EC:3.6.1.3 - FACTA Search

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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We introduced mutations to test the function of the conserved amino-terminal region of the gamma subunit from the Escherichia coli ATP synthase (F0F1-ATPase). Plasmid-borne mutant genes were expressed in an uncG strain which is deficient for the gamma subunit (gamma Gln-14-->end). Most of the changes, which were between gamma Ile-19 and gamma Lys-33, gamma Asp-83 and gamma Cys-87, or at gamma Asp-165, had little effect on growth by oxidative phosphorylation, membrane ATPase activity, or H+ pumping. Notable exceptions were gamma Met-23-->Arg or Lys mutations. Strains carrying these mutations grew only very slowly by oxidative phosphorylation. Membranes prepared from the strains had substantial levels of ATPase activity, 100% compared with wild type for gamma Arg-23 and 65% for gamma Lys-23, but formed only 32 and 17%, respectively, of the electrochemical gradient of protons. In contrast, other mutant enzymes with similar ATPase activities (including gamma Met-23-->Asp or Glu) formed H+ gradients like the wild type. Membranes from the gamma Arg-23 and gamma Lys-23 mutants were not passively leaky to protons and had functional F0 sectors. These results suggested that substitution by positively charged side chains at position 23 perturbed the energy coupling. The catalytic sites of the mutant enzymes were still regulated by the electrochemical H+ gradient but were inefficiently coupled to H+ translocation in both ATP-dependent H+ pumping and delta mu H+ driven ATP synthesis.
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PMID:F0F1-ATPase gamma subunit mutations perturb the coupling between catalysis and transport. 140 Mar 98

The large plastid ATP synthase operon of the multicellular red alga Antithamnion sp. was cloned and the sequence of six ATPase genes determined. The operon resembles more the one from cyanobacteria than the ATP synthase operon of the chloroplast genome. The gene order is atpI, H, G, F, D and A, coding for the ATPase subunits a, c, b', b, delta and alpha, respectively. In green plants, the genes atpG and atpD are located in the nucleus. Unlike the situation in three published cyanobacterial ATP synthase operons, atpC, coding for the gamma subunit, is not a part of the rhodoplast operon. A single 4.5 kb transcript was detected with atpG, F, D and A gene probes that could span the whole operon, but no transcript could be detected with atpI and atpH probes. The end of an open reading frame preceding the atp genes shows remarkable homology to elongation factor TS from Escherichia coli. Behind the ATPase cluster, two open reading frames were detected that are not homologous to any known chloroplast gene. One of them may code for a transport protein of unknown specificity. Gene arrangement and sequence comparisons support the hypothesis of a polyphyletic origin of rhodoplasts and chloroplasts.
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PMID:Large ATP synthase operon of the red alga Antithamnion sp. resembles the corresponding operon in cyanobacteria. 140 1

The basic structures of the catalytic portion (F1, alpha 3 beta 3 gamma delta epsilon) of ATP synthase are the alpha 3 beta 3 hexamer (oligomer with cooperativity) and alpha 1 beta 1 heterodimer (protomer). These were reconstituted from the alpha and beta subunits of thermophilic F1 (TF1), and the alpha 3 beta 3 hexamer was crystallized. On electrophoresis, both the dimer and hexamer showed bands with ATPase activity. Using the dimer and hexamer, we studied the nucleotide-dependent rapid molecular dynamics. The formation of the hexamer required neither nucleotide nor Mg. The hexamer was dissociated into the dimer in the presence of MgADP, while the dimer was associated into the hexamer in the presence of MgATP. The hexamer, like mitochondrial F1 and TF1, showed two kinds of ATPase activity: one was cooperative and was inhibited by only one BzADP per hexamer, and the other was inhibited by three BzADP per hexamer.
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PMID:The alpha beta complexes of ATP synthase: the alpha 3 beta 3 oligomer and alpha 1 beta 1 protomer. 142 37

The DNA of subunit II of the H(+)-ATPase from spinach chloroplast was expressed in Escherichia coli. It was found that a high gene dose is lethal to E. coli. With a lower gene dose subunit II was not able to substitute for the homologous subunit b in the E. coli ATP synthase.
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PMID:Expression of subunit II of chloroplast H(+)-ATPase in an Escherichia coli mutant lacking subunit b of its H(+)-ATPase. 144 71

Photophosphorylation in halobacteria is carried out by two rather simple elements: an A-type ATP synthase and light-driven ion-pumping bacterial rhodopsins. The unique features of halobacterial ATP synthase, mostly common to archaebacteria (A-type), and of new members of the bacteriorhodopsin family are introduced along with studies performed in the authors' laboratory. This is the story of how we found that the A-type ATP synthase is close to V-type ATPase but far from F-type ATPase, although all three ATPases are believed to have the same ancestor. Archaerhodopsins, the new members of the proton-pumping retinal proteins, were found in Australian halobacteria and have been used in a comparative study of bacterial rhodopsins.
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PMID:Photophosphorylation elements in halobacteria: an A-type ATP synthase and bacterial rhodopsins. 145 86

Yeast Saccharomyces cerevisiae oligomycin sensitivity conferring proteins (OSCP) have been expressed in Escherichia coli. Heterologous expression results in production of a protein that is identical to yeast mature OSCP, including the absence of the initiating methionine residue. Yeast OSCP expressed in E. coli has been purified to homogeneity and it is able to reconstitute oligomycin-sensitive ATPase using purified F1- and F1/OSCP-depleted membranes (electron transport particles (ETP). Binding of F1 to ETP is dependent on the addition of OSCP. Binding studies using 35S-OSCP indicated that OSCP binds to ETP with a Kd of 200 nM and a capacity of 420 pmol/mg particle protein, whereas OSCP does not interact with F1 in the absence of ETP. These data indicate that yeast OSCP must first form a specific complex with F0, which then binds F1 forming the functional complex. To identify functional domains in yeast OSCP, two deletion mutants have been made. Antibodies directed to these deletion products do not inhibit OSCP-dependent binding of F1 to ETP. However, antibodies directed against the last one-third of OSCP greatly reduce the oligomycin sensitivity of the reconstituted ATPase. These data suggest that OSCP is involved in a functional role in energy transduction or proton translocation and serves a structural role in the yeast mitochondrial ATP synthase.
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PMID:Heterologous expression, purification, and biochemistry of the oligomycin sensitivity conferring protein (OSCP) from yeast. 146 86

Many parasitic protozoa go through complex life cycles in the course of which they adapt to widely different environments; ion transport processes are expected to play a role both in pathogenicity and in adaptation. So far, studies on ion transport have been virtually limited to Leishmania, Plasmodium and Entamoeba. The distribution of ion pumps in the former two organisms generally appears to conform to the picture established for other protozoa, i.e. a proton-motive P-ATPase in the plasma membrane provides the driving force for H(+)-coupled secondary-active transport, a proton-motive V-ATPase in the digestive vacuoles is responsible for vacuolar acidification, and an F-ATPase (ATP synthase) is found in the mitochondria. The situation in Entamoeba, an archaic organism that lacks mitochondria, could be different from that in the two other parasites in that a V-ATPase may be present and active both in the plasma membrane and in the membranes of the endocytic vesicles.
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PMID:Ion transport in parasitic protozoa. 149 Dec 29

(1) Previous mutational analyses have shown that residue beta R398 of the beta-subunit is a key residue for binding of the inhibitory antibiotic aurovertin to Escherichia coli F1Fo-ATP synthase. Here, we studied purified F1 from the beta R398C and beta R398W mutants. ATPase activity in both cases was resistant to aurovertin inhibition. The fluorescence spectrum (lambda exc = 278 or 295 nm) of beta R398W F1 showed a significant red-shift as compared to wild-type and beta R398C enzymes, indicating that residue beta R398 lies in a polar environment. On the basis of this and previous evidence, we propose that aurovertin binding to F1-ATPase involves a specific charged donor-acceptor H-bond between residue beta R398 and the 7-hydroxyl group of aurovertin. (2) The fluorescent substrate analog lin-benzo-ADP was shown to bind to beta R398W F1 catalytic sites with the same Kd values as to wild-type F1, and with the same quenching of the fluorescence of the analog. Fluorescence energy transfer was seen between the beta R398W residue and bound lin-benzo-ADP. Analysis of transfer efficiency at varying stoichiometry of bound lin-benzo-ADP showed that interaction occurred between one beta R398W residue and one catalytic-site-bound analog molecule at a distance of approximately 23 A. The relationships of the aurovertin and catalytic sites in the primary and tertiary structure are discussed.
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PMID:Investigation of the aurovertin binding site of Escherichia coli F1-ATPase by fluorescence spectroscopy and site-directed mutagenesis. 153 96

Studies to establish the structure/function relationships of oligomycin sensitivity-conferring protein (OSCP) of mitochondrial ATP synthase were carried out using genetic engineering and biochemical approaches. A full-length cDNA clone encoding OSCP was isolated from a bovine heart cDNA library, and the mature form of OSCP was expressed in Escherichia coli using plasmid expression vector pKP1500. Recombinant OSCP was found to accumulate in the cytoplasmic inclusion bodies, by virtue of which the recombinant protein could be purified to greater than 85% purity by simple low speed centrifugation of cell lysates. Recombinant OSCP was found to be indistinguishable from OSCP isolated from mitochondria with respect to (i) apparent molecular mass on sodium dodecyl sulfate gel electrophoresis, (ii) immunological reactivity to anti-OSCP serum, (iii) biological activity in restoring oligomycin-sensitive ATPase and Pi-ATP exchange activities to OSCP-depleted ATP synthase complexes, and (iv) insensitivity of the biological activity to sulfhydryl-directed alkylating reagents. The amino-terminal sequence of the recombinant protein revealed that the initiating methionine was not removed by E. coli, although that apparently did not affect protein folding or its biological activity. Data on nested deletion mutations starting from the carboxyl terminus in OSCP demonstrated that, in each instance, the mutant form was expressed and the protein product was sequestered in cytoplasmic inclusion bodies, similar to the wild-type form. However, none of the variants, including the one in which only the last 10 residues were deleted, was able to restore cold-stable oligomycin-sensitive ATPase or Pi-ATP exchange activity in OSCP-depleted complexes. Taken together, these data suggest that amino acid residues 181-190 (or some of the residues in this region) in the OSCP sequence may be important for OSCP-F1 interactions.
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PMID:Oligomycin sensitivity-conferring protein (OSCP) of mitochondrial ATP synthase. The carboxyl-terminal region of OSCP is essential for the reconstitution of oligomycin-sensitive H(+)-ATPase. 153 27

The rate of trypsin cleavage of the epsilon subunit of Escherichia coli F1 (ECF1) has been found to be ligand-dependent, as measured indirectly by the activation of the enzyme that occurs on protease digestion, or when followed directly by monitoring the cleavage of this subunit using monoclonal antibodies. The cleavage of the epsilon subunit was fast in the presence of ADP alone, ADP + MG2+, ATP + EDTA, or AMP-PNP, but slow when Pi was added along with ADP + Mg2+ or when ATP + Mg2+ was added to generate ADP + Pi (+Mg2+) in the catalytic site(s). The half-maximal concentration of Pi required in the presence of ADP + Mg2+ to protect the epsilon subunit from cleavage by trypsin was 50 microM, which is in the range measured for the high-affinity binding of Pi to F1. The ligand-dependent conformational changes in the epsilon subunit were also examined in cross-linking experiments using the water-soluble carbodiimide 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide (EDC). In the presence of ATP + Mg2+ or ADP + Mg2+ + Pi, the epsilon subunit cross-linked to beta in high yield. With ATP + EDTA or ADP + Mg2+ (no Pi), the yield of the beta-epsilon cross-linked product was much reduced. We conclude that the epsilon subunit undergoes a conformational change dependent on the presence of Pi. It has been found previously that binding of the epsilon subunit to ECF1 inhibits ATPase activity by decreasing the off rate of Pi [Dunn, S. D., Zadorozny, V. D., Tozer, R. G., & Orr, L. E. (1987) Biochemistry 26, 4488-4493]. This reciprocal relationship between Pi binding and epsilon-subunit conformation has important implications for energy transduction by the E. coli ATP synthase.
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PMID:Catalytic site nucleotide and inorganic phosphate dependence of the conformation of the epsilon subunit in Escherichia coli adenosinetriphosphatase. 182 19

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