Fragmentation of mitochondrial H+-ATPase hydrophobic complex]

The subunits with molecular weights of 30 000, 10 000 and 20 000 + 19 000 have been obtained by fractionation of the hydrophobic part of the oligomycin-sensitive ATPase complex on Sephadex G-200 and Sephadex G-150 in the presence of sodium dodecyl sulfate.     

Damage to the chloroplast H+-ATPase complex by low concentrations of glutaraldehyde

The energy-dependent processes coupled to electron transport were studied in isolated pea chloroplasts treated with low concentrations (1-5 mM) of glutaraldehyde (GA) in the dark and in the light sufficient to cause energization of the membrane. After GA treatment the chloroplasts exhibited a strong suppression of cyclic and non-cyclic phosphorylation, coupled (+ADP+Pi) electron transport and diminution of the light-activated Mg2+-ATPase activity. The rate of basal electron transport was unaffected. The GA-treated chloroplasts were found to retain the capacity to form the osmotic component of the transmembrane potential. These data and the results of the effect of florizine and ATP on electron transport suggest that the effect of GA on energy transduction processes associated with photophosphorylation may consist in its action on reversible H+-ATPase. In light-adapted samples treated with GA the data characterizing the formation of a high energy state (rate of photophosphorylation, steady-state level of photo-induced quenching of atebrin fluorescence and its dark recovery; photo-induced absorbance changes at 520 nm; rate of the slow phase of delayed fluorescence increment) appear to be changed to a greater extent as compared to the dark-adapted samples. The observed changes may arise from a greater conductivity of thylakoid membranes due to fixation of the H+-ATPase proton channel in the "open" state.     

Early steps in assembly of the yeast vacuolar H+-ATPase.

Vacuolar proton-translocating ATPases are composed of a complex of integral membrane proteins, the Vo sector, attached to a complex of peripheral membrane proteins, the V1 sector. We have examined the early steps in biosynthesis of the yeast vacuolar ATPase by biosynthetically labeling wild-type and mutant cells for varied pulse and chase times and immunoprecipitating fully and partially assembled complexes under nondenaturing conditions. In wild-type cells, several V1 subunits and the 100-kDa Vo subunit associate within 3-5 min, followed by addition of other Vo subunits with time. Deletion mutants lacking single subunits of the enzyme show a variety of partial complexes, including both complexes that resemble intermediates in the assembly pathway of wild-type cells and independent V1 and Vo sectors that form without any apparent V1Vo subunit interaction. Two yeast sec mutants that show a temperature-conditional block in export from the endoplasmic reticulum accumulate a complex containing several V1 subunits and the 100-kDa Vo subunit during incubation at elevated temperature. This complex can assemble with the 17-kDa Vo subunit when the temperature block is reversed. We propose that assembly of the yeast V-ATPase can occur by two different pathways: a concerted assembly pathway involving early interactions between V1 and Vo subunits and an independent assembly pathway requiring full assembly of V1 and Vo sectors before combination of the two sectors. The data suggest that in wild-type cells, assembly occurs predominantly by the concerted assembly pathway, and V-ATPase complexes acquire the full complement of Vo subunits during or after exit from the endoplasmic reticulum.     

Activation of Mg-ATP hydrolysis in isolated Rhodospirillum rubrum H+-ATPase

The effects of lauryl dimethylamine oxide on the Rhodospirillum rubrum H+-ATPase have been studied. This detergent activates Mg2+-dependent ATP hydrolysis in the isolated R. rubrum F0-F1 34-fold, whereas the Ca2+-ATPase activity is only slightly modified. ATPase activation by lauryl dimethylamine oxide enhances the effect on ATP hydrolysis exerted by free Mg2+ ions. Concentrations of free Mg2+ in the range of 0.025 mM favor activation while higher concentrations inhibit ATPase activity by approximately 70%. Steady-state kinetic analysis shows that lauryl dimethylamine oxide induces a complex kinetic behavior for Mg-ATP in the chromatophores, similar to the untreated F0-F1 complex. The initial rate value for Mg-ATP unisite catalysis was found to be 6.3 times higher (3.5 X 10(-3) mol Pi per mol R. rubrum F0-F1 per second) in the presence than in the absence of detergent, where the initial rate was 5.5 X 10(-4) mol Pi per mol R. rubrum F0-F1 per second. These experiments show that lauryl dimethylamine oxide shifts the cation requirement for ATP-hydrolysis of the isolated R. rubrum H+-ATPase from Ca2+ to Mg2+ and that it activates both multisite and unisite catalysis. Results are discussed in relation to the possibility of a regulatory role by Mg2+ ions on ATP hydrolysis expressed through subunit interactions.     

Resolution and reconstitution of H+ -ATPase complex from beef heart mitochondria

Mitochondrial H+ -ATPase complex, purified by the lysolecithin extraction procedure, has been resolved into a "membrane" (NaBr-F0) and a "soluble" fraction by treatment with 3.5 M sodium bromide. The NaBr-F0 fraction is completely devoid of beta, delta, and epsilon subunits of the F, ATPase and largely devoid of alpha and gamma subunits of F1, where F0 is used to denote the membrane fraction and F1, coupling factor 1. This is confirmed by complete loss of ATPase and Pi-ATP exchange activities. The addition of F1 (400 micrograms X mg-1 F0) results in complete restoration of oligomycin sensitivity without any reduction in the F1-ATPase activity. Presumably, this is due to release of ATPase inhibitor protein from the F1-F0 complex consequent to sodium bromide extraction. Restoration of Pi-ATP exchange and H+ -pumping activities require coupling factor B in addition to F1-ATPase. The oligomycin-sensitive ATPase and 32Pi-ATP exchange activities in reconstituted F1-F0 have the same sensitivity to uncouplers and energy transfer inhibitors as in starting submitochondrial particles from the heavy layer of mitochondria and F1-F0 complex. The data suggest that the altered properties of NaBr-F0 observed in other laboratories are probably inherent to their F1-F0 preparations rather than to sodium bromide treatment itself. The H+ -ATPase (F1-F0) complex of all known prokaryotic (3, 8, 9, 10, 21, 32, 34) and eukaryotic (11, 26, 30, 33, 35-37) phosphorylating membranes contain two functionally and structurally distinct entities. The hydrophilic component F1, composed of five unlike subunits, shows ATPase activity that is cold labile as well as uncoupler- and oligomycin-insensitive. The membrane-bound hydrophobic component F0, having no energy-linked catalytic activity of its own, is indirectly assayed by its ability to regain oligomycin sensitive ATPase and Pi-ATP exchange activities on binding to F1-ATPase (33). The purest preparations of bovine heart mitochondrial F0 show seven or eight major components in polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate or SDS-PAGE (1, 2, 12, 14), ranging from 6 to 54 ku in molecular weight (12). The precise structure and polypeptide composition of mitochondrial F0 is not known. The F0 preparations from bovine heart reported so far have been derived from H+ -ATPase preparations isolated in the presence of cholate and deoxycholate (11, 33, 36, 37).(ABSTRACT TRUNCATED AT 400 WORDS)     

H+ transport by reconstituted gastric (H+ + K+)-ATPase

Gastric (H+ + K+)-ATPase was reconstituted into artificial phosphatidylcholine/cholesterol liposomes by means of a freeze-thaw-sonication technique. Upon addition of MgATP, active H+ transport was observed, with a maximal rate of 2.1 mumol X mg-1 X min-1, requiring the presence of 100 mM K+ at the intravesicular site. However, in the absence of ATP an H+-K+ exchange with a maximal rate of 0.12 mumol X mg-1 X min-1 was measured, which could be inhibited by the well-known ATPase inhibitors vanadate and omeprazole, giving the first evidence of a passive K+-H+ exchange function of gastric (H+ + K+)-ATPase. An Na+-H+ exchange activity was also measured, which was fully inhibited by 1 mM amiloride. Simultaneous reconstitution of Na+/H+ antiport and (H+ + K+)-ATPase could explain why reconstituted ATPase appeared less cation-specific than the native enzyme (Rabon, E.C., Gunther, R.B., Soumarmon, A., Bassilian, B., Lewin, M.J.M. and Sachs, G. (1985) J. Biol. Chem. 260, 10200-10212).     

Inhibition of (H+ + K+)-ATPase by omeprazole in isolated gastric vesicles requires proton transport

Omeprazole was found to inhibit the (H+ + K+)-ATPase activity in isolated gastric vesicles only when acid was accumulated in the vesicle lumen. The ATPase activity was time- and dose-dependently inhibited in the presence of K+ and valinomycin. Under conditions in which no pH-gradient was generated, i.e., in the presence of K+ alone or NH4+, no effect of omeprazole was found. The degree of inhibition was directly correlated to the amount of inhibitor bound to the preparation. A stoichiometry of 2 mol radiolabelled inhibitor bound per mol phosphoenzyme was found on total inhibition of the K+ plus valinomycin-stimulated activity. This inhibitory action of omeprazole on the ATPase activity could be fully reversed by addition of beta-mercaptoethanol. The inhibition of the proton transport in the (H+ + K+)-ATPase-containing vesicles by omeprazole was also strictly correlated to the amount of bound inhibitor. The stoichiometry of binding at total inhibition of this reaction was found to be 1.4 mol per mol phosphoenzyme. The K+-stimulated p-nitrophenylphosphatase activity was inhibited in parallel with the ATPase activity, whereas the phosphoenzyme levels were affected to a lesser extent by omeprazole. Gel electrophoresis of an omeprazole-inhibited vesicle preparation showed that the radiolabel was mainly found at 94 kDa, the molecular weight of the (H+ + K+)-ATPase catalytic subunit(s).     

Characterization of epitopes of the yeast mitochondrial H+-ATPase complex recognized by monoclonal antibodies

Nine monoclonal antibodies which react with the beta subunit of the yeast mitochondrial H+-ATPase and three which react with a 25 kDa subunit of the enzyme complex (P25) have been characterized. Competitive binding studies indicated the presence of at least four antigenic regions on the beta subunit of the enzyme complex. One antigenic region of the beta subunit is recognized by two monoclonal antibodies RH 57.1 and RH 45.5 which inhibit the ATPase activity to different degrees. Antibody RH 48.6 appears to bind to a second region on the beta subunit and has no effect on the ATPase activity. A third region of the beta subunit is recognized by antibodies RH 51.4 and RH 72.1. RH 51.4 has no effect on the ATPase activity, whereas RH 72.1 stimulates ATPase activity. Antibody RH 32.4 which has no effect on the ATPase activity appears to bind to the fourth epitope of the beta subunit. All three monoclonal anti-P25 antibodies, RH 66.3, RH 41.2 and RH 37.0, apparently bind to the same antigenic region on this subunit. Two of the monoclonal anti-beta antibodies RH 48.6 and RH 51.4 were found to be very effective in immunoprecipitating the whole H+-ATPase complex in a solid phase system. However, the other monoclonal antibodies (and also a polyclonal antiserum) appear to induce the dissociation of one or more of the H+-ATPase subunits by their binding to the epitopes on the beta or the P25 subunits.     

Properties and subunit composition of the H+-ATPase complex from pea chloroplasts

The H+-ATPase complex from pea chloroplasts was isolated and partially purified. The complex incorporated into the phospholipid membrane can catalyze the 32Pi-ATP exchange reaction. The complex contains eight types of the subunits, five of which belong to the catalytic and three--to the hydrophobic moieties. The molecular weights of the subunits were determined.     

Stoichiometry of subunits in the H+-ATPase complex of Escherichia coli

The H+-ATPase (F1F0) of Escherichia coli was purified from cells labeled with either [35S]sulfate or [U-14C-D] glucose, and the molar ratio of subunits in the complex determined. The molar ratio was calculated from the radioactivity incorporated into each subunit, using either the subunit sulfur content or subunit molecular weight. These labeling experiments confirm an alpha 3 beta 3 gamma 1 delta 1 epsilon 1 ratio of subunits in F1, and indicate a chi 1 psi 2 omega 10 ratio of subunits in F0. The chi, psi, and omega designations used here refer to the subunits of F0 in order of decreasing molecular weight. Staining with Coomassie brilliant blue gave a reliable indication of the molar ratio of subunits in F1, but very erroneous values for each of the subunits of F0. We attempted to estimate the ratio of subunits in the native membrane, since the stoichiometry determined for the purified complex could be an anomaly of purification. These estimates were made after labeling cells with [35S]sulfate during amplification of the ATPase genes carried on a lambda transducing phage. The subunit ratios in the native membrane were reasonably close to those obtained with purified F1F0. We conclude that the stoichiometry determined reflects the composition of F1F0 in the native membrane. The most surprising conclusion from this study is that there are 10 +/- 1 omega ("proteolipid") subunits in each F1F0 complex. This is considerably more than had been assumed previously.     

Lysosomal H+-translocating ATPase has a similar subunit structure to chromaffin granule H+-ATPase complex

Subunit structure of the lysosomal H+-ATPase was investigated using cold inactivation, immunological cross-reactivity with antibodies against individual subunits of the H+-ATPase from chromaffin granules and chemical modification with N,N'-dicyclohexyl[14C]carbodiimide. The lysosomal H+-ATPase was irreversibly inhibited when incubated at 0 degrees C in the presence of chloride or nitrate and MgATP. Inactivation in the cold resulted in the release of several polypeptides (72, 57, 41, 34 and 33 kDa) from the membrane, which had the same electrophoretic mobility as the corresponding subunits of chromaffin granule H+-ATPase. Cross-reactivity of antibodies revealed that the 72, 57 and 34 kDa polypeptides were immunologically identical to the corresponding subunits of chromaffin granule H+-ATPase. Dicyclohexylcarbodiimide, which inhibits proton translocation in the vacuolar ATPase, predominantly labeled two polypeptides of 18 and 15 kDa, which compose the membrane sector of the enzyme. These results suggest that the lysosomal H+-ATPase is a multimeric enzyme, whose subunit structure is similar to the chromaffin granule H+-ATPase. The subunit structure of other vacuolar H+-ATPases, revealed by cold inactivation and immunological cross-reactivity, is also presented.     

Structure and function of H+-ATPase

(1) Extensive studies on proton-translocating ATPase (H⁺-ATPase) revealed that H⁺-ATPase is an energy transforming device universally distributed in membranes of almost all kinds of cells. (2) Crystallization of the catalytic portion (F₁) of H⁺-ATPase showed that F₁ is a hexagonal molecule with a central hole. The diameter of F₁ is about 90 Å and its molecular weight is about 380,000. (3) Use of thermophilic F₁ permits the complete reconstitution of F₁ from its five subunits (, , , , and ) and demonstration of the gate function of the -complex, the catalytic function of (supported by and ), and the H⁺-translocating functions of all five subunits. (4) Studies using purified thermostable F₀ showed that F₀ is an H⁺-channel portion of H⁺-ATPase. The direct measurement of H⁺-flux through F₀, sequencing of DCCD-binding protein, and isolation of F₁-binding protein are described. (5) The subunit stoichiometry of F₁ may be ₃₃. (6) Reconstitution of stable H⁺-ATPase-liposomes revealed that ATP is directly synthesized by the flow of H⁺ driven by an electrochemical potential gradient and that H⁺ is translocated by ATP hydrolysis. This rules out functions for all the hypothetical components that do not belong to H⁺-ATPase in H⁺-driven ATP synthesis. The roles of conformation change and other phenomena in ATP synthesis are also discussed.     

Regulatory role of the ATPase inhibitor protein on proton conduction by mitochondrial H+-ATPase complex

This study shows that the natural inhibitor protein of mitochondrial H+-ATPase complex (IF1) inhibits, in addition to the catalytic activity, the proton conductivity of the complex. The inhibition of ATPase activity by IF1 is less effective in the purified F1 than in submitochondrial particles where F1 is bound to F0. No inhibition of H+ conductivity by F0 is observed in F1-depleted particles.     

Topology and function of "stalk" proteins in the bovine mitochondrial H+-ATPase

Proton translocating ATPases comprise a hydrophilic sector F1, a membrane sector F0, and, in the case of bovine mitochondria, a connecting "stalk" which is believed to contain the oligomycin sensitivity-conferring protein (OSCP) and coupling factor 6 (F6). The present study was undertaken to verify the accessibility of F6 and OSCP to trypsin and to examine the functional consequences of such treatment. Our data show that F1 binds equally to trypsin-treated F0 and untreated F0, but the former complexes exhibit cold lability and only partial sensitivity to oligomycin. Furthermore, these complexes fail to exhibit ATP-driven proton translocation or ATP-32Pi exchange activity. Trypsinization of F0 does not, however, inhibit passive proton conductance through the membrane sector but actually enhances it. Immunological data indicate extensive degradation of OSCP under conditions where F6 proteolysis is insignificant. Intact H+-ATPase complexes are relatively resistant to both the structural and functional effects of trypsin. We conclude that OSCP is predominantly an extrinsic protein which is shielded by F1 in the native membrane. F6 may also be an extrinsic protein but is shielded from trypsinization by OSCP and/or other F0 polypeptides. The exposed, trypsin-sensitive segments of OSCP are not required for passive proton conductance through F0 but may be required for ATP-driven reactions. We propose that bovine mitochondrial OSCP is a functional analogue of subunit b in the Escherichia coli H+-ATPase.     

The glycolytic enzyme aldolase mediates assembly, expression, and activity of vacuolar H+-ATPase

Vacuolar H(+)-ATPases (V-ATPases) are a family of highly conserved proton pumps that couple hydrolysis of cytosolic ATP to proton transport out of the cytosol. How ATP is supplied for V-ATPase-mediated hydrolysis and for coupling of proton transport is poorly understood. We have reported that the glycolytic enzyme aldolase physically associates with V-ATPase. Here we show that aldolase interacts with three different subunits of V-ATPase (subunits a, B, and E). The binding sites for the V-ATPase subunits on aldolase appear to be on distinct interfaces of the glycolytic enzyme. Aldolase deletion mutant cells were able to grow in medium buffered at pH 5.5 but not at pH 7.5, displaying a growth phenotype similar to that observed in V-ATPase subunit deletion mutants. Abnormalities in V-ATPase assembly and protein expression observed in aldolase deletion mutant cells could be fully rescued by aldolase complementation. The interaction between aldolase and V-ATPase increased dramatically in the presence of glucose, suggesting that aldolase may act as a glucose sensor for V-ATPase regulation. Taken together, these findings provide functional evidence that the ATP-generating glycolytic pathway is directly coupled to the ATP-hydrolyzing proton pump through physical interaction between aldolase and V-ATPase.     

Vacuolar-type H+ -ATPase distribution in unstimulated and acetylcholine-activated isolated human eccrine sweat glands

The presence and cellular distribution of subunits of the V₁ sector of the vacuolar-type H⁺-ATPase (V-ATPase) was investigated in isolated human eccrine sweat glands. In every instance, V-ATPase was located in the cytoplasm and apical membranes of the luminal cells of the reabsorptive duct segment. In the secretory coil, both diffuse and perinuclear staining was demonstrated in the secretory cells, with additional expression at the apical and basolateral membranes and on the intercellular canaliculi. There was no detectable difference in V-ATPase expression as a result of prior application of 100µM acetylcholine.     

Diamide blocks H+ conductance in mitochondrial H+-ATPase by oxidizing FB dithiol

Effects of diamide on proton conductance of electron transport particles (ETPH), purified H+-ATPase (F1-F0), F0 of the H+-ATPase from beef heart mitochondria and binding of cadmium (109Cd) to the H+-ATPase have been examined in the present paper. When ETPH and purified H+-ATPase are treated with 1 mM diamide, ATP-dependent generation of membrane potential, monitored by the absorbance change produced by the redistribution of oxonol VI, is consistently inhibited. Diamide also blocks passive H+ conductance driven by a K+ diffusion potential in the membrane sector, F0, of H+-ATPase. Furthermore, diamide treatment drastically reduces the binding of 109Cd2+ to H+-ATPase, showing competition for the FB dithiol group.