Reversible disassembly of the yeast V-ATPase revisited under in vivo conditions.

Primary active proton transport by eukaryotic V-ATPases (vacuolar ATPases) is regulated via the reversible disassembly of the V1Vo holoenzyme into its peripheral catalytic V1 complex and its membrane-bound proton-translocating Vo complex. This nutrient-dependent phenomenon had been first detected in the midgut epithelium of non-feeding moulting tobacco hornworms (Manduca sexta) and in glucose-deprived yeast cells (Saccharomyces cerevisiae). Since reversible disassembly to date had been investigated mostly in vitro, we wanted to test this phenomenon under in vivo conditions. We used living yeast cells with V-ATPase subunits fused to green, yellow or cyan fluorescent protein and found that only the V1 subunit C (Vma5) was released into the cytosol after substitution of extracellular glucose with galactose, whereas the other V1 subunits remained at or near the membrane. FRET analysis demonstrated close proximity between V1 and Vo even under glucose-starvation conditions. Disassembly, but not reassembly, depended on functional microtubules. Results from overlay blots, pull-down assays and bimolecular fluorescence complementation support the assumption that subunit C interacts directly with microtubules without involvement of linker proteins.

Vacuolar H(+)-ATPases: intra- and intermolecular interactions.

V-ATPases in eukaryotes are heteromultimeric, H(+)-transporting proteins. They are localized in a multitude of different membranes and energize many different transport processes. Unique features of V-ATPases are, on the one hand, their ability to regulate enzymatic and ion transporting activity by the reversible dissociation of the catalytic V(1) complex from the membrane bound proton translocating V(0) complex and, on the other hand, their high sensitivity to specific macrolides such as bafilomycin and concanamycin from streptomycetes or archazolid and apicularen from myxomycetes. Both features require distinct intramolecular as well as intermolecular interactions. Here we will summarize our own results together with newer developments in both of these research areas.