J M Edwardson

Syntaxin Is Efficiently Excluded from Sphingomyelin-enriched Domains in Supported Lipid Bilayers Containing Cholesterol

Formation of a trans-complex between the three SNARE proteins syntaxin, synaptobrevin and SNAP-25 drives membrane fusion. The structure of the core SNARE complex has been studied extensively. Here we have used atomic force microscopy to study the behavior of recombinant syntaxin 1A both in detergent extracts and in a lipid environment. Full-length syntaxin in detergent extracts had a marked tendency to aggregate, which was countered by addition of munc-18. In contrast, syntaxin lacking its transmembrane region was predominantly monomeric. Syntaxin could be integrated into liposomes, which formed lipid bilayers when deposited on a mica support. Supported bilayers were decorated with lipid vesicles in the presence, but not the absence, of full-length syntaxin, indicating that formation of syntaxin complexes in trans could mediate vesicle docking. Syntaxin complexes remained at the sites of docking following detergent solubilization of the lipids. Raised lipid domains could be seen in bilayers containing sphingomyelin, and these domains were devoid of syntaxin and docked vesicles in the presence, but not the absence, of cholesterol. Our results demonstrate that syntaxin is excluded from sphingomyelin-enriched domains in a cholesterol-dependent manner.

Syncollin homo-oligomers associate with lipid bilayers in the form of doughnut-shaped structures

Syncollin is a 16-kDa protein that is associated with the luminal surface of the zymogen granule membrane in the pancreatic acinar cell. Detergent-solubilized, purified syncollin migrates on sucrose density gradients as a large (120-kDa) protein, suggesting that it exists naturally as a homo-oligomer. In this study, we investigated the structure of the syncollin oligomer. Chemical cross-linking of syncollin produced a ladder of bands, the sizes of which are consistent with discrete species from monomers up to hexamers. Electron microscopy of negatively stained syncollin revealed doughnut-shaped structures of outer diameter 10 nm and inner diameter 3 nm. Atomic force microscopy (AFM) of syncollin on mica supports at pH 7.6 showed particles of molecular volume 155 nm3. Smaller particles were observed either at alkaline pH (11.0), or in the presence of a reducing agent (dithiothreitol), conditions that cause dissociation of the oligomer. AFM imaging of syncollin attached to supported lipid bilayers again revealed doughnut-shaped structures (outer diameter 31 nm, inner diameter 6 nm) protruding 1 nm from the bilayer. Finally, addition of syncollin to liposomes rendered them permeable to the water-soluble fluorescent probe 5(6)-carboxyfluorescein. These results are discussed in relation to the possible physiological role of syncollin.

Cholesterol-dependent interaction of syncollin with the membrane of the pancreatic zymogen granule.

Syncollin is a protein of the pancreatic zymogen granule that was isolated through its ability to bind to syntaxin. Despite this in vitro interaction, it is now clear that syncollin is present on the luminal side of the zymogen granule membrane. Here we show that there are two pools of syncollin within the zymogen granule: one free in the lumen and the other tightly associated with the granule membrane. When unheated or cross-linked samples of membrane-derived syncollin are analysed by SDS/PAGE, higher-order forms are seen in addition to the monomer, which has an apparent molecular mass of 16 kDa. Extraction of cholesterol from the granule membrane by treatment with methyl-beta-cyclodextrin causes the detachment of syncollin, and this effect is enhanced at a high salt concentration. Purified syncollin is able to bind to brain liposomes at pH 5.0, but not at pH 11.0, a condition that also causes its extraction from granule membranes. Syncollin binds only poorly to dioleoyl phosphatidylcholine liposomes, but binding is dramatically enhanced by the inclusion of cholesterol. Finally, cholesterol can be co-immunoprecipitated with syncollin. We conclude that syncollin is able to interact directly with membrane lipids, and to insert into the granule membrane in a cholesterol-dependent manner. Membrane-associated syncollin apparently exists as a homo-oligomer, possibly consisting of six subunits, and its association with the membrane may be stabilized by electrostatic interactions with either other proteins or phospholipids.

Molecular mechanisms in exocytosis

Introduction Exocytosis, the last stage in the secretory pathway, in- volves the fusion of the membranes of secretory vesicles with the plasma membrane. It results in the release of the vesicle contents from the cell and also the delivery of vesicle membrane proteins into the plasma membrane. Exocytosis may either be constitutive, where vesicles budding from the

Demonstration of ligand decoration, and ligand-induced perturbation, of G-quadruplexes in a plasmid using atomic force microscopy.

G-Quadruplexes are nucleic acid secondary structures consisting of a planar arrangement of four guanine residues. Potential G-quadruplex-forming sequences are widely distributed throughout the genome. Significantly, they are present in telomeres and are enriched in gene promoters and first introns, raising the possibility that perturbation of G-quadruplex stability might have therapeutic potential, for example in the treatment of cancer. Ligands that interact selectively with G-quadruplexes include both proteins and small molecules, although the interactions between ligands and their G-quadruplex targets have been monitored using indirect methods. In addition, the G-quadruplex targets have often been short DNA fragments. Here, we have used atomic force microscopy imaging to examine directly at the single-molecule level the interaction of ligands with G-quadruplexes generated during transcription of a plasmid containing a G-rich insert. We show that the structures produced during transcription are decorated specifically by the single-chain antibody HF1 and by the nuclear protein PARP-1, both of which are known to recognize G-quadruplexes. Our results provide clear structural evidence of G-quadruplex formation in a transcription-dependent case and demonstrate directly how small-molecule stabilizers and destabilizers can manipulate these structures in a biochemically functional system.