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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)
Oligonucleotide-directed mutagenesis was used to substitute Asn or Val for residue
Asp
-242 in the beta-subunit of Escherichia coli
F1-ATPase
.
Asp
-242 is strongly conserved in beta-subunits of
F1-ATPase
enzymes, in a region of sequence which shows homology with numerous nucleotide-binding proteins. By analogy with adenylate kinase (Fry, D.C., Kuby, S.A., and Mildvan, A.S. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 907-911), beta-
Asp
-242 of
F1-ATPase
might participate in catalysis through electrostatic effects on the substrate Mg2+ or through hydrogen bonding to the substrate(s); an acid-base catalytic role is also plausible. The substitutions Asn and Val were chosen to affect the charge, hydrogen-bonding ability, and hydrophobicity of residue beta-
Asp
-242. Both mutations significantly impaired oxidative phosphorylation rates in vivo and membrane ATPase and ATP-driven proton-pumping activities in vitro. Asn-242 was more detrimental than Val-242. Purified soluble mutant F1-ATPases had normal molecular size and subunit composition, and displayed 7% (beta-Asn-242) and 17% (beta-Val-242) of normal specific Mg-ATPase activity. The relative MgATPase activities of both mutant enzymes showed similar pH dependence to normal. Relative MgATPase and CaATPase activities of normal and mutant enzymes were compared at widely varied pMg and pCa. The mutations had little effect on KM MgATP, but KM CaATP was reduced. The data showed that the carboxyl side-chain of beta-
Asp
-242 is not involved in catalysis either as a general acid-base catalyst or through direct involvement in any protonation/deprotonation-linked mechanism, nor is it likely to be directly involved in liganding to substrate Mg2+ during the reaction. Specificity constants (kcat/KM) for MgATP and CaATP were reduced in both mutant enzymes, showing that the mutations destabilized interactions between the catalytic nucleotide-binding domain and the transition state.
...
PMID:Directed mutagenesis of the strongly conserved aspartate 242 in the beta-subunit of Escherichia coli proton-ATPase. 290 40
A complete analysis is presented of the component rate constants of the "unisite" reaction pathway in normal Escherichia coli
F1-ATPase
. Gibbs free energy profiles of the unisite reaction pathway were constructed for both normal E. coli F1 and bovine-heart mitochondrial F1, and comparison indicated that E. coli F1 is an ancestral form of the mitochondrial enzyme. Similar kinetic and thermodynamic analyses of the unisite reaction pathway were done for mutant beta-Asn-242 and beta-Val-242 E. coli F1-ATPases. Both mutations affected unisite binding and hydrolysis of MgATP but had little effect on release of products or binding of MgADP. It was apparent that a primary effect of the mutations was on the interaction between the catalytic nucleotide-binding domain and the substrate MgATP. The catalytic transition state [F1-ATP]++ was the most destabilized step in the reaction sequence. Measurements of delta delta G[F1.ATP]++ and linear free energy plots for the catalytic step were consistent with the view that, in normal enzyme, residue beta-
Asp
-242 accepts an H-bond from the transition-state substrate in order to facilitate catalysis. Both mutations impaired positive catalytic cooperativity. This was caused by energetic destabilization of the catalytic transition state and was an indirect effect, not a direct effect on signal transmission per se between catalytic nucleotide-binding domains on beta-subunits. Therefore, impairment of unisite catalysis and of positive catalytic cooperativity appeared to be linked. This may provide a unifying explanation as to why a series of other, widely separated mis-sense mutations within the catalytic nucleotide-binding domain on F1-beta-subunit, which have been reported to affect unisite catalysis, also impair positive catalytic cooperativity. Linear free energy plots for the ATP-binding step of unisite catalysis demonstrated that beta-Asn-242 and beta-Val-242 mutant enzymes did not suffer any gross disruptive change in structure of the catalytic nucleotide-binding domain, reinforcing the view that impairment of catalysis was due to a localized effect. Such analyses confirmed that six other F1-beta-subunit mutants, previously generated and characterized in this laboratory and thought to have inhibitory side-chain substitutions in the catalytic nucleotide-binding domain, are also devoid of gross structural disruption.
...
PMID:Complete kinetic and thermodynamic characterization of the unisite catalytic pathway of Escherichia coli F1-ATPase. Comparison with mitochondrial F1-ATPase and application to the study of mutant enzymes. 290 41
When the bovine mitochondrial
F1-ATPase
is inactivated with dicyclohexyl[14C]carbodiimide and then gel-filtered, from 2 to 3 g atoms of 14C are incorporated/mol of enzyme. Prior inactivation of the enzyme by the modification of an essential tyrosine residue with 4-chloro-7-nitrobenzofurazan, a reaction that can be reversed by thiols, does not affect the irreversible inactivation of the ATPase by dicyclohexyl[14C]carbodiimide. During the large scale modification of the
F1-ATPase
by dicyclohexyl[14C]carbodiimide which led to 70% inactivation, 1.9 g atoms of 14C were incorporated/mol of enzyme. Isolation of the alpha, beta, and gamma subunits from this large scale inactivation revealed that the gram atoms of 14C bound per mol of each of the subunits was: alpha, 0.04; beta, 0.56; and gamma, 0.04. The majority of the radioactivity in a cyanogen bromide digest of the 14C-labeled beta subunit was isolated in a fragment that has the following amino acid sequence: Glu-Leu-Ile-Asn-Asn-Val-Ala-Lys-Ala-His-Gly-Gly-Tyr-Ser-Val-Phe-Ala-Gly-Val-Gly -Glu-Arg-Thr-Arg-Glu-Gly-Asn-
Asp
-Leu-Tyr-Glu*-His-Met; where Glu* represents the N gamma-glutamyl derivative of dicyclohexyl[14C]urea.
...
PMID:Inactivation of the bovine mitochondrial F1-ATPase with dicyclohexyl[14C]carbodiimide leads to the modification of a specific glutamic acid residue in the beta subunit. 611 57
The amino acid sequence of the proteolipid subunit of the
ATP synthase
was analyzed in six mutant strains from Escherichia coli K12, selected for their increased resistance towards the inhibitor N,N'-dicyclohexylcarbodiimide. All six inhibitor-resistant mutants were found to be altered at the same position of the proteolipid, namely at the isoleucine at residue 28. Two substitutions could be identified. In type I this residue was substituted by a valine resulting in a moderate decrease in sensitivity to dicyclohexylcarbodiimide. Type II contained a threonine residue at this position. Here a strong resistance was observed. These two amino acid substitutions did not influence functional properties of the ATPase complex. ATPase as well as ATP-dependent proton-translocating activities of mutant membranes were indistinguishable from the wild type. At elevated concentrations, dicyclohexylcarbodiimide still bound specifically to the
aspartic acid
at residue 61 of the mutant proteolipid as in the wild type, and thereby inhibited the activity of the ATPase complex. It is suggested that the residue 28 substituted in the resistant mutants interacts with dicyclohexylcarbodiimide during the reactions leading to the covalent attachment of the inhibitor to the
aspartic acid
at residue 61. This could indicate that these two residues are in close vicinity and would thus provide a first hint on the functional conformation of the proteolipid. Its polypeptide chain would have to fold back to bring together these two residues separated by a segment of 32 residues.
...
PMID:Identification of amino-acid substitutions in the proteolipid subunit of the ATP synthase from dicyclohexylcarbodiimide-resistant mutants of Escherichia coli. 625 67
The mechanisms of energy coupling and catalytic co-operativity are not yet understood for H(+)-ATPase (
ATP synthase
). An Escherichia coli gamma subunit frameshift mutant (downstream of Thr-gamma 277) could not grow by oxidative phosphorylation because both mechanisms were defective (Iwamoto, A., Miki, J., Maeda, M., and Futai, M. (1990) J. Biol. Chem. 265, 5043-5048). The defect(s) of the gamma frameshift was obvious, because the mutant subunit had a carboxyl terminus comprising 16 residues different from those in the wild type. However, in this study, we surprisingly found that an Arg-beta 52-->Cys or Gly-beta 150-->
Asp
replacement could suppress the deleterious effects of the gamma frameshift. The membranes of the two mutants (gamma frameshift/Cys-beta 52 with or without a third mutation, Val-beta 77-->Ala) exhibited increased oxidative phosphorylation, together with 70-100% of the wild type ATPase activity. Similarly, the gamma frameshift/
Asp
-beta 150 mutant could grow by oxidative phosphorylation, although this mutant had low membrane ATPase activity. These results suggest that the beta subunit mutation suppressed the defects of catalytic cooperativity and/or energy coupling in the gamma mutant, consistent with the notion that conformational transmission between the two subunits is pertinent for this enzyme.
...
PMID:Beta-gamma subunit interaction is required for catalysis by H(+)-ATPase (ATP synthase). Beta subunit amino acid replacements suppress a gamma subunit mutation having a long unrelated carboxyl terminus. 755 18
Glu-beta 185 of the Escherichia coli H(+)-ATPase (
ATP synthase
) beta subunit was replaced by 19 different amino acid residues. The rates of multisite (steady state) catalysis of all the mutant membrane ATPases except
Asp
- beta 185 were less than 0.2% of the wild type one; the
Asp
- beta 185 enzyme exhibited 15% (purified) and 16% (membrane-bound) ATPase activity. The purified inactive Cys- beta 185
F1-ATPase
recovered substantial activity after treatment with iodoacetate in the presence of MgCl2; maximal activity was obtained upon the introduction of about 3 mol of carboxymethyl residues/mol of F1. The divalent cation dependences of the S-carboxymethyl- beta 185 and
Asp
- beta 185 ATPase activities were altered from that of the wild type. The
Asp
- beta 185, Cys- beta 185, S-carboxymethyl-beta 185, and Gln- beta 185 enzymes showed about 130, 60, 20, and 50% of the wild type unisite catalysis rates, respectively. The S-carboxymethyl- beta 185 and
Asp
- beta 185 enzymes showed altered divalent cation sensitivities, and the S-carboxymethyl- beta 185 enzyme showed no Mg2+ inhibition. Unlike the wild type, the two mutant enzymes showed low sensitivities to azide, which stabilizes the enzyme Mg-ADP complex. These results suggest that Glu- beta 185 may form a Mg2+ binding site, and its carboxyl moiety is essential for catalytic cooperativity. Consistent with this model, the bovine glutamate residue corresponding to Glu- beta 185 is located close to the catalytic site in the higher order structure (Abrahams, J.P., Leslie, A.G.W., Lutter, R ., and Walker, J.E. (1994) Nature 370, 621-628)
...
PMID:Beta subunit Glu-185 of Escherichia coli H(+)-ATPase (ATP synthase) is an essential residue for cooperative catalysis. 759 42
Deletion mutations in the NH2- and COOH-terminal regions of the epsilon subunit of Escherichia coli
ATP synthase
were constructed making use of the AatII and HincII restriction enzyme sites. The resultant mutated epsilon species were analyzed for in vivo functionality and for recognition by anti-epsilon monoclonal antibodies. Deletion of residues
Asp
-7 through Gln-14 (epsilon delta D7-Q14) resulted in reduced ability to complement uncC mutants as determined by growth yields on limiting glucose medium and by formation of small colonies on plates with succinate as the source of carbon and energy. None of the other mutants was notably impaired. Upon induction to obtain overexpression, the NH2-terminal deletion mutants were expressed at levels comparable to the wild-type epsilon subunit, but the COOH-terminal deletion mutants were expressed less strongly, suggesting that residues in the latter region are important for protein stability. Monoclonal antibody epsilon-1, which cannot bind to epsilon when it is part of
F1-ATPase
, recognized the COOH-terminal deletions well, but the NH2-terminal deletions poorly. Additional epitope mapping using epsilon fusion proteins revealed that residues required for the epsilon-1 epitope extend to between Thr-77 and Arg-85. Monoclonal antibody epsilon-4, which can bind to epsilon when it is part of
F1-ATPase
, recognized the NH2-terminal deletions well, but hardly recognized the COOH-terminal deletions, indicating a role of residues located COOH-terminal to Ile-131 in recognition by this antibody. Epitope mapping using the fusion proteins revealed that the residues required by epsilon-4 begin in the region between Val-78 and Met-95. These results imply a two-domain structure of epsilon and orient the subunit within the enzyme.
...
PMID:Orientation of the epsilon subunit in Escherichia coli ATP synthase. 768 93
The F0 complex of the Escherichia coli
ATP synthase
embedded into cardiolipin liposomes was studied by FT-IR spectroscopy. For comparison, respective studies were performed with dried F0 liposomes and with F0 liposomes treated with N,N'-dicyclohexyl-carbodiimide (DCCD), which binds to
Asp
-61 of subunit c. Furthermore, the effect of H2O-->D2O exchange on the infrared spectrum was investigated. With F0 liposomes an infrared continuum is observed beginning at about 3000 cm-1 and extending toward smaller wavenumbers. In the DCCD-treated sample, this continuum is no longer observed. It vanishes also with drying of the liposomes. After H2O-->D2O exchange, this infrared continuum begins at about 2350 cm-1 and is less intense. All of these results demonstrate that a proton pathway in native F0 is present, in which the protons are shifted in a hydrogen-bonded chain with large proton polarizability due to collective proton tunneling. With the D2O-hydrated system, deuteron polarizability due to collective deuteron motion is observed, but the polarizability due to collective deuteron motion is smaller. Such pathways are very efficient, because they conduct protons or deuterons within picoseconds. These pathways lose their polarizability if the F0 complex is blocked by DCCD or if the liposomes are dried. On the basis of our results on the proton polarizability of hydrogen bonds and hydrogen-bonded systems and on the basis of structural data from the literature, the nature of the proton pathway of the F0 complex of E. coli is discussed.
...
PMID:The F0 complex of the ATP synthase of Escherichia coli contains a proton pathway with large proton polarizability caused by collective proton fluctuation. 771 Dec 31
Most F1F0 type ATP synthases, including that in Escherichia coli, use H+ as the coupling ion for ATP synthesis. However, the structurally related F1F0
ATP synthase
in Propionigenium modestum uses Na+ instead. The binding site for Na+ residues in the F0 sector of the P. modestum enzyme. We postulated that Na+ might interact with subunit c of F0. Subunit c of P. modestum and E. coli are reasonably homologous (19% identity) but show striking variations around the H(+)-translocating, dicyclohexylcarbodiimide-reactive carboxyl (Asp61 in E. coli). Several hydrophobic residues around Asp61 were replaced with polar residues according to the P. modestum sequence in the hope that the polar replacements might provide liganding groups for Na+. One mutant from 31 different mutation combinations did generate an active enzyme that binds Li+, the combination being V60A, D61E, A62S, and I63T. Li+ binding was detected by Li+ inhibition of ATP-driven H+ transport, Li+ inhibition of F1F0-ATPase activity, and Li+ inhibition of F0-mediated H+ transport. The Li+ effects were observed with membrane vesicles prepared from a delta nhaA, delta nhaB mutant background which lacks Na+/H+ antiporters, and with purified, reconstituted preparations of F0 prepared from this background strain. Li+ inhibition was observed at pH 8.5 but not at pH 7.0. H+ thus appears to compete with Li+ for the binding site. Li+ binding was abolished by replacement of Glu61 by
Asp
or Ser62 by Ala. The side chains at Ala60 and Thr63 may act in a supporting structural role by providing a more flexible conformation for the Li+ binding cavity. Thr63 does not appear to provide a liganding group since H+ transport in two other mutants, with Gly or Ala in place of Thr63, was also inhibited by Li+. We suggest that a X-Glu-Ser-Y or X-Glu-Thr-Y sequence may provide a general structural motif for monovalent cation binding, and that the flexibility provided by residues X and Y will prove crucial to this structure.
...
PMID:Changing the ion binding specificity of the Escherichia coli H(+)-transporting ATP synthase by directed mutagenesis of subunit c. 781 24
Purified subunit c from the H(+)-transporting F1F0
ATP synthase
of Escherichia coli folds as an antiparallel pair of extended helices in a solution of chloroform-methanol-water. A similar hairpin-like folding is predicted for the native protein in the multisubunit transmembrane Fo sector of the
ATP synthase
. A single Cys variant (A67C) of subunit c was created and modified with a maleimido-PROXYL [[3-(maleimidomethyl)-2,2,5,5-tetramethyl-1-pyrrolidinyl]oxy] spin label. Pairs of 1H 2D correlation and NOE spectra were collected with the nitroxide oxidized (paramagnetic) and reduced (diamagnetic). The pairs of spectra were subtracted, yielding difference spectra containing only cross-peaks from 1H within 15 A of the spin label. These greatly simplified spectra were easily analyzed to provide complete assignments for residues 10-25 and 52-79 of the protein, 150 NOE distance restraints, and 27 hydrogen-bonding restraints. The chemical shifts and NOE patterns observed in the derivatized mutant were virtually identical to those which were resolved in the unmodified wild-type protein, strongly suggesting that the spin label was not perturbing the protein structure. The restaints enabled us to calculate a detailed structure for this region of subunit c. The structure consisted of two gently curved helices, crossing at a slight (30 degrees) angle. The C-terminal helix was disrupted from Val60 to Ala62 near the essential Pro64. Asp61, the residue thought to undergo protonation--deprotonation with each H+ transported across the membrane, was in ver der Waals contact with Ala24. The proximity of these residues had been predicted from mutant analyses, where H+ translocation was retained on moving the
Asp
from position 61 to 24.
...
PMID:Determination of local protein structure by spin label difference 2D NMR: the region neighboring Asp61 of subunit c of the F1F0 ATP synthase. 784 23
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