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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)
Novel tryptophan substitutions, surrounding the nucleotide bound in catalytic sites, were introduced into Escherichia coli
F1-ATPase
. The mutant enzymes were purified and studied by fluorescence spectroscopy. One cluster of Trp substitutions, consisting of beta-Trp-404, beta-Trp-410, beta-
Asp
-158 (lining the adenine-binding pocket), and beta-Trp-153 (close to the alpha/beta-phosphates), showed the same fluorescence responses to MgADP, MgAMPPNP, and MgATP and the same nucleotide binding pattern with MgADP and MgAMPPNP, with one site of higher and two sites of lower affinity. Therefore, in absence of catalytic turnover (and of gamma-subunit rotation), sites 2 and 3 appeared similar in affinity, and the region of the catalytic site sensed by these Trp substitutions did not change conformation with different nucleotides. In contrast, alpha-Trp-291 and beta-Trp-297, both close to the gamma-phosphate, showed very different fluorescence responses to MgADP versus MgAMPPNP, and in these cases the response was due exclusively or predominantly to nucleotide binding at the first, high-affinity catalytic site, thus allowing specific detection of this site. Titration with MgATP showed that the high-affinity site was present under conditions of steady-state, Vmax MgATP hydrolysis.
...
PMID:Tryptophan substitutions surrounding the nucleotide in catalytic sites of F1-ATPase. 972 15
Subunit 8 (Y8), a mitochondrially encoded subunit of the F0 sector of the F1F0-
ATP synthase
is essential for oxidative phosphorylation. We have previously introduced the technique of allotopic expression to study the structure/function of Y8, whereby an artificial Y8 gene is expressed in the nucleus of cells lacking a functional mitochondrial Y8, thus generating assembly of a functional F1F0-ATPase complex. In this paper we show that when a gene encoding an essentially unmodified version of Y8 is allotopically expressed, ATP synthesis and hydrolysis rates, as well as efficiency of oxidative phosphorylation, were similar to those of the parental wild-type strain in which Y8 is naturally expressed in mitochondria. We then tested the requirement for the hydrophobicity of the central domain (residues 14-32), which possibly represents a transmembrane stem, by introducing adjacent negative charges at different positions of Y8. One of the variants thus generated, which carries the double substitution Leu23-->
Asp
, Leu24-->
Asp
, when expressed in a strain lacking endogenous Y8, gave rise to cells which grew very slowly by oxidative phosphorylation. Measurement of bioenergetic parameters showed two major defects in these cells relative to control cells allotopically expressing unmodified Y8. First, the activity of the F1F0-
ATP synthase
was significantly decreased. ATP synthesis and state 3 of respiration were reduced by approximately 30-40%. ATP hydrolysis was reduced by approximately 30% and was almost insensitive to the F0 inhibitor oligomycin. Second, the physical coupling between the two sectors of the enzyme, as well as the stability of the F1 sector itself, were affected as shown by decreased recovery of F0 sector [8, 9, b, oligomycin sensitivity-conferring protein (OSCP), d, h and f] and F1 sector (alpha, gamma, delta) subunits in immunoprecipitates of
ATP synthase
. This study indicates that Y8 not only performs an important role in the structure of the mitochondrial complex but also in its activity. We conclude that the hydrophobic character of amino acids 23 and 24 in the middle of the putative transmembrane stem of Y8 is essential for coupling proton transport through F0 to ATP synthesis on F1.
...
PMID:Bioenergetic and structural consequences of allotopic expression of subunit 8 of yeast mitochondrial ATP synthase. The hydrophobic character of residues 23 and 24 is essential for maximal activity and structural stability of the enzyme complex. 1021 55
The structure of the subunit c oligomer of the H+-transporting
ATP synthase
of Escherichia coli has been modeled by molecular dynamics and energy minimization calculations from the solution structure of monomeric subunit c and 21 intersubunit distance constraints derived from cross-linking of subunits. Subunit c folds in a hairpin-like structure with two transmembrane helices. In the c12 oligomer model, the subunits pack to form a compact hollow cylinder with an outer diameter of 55-60 A and an inner space with a minimal diameter of 11-12 A. Phospholipids are presumed to pack in the inner space in the native membrane. The transmembrane helices pack in two concentric rings with helix 1 inside and helix 2 outside. The calculations strongly favor this structure versus a model with helix 2 inside and helix 1 outside.
Asp
-61, the H+-transporting residue, packs toward the center of the four transmembrane helices of two interacting subunits. From this position at the front face of one subunit, the
Asp
-61 carboxylate lies proximal to side chains of Ala-24, Ile-28, and Ala-62, projecting from the back face of a second subunit. These interactions were predicted from previous mutational analyses. The packing supports the suggestion that a c-c dimer is the functional unit. The positioning of the
Asp
-61 carboxyl in the center of the interacting transmembrane helices, rather than at the periphery of the cylinder, has important implications regarding possible mechanisms of H+-transport-driven rotation of the c oligomer during ATP synthesis.
...
PMID:Structure of the subunit c oligomer in the F1Fo ATP synthase: model derived from solution structure of the monomer and cross-linking in the native enzyme. 1039 99
To better define the regulatory role of the F(1)-ATPase alpha-subunit in the catalytic cycle of the
ATP synthase
complex, we isolated suppressors of mutations occurring in ATP1, the gene for the alpha-subunit in Saccharomyces cerevisiae. First, two atp1 mutations (atp1-1 and atp1-2) were characterized that prevent the growth of yeast on non-fermentable carbon sources. Both mutants contained full-length F(1)alpha-subunit proteins in mitochondria, but in lower amounts than that in the parental strain. Both mutants exhibited barely measurable F(1)-ATPase activity. The primary mutations in atp1-1 and atp1-2 were identified as Thr(383) --> Ile and Gly(291) -->
Asp
, respectively. From recent structural data, position 383 lies within the catalytic site. Position 291 is located near the region affecting subunit-subunit interaction with the F(1)beta-subunit. An unlinked suppressor gene, ASC1 (alpha-subunit complementing) of the atp1-2 mutation (Gly(291) -->
Asp
) restored the growth defect phenotype on glycerol, but did not suppress either atp1-1 or the deletion mutant Deltaatp1. Sequence analysis revealed that ASC1 was allelic with RAS2, a G-protein growth regulator. The introduction of ASC1/RAS2 into the atp1-2 mutant increased the F(1)-ATPase enzyme activity in this mutant when the transformant was grown on glycerol. The possible mechanisms of ASC1/RAS2 suppression of atp1-2 are discussed; we suggest that RAS2 is part of the regulatory circuit involved in the control of F(1)-ATPase subunit levels in mitochondria.
...
PMID:ASC1/RAS2 suppresses the growth defect on glycerol caused by the atp1-2 mutation in the yeast Saccharomyces cerevisiae. 1074 40
Previously, we generated genetically fused dimers and trimers of subunit c of the Escherichia coli
ATP synthase
based upon the precedent of naturally occurring dimers in V-type H(+)-transporting ATPases. The c(2) and c(3) oligomers have proven useful in testing hypothesis regarding the mechanism of energy coupling. In the first part of this paper, the uncoupling Q42E substitution has been introduced into the second loop of the c(2) dimer or the third loop of the c(3) trimer. Both mutant proteins proved to be as functional as the wild type c(2) dimer or wild type c(3) trimer. The results argue against an obligatory movement of the epsilon subunit between loops of monomeric subunit c in the c(12) oligomer during rotary catalysis. Rather, the results support the hypothesis that the c-epsilon connection remains fixed as the c-oligomer rotates. In the second section of this paper, we report on the effect of substitution of the proton translocating
Asp
(61) in every second helical hairpin of the c(2) dimer, or in every third hairpin of the c(3) trimer. Based upon the precedent of V-type ATPases, where the c(2) dimer occurs naturally with a single proton translocating carboxyl in every second hairpin, these modified versions of the E. coli c(2) and c(3) fused proteins were predicted to have a functional H(+)-transporting ATPase activity, with a reduced H(+)/ATP stoichiometry, but to be inactive as ATP synthases. A variety of
Asp
(61)-substituted proteins proved to lack either activity indicating that the switch in function in V-type ATPases is a consequence of more than a single substitution.
...
PMID:Mutations in single hairpin units of genetically fused subunit c provide support for a rotary catalytic mechanism in F(0)F(1) ATP synthase. 1075 49
Recently, a novel molecular mechanism of torque generation in the F(0) portion of
ATP synthase
was proposed [Rohatgi, Saha and Nath (1998) Curr. Sci. 75, 716-718]. In this mechanism, rotation of the c-subunit was conceived to take place in 12 discrete steps of 30 degrees each due to the binding and unbinding of protons to/from the leading and trailing
Asp
-61 residues of the c-subunit, respectively. Based on this molecular mechanism, a kinetic scheme has been developed in this work. The scheme considers proton transport driven by a concentration gradient of protons across the proton half-channels, and the rotation of the c-subunit by changes in the electrical potential only. This kinetic scheme has been analyzed mathematically and an expression has been obtained to explain the pH dependence of the rate of ATP synthesis by
ATP synthase
under steady state operating conditions. For a single set of three enzymological kinetic parameters, this expression predicts the rates of ATP synthesis which agree well with the experimental data over a wide range of pH(in) and pH(out). A logical consequence of our analysis is that DeltapH and Deltapsi are kinetically inequivalent driving forces for ATP synthesis.
...
PMID:Kinetic model of ATP synthase: pH dependence of the rate of ATP synthesis. 1091 96
Chloroplast
ATP synthase
is a thiol-modulated enzyme whose DeltamuH(+)-linked activation is strongly influenced by reduction and the formation of a disulphide bridge between Cys(199) and Cys(205) on the gamma subunit. In solubilized chloroplast coupling factor 1 (CF(1)), reduction of the disulphide bond elicits the latent ATP-hydrolysing activity. To assess the regulatory importance of the amino acid residues around these cysteine residues, we focused on the three negatively charged residues Glu(210)-
Asp
-Glu(212) close to the two cysteine residues and also on the following region from Leu(213) to Ile(230), and investigated the modulation of ATPase activity by chloroplast thioredoxins. The mutant gamma subunits were reconstituted with the alpha and beta subunits from F(1) of the thermophilic bacterium Bacillus PS3; the active ATPase complexes obtained were purified by gel-filtration chromatography. The complex formed with a mutant gamma subunit in which Glu(210) to Glu(212) had been deleted was inactivated rather than activated by reduction of the disulphide bridge by reduced thioredoxin, indicating inverse regulation. This complex was insensitive to the inhibitory CF(1)-epsilon subunit when the mutant gamma subunit was oxidized. In contrast, the deletion of Glu(212) to Ile(230) converted the complex from a modulated state into a highly active state.
...
PMID:Inverse regulation of F1-ATPase activity by a mutation at the regulatory region on the gamma subunit of chloroplast ATP synthase. 1110 86
The multicopy subunit c of the H(+)-transporting F1Fo
ATP synthase
of Escherichia coli folds across the membrane as a hairpin of two hydrophobic alpha helices. The subunits interact in a front-to-back fashion, forming an oligomeric ring with helix 1 packing in the interior and helix 2 at the periphery. A conserved carboxyl,
Asp
(61) in E. coli, centered in the second transmembrane helix is essential for H+ transport. A second carboxylic acid in the first transmembrane helix is found at a position equivalent to Ile28 in several bacteria, some the cause of serious infectious disease. This side chain has been predicted to pack proximal to the essential carboxyl in helix 2. It appears that in some of these bacteria the primary function of the enzyme is H+ pumping for cytoplasmic pH regulation. In this study, Ile28 was changed to
Asp
and Glu. Both mutants were functional. However, unlike the wild type, the mutants showed pH-dependent ATPase-coupled H+ pumping and passive H+ transport through Fo. The results indicate that the presence of a second carboxylate enables regulation of enzyme function in response to cytoplasmic pH and that the ion binding pocket is aqueous accessible. The presence of a single carboxyl at position 28, in mutants I28D/D61G and I28E/D61G, did not support growth on a succinate carbon source. However, I28E/D61G was functional in ATPase-coupled H+ transport. This result indicates that the side chain at position 28 is part of the ion binding pocket.
...
PMID:Introduction of a carboxyl group in the first transmembrane helix of Escherichia coli F1Fo ATPase subunit c and cytoplasmic pH regulation. 1116 82
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.
...
PMID:Structure of spinach chloroplast F1-ATPase complexed with the phytopathogenic inhibitor tentoxin. 1190 10
Mitochondrial ATP synthases, the major producers of ATP in higher eukaryotic cells, are known to be regulated by a peptide designated IF(1). In contrast, in yeast three such peptides have been identified, IF(1) and STF(1), which inhibit the reverse ATPase reaction, and STF(2), a modulator of the action of these inhibitors. Despite significant homology to IF(1), STF(1) exhibits less than half ( approximately 40%) its inhibitory potency. The two-fold purpose of this bioinformatic study was to gain structural insight into the different inhibitory potencies of IF(1) and STF(1) and to determine to what extent yeast are unique in employing multiple peptides to regulate the
ATP synthase
. Sequence and secondary structural analyses and comparison with the known structure of bovine IF(1) predicted a dimeric structure for yeast STF(1) in which the C-terminal regions form a coiled-coil. Moreover, sequence comparisons showed that within this C-terminal region a conserved acidic residue (
Asp
59) in yeast IF(1) is replaced by Asn in STF(1). In the known structure of bovine IF(1), predicted to be very similar to that of yeast IF(1), the residue Glu 68 corresponding to
Asp
59 participates in the formation of a four-residue conserved acidic cluster in the middle of the coiled-coil in the C-terminal region. It is deduced here that this acidic cluster is likely to be important in the regulation of IF(1)'s inhibitory capacity and that replacement of conserved
Asp
59 by Asn in STF(1) may reduce its potency. Although other homologs to the inhibitors IF(1) and STF(1) were not found in searches of available eukaryotic genomes, including human, a new homolog, named STF(3), with 65% identity to the modulator STF(2), was discovered within the yeast genome and identified to be expressed by searching the yeast EST database. Thus, yeast appears unique in regulating the
ATP synthase
by involving multiple peptides (IF(1), STF(1), STF(2), and perhaps STF(3)).
...
PMID:ATP synthase of yeast: structural insight into the different inhibitory potencies of two regulatory peptides and identification of a new potential regulator. 1217 55
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