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Browsing by Author "Mirmira, Raghu G."
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Item An Investigation of Molecular Pathways to Aid in Therapeutic Development for Neurofibromatosis Type 2(2019-05) Hawley, Eric Thomas; Clapp, D. Wade; Goebl, Mark G.; Harrington, Maureen A.; Mirmira, Raghu G.Neurofibromatosis type 2 (NF2) is an autosomal dominant cancer predisposition in which loss of heterozygosity at the NF2 gene locus leads to the development of tumors of neural crest derived origin, most commonly bilateral vestibular schwannomas. There are currently no FDA approved chemotherapeutic agents for treatment in patients with NF2. Development of therapeutic agents has been hampered by our incomplete knowledge of how Merlin, the protein product of the NF2 gene, functions as a tumor suppressor. In order develop a deeper understanding for how loss of Merlin leads to oncogenic transformation in Schwann cells we have developed a genetically engineered mouse model (GEMM) of Neurofibromatosis Type 2 in which functional expression of Merlin is lost in Schwann cell precursors. In parallel studies utilizing these mice, we have sought to understand the pathophysiology driving tumor formation in Merlin deficient Schwann cells. In Chapter 1, we explore the role of Merlin as a negative regulator of the Group A p21 activated kinases, PAK1 and PAK2. We demonstrate that PAK1, a previously well established oncogene in solid tumors and Merlin binding partner, is hyperactivated in Merlin deficient schwannomas. Through therapeutic interventions and genetic manipulations we demonstrate that inhibition of PAK1 was capable of reducing tumor formation and alleviating sensorineural hearing loss in our NF2 GEMM. In Chapter 2, we investigate the role of NF-kB inducing kinase (NIK) and NF-kB signaling in the formation and growth of Merlin deficient Schwann cell tumors. Prior work in our lab as well as by others demonstrated elevated NF-kB signaling in Merlin deficient Schwann cell tumors. We observed accumulation of a catalytically active fragment of NF-kB inducing kinase and present data that accumulation of a 55Kd constitutively active fragment of NIK is sufficient trigger wild type Schwann cells to form tumors. In vivo however, Schwann cell intrinsic expression of NIK is not required for tumor formation or growth.Item Role of the 12-lipoxygenase pathway in diabetes pathogenesis and complications(Elsevier, 2019-03) Dobrian, A. D.; Morris, M. A.; Taylor-Fishwick, D. A.; Holman, T. R.; Imai, Y.; Mirmira, Raghu G.; Nadler, J. L.; Pediatrics, School of Medicine12-lipoxygenase (12-LOX) is one of several enzyme isoforms responsible for the metabolism of arachidonic acid and other poly-unsaturated fatty acids to both pro- and anti-inflammatory lipid mediators. Mounting evidence has shown that 12-LOX plays a critical role in the modulation of inflammation at multiple checkpoints during diabetes development. Due to this, interventions to limit pro-inflammatory 12-LOX metabolites either by isoform-specific 12-LOX inhibition, or by providing specific fatty acid substrates via dietary intervention, has the potential to significantly and positively impact health outcomes of patients living with both type 1 and type 2 diabetes. To date, the development of truly specific and efficacious inhibitors has been hampered by homology of LOX family members; however, improvements in high throughput screening have improved the inhibitor landscape. Here, we describe the function and role of human 12-LOX, and mouse 12-LOX and 12/15-LOX, in the development of diabetes and diabetes-related complications, and describe promise in the development of strategies to limit pro-inflammatory metabolites, primarily via new small molecule 12-LOX inhibitors.Item The roles of pancreatic hormones in regulating pancreas development and beta cell regeneration(2015-06-16) Ye, Lihua; Anderson, Ryan M.; Mirmira, Raghu G.; Roach, Peter J.; Fueger, Patrick T.; Skalnik, David G.Diabetes mellitus is a group of related metabolic diseases that share a common pathological mechanism: insufficient insulin signaling. Insulin is a hormone secreted from pancreatic β cells that promotes energy storage and consequently lowers blood glucose. In contrast, the hormone glucagon, released by pancreatic α cells, plays a critical complementary role in metabolic homeostasis by releasing energy stores and increasing blood glucose. Restoration of β cell mass in diabetic patients via β cell regeneration is a conceptually proven approach to finally curing diabetes. Moreover, in situ regeneration of β cells from endogenous sources would circumvent many of the obstacles encountered by surgical restoration of β cell mass via islet transplantation. Regeneration may occur both by β cell self-duplication and by neogenesis from non-β cell sources. Although the mechanisms regulating the β cell replication pathway have been highly investigated, the signals that regulate β cell neogenesis are relatively unknown. In this dissertation, I have used zebrafish as a genetic model system to investigate the process of β cell neogenesis following insulin signaling depletion by various modes. Specifically, I have found that after their ablation, β cells primarily regenerate from two discrete cellular sources: differentiation from uncommitted pancreatic progenitors and transdifferentiation from α cells. Importantly, I have found that insulin and glucagon play crucial roles in controlling β cell regeneration from both sources. As with metabolic regulation, insulin and glucagon play counter-balancing roles in directing endocrine cell fate specification. These studies have revealed that glucagon signaling promotes β cell formation by increasing differentiation of pancreas progenitors and by destabilizing α cell identity to promote α to β cell transdifferentiation. In contrast, insulin signaling maintains pancreatic progenitors in an undifferentiated state and stabilizes α cell identity. Finally, I have shown that insulin also regulates pancreatic exocrine cell development. Insufficient insulin signaling destabilized acinar cell fate and impairs exocrine pancreas development. By understanding the roles of pancreatic hormones during pancreas development and regeneration can provide new therapeutic targets for in vivo β cell regeneration to remediate the devastating consequences of diabetes.