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Photonic probe and techniques for biological imaging applications

$333,900R01FY2014GMNIH

Ut Southwestern Medical Center, Dallas TX

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Abstract

DESCRIPTION (provided by applicant): The long term goal of this project is to engineer photonic probes to enable biological discovery. This proposal represents an integral approach by combining molecular design, organic synthesis, optogenetics, and advanced fluorescence microscopy to develop fluorescent probes and imaging techniques, and to apply them to study an important function of gap junction coupling: how gap junction intercellular communication mediates synchronized cell secretion. To this end, we will first develop a new class of fluorescent probes for imaging the dynamics of regulated exocytosis with very high sensitivity and spatiotemporal resolution. The development is based on the observation that a number of secretory cells, including pancreatic islet beta cells, contain a high level of zinc ion (Zn2+) in their secretory granules. Upon stimulation, these cells release the contents of their secretory granules into extracellular medium, during which Zn2+ is co-released. By engineering zinc sensors to specifically report local Zn2+ rise near plasma membranes, we are able to monitor Zn2+ granule release continuously at cellular and subcellular resolution. To examine how gap junction coupling regulates synchronized secretion, we will apply the technique of optogenetics to control the membrane excitability, and to integrate the method of photo-activation with zinc imaging. Combined with pharmacological and genetic approaches to manipulate cell coupling strength, we will investigate how gap junction coupling synchronizes cell secretion. Finally, to characterize how cells coordinate their secretory activity in physiological preparations or in tissues where normal cell-cell contact is maintained, we will use imaging methods of high spatial selectivity, including two photon laser scanning microscopy and spinning disk confocal microscopy, to examine Zn2+ granule release in three dimensions at cellular and subcellular resolution. New probes and methods developed here should have broad applications in cellular and neuronal biology and in different biological systems.

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