Membrane fusion is a process that intimately involves both proteins and lipids. Although the SNARE proteins, which ultimately overcome the energy barrier for fusion, have been extensively studied, regulation of the energy barrier itself, determined by specific membrane lipids, has been largely overlooked. Our findings reveal a novel function for SNARE proteins in reducing the energy barrier for fusion, by directly binding and sequestering fusogenic lipids to sites of fusion. We demonstrate a specific interaction between Syntaxin1A and the fusogenic lipid phosphatidic acid, in addition to multiple polyphosphoinositide lipids, and define a polybasic juxtamembrane region within Syntaxin1A as its lipidbinding domain. In PC-12 cells, Syntaxin1A mutations that progressively reduced lipid binding resulted in a progressive reduction in evoked secretion. Moreover, amperometric analysis of fusion events driven by a lipid-binding-deficient Syntaxin1A mutant (5RK/A) demonstrated alterations in fusion pore dynamics, suggestive of an energetic defect in secretion. Overexpression of the phosphatidic acid-generating enzyme, phospholipase D1, completely rescued the secretory defect seen with the 5RK/A mutant. Moreover, knockdown of phospholipase D1 activity drastically reduced control secretion, while leaving 5RK/A-mediated secretion relatively unaffected. Altogether, these data suggest that Syntaxin1A-lipid interactions are a critical determinant of the energetics of SNARE-catalyzed fusion events.
INTRODUCTIONMembrane fusion is a process that underlies compartmentalization within all eukaryotic cells, and allows for the many critical and diverse physiological functions in higher organisms. Despite the essential and ubiquitous nature of this process, a considerable energetic expenditure is required to overcome the electrostatic repulsion between opposing lipid bilayers and to deform and ultimately rupture these bilayers (Chernomordik and Kozlov, 2003;Cohen and Melikyan, 2004). As a result, substantial effort has been placed on defining the molecular machinery that overcomes this energetic barrier to accomplish regulated and rapid membrane fusion. SNARE (soluble n-ethylmaleimide-sensitive fusion factor attachment protein receptor) proteins have now been identified as the minimal protein machinery required for membrane fusion (Jahn and Scheller, 2006). Their critical role is supported by multiple lines of evidence, including that SNARE proteins are sufficient to drive membrane fusion when reconstituted into liposomes in vitro (Weber et al., 1998) and that cleavage of SNARE proteins by clostridial toxins (Schiavo et al., 1992; Blasi et al., 1993a,b), as well as genetic mutations resulting in loss of SNARE protein function (Broadie et al., 1995;Littleton et al., 1998;Saifee et al., 1998), strongly inhibit neurotransmitter release. Currently, the role of SNARE proteins in membrane fusion is believed to be predominantly mechanical. During neurotransmitter release, nucleation and zippering of a highly stable SNARE core complex formed f...
