Synaptotagmin-7 controls the size of the reserve and resting pools of synaptic vesicles in hippocampal neurons.

Continuous neurotransmitter release is subjected to synaptic vesicle availability, which in turn depends on vesicle recycling and the traffic of vesicles between pools. We studied the role of Synaptotagmin-7 (Syt-7) in synaptic vesicle accessibility for release in hippocampal neurons in culture. Synaptic boutons from Syt-7 knockout (KO) mice displayed normal basal secretion with no alteration in the RRP size or the probability of release. However, stronger stimuli revealed an increase in the size of the reserve and resting vesicle pools in Syt-7 KO boutons compared with WT. These data suggest that Syt-7 plays a significant role in the vesicle pool homeostasis and, consequently, in the availability of vesicles for synaptic transmission during strong stimulation, probably, by facilitating advancing synaptic vesicles to the readily releasable pool.

G protein-coupled receptor signalling potentiates the osmo-mechanical activation of TRPC5 channels.

TRPC5 is an ion channel permeable to monovalent and divalent cations that is widely expressed in different tissues. Although implicated in the control of neurite extension and in the growth cone morphology of hippocampal neurons, as well as in fear-related behaviour, the mechanisms by which TRPC5 is activated remain poorly understood. TRPC5 is known to be activated downstream of Gq-coupled receptors and by membrane stretch, and since there is evidence that mechanical stress may directly activate Gq-coupled receptors, we examined the relationship between the activation of TRPC5 by the type 1 histamine receptor and osmotic stress. Using calcium imaging and patch clamp recordings, we found that a higher proportion of cells expressing TRPC5 respond to hypoosmotic solution when they co-express H1R. This response is associated with a phospholipase C-dependent increase in the cells internal calcium concentration, which is abolished on depletion of calcium stores. We also found that the hypoosmotic stimulus that provokes mechanical stress drives the translocation of TRPC5 to the plasma membrane by a mechanism dependent on PI3K. This increase in TRPC5 at the plasma membrane augments the proportion of cells that respond to hypoosmotic stimulation. Together, these results suggest that hypoosmotic cell-swelling activates Gq-coupled receptors, which in turn enhance the activation of TRPC5 by regulating this channel membrane trafficking. Gq-coupled receptors and TPRC5 are co-expressed in several tissues such as those of the vascular system and in somatosensory neurons, suggesting that this mechanism of TRPC5 activation may have interesting and important implications in arterial pressure sensing and mechanotransduction.

Push-and-pull regulation of the fusion pore by synaptotagmin-7.

In chromaffin cells, Ca(2+) binding to synaptotagmin-1 and -7 triggers exocytosis by promoting fusion pore opening and fusion pore expansion. Synaptotagmins contain two C2 domains that both bind Ca(2+) and contribute to exocytosis; however, it remains unknown whether the C2 domains act similarly or differentially to promote opening and expansion of fusion pores. Here, we use patch amperometry measurements in WT and synaptotagmin-7-mutant chromaffin cells to analyze the role of Ca(2+) binding to the two synaptotagmin-7 C2 domains in exocytosis. We show that, surprisingly, Ca(2+) binding to the C2A domain suffices to trigger fusion pore opening but that the resulting fusion pores are unstable and collapse, causing a dramatic increase in kiss-and-run fusion events. Thus, synaptotagmin-7 controls fusion pore dynamics during exocytosis via a push-and-pull mechanism in which Ca(2+) binding to both C2 domains promotes fusion pore opening, but the C2B domain is selectively essential for continuous expansion of an otherwise unstable fusion pore.