EC:3.6.3.14 - FACTA Search

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Query: EC:3.6.3.14 (ATP synthase)
7,042 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The interaction faces of the gamma and epsilon subunits in the Escherichia coli F1-ATPase have been explored by a combination of cross-linking and chemical modification experiments using several mutant epsilon subunits as follows: epsilonS10C, epsilonH38C, epsilonT43C, epsilonS65C, epsilonS108C, and epsilonM138C, along with a mutant of the gamma subunit, gammaT106C. The replacement of Ser-10 by a Cys or Met-138 by a Cys reduced the inhibition of ECF1 by the epsilon subunit, while the mutation S65C increased this inhibitory effect. Modification of the Cys at position 10 with N-ethylmaleimide or fluoroscein maleimide further reduced the binding affinity of, and the maximal inhibition by, the epsilon subunit. Similar chemical modification of the Cys at position 43 of the epsilon subunit (in the mutant epsilonT43C) and a Cys at position 106 of the gamma subunit (gammaT106C) also affected the inhibition of ECF1 by the epsilon subunit. The various epsilon subunit mutants were reacted with TFPAM3, and the site(s) of cross-linking within the ECF1 complex was determined. Previous studies have shown cross-linking from the Cys at positions 10 and 38 with the gamma subunit and from a Cys at position 108 to an alpha subunit (Aggeler, R., Chicas-Cruz, K., Cai, S. X., Keana, J. F. W., and Capaldi, R. A. (1992) Biochemistry 31, 2956-2961; Aggeler, R., Weinreich, F., and Capaldi, R. A. (1995) Biochim. Biophys. Acta 1230, 62-68). Here, cross-linking was found from a Cys at position 43 to the gamma subunit and from the Cys at position 138 to a beta subunit. The site of cross-linking from Cys-10 of epsilon to the gamma subunit was localized by peptide mapping to a region of the gamma subunit between residues 222 and 242. Cross-linking from a Cys at position 38 and at position 43 was with the C-terminal part of the gamma subunit, between residues 202 and 286. ECF1 treated with trypsin at pH 7.0 still binds purified epsilon subunit, while enzyme treated with the protease at pH 8.0 does not. This identifies sites around residue 70 and/or between 202 and 212 of the gamma subunit as involved in epsilon subunit binding.
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PMID:Characterization of the interface between gamma and epsilon subunits of Escherichia coli F1-ATPase. 862 95

Replacement of the F0F1 ATP synthase gamma subunit Met-23 with Lys (gammaM23K) perturbs coupling efficiency between transport and catalysis (Shin, K., Nakamoto, R. K., Maeda, M., and Futai, M. (1992) J. Biol. Chem. 267, 20835-20839). We demonstrate here that the gammaM23K mutation causes altered interactions between subunits. Binding of delta or epsilon subunits stabilizes the alpha3beta3gamma complex, which becomes destabilized by the mutation. Significantly, the inhibition of F1 ATP hydrolysis by the epsilon subunit is no longer relieved when the gammaM23K mutant F1 is bound to F0. Steady state Arrhenius analysis reveals that the gammaM23K enzyme has increased activation energies for the catalytic transition state. These results suggest that the mutation causes the formation of additional bonds within the enzyme that must be broken in order to achieve the transition state. Based on the x-ray crystallographic structure of Abrahams et al. (Abrahams, J. P., Leslie, A. G. W., Lutter, R., and Walker, J. E. (1994) Nature 370, 621-628), the additional bond is likely due to gammaM23K forming an ionized hydrogen bond with one of the betaGlu-381 residues. Two second site mutations, gammaQ269R and gammaR242C, suppress the effects of gammaM23K and decrease activation energies for the gammaM23K enzyme. We conclude that gammaM23K is an added function mutation that increases the energy of interaction between gamma and beta subunits. The additional interaction perturbs transmission of conformational information such that epsilon inhibition of ATPase activity is not relieved and coupling efficiency is lowered.
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PMID:Energy coupling, turnover, and stability of the F0F1 ATP synthase are dependent on the energy of interaction between gamma and beta subunits. 899 37

Previously, we established a method to detect subunit interactions of F1-ATPase by the yeast two-hybrid system (Moritani, C., et al. Biochim. Biophys. Acta 1274, 67-72, 1996). Here, we isolated mutants of the gamma subunits defective in interaction with the epsilon subunit by this new procedure to study the molecular basis of coupling mechanisms of the F1F0-ATPase. Based on the intensities of the reporter gene expression in this system, five mutants of the gamma subunit with different levels of gamma-epsilon interactions were isolated and their single base substitutions were determined. Mutants with a substitution of Pro-55 for Leu, Thr-102 for Met, Val-141 for Asp, or Gln-235 for Leu exhibited decreased reporter gene expression, suggesting decreased levels of interaction, while Asp-85 for Gly mutation caused a higher level of expression, suggesting increased interaction. Among these point mutations, G85D, M102T, or D141V mutations were introduced into the gamma subunit gene in the plasmid carrying whole unc operon. Transformants carrying a deletion mutant of the whole unc operon with these expression plasmids were analyzed. Mutations M102T and D141V with decreased gamma-epsilon interaction caused increases of membrane-bound F1-ATPase activity and proton pumping activity, while G85D with increased gamma-epsilon interaction exhibited lower levels of F1-ATPase activity in the membranes. Molecular assembly of the F1 subunits on the mutant membranes detected by Western blotting exhibited no defect for all three mutants. These results suggested that the correlation between the ATPase activity and gamma-epsilon interaction is reciprocal and this interaction may regulate the ATPase activity. The topological and functional importance of Gly-85, Met-102, and Asp-141 together with Leu-55 and Leu-235 in gamma-epsilon interaction is discussed.
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PMID:Subunit interactions of Escherichia coli F1-ATPase: mutants of the gamma subunits defective in interaction with the epsilon subunit isolated by the yeast two-hybrid system. 939 Jan 90

An affinity resin for the F1 sector of the Escherichia coli ATP synthase was prepared by coupling the b subunit to a solid support through a unique cysteine residue in the N-terminal leader. b24-156, a form of b lacking the N-terminal transmembrane domain, was able to compete with the affinity resin for binding of F1. Truncated forms of b24-156, in which one or four residues from the C terminus were removed, competed poorly for F1 binding, suggesting that these residues play an important role in b-F1 interactions. Sedimentation velocity analytical ultracentrifugation revealed that removal of these C-terminal residues from b24-156 resulted in a disruption of its association with the purified delta subunit of the enzyme. To determine whether these residues interact directly with delta, cysteine residues were introduced at various C-terminal positions of b and modified with the heterobifunctional cross-linker benzophenone-4-maleimide. Cross-links between b and delta were obtained when the reagent was incorporated at positions 155 and 158 (two residues beyond the normal C terminus) in both the reconstituted b24-156-F1 complex and the membrane-bound F1F0 complex. CNBr digestion followed by peptide sequencing showed the site of cross-linking within the 177-residue delta subunit to be C-terminal to residue 148, possibly at Met-158. These results indicate that the b and delta subunits interact via their C-terminal regions and that this interaction is instrumental in the binding of the F1 sector to the b subunit of F0.
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PMID:The b and delta subunits of the Escherichia coli ATP synthase interact via residues in their C-terminal regions. 961 29

The rotation of the gamma-subunit has been included in the binding-change mechanism of ATP synthesis/hydrolysis by the proton ATP synthase (FOF1). The Escherichia coli ATP synthase was engineered for rotation studies such that its ATP hydrolysis and synthesis activity is similar to that of wild type. A fluorescently labeled actin filament connected to the gamma-subunit of the F1 sector rotated on addition of ATP. This progress enabled us to analyze the gammaM23K (the gamma-subunit Met-23 replaced by Lys) mutant, which is defective in energy coupling between catalysis and proton translocation. We found that the F1 sector produced essentially the same frictional torque, regardless of the mutation. These results suggest that the gammaM23K mutant is defective in the transformation of the mechanical work into proton translocation or vice versa.
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PMID:The gamma-subunit rotation and torque generation in F1-ATPase from wild-type or uncoupled mutant Escherichia coli. 1039 98

The b subunit dimer of the Escherichia coli ATP synthase, along with the delta subunit, is thought to act as a stator to hold the alpha(3)beta(3) hexamer stationary relative to the a subunit as the gammaepsilonc(9-12) complex rotates. Despite their essential nature, the contacts between b and the alpha, beta, and a subunits remain largely undefined. We have introduced cysteine residues individually at various positions within the wild type membrane-bound b subunit, or within b(24-156), a truncated, soluble version consisting only of the hydrophilic C-terminal domain. The introduced cysteine residues were modified with a photoactivatable cross-linking agent, and cross-linking to subunits of the F(1) sector or to complete F(1)F(0) was attempted. Cross-linking in both the full-length and truncated forms of b was obtained at positions 92 (to alpha and beta), and 109 and 110 (to alpha only). Mass spectrometric analysis of peptide fragments derived from the b(24-156)A92C cross-link revealed that cross-linking took place within the region of alpha between Ile-464 and Met-483. This result indicates that the b dimer interacts with the alpha subunit near a non-catalytic alpha/beta interface. A cysteine residue introduced in place of the highly conserved arginine at position 36 of the b subunit could be cross-linked to the a subunit of F(0) in membrane-bound ATP synthase, implying that at least 10 residues of the polar domain of b are adjacent to residues of a. Sites of cross-linking between b(24-156)A92C and beta as well as b(24-156)I109C and alpha are proposed based on the mass spectrometric data, and these sites are discussed in terms of the structure of b and its interactions with the rest of the complex.
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PMID:Site-directed cross-linking of b to the alpha, beta, and a subunits of the Escherichia coli ATP synthase. 1074 4

Angiostatin effectively blocks tumor angiogenesis through still poorly understood mechanisms. Given the close association between immune and vascular regulation, we investigated the effects of angiostatin on angiogenesis-associated leukocytes. Angiostatin inhibited the migration of monocytes and, even more markedly, neutrophils. Angiostatin blocked chemotaxis of neutrophils to CXCR2 chemokine receptor agonists (IL-8, MIP-2, and GROalpha), formyl-Met-Leu-Phe (fMLP), and 12-O-tetradecanoylphorbol 13-acetate, and repressed fMLP-induced mitochondrial activity. Two different angiostatin forms (kringles 1-4 and 1-3) were effective, whereas whole plasminogen had no effect. IL-8, MIP-2, and GROalpha induced intense angiogenic reactions in vivo, but no angiogenic response to these factors was observed in neutropenic mice, demonstrating an essential role for neutrophils. Angiostatin potently inhibited chemokine-induced angiogenesis in vivo, and consistent with in vitro observations, both angiostatin forms were active and whole plasminogen had little effect. Angiostatin inhibition of angiogenesis in vivo was accompanied by a striking reduction in the number of recruited leukocytes. In vivo, the inflammatory agent lipopolysaccharide also induced extensive leukocyte infiltration and angiogenesis that were blocked by angiostatin. Neutrophils expressed mRNAs for ATP synthase and angiomotin, two known angiostatin receptors. These data show that angiostatin directly inhibits neutrophil migration and neutrophil-mediated angiogenesis and indicate that angiostatin might inhibit inflammation.
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PMID:Neutrophils as a key cellular target for angiostatin: implications for regulation of angiogenesis and inflammation. 1177 50

Tentoxin, a natural cyclic tetrapeptide produced by phytopathogenic fungi from the Alternaria species affects the catalytic function of the chloroplast F(1)-ATPase in certain sensitive species of plants. In this study, we show that the uncompetitive inhibitor tentoxin binds to the alphabeta-interface of the chloroplast F(1)-ATPase in a cleft localized at betaAsp-83. Most of the binding site is located on the noncatalytic alpha-subunit. The crystal structure of the tentoxin-inhibited CF(1)-complex suggests that the inhibitor is hydrogen bonded to Asp-83 in the catalytic beta-subunit but forms hydrophobic contacts with residues Ile-63, Leu-65, Val-75, Tyr-237, Leu-238, and Met-274 in the adjacent alpha-subunit. Except for minor changes around the tentoxin-binding site, the structure of the chloroplast alpha(3)beta(3)-core complex is the same as that determined with the native chloroplast ATPase. Tentoxin seems to act by inhibiting inter-subunit contacts at the alphabeta-interface and by blocking the interconversion of binding sites in the catalytic mechanism.
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PMID:Structure of spinach chloroplast F1-ATPase complexed with the phytopathogenic inhibitor tentoxin. 1190 10

The stator in F(1)F(o)-ATP synthase resists strain generated by rotor torque. In Escherichia coli, the b(2)delta subunit complex comprises the stator, bound to subunit a in F(o) and to the alpha(3)beta(3) hexagon of F(1). Previous work has shown that N-terminal residues of alpha subunit are involved in binding delta. A synthetic peptide consisting of the first 22 residues of alpha (alphaN1-22) binds specifically to isolated wild-type delta subunit with 1:1 stoichiometry and high affinity, accounting for a major portion of the binding energy between delta and F(1). Residues alpha6-18 are predicted by secondary structure algorithms and helical wheels to be alpha-helical and amphipathic, and a potential helix capping box occurs at residues alpha3-8. We introduced truncations, deletions, and mutations into alphaN1-22 peptide and examined their effects on binding to the delta subunit. The deletions and mutations were introduced also into the N-terminal region of the uncA (alpha subunit) gene to determine effects on cell growth in vivo and membrane ATP synthase activity in vitro. Effects seen in the peptides were well correlated with those seen in the uncA gene. The results show that, with the possible exception of residues close to the initial Met, all of the alphaN1-22 sequence is required for binding of delta to alpha. Within this sequence, an amphipathic helix seems important. Hydrophobic residues on the predicted nonpolar surface are important for delta binding, namely alphaIle-8, alphaLeu-11, alphaIle-12, alphaIle-16, and alphaPhe-19. Several or all of these residues probably make direct interaction with helices 1 and 5 of delta. The potential capping box sequence per se appeared less important. Impairment of alpha/delta binding brings about functional impairment due to reduced level of assembly of ATP synthase in cells.
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PMID:Analysis of sequence determinants of F1Fo-ATP synthase in the N-terminal region of alpha subunit for binding of delta subunit. 1506 69

The atpE gene encoding the subunit c of the ATP synthase of Mycobacterium tuberculosis, the target of the new diarylquinoline drug R207910, has been sequenced from in vitro mutants resistant to the drug. The previously reported mutation A63P and a new mutation, I66M, were found. The genetic diversity of atpE in 13 mycobacterial species was also investigated, revealing that the region involved in resistance to R207910 is conserved, except in Mycobacterium xenopi in which the highly conserved residue Ala63 is replaced by Met, a modification that may be associated with the natural resistance of M. xenopi to R207910.
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PMID:Genetic basis for natural and acquired resistance to the diarylquinoline R207910 in mycobacteria. 1687 Jul 85

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