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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 question of the possible identity of catalytic and regulatory proton pathways in the chloroplast FoF1 ATPase has been studied using different energy-transfer inhibitors. Venturicidin, a reversible inhibitor of Fo, affects neither the delta mu H(+)-dependent thiol reduction of the membrane-bound
chloroplast ATPase
nor its ability to be activated by the proton gradient. It seems therefore to block only the proton flow required by the catalytic function of the enzymes. Venturicidin, however, also slows down the deactivation of the thiol-reduced ATPases during uncoupled ATP hydrolysis, following a delta mu H+ activation, but phloridzin, a reversible F1 inhibitor, has the same effect.
Tentoxin
, an irreversible F1 inhibitor, decreases the rate of ATP hydrolysis but does not affect the rate of deactivation. These findings suggest that catalytic and regulatory H(+)-binding sites are different. No distinction can be made, if any, between protons involved in unmasking the thiol-sensitive groups of F1 and in activating the enzyme. The effect of venturicidin and phloridzin on the deactivation is consistent with an inhibitory effect of newly formed--by ATP hydrolysis--ADP molecules, which might affect the enzyme without passing through the medium. Phosphate at millimolar concentration has an effect similar to low concentrations of phloridzin and venturicidin, probably by a simple back-reaction effect.
...
PMID:An attempt to discriminate catalytic and regulatory proton binding sites in membrane-bound, thiol-reduced chloroplast ATPase. 131 60
The interaction between rat and human liver cytochrome P-450 with tentoxin, a natural phytotoxic cyclotetrapeptide having chlorotic properties, was studied by difference ultraviolet visible spectroscopy.
Tentoxin
interacted with rat liver microsomes and the difference spectrum was characteristic of binding to a protein site close to the heme. The intensity of this spectrum was clearly dependent on the amounts of P-450 3A in the microsomes and was optimal in dexamethasone-treated rat microsomes.
Tentoxin
exhibited a high affinity for P-450 3A (Ks approximately 10 microM). Similar results were observed with human P-450 isozymes expressed in yeast. Only P-450 3A4 and 3A5 were able to give spectral interactions with tentoxin. Liver microsomes from rats pretreated with dexamethasone, a specific inducer of P-450 3A, were found to be particularly active for the oxidation of tentoxin, which occurs mainly on its Ala(Me) function leading to demethylation. Yeast-expressed P-450 3A also exhibited high activity to metabolize tentoxin. The metabolites were identified by their ultraviolet and mass spectra in fast atom bombardment and collision-activated dissociation modes. In addition to the major N-demethylated metabolite, other hydroxylated metabolites were formed. Preliminary analysis showed that as tentoxin, some metabolites were still efficient
chloroplast ATPase
inhibitors, while at least one of them exhibited even at low concentration stimulatory effects.
...
PMID:Metabolism of tentoxin by hepatic cytochrome P-450 3A isozymes. 943 3
The mechanism of action of tentoxin on the soluble part (chloroplast F1 H+-ATPase; CF1) of chloroplast
ATP synthase
was analyzed in the light of new kinetic and equilibrium experiments. Investigations were done regarding the functional state of the enzyme (activation, bound nucleotide, catalytic turnover). Dialysis and binding data, obtained with 14C-tentoxin, fully confirmed the existence of two tentoxin binding sites of distinct dissociation constants consistent with the observed Kinhibition and Koveractivation. This strongly supports a two-site model of tentoxin action on CF1. Kinetic and thermodynamic parameters of tentoxin binding to the first site (Ki = 10 nM; kon = 4.7 x 10(4) s-1.M-1) were determined from time-resolved activity assays.
Tentoxin
binding to the high affinity site was found independent on the catalytic state of the enzyme. The analysis of the kinetics of tentoxin binding on the low affinity site of the enzyme showed strong evidence for an interaction between this site and the nucleotide binding sites and revealed a complex relationship between the catalytic state and the reactivation process. New catalytic states of CF1 devoid of epsilon-subunit were detected: a transient overstimulated state, and a dead end complex unable to bind a second tentoxin molecule. Our experiments led to a kinetic model for the reactivation phenomenon for which rate constants were determined. The implications of this model are discussed in relation to the previous mechanistic hypotheses on the effect of tentoxin.
...
PMID:Kinetic analysis of tentoxin binding to chloroplast F1-ATPase. A model for the overactivation process. 987 24
Tentoxin
, produced by phytopathogenic fungi, selectively affects the function of the
ATP synthase
enzymes of certain sensitive plant species. Binding of tentoxin to a high affinity (K(i) approximately 10 nM) site on the chloroplast F(1) (CF(1)) strongly inhibits catalytic function, whereas binding to a second, lower affinity site (K(d) > 10 microM) leads to restoration and even stimulation of catalytic activity. Sensitivity to tentoxin has been shown to be due, in part, to the nature of the amino acid residue at position 83 on the catalytic beta subunit of CF(1). An aspartate in this position is required, but is not sufficient, for tentoxin inhibition. By comparison with the solved structure of mitochondrial F(1) [Abrahams, J. P., Leslie, A. G. W., Lutter, R., and Walker, J. E. (1994) Nature 370, 621-628], Asp83 is probably located at an interface between alpha and beta subunits on CF(1) where residues on the alpha subunit could also participate in tentoxin binding. A hybrid core F(1) enzyme assembled with beta and gamma subunits of the tentoxin-sensitive spinach CF(1), and an alpha subunit of the tentoxin-insensitive photosynthetic bacterium Rhodospirillum rubrum F(1) (RrF(1)), was stimulated but not inhibited by tentoxin [Tucker, W. C., Du, Z., Gromet-Elhanan, Z. and Richter, M. L. (2001) Eur. J. Biochem. 268, 2179-2186]. In this study, chimeric alpha subunits were prepared by introducing short segments of the spinach CF(1) alpha subunit from a poorly conserved region which is immediately adjacent to beta-Asp83 in the crystal structure, into equivalent positions in the RrF(1) alpha subunit using oligonucleotide-directed mutagenesis. Hybrid enzymes containing these chimeric alpha subunits had both the high affinity inhibitory tentoxin binding site and the lower affinity stimulatory site. Changing beta-Asp83 to leucine resulted in loss of both inhibition and stimulation by tentoxin in the chimeras. The results indicate that tentoxin inhibition requires additional alpha residues that are not present on the RrF(1) alpha subunit. A structural model of a putative inhibitory tentoxin binding pocket is presented.
...
PMID:Role of the ATP synthase alpha-subunit in conferring sensitivity to tentoxin. 1141 8
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
The P515 absorbance change upon single-turnover light flashes has been studied in intact leaves and isolated chloroplasts from spinach. A comparative study of the effects of preillumination on the kinetics of the P515 response and on the activity of the
chloroplast ATPase
has been made. The slow component (reaction 2) in the flash-induced P515 response normally present in dark-adapted chloroplasts is reduced or even absent under conditions in which the ATPase is activated by preillumination. This suppression of reaction 2 appeared to be temporary in leaves and chloroplasts; its duration in chloroplasts is shown to be dependent on the amount of ATP present.
Tentoxin
inhibits the preillumination-dependent suppression of reaction 2.
...
PMID:On the correlation between the activity of ATP-hydrolase and the kinetics of the flash-induced P515 electrochromic bandshift in spinach chloroplasts. 1825 30
F1-ATPase
is the smallest mechanical motor known.
Tentoxin
, a cyclic peptide produced by phytopathogenic fungi, inactivates the F1 motor in sensitive plants at nanomolar to micromolar concentrations, whereas higher concentrations surpass the natural activity of the enzyme. Single molecule studies now have clarified the molecular steps involved in both processes. Inactivation delays the dwell time of a single step in the complete 360 degrees turn and results in an asymmetric rotation of the central rotor subunit. In contrast, rotation in the stimulated F1 particle is smooth and accompanied by strongly reduced ADP inhibition. Our study provides for the first time the direct observation of a noncompetitively inhibited state of the enzyme and directly visualizes the regulation of the molecular motor by an external natural compound. In addition, the ADP release step during catalysis was revealed by analysis of the single molecule rotation behavior. Hence, tentoxin is a sophisticated molecular tool to mark and control certain catalytic steps within the reaction pathway of the molecular F1 motor.
...
PMID:Molecular processes of inhibition and stimulation of ATP synthase caused by the phytotoxin tentoxin. 1857 20
