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.     

Derivatization of the catalytic subunits of the chloroplast ATPase by 2-azido-ATP and dicyclohexylcarbodiimide. Evidence for catalytically induced interchange of the subunits

Modifications of the catalytic beta subunits of the chloroplast ATPase (CF1-ATPase) are reported which support the proposal that all three subunits participate sequentially during catalysis. The beta subunits of the CF1-ATPase are sufficiently homogeneous to allow detection of their derivatization with dicyclohexylcarbodiimide (DCCD) or the substrate analog 2-azido-ATP by two-dimensional isoelectric focusing. Whether the DCCD reacts with the same beta subunit that tightly binds ATP has not been known. Our results show that when CF1-ATPase is covalently labeled with 2-azido-ATP followed by reaction with DCCD, different beta subunits are labeled. The DCCD labeling does not stop catalytic cooperativity of the CF1-ATPase and allows slow enzyme turnover. When the DCCD-modified enzyme catalyzes 2-azido-ATP cleavage and the enzyme with tightly bound nucleotide is photolyzed, both DCCD-modified and unmodified subunits are randomly labeled by the azido nucleotide. This result is as expected if during the catalytic cycle one beta subunit with unique properties is replaced by another subunit that gains these properties. The participation of all three subunits in the catalytic cycle is suggested by the apparent retention of catalytic cooperativity by the two remaining subunits after one subunit has already catalyzed 2-azido-ATP cleavage and been labeled.     

Pressure-induced dissociation of solubilized sarcoplasmic reticulum ATPase

The effect of hydrostatic pressure on the self-association of sarcoplasmic reticulum ATPase solubilized by nonionic detergent was studied in the pressure range of 1 atm up to 2 kilobars. Polarization of intrinsic tryptophan fluorescence or of fluorescence of a pyrene probe covalently attached to the ATPase was measured. An increase in hydrostatic pressure promoted dissociation of the protein into monomers. For a midpoint dissociation pressure of 1.3 kilobars, the standard volume change in the dissociation reaction was delta Vop = -167 ml/mol. Full reversibility of the pressure effects was shown to occur, as seen by recovery of polarization. An increase in Ca2+ concentration from 50 microM to 5 mM and of pH from 6.9 to 8.6 were found to increase the midpoint dissociation pressure, indicating that these factors stabilize the dimeric state. The hydrolytic activity of the ATPase was measured under pressure. The activity was inhibited by pressure increase. It was found that an irreversible inactivation of the solubilized enzyme occurred during turnover and that increasing pressure added to this instability. Reversibility of the activity was critically dependent on the presence of 10 mM Ca2+ in the assay medium.     

Dissociation of purified erythrocyte Ca(2+)-ATPase by hydrostatic pressure.

Subunit interactions in the Ca(2+)-ATPase from erythrocyte plasma membranes were investigated through a combination of fluorescence spectroscopy and high-pressure techniques. Application of hydrostatic pressure in the range of 1 bar to 2.4 kbar promoted full dissociation of the ATPase, as revealed by spectral shifts of the intrinsic fluorescence emission and by changes in the fluorescence polarization of dansyl-conjugated ATPase. Pressure dissociation of the ATPase displayed a dependence on protein concentration compatible with dissociation of a dimer. Calculated from pressure-dissociation curves, the standard volume change dV0 for the association of subunits was 43-50 ml/mol and K0, the dissociation constant at atmospheric pressure, was 6-9 x 10(-8) M. Addition of Ca2+ stabilized the dimeric ATPase structure against pressure dissociation, whereas addition of vanadate facilitated dissociation by pressure. These results suggest that intersubunit interactions depend on the equilibrium between the two major conformational states E1 and E2 of the ATPase. Addition of calmodulin in the presence of Ca2+ had no additional effect when compared to that observed in the presence of Ca2+ alone. This finding is interpreted in terms of the mechanism of calmodulin activation of ATPase catalysis.     

Inactivation of creatine kinase by high pressure may precede dimer dissociation.

The effects of hydrostatic pressure on creatine kinase activity and conformation were investigated using either the high-pressure stopped-flow method in the pressure range 0.1-200 MPa for the activity determination, or the conventional activity measurement and fluorescence spectroscopy up to 650 MPa. The changes in creatine kinase activity and intrinsic fluorescence show a total or partial reversibility after releasing pressure, depending on both the initial value of the high pressure applied and on the presence or absence of guanidine hydrochloride. The study on 8-anilinonaphthalene-1-sulfonate binding to creatine kinase under high pressure indicates that the hydrophobic core of creatine kinase was progressively exposed to the solvent at pressures above 300 MPa. This data shows that creatine kinase is inactivated at low pressure, preceding both the enzyme dissociation and the unfolding of the hydrophobic core occurring at higher pressure. Moreover, in agreement with the recently published structure of the dimer, it can be postulated that the multistate transitions of creatine kinase induced both by pressure and guanidine denaturation are in direct relationship with the existence of hydrogen bonds which maintain the dimeric structure of the enzyme.     

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.     

Partial proteolysis as a probe of the conformation of the gamma subunit in activated soluble and membrane-bound chloroplast coupling factor 1

Treatments that enhance the latent ATPase activity of the chloroplast coupling factor (CF1) also induce hypersensitivity of the gamma subunit toward trypsin. A number of different gamma subunit cleavage products are formed (Moroney, J. V., and McCarty, R. E. (1982) J. Biol. Chem. 257, 5910-5914). We have compared the gamma cleavage products of membrane-bound and isolated CF1, activated either by reduction of the gamma disulfide bond or by removal of the epsilon subunit. The gamma subunit of isolated CF1 lacking the epsilon subunit was cleaved to a 27,000-Da species. The same cleavage site became exposed following energy-dependent conformational changes in the membrane-bound enzyme. Activation by reduction of the gamma disulfide bond also exposed this site. However, the gamma subunit of reduced CF1 was cleaved rapidly at an additional site and trypsin treatment gave rise to a 25,000-Da gamma species. The small peptide generated by the second cleavage contains one of the cysteinyl residues of the reduced disulfide bridge of gamma. This peptide dissociates from the enzyme and can be isolated by gel filtration. The close proximity of the trypsin cleavage sites to the disulfide bond of gamma is discussed with respect to the effects of tryptic cleavage on the ATPase activity of CF1. The data indicate that structural changes in a limited region of the gamma subunit strongly influence the catalytic properties of both soluble and membrane-bound CF1.     

Inhibition of the ATPase activity of the catalytic portion of ATP synthases by cationic amphiphiles

Melittin, a cationic, amphiphilic polypeptide, has been reported to inhibit the ATPase activity of the catalytic portions of the mitochondrial (MF1) and chloroplast (CF1) ATP synthases. Gledhill and Walker [J.R. Gledhill, J.E. Walker. Inhibition sites in F1-ATPase from bovine heart mitochondria, Biochem. J. 386 (2005) 591-598.] suggested that melittin bound to the same site on MF1 as IF1, the endogenous inhibitor polypeptide. We have studied the inhibition of the ATPase activity of CF1 and of F1 from Escherichia coli (ECF1) by melittin and the cationic detergent, cetyltrimethylammonium bromide (CTAB). The Ca2+- and Mg2+-ATPase activities of CF1 deficient in its inhibitory epsilon subunit (CF1-epsilon) are sensitive to inhibition by melittin and by CTAB. The inhibition of Ca2+-ATPase activity by CTAB is irreversible. The Ca2+-ATPase activity of F1 from E. coli (ECF1) is inhibited by melittin and the detergent, but Mg2+-ATPase activity is much less sensitive to both reagents. The addition of CTAB or melittin to a solution of CF1-epsilon or ECF1 caused a large increase in the fluorescence of the hydrophobic probe, N-phenyl-1-naphthylamine, indicating that the detergent and melittin cause at least partial dissociation of the enzymes. ATP partially protects CF1-epsilon from inhibition by CTAB. We also show that ATP can cause the aggregation of melittin. This result complicates the interpretation of experiments in which ATP is shown to protect enzyme activity from inhibition by melittin. It is concluded that melittin and CTAB cause at least partial dissociation of the alpha/beta heterohexamer.     

Detergent activation of the ATPase activity of chloroplast coupling factor 1

The activation of the ATPase activity of coupling factor 1 (CF1) from chloroplasts by several detergents was studied. Further evidence that detergent micelles are important in the activation of Ca2+-ATPase was obtained. Maximal activation of CA2+-ATPase was achieved with short-chain alkyl-beta-D-glucopyranoside (alkylglucosides) detergents. Treatment of CF1 with hexylglucoside or heptylglucoside followed by hydroxylapatite chromatography caused nearly total removal of the epsilon subunit of the enzyme, whereas treatment with decylglucoside caused less ATPase activation and less loss of the epsilon subunit. The ATPase activity of detergent-activated CF1 was inhibited by purified epsilon subunit. Detergents that form small micelles appear to be most effective in removing the epsilon subunit and in activating the Ca2+-ATPase of CF1. When present during assay, the alkylglucosides also induce a Mg2+-ATPase activity in CF1. Octyl- and nonylglucoside are most effective in promoting this reaction. If, however, CF1 deficient in the epsilon subunit was used, even decylglucoside elicited rapid Mg2+-ATPase hydrolysis. It is concluded that removal of the epsilon subunit, although necessary for the expression of Mg2+-ATPase, is not sufficient. The detergents that cause maximal displacement of the epsilon subunit are less effective in inducing Mg2+-ATPase activity. The selective removal of subunits from CF1 by specific detergents points to potential problems with the use of these detergents in the solubilization of oligomeric membrane proteins.     

Stochastic high-speed rotation of Escherichia coli ATP synthase F1 sector: the epsilon subunit-sensitive rotation

The gamma subunit of the ATP synthase F(1) sector rotates at the center of the alpha(3)beta(3) hexamer during ATP hydrolysis. A gold bead (40-200 nm diameter) was attached to the gamma subunit of Escherichia coli F(1), and then its ATP hydrolysis-dependent rotation was studied. The rotation speeds were variable, showing stochastic fluctuation. The high-speed rates of 40- and 60-nm beads were essentially similar: 721 and 671 rps (revolutions/s), respectively. The average rate of 60-nm beads was 381 rps, which is approximately 13-fold faster than that expected from the steady-state ATPase turnover number. These results indicate that the F(1) sector rotates much faster than expected from the bulk of ATPase activity, and that approximately 10% of the F(1) molecules are active on the millisecond time scale. Furthermore, the real ATP turnover number (number of ATP molecules converted to ADP and phosphate/s), as a single molecule, is variable during a short period. The epsilon subunit inhibited rotation and ATPase, whereas epsilon fused through its carboxyl terminus to cytochrome b(562) showed no effect. The epsilon subunit significantly increased the pausing time during rotation. Stochastic fluctuation of catalysis may be a general property of an enzyme, although its understanding requires combining studies of steady-state kinetics and single molecule observation.     

Chemical modification and fluorescence labeling study of Ca2+,Mg2+-adenosine triphosphatase of sarcoplasmic reticulum using iodoacetamide and its N-substituted derivatives

Sarcoplasmic reticulum membrane vesicles from rabbit skeletal muscle were treated with iodoacetamide (IAA) at pH 7.0 and 30 degrees C. At 1.0 mM IAA, 1 mol of IAA per mol of ATPase peptide was bound in 1 h. Under these conditions, IAA was attached specifically to the B-tryptic fragment portion of the peptide. The binding of IAA did not affect the Ca2+-transporting activity of ATPase. Three fluorescent derivatives of iodoacetamide, 5-(2-acetamidoethyl)aminonaphthalene-1-sulfonate (IAEDANS), 5-iodoacetamido fluorescein (IAF), and 5-iodoacetamido eosin (IAE), were also tested for reactivity toward sarcoplasmic reticulum ATPase at 30 degrees C and pH 7.0. In 1 h at 50 microM concentration, each of these fluorescent labels modified ATPase to a labeling density of 1 mol per mol of ATPase. Neither IAEDANS nor IAF at this labeling density affected Ca2+-transporting activity, but IAE reduced it to 20% of the untreated control. The target site of IAEDANS at this labeling density was located exclusively on the B-fragment portion, as was the case with IAA, but IAF label was found on both A1 and B fragments after limited tryptic digestion. IAEDANS was used as a B-fragment portion-directed conformational probe of Ca2+-transport ATPase, and an increase in fluorescence intensity accompanying E1Ca-P formation was detected. The fluorescence enhancement was abolished when E1Ca-P X ADP beta S was formed by adding ADP beta S to preformed E1Ca-P. This suggests that the conformation of ATPase in the neighborhood of the IAEDANS binding site may be altered in response to the dissociation of ADP from the phosphorylated intermediate.     

Hydrostatic pressure and calcium-induced dissociation of calpains

The dissociation of mu- and m-calpains was studied by fluorescence spectroscopy under high hydrostatic pressure (up to 650 MPa). Increasing pressure induced a red shift of the tryptophan fluorescence of the calcium-free enzyme. The concentration dependence of the spectral transition was consistent with a pressure-induced dissociation of the subunits. Rising temperature increased the stability of calpain heterodimers and confirmed the predominance of hydrophobic interactions between monomers. At saturating calcium, the spectral transition was not observed for native or iodoacetamide-inactivated calpains, indicating that they were already dissociated by calcium. The reaction volume was about -150 ml mol-1 for both isoforms, and the dissociation constants at atmospheric pressure are approximately 10-12 M and 10-15 M for mu- and m-calpains, respectively. This result indicates a tighter interaction in the isoform that requires higher calcium concentration for activity.     

Inhibition of the ATPase activity of the catalytic portion of ATP synthases by cationic amphiphiles

Melittin, a cationic, amphiphilic polypeptide, has been reported to inhibit the ATPase activity of the catalytic portions of the mitochondrial (MF1) and chloroplast (CF1) ATP synthases. Gledhill and Walker [J.R. Gledhill, J.E. Walker. Inhibition sites in F1-ATPase from bovine heart mitochondria, Biochem. J. 386 (2005) 591-598.] suggested that melittin bound to the same site on MF1 as IF1, the endogenous inhibitor polypeptide. We have studied the inhibition of the ATPase activity of CF1 and of F1 from Escherichia coli (ECF1) by melittin and the cationic detergent, cetyltrimethylammonium bromide (CTAB). The Ca²⁺- and Mg²⁺-ATPase activities of CF1 deficient in its inhibitory ε subunit (CF1-ε) are sensitive to inhibition by melittin and by CTAB. The inhibition of Ca²⁺-ATPase activity by CTAB is irreversible. The Ca²⁺-ATPase activity of F1 from E. coli (ECF1) is inhibited by melittin and the detergent, but Mg²⁺-ATPase activity is much less sensitive to both reagents. The addition of CTAB or melittin to a solution of CF1-ε or ECF1 caused a large increase in the fluorescence of the hydrophobic probe, N-phenyl-1-naphthylamine, indicating that the detergent and melittin cause at least partial dissociation of the enzymes. ATP partially protects CF1-ε from inhibition by CTAB. We also show that ATP can cause the aggregation of melittin. This result complicates the interpretation of experiments in which ATP is shown to protect enzyme activity from inhibition by melittin. It is concluded that melittin and CTAB cause at least partial dissociation of the α/β heterohexamer.     

The C-terminal domain of the epsilon subunit of the chloroplast ATP synthase is not required for ATP synthesis

The epsilon subunit of the ATP synthases from chloroplasts and Escherichia coli regulates the activity of the enzyme and is required for ATP synthesis. The epsilon subunit is not required for the binding of the catalytic portion of the chloroplast ATP synthase (CF1) to the membrane-embedded part (CFo). Thylakoid membranes reconstituted with CF1 lacking its epsilon subunit (CF1-epsilon) have high ATPase activity and no ATP synthesis activity, at least in part because the membranes are very leaky to protons. Either native or recombinant epsilon subunit inhibits ATPase activity and restores low proton permeability and ATP synthesis. In this paper we show that recombinant epsilon subunit from which 45 amino acids were deleted from the C-terminus is as active as full-length epsilon subunit in restoring ATP synthesis to membranes containing CF1-epsilon. However, the truncated form of the epsilon subunit was significantly less effective as an inhibitor of the ATPase activity of CF1-epsilon, both in solution and bound to thylakoid membranes. Thus, the C-terminus of the epsilon subunit is more involved in regulation of activity, by inhibiting ATP hydrolysis, than in ATP synthesis.     

Localization of subunit C (Vma5p) in the yeast vacuolar ATPase by immuno electron microscopy

Vacuolar ATPases (V1V0 -ATPases) function in proton translocation across lipid membranes of subcellular compartments. We have used antibody labeling and electron microscopy to define the position of subunit C in the vacuolar ATPase from yeast. The data show that subunit C is binding at the interface of the ATPase and proton channel, opposite from another stalk density previously identified as subunit H [Wilkens S., Inoue T., and Forgac M. (2004) Three-dimensional structure of the vacuolar ATPase - Localization of subunit H by difference imaging and chemical cross-linking. J. Biol. Chem. 279, 41942-41949]. A picture of the vacuolar ATPase stalk domain is emerging in which subunits C and H are positioned to play a role in reversible enzyme dissociation and activity silencing.     

Sub-zero temperature inactivation of carboxypeptidase Y under high hydrostatic pressure.

High hydrostatic pressure induced cold inactivation of carboxypeptidase Y. Carboxypeptidase Y was fully active when exposed to subzero temperature at 0.1 MPa; however, the enzyme became inactive when high hydrostatic pressure and subzero temperature were both applied. When the enzyme was treated at pressures higher than 300 MPa and temperatures lower than -5 degrees C, it underwent an irreversible inactivation in which nearly 50% of the alpha-helical structure was lost as judged by circular dichroism spectral analysis. When the applied pressure was limited to below 200 MPa, the cold inactivation process appeared to be reversible. In the presence of reducing agent, this reversible phenomenon, observed at below 200 MPa, diminished to give an inactive enzyme; the agent reduces some of disulfide bridge(s) in an area of the structure that is newly exposed area because of the cold inactivation. Such an area is unavailable if carboxypeptidase Y is in its native conformation. Because all the disulfide bridges in carboxypeptidase Y locate near the active site cleft, it is suggested that the structural destruction, if any, occurs preferentially in this disulfide rich area. A possible mechanism of pressure-dependent cold inactivation of CPY is to destroy the alpha-helix rich region, which creates an hydrophobic environment. This destruction is probably a result of the reallocation of water molecules. Experiments carried out in the presence of denaturing agents (SDS, urea, GdnHCl), salts, glycerol, and sucrose led to a conclusion consistent with the idea of water reallocation.     

Mechanisms of inhibition of (Na,K)-ATPase by hydrostatic pressure studied with fluorescent probes

To investigate the mechanisms by which hydrostatic pressure inhibits (Na,K)-ATPase, we measured enzyme activity, as a function of pressure and temperature, of purified (Na,K)-ATPase from dog kidney and eel electroplax, and we monitored protein conformation, possible subunit interactions, and the fluidity of the membrane with fluorescent probes. The (Na,K)-ATPase and p-nitrophenylphosphatase activities were inhibited reversibly by pressures below 1.5 kilobars (eel enzyme) and 2.5 kilobars (dog kidney enzyme). Above these pressures, the enzymes were inactivated irreversibly. The plots of 1n(activity) versus pressure were curvilinear; this indicates that the reversible inhibition by pressure involves two or more rate-limiting steps. The calculated activation volumes varied with temperature and pressure and were larger for the (Na,K)-ATPase activity compared to the p-nitrophenylphosphatase activity. The fluorescence polarization of three hydrophobic probes decreased with increasing temperature (10-36 degrees C) and increased with increasing pressure (10(-3)-1.5 kilobars), reversibly, without any evidence of a lipid phase transition. Plots of enzyme activity versus fluorescence polarization of the lipid probes showed an inverse relationship; this indicates that enzyme activity was directly related to the fluidity of the membrane as measured by the lipid probes. Pressure had no effect on the fluorescence polarization of two cardiac glycoside probes nor on the efficiency of resonance energy transfer between either donor and acceptor cardiac glycosides specifically bound to the ouabain sites of different alpha-subunits, or tryptophan and the bound cardiac glycoside probe. These results suggest that dissociation of dimeric alpha-subunits is not related to the inhibition by pressure, and that the cardiac glycoside-complexed enzyme conformation is stabilized by pressure. It is concluded that increased pressure decreases the membrane fluidity which hinders conformational transitions associated with rate-limiting steps of the (Na,K)-ATPase reaction. It is proposed that ion-bound or -occluded forms of (Na,K)-ATPase are stabilized by pressure because they occupy a smaller volume.     

Subunit interactions within the chloroplast ATP synthase (CF0-CF1) as deduced by specific depletion of CF0 polypeptides

The proton-linked ATP synthase (CF1-CF0) of chloroplasts consists of a catalytic component (CF1) and a membrane-embedded part (CF0) that interacts with CF1 and contains a proton channel. The subunits of CF0 which are involved in binding of CF1 were studied by examining the effect of selective depletion of subunits I, II, and IV of CF0 from the chloroplast ATP synthase on the association of the remaining CF0 subunits with CF1. Dissociated CF0 subunits were identified by sucrose density gradient centrifugation. Removal of subunit IV alone from CF0-CF1 did not cause dissociation of the other CF0 subunits from CF1. Upon removal of both subunits I and IV from CF0-CF1, subunit II also dissociated, but subunit III was still bound to CF1. Thus, at least two subunits of CF0, I and III, directly associate with CF1. Subunit II is unlikely to bind CF1 directly and may associate with subunit I. Although depletion of subunit IV does not cause dissociation of CF0 from CF1, its interaction with CF1 subunits is uncertain.     

Involvement of sulfhydryl groups in the activation mechanism of the ATPase activity of chloroplast coupling factor 1

Activation of the ATPase activity and the exposition of a new adenine nucleotide binding site of chloroplast coupling factor 1 (CF1) by dithioerythritol at 25 degrees C were reversed by oxidants. The ATPase activity elicited by heat (63 degrees C, 4 min) was slightly inhibited by oxidants and was partially additive with the activity induced by dithioerythritol. Titration of the thiols of CF1 and determination of their subunit distribution before and after activation by dithioerythritol show an increase of the free groups from 8 to 10 with the appearance of the 2 new thiols on the gamma subunit. These thiols were available to reagents in nondenatured enzyme and were reoxidized to a disulfide bond by iodosobenzoate or CuCl2. It is concluded that the mechanisms of CF1 activation by dithioerythritol and by heat are different and that the former involves a net reduction of a disulfide bond of the gamma subunit.