Abstract
The V-ATPase is a proton pump consisting of a membrane-integral V0 sector and a peripheral V1 sector, which carries the ATPase activity. In vitro studies of yeast vacuole fusion and evidence from worms, flies, zebrafish and mice suggested that V0 interacts with the SNARE machinery for membrane fusion, that it promotes the induction of hemifusion and that this activity requires physical presence of V0 rather than its proton pump activity. A recent in vivo study in yeast has challenged these interpretations, concluding that fusion required solely lumenal acidification but not the V0 sector itself. Here, we identify the reasons for this discrepancy and reconcile it. We find that acute pharmacological or physiological inhibition of V-ATPase pump activity de-acidifies the vacuole lumen in living yeast cells within minutes. Time-lapse microscopy revealed that de-acidification induces vacuole fusion rather than inhibiting it. Cells expressing mutated V0 subunits that maintain vacuolar acidity were blocked in this fusion. Thus, proton pump activity of the V-ATPase negatively regulates vacuole fusion in vivo. Vacuole fusion in vivo does, however, require physical presence of a fusion-competent V0 sector.
Highlights
The V-ATPase is a proton pump consisting of a membrane-integral V0 sector and a peripheral V1 sector, which carries the ATPase activity
If a fusion defect is due to a loss of proton pump activity it should become visible in a V1 mutant, which eliminates pump activity as effectively as a V0 mutant but leaves V0 intact
If V0 deletion shows additional defects compared to a V1 deletion, those cannot be accounted for by defects in proton pump activity, but they are consistent with a physical role of V0
Summary
The V-ATPase is a proton pump consisting of a membrane-integral V0 sector and a peripheral V1 sector, which carries the ATPase activity. Studies on the fusion of isolated yeast vacuoles indicated a physical role of the membrane-integral sector of the V-ATPase, V0, in vacuole fusion that could be separated from its function in proton pumping They showed that V0 interacts with vacuolar SNARE proteins[7,9,15,16]. Targeted approaches in vertebrates implicated V0 in secretion of insulin, neurotransmitters and catecholamines[21,22,23,24] All these studies provide evidence that the observed fusion defects depend on the physical presence of V0 and on its interaction with SNAREs. In none of the cases could they be explained by a loss of V-ATPase proton pump function. A direct, real-time assay of this www.nature.com/scientificreports/
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