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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 gene encoding the epsilon subunit (atpE) of the chloroplast
ATP synthase
of Spinacia oleracea has been overexpressed in Escherichia coli. The recombinant protein can be solubilized in 8 M urea and directly diluted into buffer containing ethanol and glycerol to obtain epsilon that is as biologically active as epsilon purified from chloroplast-coupling factor 1 (CF1). Recombinant epsilon folded in this manner inhibits the ATPase activity of soluble and membrane-bound CF1 deficient in epsilon and restores proton impermeability to thylakoid membranes reconstituted with CF1 deficient in epsilon. Site-directed mutagenesis was used to generate truncations and single amino acid substitutions in the primary structure of epsilon. In the five mutants tested, alterations that weaken ATPase inhibition by recombinant epsilon affect its ability to restore proton impermeability to a similar extent, with one exception. Substitution of
histidine
-37 with arginine appears to uncouple ATPase inhibition and the restoration of proton impermeability. As in the case of E. coli, it appears that N-terminal truncations of the epsilon subunit have more profound effects than C-terminal deletions on the function of epsilon. Recombinant epsilon with six amino acids deleted from the C terminus, which is the only region of significant mismatch between the epsilon of spinach and the epsilon of Pisum sativum, inhibits ATPase activity with a reduced potency similar to that of purified pea epsilon. Four of the six amino acids are serine or threonine. These hydroxylated amino acids may be important in epsilon-CF1 interactions.
...
PMID:Molecular dissection of the epsilon subunit of the chloroplast ATP synthase of spinach. 853 97
In the absence of an electrochemical proton gradient, the F1 moiety of the mitochondrial
ATP synthase
catalyzes the hydrolysis of ATP. This reaction is inhibited by a natural protein inhibitor, in a process characterized by an increase in ATPase inhibition as pH is decreased from 8.0 to 6.0. In order to gain greater insight into the molecular and chemical events underlying this regulatory process, the relationships among pH, helicity of the inhibitor protein, and its capacity to inhibit
F1-ATPase
activity were examined. First, peptides corresponding to four regions of the 82-amino-acid inhibitor protein were chemically synthesized and assessed for both retention of secondary structure, and capacity to inhibit
F1-ATPase
activity. These studies showed that a region of only 24-amino-acid residues, from Phe 22 through Len 45, accounts for the inhibitory capacity of the inhibitor protein, and that retention of native helical structure in this region is not essential for inhibition. Second, three mutants (33P34, 39P40, and 43P44) of the intact inhibitor protein were prepared in which a proline residue was inserted within the inhibitory region to disrupt native helical structure. The secondary structures and inhibitory capacities of these mutants were analyzed as a function of pH. These studies revealed that, despite the initial loss of helical structure within the inhibitory region due to proline insertion, a further loss of helical structure is required to modulate inhibitory activity. These results suggest that a loss of helical structure outside the inhibitory region correlates with an increase in inhibitory capacity. Finally, two separate mutants (H48A and H55A) were prepared in which a conserved
histidine
residue in the wild-type inhibitor protein was replaced with an alanine. The secondary structures and inhibitory capacities of these mutants were also investigated as a function of pH. Results indicated that, although
histidine
residues do not directly affect the inhibitory capacity of the protein, they are important for maintaining the inhibitor protein in an inactive form at high pH. Furthermore, these results show that loss in helical structure, although correlated with an increase in inhibitory capacity, is not essential for this function. These novel experiments are consistent with a model in which the inhibitor protein is envisioned as consisting of two regions, an inhibitory region and a regulatory region. It is suggested that reduction of pH allows for the protonation of a
histidine
residue blocking the interaction between the two regions, thus activating the inhibitory response. The pH reduction also correlates with a partial unfolding of the protein that may either cause or result from the loss of interaction between the two helices. This unfolding may be necessary for further optimization of inhibitor function.
...
PMID:Protein inhibitor of mitochondrial ATP synthase: relationship of inhibitor structure to pH-dependent regulation. 866 Jun 64
Peptide segments of the inhibitor protein (IF1) of the F0F1
ATP synthase
complex from bovine-heart mitochondria have been constructed by chemical synthesis. The IF1-(42-58)-peptide was equally effective as IF1 in inhibiting the ATPase activity of both the F0F1 complex in the mitochondrial membrane deprived of IF1 (SMP) and soluble F1. The IF1-(22-46)-peptide inhibited the ATPase activity in the soluble F1 but had no effect on either the ATPase activity or H+ conduction in SMP. Substitution of the
His
or Lys residues with Ala in the IF1-(42-58)-peptide decreased the inhibition of ATP hydrolysis. The inhibition exerted by the IF1-(42-58)-peptide on ATP hydrolysis in SMP exhibited a pH dependence, similar to that observed with IF1, which was lost upon replacement of
His
or Lys with Ala. In soluble F1, inhibition of ATP hydrolysis by IF1, the IF1-(42-58)-peptide and the IF1-(22-46)-peptide was pH dependent when F1 was first incubated with ATP. The IF1-(42-58)-peptide also caused inhibition of passive H+ conduction in SMP. This activity of the synthetic peptide was weaker, as compared to that of IF1, and practically unaffected by substitution of
His
or Lys with Ala. An antibody against the IF1-(42-58)-synthetic peptide stimulated ATP hydrolysis in the membrane-bound F0F1 complex with associated IF1 but was without effect on H+ conduction. An antibody against IF1 stimulated both processes.
...
PMID:Identification of functional domains and critical residues in the adenosinetriphosphatase inhibitor protein of mitochondrial F0F1 ATP synthase. 884 13
An engineered gamma subunit of Escherichia coli
F1-ATPase
with extra 14 and 20 amino acid residues at the N- and C-termini (
His
-tag gamma), respectively, was overproduced in E. coli and purified. Six histidines are included in the C-terminal extension. The reconstituted F1 containing alpha, beta, and
His
-tagged gamma exhibited sixty percent of the wild-type ATPase activity. The reconstituted alphabeta
His
-tag gamma complex was subjected to affinity chromatography with nickel-nitrilotriacetic acid (Ni-NTA) agarose resin. ATPase activity was eluted specifically with imidazole. These results implied that the tag sequence protruded to the surface of the complex and did not seriously impair the activity. The reconstituted alphabeta
His
-tag gamma complex, even after its binding to the resin, exhibited ATPase activity suggesting that the gamma subunit, when fixed to a solid phase, may rotate the alphabeta complex. This system may provide a new approach for analysis of the rotation mechanisms in
F1-ATPase
.
...
PMID:Reconstitution of F1-ATPase activity from Escherichia coli subunits alpha, beta and subunit gamma tagged with six histidine residues at the C-terminus. 961 1
Subunit a of the E. coli F1F0
ATP synthase
was probed by insertion scanning mutagenesis in a region between residues Glu219 and His245. A series of single amino acid insertions, of both alanine and aspartic acid, were constructed after the following residues: 225, 229, 233, 238, 243, and 245. The mutants were tested for growth yield, binding of F1 to membranes, dicyclohexylcarbodiimide sensitivity of ATPase activity, ATP-driven proton translocation, and passive proton permeability of membranes stripped of F1. Significant loss of function was seen only with insertions after positions 238 and 243. In contrast, both insertions after residue 225 and the alanine insertion after residue 245 were nearly identical in function to the wild type. The other insertions showed an intermediate loss of function. Missense mutations of His245 to serine and cysteine were nonfunctional, while the W241C mutant showed nearly normal ATPase function. Replacement of Leu162 by
histidine
failed to suppress the 245 mutants, but chemical rescue of H245S was partially successful using acetate. An interaction between Trp241 and His245 may be involved in gating a "half-channel" from the periplasmic surface of F0 to Asp61 of subunit a.
...
PMID:Insertion scanning mutagenesis of subunit a of the F1F0 ATP synthase near His245 and implications on gating of the proton channel. 963 81
Approximately 37 amino acids at the amino-terminus of subunit a of the Escherichia coli
ATP synthase
are found localized to the periplasm. Results indicate that a single amino acid substitution, H15D, disrupts assembly of subunit a and causes a loss of
ATP synthase
function. In this study, a conserved region of nine amino acids, 11-19, was initially mutagenized randomly, generating no mutants that could grow on succinate-minimal medium. Subsequent mutagenesis, confined to residues
His
(14),
His
(15), and Asn(17), indicated that constructs containing H15D were the most deleterious. Four single mutants were constructed and analyzed: H15A, H14D, H15A, and H15D. Only H15D was significantly impaired, with respect to ATP-driven proton translocation, passive proton permeability through F(o), and sensitivity of membrane-bound ATPase to DCCD. Immunoblot analysis indicated very low levels of subunit a from H15D. Cysteine mutations were constructed at positions 14, 15, 17, and 18. Residues 14, 15, and 17 were shown to be accessible in the periplasmic space, while residue 18 was not, indicating that this region was stably folded. While both
His
(14) and
His
(15) are conserved among a group of bacteria, results presented here indicate that they are not equivalent, and that a specific role for
His
(15) in the assembly or structure of the
ATP synthase
is supported.
...
PMID:His(15) of subunit a of the Escherichia coli ATP synthase is important for the structure or assembly of the membrane sector F(o). 1041 27
A considerable interest exists currently in designing innovative strategies to produce two-dimensional crystals of membrane proteins that are amenable to structural analysis by electron crystallography. We have developed a protocol for crystallizing membrane protein that is derived from the classical lipid-layer two-dimensional crystallization at the air/water interface used so far for soluble proteins. Lipid derivatized with a Ni(2+)-chelating head group provided a general approach to crystallizing
histidine
-tagged transmembrane proteins. The processes of protein binding and two-dimensional crystallization were analyzed by electron microscopy, using two prototypic membrane proteins: FhuA, a high-affinity receptor from the outer membrane of Escherichia coli, and the F(0)F(1)-
ATP synthase
from thermophilic Bacillus PS3. Conditions were found to avoid solubilization of the lipid layer by the detergent present with the purified membrane proteins and thus to allow binding of micellar proteins to the functionalized lipid head groups. After detergent removal using polystyrene beads, membrane sheets of several hundreds of square micrometers were reconstituted at the interface. High protein density in these membrane sheets allowed further formation of planar two-dimensional crystals. We believe that this strategy represents a new promising alternative to conventional dialysis methods for membrane protein 2D crystallization, with the additional advantage of necessitating little purified protein.
...
PMID:Two-dimensional crystallization on lipid layer: A successful approach for membrane proteins. 1047 16
The membrane-bound
ATP synthase
(F(1)F(o)) from mitochondria, chloroplasts and bacteria plays a crucial role in energy-transducing reactions. In the case of Escherichia coli, the reversible, proton-translocating ATPase complex consists of two different entities, F(1) and F(o). The water-soluble F(1) part carries the catalytic sites for ATP synthesis and hydrolysis. It is associated with the membrane-embedded F(o) complex, which functions as a proton channel and consists of subunits a, b and c present in a stoichiometry of 1:2:12. Subunit b was isolated by preparative gel electrophoresis, acetone-precipitated and renatured in a cholate-containing buffer. Reconstituted subunit b together with purified ac subcomplex is active in proton translocation and F(1) binding, thereby demonstrating that subunit b had recovered its native conformation. Circular dichroism spectroscopy of subunit b reconstituted into liposomes revealed a rather high degree of alpha -helical conformation of 80%. After addition of a
His
(6)-tag to the N terminus of subunit a, a stable ab(2) subcomplex was purified instead of a single subunit a, arguing in favour of a direct interaction between these subunits. After addition of subunit c and reconstitution into phospholipid vesicles, an F(o) complex was obtained exhibiting rates of proton translocation and F(1) binding comparable with those of wild-type F(o). The epitopes of monoclonal antibodies against subunit c are located in the hydrophilic loop region (cL31-Q42) as mapped by enzyme-linked immunosorbent assay using overlapping synthetic heptapeptides. Binding studies revealed that all monoclonal antibodies (mAbs) bind to everted membrane vesicles irrespective of the presence or absence of F(1). Although the hydrophilic region of subunit c, and especially the highly conserved residues cA40, cR41, cQ42 and cP43, are known to interact with subunits gamma and epsilon of the F(1) part, the mAb molecules have no effect on the function of F(o), either in proton translocation or in F(1) binding. However, the F(1) part and the mAb molecule(s) are bound simultaneously to the F(o) complex, suggesting that not all c subunits are involved in the interaction with F(1).
...
PMID:Structure and function of the F(o) complex of the ATP synthase from Escherichia coli. 1060 Jun 69
The electron paramagnetic resonance (EPR), electron spin echo envelope modulation (ESEEM) and hyperfine sublevel correlation (HYSCORE) spectra of Mg2+-depleted chloroplast
F1-ATPase
substituted with stoichiometric VO2+ are reported. The ESEEM and HYSCORE spectra of the complex are dominated by the hyperfine and quadrupole interactions between the VO2+ paramagnet and two different nitrogen ligands with isotropic hyperfine couplings /A1/ = 4.11 MHz and /A2/ = 6.46 MHz and nuclear quadrupole couplings e2qQ1 approximately 3.89-4.49 MHz and e2qQ2 approximately 1.91-2.20 MHz, respectively. Aminoacid functional groups compatible with these magnetic couplings include a
histidine
imidazole, the epsilon-NH2 of a lysine residue, and the guanidinium group of an arginine. Consistent with this interpretation, very characteristic correlations are detected in the HYSCORE spectra between the 14N deltaM1 = 2 transitions in the negative quadrant, and also between some of the deltaM1 = 1 transitions in the positive quadrant. The interaction of the substrate and product ADP and ATP nucleotides with the enzyme has been studied in protein complexes where Mg2+ is substituted for Mn2+. Stoichiometric complexes of Mn x ADP and Mn x ATP with the whole enzyme show distinct and specific hyperfine couplings with the 31P atoms of the bonding phosphates in the HYSCORE (ADP, A(31Pbeta) = 5.20 MHz: ATP, A(31Pbeta) = 4.60 MHz and A(31Pgamma) = 5.90 MHz) demonstrating the role of the enzyme active site in positioning the di- or triphosphate chain of the nucleotide for efficient catalysis. When the complexes are formed with the isolated alpha or beta subunits of the enzyme, the HYSCORE spectra are substantially modified, suggesting that in these cases the nucleotide binding site is only partially structured.
...
PMID:The role of the Mg2+ cation in ATPsynthase studied by electron paramagnetic resonance using VO2+ and Mn2+ paramagnetic probes. 1072 46
The rotary motion in response to ATP hydrolysis of the ring of c subunits of the membrane portion, F(o), of
ATP synthase
, F(o)F(1), is still under contention. It was studied with EF(o)EF(1) (Escherichia coli) using microvideography with a fluorescent actin filament. To overcome the limited specificity of actin attachment through a Cys-maleimide couple which might have hampered the interpretation of previous work, we engineered a 'strep-tag' sequence into the C-terminal end of subunit c. It served (a) to purify the holoenzyme and (b) to monospecifically attach a fluorescent actin filament to subunit c. EF(o)EF(1) was immobilized on a Ni-NTA-coated glass slide by the engineered
His
-tag at the N-terminus of subunit beta. In the presence of MgATP we observed up to five counterclockwise rotating actin filaments per picture frame of 2000 microm(2) size, in some cases yielding a proportion of 5% rotating over total filaments. The rotation was unequivocally attributable to the ring of subunit c. The new, doubly engineered construct serves as a firmer basis for ongoing studies on torque and angular elastic distortions between F(1) and F(o).
...
PMID:F-ATPase: specific observation of the rotating c subunit oligomer of EF(o)EF(1). 1078
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