Immunological and chemical characterization of rat liver cytochrome c oxidase

Rat liver cytochrome c oxidase (ferrocytochrome c: oxygen oxidoreductase; EC 1.9.3.1) was separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis into 12 different polypeptide chains. Specific antisera against the holoenzyme and against purified subunits IV and VIII were used to characterize the enzyme complex. The antiserum against subunit IV precipitates from sodium dodecyl sulfate-dissociated mitochondria only subunit IV and from Triton X-100-dissolved mitochondria all 12 polypeptide chains, indicating their integral location within the enzyme complex. Different antisera against the holoenzyme only precipitate subunits IV, V and VIb from sodium dodecyl sulfate-dissociated mitochondria, suggesting the location of these subunits on the surface layer of the complex. Subunit VIII is thought to be located within the complex, since a specific antiserum does not precipitate the complex. The amino acid composition of all 12 protein subunits is different, thus excluding their origin from proteolytic degradation. The proteolytic degradation of subunit IV into IV during isolation of the enzyme was corroborated by the very similar amino acid composition of both proteins.     

The transmembrane domain of subunit b of the Escherichia coli F1F(O) ATP synthase is sufficient for H(+)-translocating activity together with subunits a and c.

Subunit b is indispensable for the formation of a functional H(+)-translocating F(O) complex both in vivo and in vitro. Whereas the very C-terminus of subunit b interacts with F(1) and plays a crucial role in enzyme assembly, the C-terminal region is also considered to be necessary for proper reconstitution of F(O) into liposomes. Here, we show that a synthetic peptide, residues 1-34 of subunit b (b(1-34)) [Dmitriev, O., Jones, P.C., Jiang, W. & Fillingame, R.H. (1999) J. Biol. Chem.274, 15598-15604], corresponding to the membrane domain of subunit b was sufficient in forming an active F(O) complex when coreconstituted with purified ac subcomplex. H(+) translocation was shown to be sensitive to the specific inhibitor N,N'-dicyclohexylcarbodiimide, and the resulting F(O) complexes were deficient in binding of isolated F(1). This demonstrates that only the membrane part of subunit b is sufficient, as well as necessary, for H(+) translocation across the membrane, whereas the binding of F(1) to F(O) is mainly triggered by C-terminal residues beyond Glu34 in subunit b. Comparison of the data with former reconstitution experiments additionally indicated that parts of the hydrophilic portion of the subunit b dimer are not involved in the process of ion translocation itself, but might organize subunits a and c in F(O) assembly. Furthermore, the data obtained functionally support the monomeric NMR structure of the synthetic b(1-34).     

Molecular models of the structural arrangement of subunits and the mechanism of proton translocation in the membrane domain of F(1)F(0) ATP synthase

Subunit c of the proton-transporting ATP synthase of Escherichia coli forms an oligomeric complex in the membrane domain that functions in transmembrane proton conduction. The arrangement of subunit c monomers in this oligomeric complex was studied by scanning mutagenesis. On the basis of these studies and structural information on subunit c, different molecular models for the potential arrangement of monomers in the c-oligomer are discussed. Intersubunit contacts in the F(0) domain that have been analysed in the past by chemical modification and mutagenesis studies are summarised. Transient contacts of the c-oligomer with subunit a might play a crucial role in the mechanism of proton translocation. Schematic models presented by several authors that interpret proton transport in the F(0) domain by a relative rotation of the c-subunit oligomer against subunit a are reviewed against the background of the molecular models of the oligomer.     

Regulation of the F0F1-ATP synthase: the conformation of subunit epsilon might be determined by directionality of subunit gamma rotation

F(0)F(1)-ATP synthase couples ATP synthesis/hydrolysis with transmembrane proton transport. The catalytic mechanism involves rotation of the gamma epsilon c(approximately 10)-subunits complex relative to the rest of the enzyme. In the absence of protonmotive force the enzyme is inactivated by the tight binding of MgADP. Subunit epsilon also modulates the activity: its conformation can change from a contracted to extended form with C-terminus stretched towards F(1). The latter form inhibits ATP hydrolysis (but not synthesis). We propose that the directionality of the coiled-coil subunit gamma rotation determines whether subunit epsilon is in contracted or extended form. Block of rotation by MgADP presumably induces the extended conformation of subunit epsilon. This conformation might serve as a safety lock, stabilizing the ADP-inhibited state upon de-energization and preventing spontaneous re-activation and wasteful ATP hydrolysis. The hypothesis merges the known regulatory effects of ADP, protonmotive force and conformational changes of subunit epsilon into a consistent picture.     

Identification of immunodominant epitope of F1 antigen of Yersinia pestis

The F1 antigen of Yersinia pestis has been identified as one of the major protective antigens of this bacterium. The present study aims to delineate major and minor antigenic sites of F1 antigen. Using algorithmic predictions, five peptide sequences (P1, P2, P3, P4 and P5) spanning the C-terminal region were identified and synthesized. Antibodies were generated in mice against the peptides, native F1 protein and polymerized F1 antigen using liposomes as mode of immunization. Cross-reactivity between F1 antigen and peptides was tested using both solid and solution phase assays. Similar assays were done with rabbit anti-F1 sera. Competitive inhibition assays using a different combination of antisera and competing antigen identified P2 peptide FFVRSIGSKGGKLAAGKYTDAVTV (142-165) as the immunodominant sequence. The results indicate that this sequence appears to be exposed on the surface of F1 molecule. In a solid phase binding assay, P2 peptide was recognized even at high F1 antisera dilution. However, when antisera raised to different peptides were tested for binding to F1 antigen, antisera to P4 peptide showed maximal immunoreactivity. This implies more accessibility of this region during immobilization on solid surface. There was consistency in the results obtained for different strains of mice as well as for the rabbit antisera. Such a sequence of F1 antigen, which is recognized widely in animals of different genetic background, would be useful for diagnosis and subunit vaccine.     

F0 part of the ATP synthase from Escherichia coli. Influence of subunits a, and b, on the structure of subunit c

Four different sets of proteoliposomes were prepared from F0, subunit c, a complex of subunits a and c (ac complex) and an ac complex supplemented with subunit b. Only liposomes containing intact F0 or all subunits of F0 were active in proton translocation and F1 binding [Schneider, E. and Altendorf, K. (1985) EMBO J. 4, 515-518]. The conformation of subunit c in the different preparations was analyzed by labelling the proteoliposomes with the hydrophobic photoactivatable reagent 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine ([125I]TID). Subsequent isolation and Edman degradation of this polypeptide revealed distinct radioactive labelling patterns over the entire amino acid sequence. In the F0 complex and in the ac complex subunit c retains a labelling pattern which is related to that found in TID-labelled membrane vesicles of Escherichia coli [Hoppe et al. (1984) Biochemistry 23, 5610-5616]. In the absence of subunit a, considerably more and different amino acid residues of subunit c are modified. The labelling data are discussed in relation to structural aspects of F0 and functional properties of proteoliposomes reconstituted with F0 or individual subunits.     

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.     

The ATP synthase of Escherichia coli: structure and function of F(0) subunits

In this review we discuss recent work from our laboratory concerning the structure and/or function of the F(0) subunits of the proton-translocating ATP synthase of Escherichia coli. For the topology of subunit a a brief discussion gives (i) a detailed picture of the C-terminal two-thirds of the protein with four transmembrane helices and the C terminus exposed to the cytoplasm and (ii) an evaluation of the controversial results obtained for the localization of the N-terminal region of subunit a including its consequences on the number of transmembrane helices. The structure of membrane-bound subunit b has been determined by circular dichroism spectroscopy to be at least 75% alpha-helical. For this purpose a method was developed, which allows the determination of the structure composition of membrane proteins in proteoliposomes. Subunit b was purified to homogeneity by preparative SDS gel electrophoresis, precipitated with acetone, and redissolved in cholate-containing buffer, thereby retaining its native conformation as shown by functional coreconstitution with an ac subcomplex. Monoclonal antibodies, which have their epitopes located within the hydrophilic loop region of subunit c, and the F(1) part are bound simultaneously to the F(0) complex without an effect on the function of F(0), indicating that not all c subunits are involved in F(1) interaction. Consequences on the coupling mechanism between ATP synthesis/hydrolysis and proton translocation are discussed.     

Organization of the F0 sector of Escherichia coli H+-ATPase: the polar loop region of subunit c extends from the cytoplasmic face of the membrane

The membrane-spanning F0 sector of the Escherichia coli H+-transporting ATP synthase (EC 3.6.1.34) contains multiple copies of subunit c, a 79 amino acid residue protein that is thought to insert in the membrane like a hairpin with two membrane traversing alpha-helices. The center of the protein is much more polar than the putative transmembrane alpha-helices and has been postulated to play a crucial role in coupling H+ translocation through F0 to ATP synthesis in the membrane extrinsic, F1 sector of the complex. However, the direction of insertion of subunit c in the membrane has not been established. We show here that the "polar loop" lies on the F1 binding side of the membrane. A peptide corresponding to Lys34----Ile46 of the polar loop was synthesized. Antisera were generated to the Lys34----Ile46 cognate peptide, and the polyclonal antipeptide IgG was shown to bind to a crude F0 fraction by using enzyme-linked immunosorbent assays. The antipeptide serum did not bind tightly enough to F0 to disrupt function. However, a polyclonal antiserum made to purified, whole subunit c was shown to block the binding of F1 to the F0 exposed in F1-stripped membranes. Incubation of the antisubunit c serum with the peptide reduced the inhibitory effect of the antiserum on the binding of F1 to F0. The reversal of inhibition by the peptide was specific to the antisubunit c serum in that the peptide had no effect on inhibition of F1 binding to F0 by antiserum to subunit a of F0.(ABSTRACT TRUNCATED AT 250 WORDS)     

F1F0-ATPase from Escherichia coli with mutant F0 subunits. Partial purification and immunoprecipitation of F1F0 complexes

Previously identified mutations in subunits a and b of the F0 sector of the F1F0-ATPase from Escherichia coli are further characterized by isolating detergent-solubilized, partially purified F1F0 complexes from cells bearing these mutations. The composition of the various F1F0 complexes was judged by quantitating the amount of each subunit present in the detergent-solubilized preparations. The composition of the F0 sectors containing altered polypeptides was determined by quantitating the F0 subunits that were immunoprecipitated by antibodies directed against the F1 portion. In this way, the relative amounts of F0 subunits (a, b, c) which survived the isolation procedure bound to F1 were determined for each mutation. This analysis indicates that both missense mutations in subunit a (aser206----leu and ahis245----tyr) resulted in the isolation of F1F0 complexes with normal subunit composition. The nonsense mutation in subunit a (atyr235----end) resulted in isolation of a complex containing the b and c subunits. The bgly131----asp mutation in the b subunit results in an F0 complex which does not assemble or survive the isolation. The isolated F1F0 complex containing the mutation bgly9----asp in the b subunit was defective in two regards: first, a reduction in F1 content relative to F0 and second, the absence of the a subunit. Immunoprecipitations of this preparation demonstrated that F1 interacts with both c and mutant b subunits. A strain carrying the mutation, bgly9----asp, and the compensating suppressor mutation apro240----leu (previously shown to be partially unc+) yielded an F1F0 ++ complex that remained partially defective in F1 binding to F0 but normal in the subunit composition of the F0 sector. The assembly, structure, and function of the F1F0-ATPase is discussed.     

H+-ATPase activity of Escherichia coli F1F0 is blocked after reaction of dicyclohexylcarbodiimide with a single proteolipid (subunit c) of the F0 complex

Dicyclohexylcarbodiimide (DCCD) specifically inhibits the F1F0-H+-ATP synthase complex of Escherichia coli by covalently modifying a proteolipid subunit that is embedded in the membrane. Multiple copies of the DCCD-reactive protein, also known as subunit c, are found in the F1F0 complex. In order to determine the minimum stoichiometry of reaction, we have treated E. coli membranes with DCCD, at varying concentrations and for varying times, and correlated inhibition of ATPase activity with the degree of modification of subunit c. Subunit c was purified from the membrane, and the degree of modification was determined by two methods. In the "specific radioactivity" method, the moles of [14C]DCCD per total mole of subunit c was calculated from the radioactivity incorporated per mg of protein, and conversion of mg of protein to mol of protein based upon amino acid analysis. In the "high performance liquid chromatography (HPLC) peak area" method, the DCCD-modified subunit c was separated from unmodified subunit c on an anion exchange AX300 HPLC column, and the areas of the peaks from the chromatogram quantitated. The shape of the modification versus inhibition curve indicated that modification of a single subunit c per F0 was sufficient to abolish ATPase activity. The titration data were fit by nonlinear regression analysis to a single hit mathematical model, A = Un(1 - r) + r, where A is the relative activity, U is the ratio of unmodified/total subunit c, n is the number of subunit c per F0, and r is a residual fraction of ATPase activity that was resistant to inhibition by DCCD. The two methods gave values for n equal to 10 by the specific radioactivity method and 14 by the HPLC peak area method, and values for r of 0.28 and 0.30, respectively. Most of the r value was accounted for by the observed dissociation of 15-20% of the F1-ATPase from the membrane under ATPase assay conditions. When the minimal, experimentally justified value of r = 0.15 was used in the equation above, the calculated values of n were reduced to 8 and 11, respectively. The value of n determined here, with a probable range of uncertainty of 8-14, is consistent with, and provides an independent type of experimental support for, the suggested stoichiometry of 10 +/- 1 subunit c per F1F0, which was determined by a more precise radiolabeling method (Foster, D. L., and Fillingame, R. H. (1982) J. Biol. Chem. 257, 2009-2015).     

Both rotor and stator subunits are necessary for efficient binding of F1 to F0 in functionally assembled Escherichia coli ATP synthase

In F1F0-ATP synthase, the subunit b2delta complex comprises the peripheral stator bound to subunit a in F0 and to the alpha3beta3 hexamer of F1. During catalysis, ATP turnover is coupled via an elastic rotary mechanism to proton translocation. Thus, the stator has to withstand the generated rotor torque, which implies tight interactions of the stator and rotor subunits. To quantitatively characterize the contribution of the F0 subunits to the binding of F1 within the assembled holoenzyme, the isolated subunit b dimer, ab2 subcomplex, and fully assembled F0 complex were specifically labeled with tetramethylrhodamine-5-maleimide at bCys64 and functionally reconstituted into liposomes. Proteoliposomes were then titrated with increasing amounts of Cy5-maleimide-labeled F1 (at gammaCys106 and analyzed by single-molecule fluorescence resonance energy transfer. The data revealed F1 dissociation constants of 2.7 nm for the binding of F0 and 9-10 nm for both the ab2 subcomplex and subunit b dimer. This indicates that both rotor and stator components of F0 contribute to F1 binding affinity in the assembled holoenzyme. The subunit c ring plays a crucial role in the binding of F1 to F0, whereas subunit a does not contribute significantly.     

Interaction with monomeric subunit c drives insertion of ATP synthase subunit a into the membrane and primes a-c complex formation

Subunit a is the main part of the membrane stator of the ATP synthase molecular turbine. Subunit c is the building block of the membrane rotor. We have generated two molecular fusions of a and c subunits with different orientations of the helical hairpin of subunit c. The a/c fusion protein with correct orientation of transmembrane helices was inserted into the membrane, and co-incorporated into the F(0) complex of ATP synthase with wild type subunit c. The fused c subunit was incorporated into the c-ring tethering the ATP synthase rotor to the stator. The a/c fusion with incorrect orientation of the c-helices required wild type subunit c for insertion into the membrane. In this case, the fused c subunit remained on the periphery of the c-ring and did not interfere with rotor movement. Wild type subunit a inserted into the membrane equally well with wild type subunit c and c-ring assembly mutants that remained monomeric in the membrane. These results show that interaction with monomeric subunit c triggers insertion of subunit a into the membrane, and initiates formation of the a-c complex, the ion-translocating module of the ATP synthase. Correct assembly of the ATP synthase incorporating topologically correct fusion of subunits a and c validates using this model protein for high resolution structural studies of the ATP synthase proton channel.     

The F0 complex of the ATP synthase of Escherichia coli contains a proton pathway with large proton polarizability caused by collective proton fluctuation.

The F0 complex of the Escherichia coli ATP synthase embedded into cardiolipin liposomes was studied by FT-IR spectroscopy. For comparison, respective studies were performed with dried F0 liposomes and with F0 liposomes treated with N,N'-dicyclohexyl-carbodiimide (DCCD), which binds to Asp-61 of subunit c. Furthermore, the effect of H2O-->D2O exchange on the infrared spectrum was investigated. With F0 liposomes an infrared continuum is observed beginning at about 3000 cm-1 and extending toward smaller wavenumbers. In the DCCD-treated sample, this continuum is no longer observed. It vanishes also with drying of the liposomes. After H2O-->D2O exchange, this infrared continuum begins at about 2350 cm-1 and is less intense. All of these results demonstrate that a proton pathway in native F0 is present, in which the protons are shifted in a hydrogen-bonded chain with large proton polarizability due to collective proton tunneling. With the D2O-hydrated system, deuteron polarizability due to collective deuteron motion is observed, but the polarizability due to collective deuteron motion is smaller. Such pathways are very efficient, because they conduct protons or deuterons within picoseconds. These pathways lose their polarizability if the F0 complex is blocked by DCCD or if the liposomes are dried. On the basis of our results on the proton polarizability of hydrogen bonds and hydrogen-bonded systems and on the basis of structural data from the literature, the nature of the proton pathway of the F0 complex of E. coli is discussed.     

An intermediate step in the evolution of ATPases--the F1F0-ATPase from Acetobacterium woodii contains F-type and V-type rotor subunits and is capable of ATP synthesis

Previous preparations of the Na(+) F(1)F(0)-ATP synthase solubilized by Triton X-100 lacked some of the membrane-embedded motor subunits [Reidlinger J & Müller V (1994) Eur J Biochem233, 275-283]. To improve the subunit recovery, we revised our purification protocol. The ATP synthase was solubilized with dodecylmaltoside and further purified to apparent homogeneity by chromatographic techniques. The preparation contained, along with the F(1) subunits, the entire membrane-embedded motor with the stator subunits a and b, and the heterooligomeric c ring, which contained the V(1)V(0)-like subunit c(1) and the F(1)F(0)-like subunits c(2) and c(3). After incorporation into liposomes, ATP synthesis could be driven by an electrochemical sodium ion potential or a potassium ion diffusion potential, but not by a sodium ion potential. This is the first demonstration that an ATPase with a V(0)-F(0) hybrid motor is capable of ATP synthesis.     

Antibodies to liposomal phosphatidylserine and phosphatidic acid

Polyclonal antisera to phosphatidylserine or phosphatidic acid were induced in rabbits by injecting liposomes containing phosphatidylserine or phosphatidic acid and lipid A. Adsorption of antisera with liposomes containing different phospholipids revealed that some degree of reactivity with one or more phospholipids other than the immunizing phospholipid was often observed. However, cross-reactivity with other phospholipids was not a universal phenomenon, and one antiserum to phosphatidylserine failed to cross-react (i.e., was not adsorbed) with liposomes containing other phospholipids. All of the antisera were inhibited by soluble phosphorylated haptens (e.g., phosphocholine but not choline), but one of the antisera to phosphatidylserine was inhibited both by phosphoserine and by serine alone. Liposomal membrane composition influenced the activity of antiserum to phosphatidylserine. Regardless of whether unsaturated (beef brain) or saturated (dimyristoyl) phosphatidylserine was used in the immunizing liposomes, the antisera reacted more vigorously with liposomes containing unsaturated than saturated phosphatidylserine. We conclude that liposomes containing lipid A can serve as vehicles for stimulating polyclonal antisera to phosphatidylserine and phosphatidic acid. Although cross-reactivity with certain other phospholipids can be observed, sera from selected animals apparently can exhibit a high degree of specific activity to the immunizing phospholipid antigen.     

ATP synthetase (F1F0) of Escherichia coli K-12. High-yield preparation of functional F0 by hydrophobic affinity chromatography

1. The purified ATP synthetase complex (F1F0) from Escherichia coli was adsorbed to immobilized poly-(L-lysine)-deoxycholic acid. About 0.7 mg F1F0 were bound per ml of settled gel. The hydrophilic F1 part was dissociated from the complex by treatment with 7 M urea. F0 was eluted in high yield either with deoxycholate (6 mM) or taurodeoxycholate (10 mM). About 14% of the total protein bound to the column was eluted as F0, which corresponds to 64% of the total F0 in the F1F0 complex. 2. The purified F0 preparation obtained was composed of three different kinds of subunits with apparent molecular weights of 24000 (a), 19000 (b) and 8300 (c), respectively as determined by sodium dodecyl sulfate gel electrophoresis. 3. After incorporation into liposomes and the generation of a potassium diffusion potential by valinomycin, the F0 preparation mediated H+ translocation. This H+ uptake is inhibited by either dicyclohexylcarbodiimide or purified F1 ATPase. 4. Incubation of F0-containing liposomes with F1 led to the reconstitution of an ATP-driven quenching of acridine-dye fluorescence. The quenching was abolished by uncoupler and prevented by dicyclohexylcarbodiimide.     

The production of F41 fimbriae by piglet strains of enterotoxigenic Escherichia coli that lack K88, K99 and 987P fimbriae

The enterotoxigenic Escherichia coli strains 1676, 1706, 1751 and KEC96a, which do not produce fimbrial adhesive antigens of the K88, K99 or 987P antigen type reacted both in vitro and in vivo with antiserum to F41 fimbriae in an indirect immunofluorescent antibody technique. Antiserum used to demonstrate material B, an adhesive antigen thought to mediate the adhesive and mannose-resistant (MR) haemagglutinating properties of E. coli strains 1676, 1706 and 1751, reacted in vitro with an F41+ strain. The antiserum also inhibited the MR haemagglutinating activity of F41 antigen and gave an anionic precipitation line in immunoelectrophoresis experiments with an extract containing F41 antigen. The MR haemagglutinating properties of an antigen extract containing material B from E. coli strain 1706 was neutralized by antiserum to F41 fimbriae and by OK antisera to E. coli strains that produce both F41 and K99 fimbriae. These sera also gave an anionic precipitation line with the MR haemagglutinin from E. coli strain 1706 and the MR haemagglutinin gave a line of identity with F41 in gel diffusion experiments with antiserum to F41 fimbriae. OK antisera to K99+ F41- bacteria and OK antisera to K88+ bacteria and 987P+ bacteria did not react with this haemagglutinin. Transmission electron microscopy on the ileum of newborn gnotobiotic piglets infected with E. coli strain 1706 showed irregular, poorly defined filamentous material surrounding some,though not all, bacteria but regular fimbrial structures were not visible.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cross-linking and labeling of the Escherichia coli F1F0-ATP synthase reveal a compact hydrophilic portion of F0 close to an F1 catalytic subunit

The subunit arrangement of the F0 sector of the Escherichia coli ATP synthase is examined using hydrophilic and hydrophobic (cleavable) cross-linking reagents and the water-soluble labeling reagent [35S] diazoniumbenzenesulfonate ( [35S]DABS). Cross-linking is performed on purified ATP synthase and inverted minicell membranes. ATP synthase incorporated into liposomes is labeled with [35S]DABS. Three cross-linked products involving the F0 subunits (a, b, and c) are observed with the purified ATP synthase in solution: a-b, b2, and c2 dimers. A cross-link between the F0 and F1 is detected and occurs between the a and beta subunits. A cross-linker independent association between the b and beta subunits is also evident, suggesting that the two subunits are close enough to form a disulfide bridge. A cross-linking reagent stable to reducing agents produces a b-beta dimer, as detected by immunoblotting with anti-beta serum. The c subunit does not cross-link with any F1 polypeptide. Minicell membranes containing ATP synthase polypeptides radioactively labeled in vivo similarly show b2 and c2 dimers after cross-linking. [35S]DABS labels the a and b, but not c, subunits, showing that the a and b, but not c, subunits possess hydrophilic domains. Thus, certain domains of subunits a and b extend from the membrane and are in close proximity to one another and the F1 catalytic subunit beta.     

Structural and functional relationship of ATP synthases (F1F0) from Escherichia coli and the thermophilic bacterium PS3

Functional compatibility between the F1 and F0 parts of ATP synthases from Escherichia coli (EF1F0) and the thermophilic bacterium PS3 (TF1F0) was analyzed. F1-stripped everted membrane vesicles from both organisms bound the homologous or heterologous F1 part to the same extent. Titration of the reconstituted membrane vesicles with dicyclohexylcarbodiimide revealed a similar sensitivity of the homologous and hybrid F1F0 complexes towards the inhibitor. Furthermore, the heterologous enzymes exhibited ATP-dependent H+ translocation comparable to that of homologous F1F0. Antisera raised against EF1 or subunits a, b, and c of EF0 were analyzed for cross-reactivity with TF1 and TF0. Common antigenic sites have been detected with immunoblot analysis for subunit beta and subunit c of EF1F0 and the corresponding subunits from TF1F0. A weak binding of the anti-a and anti-b antisera with the TF0 part has been observed in an enzyme-linked immunosorbent assay. Based on these findings the structural and functional relationship between the mesophilic and thermophilic ATP synthase complexes is discussed.