Quaternary structure of chloroplast F1-ATPase in solution. Conformational changes in spatial arrangement of subunits upon activation

The hydrodynamic properties of isolated ATPases were studied via their rotational diffusion in buffer solution. Chloroplast F1-ATPase (CF1) and Escherichia coli F1-ATPase (EF1) were covalently labeled with eosinisothiocyanate and then investigated by polarized laser spectroscopy. The rotational correlation time in aqueous buffer of latent (five-subunit) CF1 was 390 ns. Four-subunit (delta-deficient) CF1 showed the same correlation time, however, for three-subunit (delta, epsilon-deficient) CF1 the rotational correlation time was more than eight times larger (3200 ns). The rotational correlation time of activated CF1 was three times larger than the one of latent CF1. These large changes in the rotational correlation times are directly related to changes in the quaternary structure of CF1 upon activation. EF1 was found to behave essentially as activated CF1. Based on the observed rotational correlation times we concluded that the mass distributions of latent CF1 and of delta-deficient CF1 resemble a dimeric arrangement. The structure of delta, epsilon-deficient CF1 more likely resembles a hexagon, the mass centers of the six main subunits lie in one plane. The structure of the activated forms of CF1 can be described best as an intermediate between the dimeric arrangement of latent CF1 and an octahedron. The large changes in the quaternary structure of isolated CF1 are reversed when the activation of the enzyme is reversed.     

Specific binding of coupling factor 1 lacking the delta and epsilon subunits to thylakoids

An improved procedure for the preparation of chloroplast coupling factor 1 (CF1) lacking the delta subunit is described. In addition, CF1 deficient in the epsilon subunit was isolated by a new method and CF1 lacking both of the smaller subunits was prepared. The ability of the subunit-deficient forms and of CF1, either heated or incubated with dithiothreitol to activate its ATPase activity, to bind to thylakoids from which CF1 had been removed was studied. All CF1 preparations bound in a cation-dependent manner to similar extents. CF1 lacking the delta subunit required higher cation concentrations for maximal binding. All preparations competed similarly with control CF1 for binding sites on the depleted membranes. The alpha subunit of all forms of CF1 in solution was rapidly cleaved by trypsin. After reconstitution, however, the alpha subunit of CF1, as well as of the subunit-deficient and the activated forms, was resistant to attack by trypsin. Moreover, treatment of the membranes with either trypsin or N,N'-dicyclohexylcarbodiimide inhibited the binding of all CF1 forms. These results suggest that the binding of the subunit-deficient and activated forms of CF1 is specific. CF1 lacking the epsilon subunit restored neither proton uptake nor ATP synthesis to the depleted membranes. In contrast to our previous results, CF1 lacking the delta subunit was partially effective. Previously, we used a suboptimal Mg2+ concentration for binding the delta-deficient enzyme which we show here was partially deficient in the epsilon subunit. These results show that the delta and epsilon subunits are not required for binding CF1 to the membranes and that the delta subunit is not an absolute requirement for ATP synthesis.     

Identification and tryptic cleavage of the catalytic core of HeLa and calf thymus DNA polymerase epsilon

DNA polymerase epsilon, formerly known as a proliferating cell nuclear antigen-independent form of DNA polymerase delta, has been shown elsewhere to be catalytically and structurally distinct from DNA polymerase delta. The catalytic activity of HeLa DNA polymerase epsilon, an enzyme consisting of greater than 200- and 55-kDa polypeptides, was assigned to the larger polypeptide by polymerase trap reaction. This catalytic polypeptide was cleaved by incubation with trypsin into two polypeptide fragments with molecular masses of 122 and 136 kDa, the former of which was relatively resistant to further proteolysis and possessed the polymerase activity. The cleavage increased the polymerase and exonuclease activities of the enzyme some 2-3-fold. DNA polymerase epsilon was also purified in a smaller 140-kDa form from calf thymus. The digestion of this form of the enzyme by trypsin also generated a 122-kDa polypeptide. These results suggest that the catalytic core of DNA polymerase epsilon is a 258-kDa polypeptide that is composed of two segments linked with a protease-sensitive area. One of the segments harbors both DNA polymerase and 3'----5' exonuclease activities. In spite of the different polypeptide structures, the catalytic properties of the HeLa enzyme, its trypsin-digested form, and the calf thymus enzyme remained essentially the same.     

Binding stoichiometry and structural mapping of the epsilon polypeptide of chloroplast coupling factor 1

Fluorescent probes were attached to the single sulfhydryl residue on the isolated epsilon polypeptide of chloroplast coupling factor 1 (CF1), and the modified polypeptide was reconstituted with the epsilon-deficient enzyme. A binding stoichiometry of one epsilon polypeptide per CF1 was obtained. This stoichiometry corresponded to a maximum inhibition of the Ca2+-dependent ATPase activity of the enzyme induced by epsilon removal. Resonance energy transfer between the modified epsilon polypeptide and fluorescent probes attached to various other sites on the enzyme allowed distance measurements between these sites and the epsilon polypeptide. The epsilon-sulfhydryl is nearly equidistant from both the disulfide (23 A) and the dark-accessible sulfhydryl (26 A) of the gamma subunit. Measurement of the distance between epsilon and the light-accessible gamma-sulfhydryl was not possible due to an apparent exclusion of modified epsilon from epsilon-deficient enzyme after modification of the light-accessible site. The distances measured between epsilon and the nucleotide binding sites on the enzyme were 62, 66, and 49 A for sites 1, 2, and 3, respectively. These measurements place the epsilon subunit in close physical proximity to the sulfhydryl-containing domains of the gamma subunit and approximately 40 A from the membrane surface. Enzyme activity measurements also indicated a close association between the epsilon and gamma subunits: epsilon removal caused a marked increase in accessibility of the gamma-disulfide bond to thiol reagents and exposed a trypsin-sensitive site on the gamma subunit. Either disulfide bond reduction or trypsin cleavage of gamma significantly enhanced the Ca2+-ATPase activity of the epsilon-deficient enzyme. Thus, the epsilon and gamma polypeptides of coupling factor 1 are closely linked, both physically and functionally.     

Purification of membrane attachment and inhibitory subunits of the proton translocating adenosine triphosphatase from Escherichia coli.

The portion of Escherichia coli adenosine triphosphatase (ATPase) which is peripheral to the membrane (ECFl) is composed of five separate polypeptides referred to as alpha, beta, gamma, delta, and epsilon. Treating purified ECFl with pyridine precipitated the three larger polypeptides (alpha, beta, and gamma), but the two smaller ones (delta and epsilon), which represent only about 10% of ECFl, remained in solution. After removing the pyridine, both delta and epsilon were active and both were obtained in essentially pure form after chromatography on a single molecular-seive column. epsilon strongly inhibited the ATPase activity of ECFl, indicating that epsilon has a regulatory role in the enzyme. epsilon inhibited ECFl missing delta, indicating that delta is not required for inhibition by epsilon. However, enzyme containing just the alpha and beta subunits, which was prepared by treating ECFl with a protease, was fully active hydrolytically but not at all sensitive to inhibition by epsilon. This result suggests that the gamma polypeptide is required for the inhibition of the ATPase by epsilon. delta restored the capacity of ECFl missing delta to recombine with ECFl-depleted membrane vesicles. The ECFl, which became attached to the vesicles by the added delta, was functional in energy transduction, as evidenced by the coupling of ATP hydrolysis to the transhydrogenase reaction in the vesicles. The rebinding of ECFl missing delta was directly proportional to the amount of delta added until all the ECFl receptors in the membranes were occupied. delta may be a stalk which connects the Fl headpiece to the membrane, since the attachment of ECFl to the membrane exhibited an absolute dependence on delta. Although delta is known to have an apparent molecular weight of about 20,000 by gel electrophoresis in the presence of sodium dodecyl sulfate, the active delta eluted from a molecular-seive column with an apparent molecular weight of about 35,000, suggesting that in the active form delta is a dimer or rather elongated in shape. The active epsilon subunit eluted from the same column with an apparent molecular weight of about 16,000.     

Modifications of the gamma subunit of chloroplast coupling factor 1 alter interactions with the inhibitory epsilon subunit.

The treatment of chloroplast coupling factor 1 (CF1) with dithiothreitol or with trypsin modifies the gamma subunit. Reduction of the gamma subunit disulfide bond in CF1 in solution with dithiothreitol enhances the dissociation of epsilon (Duhe, R. J., and Selman, B. R. (1990) Biochim. Biophys. Acta 1017, 70-78). The Ca(2+)-ATPase activity of either oxidized or reduced CF1 increases as the enzyme is diluted. Added epsilon subunit inhibits the Ca(2+)-ATPase activity of both forms of the diluted CF1, suggesting that epsilon dissociation is the cause of activation by dilution. Half-maximal activation occurred at much higher concentrations of the reduced CF1, indicating that reduction decreases the affinity for epsilon about 20-fold. Immunoblotting techniques show that there is only one epsilon subunit/CF1 in intact chloroplasts, in thylakoid membranes, and in solution. No epsilon is released from CF1 in thylakoids under conditions of ATP synthesis. The gamma subunit of CF1 in illuminated thylakoids is specifically cleaved by trypsin. CF1 purified from thylakoids treated with trypsin in the light is deficient in epsilon subunit, and has a high rate of ATP hydrolysis. Added epsilon neither inhibits the ATPase activity of, nor binds tightly to the cleaved enzyme.     

Aspects of Subunit Interactions in the Chloroplast ATP Synthase (II. Characterization of a Chloroplast Coupling Factor 1-Subunit III Complex from Spinach Thylakoids)

A complex between chloroplast-coupling factor 1 (CF1) and subunit III of the membrane-spanning portion of the chloroplast ATP synthase (CF0), isolated as described in the accompanying paper (C.M. Wetzel and R.E. McCarty [1993] Plant Physiol 102: 241-249), has been further characterized. A comparison of the ATPase activities of CF1, CF1-subunit III, and the chloroplast ATP synthase (CF1-CF0) holoenzyme revealed that the properties of CF1-subunit III more closely resemble those of CF1-CF0 than those of CF1. In particular, the Ca2+-ATPase activity after reduction of the enzyme with dithiothreitol was much lower in CF1-subunit III and CF1-CF0 than in CF1, suggesting that the association of the inhibitory [epsilon] subunit is tightened by the presence of either CF0 or subunit III. Cold stability is a property of CF1-CF0 in thylakoid membranes. The ATPase activity of CF1 incubated in the cold in the presence of asolectin liposomes was lost more rapidly than that of either CF1-subunit III or CF1-CF0 incorporated into liposomes. Removal of the [epsilon] subunit from all three preparations resulted in marked stimulation of their ATPase activity. Although subunit III was also removed during depletion of the [epsilon] subunit, it is not known whether the two subunits interact directly. CF1 deficient in the [epsilon] subunit binds to liposomes containing either subunit III or CF0. Taken together, these results provide evidence that the association of CF1 and subunit III of CFo is specific and may play a role in enzyme regulation.     

Functional Consequences of Deletions of the N Terminus of the [epsilon] Subunit of the Chloroplast ATP Synthase

The [epsilon] subunit of the chloroplast ATP synthase functions in part to prevent wasteful ATP hydrolysis by the enzyme. In addition, [epsilon] together with the remainder of the catalytic portion of the synthase (CF1) is required to block the nonproductive leak of protons through the membrane-embedded component of the synthase (CFO). Mutant [epsilon] subunits of the spinach (Spinacia oleracea) chloroplast ATP synthase that lack 5, 11, or 20 amino acids from their N termini ([epsilon]-[delta]5N, [epsilon]-[delta]11N, and [epsilon]-[delta]20N, respectively), were overexpressed as inclusion bodies. Using a procedure that resulted in the folding of full-length, recombinant [epsilon] in a biologically active form, none of these truncated forms resulted in [epsilon] that inhibited the ATPase activity of CF1 deficient in [epsilon], CF1(-[epsilon]). Yet, the [epsilon]-[delta]5N and [epsilon]-[delta]11N peptides significantly inhibited the ATPase activity of CF1(-[epsilon]) bound to CFO in NaBr-treated thylakoids. Although full-length [epsilon] rapidly inhibited the ATPase activity of CF1(-[epsilon]) in solution or bound to CFO, an extended period was required for the truncated forms to inhibit membrane-bound CF1(-[epsilon]). Despite the fact that [epsilon]-[delta]5N significantly inhibited the ATPase activity of CF1(-[epsilon]) bound to CFO, it did not block the proton conductance through CFO in NaBr-treated thylakoids reconstituted with CF1(-[epsilon]). Based on selective proteolysis and the binding of 8-anilino-1-naphthalene sulfonic acid, each of the truncated peptides gained significant secondary structure after folding. These results strongly suggest (a) that the N terminus of [epsilon] is important in its binding to CF1, (b) that CF0 stabilizes [epsilon] binding to the entire ATP synthase, and (c) that the N terminus may play some role in the regulation of proton flux through CFO.     

Added subunit beta of CF1 as well as gamma/delta/epsilon restore photophosphorylation in partially CF1-depleted thylakoids.

We investigated the ability of subunits beta, gamma, delta, and epsilon of CF1, the F1-ATPase of chloroplasts, to interact with exposed CF0 in EDTA-treated, partially CF1-depleted thylakoid membranes. We measured the ability of subunits beta, gamma, delta, and epsilon to stimulate the rate of photophosphorylation under continuous light and, for subunit beta, also the ability to diminish the proton leakage through exposed CF0 by deceleration of the decay of electrochromic absorption transients under flashing light. The greatest effect was caused by subunit beta, followed by gamma/delta/epsilon. Pairwise combinations of gamma, delta, and epsilon or each of these subunits alone were only marginally effective. Subunit gamma from the thermophilic bacterium PS 3 in combination with chloroplast delta and epsilon was as effective as chloroplast gamma. The finding that the small CF1 subunits in concert and the beta subunit by itself specifically interacted with the exposed proton channel CF0, qualifies the previous concept of subunit delta acting particularly as a plug to the open CF0 channel. The interactions between the channel and the catalytic portion of the enzyme seem to involve most of the small, and at least beta of the large subunits.     

Effect of proteolytic digestion on the Ca2+-ATPase activity and subunits of latent and thiol-activated chloroplast coupling factor 1

The activation by proteases of the Ca2+-dependent ATPase of chloroplast coupling factor 1 (CF1) has been investigated. Using low concentrations of papain and trypsin, the increase in ATPase activity and the degradation of the five subunits of CF1 were compared. Sodium dodecyl sulfate-gel electrophoresis of protease-treated CF1 revealed that the delta subunit was very rapidly degraded and that the alpha and beta subunits were clipped. The gamma and epsilon subunits were more resistant to digestion. The modification of the alpha subunit of latent CF1 most closely correlated with the activation of Ca2+-ATPase activity. Trypsin treatment of dithiothreitol-activated CF1 resulted in a very rapid increase in Ca2+-ATPase activity and a corresponding rapid cleavage of the gamma subunit to a 25,000-dalton species. With more prolonged treatment, the 25,000-dalton species was cleaved to fragments of 14,000 and 11,000-daltons. Dithiothreitol treatment did not alter the rate of attack on the other subunits. The gamma subunit of heat-activated CF1 was also more susceptible to protease digestion. The increased protease sensitivity of the gamma subunit of soluble CF1 after treatment with dithiothreitol or heat mimics the increased protease sensitivity of the gamma subunit of bound CF1 when thylakoids are treated with trypsin during illumination (Moroney, J. V., and McCarty, R. E. (1982) J. Biol. Chem. 257, 5915-5920). These results suggest that the conformational changes that occur when purified CF1 is exposed to dithiothreitol are similar to those that CF1 bound to thylakoid membranes undergoes under illumination.     

ATPase of Escherichia coli: purification, dissociation, and reconstitution of the active complex from the isolated subunits.

A simple procedure for the purification of Mg2+-stimulated ATPase of Escherichia coli by fractionation with poly(ethylene glycols) and gel filtration is described. The enzyme restores ATPase-linked reactions to membrane preparations lacking these activities. Five different polypeptides (alpha, beta, gamma, delta, epsilon) are observed in sodium dodecyl sulfate electrophoresis. Freezing in salt solutions splits the enzyme complex into subunits which do not possess any catalytic activity. The presence of different subunits is confirmed by electrophoretic and immunological methods. The active enzyme complex can be reconstituted by decreasing the ionic strength in the dissociated sample. Temperature, pH, protein concentration, and the presence of substrate are each important determinants of the rate and extent of reconstitution. The dissociated enzyme has been separated by ion-exchange chromatography into two major fragments. Fragment IA has a molecular weight of about 100000 and contains the alpha, gamma, and epsilon polypeptides. The minor fragment, IB, has about the same molecular weight but contains, besides alpha, gamma, and epsilon, the delta polypeptide. Fragment II, with a molecular weight of about 52000, appears to be identical with the beta polypeptide. ATPase activity can be reconstituted from fragments IA and II, whereas the capacity of the ATPase to drive energy-dependent processes in depleted membrane vesicles is only restored after incubation of these two fractions with fraction IB, which contains the delta subunit.     

Role of a disulfide bond in the gamma subunit in activation of the ATPase of chloroplast coupling factor 1

The relationship between activation of the latent ATPase activity of isolated chloroplast coupling factor 1 (CF1) and reduction of a disulfide in the gamma subunit has been assessed. The sulfhydryl residues involved in the disulfide bond are distinct from residues normally accessible to maleimide modification during incubation of thylakoids in the dark or the light. Dithiothreitol-induced activation is time dependent, and correlates with reduction of the disulfide. Sulfhydryl residues exposed during activation can be reoxidized to disulfide by incubation with iodosobenzoate , with a concomitant loss of ATPase activity. Activation and deactivation are reversible, but deactivation is prevented by treatment of the reduced enzyme with N-ethylmaleimide. Heat activation does not reduce the disulfide bond unless dithiothreitol is present during activation. Prior heating of CF1, which partially activates the enzyme, renders the disulfide more susceptible to subsequent dithiol reduction. The activity obtained when heat and dithiothreitol are used together is approximately equal to the sum of the partial activations obtained with heat or dithiothreitol alone. Iodosobenzoate has no effect on heat-activated CF1. Enzyme activated by heating in the presence of dithiothreitol can be partially deactivated, consistent with reversal of the activity attributable to the dithiol effect. Fluorescence polarization of anilinonaphthylmaleimide bound to the reduced enzyme indicates that the sulfhydryl residues involved in the disulfide are in a less rigid environment than the other two sulfhydryl residues in the gamma subunit. Polarization of anilinonaphthylmaleimide bound to these sulfhydryls is reduced by heat treatment of CF1. The increased susceptibility of the disulfide to reduction upon heat treatment, and the activation of ATPase activity with or without disulfide bond cleavage are indicative of conformational changes within the gamma subunit that occur during the conversion of CF1 from a latent to an active ATPase. In addition the results are consistent with at least two distinct conformational forms of CF1 that can hydrolyze ATP.     

Two forms of DNA polymerase delta from mouse cells. Purification and properties

A procedure is described for the purification from cultured mouse cells of two DNA polymerase "delta-like" enzymes, as defined by intrinsic 3'-exonuclease activity, inhibition by aphidicolin, and relative insensitivity to N2-(p-n-butylphenyl)-dGTP. One of the two enzymes has been purified to near homogeneity and, similar to the DNA polymerase delta from calf thymus described by Lee et al. (Lee, M. Y. W. T., Tan, C. K., Downey, K. M., and So, A. G. (1984) Biochemistry 23, 1906-1913), it has a total molecular mass of 178 kDa (from sedimentation velocity of 8.0 S and Stokes radius of 54 A) and is composed of one each of 125- and 50-kDa polypeptides. It also resembles the DNA polymerase delta of Lee et al. in being stimulated by proliferating cell nuclear antigen (PCNA). It is the first clear structural and functional counterpart of the calf thymus enzyme. The major difference between the mouse DNA polymerase delta and the calf thymus enzyme of Lee et al. is that, under specific conditions, the mouse enzyme is active with poly(dA).oligo(dT) in the absence of PCNA, whereas the activity of the calf thymus enzyme with this template is reported to be completely dependent on PCNA. The reason for this difference is not known at this time. The second mouse cell enzyme has a molecular mass of 112 kDa (from sedimentation velocity of 6.3 S and Stokes radius of 43.0 A) and consists of a single polypeptide of 123-125 kDa in denaturing gels (p125). On the basis of its apparent formation by dissociation of DNA polymerase delta, and multiple similarities with DNA polymerase delta in enzymatic properties, the p125 is provisionally identified as the 125-kDa polypeptide of DNA polymerase delta. The p125 does not respond to PCNA, suggesting that the 50-kDa polypeptide is required for the stimulation of DNA polymerase delta by PCNA. The presence of the p125 in cell extracts would explain reports that DNA polymerase delta consists of a single polypeptide of approximately 125 kDa and/or thast it has a smaller molecular mass than DNA polymerase delta of Lee et al. and is not affected by PCNA (this does not apply to PCNA-independent DNA polymerase delta-like enzymes with higher molecular mass than the polymerase delta of Lee et al., which have recently been named DNA polymerases epsilon).     

Regulatory role of the C-terminus of the epsilon subunit from the chloroplast ATP synthase

The ATP synthases from chloroplasts and Escherichia coli are regulated by several factors, one of which is the epsilon subunit. This small subunit is also required for ATP synthesis. Thylakoid membranes reconstituted with CF1 lacking the epsilon subunit (CF1-epsilon) exhibit no ATP synthesis and very high ATP hydrolysis. Either native or recombinant epsilon restores ATP synthesis and inhibits ATP hydrolysis. Previously, we showed that truncated epsilon, lacking the last 45 C-terminal amino acids, restored ATP synthesis to membranes reconstituted with CF1-epsilon but was not an efficient inhibitor of ATP hydrolysis. In this paper, we show that this truncated epsilon is unable to inhibit ATP hydrolysis when Mg(2+) is the divalent cation present, both for the enzyme in solution and on the thylakoid membrane. In addition, the rate of reduction of the disulfide bond of the gamma subunit by dithiothreitol is not decreased by truncated epsilon, although full-length epsilon greatly impedes reduction. Thylakoid membranes can synthesize ATP at the expense of proton gradients generated by pH transitions in the dark. Our reconstituted membranes are able to produce a limited amount of ATP under these "acid-bath" conditions, with approximately equal amounts produced by the membranes containing wild-type epsilon and those containing truncated epsilon. However, the membranes containing truncated epsilon exhibit much higher background ATP hydrolysis under the same acid-bath conditions, leading to the conclusion that, without the C-terminus of epsilon, the CF1CFo is unable to check unwanted ATP hydrolysis.     

Evidence that DNA polymerase delta isolated by immunoaffinity chromatography exhibits high-molecular weight characteristics and is associated with the KIAA0039 protein and RPA

DNA polymerase delta, the key enzyme for eukaryotic chromosomal replication, has been well characterized as consisting of a core enzyme of a 125 kDa catalytic subunit and a smaller 50 kDa subunit. However, less is known about the other proteins that may comprise additional subunits or participate in the macromolecular protein complex that is involved in chromosomal DNA replication. In this study, the properties of calf thymus pol delta preparations isolated by immunoaffinity chromatography were investigated. It is demonstrated for the first time using highly purified preparations that the pol delta heterodimer is associated with other polypeptides in high-molecular weight species that range from 260000 to >500000 in size, as determined by FPLC gel filtration. These preparations are associated with polypeptides of ca. 68-70, 34, 32, and 25 kDa. Similar findings were revealed with glycerol gradient ultracentrifugation. The p68 polypeptide was shown to be a PCNA binding protein by overlay methods with biotinylated PCNA. Protein sequencing of the p68, p34, and p25 polypeptide bands revealed sequences that correspond to the hypothetical protein KIAA0039. KIAA0039 displays a small but significant degree of homology to Schizosaccharomyces pombe Cdc27, which, like Saccharomyces cerevisiae Pol32p, has been described as the third subunit of yeast pol delta. These studies provide evidence that p68 is a subunit of pol delta. In addition, the p68-70 and p32 polypeptides were found to be derived from the 70 and 32 kDa subunits of RPA, respectively.     

Activation of ATPase of spinach coupling factor 1. Release of tightly bound ADP from the soluble enzyme

Several seemingly unrelated procedures used to elicit the latent ATPase activity of soluble spinach coupling factor 1 can be correlated to the release of tightly-bound ADP from the uncoupled enzyme. This ADP release is further enhanced by the presence of medium nucleotides, especially substrate ATP, and may or may not involve release from the catalytic site itself. Similarly, the light/dithiothreitol activation of membrane-bound CF1 ATPase is reported to be accompanied by energy-dependent ADP dissociation. Further indication that ADP release is involved in the ATPase activation mechanism is the observation that a pyruvate kinase phosphoenolpyruvate trap for ADP released during light/dithiothreitol treatment greatly retards the decay of membrane-bound ATPase activity that occurs in the dark, presumably by preventing reassociation of ADP. The time course of CF1 reactivation by light, after light/dithiothreitol activation followed by dark decay, allows a distinction to be made between the apparently rate-limiting dithiol modification and the more rapid dissociation of tightly bound ADP.     

The dithiothreitol-stimulated dissociation of the chloroplast coupling factor 1 epsilon-subunit is reversible

The chloroplast coupling factor 1 complex (CF1) contains an epsilon-subunit which inhibits the CF1 ATPase activity. Chloroform treatment of Chlamydomonas reinhardtii thylakoid membranes solubilizes only forms of the enzyme which apparently lack the delta-subunit. Four interrelated observations are described in this paper. (1) The dithiothreitol- (DTT) induced ATPase activation of CF1(-delta) and the DTT-induced formation of a physically resolvable CF1(-delta,epsilon) from the CF1(-delta) precursor are compared. The similar time-courses of these two phenomena suggest that the dissociation of the epsilon-subunit is an obligatory process in the DTT-induced ATPase activation of soluble CF1. (2) The reversible dissociation of the epsilon-subunit of the CF1 is demonstrated by the exchange of subunits between distinguishable oligomers. 35S-labelled chloroplast coupling factor 1 lacking the delta and epsilon subunits [CF1(-delta,epsilon)] was added to a solution of non-radioactive coupling factor 1 lacking only the delta subunit [CF1(-delta)]. After separation of the two enzyme forms, via high resolution anion-exchange chromatography, radioactivity was detected in the chromatographic fractions containing CF1(-delta). (3) epsilon-deficient CF1 can be resolved from DTT pretreated epsilon-containing CF1 for several days after the removal of DTT. On the other hand, brief incubation of the DTT pretreated epsilon-containing CF1 with low concentrations of o-iodosobenzoate results in chromatographs containing only the peak of epsilon-containing CF1. A simple explanation for this phenomenon is that reduction of CF1 with DTT increases the apparent dissociation constant for the epsilon-subunit to an estimated 3.5 x 10(-8) M (+/- 1.0 x 10(-8) M) from a value of less than or equal to 5 x 10(-11) M for the oxidized enzyme. (4) ATPase activity data show that oxidation of the epsilon-deficient enzyme does not completely inhibit its manifest activity, but oxidation of DTT pre-treated CF1 which contains the epsilon-subunit completely inhibits manifest activity. A simple model is proposed for the influence of the oxidation state of the soluble enzyme on the distribution of ATPase-inactive and ATPase-active subunit configurations.     

The special reaction of photophosphorylation using epsilon ADP--a fluorescent analog of ADP

Photophosphorylation of epsilon ADP in a chloroplast synthetase system reconstituted with CF1 or with CF1 modified by covalently bound epsilon ADP has been studied. The reconstitution of EDTA-treated chloroplasts with CF1 restores the photophosphorylating activity to about 90%. When the CF1 modified by covalently bound epsilon ADP is used for reconstitution the photophosphorylating activity of EDTA-treated chloroplasts is restored to 37%. Based on the results of a photochemical study of the chloroplast ATP-synthetase system reconstituted with CF1 with covalently bound epsilon ADP it may be assumed that the substrate, adenine, participates in proton translocation to inorganic phosphate in the active center of the coupling enzyme during photophosphorylation.