Identification of the SNARE complex mediating the exocytosis of NMDA receptors.

In the central nervous system, NMDA receptors mediate excitatory neurotransmissions and play important roles in synaptic plasticity. The regulation of NMDA receptor trafficking is critical for neural functions in the brain. Here, we directly visualized individual exocytic events of NMDA receptors in rat hippocampal neurons by total internal reflection fluorescence microscopy (TIRFM). We found that the constitutive exocytosis of NMDA receptors included both de novo exocytic and recycling events, which were regulated by different Rab proteins. We also identified the SNAP25-VAMP1-syntaxin4 complex mediating the constitutive exocytosis of NMDA receptors. Transient knockdown of each component of the SNARE complex interfered with surface delivery of NMDA receptors to both extrasynaptic and synaptic membranes. Our study uncovers the postsynaptic function of the SNAP25-VAMP1-syntaxin4 complex in mediating the constitutive exocytosis of NMDA receptors, suggesting that this SNARE complex is involved in excitatory synaptic transmission.

SnAvi--a new tandem tag for high-affinity protein-complex purification.

Systematic tandem-affinity-purification (TAP) of protein complexes was tremendously successful in yeast and has changed the general concept of how we understand protein function in eukaryotic cells. The transfer of this method to other model organisms has been difficult and may require specific adaptations. We were especially interested to establish a cell-type-specific TAP system for Caenorhabditis elegans, a model animal well suited to high-throughput analysis, proteomics and systems biology. By combining the high-affinity interaction between in vivo biotinylated target-proteins and streptavidin with the usage of a newly identified epitope of the publicly shared SB1 monoclonal antibody we created a novel in vivo fluorescent tag, the SnAvi-Tag. We show the versatile application of the SnAvi-Tag in Escherichia coli, vertebrate cells and in C. elegans for tandem affinity purification of protein complexes, western blotting and also for the in vivo sub-cellular localization of labelled proteins.

Effect of monolayer lipid charges on the structure and orientation of protein VAMP1 at the air-water interface.

SNARE proteins are implicated in membrane fusion during neurotransmission and peptide hormone secretion. Relatively little is known about the molecular interactions of their trans- and juxtamembrane domains with lipid membranes. Here, we report the structure and the assembling behavior of one of the SNARE proteins, VAMP1/synaptobrevin1 incorporated in a lipid monolayer at an air-water interface which mimics the membrane environment. Our results show that the protein is extremely sensitive to surface pressure as well as the lipid composition. Monolayers of proteins alone or in the presence of the neutral phospholipid DMPC underwent structural transition from alpha-helix to beta-sheet upon surface compression. In contrast, the anionic phospholipid DMPG inhibited this transition in a concentration-dependent manner. Moreover, the orientation of the proteins was highly sensitive to the charge density of the lipid layers. Thus, the structure of VAMP1 is clearly controlled by protein-lipid interactions.

Reversible transition between alpha-helix and beta-sheet conformation of a transmembrane domain.

Despite the important functions of protein transmembrane domains, their structure and dynamics are often scarcely known. The SNARE proteins VAMP/synaptobrevin and syntaxin 1 are implicated in membrane fusion. Using different spectroscopic approaches we observed a marked sensitivity of their transmembrane domain structure in regard to the lipid/peptide ratio. In the dilute condition, peptides corresponding to the complete transmembrane domain fold into an alpha-helix inserted at approximately 35 degrees to the normal of the membranes, an observation in line with molecular simulations. Upon an increase in the peptide/lipid ratio, the peptides readily exhibited transition to beta-sheet structure. Moreover, the insertion angle of these beta-sheets increased to 54 degrees and was accompanied by a derangement of lipid acyl chains. For both proteins the transition from alpha-helix to beta-sheet was reversible under certain conditions by increasing the peptide/lipid ratio. This phenomenon was observed in different model systems including multibilayers and small unilamellar vesicles. In addition, differences in peptide structure and transitions were observed when using distinct lipids (DMPC, DPPC or DOPC) thus indicating parameters influencing transmembrane domain structure and conversion from helices to sheets. The putative functional consequences of this unprecedented dynamic behavior of a transmembrane domain are discussed.