA is associated with the expression of persistent anxiety-like behavior but dissociated from the mechanisms causing the behavioral sensitization. Pharmacological studies confirmed that a reduced Sstr2 mediated effect in the BLA is likely to play a role in persistent anxiety and should be investigated further.Item Paclitaxel alters the function of the small diameter sensory neurons(2011-07-08) Gracias, Neilia; Vasko, Michael R.; Brustovetsky, Nickolay; Hingtgen, Cynthia M., 1966-; Hudmon, Andrew; Kelley, Mark Richard, 1957-Although paclitaxel is a commonly used anti-neoplastic agent for the treatment of solid tumors, therapy often results in a number of side effects, the most debilitating of which is peripheral neuropathy. Peripheral neuropathy is defined as a pathology of peripheral nerves, and, depending on the type of nerves damaged, the neuropathy can be classified as sensory, motor, or autonomic neuropathy. In the case of peripheral neuropathy induced by paclitaxel, the symptoms are experienced in the extremities and are sensory in nature. Patients undergoing chemotherapy with paclitaxel often report sensory disturbances such as burning, tingling, numbness, a diminished sensation to pain and temperature, loss of vibration sense, loss of proprioception, and loss of deep tendon reflexes. Electrophysiological abnormalities including decreased sensory nerve action potential amplitude and conduction confirm damage to large myelinated fibers. However, the involvement of damage to small diameter sensory neurons in the etiology of paclitaxel – induced peripheral neuropathy is still controversial. Therefore, experiments were performed to determine if paclitaxel alters the function of small diameter sensory neurons and to examine the mechanisms responsible for the change in function. vi Sensory neuron mediated vasodilatation in paclitaxel – injected animals was examined as an indirect measure of calcitonin gene related peptide (CGRP) release and therefore of sensory neuron function. CGRP release was also directly measured from central terminals in the spinal cord. To examine mechanisms of paclitaxel – induced sensory neuron damage, CGRP release and neurite length was examined in paclitaxel – treated sensory neurons in culture. The results demonstrate that (1) paclitaxel decreases the ability of small diameter sensory neurons to produce an increase in blood flow in the skin; (2) paclitaxel alters the release of CGRP from the small diameter sensory neurons; (3) paclitaxel causes the neuronal processes of isolated sensory neurons to degenerate. This dissertation provides novel information showing that paclitaxel alters the function of small diameter sensory neurons and thus provides a better understanding of the mechanisms mediating the sensory disturbances characteristic of peripheral neuropathy resulting from chemotherapy with paclitaxel.Item RET-DEPENDENT AND RET-INDEPENDENT MECHANISMS OF GFL-INDUCED ENHANCEMENT IN THE CAPSAICIN STIMULATED-RELEASE OF iCGRP FROM SENSORY NEURONS(2010-02-02T22:18:31Z) Schmutzler, Brian S.; Hingtgen, Cynthia M., 1966-; Cummins, Theodore R.; Vasko, Michael R.; Broustovetski, Nikolai; Hudmon, AndyThe glial cell line-derived neurotrophic factor (GDNF) family ligands (GFLs) are peptides implicated in the inflammatory response. They are released in increased amounts during inflammation and induce thermal hyperalgesia. Whether these molecules directly affect the sensitivity of primary nociceptive sensory neurons is unknown. This information could provide a link between increased inflammation-induced release of GFLs and their ability to promote inflammatory hyperalgesia. These molecules bind to one of four GFRα receptor subtypes, and this GFL-GFRα complex often translocates to the receptor tyrosine kinase, Ret. The focus of this dissertation was to determine whether GFLs modulate the stimulated-release of calcitonin gene-related peptide (CGRP). Isolated sensory neurons and freshly dissociated spinal cord tissue were used to examine the enhancement in stimulated-release of CGRP, a measure of sensitization. Exposure of isolated sensory neurons to GDNF, neurturin, and artemin, enhanced the capsaicin stimulated-release of immunoreactive CGRP (iCGRP). Sensitization by GFLs occurred in freshly dissociated spinal cord tissue. Persephin, another member of the GFL family, did not enhance stimulated-release of iCGRP. These results demonstrate that specific GFLs are mediators of neuronal sensitivity. The intracellular signaling pathways responsible for this sensitization were also evaluated. Inhibition of the mitogen activated protein kinase (MAPK)/extracellular signal-related kinase 1/2 (Erk 1/2) pathway selectively abolished the enhancement of CGRP release by GDNF. NTN-induced sensitization was abolished by inhibition of the phosphatidylinositol-3-kinase (PI-3K) pathway. Reduction in Ret abolished the GDNF-induced sensitization, but did not fully inhibit NTN or ART-induced sensitization. Inhibition of other cell surface receptors (neural cell adhesion molecule (NCAM), and Integrin β-1) had distinct effects on the sensitization capability of each of the GFLs. Ret and NCAM inhibition in combination abolished ART-induced sensitization. It was necessary to inhibit Ret, NCAM, and Integrin β-1 to prevent the NTN-induced sensitization. These data demonstrate that the GFLs use distinct signaling mechanisms to induce the sensitization of nociceptive sensory neurons. The work presented in this thesis provides the first evidence for these novel and distinct Ret-independent pathways for GFL-induced actions and provides insight into the mechanism of sensory neuronal sensitization in general.Item The role of SMF 1, SMF-2, SMF-3 in metal-induced whole animal vulnerability and dopamine neuron degeneration in Caenorhabditis elegans(2012-12-04) LeVora, Jennifer K.; Nass, Richard M.; Nicol, Grant D.; Hingtgen, Cynthia M., 1966-The etiology of many neurodegenerative diseases is unknown, but a number of studies indicate that a combination of both genetic and environmental factors contribute to the progression of disease. Exposure to environmental metals, such as Mn2+, Fe2+, Cu2+, and Al3+, has been shown to increase cell death that is characteristic of neurodegenerative disorders such as AD, PD, Wilson’s disease and Menkes disease. These metals are important in numerous biological processes in the brain and their homeostasis is regulated through multiple mechanisms of transport, storage, and secretion. The vertebrate divalent metal transporter-1 (DMT-1) has been implicated in transport and homeostasis of these divalent cations. In these studies I utilize Caenorhabditis elegans (C. elegans) to show that long term exposure to Mn2+ decreases animal viability in a dose-dependent manner, and I demonstrate that C. elegans homologues to DMT-1, SMF-1, SMF-2, and SMF-3, play specific roles in divalent metal ion-induced DA neurodegeneration. I show that SMF-1 contributes to Fe2+-induced DA neuron degeneration, SMF-3 contributes to Al3+-induced DA neuron degeneration, and both SMF-2 and DAT-1 contribute to Cu2+-induced DA neuron cell death. These studies utilize C. elegans as a powerful model to characterize molecules and pathways involved in metal toxicity and metal-induced DA neuron degeneration.