Calcium Channels and Calcium-Binding Proteins.

Signals of nerve impulses are transmitted to excitatory cells to induce the action of organs via the activation of Ca entry through voltage-gated Ca channels (VGCC), which are classified based on their activation threshold into high- and low-voltage activated channels, expressed specifically for each organ [...

A Role for the V0 Sector of the V-ATPase in Neuroexocytosis: Exogenous V0d Blocks Complexin and SNARE Interactions with V0c.

V-ATPase is an important factor in synaptic vesicle acidification and is implicated in synaptic transmission. Rotation in the extra-membranous V1 sector drives proton transfer through the membrane-embedded multi-subunit V0 sector of the V-ATPase. Intra-vesicular protons are then used to drive neurotransmitter uptake by synaptic vesicles.

Mechanisms of Synaptic Vesicle Exo- and Endocytosis.

Within 1 millisecond of action potential arrival at presynaptic terminals voltage-gated Ca channels open. The Ca channels are linked to synaptic vesicles which are tethered by active zone proteins. Ca entrance into the active zone triggers: (1) the fusion of the vesicle and exocytosis, (2) the replenishment of the active zone with vesicles for incoming exocytosis, and (3) various types of endocytosis for vesicle reuse, dependent on the pattern of firing.

Stable and Flexible Synaptic Transmission Controlled by the Active Zone Protein Interactions.

An action potential triggers neurotransmitter release from synaptic vesicles docking to a specialized release site of the presynaptic plasma membrane, the active zone. The active zone is a highly organized structure with proteins that serves as a platform for synaptic vesicle exocytosis, mediated by SNAREs complex and Ca sensor proteins, within a sub-millisecond opening of nearby Ca channels with the membrane depolarization. In response to incoming neuronal signals, each active zone protein plays a role in the release-ready site replenishment with synaptic vesicles for sustainable synaptic transmission.

Neurotransmitter Release Site Replenishment and Presynaptic Plasticity.

An action potential (AP) triggers neurotransmitter release from synaptic vesicles (SVs) docking to a specialized release site of presynaptic plasma membrane, the active zone (AZ). The AP simultaneously controls the release site replenishment with SV for sustainable synaptic transmission in response to incoming neuronal signals. Although many studies have suggested that the replenishment time is relatively slow, recent studies exploring high speed resolution have revealed SV dynamics with milliseconds timescale after an AP.

Ca2.2 (N-type) voltage-gated calcium channels are activated by SUMOylation pathways.

SUMOylation is an important post-translational modification process involving covalent attachment of SUMO (Small Ubiquitin-like MOdifier) protein to target proteins. Here, we investigated the potential for SUMO-1 protein to modulate the function of the Ca2.2 (N-type) voltage-gated calcium channel (VGCC), a protein vital for presynaptic neurotransmitter release.

Presynaptic Calcium Channels.

Presynaptic Ca entry occurs through voltage-gated Ca (Ca) channels which are activated by membrane depolarization. Depolarization accompanies neuronal firing and elevation of Ca triggers neurotransmitter release from synaptic vesicles. For synchronization of efficient neurotransmitter release, synaptic vesicles are targeted by presynaptic Ca channels forming a large signaling complex in the active zone.

Presynaptic calcium channels.

At the presynaptic terminal, neuronal firing activity induces membrane depolarization and subsequent Ca entry through voltage-gated Ca (Ca) channels triggers neurotransmitter release from the active zone. Presynaptic Ca channels form a large signaling complex, which targets synaptic vesicles to Ca channels for efficient release and mediates Ca channel regulation. The presynaptic Ca2 channel family (comprising Ca2.

Millisecond Ca dynamics activate multiple protein cascades for synaptic vesicle control.

For reliable transmission at chemical synapses, neurotransmitters must be released dynamically in response to neuronal activity in the form of action potentials. Stable synaptic transmission is dependent on the efficacy of transmitter release and the rate of resupplying synaptic vesicles to their release sites. Accurate regulation is conferred by proteins sensing Ca entering through voltage-gated Ca channels opened by an action potential.

SAD-B Phosphorylation of CAST Controls Active Zone Vesicle Recycling for Synaptic Depression.

Short-term synaptic depression (STD) is a common form of activity-dependent plasticity observed widely in the nervous system. Few molecular pathways that control STD have been described, but the active zone (AZ) release apparatus provides a possible link between neuronal activity and plasticity. Here, we show that an AZ cytomatrix protein CAST and an AZ-associated protein kinase SAD-B coordinately regulate STD by controlling reloading of the AZ with release-ready synaptic vesicles.

Synaptic vesicle glycoprotein 2A modulates vesicular release and calcium channel function at peripheral sympathetic synapses.

Synaptic vesicle glycoprotein (SV)2A is a transmembrane protein found in secretory vesicles and is critical for Ca(2+) -dependent exocytosis in central neurons, although its mechanism of action remains uncertain. Previous studies have proposed, variously, a role of SV2 in the maintenance and formation of the readily releasable pool (RRP) or in the regulation of Ca(2+) responsiveness of primed vesicles. Such previous studies have typically used genetic approaches to ablate SV2 levels; here, we used a strategy involving small interference RNA (siRNA) injection to knockdown solely presynaptic SV2A levels in rat superior cervical ganglion (SCG) neuron synapses.

Exogenous α-synuclein decreases raft partitioning of Cav2.2 channels inducing dopamine release.

α-Synuclein is thought to regulate neurotransmitter release through multiple interactions with presynaptic proteins, cytoskeletal elements, ion channels, and synaptic vesicles membrane. α-Synuclein is abundant in the presynaptic compartment, and its release from neurons and glia has been described as responsible for spreading of α-synuclein-derived pathology. α-Synuclein-dependent dysregulation of neurotransmitter release might occur via its action on surface-exposed calcium channels.

Ca2+-independent activation of Ca2+/calmodulin-dependent protein kinase II bound to the C-terminal domain of CaV2.1 calcium channels.

Ca(2+)/calmodulin-dependent protein kinase II (CaMKII) forms a major component of the postsynaptic density where its functions in synaptic plasticity are well established, but its presynaptic actions are poorly defined. Here we show that CaMKII binds directly to the C-terminal domain of Ca(V)2.1 channels.

Fine-tuning synaptic plasticity by modulation of Ca(V)2.1 channels with Ca2+ sensor proteins.

Modulation of P/Q-type Ca(2+) currents through presynaptic voltage-gated calcium channels (Ca(V)2.1) by binding of Ca(2+)/calmodulin contributes to short-term synaptic plasticity. Ca(2+)-binding protein-1 (CaBP1) and Visinin-like protein-2 (VILIP-2) are neurospecific calmodulin-like Ca(2+) sensor proteins that differentially modulate Ca(V)2.

The synaptic vesicle glycoprotein 2A ligand levetiracetam inhibits presynaptic Ca2+ channels through an intracellular pathway.

Levetiracetam (LEV) is a prominent antiepileptic drug that binds to neuronal synaptic vesicle glycoprotein 2A protein and has reported effects on ion channels, but with a poorly defined mechanism of action. We investigated inhibition of voltage-dependent Ca(2+) (Ca(V)) channels as a potential mechanism through which LEV exerts effects on neuronal activity. We used electrophysiological methods to investigate the effects of LEV on cholinergic synaptic transmission and Ca(V) channel activity in superior cervical ganglion neurons (SCGNs).

Inhibition of synaptic transmission and G protein modulation by synthetic CaV2.2 Ca²+ channel peptides.

Modulation of presynaptic voltage-dependent Ca2+ channels is a major means of controlling neurotransmitter release. The CaV2.2Ca2+ channel subunit contains several inhibitory interaction sites for Gβγ subunits, including the amino terminal (NT) and I-II loop.

Activity-dependent regulation of synaptic vesicle exocytosis and presynaptic short-term plasticity.

Neuronal firing activity controls protein function and dynamically remodels synaptic efficacy. Exocytosis is triggered and regulated by Ca²+ which enters through voltage-gated Ca²+(CaV) channels and diffuses into the presynaptic terminal accompanying action potential firings. Residual Ca²+ is sensed by Ca²+-binding proteins; among other potential actions, it mediates time- and space-dependent synaptic facilitation and depression via effects on Ca(V)2 channel gating and vesicle replenishment in the readily releasable pool (RRP).

Ca/Calmodulin and presynaptic short-term plasticity.

Synaptic efficacy is remodeled by neuronal firing activity at the presynaptic terminal. Presynaptic activity-dependent changes in transmitter release induce postsynaptic plasticity, including morphological change in spine, gene transcription, and protein synthesis and trafficking. The presynaptic transmitter release is triggered and regulated by Ca(2+), which enters through voltage-gated Ca(2+) (Ca(V)) channels and diffuses into the presynaptic terminal accompanying action potential firings.

KIF5B motor adaptor syntabulin maintains synaptic transmission in sympathetic neurons.

Newly synthesized synaptic proteins and mitochondria are transported along lengthy neuronal processes to assist in the proper assembly of developing synapses and activity-dependent remodeling of mature synapses. Neuronal transport is mediated by motor proteins that associate with their cargoes via adaptors and travel along the cytoskeleton within neuronal processes. Our previous studies in developing hippocampal neurons revealed that syntabulin acts as a KIF5B motor adaptor and mediates anterograde transport of presynaptic cargoes and mitochondria, presynaptic assembly, and activity-induced plasticity.