Comparative energy measurements in single molecule interactions.

Single molecule experiments have opened promising new avenues of investigations in biology, but the quantitative interpretation of results remains challenging. In particular, there is a need for a comparison of such experiments with theoretical methods. We experimentally determine the activation free energy for single molecule interactions between two synaptic proteins syntaxin 1A and synaptobrevin 2, using an atomic force microscope and the Jarzynski equality of nonequilibrium thermodynamics. The value obtained is shown to be reasonably consistent with that from single molecule reaction rate theory. The temperature dependence of the spontaneous dissociation lifetime along with different pulling speeds is used to confirm the approach to the adiabatic limit. This comparison of the Jarzynski equality for intermolecular interactions extends the procedure for calculation of activation energies in nonequilibrium processes.

Assembly of the Drosophila larval exoskeleton requires controlled secretion and shaping of the apical plasma membrane.

The apical plasma membrane of epithelial cells plays a central role in producing and shaping the apical extracellular matrix (aECM) that eventually adopts a stereotypic architecture required for the physical and physiological needs of the epithelium. To assess the implication of the apical plasma membrane on aECM differentiation, we have studied the function of the apical plasma membrane t-SNARE Syntaxin 1A in the embryo of the fruit fly Drosophila melanogaster during differentiation of the stratified exoskeleton, the cuticle, which is composed of proteins and the polysaccharide chitin. The cuticle layers of syntaxin1A deficient larvae are rudimentary. Consistently, Syntaxin 1A is required for the secretion of O-glycosylated proteins and components involved in pigmentation and protein cross-linking. By contrast, localization of chitin synthesis and organising proteins to the apical plasma membrane or to the extracellular space does not depend on Syntaxin 1A activity. However, chitin microfibrils have a random orientation instead of being arranged in parallel. This correlates with the lack of corrugations at the apical plasma membrane of epidermal cells, the apical undulae that have been proposed to be crucial for chitin microfibril orientation. Hence, Syntaxin 1A contributes to cuticle differentiation by controlling correct apical plasma membrane topology as well as mediating secretion of a subset of extracellular proteins required for layer organisation. Our data also indicate that yet another unidentified t-SNARE is needed in parallel to Syntaxin 1A to deliver extracellular material for complete cuticle assembly. Evidently, coordination of apical membrane modelling and two secretion routes are essential for stereotypic aECM organisation.

Myosin-Va regulates exocytosis through the submicromolar Ca2+-dependent binding of syntaxin-1A.

Myosin-Va is an actin-based processive motor that conveys intracellular cargoes. Synaptic vesicles are one of the most important cargoes for myosin-Va, but the role of mammalian myosin-Va in secretion is less clear than for its yeast homologue, Myo2p. In the current studies, we show that myosin-Va on synaptic vesicles interacts with syntaxin-1A, a t-SNARE involved in exocytosis, at or above 0.3 microM Ca2+. Interference with formation of the syntaxin-1A-myosin-Va complex reduces the exocytotic frequency in chromaffin cells. Surprisingly, the syntaxin-1A-binding site was not in the tail of myosin-Va but rather in the neck, a region that contains calmodulin-binding IQ-motifs. Furthermore, we found that syntaxin-1A binding by myosin-Va in the presence of Ca2+ depends on the release of calmodulin from the myosin-Va neck, allowing syntaxin-1A to occupy the vacant IQ-motif. Using an anti-myosin-Va neck antibody, which blocks this binding, we demonstrated that the step most important for the antibody's inhibitory activity is the late sustained phase, which is involved in supplying readily releasable vesicles. Our results demonstrate that the interaction between myosin-Va and syntaxin-1A is involved in exocytosis and suggest that the myosin-Va neck contributes not only to the large step size but also to the regulation of exocytosis by Ca2+.