Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0043167 (pertussis)
19,595 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Pertussis toxin is a member of ADP-ribosylating bacterial toxins that are capable of catalyzing the cleavage of the N-glycosidic bond of NAD+ and the transfer of its ADP-ribose moiety to G proteins. The catalytic S1 subunit of pertussis toxin uses signal transducing G proteins as acceptor substrates but can also catalyze the transfer of the ADP-ribose moiety to water in the absence of G proteins. Site-directed mutagenesis followed by kinetic analyses of truncated soluble mutant proteins revealed that His-35 of S1 is a catalytic residue because alterations of this residue affect the turnover rate of NAD-glycohydrolysis by approximately two orders of magnitude without significantly affecting substrate binding. Replacement of the imidazole of His-35 by the side chain of glutamine maintained the highest residual activity. The pH dependence of the enzyme activity showed only slight variations over the experimental range with an optimum at pH 7.5 and an approximate pKa of 6.5 to 7. This pH dependence was abolished by the Gln substitution, which still retained significant activity, suggesting that His-35 probably does not act as a true base but rather as a proton acceptor. Direct catalytic roles for several other residues were ruled out. Ser-52 substitutions resulted in slight alterations of both kcat and Km for NAD+ suggesting an involvement in maintaining the local geometry of the active site rather than a direct role in catalysis for this residue. Kinetic studies on mutants with substitutions of Ser-40 indicate a role in NAD+ binding for this residue. In conjunction with previous findings, these studies suggest that the NAD-glycohydrolase activity of S1 utilizes 2 catalytic residues, His-35 and the previously identified Glu-129. The enzyme mechanism could therefore proceed through an activation by polarization of the acceptor substrate water or G protein by His-35, and the stabilization of an oxocarbonium-like transition state intermediate by Glu-129.
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PMID:The NAD-glycohydrolase activity of the pertussis toxin S1 subunit. Involvement of the catalytic HIS-35 residue. 811 96

Pertussis toxin is a complex protein composed of five different subunits, named S1 through S5 and arranged in an A-B structure. The B oligomer, composed of S2 through S5, is the receptor-binding moiety, and the A promoter, composed of S1, is the enzymatically active moiety. S1 catalyzes the ADP-ribosylation of a cysteine in the alpha subunit of heterotrimeric G proteins. In the absence of G proteins it also catalyzes the cleavage of NAD+ into ADP-ribose and nicotinamide. Molecular dissection has indicated that the C-terminal domain of S1 is involved in G-protein binding, while the N-terminal domain, homologous to other ADP-ribosylating toxins, contains the NAD(+)-binding site and the residues involved in catalysis. By site-directed mutagenesis and kinetic analyses Glu-129 and His-35 were identified as the catalytic residues. Glutamates analogous to Glu-129 are found in all studied ADP-ribosylating toxins, while His-35 is less well conserved. This suggests that Glu-129 acts on the common substrate NAD+, whereas His-35 plays its role on the acceptor substrates. We propose a mechanism in which Glu-129 exerts its action on the 2'-OH group of the NAD+ ribose, thereby facilitating the formation of an oxocarbonium-like intermediate and the weakening of the N-glycosidic bond. His-35 could increase the nucleophilicity of the cysteine in the G protein or the water molecule to attack the weakened N-glycosidic bond of NAD+ and yield the products of the reaction.
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PMID:A proposed mechanism of ADP-ribosylation catalyzed by the pertussis toxin S1 subunit. 852 86

We have recently reported that gangliosides act as inhibitors of ADP-ribosyltransferases and NAD+ glycohydrolases (NADase) of pertussis toxin and the C3 exoenzyme from Clostridium botulinum (Hara-Yokoyama, M., Hirabayashi, Y., Irie, F., Syuto, B., Moriishi, K., Sugiya, H., and Furuyama, S. (1995) J. Biol. Chem. 270, 8115-8121). Here, we investigated the effect of gangliosides on the enzymatic activity of leukocyte cell surface antigen CD38, which is identified as an ecto-NADase (Kontani, K., Nishina, H., Ohoka, Y., Takahashi, K., and Katada, T. (1993) J. Biol. Chem. 268, 16895-16898). Gangliosides GM1a and GQ1balpha inhibited the NADase activity in the immunoprecipitate of anti-CD38 antibody from the membrane extract of retinoic acid-treated human leukemic HL-60 cells. Gangliosides also inhibited the NADase activity of the extracellular domain of CD38 antigen that was deprived of the transmembrane domain and was expressed in Escherichia coli as a fusion protein with maltose-binding protein (MBP-CD38). The order of the inhibitory effect of purified ganglioside species on the NADase activity on MBP-CD38 was as follows: GQ1balpha > GT1b, GQ1b > GD1a, GD1b, GM1a, GM1b, GD3, GM3. GQ1balpha inhibited the NADase of MBP-CD38 in a noncompetitive manner versus NAD+ with a Ki value of about 0.3 microM. Neither ceramide nor the oligosaccharide moiety of GQ1balpha had an effect on the NADase activity. GQ1balpha, GT1b, and GQ1b also efficiently inhibited the ADP-ribosyl cyclase activity of MBP-CD38. At present, gangliosides are the only endogenous species that can block the enzymatic activity of CD38 antigen. The present results suggest a potential role of gangliosides as inhibitors of the ecto-NADases.
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PMID:Inhibition of NAD+ glycohydrolase and ADP-ribosyl cyclase activities of leukocyte cell surface antigen CD38 by gangliosides. 866 99

Pertussis toxin from Bordatella pertussis catalyzes the ADP ribosylation of several G-proteins, using NAD+ as a substrate. In the absence of an acceptor protein, the toxin acts as a NAD+ glycohydrolase. Pertussis toxin is one of the virulent factors for whooping cough and therefore a target for site-specific inhibitors based on the transition state structure. A family of kinetic isotope effects was determined for the hydrolysis reaction, using NAD+ labeled with 3H, 14C, and 15N as substrates. Primary isotope effects were 1.021 +/- 0.001 for [1'N-14C]NAD+ and 1.021 +/- 0.004 for [1N-15N]NAD+, and the double-primary effect of [1'N-14C,1N-15N]NAD+ was 1.049 +/- 0.004. Secondary kinetic isotope effects were 1.207 +/- 0.010 for the [1'N-3H]-, 1.144 +/- 0.005 for the [2'N-3H]-, 0.989 +/- 0.001 for the [4'N-3H]-, and 1.019 +/- 0.004 for the [5'N-3H]NAD+, respectively. Commitment to catalysis was excluded by isotope trapping experiments, and the experimental kinetic isotope effects were independent of pH. The measured isotope effects are therefore intrinsic. The isotope effects are remarkable because they indicate an oxocarbenium-like ribose ring at the transition state but a stiffer than expected vibrational environment for C1' at the reaction center. On the basis of these isotope effects, a bond order vibrational analysis was performed to locate a transition state structure consistent with the isotope effects. The kinetic isotope effects predict a residual bond order to the nicotinamide leaving group of 0.11, corresponding to a distance of 2.14 A. Participation of the water nucleophile is weak, consistent either with an S(N)1-like transition state with no water interaction or with the water oxygen no closer than 3.5 A from the reaction center. The positive charge of the ribose oxocarbenium is stabilized by delocalization between the C1'-O4' and C1'-C2' bonds. The enzyme contacts restrict the vibrational environment of the reaction coordinate requiring increased bonding force constants for the enzyme-stabilized transition state. NAD+ analogues with the nicotinamide ribose replaced by an iminoribitol ring, mimicking the flattened ribose ring of the transition state, are expected to be transition state inhibitors.
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PMID:Kinetic isotope effect characterization of the transition state for oxidized nicotinamide adenine dinucleotide hydrolysis by pertussis toxin. 910 61

Pertussis toxin from Bordetella pertussis is one of the ADP-ribosylating toxins which are the cytotoxic agents of several infectious diseases. Transition state analogues of these enzymes are expected to be potent inhibitors and may be useful in therapy. Pertussis toxin catalyzes the ADP-ribosylation of a cysteine in the synthetic peptide alphai3C20, corresponding to the C-terminal 20 amino acids of the alpha-subunits of the G-protein Gi3. A family of kinetic isotope effects was determined for the ADP-ribosylation reaction, using 3H-, 14C- and 15N-labeled NAD+ as substrates. Primary kinetic isotope effects were 1.050 +/- 0.006 for [1'N-14C] and 1.021 +/- 0.002 for [1N-15N], the double primary effect of [1'N-14C,1N-15N] was 1.064 +/- 0.002. Secondary kinetic isotope effects were 1.208 +/- 0.014 for [1'N-3H], 1.104 +/- 0.010 for [2'N-3H], 0.989 +/- 0.001 for [4'N-3H], and 1.014 +/- 0.002 for [5'N-3H]. Isotope trapping experiments yielded a commitment factor of 0.01, demonstrating that the observed isotope effects are near intrinsic. Solvent D2O kinetic isotope effects are inverse, consistent with deprotonation of the attacking Cys prior to transition state formation. The transition state structure was determined by a normal mode bond vibrational analysis. The transition state is characterized by a nicotinamide leaving group bond order of 0.14, corresponding to a bond length of 2.06 A. The incoming thiolate nucleophile has a bond order of 0.11, corresponding to 2.47 A. The ribose ring has strong oxocarbenium ion character. Pertussis toxin also catalyzes the slow hydrolysis of NAD+ in the absence of peptides. Comparison of the transition states for NAD+ hydrolysis and for ADP-ribosylation of peptide alphai3C20 indicates that the sulfur nucleophile from the peptide Cys participates more actively as a nucleophile in the reaction than does water in the hydrolytic reaction. Participation of the thiolate anion at the transition state provides partial neutralization of the cationic charge which normally develops at the transition states of N-ribohydrolases and transferases. Thus, the presence of the peptide provides increased SN2 character in a loose transition state which retains oxocarbenium character in the ribose.
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PMID:Pertussis toxin: transition state analysis for ADP-ribosylation of G-protein peptide alphai3C20. 920 66

Cyclic ADP-ribose (cADP-ribose) is an endogenous modulator of ryanodine-sensitive Ca2+ release channels. An unsolved question is whether or not cADP-ribose mediates intracellular signals from hormone or neurotransmitter receptors. The first step in this study was to develop a TLC method to measure ADP-ribosyl cyclase, by which conversion of [3H]NAD+ to [3H]cADP-ribose was confirmed in COS-7 cells overexpressing human CD38. A membrane fraction of NG108-15 neuroblastoma x glioma hybrid cells possessed ADP-ribosyl cyclase activity measured by TLC. Carbamylcholine increased this activity by 2.6-fold in NG108-15 cells overexpressing m1 or m3 muscarinic acetylcholine receptors (mAChRs), but inhibited it by 30-52% in cells expressing m2 and/or m4 mAChRs. Both of these effects were mimicked by GTP. Pretreatment of cells with cholera toxin blocked the activation, whereas pertussis toxin blocked the inhibition. Application of carbamylcholine caused significant decreases in NAD+ concentrations in untreated m1-transformed NG108-15 cells, but an increase in cholera toxin-treated cells. These results suggest that mAChRs couple to ADP-ribosyl cyclase within cell membranes via trimeric G proteins and can thereby control cellular function by regulating cADP-ribose formation.
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PMID:Muscarinic receptor-mediated dual regulation of ADP-ribosyl cyclase in NG108-15 neuronal cell membranes. 939 53

Pertussis toxin (PT) catalyzes ADP-ribosylation of G protein alpha subunits, thus preventing their role as transducers of external signals targeting metabolic pathways. In vitro, in human circulating lymphocytes insulin at physiological concentrations (5 microU/ml) determines sharp activation of pyruvate dehydrogenase (PDH), the rate limiting enzyme in glucose oxidative breakdown. This study evaluates whether the above-described effects of insulin over PDH are mediated through G proteins. Human circulating lymphocytes (six samples from different donors) were exposed to insulin (5 microU/ml), PT (1-2 micrograms/ml) or PT-9K, a mutated PT void of catalytic activity (1-10 micrograms/ml), and to insulin in combination with the two toxins, and then assessed for PDH activity. Plasma membranes from cells incubated with and without PT or PT-9K were subjected to ADP-ribosylation in the presence of [32P] NAD+ and activated PT. In circulating lymphocytes exposed to PT alone, or in combination with insulin, PDH activity falls significantly below basal values (P < 0.001); PT-9K instead has no effect on basal or on insulin-stimulated PDH activity. ADP-ribosylation of a plasma membrane component with apparent molecular mass (42 kDa) comparable to that of the Gi (inhibitory) protein alpha subunit takes place in cells exposed to PT but not in those exposed to PT-9K. In human circulating lymphocytes Gi proteins or Gi protein-like components appear to be involved in preserving basal PDH activity as well as in the mechanism by which insulin exerts its control over PDH.
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PMID:G proteins and regulation of pyruvate dehydrogenase activity by insulin in human circulating lymphocytes. 943 82

Pertussis toxin ADP-ribosylates a specific Cys side chain in the alpha-subunit of several G-proteins. Recombinant Gialpha1-subunits were rapidly ADP-ribosylated in the absence of betagamma-subunits, with a Km of 800 microM and a kcat of 40 min-1. Addition of betagamma-subunits decreases Km to 0.3 microM with little change of kcat. Kinetic isotope effects established the transition-state structure for ADP-ribosylation of Gialpha1 subunits. The transition state is dissociative, with a 2.1 A bond to the nicotinamide leaving group and a bond of 2.5 A to the sulfur nucleophile. The nucleophilic participation of Gialpha1 at the transition state is greater than that for water in the hydrolysis of NAD+by pertussis toxin. Crystal structures for Gialpha1 show the Cys nucleophile in a disordered segment or inaccessible for attack on NAD+. Therefore, transition-state formation requires an altered Gialpha1 conformation to expose and ionize Cys. The transition state has been docked into the crystal structure of pertussis toxin in a geometry required for transition state formation.
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PMID:Transition-state structure for the ADP-ribosylation of recombinant Gialpha1 subunits by pertussis toxin. 948 25

Gi/Go proteins are uncoupled from receptors by ADP-ribosylation with pertussis toxin (PTX). However, PTX treatment of delta opioid receptor-containing NG108-15 cells reduces, but does not eliminate, opioid inhibition of adenylyl cyclase. The present study explored potential mechanisms of this residual inhibition. Overnight treatment of NG108-15 cells with 100 ng/ml PTX eliminated both PTX-catalyzed [adenylyl-32P]NAD+-labeling of G proteins and agonist stimulation of low Km GTPase in membranes. Although PTX-treatment decreased the maximal opioid inhibition of adenylyl cyclase by 50-65%, the inhibition that remained was concentration-dependent and antagonist-reversible. This inhibition persisted in the absence of GTP (even though opioid inhibition of adenylyl cyclase in untreated membranes was GTP-dependent), but was eliminated by hydrolysis-resistant guanine nucleotide analogs, indicating that G-proteins were still involved in the coupling mechanism. However, assays of agonist-stimulated [35S]GTPgammaS binding in the presence of excess GDP indicated that PTX pretreatment eliminated stimulation of guanine nucleotide exchange by opioid agonists. These results suggest that in membranes from PTX-treated NG108-15 cells, a subpopulation of G proteins may transduce an inhibitory signal from agonist-bound opioid receptors without involvement of guanine nucleotide exchange.
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PMID:Opioid inhibition of adenylyl cyclase in membranes from pertussis toxin-treated NG108-15 cells. 949 66

ADP-ribosyl cyclase activities in cultured rat astrocytes were examined by using TLC for separation of enzymatic products. A relatively high rate of [3H]cyclic ADP-ribose production converted from [3H]NAD+ by ADP-ribosyl cyclase (2.015+/-0.554 nmol/min/mg of protein) was detected in the crude membrane fraction of astrocytes, which contained approximately 50% of the total cyclase activity in astrocytes. The formation rate of [3H]ADP-ribose from cyclic ADP-ribose by cyclic ADP-ribose hydrolase and/or from NAD+ by NAD glycohydrolase was low and enriched in the cytosolic fraction. Although NAD+ in the extracellular medium was metabolized to cyclic ADP-ribose by incubating cultures of intact astrocytes, the presence of Triton X-100 in the medium for permeabilizing cells increased cyclic ADP-ribose production three times as much. Isoproterenol and GTP increased [3H]cyclic ADP-ribose formation in crude membrane-associated cyclase activity. This isoproterenol-induced stimulation of membrane-associated ADP-ribosyl cyclase activity was confirmed by cyclic GDP-ribose formation fluorometrically. This stimulatory action was blocked by prior treatment of cells with cholera toxin but not with pertussis toxin. These results suggest that ADP-ribosyl cyclase in astrocytes has both extracellular and intracellular actions and that signals of beta-adrenergic stimulation are transduced to membrane-bound ADP-ribosyl cyclase via G proteins within cell surface membranes of astrocytes.
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PMID:Membrane-bound form of ADP-ribosyl cyclase in rat cortical astrocytes in culture. 1064 18


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