T-snare

A second mechanism that impinges on the localization of transporters is through the association with proteins, the most prominent example being syntaxin. Syntaxin is a t-SNARE protein necessary for the fusion of vesicles with the plasma membrane (see the chapter on exocytosis). On the cell surface syntaxin consistently stabilizes the localization of GABA, noradrenaline, glycine, and 5HT transporters the PKCa isoform can sever the interaction with syntaxin suggesting a general mechanism for transporter internalization. 

Vennekens R, Olausson J, Meissner M, Bloch W, Mathar I, Philipp SE, Schmitz F, Weissgerber R Nilius B, Flockerzi V, Freichel M Increased IgE-dependent mast cell activation and anaphylactic responses in mice lacking the calcium-activated nonselective cation channel XRPM4. Nat Immunol 2007 8 312-320. Guo Z, Xurner C, Castle D Relocation of the t-SNARE SNAP-23 from lamellipodia-like cell surface projections regulates compound exocytosis in mast cells. Cell 1998 94 537-548. 

Seel A member of a family of proteins that attach to t-SNAREs and are displaced from them by Rab proteins, thereby allowing v-SNARE-t-SNARE interactions to occur. 

Based largely on a proposal by Rothman and colleagues, anterograde vesicular transport can be considered to occur in eight steps (Figure 46-7). The basic concept is that each transport vesicle bears a unique address marker consisting of one or more v-SNARE proteins, while each target membrane bears one or more complementary t-SNARE proteins with which the former interact specifically. 

Step 5 Vesicle targeting is achieved via members of a family of integral proteins, termed v-SNAREs, that tag the vesicle during its budding. v-SNAREs pair with cognate t-SNAREs in the target membrane to dock the vesicle. 

Q Studies using v- and t-SNARE ptoteins reconsti-mted into separate lipid bilayer vesicles have indicated that they form SNAREpins, ie, SNARE complexes that hnk two membranes (vesicles). SNAPs and NSF are required for formation of SNAREpins, but once they have formed they can apparently lead to spontaneous fusion of membranes at physiologic temperamre, suggesting that they are the minimal machinery required for membrane fusion. 

The decisive element in exocytosis is the interaction between proteins known as SNAREs that are located on the vesicular membrane (v-SNAREs) and on the plasma membrane (t-SNAREs). In the resting state (1), the v-SNARE synaptobrevin is blocked by the vesicular protein synaptotagmin. When an action potential reaches the presynaptic membrane, voltage-gated Ca "" channels open (see p. 348). Ca "" flows in and triggers the machinery by conformational changes in proteins. Contact takes place between synaptobrevin and the t-SNARE synaptotaxin (2). Additional proteins known as SNAPs bind to the SNARE complex and allow fusion between the vesicle and the plasma membrane (3). The process is supported by the hydrolysis of GTP by the auxiliary protein Rab. 

In eukaryotes, soluble N-ethylmaleimide-sensitive factor (NSF) adaptor proteins (SNAPs) receptors (SNAREs) are known to be required for docking and fusion of intracellular transport vesicles with acceptor/target membranes. The fusion of vesicles in the secretory pathway involves target-SNAREs (t-SNAREs) on the target membrane and vesicle-SNAREs (v-SNAREs) on vesicle membranes that recognize each other and assemble into trans-SNARE complexes (Sollner et al., 1993). 

Pagan, J.K., Wylie, F.G., Joseph, S., Widberg, C., Bryant, N.J., James, D.E., Stow, J.L. The t-SNARE syntaxin 4 is regulated during macrophage activation to function in membrane traffic and cytokine secretion. Curr Biol 13 (2003) 156-160. 

There is a potentially simple reason why dysbindin-1 exerts an inhibitory effect on dopamine release by PC-12 cells, but an excitatory effect on glutamate release by cerebrocortical neurons. Knockdown of dysbindin-1 in these two cell types leads to opposite effects on SNAP-25, which is a critical t-SNARE as noted above. Knockdown of dysbindin-1 raises SNAP-25 in PC-12 cells (Kumamoto et al., 2006), but lowers SNAP-25 in cerebrocortical neurons (Numakawa et al., 2004). 

Protein transport between intracellular compartments is mediated by a mechanism that is well-conserved among all eukaryotes, from yeast to man. The transport mechanism involves carrier vesicles that bud from one organelle and fuse selectively to another. Specialized proteins are required for vesicle transport, docking, and fusion, and they have been generically named SNAREs (an acronym for soluble N-ethylma-leimide-sensitive fusion attachment protein receptor). SNAREs have been divided into those associated with the vesicle (termed v-SNAREs), and those associated with the target (termed t-SNAREs). The key protein, which led to the discovery of SNAREs was NSF, an ATPase found ubiquitously in all cells, and involved in numerous intracellular transport events. The subsequent identification of soluble proteins stably bound to NSF, the so-called SNARE complex, led to the formulation of the SNARE hypothesis, which posits that all intracellular fusion events are mediated by SNAREs (Rothman, 2002). 

In neurons, the SNARE complex consists of three main proteins the v-SNARE synaptobrevin or VAMP (vesicle-associated membrane protein), and two t-SNAREs, syntaxin and SNAP-25 (synaptosomal associated protein of 25 kD). Synaptobrevins traverse the synaptic vesicle membrane in an asymmetric manner a few amino acids are found inside the vesicle, but most of the molecule lies outside the vesicle, within the cytoplasm. Synaptobrevin makes contact with another protein anchored to the plasma membrane of the presynaptic neuron, syntaxin, which is associated with SNAP-25. Via these interactions, the SNARE proteins play a role in the docking and fusion of synaptic vesicles to the active zone. 

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