| Intercellular communication via chemical signaling is vital to the healthy functioning of multicellular organisms. In exocytosis, intracellular vesicles undergo Ca2+-triggered fusion with the cell plasma membrane, releasing their chemical messengers into the extracellular space. As exocytosis serves as the primary mechanism of communication at neuronal synapses, great emphasis has been placed on understanding the complex cellular regulation of this process. This dissertation focused on the use of amperometry and fast scan cyclic voltammetry at carbon-fiber microelectrodes to monitor exocytosis in real-time at both isolated neurons and chromaffin cells, well-characterized model cells for neuronal exocytosis. These techniques provide the necessary temporal resolution and sensitivity required to detect the chemical signals resulting from individual vesicular release events. Amperometric recordings at midbrain dopamine neurons showed that somatodendritic dopamine release is exocytotic, with a bimodal distribution of vesicular events. A combinatorial approach was used to demonstrate alterations in biogenic amine exocytosis in mice lacking the mitochondrial uncoupling protein UCP2 or the hormone leptin. Conversely, a mouse model of fragile X syndrome revealed no deficiencies in vesicular release mechanisms. Electrochemical methodologies were developed to distinguish catecholamine transmitters from the L-tyrosine-derived trace amines. Application of these methods revealed poor vesicular accumulation of trace amines precludes their function as false transmitters. Finally, vesicular quantal size in chromaffin cells was shown to be resistant to exogenous application of catecholamine precursors. |
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