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Reference: Beyenbach KW and Wieczorek H (2006) The V-type H+ ATPase: molecular structure and function, physiological roles and regulation. J Exp Biol 209(Pt 4):577-89

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Abstract

It was nearly 30 years before the V-type H(+) ATPase was admitted to the small circle of bona fide transport ATPases alongside F-type and P-type ATPases. The V-type H(+) ATPase is an ATP-driven enzyme that transforms the energy of ATP hydrolysis to electrochemical potential differences of protons across diverse biological membranes via the primary active transport of H(+). In turn, the transmembrane electrochemical potential of H(+) is used to drive a variety of (i) secondary active transport systems via H(+)-dependent symporters and antiporters and (ii) channel-mediated transport systems. For example, expression of Cl(-) channels or transporters next to the V-type H(+) ATPase in vacuoles of plants and fungi and in lysosomes of animals brings about the acidification of the endosomal compartment, and the expression of the H(+)/neurotransmitter antiporter next to the V-type H(+) ATPase concentrates neurotransmitters in synaptic vesicles. First found in association with endosomal membranes, the V-type H(+) ATPase is now also found in increasing examples of plasma membranes where the proton pump energizes transport across cell membranes and entire epithelia. The molecular details reveal up to 14 protein subunits arranged in (i) a cytoplasmic V(1) complex, which mediates the hydrolysis of ATP, and (ii) a membrane-embedded V(0) complex, which translocates H(+) across the membrane. Clever experiments have revealed the V-type H(+) ATPase as a molecular motor akin to F-type ATPases. The hydrolysis of ATP turns a rotor consisting largely of one copy of subunits D and F of the V(1) complex and a ring of six or more copies of subunit c of the V(0) complex. The rotation of the ring is thought to deliver H(+) from the cytoplasmic to the endosomal or extracellular side of the membrane, probably via channels formed by subunit a. The reversible dissociation of V(1) and V(0) complexes is one mechanism of physiological regulation that appears to be widely conserved from yeast to animal cells. Other mechanisms, such as subunit-subunit interactions or interactions of the V-type H(+) ATPase with other proteins that serve physiological regulation, remain to be explored. Some diseases can now be attributed to genetic alterations of specific subunits of the V-type H(+) ATPase.

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Journal Article
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Beyenbach KW, Wieczorek H
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