High-throughput screens to identify modulators of phospholipase C isozymes
Univ Of North Carolina Chapel Hill, Chapel Hill NC
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Abstract
DESCRIPTION (provided by applicant): Humans express thirteen phospholipase C (PLC) isozymes that can be divided into six classes (PLC-(, -(, -(, -(, -( and -() based upon sequence similarity. PLC signaling cascades are responsible for numerous cellular and physiological processes including: cell motility and migration, proliferation, immune response, fertilization, vasculogenesis, brain development, muscle contraction, and hematopoiesis. Consequently, abnormal regulation of PLC enzymes results in a variety of diseases such as breast, prostate, and pancreatic cancers, cardiac failure, renal failure, and epilepsy. Due to the pathological cellular responses that result from improper signaling through PLC enzymes, these enzymes are key drug targets. However, to date, there are no selective small molecule inhibitors for PLC isozymes, primarily due to the lack of a high-throughput screening assay for PLC isozymes. Within this proposal, we describe the development of a novel, soluble small molecule, WH-15, that is hydrolyzed with similar kinetics as the endogenous PLC substrate, PtdIns (4, 5) P2, to yield an easily detectable fluorescent product. The focus of this proposal is to develop a fluorescent assay and integrate it with a series of secondary assays for a complete set of high-throughput screening protocols to identify modulators of PLC activity. We will accomplish the goals of this proposal through two aims. In Specific Aim 1, we will optimize our assays with WH-15 to enable them suitable for high throughput screens in 384-well format and verify them by screening the LOPAC1280 library with PLC- (2 and PLC- (1. In Specific Aim 2, we will develop a series of secondary assays to complement the fluorescent assay from Aim 1 using a diverse 5000 compound library. Through the completion of these aims, we will for the first time, have a robust, fluorogenic assay and a complete screening protocol suitable for high-throughput screening to identify PLC selective modulators. These small molecules could serve as probes to dissect PLC signaling in various disease states including the development and progression of breast and prostate cancers, and act as potential lead compounds for drug development.
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