Abstract
During exocytosis, the fusion pore expands to allow release of neurotransmitters and hormones to the extracellular space. To understand the process of synaptic transmission, it is of outstanding importance to know the properties of the fusion pore and how these properties affect the release process. Many proteins have been implicated in vesicle fusion; however, there is little evidence for proteins involved in fusion pore expansion. Myosin II has been shown to participate in the transport of vesicles and, surprisingly, in the final phases of exocytosis, affecting the kinetics of catecholamine release in adrenal chromaffin cells as measured by amperometry. Here, we have studied single vesicle exocytosis in chromaffin cells overexpressing an unphosphorylatable form (T18AS19A RLC-GFP) of myosin II that produces an inactive protein by patch amperometry. This method allows direct determination of fusion pore expansion by measuring its conductance, whereas the release of catecholamines is recorded simultaneously by amperometry. Here we demonstrated that the fusion pore is of critical importance to control the release of catecholamines during single vesicle secretion in chromaffin cells. We proved that myosin II acts as a molecular motor on the fusion pore expansion by hindering its dilation when it lacks the phosphorylation sites.
Highlights
Exocytosis is a fundamental cellular mechanism used by neurons and hormone-secreting cells to interact with each other and to influence their environment through the release of neurotransmitters and hormones
In addition to the simultaneous measurement of capacitance changes caused by single chromaffin granules and the associated release of catecholamines, patch amperometry allows for a detailed characterization of the dynamics of the fusion pore by off-line admittance analysis (Fig. 1A, bottom panel)
The cumulative histogram of pore open times, as measured by the time in which the Gp max value is reached, revealed that over 80% of the pores in WT cells has already opened in 20 ms; in mutant cells only a 40% of the pores open in the same time period of 20 ms (Fig. 2, H and I). These results indicate that the expression of T18A/ S19A regulatory light chain (RLC)-green fluorescent protein (GFP) mutations leads to a slow expansion of the fusion pore with lower conductance values, to explode open to release the bulk contents of the secretory vesicle
Summary
Exocytosis is a fundamental cellular mechanism used by neurons and hormone-secreting cells to interact with each other and to influence their environment through the release of neurotransmitters and hormones. In addition to the simultaneous measurement of capacitance changes caused by single chromaffin granules and the associated release of catecholamines, patch amperometry allows for a detailed characterization of the dynamics of the fusion pore by off-line admittance analysis (Fig. 1A, bottom panel).
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