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ROLES OF GFL-RET SIGNALING IN BLADDER SENSATION

$331,688R01FY2016DKNIH

Washington University, Saint Louis MO

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Abstract

DESCRIPTION (provided by applicant): Abnormal sensory activity plays a major role in bladder diseases such as interstitial cystitis/painful bladder syndrome (IC/PBS), sensory neuropathy in uremia, and age related bladder dysfunction in neurodegenerative diseases such as Parkinson's. Identifying molecular and genetic mechanisms regulating urinary tract sensation in normal and disease states is essential for rational design of therapies for bladder sensory disorders and risk stratification. The glial cell line-derived neurotrophic factor (GDNF) family of ligands (GFLs) are neurotrophic factors that bind to one of the coreceptors GFR? (1-4) and activate the receptor tyrosine kinase RET. GFL-RET signaling promotes sensory neuron survival and axonal growth and prevents axonal degeneration. We demonstrated that RET activation leads to phosphorylation of key docking tyrosines that bind intracellular adaptors and activate specific signal transduction pathways such as PLC? and PI3K/MAPK to regulate proliferation, survival and migration of autonomic and eneteric neurons, and collecting system progenitors. We discovered distinct tissue-specific roles of Ret-docking tyrosines in the urinary tract and autonomic ganglia and that Ret is important in somatic pain sensation. Our preliminary data show high RET expression in human sensory ganglia (DRG) and in urothelial, submucosal and myenteric nerves in the bladder suggesting an unexplored role for GFL-RET signaling in bladder function. We observed that Ret-null mice have severely reduced bladder innervation. Using our unique Ret mutant mice we found that Ret+ sensory neurons innervate the bladder and that Gdnf haploinsufficiency reduces pain in an acute cystitis model. These results collectively support an important role for GFL-RET signaling in bladder function and health. We hypothesize that GFL-RET signaling has a critical role in regulating bladder sensation in naïve and injured states, and that RET mutations found in humans affect the health of sensory neurons. Three specific aims are proposed. In Aim 1 we will identify physiologically relevant RET-activated signaling pathways that regulate bladder sensation in normal and injured states using a battery of unique RET-mutant mice. In Aim 2 we will determine the regulation of select ion channels (TRPV1, TRPA1 and voltage-gated sodium and potassium channels) by specific RET- activated pathways in bladder afferent DRG neurons using calcium imaging and electrophysiology analysis. In Aim 3 we will decipher the roles of RET mutations found in humans in primary sensory neuron survival, axonal growth and degeneration. These results will provide insights into how GFL-RET signaling can be targeted for therapy in sensory dysfunction in bladder diseases. GFLs are currently in clinical trials for neurodegenerative disease and chronic pain. This will allow accelerated clinical translation of the proposed studies.

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