Molecular weight and subunit stoichiometry of the chloroplast coupling factor 1 from Chlamydomonas reinhardi

Catalytic and EPR studies of the beta E204Q mutant of the chloroplast F1-ATPase from Chlamydomonas reinhardtii

The mutation E204Q in the beta subunit of the chloroplast F1-ATPase was made by biolistic transformation of Chlamydomonas reinhardtii. The yield of chloroplast F1-ATPase (CF1) purified from thylakoids was unaltered, suggesting that the mutation did not affect protein assembly. However, photoautotrophic growth of Chlamydomonas strains containing beta E204Q was virtually abolished, and the effect of the mutation on the light-driven ATPsynthase activity catalyzed by purified thylakoids was comparable to the change in the photoautotrophic growth rate. The loss of ATPsynthase activity in the mutant was not the result of uncoupling. Addition of wild-type CF1 to mutant thylakoids depleted of CF1 reconstituted ATPsynthase activity indicating that the mutation did not affect assembly of F0. Furthermore, the mutant CF1F0 was capable of catalyzing ATPase-dependent proton pumping as measured by fluorescence quenching of 9-amino acridine. Although the mutation significantly affected the apparent kcat/K(m) of the Mg(2+)-ATPase activity of the purified CF1-ATPase, no significant effect on the apparent kcat was observed with the mutant compared to wild-type. No significant changes in the ability of Mg2+ or Mn2+ to serve either as a cofactor or as an inhibitor of ATPase activity were observed in the mutants relative to the wild-type CF1-ATPase. EPR spectra were also taken of VO2+ bound at catalytic site 3 in its latent form. In a large fraction of the latent enzyme, a carboxyl group has displaced the nucleotide-phosphate coordination to the metal which results in the free-metal inhibited form (M3). No significant effects on the gII and AII 51V hyperfine parameters were observed between wild-type and mutant. However, the mutation increased the abundance of the M3 form relative to the M3-N3 form (metal-nucleotide-coordinated form). On the basis of these results, beta E204 is not the carboxyl group that displaces the nucleotide phosphate as a ligand to form the free-metal inhibited enzyme form which predominates in site 3 in the latent state. Instead, the data are consistent with a role in which beta E204 is essential to protonate an inorganic phosphate-oxygen to make that oxygen a good leaving group to facilitate ATP synthesis and, via this role in H-bonding, increases the abundance of the functional metal-nucleotide complex bound to the catalytic site.

Inactivation of chloroplast H(+)-ATPase by modification of Lys beta 359, Lys alpha 176 and Lys alpha 266

Treatment of isolated, latent chloroplast ATPase with pyridoxal-5-phosphate (pyridoxal-P) in presence of Mg2+ causes inhibition of dithiothreitol-activated plus heat-activated ATP hydrolysis. The amount of [3H]pyridoxal-P bound to chloroplast coupling factor 1 (CF1) was estimated to run up to 6 +/- 1 pyridoxal-P/enzyme, almost equally distributed between the alpha- and beta-subunits. Inactivation, however, is complete after binding of 1.5-2 pyridoxal-P/CF1, suggesting that two covalently modified lysines prevent the activation of the enzyme. ADP as well as ATP in presence of Mg2+ protects the enzyme against inactivation and concomittantly prevents incorporation of a part of the 3H-labeled pyridoxal-P into beta- and alpha-subunits. Phosphate prevents labeling of the alpha-subunit, but has only a minor effect on protection against inactivation. The data indicate a binding site at the interface between the alpha- and beta-subunits. Cleavage of the pyridoxal-P-labeled subunits with cyanogen bromide followed by sequence analysis of the labeled peptides led to the detection of Lys beta 359, Lys alpha 176 and Lys alpha 266, which are closely related to proposed nucleotide-binding regions of the alpha- and beta-subunits.

Transcription and translation of the chloroplast atpB-gene and assembly of ATP synthase subunit beta

In vitro transcription and subsequent translation of the cloned Chlamydomonas chloroplast atpB gene was used to study assembly of ATP synthase. Translation in the presence of thylakoids resulted in association of the beta subunit with the membrane. The in vitro synthesized polypeptide bound to the membrane copurified with CF1 on sucrose gradients. This provides more evidence for the self-assembly of CF1.

N-Ethylmaleimide inhibition of the catalytic activities of the Dunaliella salina coupling factor 1 (CF1) and the restoration of the inhibition of the CF1 ATPase activity by N-ethylmaleimide

The sensitivity of the catalytic activities of the D. salina chloroplast coupling factor 1 (CF1) to chemical modification by N-ethylmaleimide has been investigated. When D. salina thylakoid membranes are treated with N-ethylmaleimide, both photophosphorylation and the inducible CF1 ATPase activity are partially (approx. 60%) inhibited. The inhibition of both activities does not require the presence of a proton-motive force, and the inhibition of photophosphorylation is directly related to the N-ethylmaleimide-covalent modification of CF1 as shown by the time-course for the inhibition and the maximal extent of inhibition. Treatment of the purified, latent, D. salina CF1 with low concentrations of N-ethylmaleimide also results in the partial (approx. 60%) inhibition of the inducible ATPase activity (I50 approximately 50 microM). The inhibition does not require the presence of the chemical modifier during the activation of the enzyme. N-ethylmaleimide-induced inhibition of the ATPase activity of either membrane-bound or solubilized CF1 is partially reversed by either prolonged incubation at low concentrations of N-ethylmaleimide or short incubation times at high concentrations of N-ethylmaleimide. The results are interpreted as indicating multiple binding sites on the D. salina CF1 that have different rates of reactivity with N-ethylmaleimide. Those sites (or site) that react rapidly with N-ethylmaleimide cause(s) an inhibition of both ATP synthase and ATPase activities, whereas those sites (or site) that react more slowly partially restore(s) the original ATPase activity. The effects of N-ethylmaleimide on the catalytic activity of D. salina CF1 are probably mediated by N-ethylmaleimide-induced conformational changes of the enzyme.

Photoaffinity labeling of the tight ADP binding site of the chloroplast coupling factor one (CF1): the effect on the CF1-ATPase activity

Chloroplast thylakoid membranes contain tightly bound ADP which is intimately involved in the mechanism of photophosphorylation. The photoaffinity analog 2-azido-ADP binds tightly to spinach thylakoid membrane-bound coupling factor one (CF1) and, in a manner similar to ADP, inhibits the light-triggered ATPase activity (Czarnecki, J.J., Abbott, M.S. and Selman, B.R. (1983) Eur. J. Biochem. 136, 19-24). Ultraviolet irradiation of thylakoid membranes containing noncovalently, tightly bound 2-azido[beta-32P]ADP results in the inactivation of both the methanol-stimulated MgATPase activity of the membrane-bound CF1 and the octylglucoside-dependent MgATPase activity of the solubilized enzyme. There is a linear correlation between the loss of enzyme activity and the covalent incorporation of the photoaffinity analog. Full inactivation of catalytic activity is estimated to occur upon incorporation of 1.07 mol analog and 0.65 mol analog per mol enzyme for the methanol- and octylglucoside-stimulated activities, respectively. Since 2-azido-ADP modifies only the beta subunit of the CF1 and since there are probably three beta subunits per CF1, these results indicate strong cooperativity among beta subunits and between the site of tightly bound nucleotides and the catalytic sites.

Plastome mutation affecting the chloroplast ATP synthase involves a post-transcriptional defect

In a plastid genome (plastome) mutation of Oenothera hookeri, at least two of the plastome-coded polypeptides (the beta and epsilon subunits) of the chloroplast ATP synthase are directly affected. As in other plastid chromosomes, the genes for the beta and epsilon subunits are located next to each other on the Oenothera ptDNA molecule and are cotranscribed. Immunoanalysis and peptide mapping of in vivo products suggests that a fusion of the two genes may have occurred in the plastome mutant. In contrast to the in vivo data, in vitro translation of the RNA using a heterologous system results in polypeptides which cannot be distinguished from those of wild-type. In addition, neither the mRNA sizes nor plastid DNA restriction fragment patterns differ from wild-type. To reconcile the paradox of these results, it is suggested that either a defect in a translational signal or some other post-transcriptional event is responsible for the mutant phenotype.

Photosynthetic ATPases: purification, properties, subunit isolation and function

Photosynthetic coupling factor ATPases (F1-ATPases) generally censist of five subunits named α, β, γ, δ and ε in order of decreasing apparent molecular weight. The isolated enzyme has a molecular weight of between 390,000 to 400,000, with the five subunits probably occurring in a 3:3:1:1:1 ratio. Some photosynthetic F1 ATPases are inactive as isolated and require treatment with protease, heat or detergent in order to elicit ATPase activity. This activity is sensitive to inhibition by free divalent cations and appears to be more specific for Ca(2+) vs. Mg(2+) as the metal ion substrate chelate. This preference for Ca(2+) can be explained by the higher inhibition constant for inhibition of ATPase activity by free Ca(2+). Methods for the assay of a Mg-dependent ATPase activity have recently been described. These depend on the presence of organic solvents or detergents in the reaction mixture for assay. The molecular mechanism behind the expression of either the Ca- or Mg-ATPase activities is unknown. F1-ATPases function to couple proton efflux from thylakoid membranes or chromatophores to ATP synthesis. The isolated enzyme may thus also be assayed for the reconstitution of 'coupling activity' to membranes depleted of coupling factor 1.The functions of the five subunits in the complex have been deduced from the results of chemical modification and reconstitution studies. The δ subunit is required for the functional binding of the F1 to the F0. The active site is probably contained in the β (and α) subunit(s). The proposed functions for the γ and ε subunits are, however, still matters of controversy. Coupling factors from a wide variety of species including bacteria, algae, C3 and C4 plants, appear to be immunologically related. The β subunits are the most strongly related, although the α and γ subunits also show significant immunological cross-reactivity. DNA sequence analyses of the genes for the β subunit of CF1 have indicated that the primary sequence of this polypeptide is highly conserved. The genes for the polypeptides of CF1 appear to be located in two cellular compartments. The α, β and ε subunits are coded for on chloroplast DNA, whereas the γ and δ subunits are probably nuclear encoded. Experiments involving protein synthesis by isolated chloroplasts or protein synthesis in the presence of inhibitors specific for one or the other set of ribosomes in the cell suggest the existence of pools of unassembled CF1 subunits. These pools, if they do exist in vivo, probably make up no greater than 1% of the total CF1 content of the cell.

Identification of the alpha and beta subunits of the chloroplast coupling factor one in Chlamydomonas reinhardi

The alpha and beta subunits of the Chlamydomonas reinhardi coupling factor one have been identified by an immunochemical method and by the reaction of dicyclohexylcarbodiimide with the beta subunit. Antibodies raised against the C. reinhardi subunit with the highest apparent molecular weight react with the alpha subunit of spinach coupling factor one and antibodies raised against the beta subunit of the spinach chloroplast enzyme cross-react with the C. reinhardi subunit of lower apparent molecular weight. Dicyclohexylcarbodiimide also reacts with this subunit. We conclude therefore that the two subunits of highest apparent molecular weight can be named alpha and beta in order of decreasing apparent molecular weight, in contrast to the nomenclature suggested by Piccioni, R. G., Bennoun, P. and Chua, N.-H. [(1981) Eur. J. Biochem. 117, 93-102].

Localization of the tight ADP-binding site on the membrane-bound chloroplast coupling factor one

The photoaffinity analog 2-azido-ADP (2-azidoadenosine 5'-diphosphate) was used as a probe of the spinach chloroplast ATP synthase. The analog acted as a substrate for photophosphorylation. Several observations suggested that 2-azido-ADP and ADP bound to the same class of tight nucleotide binding sites: (a) 2-azido-ADP competitively inhibited ADP tight binding (Ki = 1.4 microM); (b) the concentration giving 50% maximum binding, K0.5 for analog tight binding (1 microM) was similar to that observed for ADP (2 microM); (c) nucleotide tight binding required prior membrane energization and was completely reversed by re-energization; (d) the tight binding of 2-azido-[beta-32P]ADP was completely prevented by ADP; (e) the analog inhibited the light-triggered ATPase activity at micromolar concentrations. Ultraviolet irradiation of washed thylakoid membranes containing tightly bound 2-azido-[beta-32P]ADP resulted in the covalent incorporation of the label into the membranes. Denaturing polyacrylamide gel electrophoresis of the labeled membranes demonstrated that the beta subunit of the coupling factor one complex was the only polypeptide in the thylakoid membranes which was labeled. These results identify the beta subunit of the coupling factor as the location of the tightly bound ADP on the thylakoid membranes.