Abstract
The pattern of stimulation defines important characteristics of the secretory process in neurons and neuroendocrine cells, including the pool of secretory vesicles being recruited, the type and amount of transmitters released, the mode of membrane retrieval, and the mechanisms associated with vesicle replenishment. This review analyzes the mechanisms that regulate these processes in chromaffin cells, as well as in other neuroendocrine and neuronal models. A common factor in these mechanisms is the spatial and temporal distribution of the Ca(2+) signal generated during cell stimulation. For instance, neurosecretory cells and neurons have pools of vesicles with different locations with respect to Ca(2+) channels, and those pools are therefore differentially recruited following different patterns of stimulation. In this regard, a brief stimulus will induce the exocytosis of a small pool of vesicles that is highly coupled to voltage-dependent Ca(2+) channels, whereas longer or more intense stimulation will provoke a global Ca(2+) increase, promoting exocytosis irrespective of vesicle location. The pattern of stimulation, and therefore the characteristics of the Ca(2+) signal generated by the stimulus also influence the mode of exocytosis and the type of endocytosis. Indeed, low-frequency stimulation favors kiss-and-run exocytosis and clathrin-independent fast endocytosis, whereas higher frequencies promote full fusion and clathrin-dependent endocytosis. This latter type of endocytosis is accelerated at high-frequency stimulation. Synaptotagmins, calcineurin, dynamin, complexin, and actin remodeling, appear to be involved in the mechanisms that determine the response of these processes to Ca(2+) . In chromaffin cells, a brief stimulus induces the exocytosis of a small pool of vesicles that is highly coupled to voltage-dependent Ca(2+) channels (A), whereas longer or high-frequency stimulation provokes a global Ca(2+) increase, promoting exocytosis irrespective of vesicle location (B). Furthermore, low-frequency stimulation favors kiss-and-run exocytosis (A), whereas higher frequencies promote full fusion (B). In this review, we analyze the mechanisms by which a given stimulation pattern defines the mode of exocytosis, and recruitment and recycling of neurosecretory vesicles. This article is part of a mini review series on Chromaffin cells (ISCCB Meeting, 2015).
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