A structure-based model for the 16 kDa membrane sector of the vacuolar H(+)-ATPase

Topological Characterization of the c, c′, and c″ Subunits of the Vacuolar ATPase from the Yeast Saccharomyces cerevisiae

The vacuolar ATPase (V-ATPase) is a multisubunit enzyme that acidifies intracellular organelles in eukaryotes. Similar to the F-type ATP synthase (FATPase), the V-ATPase is composed of two subcomplexes, V(1) and V(0). Hydrolysis of ATP in the V(1) subcomplex is tightly coupled to proton translocation accomplished by the V(0) subcomplex, which is composed of five unique subunits (a, d, c, c', and c"). Three of the subunits, subunit c (Vma3p), c' (Vma11p), and c" (Vma16p), are small highly hydrophobic integral membrane proteins called "proteolipids" that share sequence similarity to the F-ATPase subunit c. Whereas subunit c from the F-ATPase spans the membrane bilayer twice, the V-ATPase proteolipids have been modeled to have at least four transmembrane-spanning helices. Limited proteolysis experiments with epitope-tagged copies of the proteolipids have revealed that the N and the C termini of c (Vma3p) and c' (Vma11p) were in the lumen of the vacuole. Limited proteolysis of epitope-tagged c" (Vma16p) indicated that the N terminus is located on the cytoplasmic face of the vacuole, whereas the C terminus is located within the vacuole. Furthermore, a chimeric fusion between Vma16p and Vma3p, Vma16-Vma3p, was found to assemble into a fully functional V-ATPase complex, further supporting the conclusion that the C terminus of Vma16p resides within the lumen of the vacuole. These results indicate that subunits c and c' have four transmembrane segments with their N and C termini in the lumen and that c" has five transmembrane segments, with the N terminus exposed to the cytosol and the C terminus lumenal.

A common molecular machinery for exocytosis and the ‘kiss-and-run’ mechanism in chromaffin cells is controlled by phosphorylation

Exocytosis and ‘kiss-and-run’ secretion coexist in chromaffin cells. Our findings suggest that these mechanisms are closely related, based on their common molecular machinery. Here we present a model that describes how chromaffin cells regulate catecholamine release by switching the mode of secretion between the two pathways, a process controlled by phosphorylation. Stimulation-dependent vesicle-plasma membrane interactions in chromaffin cells were analysed by simultaneous ‘on-cell’ capacitance and conductance measurements, a technique that allows the monitoring of single vesicles. Capacitance steps represent fusions of large dense-core vesicles with the plasma membrane, whereas capacitance flickers correspond to transient connections of the vesicle lumen with the extracellular space. All these events require the presence of extracellular calcium in millimolar concentrations. ‘Kiss-and-run’ type of release is enhanced by the kinase inhibitor staurosporine, which suggests that this secretion mode is regulated by protein phosphorylation. We also observed capacitance bursts, which most probably represent ‘hot spots’ of secretion and we found that ‘kiss-and-run’ is the prevalent mechanism during these episodes. The significance of ‘kiss-and run’ for neurohormone release is even higher at physiological temperature, because up to half of all secretion events are mediated by this mechanism.