Sulfhydryl-alkylating reagents inactivate the NAD glycohydrolase activity of pertussis toxin

The combination of ATP, CHAPS (3-[(3-cholamidopropyl)dimethylammonio]-1-propane-sulfonate), and DTT (dithiothreitol) is known to promote the expression of the NAD glycohydrolase activity of pertussis toxin, which resides in the toxin's S1 subunit. By monitoring changes in electrophoretic mobility, we have found that ATP and CHAPS act by promoting the reduction of the disulfide bond of the S1 subunit. In addition, ATP, CHAPS, and DTT allowed sulfhydryl-alkylating reagents to inactivate the NAD glycohydrolase activity. In the presence of iodo[14C]acetate, the combination of ATP, CHAPS, and DTT increased 14C incorporation into only the S1 subunit of the toxin, indicating that alkylation of this subunit was responsible for the loss of activity. If iodoacetate is used as the alkylating reagent, alkylation can be monitored by an acidic shift in the isoelectric point of the S1 peptide. Including NAD in alkylation reactions promoted the accumulation of a form of the S1 peptide with an isoelectric point intermediate between that of native S1 and that of S1 alkylated in the absence of NAD. This result suggests that NAD interacts with one of the two cysteines of the S1 subunit. In addition, we found the pH optimum for the NAD glycohydrolase activity of pertussis toxin is 8, which may reflect the participation of a cysteine in the catalytic mechanism of the toxin.     

Adenine nucleotides promote dissociation of pertussis toxin subunits

Pertussis toxin is composed of an enzymatically active A subunit and a binding component (B oligomer). Both the holotoxin and the isolated A subunit have previously been shown to exhibit NAD glycohydrolase activity although the A subunit is more active on a molar basis than the holotoxin. We have investigated the mechanism by which ATP stimulates the activity of this toxin. Since dissociation of pertussis toxin subunits would result in increased NAD glycohydrolase activity, the ability of ATP to promote release of the A subunit from the B oligomer was examined. In the presence of the zwitterionic detergent 3-(3-cholamidopropyldimethyl)-1-ammonio)-propanesulfonate, concentrations of ATP as low as 1 microM promoted subunit dissociation. The concentration of ATP required for release of the A subunit was similar to that required for stimulation of NAD glycohydrolase activity. Both ATP and ADP promoted subunit dissociation and stimulated NAD glycohydrolase activity. In contrast, AMP and adenosine did not alter NAD glycohydrolase activity or affect subunit structure. The ability of ATP to decrease the affinity of the A subunit for the B oligomer may play a role in nucleotide stimulation of pertussis toxin activity.     

Stimulation of the thiol-dependent ADP-ribosyltransferase and NAD glycohydrolase activities of Bordetella pertussis toxin by adenine nucleotides, phospholipids, and detergents

Pertussis toxin catalyzed ADP-ribosylation of the guanyl nucleotide binding protein transducin was stimulated by adenine nucleotide and either phospholipids or detergents. To determine the sites of action of these agents, their effects were examined on the transducin-independent NAD glycohydrolase activity. Toxin-catalyzed NAD hydrolysis was increased synergistically by ATP and detergents or phospholipids; the zwitterionic detergent 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS) was more effective than the nonionic detergent Triton X-100 greater than lysophosphatidylcholine greater than phosphatidylcholine. The A0.5 for ATP in the presence of CHAPS was 2.6 microM; significantly higher concentrations of ATP were required for maximal activation in the presence of cholate or lysophosphatidylcholine. In CHAPS, NAD hydrolysis was enhanced by ATP greater than ADP greater than AMP greater than adenosine; ATP was more effective than MgATP or the nonhydrolyzable analogue adenyl-5'-yl imidodiphosphate. GTP and guanyl-5'-yl imidodiphosphate were less active than the corresponding adenine nucleotides. Activity in the presence of CHAPS and ATP was almost completely dependent on dithiothreitol; the A0.5 for dithiothreitol was significantly decreased by CHAPS alone and, to a greater extent, by CHAPS and ATP. To determine the site of action of ATP, CHAPS, and dithiothreitol, the enzymatic (S1) and binding components (B oligomer) were resolved by chromatography. The purified S1 subunit catalyzed the dithiothreitol-dependent hydrolysis of NAD; activity was enhanced by CHAPS but not ATP. The studies are consistent with the conclusion that adenine nucleotides, dithiothreitol, and CHAPS act on the toxin itself rather than on the substrate; adenine nucleotides appear to be involved in the activation of toxin but not the isolated catalytic unit.     

Binding of ATP by pertussis toxin and isolated toxin subunits.

The binding of ATP to pertussis toxin and its components, the A subunit and B oligomer, was investigated. Whereas, radiolabeled ATP bound to the B oligomer and pertussis toxin, no binding to the A subunit was observed. The binding of [3H]ATP to pertussis toxin and the B oligomer was inhibited by nucleotides. The relative effectiveness of the nucleotides was shown to be ATP greater than ATP greater than GTP greater than CTP greater than TTP for pertussis toxin and ATP greater than GTP greater than TTP greater than CTP for the B oligomer. Phosphate ions inhibited the binding of [3H]ATP to pertussis toxin in a competitive manner; however, the presence of phosphate ions was essential for binding of ATP to the B oligomer. The toxin substrate, NAD, did not affect the binding of [3H]ATP to pertussis toxin, although the glycoprotein fetuin significantly decreased binding. These results suggest that the binding site for ATP is located on the B oligomer and is distinct from the enzymatically active site but may be located near the eukaryotic receptor binding site.     

Structural characterization of pertussis toxin A subunit

The relationship between the structure of the A subunit of pertussis toxin and its function was analyzed. Limited tryptic digestion of the A subunit converted the protein to two stable fragments (Mr = 20,000 and 18,000). Antibodies raised to synthetic peptides homologous to regions in the A subunit were used to map these fragments. Both fragments were shown to contain the NH2-terminal portion but not the COOH-terminal portion of the A subunit. While these fragments exhibited NAD glycohydrolase activity, they were unable to reassociate with the B oligomer of the toxin. Thus the COOH-terminal portion of the A subunit does not contain the residues which are required for the NAD glycohydrolase activity of the toxin. However, this region of the molecule may be important for maintaining the oligomeric structure of the toxin. These results suggest that the A subunit of pertussis toxin is similar in structure to the A subunit of cholera toxin. In addition, antibodies raised to a synthetic peptide identical to residues 6-17 of the A subunit of pertussis toxin will bind to the A subunit of cholera toxin.     

Role of cysteine 41 of the A subunit of pertussis toxin

The 2 cysteine residues present in the A subunit of pertussis toxin form a disulfide bond in the conformation of the toxin secreted from the bacteria. Previous studies have shown that reduction of this bond is necessary for activation of the enzyme. We have found that reduction of this bond also alters the conformation of the A subunit such that it no longer readily associates with the B oligomer of the toxin, a finding which may have implications concerning the form of the toxin found within the eukaryotic cell. In addition, we have demonstrated that reduction of the disulfide bond of the purified A subunit followed by treatment with sulfhydryl-modifying reagents such as N-ethylmaleimide or 5,5'-dithiobis-(2-nitrobenzoic acid) results in inhibition of the NAD glycohydrolase activity of the protein. When a tryptic fragment of the A subunit which contains only 1 of the cysteine residues (Cys-41) of the native protein was reacted with N-ethylmaleimide, the NAD glycohydrolase activity of this fragment was substantially reduced. These data indicate that Cys-41 may be in a region of the molecule which is critical for the enzymatic activity of the toxin.     

Thiol reagents are substrates for the ADP-ribosyltransferase activity of pertussis toxin

Thiols such as cysteine and dithiothreitol are substrates for the ADP-ribosyltransferase activity of pertussis toxin. When cysteine was incubated with NAD+ and toxin at pH 7.5, a product containing ADP-ribose and cysteine (presumably ADP-ribosylcysteine) was isolated by high-performance liquid chromatography, and characterized by its composition and release of AMP with phosphodiesterase. Cysteine has a Km of 105 mM at saturating NAD+ concentration. The ability of thiols to act as a substrate is one explanation for the very high concentrations (250 mM or greater) that have been observed to enhance the apparent NAD glycohydrolase activity of the toxin.     

Photolabelling of mutant forms of the S1 subunit of pertussis toxin with NAD+.

The S1 subunit of pertussis toxin catalyses the hydrolysis of NAD+ (NAD+ glycohydrolysis) and the NAD(+)-dependent ADP-ribosylation of guanine-nucleotide-binding proteins. Recently, the S1 subunit of pertussis toxin was shown to be photolabelled by using radiolabelled NAD+ and u.v.; the primary labelled residue was Glu-129, thereby implicating this residue in the binding of NAD+. Studies from various laboratories have shown that the N-terminal portion of the S1 subunit, which shows sequence similarity to cholera toxin and Escherichia coli heat-labile toxin, is important to the maintenance of both glycohydrolase and transferase activity. In the present study the photolabelling technique was applied to the analysis of a series of recombinant-derived S1 molecules that possessed deletions or substitutions near the N-terminus of the S1 molecule. The results revealed a positive correlation between the extent of photolabelling with NAD+ and the magnitude of specific NAD+ glycohydrolase activity exhibited by the mutants. Enzyme kinetic analyses of the N-terminal mutants also identified a mutant with substantially reduced activity, a depressed photolabelling efficiency and a markedly increased Km for NAD+. The results support a direct role for the N-terminal region of the S1 subunit in the binding of NAD+, thereby providing a rationale for the effect of mutations in this region on enzymic activity.     

Localization of a region of the S1 subunit of pertussis toxin required for efficient ADP-ribosyltransferase activity

Purified recombinant S1 subunit of pertussis toxin (rS1) possessed similar NAD glycohydrolase and ADP-ribosyltransferase activities as S1 subunit purified from pertussis toxin. Purified rS1 and C180 peptide, a deletion peptide which contains amino acids 1-180 of rS1, had Km values for NAD of 24 and 13 microM and kcat values of 22 and 24 h-1, respectively, in the NAD glycohydrolase reaction. In contrast, under linear velocity conditions, the C180 peptide possessed less than 1% of the ADP-ribosyltransferase activity of rS1 using transducin as target. Radiolabeled tryptic peptides of transducin that had been ADP-ribosylated by either rS1 or C180 peptide were identical which suggested that both rS1 and C180 peptide ADP-ribosylated the same amino acid within transducin. To extend the functional primary amino acid map of the S1 subunit, two carboxyl-terminal deletions were constructed. One deletion, C195, removed the 40 carboxyl-terminal amino acids and the other, C219, removed the 16 carboxyl-terminal amino acids of the S1 subunit. Both C195 and C219 migrated in reduced sodium dodecyl sulfate-polyacrylamide gel electrophoresis with apparent molecular masses of 22,000 and 27,500 Da, respectively. Relative to the C180 peptide C195 possessed 10-20-fold increase and C219 possessed 100-150-fold increase in ADP-ribosyltransferase activities. In addition, C219 appeared to have the same ADP-ribosyltransferase activity as rS1. These studies indicate that (i) rS1, purified from Escherichia coli, possesses biochemical properties similar to S1 subunit purified from pertussis toxin, (ii) amino acids 1-180 of the S1 subunit contain residues required for NAD binding, N-glycosidic cleavage, and transfer of ADP-ribose to transducin, and (iii) residues between 181 and 219 of the S1 subunit are required for efficient ADP-ribosyltransferase activity.     

Inhibition of NAD glycohydrolase and ADP-ribosyl transferases by carbocyclic analogues of oxidized nicotinamide adenine dinucleotide

Analogues of oxidized nicotinamide adenine dinucleotide (NAD+) in which a 2,3-dihydroxycyclopentane ring replaces the beta-D-ribonucleotide ring of the nicotinamide riboside moiety of NAD+ have recently been synthesized [Slama, J. T., & Simmons, A. M. (1988) Biochemistry 27, 183]. Carbocyclic NAD+ analogues have been shown to inhibit NAD glycohydrolases and ADP-ribosyl transferases such as cholera toxin A subunit. In this study, the diastereomeric mixture of dinucleotides was separated, and the inhibitory capacity of each of the purified diastereomers was defined. The NAD+ analogue in which the D-dihydroxycyclopentane is substituted for the D-ribose is designated carba-NAD and was demonstrated to be a poor inhibitor of the Bungarus fasciatus venom NAD glycohydrolase. The diastereomeric dinucleotide pseudo-carbocyclic-NAD (psi-carba-NAD), containing L-dihydroxycyclopentane in place of the D-ribose of NAD+, was shown, however, to be a potent competitive inhibitor of the venom NAD glycohydrolase with an inhibitor dissociation constant (Ki) of 35 microM. This was surprising since psi-carba-NAD contains the carbocyclic analogue of the unnatural L-ribotide and was therefore expected to be a biologically inactive diastereomer. psi-Carba-NAD also competitively inhibited the insoluble brain NAD glycohydrolase from cow (Ki = 6.7 microM) and sheep (Ki = 31 microM) enzyme against which carba-NAD is ineffective. Sensitivity to psi-carba-NAD was found to parallel sensitivity to inhibition by isonicotinic acid hydrazide, another NADase inhibitor. psi-Carba-NAD is neither a substrate for nor an inhibitor of alcohol dehydrogenase, whereas carba-NAD is an efficient dehydrogenase substrate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of tryptophan 26 in the NAD glycohydrolase reaction of the S-1 subunit of pertussis toxin

The gene encoding a catalytically active deletion peptide, the C180 peptide, of the S-1 subunit of pertussis toxin was engineered to facilitate mutagenesis at the Trp-26 (wild-type) coding sequence. A synthetic double-stranded oligonucleotide was inserted into the C180 gene such that all possible codons would be introduced into position 26. Seven individual mutants of the C180 peptide which possessed amino acid substitutions at residue 26 (collectively termed C180W26n peptides) were purified from periplasmic extracts of Escherichia coli. Each C180W26n peptide was present as a single major peptide that had an apparent molecular mass of between 20.9 and 24.5 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and each showed similar immunoreactivity relative to the C180 peptide. The C180W26n peptides demonstrated marked reduction of both ADP-ribosyltransferase and NAD glycohydrolase activities at 25 nM and 10 microM NAD, respectively. Kinetic analysis of the two most active mutants, C180W26F and C180W26Y, revealed that the major perturbation of NAD glycohydrolase activity was due to an increase (approximately 20-fold) in the Km for NAD between these mutants and the C180 peptide.     

A quantitative analysis for the ADP-ribosylation activity of pertussis toxin: an enzymatic-HPLC coupled assay applicable to formulated whole cell and acellular pertussis vaccine products.

The majority of the biological effects of pertussis toxin (PT) are the result of a toxin-catalyzed transfer of an adenosine diphosphate-ribose (ADP-ribose) moiety from NAD(+)to the alpha-subunits of a subset of signal-transducing guanine-nucleotide-binding proteins (G-proteins). This generally leads to an uncoupling of the modified G-protein from the corresponding receptor and the loss of effector regulation. This assay is based on the PT S1 subunit enzymatic transfer of ADP-ribose from NAD to the cysteine moiety of a fluorescent tagged synthetic peptide homologous to the 20 amino acid residue carboxyl-terminal sequence of the alpha-subunit of the G(i3)protein. The tagged peptide and the ADP-ribosylated product were characterized by HPLC/MS and MS/MS for structure confirmation. Quantitation of this characterized ADP-ribosylated fluorescently tagged peptide was by HPLC fluorescence using Standard Addition methodology. The assay was linear over a five hr incubation period at 20 degrees C at PT concentrations between 0.0625 and 4.0 microg/ml and the sensitivity of the assay could be increased several fold by increasing the incubation time to 24 h. Purified S1 subunit of PT exhibited 68.1+/-10.1% of the activity of the intact toxin on a molar basis, whereas the pertussis toxin B oligomer, the genetically engineered toxoid, (PT-9K/129G), and several of the other components of the Bordetella pertussis organism possessed little (<0.6%) or no detectable ribosylation activity. Commonly used pertussis vaccine reference materials, US PV Lot #11, BRP PV 66/303, and BRP PV 88/522, were assayed by this method against Bordetella pertussis Toxin Standard 90/518 and demonstrated to contain, respectively, 0.323+/-0.007, 0.682+/-0.045, and 0.757+/-0.006 microg PT/ml (Mean+/-SEM) or in terms of microg/vial: 3.63, 4.09 and 4.54, respectively. A survey of several multivalent pertussis vaccine products formulated with both whole cell as well as acellular components indicated that products possessed a wide range of ribosylation activities. The pertussis toxin S1 subunit catalyzed ADP- ribosylation of the FAC-Galpha(i3)C20 peptide substrate and its subsequent quantitation by HPLC was demonstrated to be a sensitive and quantitative method for measuring intrinsic pertussis toxin activity. This methodology not only has the potential to be an alternative physicochemical method to replace existing bioassay methodology, but has the added advantage of being a universal method applicable to the assay of pertussis toxin in both whole cell and acellular vaccines as well as bulk and final formulated vaccine products. Acceptance of this method by regulatory agencies and industry as a credible alternative to existing methods would, however, require validation in an international collaborative study against the widely accepted bioassay methods.     

Mechanism of action of choleragen

Choleragen exerts its effect on cells through activation of adenylate cyclase. Choleragen initially interacts with cells through binding of the B subunit of the toxin to the ganglioside G_M1 on the cell surface. Subsequent events are less clear. Patching or capping of toxin on the cell surface may be an obligatory step in choleragen action. Studies in cell-free systems have demonstrated that activation of adenylate cyclase by choleragen requires NAD. In addition to NAD, requirements have been observed for ATP, GTP, and calcium-dependent regulatory protein. GTP also is required for the expression of choleragen-activated adenylate cyclase. In preparations from turkey erythrocytes, choleragen appears to inhibit an isoproterenol-stimulated GTPase. It has been postulated that by decreasing the activity of a specific GTPase, choleragen would stabilize a GTP-adenylate cyclase complex and maintain the cyclase in an activated state. Although the holotoxin is most effective in intact cells, with the A subunit having 1/20th of its activity and the B subunit (choleragenoid) being inactive, in cell-free systems the A subunit, specifically the A₁ fragment, is required for adenylate cyclase activation. The B protomer is inactive. Choleragen, the A subunit, or A₁ fragment under suitable conditions hydrolyzes NAD to ADP-ribose and nicotinamide (NAD glycohydrolase activity) and catalyzes the transfer of the ADP-ribose moiety of NAD to the guandino group of arginine (ADP-ribosyltransferase activity). The NAD glycohydrolase activity is similar to that exhibited by other NAD-dependent bacterial toxins (diphtheria toxin, Pseudomonas exotoxin A), which act by catalyzing the ADP-ribosylation of a specific acceptor protein. If the ADP-ribosylation of arginine is a model for the reaction catalyzed by choleragen in vivo, then arginine is presumably an analog of the amino acid which is ADP-ribosylated in the acceptor protein. It is postulated that choleragen exerts its effects on cells through the NAD-dependent ADP-ribosylation of an arginine or similar amino acid in either the cyclase itself or a regulatory protein of the cyclase system.     

Alkylation of cysteine 41, but not cysteine 200, decreases the ADP-ribosyltransferase activity of the S1 subunit of pertussis toxin

Sulfhydryl-alkylating reagents are known to inactivate the NAD glycohydrolase and ADP-ribosyltransferase activities of the S1 subunit of pertussis toxin, a protein which contains two cysteines at positions 41 and 200. It has been proposed that NAD can retard alkylation of one of the two cysteines of this protein (Kaslow, H.R., and Lesikar, D.D. (1987) Biochemistry 26, 4397-4402). We now report that NAD retards the ability of these alkylating reagents to inactivate the S1 subunit. In order to determine which cysteine is protected by NAD, we used site-directed mutagenesis to construct analogs of the toxin with serines at positions 41 and/or 200. Sulfhydryl-alkylating reagents reduced the ADP-ribosyltransferase activity of the analog with a single cysteine at position 41; NAD retarded this inactivation. In contrast, sulfhydryl-alkylating reagents did not inactivate analogs with serine at position 41. An analog with alanine at position 41 possessed substantial ADP-ribosyltransferase activity. We conclude that alkylation of cysteine 41, and not cysteine 200, inactivates the S1 subunit of pertussis toxin, but that the sulfhydryl group of cysteine 41 is not essential for the ADP-ribosyltransferase activity of the toxin. These results suggest that the region near cysteine 41 contributes to features of the S1 subunit important for ADP-ribosyltransferase activity. Using site-directed mutagenesis, we found that changing aspartate 34 to asparagine, arginine 39 to lysine, and glutamine 42 to glutamate had little effect on ADP-ribosyltransferase activity. However, substituting an asparagine for the histidine at position 35 markedly decreased, but did not eliminate, ADP-ribosyltransferase activity. Chou-Fasman analysis predicted no significant modifications in secondary structure of the S1 peptide with the change of histidine 35 to asparagine. Thus, histidine 35 may interact with a substrate of the S1 subunit without being essential for catalysis.     

Inhibition and activation of bovine heart NAD-specific isocitrate dehydrogenase by ATP

In the absence of added calcium, inhibition of NAD-specific isocitrate dehydrogenase by ATP occurred without ADP (I0.5 = 1.8 mM) and with 0.2 mM ADP3- (I0.5 = 1.0 mM) at subsaturating substrate concentrations at pH 7.4. Inhibition by ATP was competitive with NAD+ in the presence and absence of ADP and was not reversed by magnesium citrate. No reversal of ATP inhibition by free Ca2+ was observed in the presence of ADP (0.2 mM). However, when ADP was absent, increasing Ca2+ first caused progressive reversal of ATP inhibition followed by activation by ATP. Without ADP, the S0.5 for calcium activation was 80-140 microM at ATP concentrations between 0.6 and 3.0 mM. The S0.5 for ATP activation, in the absence of ADP, was 1.1 and 2.1 microM when free Ca2+ was held constant at 0.1 and 1.0 mM, respectively. As in activation by ADP, ATP decreased the S0.5 for magnesium isocitrate without affecting V. However, in contrast to ADP, the activation by ATP occurred without lowering the Hill coefficient for the substrate. GDP activated the enzyme at relatively high concentrations of Ca2+ but not without added Ca2+.     

Inhibition of hepatic adenylate cyclase by NADH

Adenylate cyclase activity in isolated rat liver plasma membranes was inhibited by NADH in a concentration-dependent manner. Half-maximal inhibition of adenylate cyclase was observed at 120 microM concentration of NADH. The effect of NADH was specific since adenylate cyclase activity was not altered by NAD+, NADP+, NADPH, and nicotinic acid. The ability of NADH to inhibit adenylate cyclase was not altered when the enzyme was stimulated by activating the cyclase was not altered when the enzyme was stimulated by activating the Gs regulatory element with either glucagon or cholera toxin. Similarly, inhibition of Gi function by pertussis toxin treatment of membranes did not attenuate the ability of NADH to inhibit adenylate cyclase activity. Inhibition of adenylate cyclase activity to the same extent in the presence and absence of the Gpp (NH) p suggested that NADH directly affects the catalytic subunit. This notion was confirmed by the finding that NADH also inhibited solubilized adenylate cyclase in the absence of Gpp (NH)p. Kinetic analysis of the NADH-mediated inhibition suggested that NADH competes with ATP to inhibit adenylate cyclase; in the presence of NADH (1 mM) the Km for ATP was increased from 0.24 +/- 0.02 mM to 0.44 +/- 0.08 mM with no change in Vmax. This observation and the inability of high NADH concentrations to completely inhibit the enzyme suggest that NADH interacts at a site(s) on the enzyme to increase the Km for ATP by 2-fold and this inhibitory effect is overcome at high ATP concentrations.     

Purification, kinetic behavior, and regulation of NAD(P)+ malic enzyme of tumor mitochondria

The purification and kinetic characterization of an NAD(P)+-malic enzyme from 22aH mouse hepatoma mitochondria are described. The enzyme was purified 328-fold with a final yield of 51% and specific activity of 38.1 units/mg of protein by employing DEAE-cellulose chromatography and an ATP affinity column. Sephadex G-200 chromatography yielded a native Mr = 240,000. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a major subunit with Mr = 61,000, suggesting a tetrameric structure, and also showed that the preparation contained less than 10% polypeptide impurities. Use of the ATP affinity column required the presence of MnCl2 and fumarate (an allosteric activator) in the elution buffers. In the absence of fumarate, the Michaelis constants for malate, NAD+, and NADP+ were 3.6 mM, 55 microM, and 72 microM, respectively; in the presence of fumarate (2 mM), the constants were 0.34 mM, 9 microM, and 13 microM, respectively. ATP was shown to be an allosteric inhibitor, competitive with malate. However, the inhibition by ATP displayed hyperbolic competitive kinetics with a KI (ATP) of 80 microM (minus fumarate) and 0.5 mM (plus 2 mM fumarate). The allosteric properties of the enzyme are integrated into a rationale for its specific role in the pathways of malate and glutamate oxidation in tumor mitochondria.     

Binding of NAD+ by cholera toxin.

1. The Km for NAD+ of cholera toxin working as an NAD+ glycohydrolase is 4 mM, and this is increased to about 50 mM in the presence of low-Mr ADP-ribose acceptors. Only molecules having both the adenine and nicotinamide moieties of NAD+ with minor alterations in the nicotinamide ring can be competitive inhibitors of this reaction. 2. This high Km for NAD+ is also reflected in the dissociation constant, Kd, which was determined by a variety of methods. 3. Results from equilibrium dialysis were subject to high error, but showed one binding site and a Kd of about 3 mM. 4. The A1 peptide of the toxin is digested by trypsin, and this digestion is completely prevented by concentrations of NAD+ above 50 mM. Measurement (by densitometric scanning of polyacrylamide-gel electrophoretograms) of the rate of tryptic digestion at different concentrations of NAD+ allowed a more accurate determination of Kd = 4.0 +/- 0.4 mM. Some analogues of NAD+ that are competitive inhibitors of the glycohydrolase reaction also prevented digestion.     

ADP-ribosyl transferase and NAD glycohydrolase activities in rat liver mitochondria

ADP-ribosyl transferase and NAD glycohydrolase activities have been estimated in mitochondria in mitoplasts as well as in other submitochondrial fractions. A high activity of these two enzymes was present in mitoplasts as compared to the outer membrane preparation or intermembrane compartment. Inhibitor studies provide strong evidence for the involvement of ADP-ribosyl transferase in the process of ADP-ribosylation of mitochondrial proteins. When NAD glycohydrolase was blocked by nicotinamide or 3-aminobenzamide, the incorporation of ADP-ribose into mitochondrial proteins still occurs. ADP-ribosyl transferase activity could also be detected when NAD glycohydrolase was separated by hydroxylapatite chromatography. The protein-linked ADP-ribose moiety appears to be an oligomer in mitochondria.     

Muscarinic cholinergic stimulation of inositol phosphate production in cultured embryonic chick atrial cells. Evidence for a role of two guanine-nucleotide-binding proteins.

These studies demonstrate a novel mechanism for the coupling of the muscarinic receptor to phospholipase C activity in embryonic chick atrial cells. In monolayer cultures of atrial cells from hearts of embryonic chicks at 14 days in ovo, carbamylcholine stimulated the sequential appearance of InsP3, InsP2 and InsP1 with an EC50 (concn. causing 50% of maximal stimulation) of 30 microM. In the presence of 15 mM-Li, a 5 min exposure to carbamylcholine (0.1 mM) increased InsP3 levels to a maximum of 47 +/- 12% over basal, InsP2 to 108 +/- 13% over basal and InsP1 to 42 +/- 5% over basal. This effect was blocked by 5 microM-atropine. Incubation of these cells with pertussis toxin (15 h; 0.5 ng/ml) inhibited carbamylcholine-stimulated InsP3, InsP2 and InsP1 formation by 42 +/- 7%, 30 +/- 3% and 48 +/- 7% respectively. The IC50 (concn. causing 50% inhibition) for pertussis toxin inhibition of all three inositol phosphates was 0.01 ng/ml, with a half-time of 6 h at 0.5 ng/ml. This partial sensitivity to pertussis toxin was not due to incomplete ADP-ribosylation of the guanine-nucleotide-binding protein (G-protein), since autoradiography of polyacrylamide gels of cell homogenates incubated with [32P]NAD+ in the presence of pertussis toxin demonstrated that incubation of cells with 0.5 ng of pertussis toxin/ml for 15 h resulted in complete ADP-ribosylation of pertussis toxin substrates by endogenous NAD+. In cells permeabilized with saponin (10 micrograms/ml), 0.1 mM-GTP[S] (guanosine 5'-[gamma-thio]triphosphate) stimulated InsP1 by 102 +/- 15% (mean +/- S.E.M., n = 4), InsP2 by 421 +/- 67% and InsP3 by 124 +/- 33% above basal. Incubation of cells for 15 h with 0.5 ng of pertussis toxin/ml decreased GTP[S]-stimulated InsP1 production in saponin-treated cells by 30 +/- 10% (n = 3), InsP2 production by 45 +/- 7% (n = 4) and InsP3 production by 49 +/- 6% (n = 4). These data demonstrate that in embryonic chick atrial cells at least two independent G-proteins, a pertussis toxin-sensitive G-protein and a pertussis toxin-insensitive G-protein, play a role in coupling muscarinic agonist binding to phospholipase C activation and to inositol phosphate production.