Non-covalently bound adenine nucleotides in adenosine triphosphatase of Escherichia coli

3'-O-(4-Benzoyl)benzoyladenosine 5'-triphosphate inhibits activity of the vacuolar (H+)-ATPase from bovine brain clathrin-coated vesicles by modification of a rapidly exchangeable, noncatalytic nucleotide binding site on the B subunit

It was previously observed that the B subunit of the tonoplast V-ATPase is modified by the photoactivated nucleotide analog 3'-O-(4-benzoyl)benzoyladenosine 5'-triphosphate (BzATP) (Manolson, M. F., Rea, P. A., and Poole, R. J. (1985) J. Biol. Chem. 260, 12273-12279). We have further characterized the nucleotide binding sites on the V-ATPase and the interaction between BzATP and the B subunit. We observe that the V-ATPase isolated from bovine clathrin-coated vesicles possesses approximately 1 mol of endogenous, tightly bound ATP/mol of V-ATPase complex. BzATP is not a substrate for the V-ATPase, but does act as a noncovalent inhibitor in the absence of irradiation, changing the kinetic characteristics of ATP hydrolysis. Irradiation of the V-ATPase in the presence of [3H]BzATP results primarily in modification of the 58-kDa B subunit, with complete inhibition of V-ATPase activity occurring upon modification of one B subunit per V-ATPase complex. Inhibition occurs as the result of modification of a rapidly (t1/2 < 2 min) exchangeable site, and yet this site does not correspond to a catalytic site, as indicated by the effects of cysteine-modifying reagents which react with Cys254 located at the catalytic sites on the A subunit. Thus, the noncatalytic nucleotide binding site modified by BzATP appears to be rapidly exchangeable. The site of [3H]BzATP modification of the B subunit was localized to the region Ile164 to Gln171, which from the x-ray crystal structure of the homologous F-ATPase alpha subunit, is within 10 A of the ribose ring of ATP bound to the noncatalytic nucleotide binding site. Thus, despite the absence of a glycine-rich loop region in the B subunit, these data are consistent with a similar overall folding pattern for the V-ATPase B subunit and the F-ATPase alpha subunit.

Changes in the adenine nucleotide and inorganic phosphate content of Escherichia coli F1-ATPase during ATP synthesis in dimethyl sulphoxide

Escherichia coli F1-ATPase contained 2.9 +/- 0.1 mol of adenine nucleotide and 3.1 +/- 0.3 mol of Pi/mol of enzyme. After preincubation with ATP, the nucleotide and phosphate contents were 5.6 and 6.0 +/- 0.5 mol/mol of enzyme respectively. The F1-ATPase was induced to synthesize ATP in the presence of 30% (v/v) dimethyl sulphoxide (Me2SO). The ATP originated from endogenous bound ADP. The bound adenine nucleotide and Pi contents of the enzyme during the time course of ATP synthesis were investigated by using F1-ATPase which had been preincubated with ATP. We show that the process of ATP synthesis in Me2SO involves (i) an initial rapid loss of nucleotide from the enzyme, the process being facilitated by exogenous Pi, (ii) a rapid loss of Pi from the enzyme, at least in the absence of exogenous Pi, (iii) re-binding of a portion of the lost nucleotide, and (iv) synthesis of ATP from bound ADP and exogenous Pi. It is proposed that transfer of the F1-ATPase to the Me2SO medium induces a change in the conformation of the enzyme to a form favouring ATP synthesis.

Molecular genetics of F1-ATPase from Escherichia coli

We have reviewed recent molecular biological studies on F1-ATPase of Escherichia coli and emphasized the advantages of using the bacterium in studies on this important enzyme. All subunits had homologies of varied degrees with those from other organisms. Mutations of F1 subunits caused defects in catalysis and assembly. Defects of the mutant enzymes were studied extensively together with the determination of the amino acid substitutions. Extensive molecular biological studies may help greatly in understanding the normal mechanism and assembly of the complex.

Effect of disulfide cross-linking between alpha and delta subunits on the properties of the F1 adenosine triphosphatase of Escherichia coli

Under very mild oxidizing conditions the delta subunit of the F1-ATPase of Escherichia coli can be crosslinked by a disulfide linkage to one of the alpha subunits of the enzyme. The cross-linked ATPase resembles the native enzyme in the following properties: specific activity; activation by lauryldimethylamine N-oxide (LDAO); binding of aurovertin D and ADP; cross-linking products with 3,3'-dithiobis(succinimidyl propionate); binding to ATPase-stripped everted membrane vesicles and the N,N'-dicyclohexylcarbodiimide sensitivity of the rebound enzyme. However, the rebound crosslinked ATPase differed from the native enzyme in lacking the ability to restore NADH oxidation - and ATP hydrolysis-dependent quenching of the fluorescence of quinacrine to ATPase-stripped membrane vesicles. It is proposed that the delta subunit is involved in the proton pathway of the ATPase, and that this pathway is affected in the alpha delta-cross-linked enzyme. The mechanism for activation of the ATPase by LDAO was examined. Evidence against the proposal of Lötscher, H.-R., De Jong, C. and Capaldi, R.A. (Biochemistry (1984) 23, 4140-4143) that activation involves displacement of the epsilon subunit from an active site on a beta subunit was obtained.

Catalytic properties of the Escherichia coli proton adenosinetriphosphatase: evidence that nucleotide bound at noncatalytic sites is not involved in regulation of oxidative phosphorylation

Nucleotide-depleted F1-ATPase from Escherichia coli was reconstituted with F1-depleted membranes and shown to catalyze high rates of oxidative phosphorylation of ADP and GDP. Adenine nucleotide became bound to the nonexchangeable nucleotide sites on membrane-bound F1 during ATP synthesis, but binding of guanine nucleotides to nonexchangeable sites during GTP synthesis was not detectable. It was possible to reload the nonexchangeable sites on nucleotide-depleted F1 with radioactive adenine nucleotide prior to membrane reconstitution. The radioactive adenine nucleotide did not exchange significantly during oxidative phosphorylation of ADP or GDP. The amount of nonexchangeable adenine nucleotide found in membrane-bound F1 was the same when the nonexchangeable sites were reloaded either prior to membrane reconstitution of the F1 or after membrane reconstitution with nucleotide-free F1 followed by a burst of oxidative phosphorylation of ADP. The results showed that occupation of the nonexchangeable sites on F1 by tightly bound nucleotide is not required for oxidative phosphorylation of GDP (a physiological activity of F1 in the bacterial cell). Also, the results confirm directly that the adenine-specific nonexchangeable sites on F1 are noncatalytic sites. Using this experimental approach, it was possible to look for a regulatory effect of the nonexchangeable nucleotide on oxidative phosphorylation. Nucleotide-depleted F1 was first reloaded with (i) ATP, (ii) ADP, (iii) 5'-adenylyl imidodiphosphate, or (iv) zero nucleotide, and was then reconstituted with F1-depleted membranes. The reconstituted membranes were compared in respect to rates of oxidative phosphorylation of GDP and Km values of GDP and Pi. No regulatory role for the nonexchangeable nucleotide was evident.(ABSTRACT TRUNCATED AT 250 WORDS)

Specificity of the proton adenosinetriphosphatase of Escherichia coli for adenine, guanine, and inosine nucleotides in catalysis and binding

Specificity of the Escherichia coli proton ATPase for adenine, guanine, and inosine nucleotides in catalysis and binding was studied. MgADP, CaADP, MgGDP, and MgIDP were each good substrates for oxidative phosphorylation. The corresponding triphosphates were each substrates for hydrolysis and proton pumping. At 1 mM concentration, MgATP, MgGTP, and MgITP drove proton pumping with equal efficiency. At 0.1 mM concentration, MgATP was 4-fold more efficient than MgITP or MgGTP. Nucleotide-depleted soluble F1 could rebind to F1-depleted membranes and block proton conductivity through F0; rebound nucleotide-depleted F1 catalyzed pH gradient formation with MgATP, MgGTP, or MgITP. This showed that the nonexchangeable nucleotide sites on F1 need not be occupied by adenine nucleotide for proton pumping to occur. It was further shown that no nucleotide was tightly bound in the nonexchangeable sites of F1 during proton pumping driven by MgGTP in these reconstituted membranes, whereas adenine nucleotide was tightly bound when MgATP was the substrate. Nucleotide-depleted soluble F1 bound maximally 5.9 ATP, 3.2 GTP, and 3.6 ITP of which half the ATP and almost all of the GTP and ITP exchanged over a period of 30-240 min with medium ADP or ATP. Also, half of the bound ATP exchanged with medium GTP or ITP. These data showed that inosine and guanine nucleotides do not bind to soluble F1 in nonexchangeable fashion, in contrast to adenine nucleotides. Purified alpha-subunit from F1 bound ATP at a single site but showed no binding of GTP nor ITP, supporting previous suggestions that the non-exchangeable sites in intact F1 are on alpha-subunits.

In vivo and in vitro incorporation of endogenous nucleotides by the energy-transducing ATPase of Streptococcus faecalis

The soluble ATPase isolated from Streptococcus faecalis membranes containing tightly bound endogenous nucleotides do not exchange in the presence of ATP and Mg+2 added during the purification of the enzyme. In this paper the stoichiometry of endogenous nucleotides in the soluble ATPase obtained from (a) growing cells, (b) nongrowing glycolyzing cells, and (c) isolated cell membranes has been defined. The time course of incorporation was also studied in nongrowing, glycolyzing cells and isolated cell membranes. In all cases, 1-2 mol of nucleotide was bound per mol of enzyme. Maximal incorporation required approximately 1 h at 38 degrees C. Incorporation of cytoplasmic nucleotide into the enzyme occurred by a process of slow exchange for bound nucleotide. N,N'-dicyclohexylcarbodiimide, which inhibits the membrane-bound ATPase and prevents generation of the protonmotive force, had no effect on incorporation of endogenous nucleotides in glycolyzing cells. Treatment of glycolyzing cells with gramicidin D plus K+, which dissipates the protonmotive force but has no effect on ATPase activity, did not inhibit incorporation of nucleotide. These results support the view that the slow exchange-incorporation of endogenous nucleotide(s) is independent of ATP hydrolysis and a protonmotive force. An in vitro system for the study of nucleotide binding at endogenous sites is described.

Changes in chemical properties of mitochondrial adenosinetriphosphatase upon removal of tightly bound nucleotides

The removal of tightly bound nucleotides from mitochondrial F1-ATPase was found to affect the inhibition by ADP and chemical reactivity toward 7-chloro-4-nitro-2,1,3-benzoxadiazole (NBD-C1) and sulfhydryl reagents. Preincubation of nucleotide-depleted F1 with 40 microM ADP in the presence of ethylenediaminetetraacetic acid (EDTA) resulted in a 51% inhibition of the steady-state level of ATPase activity whereas only a 25% inhibition was observed for native F1. Both partially inhibited states of the enzyme could be reversed by the subsequent addition of ATP. Measurement of [14C]ADP binding to nucleotide-depleted F1 in the presence of EDTA reveals three equivalent ADP binding sites with a Kd of 0.45 microM, and a fourth site of lower affinity. The sulfhydryl reagents 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) and N-ethylmaleimide (NEM) were found to inhibit the ATPase activity of nucleotide-depleted F1 but not native F1 or nucleotide-depleted F1 in the presence of ADP or ATP. Polyacrylamide gel electrophoresis of nucleotide-depleted F1 labeled with [14C]NEM gave a 2-fold increase in incorporation into the (alpha + beta) subunits and a 7-fold increase in label in the gamma subunit after 90 min compared to when ADP was present during the reaction. ADP binding to the noncatalytic sites enhanced the rate of inhibition of nucleotide-depleted F1 by NBD-C1 about 2-fold while retarding the subsequent intramolecular transfer from an essential phenol group to an amino group about 2.8-fold. The results suggest a conformational change in F1 caused by changes in nucleotide--protein interaction at the noncatalytic sites.

Conformational change of the alpha subunit of Escherichia coli F1 ATPase: ATP changes the trypsin sensitivity of the subunit

Conformational change in the alpha subunit of Escherichia coli proton-translocating ATPase was studied using trypsin. The subunit was cleaved with a small amount of trypsin (1 microgram/mg subunit) to peptides of less than 8000 daltons. On the other hand, the subunit was cleaved to two main polypeptides (30,000 and 25,000 daltons) in the presence of sufficient ATP (1 mM-0.5 microM) to saturate the high-affinity site of the subunit. Analysis of digests of the subunit combined with fluorescent maleimide suggested that the subunit was digested in the middle of the polypeptide chain in the presence of the nucleotide. ADP and adenylyl imidodiphosphate had the same effect as ATP. These results suggest that the conformation of the subunit changed to form two trypsin-resistant domains upon binding of ATP to the high-affinity site.

Functional groups at the catalytic site of BF1 adenosinetriphosphatase from Escherichia coli

The rates of inactivation of BF1 adenosinetriphosphatase (BF1-ATPase) from Escherichia coli by 7-chloro-4-nitro-2,1,3-benzoxadiazole, 1-fluoro-2,4-dinitrobenzene, 2,4,6-trinitrobenzenesulfonate, phenylglyoxal, and N,N'-dicyclohexylcarbodiimide have been measured in the presence and absence of various concentrations of inorganic phosphate, ADP, ATP, or magnesium ion. Dissociation equilibrium constants and rate constants for the labeling reactions have been deduced from a quantitative treatment of the kinetic data. The results suggest that the essential Tyr, Lys, Arg, and Glu or Asp residues are probably located at the catalytic site of BF1-ATPase and that in addition to steric interference, the effect of charge interaction should also be considered in interpreting the kinetic data on the protection of BF1-ATPase by substrate molecules against inactivation by the above labeling reagents. Examination of the relative values of the rate constants for the labeling reactions in the presence and absence of inorganic phosphate, ADP, ATP, or magnesium ion, respectively, and the effect of NBD label on the rates of labeling of the essential guanidinium, amino, and carboxyl groups suggest that the arrangement of these four functional groups at the catalytic site of BF1 may be similar to that previously proposed for MF1-ATPase from bovine heart; namely, the essential amino group and the unusually reactive phenol group are probably located near the bound inorganic phosphate or the gamma-phosphate group of the bound ATP, the essential guanidinium group is probably located nearer to the alpha- or beta-phosphate group than to the gamma-phosphate group of the bound ATP or the bound inorganic phosphate, and the essential carboxylate group is probably complexed with a magnesium ion which it shares with the bound inorganic phosphate.

Behavior of vesicular stomatitis virus glycoprotein in mouse LM cells with modified membrane-phospholipids

LM cells in which the membrane phospholipids had been modified with choline analogues were infected with vesicular stomatitis virus. The choline analogues tested were choline, N,N'-dimethylethanolamine, N-monomethylethanolamine and ethanolamine. These modifications per se did not affect the syntheses of individual viral proteins. The viral glycoprotein was detected in the plasma membranes of all the modified cells by pronase digestion in pulse-chase experiments, but the amount of glycoprotein susceptible to proteolysis varied, decreasing in these modified cells in the following order: N,N'-dimethylethanolamine- greater than choline- greater than N-monomethylethanolamine- greater than ethanolamine-treated cells. After a 4-h chase, glycoprotein was mainly distributed in the plasma membranes of cells modified with N,N'-dimethylethanolamine, whereas it was found in both the microsomes and plasma membranes of cells modified with other analogues. Fairly large amounts of glycoprotein were also found in the soluble fraction of ethanolamine-treated cells, but not in that of choline- or N,N'-dimethylethanolamine-treated cells. More precise experiments on the behaviour of glycoprotein with a short period of chase strongly suggested that migration of glycoprotein from the microsomes to the plasma membranes was fastest in cells modified with N,N'-dimethylethanolamine and slowest in cells modified with ethanolamine. Membrane lipid modifications also resulted in release of different numbers of progeny virions from the cells, release of virions from the cells decreasing in the following order: N,N'-dimethylethanolamine- greater than choline- greather N-monomethylethanolamine- greater than ethanolamine-treated cells. These results indicate that modification of membrane phospholipids influences not only the insertion of glycoprotein into the microsomes and its migration to the plasma membranes, but also the production of progeny virions.