Variable priming of a docked synaptic vesicle

Variable priming of a docked synaptic vesicle

The priming of a docked synaptic vesicle determines the probability of its membrane (VM) fusing with the presynaptic membrane (PM) when a nerve impulse arrives. To gain insight into the nature of priming, we searched by electron tomography for structural relationships correlated with fusion probabil...

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Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 113; no. 8; pp. E1098 - E1107
Main Authors: Jung, Jae Hoon, Szule, Joseph A., Marshall, Robert M., McMahan, Uel J.
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 23-02-2016
National Acad Sciences
Series:PNAS Plus
Subjects:
Animals
Anura
Biological Sciences
Calcium Channels - metabolism
Electron Microscope Tomography
Equilibrium
Membranes
Neurosciences
Normal distribution
PNAS Plus
Probability
Rana pipiens
Synaptic Membranes - metabolism
Synaptic Membranes - ultrastructure
Synaptic Vesicles - metabolism
Synaptic Vesicles - ultrastructure
Tomography
priming
active zone material
synapse
hemifusion
electron tomography
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Summary:The priming of a docked synaptic vesicle determines the probability of its membrane (VM) fusing with the presynaptic membrane (PM) when a nerve impulse arrives. To gain insight into the nature of priming, we searched by electron tomography for structural relationships correlated with fusion probability at active zones of axon terminals at frog neuromuscular junctions. For terminals fixed at rest, the contact area between the VM of docked vesicles and PM varied >10-fold with a normal distribution. There was no merging of the membranes. For terminals fixed during repetitive evoked synaptic transmission, the normal distribution of contact areas was shifted to the left, due in part to a decreased number of large contact areas, and there was a subpopulation of large contact areas where the membranes were hemifused, an intermediate preceding complete fusion. Thus, fusion probability of a docked vesicle is related to the extent of its VM–PM contact area. For terminals fixed 1 h after activity, the distribution of contact areas recovered to that at rest, indicating the extent of a VM–PM contact area is dynamic and in equilibrium. The extent of VM–PM contact areas in resting terminals correlated with eccentricity in vesicle shape caused by force toward the PM and with shortness of active zone material macromolecules linking vesicles to PM components, some thought to include Ca2+ channels. We propose that priming is a variable continuum of events imposing variable fusion probability on each vesicle and is regulated by force-generating shortening of active zone material macromolecules in dynamic equilibrium.
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Author contributions: J.H.J., J.A.S., and U.J.M. designed research; J.H.J., J.A.S., R.M.M., and U.J.M. performed research; J.H.J., J.A.S., and U.J.M. analyzed data; and J.H.J., J.A.S., and U.J.M. wrote the paper.
Edited by Thomas S. Reese, National Institutes of Health, Bethesda, MD, and approved January 12, 2016 (received for review November 30, 2015)
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1523054113