Pierre V. Vignais

ADP-ribosylation of a small size GTP-binding protein in bovine neutrophils by the C3 exoenzyme of Clostridium botulinum and effect on the cell motility.

A 24-kDa G protein, ADP-ribosylable by exoenzyme C3 from Clostridium botulinum and therefore related to the rho family, was found to be abundantly present in human and bovine neutrophils, and preferentially located in cytosol. In human myeloid HL60 cells, the amount of C3 substrate increased during differentiation of the HL60 cells into granulocytes. The effect of exoenzyme C3 on different functions of bovine neutrophils, namely generation of O-2, degranulation and chemotaxis, has been tested, using electropermeabilized cells. Exoenzyme C3 hardly affected the respiratory burst and the degranulation. In contrast, it efficiently inhibited the spontaneous and chemoattractant-induced motility of the cells and disorganized the actin microfilament assembly.

Recent developments on structural and functional aspects of the F1 sector of H+-linked ATPases

SummaryThis review concerns the catalytic sector of F1 factor of the H+-dependent ATPases in mitochondria (MF1), bacteria (BF1) and chloroplasts (CF1). The three types of Ft have many similarities with respect to the structural parameters, subunit composition and catalytic mechanism. An α3β3γ2δ2ε2 stoichiometry is now accepted for MF1 and BF1; the α2β2γ2δ2ɛ2 stoichiometry for CFI remains as matter of debate. The major subunits α, β and γ are equivalent in MF1, BF1 and CF1; this is not the case for the minor subunits δ and ε. The δ subunit of MFI corresponds to the ε subunit of BF1 and CF1, whereas the mitochondria) subunit equivalent to the δ subunit of BF1 and CF1 is probably the oligomycin sensitivity conferring protein (OSCP). The a β γ assembly is endowed with ATPase activity, β being considered as the catalytic subunit and y as a proton gate. On the other hand, the 6 and E subunits of BFI and CFI most probably act as links between the F1 and F0 sectors of the ATPase complex. The natural mitochondria) ATPase inhibitor, which is a separate protein loosely attached to MF1, could have its counterpart in the E subunit of BF1 and CF1. The generally accepted view that the catalytic subunit in the different F1 species is β comes from a number of approaches, including chemical modification, specific photolabeling and, in the case of BF1, use of mutants. The a subunit also plays a central role in catalysis, since structural alteration of a by chemical modification or mutation results in loss of activity of the whole molecule of F1. The notion that the proton motive force generated by respiration is required for conformational changes of the F1 sector of the H+-ATPase complex has gained acceptance. During the course of ATP synthesis, conversion of bound ADP and Pi into bound ATP probably requires little energy input; only the release of the F1-bound ATP would consume energy. ADP and Pi most likely bind at one catalytic site of F1, while ATP is released at another site. This mechanism, which underlines the alternating cooperativity of subunits in F1, is supported by kinetic data and also by the demonstration of partial site reactivity in inactivation experiments performed with selective chemical modifiers. One obvious advantage of the alternating site mechanism is that the released ATP cannot bind to its original site. The chemistry of the condensation reaction of ADP and Pi to form ATP has not yet been elucidated. Although implicitly admitted, definite evidence that the condensation reaction does not involve a phosphorylated intermediate has been acquired recently by analysis of the stereochemical course of the phosphoric residue transfer in ATP synthesis or hydrolysis. Whereas the catalytic events of ATP synthesis are well understood, the regulatory mechanism, and particularly the role of the so-called inhibitory peptides, remain enigmatic.

Kinetic, binding and ultrastructural properties of the beef heart adenine nucleotide carrier protein after incorporation into phospholipid vesicles.

1. ADP/ATP transport has been reconstituted by incorporation of the purified carrier protein in liposomes filled with ATP. The transport was assayed by uptake of [14C]ADP into the liposomes, and by release of ATP as determined by a luminescence technique. [14C]ADP uptake was strictly dependent on internal ATP. 2. The simplest phospholipid system capable of yielding high rates of ADP/ATP transport was a mixture of phosphatidylethanolamine and cariolipin (92: 8, w/w). 3. ADP/ATP transport in the reconstituted system proceeded by exchange-diffusion with a 1/1 stoichiometry. The specificity for aDP and ATP was absolute. The capacity and the rate of exchange depended on the concentration of ATP present in liposomes. The rate of transport at 20 degrees C, at 20 mM internal ATP, routinely ranged between 300 and 1000 nmol of nucleotide exchanged per min/mg of added carrier protein. The apparent Km value for external ADP was around 10 microM. 4. The ADP/ATP exchange in the reconstituted system was rather stable to ageing. It dropped by only 20% after 1 day of ageing at 20 degrees C. Divalent cations (Mg2+, Mn2+, Ca2+) at concentrations higher than 1 to 2 mM had a deleterious effect on ADP/ATP transport, concomitant with the release of internal ATP and accumulation of multilamellar vesicles. 5. Atractyloside behaved as a competitive inhibitor and carboxyatractyloside as a non-competitive inhibitor. Bongkrekic acid required a slightly acidic pH to be inhibitory. The data concerning atractyloside, carboxyatractyloside and bongkrekic acid were similar to those obtained with whole mitochondria, suggesting that the carrier protein in liposomes has the same asymmetrical arrangement as in the mitochondria. 6. The percentage of competent carrier protein in liposomes was calculated from dose-response data concerning the inhibition of ADP/ATP transport by atractyloside or carboxyatractyloside, and from the amount of bound [3H]-atractyloside removable by ADP. By both methods, 3 to 6% of the added carrier protein was found to be competent in ADP/ATP transport, based on the assumption that the binding of one atractyloside or carboxyatractyloside molecule per 30000 molecular weight carrier unit results in complete inhibition of transport. 7. Freeze-fracture electron microscopy showed that the ADP/ATP carrier protein-lipid preparations are formed by small vesicles, most of which give rise to smooth fracture faces (probably pure lipid vesicles). Only a small percentage of the vesicles (2 to 4% depending on the amount of carrier protein added) were clearly particulated. About 90% of the particulated vesicles showed no more than 2 particles per vesicle and only 5% more than 5 particles per vesicle. The distribution of the particles between convex and concave fracture faces was asymmetric; about 2/3 of the protein molecules were anchored at the external surface of the vesicles and only 1/3 at the internal one...

Control of oxidative phosphorylation in rat heart mitochondria. The role of the adenine nucleotide carrier

Inhibitor titration experiments carried out with carboxyatractyloside, oligomycin and rotenone show that in the case of heart mitochondria the membrane-bound ATPase and the respiratory chain are the major factors controlling the rate of oxidative phosphorylation whereas the adenine nucleotide carrier exhibits no control strength. As shown by carboxyatractyloside titration curves under different conditions, the relative importance of the adenine nucleotide carrier depends on the mode of regeneration (F1-ATPase or glucose plus hexokinase) of ADP from ATP exported outside mitochondria, on the total concentration of adenine nucleotides present in the medium and on the mode of limitation of the rate of respiration (cyanide, rotenone, oligomycin or mersalyl). Concomitantly with the inhibition of O2 consumption, carboxyatractyloside brings about a rise in membrane potential. The inverse relationship between the two processes is observed for carboxyatractyloside concentrations ranging between 0.7 and 1.5 nmol per mg protein. Carboxyatractyloside concentrations below and above this range increase the membrane potential without affecting significantly the rate of respiration. Titration experiments aimed at comparing the effects of ADP, carboxyatractyloside and the uncoupler, carbonyl cyanide p-trifluoromethoxyphenylhydrazone, corroborate the conclusion that in heart mitochondria a major limiting factor in oxidative phosphorylation is the capacity of the respiratory chain.

Small angle neutron scattering of the mitochondrial ADPATP carrier protein in detergent

Abstract Small angle neutron scattering measurements have been performed on the mitochondrial ADP ATP carrier protein in micelles of the detergent, laurylamidodimethylpropylaminoxide (LAPAO). The carrier protein was stabilized in the forms of the carboxyatractyloside- and bongkrekic acid- carrier protein complexes. using a D 2 O H 2 O ratio of 10%, which annuls the contribution of LAPAO to the scattering, the calculated molecular weight of the carrier protein was 61000, assuming no exchangeable H in the protein, and 56000, assuming 65% exchangeable H. Based on a minimal molecular weight close to 32000 calculated from the amino acid sequence, the neutron scattering data indicate that both the carboxyatractyloside- carrier and bongkrekic acid-carrier complexes solubilized in LAPAO are in a dimeric state.

Spontaneous aggregation of the mitochondrial natural ATPase inhibitor in salt solutions as demonstrated by gel filtration and neutron scattering. Application to the concomitant purification of the ATPase inhibitor and F1-ATPase

(1) The natural ATPase inhibitor (IF1) from beef heart mitochondria has a tendency to form aggregates in aqueous solutions. The extent of aggregation and the structure of the aggregates were assessed by gel filtration and small-angle neutron scattering. IF1 polymerization was found to depend on the salt concentrations, pH of the medium and concentration of IF1. The higher the salt concentration, the lower the aggregation state. Aggregation of IF1 was decreased at slightly acidic pH. It increased with the concentration of IF1 as expected from the law of mass action. (2) Neutron scattering showed the aggregation of IF1 in 2 M ammonium sulfate solutions. The predominant species is the dimer which has a somewhat elongated shape. (3) The Sephadex G-50 chromatography that is supposed to deprive beef heart submitochondrial particles of loosely bound IF1 (Racker, E. and Horstman, L.L. (1967) J. Biol. Chem. 242, 2547-2551) was shown to have a limited effectiveness as a trap for IF1. The reason was that IF1 released from the particles formed high molecular weight aggregates that were not separated from the membrane vesicles by Sephadex G-50 chromatography. (4) The above observations provide the basis for a simple method of purification of beef heart IF1 which combines the recovery of the supernatant from submitochondrial particles with the last three steps of the IF1 preparation described by Horstman and Racker (J. Biol. Chem. (1970) 265, 1336-1344). The particles recovered in the sediment were deprived of IF1 and could therefore be used for preparation of F1-ATPase. The advantage of this method is that both IF1 and F1-ATPase can be prepared from the same batch of mitochondria.

Substrate-site interactions in the membrane-bound adenine-nucleotide carrier as disclosed by ADP and ATP analogs

The binding parameters of a number of ADP or ATP analogs to the adenine nucleotide carrier in mitochondria and inside-out submitochondrial particles have been explored by means of two specific inhibitors, carboxyatractyloside and bongkrekic acid. The nucleotides tested fell into two classes depending on the shape of the binding curve. Curvilinear Scatchard plots were obtained for the binding of ADP, ATP, adenosine 5-triphospho-gamma-1-(5-sulfonic acid)naphthylamidate [gamma-AmNS)ATP) and adenylyl (beta,gamma)-methylenediphosphate (p[CH2]ppA); on the other hand, rectilinear Scatchard plots were obtained in the case of naphthoyl-ADP (N-ADP) and 8-bromo ADP (8Br-ADP) binding. The total number of binding sites for N-ADP and 8Br-ADP could be extrapolated with good accuracy to 1.3-1.5 nmol/mg protein; this value corresponds to the number of carboxyatractyloside-binding sites in heart mitochondria (Block, M.R., Pougeois, R. and Vignais, P.V. (1980) FEBS Lett. 117, 335-340). On the other hand, because of the curvilinearity of the Scatchard plots for the binding of ADP, ATP, (gamma-AmNS)ATP and p[CH2]ppA, the total number of binding sites for these nucleotides could only be approximated to a value higher than 1 nmol/mg protein, the exact value being probably equal to that found for N-ADP and 8Br-ADP binding, i.e. 1.3-1.5 nmol/mg protein. Curvilinearity of Scatchard plots was discussed in terms of negative interactions between nucleotide-binding sites located on the same face of the adenine nucleotide carrier. A possible relationship between the features of the binding plots and the transportable nature of the nucleotide is discussed. Contrary to the enhancing effect of bongkrekic acid on [14C]ADP uptake observed essentially in nucleotide-depleted heart mitochondria (Klingenberg, M., Appel, M., Babel, W. and Aquila, H. (1983) Eur. J. Biochem. 131, 647-654), binding of bongkrekic acid to nondepleted heart mitochondria was found to partially displace previously bound [14C]ADP. These opposite effects of bongkrekic acid may be explained by assuming that bongkrekic acid is able to abolish negative cooperativity between external (cytosolic) ADP-binding sites.

Phosphate carrier of liver mitochondria: The reaction of its SH groups with mersalyl, 5,5′-dithio-bis-nitrobenzoate, andN-ethylmaleimide and the modulation of reactivity by the energy state of the mitochondria

The inhibitory effect of three SH reagents, mersalyl, 5,5′-dithio-bis-nitrobenzoate, andN-ethylmaleimide, on Pi transport in rat liver mitochondria was investigated under a variety of conditions. Mersalyl binds at room temperature with both high (Kd<10 µM) and low affinity to mitochondria. Inhibition of Pi transport by mersalyl goes in parallel with titration of the high-affinity sites, inhibition being complete when 3.5–4.5 nmol/mg protein is bound to the mitochondria. At concentrations of mersalyl equal to or higher than 10 µM, inhibition of Pi transport occurs in less than 10 sec. At concentrations of mersalyl lower than 10 µM, the rate of reaction with the Pi carrier is considerably decreased. At a concentration of 100 µM, 5,5′-dithio-bisnitrobenzoate fully inhibits Pi transport in about 1 min at room temperature. Nearly total inhibition is attained when as little as 40–50 pmol/mg is bound to mitochondria. Upon incubation longer than 1 min, additional SH groups, not belonging to the Pi carrier, begin to react. The uncoupler carbonyl cyanidep-trifluoromethoxyphenylhydrazone decreases the rate of reaction of mersalyl, 5,5′-dithio-bis-nitrobenzoate, andN-ethylmaleimide with the Pi carrier. Preincubation with Pi has a similar effect. We propose that both carbonyl cyanidep-trifluoromethoxyphenylhydrazone and Pi act by increasing the acidity of the mitochondrial matrix. Protonation of the Pi carrier at the matrix side would change the accessibility of its SH groups at the outer surface of the inner membrane. This might correspond to a membrane-Bohr effect, possibly related to the opening of a gating pore in the Pi carrier.

Effect of the protonmotive force on ATP-linked processes and mobilization of the bound natural ATPase inhibitor in beef heart submitochondrial particles.

In an attempt to determine whether the natural ATPase inhibitor (IF1) plays a role in oxidative phosphorylation, the time course of ATP synthesis and ATP hydrolysis in inside-out submitochondrial particles from beef heart mitochondria either possessing IF1 (Mg-ATP particles) or devoid of IF1 (AS particles) was investigated and compared to movements of IF1, as assessed by an isotopic assay. The responses of the above reactions to preincubation of the particles in aerobiosis with NADH or succinate were as follows: (1) The few seconds lag that preceded the steady-rate phase of ATP synthesis was shortened and even abolished both in Mg-ATP particles and AS particles. The rate of ATP synthesis in the steady state was independent of the length of the lag. (2) ATPase was slowly activated, maximal activation being obtained after a 50-min preincubation; there was no direct link between the development of the protonmotive force (maximal within 1 sec) and ATPase activation. (3) Bound IF1 was slowly released; the release of bound IF1 as a function of the preincubation period was parallel to the enhancement of ATPase activity; the maximal amount of IF1 released was a small fraction of the total IF1 bound to the particles (less than 20%). (4) The double reciprocal plots of the rates of ATP and ITP hydrolysis vs. substrate concentrations that were curvilinear in the absence of preincubation with a respiratory substrate became linear after aerobic preincubation with the substrate. The data conclusively show that only ATPase activity in submitochondrial particles is correlated with the release of IF1, and that the total extent of IF1 release induced by respiration is limited. On the other hand, the kinetics of ATPase in control and activated particles are consistent with the existence of two conformations of the membrane-bound F1-ATPase, directed to ATP synthesis or ATP hydrolysis and distinguishable by their affinity for IF1.

Effect of the natural ATPase inhibitor on the binding of adenine nucleotides and inorganic phosphate to mitochondrial F1-ATPase

(1) Incubation of the beef heart mitochondrial ATPase, F1 with Mg-ATP was required for the binding of the natural inhibitor, IF1, to F1 to form the inactive F1-IF1 complex. When F1 was incubated in the presence of [14C]ATP and MgCl2, about 2 mol 14C-labeled adenine nucleotides were found to bind per mol of F1; the bound 14C-labeled nucleotides consisted of [14C]ADP arising from [14C]ATP hydrolysis and [14C]ATP. The 14C- labeled nucleotide binding was not prevented by IF1. These data are in agreement with the idea that the formation of the F1-IF1 complex requires an appropriate conformation of F1. (2) The 14C-labeled adenine nucleotides bound to F1 following preincubation of F1 with Mg-[14C] ATP could be exchanged with added [3H]ADP or [3H]ATP. No exchange occurred between added [3H]ADP or [3H]ATP and the 14 C-labeled adenine nucleotides bound to the F1-IF1 complex. These data suggest that the conformation of F1 in the isolated F1-IF1 complex is further modified in such a way that the bound 14C-labeled nucleotides are no longer available for exchange. (3) 32Pi was able to bind to isolated F1 with a stoichiometry of about 1 mol of Pi per mol of F1 (Penefsky, H.S. (1977) J. Biol. Chem. 252, 2891-2899). There was no binding of 32Pi to the F1-IF1 complex. Thus, not only the nucleotides sites, but also the Pi site, are masked from interaction with external ligands in the isolated F1-IF1 complex.