Conformational change of the chloroplast ATP synthase on the enzyme activation process detected by the trypsin sensitivity of the gamma subunit

Delta mu H(+) is known to stimulate the enzyme activity of chloroplast ATP synthase in addition to its important role as energy supply for ATP synthesis. In the present study, we focused on the relationship between the proton translocation via the membrane sector of ATP synthase, F(o), and the conformational change of the central stalk subunit gamma. The conformational change of CF(1) mainly at the gamma subunit was induced by the proton flow via F(o) in the absence of substrates. The effects of inhibitors on CF(o) or CF(1) for this conformational change were also examined. The observed conformational change was partially suppressed by ADP binding. From these results, we propose the Delta mu H(+)-dependent conformational change of CF(1) on the enzyme activation process, which is affected by both ADP binding to the catalytic sites and proton flow via F(o) portion.     

Structure and Function of ε-Subunit of ATP Synthase in Higher Plant Chloroplast

Theε-subunit is the smallest subunit of chloroplast ATP synthase, and is known to inhibit ATPase activity in isolated CF1-ATPase. As a result ε is sometimes called an inhibitory subunit. In addition, and perhaps more importantly, theε-subunit is essential for the coupling of proton translocation to ATP synthesis (as proton gate). The relation between the structure and function ofε-subunit of ATP synthase in higher plant chloroplast has been studied by molecular biological methods such as site-directed mu-tagenesis and truncations for C- or N-terminus ofε-subunit. The results showed that: (1) Thr42 ofε-subunit is important for its structure and function; (2) compared with theε-subunit in E.. coli, theε-subunit of chloroplast ATP synthase is more sensitive to C- or N-terminus truncations.     

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.     

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.     

Proton flux through the chloroplast ATP synthase is altered by cleavage of its gamma subunit

Electron transport, the proton gradient and ATP synthesis were determined in thylakoids that had been briefly exposed to a low concentration of trypsin during illumination. This treatment cleaves the gamma subunit of the ATP synthase into two large fragments that remain associated with the enzyme. Higher rates of electron transport are required to generate a given value of the proton gradient in the trypsin-treated membranes than in control membranes, indicating that the treated membranes are proton leaky. Since venturicidin restores electron transport and the proton gradient to control levels, the proton leak is through the ATP synthase. Remarkably, the synthesis of ATP by the trypsin-treated membranes at saturating light intensities is only slightly inhibited even though the proton gradient is significantly lower in the treated thylakoids. ATP synthesis and the proton gradient were determined as a function of light intensity in control and trypsin-treated thylakoids. The trypsin-treated membranes synthesized ATP at lower values of the proton gradient than the control membranes. Cleavage of the gamma subunit abrogates inhibition of the activity of the chloroplast ATP synthase by the epsilon subunit. Our results suggest that overcoming inhibition by the epsilon subunit costs energy.     

Important subunit interactions in the chloroplast ATP synthase

General structural features of the chloroplast ATP synthase are summarized highlighting differences between the chloroplast enzyme and other ATP synthases. Much of the review is focused on the important interactions between the epsilon and gamma subunits of the chloroplast coupling factor 1 (CF(1)) which are involved in regulating the ATP hydrolytic activity of the enzyme and also in transferring energy from the membrane segment, chloroplast coupling factor 0 (CF(0)), to the catalytic sites on CF(1). A simple model is presented which summarizes properties of three known states of activation of the membrane-bound form of CF(1). The three states can be explained in terms of three different bound conformational states of the epsilon subunit. One of the three states, the fully active state, is only found in the membrane-bound form of CF(1). The lack of this state in the isolated form of CF(1), together with the confirmed presence of permanent asymmetry among the alpha, beta and gamma subunits of isolated CF(1), indicate that ATP hydrolysis by isolated CF(1) may involve only two of the three potential catalytic sites on the enzyme. Thus isolated CF(1) may be different from other F(1) enzymes in that it only operates on 'two cylinders' whereby the gamma subunit does not rotate through a full 360 degrees during the catalytic cycle. On the membrane in the presence of a light-induced proton gradient the enzyme assumes a conformation which may involve all three catalytic sites and a full 360 degrees rotation of gamma during catalysis.     

Effects of sequential deletions of residues from the N- or C-terminus on the functions of epsilon subunit of the chloroplast ATP synthase

Ten truncated mutants of chloroplast ATP synthase epsilon subunit from spinach (Spinacia oleracea), which had sequentially lost 1-5 amino acid residues from the N-terminus and 6-10 residues from the C-terminus, were generated by PCR. These mutants were overexpressed in Escherichia coli, reconstituted with soluble and membrane-bound CF(1), and the ATPase activity and proton conductance of thylakoid membrane were examined. Deletions of as few as 3 amino acid residues from the N-terminus or 6 residues from the C-terminus of epsilon subunit significantly affected their ATPase-inhibitory activity in solution. Deletion of 5 residues from the N-terminus abolished its abilities to inhibit ATPase activity and to restore proton impermeability. Considering the consequence of interaction of epsilon and gamma subunit in the enzyme functions, the special interactions between the epsilon variants and the gamma subunit were detected in the yeast two-hybrid system and in vitro binding assay. In addition, the structures of these mutants were modeled through the SWISS-MODEL Protein Modeling Server. These results suggested that in chloroplast ATP synthase, both the N-terminus and C-terminus of the epsilon subunit show importance in regulation of the ATPase activity. Furthermore, the N-terminus of the epsilon subunit is more important for its interaction with gamma and some CF(o) subunits, and crucial for the blocking of proton leakage. Compared with the epsilon subunit from E. coli [Jounouchi, M., Takeyama, M., Noumi, T., Moriyama, Y., Maeda, M., and Futai, M. (1992) Arch. Biochem. Biophys. 292, 87-94; Kuki, M., Noumi, T., Maeda, M., Amemura, A., and Futai, M. (1988) J. Biol. Chem. 263, 4335-4340], the chloroplast epsilon subunit is more sensitive to N-terminal or C-terminal truncations.     

Relation between the initial kinetics of ATP synthesis and of conformational changes in the chloroplast ATPase studied by external field pulses

ATP formation and the energy-dependent release of tightly bound [14C]-adenine nucleotides from the chloroplast coupling factor CF1 has been studied as a function of the time of energization of the membrane in the range of 500 mus up to 60 ms. The high time resolution was achieved because the energization was generated artificially by external electric field pulses. Applying external electric field pulses to a chloroplast suspension induces an electric potential difference across the thylakoid membrane. The following results were obtained: (1) The amount of ATP generated increases linearly with the time of energization. The steady-state rate of ATP formation is reached in less than 500 mus. (2) A fraction of the adenine nucleotides tightly bound to CF1 is released on energization with a half-rise-time of about 2 ms. The size of the fraction, i.e., the amplitude of the fast phase of the release, increases with the magnitude of the induced transmembrane electric potential difference. A further slow release is superimposed. (3) The initial rate of the release of adenine nucleotides is practically identical with the rate of ATP formation. It is concluded that the release of tightly bound nucleotides monitors an initial conformational change by which the ATPase turns from an inactive into an activated state. For the explanation of the results a reaction scheme is proposed which takes into account a preceding activation of the ATPase.     

A light-dependent dicyclohexylcarbodiimide-sensitive Ca-ATPase activity in chloroplasts which is not coupled to proton translocation

The early observation of light-dependent Ca-ATPase activity in chloroplast thylakoids [Avron, M. (1962) J. Biol. Chem. 237, 2011-2017] has been reinvestigated. It is demonstrated that in contrast to light-triggered Mg-ATP activity, Ca-ATPase activity is strictly dependent on delta microH+, the transthylakoid membrane electrochemical potential gradient, since (a) there is an absolute requirement for continuous illumination; (b) electron-transport mediators that catalyze proton uptake, like phenazinemethosulphate, methylviologen of ferricyanide, are essential and (c) uncouplers inhibit the activity. The Ca-ATPase activity is essentially unaffected by dithiols, but is inhibited by CF0-CF1 inhibitors including tentoxin, dicyclohexylcarbodiimide and antisera to CF1. Addition of Ca-ATP to thylakoids does not induce delta pH or delta psi (the electrical potential gradient) formation either in the light or following preillumination with dithiols, demonstrating that it is not coupled to proton translocation. It is also demonstrated that Ca-ATP or Ca-ADP does not induce a proton leak through CF0-CF1. It is concluded that the Ca-ATPase activity in chloroplast thylakoid reflects a partial reaction of ATP synthesis catalyzed by CF0-CF1, which is internally uncoupled from proton translocation but is dependent on energization by a transmembrane delta microH+.     

Single channel H+ currents through reconstituted chloroplast ATP synthase CF0-CF1.

The purified chloroplast ATP synthase (CF(0)-CF(1)) was reconstituted into azolectin liposomes from which bilayer membranes on the tip of a glass pipette ('dip stick technique')and planar bilayer membranes were form ed. The CF(0)-CF(1) facilitated ion conductance through the bilayer membranes. Our results clearly indicated that the observed single channel currents were carried by H+ through the isolated and reconstituted chloroplast ATPase. We demonstrated that in proteoliposomes it is the whole enzyme complex CF(0)-CF(1) and not the membrane sector CF(0) alone that constitutes a voltagegated, proton-selective channel with a high conductance of 1-5 pS at pH 5.5-8.0. After removal of CF(1) from the liposomes by NaBr treatment the membrane sector CF(0) displayed various kinds of channels also permeable to monovalent cations. The open probability P(0) of the CF(0)-CF(1) channel increased considerable with increasing membrane voltage [from P(0) less than or equal to 1% (V(m) less than or equal to 120 mV) to P(0) less than or equal to 30% (120 mV less than or equal to Vm 200 mV)]. In the presence of ADP (3 microM) and P(i) (5 microM), which specifically bind to CF(1), the open probability decreased and venturicidin (1 microM), a specific inhibitor of H+ flow through CF(0) in thylakoid membranes, blocked the channel almost completely. Our results, which reveal a high channel unit conductance, and at membrane voltages less than 100 mV low open probability with concomitant mean open times in the micros timescale (less than 100 micros) for the energy coupling in the enzyme complex. At physiological membrane voltages for photophosphorylation (about 30 mV) the enzyme complex would then display a time-averaged conductance of about 1 fS.     

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

A chloroplast ATP synthase complex (CF1 [chloroplast-coupling factor 1]-CF0 [membrane-spanning portion of chloroplast ATP synthase]) depleted of all CF0 subunits except subunit III (also known as the proteolipid subunit) was purified to study the interaction between CF1 and subunit III. Subunit III has a putative role in proton translocation across the thylakoid membrane during photophosphorylation; therefore, an accurate model of subunit inter-actions involving subunit III will be valuable for elucidating the mechanism and regulation of energy coupling. Purification of the complex from a crude CF1-CF0 preparation from spinach (Spinacia oleracea) thylakoids was accomplished by detergent treatment during anion-exchange chromatography. Subunit III in the complex was positively identified by amino acid analysis and N-terminal sequencing. The association of subunit III with CF1 was verified by linear sucrose gradient centrifugation, immunoprecipitation, and incorporation of the complex into asolectin liposomes. After incorporation into liposomes, CF1 was removed from the CF1-III complex by ethylenediaminetetracetate treatment. The subunit III-proteoliposomes were competent to rebind purified CF1. These results indicate that subunit III directly interacts with CF1 in spinach thylakoids.     

Purified subunit delta of chloroplast coupling factor CF1 reconstitutes photophosphorylation in partially CF1-depleted membranes

The ATP synthase of chloroplasts consists of the proton channel, CF0, and the catalytic part, CF1, which carries nucleotide-binding sites on subunits alpha and beta. The still poorly understood interaction between CF0 and the catalytic sites on CF1 is mediated by the smaller subunits gamma, delta and epsilon of CF1. We investigated the ability of purified delta to block proton leakage through CF0 channels after their exposure by removal of the CF1 counterpart. Thylakoids were partially depleted of CF1 by EDTA treatment. This increased their proton permeability and thereby reduced the rate of photophosphorylation. Subunit delta was isolated and purified by FPLC [Engelbrecht, S. and Junge, W. (1987) FEBS Lett. 219, 321-325]. Addition of delta to EDTA-treated thylakoids reconstituted high rates of phenazine-methosulfate-mediated photophosphorylation. Since delta does not interact with nucleotides by itself, the reconstitution was due to a reduction of the proton leakage through open CF0 channels. The molar ratio of purified delta over exposed CF0, which started to elicit this effect, was 3:1. However, if delta was added together with purified CF1 lacking delta, in a 1:1 molar ratio, the relative amount over exposed CF0 was as low as 0.06. This corroborated our previous conclusion [Lill, H., Engelbrecht, S., Sch?nknecht, G. and Junge, W. (1986) Eur. J. Biochem. 160, 627-634] that only a very small fraction of exposed CF0 was actually proton-conducting but with a very high unit conductance. CF1 including delta was apparently rebound preferentially to open CF0 channels. Although the ability of delta to control proton conduction through CF0 was evident, it remains to be established whether delta acts as a gated proton valve or as a conformational transducer in the integral CF0CF1 ATPase.     

Proton-Conductivity of CF0-CF1 Reconstructed into Planar Lipid Bilayer

The proton conductable ATP synthase (CF0-CF1) is the key enzyme of energy conversion in the membrane of bacteria, mitochondria and chloroplast. In spite of a large body of studies, the structure and molecular mechanism of ATP synthases are still elusive. In order to learn the mechanism of ATP synthases, the authors used voltage-olamp technique to study the effect of different conditions on the proton conductance of F0-F1 into planar lipid bilayer membrane. The results obtained were as follows: (1) When CF0-CF1 was reconstructed into planar lipid bilayer membrane, the resistance decreased by 10 times. (2) Channel-like current was recorded at the low concentration of CF0-CFl(protein 2 mg/L) in the solution. (3) In metal ion-free solution, the channel currents changed with the trans-membrane proton gradient (ApH). Under holding potential from 0 to + 150 mV, the stimulation of △pH on channel current increased with a rise in the ApH from 2 to 4, the stimulation of 4.5 △pH on channel current was weaker than that of △pH 4.0. (4) The proton conduetance inhibitor, dicyclohexylcarbodiimide (DCCD), showed a rapid and irreversible inhibition effect on the channel current. (5) In metal ion-free solution (10 mmol/L Tris-HC1), when the ApH across the black lipid membrane (BLM) maintained at 3.0, the addition of Mg2 + caused a alger channel current of CF0-CF1 than the addition of Ca2+ , with holding potential from 0 to + 150 mV. The results indicated that reconstruction of CF0-CF1 was successful and Mg2 + was directly involved in the proton conductance pathways.     

Proton slip in the ATP synthase of Rhodobacter capsulatus: induction, proton conduction, and nucleotide dependence

FOF1-ATP synthase converts two energetic "currencies" of the cell (ATP and protonmotive force, pmf) by coupling two rotary motors/generators. Their coupling efficiency is usually very high. Uncoupled proton leakage (slip) has only been observed in chloroplast enzyme at unphysiologically low nucleotide concentration. We investigated the properties of proton slip in chromatophores (sub-bacterial vesicles) from Rhodobacter capsulatus in the single-enzyme-per-vesicle mode. The membrane was energized by excitation with flashing light and the relaxation of the transmembrane voltage and pH difference was photometrically detected. We found that: (1) Proton slip occurred only at low nucleotide concentration (<1 microM) and after pre-illumination over several seconds. (2) Slip induction by pmf was accompanied by the release of approximately 0.25 mol ADP per mole of enzyme. There was no detectable detachment of F1 from FO. (3) The transmembrane voltage and the pH difference were both efficient in slip induction. Once induced, slip persisted for hours, and was only partially reverted by the addition of ADP or ATP (>1 microM). (4) There was no pmf threshold for the proton transfer through the slipping enzyme; slip could be driven both by voltage and pH difference. (5) The conduction was ohmic and weakly pH-dependent in the range from 5.5 to 9.5. The rate constant of proton transfer under slip conditions was 185 s(-1) at pH 8. Proton slip probably presents the free-wheeling of the central rotary shaft, subunit gamma, in an open structure of the (alphabeta)3 hexagon with no nucleotides in the catalytic sites.     

Molecular evolution of the modulator of chloroplast ATP synthase: origin of the conformational change dependent regulation

Chloroplast ATP synthase synthesizes ATP by utilizing a proton gradient as an energy supply, which is generated by photosynthetic electron transport. The activity of the chloroplast ATP synthase is regulated in several specific ways to avoid futile hydrolysis of ATP under various physiological conditions. Several regulatory signals such as Delta mu H(+), tight binding of ADP and its release, thiol modulation, and inhibition by the intrinsic inhibitory subunit epsilon are sensed by this complex. In this review, we describe the function of two regulatory subunits, gamma and epsilon, of ATP synthase based on their possible conformational changes and discuss the evolutionary origin of these regulation systems.     

Proton flux through the chloroplast ATP synthase is altered by cleavage of its gamma subunit

Electron transport, the proton gradient and ATP synthesis were determined in thylakoids that had been briefly exposed to a low concentration of trypsin during illumination. This treatment cleaves the γ subunit of the ATP synthase into two large fragments that remain associated with the enzyme. Higher rates of electron transport are required to generate a given value of the proton gradient in the trypsin-treated membranes than in control membranes, indicating that the treated membranes are proton leaky. Since venturicidin restores electron transport and the proton gradient to control levels, the proton leak is through the ATP synthase. Remarkably, the synthesis of ATP by the trypsin-treated membranes at saturating light intensities is only slightly inhibited even though the proton gradient is significantly lower in the treated thylakoids. ATP synthesis and the proton gradient were determined as a function of light intensity in control and trypsin-treated thylakoids. The trypsin-treated membranes synthesized ATP at lower values of the proton gradient than the control membranes. Cleavage of the γ subunit abrogates inhibition of the activity of the chloroplast ATP synthase by the ε subunit. Our results suggest that overcoming inhibition by the ε subunit costs energy.     

Function, structure and regulation of cyanobacterial and chloroplast ATP synthase

The proton-translocating ATP synthase from chloroplasts and cyanobacteria forms ATP upon photosynthetic electron transport by using the proton gradient across the thylakoid membrane. Both enzymes contain nine different subunits and from the similarity in gene organisation and the high degree of amino acid sequence homology of the subunits it appears that these ATP synthases might have a common ancestor. Both enzymes need to be activated by membrane energisation in order to perform catalytic activity but, in contrast to the chloroplast ATP synthase, that from the studied cyanobacteria (with the exception of Spirulina platensis ) shows no effect of the redox state on activation. Functionally, the cyanobacterial enzyme corresponds to the reduced form of the chloroplast ATP synthase. In the chloroplast enzyme a stretch of 9 amino acids, including two cysteines in the γ-subunit, is involved in this redox effect and this stretch is absent in cyanobacteria. With γ-mutants from the cyanobacterium Synechocystis 6803 the role of this stretch is studied. When active, both the cyanobacterial and the reduced chloroplast ATP synthase transport 4 protons per ATP synthesised and hydrolysed. This ratio may depend on the environment of the enzyme such as protein and lipid composition and pH.     

Cross-reconstitution of the F0F1-ATP synthases of chloroplasts and Escherichia coli with special emphasis on subunit delta

F0F1-ATP synthases catalyse ATP formation from ADP and Pi by using the free energy supplied by the transmembrane electrochemical potential of the proton. The delta subunit of F1 plays an important role at the interface between the channel portion F0 and the catalytic portion F1. In chloroplasts it can plug the protonic conductance of CF0 and in Escherichia coli it is required for binding of EF1 to EF0. We wanted to know whether or not delta of one species was effective between F0 and F1 of the other species and vice versa. To this end the respective coupling membrane (thylakoids, everted vesicles from E. coli) was (partially) depleted of F1 and purified F1, F1(-delta), and delta were added in various combinations to the F1-depleted membranes. The efficiency or reconstitution was measured in thylakoids via the rate of phenazinemethosulfate-mediated cyclic photophosphorylation and in E. coli everted vesicles via the degree of 9-amino-6-chloro-2-methoxyacridine fluorescence quenching. Addition of CF1 to partially CF1-depleted thylakoid vesicles restored photophosphorylation to the highest extent. CF1(-delta)+chloroplast delta, EF1, EF1(-delta)+E. coli delta were also effective but to lesser extent. CF1(-delta)+E. coli delta and EF1(-delta)+chloroplast delta restored photophosphorylation to a small but still significant extent. With F1-depleted everted vesicles prepared by repeated EDTA treatment of E. coli membranes, addition of CF1, CF1 (-delta)+chloroplast delta and CF1(-delta)+E. coli delta gave approximately half the extent of 9-amino-6-chloro-2-methoxyacridine fluorescence quenching as compared to EF1 or EF1(-delta)+E. coli delta by energization of the vesicles with NADH, while Ef1(-delta)+chloroplast delta was ineffective. All 'mixed' combinations were probably reconstitutively active only by plugging the protonic leak through the exposed F0 (structural reconstitution) rather than by catalytic activity. Nevertheless, the cross-reconstitution is stunning in view of the weak sequence similarity between chloroplast delta and E. coli delta. It favors a role of delta as a conformational transducer rather than as a proton conductor between F0 and F1.     

Chloroplast ATP synthase contains one single copy of subunit delta that is indispensable for photophosphorylation

F0F1 ATP synthases synthesize ATP in their F1 portion at the expense of free energy supplied by proton flow which enters the enzyme through their channel portion F0. The smaller subunits of F1, especially subunit delta, may act as energy transducers between these rather distant functional units. We have previously shown that chloroplast delta, when added to thylakoids partially depleted of the coupling factor CF1, can reconstitute photophosphorylation by inhibiting proton leakage through exposed coupling factor CF0. In view of controversies in the literature, we reinvestigated two further aspects related to subunit delta, namely (a) its stoichiometry in CF0CF1 and (b) whether or not delta is required for photophosphorylation. By rocket immunoelectrophoresis of thylakoid membranes and calibration against purified delta, we confirmed a stoichiometry of one delta per CF0CF1. In CF1-depleted thylakoids photophosphorylation could be reconstituted not only by adding CF1 and subunit delta but, surprisingly, also by CF1 (-delta). We found that the latter was attributable to a contamination of CF1 (-delta) preparations with integral CF1. To lesser extent CF1 (-delta) acted by complementary rebinding to CF0 channels that were closed because they contained delta [CF0(+delta)]. This added catalytic capacity to proton-tight thylakoid vesicles. The ability of subunit delta to control proton flow through CF0 and the absolute requirement for delta in restoration of photophosphorylation suggest an essential role of this small subunit at the interface between the large portions of ATP synthase: delta may be part of the coupling site between electrochemical, conformational and chemical events in this enzyme.     

Significance of the epsilon subunit in the thiol modulation of chloroplast ATP synthase

To understand the regulatory function of the gamma and epsilon subunits of chloroplast ATP synthase in the membrane integrated complex, we constructed a chimeric FoF1 complex of thermophilic bacteria. When a part of the chloroplast F1 gamma subunit was introduced into the bacterial FoF1 complex, the inverted membrane vesicles with this chimeric FoF1 did not exhibit the redox sensitive ATP hydrolysis activity, which is a common property of the chloroplast ATP synthase. However, when the whole part or the C-terminal alpha-helices region of the epsilon subunit was substituted with the corresponding region from CF1-epsilon together with the mutation of gamma, the redox regulation property emerged. In contrast, ATP synthesis activity did not become redox sensitive even if both the regulatory region of CF1-gamma and the entire epsilon subunit from CF1 were introduced. These results provide important features for the regulation of FoF1 by these subunits: (1) the interaction between gamma and epsilon is important for the redox regulation of FoF1 complex by the gamma subunit, and (2) a certain structural matching between these regulatory subunits and the catalytic core of the enzyme must be required to confer the complete redox regulation mechanism to the bacterial FoF1. In addition, a structural requirement for the redox regulation of ATP hydrolysis activity might be different from that for the ATP synthesis activity.