Your search keyword '"Grushin, Kirill"' showing total 3 results

1. Turbocharging synaptic transmission.

Author

Rothman, James E., Grushin, Kirill, Bera, Manindra, and Pincet, Frederic

Subjects

*SYNAPTIC vesicles, *NEURAL transmission, *MEMBRANE fusion, *SYNAPTOPHYSIN, *ELECTRON microscopy, *BIOCHEMISTRY

Abstract

Evidence from biochemistry, genetics, and electron microscopy strongly supports the idea that a ring of Synaptotagmin is central to the clamping and release of synaptic vesicles (SVs) for synchronous neurotransmission. Recent direct measurements in cell‐free systems suggest there are 12 SNAREpins in each ready‐release vesicle, consisting of six peripheral and six central SNAREpins. The six central SNAREpins are directly bound to the Synaptotagmin ring, are directly released by Ca++, and they initially open the fusion pore. The six peripheral SNAREpins are indirectly bound to the ring, each linked to a central SNAREpin by a bridging molecule of Complexin. We suggest that the primary role of peripheral SNAREpins is to provide additional force to 'turbocharge' neurotransmitter release, explaining how it can occur much faster than other forms of membrane fusion. The SV protein Synaptophysin forms hexamers that bear two copies of the v‐SNARE VAMP at each vertex, one likely assembling into a peripheral SNAREpin and the other into a central SNAREpin. [ABSTRACT FROM AUTHOR]

Published

2023

2. Munc13 structural transitions and oligomers that may choreograph successive stages in vesicle priming for neurotransmitter release.

Author

Grushin, Kirill, Sundaram, R. Venkat Kalyana, Sindelar, Charles V., and Rothman, James E.

Subjects

*SYNAPTIC vesicles, *OLIGOMERS, *CHOREOGRAPHY, *RIGID bodies, *NEURAL transmission

Abstract

How can exactly six SNARE complexes be assembled under each synaptic vesicle? Here we report cryo-EM crystal structures of the core domain of Munc13, the key chaperone that initiates SNAREpin assembly. The functional core of Munc13, consisting of C1-C2B-MUN-C2C (Munc13C) spontaneously crystallizes between phosphatidylserine-rich bilayers in two distinct conformations, each in a radically different oligomeric state. In the open conformation (state 1), Munc13C forms upright trimers that link the two bilayers, separating them by ∼21 nm. In the closed conformation, six copies of Munc13C interact to form a lateral hexamer elevated ∼14 nm above the bilayer. Open and closed conformations differ only by a rigid body rotation around a flexible hinge, which when performed cooperatively assembles Munc13 into a lateral hexamer (state 2) in which the key SNARE assembly-activating site of Munc13 is autoinhibited by its neighbor. We propose that each Munc13 in the lateral hexamer ultimately assembles a single SNAREpin, explaining how only and exactly six SNARE complexes are templated. We suggest that state 1 and state 2 may represent two successive states in the synaptic vesicle supply chain leading to "primed" ready-release vesicles in which SNAREpins are clamped and ready to release (state 3). [ABSTRACT FROM AUTHOR]

Published

2022

3. Hypothesis - buttressed rings assemble, clamp, and release SNAREpins for synaptic transmission.

Author

Rothman, James E., Krishnakumar, Shyam S., Grushin, Kirill, and Pincet, Frederic

Subjects

SNARES, ANIMAL traps, NEURAL transmission, ARTIFICIAL neural networks, PROTEINS

Abstract

Neural networks are optimized to detect temporal coincidence on the millisecond timescale. Here, we offer a synthetic hypothesis based on recent structural insights into SNAREs and the C2 domain proteins to explain how synaptic transmission can keep this pace. We suggest that an outer ring of up to six curved Munc13 ' MUN' domains transiently anchored to the plasma membrane via its flanking domains surrounds a stable inner ring comprised of synaptotagmin C2 domains to serve as a work-bench on which SNAREpins are templated. This 'buttressed-ring hypothesis' affords straightforward answers to many principal and long-standing questions concerning how SNAREpins can be assembled, clamped, and then released synchronously with an action potential. [ABSTRACT FROM AUTHOR]

Published

2017