Evidence for a catalytic role of glutamic acid 129 in the NAD-glycohydrolase activity of the pertussis toxin S1 subunit

Pasteurian Contributions to the Study of Bordetella pertussis Toxins

As a tribute to Louis Pasteur on the occasion of the 200th anniversary of his birth, this article summarizes the main contributions of scientists from Pasteur Institutes to the current knowledge of toxins produced by Bordetella pertussis. The article therefore focuses on publications authored by researchers from Pasteur Institutes and is not intended as a systematic review of B. pertussis toxins. Besides identifying B. pertussis as the causative agent of whooping cough, Pasteurians have made several major contributions with respect to the structure–function relationship of the Bordetella lipo-oligosaccharide, adenylyl cyclase toxin and pertussis toxin. In addition to contributing to the understanding of these toxins’ mechanisms at the molecular and cellular levels and their role in pathogenesis, scientists at Pasteur Institutes have also exploited potential applications of the gathered knowledge of these toxins. These applications range from the development of novel tools to study protein–protein interactions over the design of novel antigen delivery tools, such as prophylactic or therapeutic vaccine candidates against cancer and viral infection, to the development of a live attenuated nasal pertussis vaccine. This scientific journey from basic science to applications in the field of human health matches perfectly with the overall scientific objectives outlined by Louis Pasteur himself.

The History of Pertussis Toxin

Besides the typical whooping cough syndrome, infection with Bordetella pertussis or immunization with whole-cell vaccines can result in a wide variety of physiological manifestations, including leukocytosis, hyper-insulinemia, and histamine sensitization, as well as protection against disease. Initially believed to be associated with different molecular entities, decades of research have provided the demonstration that these activities are all due to a single molecule today referred to as pertussis toxin. The three-dimensional structure and molecular mechanisms of pertussis toxin action, as well as its role in protective immunity have been uncovered in the last 50 years. In this article, we review the history of pertussis toxin, including the paradigm shift that occurred in the 1980s which established the pertussis toxin as a single molecule. We describe the role molecular biology played in the understanding of pertussis toxin action, its role as a molecular tool in cell biology and as a protective antigen in acellular pertussis vaccines and possibly new-generation vaccines, as well as potential therapeutical applications.

Genetically detoxified pertussis toxin displays near identical structure to its wild-type and exhibits robust immunogenicity

The mutant gdPT R9K/E129G is a genetically detoxified variant of the pertussis toxin (PTx) and represents an attractive candidate for the development of improved pertussis vaccines. The impact of the mutations on the overall protein structure and its immunogenicity has remained elusive. Here we present the crystal structure of gdPT and show that it is nearly identical to that of PTx. Hydrogen-deuterium exchange mass spectrometry revealed dynamic changes in the catalytic domain that directly impacted NAD⁺ binding which was confirmed by biolayer interferometry. Distal changes in dynamics were also detected in S2-S5 subunit interactions resulting in tighter packing of B-oligomer corresponding to increased thermal stability. Finally, antigen stimulation of human whole blood, analyzed by a previously unreported mass cytometry assay, indicated broader immunogenicity of gdPT compared to pertussis toxoid. These findings establish a direct link between the conserved structure of gdPT and its ability to generate a robust immune response.

Structure-function analyses of a pertussis-like toxin from pathogenic Escherichia coli reveal a distinct mechanism of inhibition of trimeric G-proteins

Pertussis-like toxins are secreted by several bacterial pathogens during infection. They belong to the AB₅ virulence factors, which bind to glycans on host cell membranes for internalization. Host cell recognition and internalization are mediated by toxin B subunits sharing a unique pentameric ring-like assembly. Although the role of pertussis toxin in whooping cough is well-established, pertussis-like toxins produced by other bacteria are less studied, and their mechanisms of action are unclear. Here, we report that some extra-intestinal Escherichia coli pathogens (i.e. those that reside in the gut but can spread to other bodily locations) encode a pertussis-like toxin that inhibits mammalian cell growth in vitro We found that this protein, EcPlt, is related to toxins produced by both nontyphoidal and typhoidal Salmonella serovars. Pertussis-like toxins are secreted as disulfide-bonded heterohexamers in which the catalytic ADP-ribosyltransferase subunit is activated when exposed to the reducing environment in mammalian cells. We found here that the reduced EcPlt exhibits large structural rearrangements associated with its activation. We noted that inhibitory residues tethered within the NAD⁺-binding site by an intramolecular disulfide in the oxidized state dissociate upon the reduction and enable loop restructuring to form the nucleotide-binding site. Surprisingly, although pertussis toxin targets a cysteine residue within the α subunit of inhibitory trimeric G-proteins, we observed that activated EcPlt toxin modifies a proximal lysine/asparagine residue instead. In conclusion, our results reveal the molecular mechanism underpinning activation of pertussis-like toxins, and we also identified differences in host target specificity.

Investigating pertussis toxin and its impact on vaccination

Whooping cough, caused by Bordetella pertussis, remains a major global health problem. Each year around 40 million of pertussis cases resulting in 200,000-400,000 annual deaths occur worldwide. Pertussis toxin is a major virulence factor of B. pertussis. Murine studies have shown its importance in bacterial colonization and in immunomodulation to evade innate or adaptive immunity. The toxin is composed of an A protomer expressing ADP-ribosyltransferase activity and a B oligomer, responsible for toxin binding to target cells. The toxin is also a major protective antigen in all currently available vaccines. However, vaccine escape mutants with altered toxin expression have recently been isolated in countries with high vaccination coverage illustrating the need for improved pertussis vaccines.

Genetically detoxified pertussis toxin (PT-9K/129G): implications for immunization and vaccines

Pertussis toxin (PT) is one of the major virulence factors of Bordetella pertussis and the primary component of all pertussis vaccines available to date. Because of its various noxious effects the toxin needs to be detoxified. In all currently available vaccines, detoxification is achieved by treatment with high quantity of chemical agents such as formaldehyde, glutaraldehyde or hydrogen peroxide. Although effective in detoxification, this chemical treatment alters dramatically the immunological properties of the toxin. In contrast, PT genetically detoxified through the substitution of two residues necessary for its enzymatic activity maintains all functional and immunological properties. This review describes in detail the characteristics of this PT-9K/129G mutant and shows that it is non-toxic and a superior immunogen compared with chemically detoxified PT. Importantly, data from an efficacy trial show that the PT-9K/129G-based vaccine induces earlier and longer-lasting protection, further supporting the hypothesis that PT-9K/129G represents an ideal candidate for future pertussis vaccine formulations.

The ins and outs of pertussis toxin

Pertussis toxin, produced and secreted by the whooping cough agent Bordetella pertussis, is one of the most complex soluble bacterial proteins. It is actively secreted through the B. pertussis cell envelope by the Ptl secretion system, a member of the widespread type IV secretion systems. The toxin is composed of five subunits (named S1 to S5 according to their decreasing molecular weights) arranged in an A-B structure. The A protomer is composed of the enzymatically active S1 subunit, which catalyzes ADP-ribosylation of the α subunit of trimeric G proteins, thereby disturbing the metabolic functions of the target cells, leading to a variety of biological activities. The B oligomer is composed of 1S2:1S3:2S4:1S5 and is responsible for binding of the toxin to the target cell receptors and for intracellular trafficking via receptor-mediated endocytosis and retrograde transport. The toxin is one of the most important virulence factors of B. pertussis and is a component of all current vaccines against whooping cough.

Poly(ADP-ribose)-polymerase-catalyzed hydrolysis of NAD+: QM/MM simulation of the enzyme reaction

Poly(ADP-ribose) polymerase (PARP) is a nuclear enzyme which uses NAD+ as substrate and catalyzes the transfer of multiple units of ADP-ribose to target proteins. PARP is an attractive target for the discovery of novel therapeutic agents and PARP inhibitors are currently evaluated for the treatment of a variety of pathological conditions such as brain ischemia, inflammation, and cancer. Herein, we use the PARP-catalyzed reaction of NAD+ hydrolysis as a model for gaining insight into the molecular details of the catalytic mechanism of PARP. The reaction has been studied in both the gas-phase and in the enzyme environment through a QM/MM approach. Our results indicate that the cleavage reaction of the nicotinamide-ribosyl bond proceeds through an SN2 dissociative mechanism via an oxacarbenium transition structure. These results confirm the importance of the structural water molecule in the active site and may constitute the basis for the design of transition-state-based PARP inhibitors.

The pertussis toxin S1 subunit is a thermally unstable protein susceptible to degradation by the 20S proteasome

Pertussis toxin (PT) is an AB-type protein toxin that consists of a catalytic A subunit (PT S1) and an oligomeric, cell-binding B subunit. It belongs to a subset of AB toxins that move from the cell surface to the endoplasmic reticulum (ER) before the A chain passes into the cytosol. Toxin translocation is thought to involve A chain unfolding in the ER and the quality control mechanism of ER-associated degradation (ERAD). The absence of lysine residues in PT S1 may allow the translocated toxin to avoid ubiquitin-dependent degradation by the 26S proteasome, which is the usual fate of exported ERAD substrates. As the conformation of PT S1 appears to play an important role in toxin translocation, we used biophysical and biochemical methods to examine the structural properties of PT S1. Our in vitro studies found that the isolated PT S1 subunit is a thermally unstable protein that can be degraded in a ubiquitin-independent fashion by the core 20S proteasome. The thermal denaturation of PT S1 was inhibited by its interaction with NAD, a donor molecule used by PT S1 for the ADP ribosylation of target G proteins. These observations support a model of intoxication in which toxin translocation, degradation, and activity are all influenced by the heat-labile nature of the isolated toxin A chain.

Homology modeling and molecular dynamics studies of a novel C3-like ADP-ribosyltransferase

The novel C3-like ADP-ribosyltransferase is produced by a Staphylococcus aureus strain that especially ADP-ribosylates RhoE/Rnd3 subtype proteins, and its three-dimensional (3D) structure has not known. In order to understand the catalytic mechanism, the 3D structure of the protein is built by using homology modeling based on the known crystal structure of exoenzyme C3 from Clostridium botulinum (1G24). Then the model structure is further refined by energy minimization and molecular dynamics methods. The putative nicotinamide adenine dinucleotide (NAD(+))-binding pocket of exoenzyme C3(Stau) is determined by Binding-Site Search module. The NAD(+)-enzyme complex is developed by molecular dynamics simulation and the key residues involved in the combination of enzyme binding to the ligand-NAD(+) are determined, which is helpful to guide the experimental realization and the new mutant designs as well. Our results indicated that the key binding-site residues of Arg48, Glu180, Ser138, Asn134, Arg85, and Gln179 play an important role in the catalysis of exoenzyme C3(Stau), which is in consistent with experimental observation.

NarE: a novel ADP-ribosyltransferase from Neisseria meningitidis

Mono ADP-ribosyltransferases (ADPRTs) are a class of functionally conserved enzymes present in prokaryotic and eukaryotic organisms. In bacteria, these enzymes often act as potent toxins and play an important role in pathogenesis. Here we report a profile-based computational approach that, assisted by secondary structure predictions, has allowed the identification of a previously undiscovered ADP-ribosyltransferase in Neisseria meningitidis (NarE). NarE shows structural homologies with E. coli heat-labile enterotoxin (LT) and cholera toxin (CT) and possesses ADP-ribosylating and NAD-glycohydrolase activities. As in the case of LT and CT, NarE catalyses the transfer of the ADP-ribose moiety to arginine residues. Despite the absence of a signal peptide, the protein is efficiently exported into the periplasm of Neisseria. The narE gene is present in 25 out of 43 strains analysed, is always present in ET-5 and Lineage 3 but absent in ET-37 and Cluster A4 hypervirulent lineages. When present, the gene is 100% conserved in sequence and is inserted upstream of and co-transcribed with the lipoamide dehydrogenase E3 gene. Possible roles in the pathogenesis of N. meningitidis are discussed.

Kinetic isotope effect characterization of the transition state for oxidized nicotinamide adenine dinucleotide hydrolysis by pertussis toxin

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.

Using secondary structure predictions and site-directed mutagenesis to identify and probe the role of potential active site motifs in the RT6 mono(ADP-ribosyl)transferases

The RT6 T cell mono(ADP-ribosyl)transferases are expressed as GPI-anchored membrane proteins by mature T lymphocytes. We performed secondary structure prediction analyses of RT6 with a profile based neural network system based on multiple alignments of RT6 with other vertebrate mono(ADP-ribosyl)transferases (mADPRTs). The results reveal a linear order of predicted beta sheets/alpha helix in RT6 that are quite similar to those in the catalytic subunit of the four known crystal structures of mono-ADP-ribosylating bacterial toxins. Recognizable amino acid similarities occur throughout the region of predicted structural homology to the bacterial toxins. Three residues which have been shown to be important for catalysis in bacterial toxins (e.g. R9, S52 and E129 in pertussis toxin) occur in a similar context also in RT6 (R126, S147 and E189). We have mutated these residues in RT6 by site-directed mutagenesis. The RT6 mutants exhibit remarkably similar alterations in enzymatic phenotype as those reported for mutations of the proposed analagous residues in bacterial toxins. These results support the hypothesis that eu- and procaryotic mADPRTs share a common fold and have a common ancestry.

Mouse T cell membrane proteins Rt6-1 and Rt6-2 are arginine/protein mono(ADPribosyl)transferases and share secondary structure motifs with ADP-ribosylating bacterial toxins

Mono ADP-ribosylation is a posttranslational protein modification that has been implicated in the regulation of key biological functions in bacteria as well as in animals. Recently, the first cDNAs for eucaryotic mono(ADPribosyl)transferases were cloned and found to exhibit significant sequence similarity only to one other known protein, the T cell differentiation antigen Rt6. In this paper we describe secondary structure analyses of Rt6 and related proteins and show conserved structure motifs and amino acid residues consistent with a common ancestry of these eucaryotic proteins and bacterial ADP-ribosyltransferases. Moreover, we have expressed soluble mouse Rt6-1 and Rt6-2 gene products in which C-terminal tags (FLAG-His6) replace the native glycosylphosphatidylinositol anchor signal sequences. Purified recombinant Rt6-2, but not Rt6-1, shows NAD+ glycohydrolase activity, which is inhibited by the arginine analogue agmatine. Immunoprecipitation of recombinant Rt6-1 and Rt6-2 with anti-FLAG M2 antibody followed by incubation with [32P]NAD+ leads to rapid and covalent incorporation of radioactivity into the light chain of the M2 antibody. The bound label is resistant to treatment with HgCl2 but sensitive to NH2OH, characteristic of arginine-linked ADP-ribosylation. These results demonstrate that Rt6-1 and RT6-2 possess the enzymatic activities typical for NAD+-dependent arginine/protein mono(ADPribosyl)transferases (EC 2.4.2.31). They are the first such enzymes to be molecularly characterized in the immune system.

Identification of glutamic acid 381 as a candidate active site residue of Pseudomonas aeruginosa exoenzyme S

Exoenzyme S of Pseudomonas aeruginosa (ExoS) is a member of the family of bacterial ADP-ribosylating exotoxins (bAREs). Site-directed mutagenesis of glutamic acids within the catalytic domain of ExoS (termed delta N222) allowed the identification of the preferential inactivation of ADP-ribosyltransferase activity by alanine substitution of E381. The specific activity of E381A mutant was 0.02% of wild-type delta N222. Delta N222(E381A) retained the requirement of factor activating exoenzyme S (FAS) activation for the expression of ADP-ribosyltransferase activity. In contrast, E387A, E399A, and E414A mutants possessed ADP-ribosyltransferase activity similar to that of wild-type delta N222. Kinetic evaluation of E381A and two other mutants, E381D and E381S, showed that their primary defect was a lower kcat in the ADP-ribosylation of soybean trypsin inhibitor (SBTI). The Km for NAD and SBTI and activation by FAS varied 2- and 10-fold relative to delta N222. In addition, the E381 mutants possessed identical protease patterns during thrombin and trypsin digestion as delta N222, which indicated that E381 mutants had retained their overall conformation. Together, these data identify E381 as contributing to the catalytic activity of exoenzyme S.

Active site mutation of the C3-like ADP-ribosyltransferase from Clostridium limosum--analysis of glutamic acid 174

Clostridium limosum ADP-ribosyltransferase modifies low molecular mass GTP-binding proteins of the Rho subtype family. Here we cloned and sequenced the gene of the transferase and expressed it in Escherichia coli. The gene encodes a protein of 250 amino acids (M(r) = 27,840), with a putative signal peptide of 45 amino acids, that shows about 60-65% identity with C3 transferases from Clostridium botulinum. The mature C. limosum transferase was expressed as a maltose-binding fusion protein in E. coli and purified to apparent homogeneity. To study the functional role of Glu174 of C. limosum transferase, which was recently photoaffinity-labeled with [carbonyl-14C]NAD [Jung, M., et al. (1993) J. Biol. Chem. 268, 23215-23218], two mutants E174D and E174Q were constructed by a polymerase chain reaction-based system. The E174D and E174Q mutants showed a dramatic decrease in kcat, but no major changes in Km,NAD. Furthermore, replacement of Glu174 by aspartic acid and glutamine largely reduced and completely blocked UV-induced incorporation of [carbonyl-14C]NAD into the transferase. The data indicate that Glu174 is an active site residue of C. limosum transferase.

Mono-ADP-ribosylation: a reversible posttranslational modification of proteins

Mono-ADP-ribosyltransferase activity has been detected in numerous vertebrate tissues and transferase cDNAs from a few species have recently been cloned. In vitro ADP-ribosylation has been demonstrated with diverse substrates such as phosphorylase kinase, actin, and Gs alpha resulting in the alteration of substrate function. ADP-ribosylation of endogenous target proteins has been observed in chicken heterophils, rat brain, and human platelets, and integrin alpha 7 was found to be the endogenous substrate of the GPI-anchored rabbit skeletal muscle transferase. The reversibility of ADP-ribosylation is made possible by ADP-ribosylarginine hydrolases which have been isolated and cloned from rodent and human tissues. The transferases and hydrolases could in principle form an intracellular ADP-ribosylation regulatory cycle. In the case of the skeletal muscle transferases, however, processing of ADP-ribosylated integrin alpha 7 is carried out by phosphodiesterases and possibly phosphatases (Fig. 1). Most bacterial toxin and eukaryotic mono-ADP-ribosyltransferases, and perhaps other NAD-utilizing enzymes such as the RT6 family of proteins, share a common catalytic-site structure despite a lack of overall sequence identity. The transferases that have been studied thus far possess a critical glutamic acid and other amino acids at the catalytic cleft which function to position NAD for nucleophilic attack at the N-glycosidic linkage for either ADP-ribose transfer or NAD hydrolysis. The amino acid differences among transferases at the active site may reflect different catalytic mechanisms of ADP-ribosylation or may be required for accommodating the different ADP-ribose acceptor molecules.

Structure and function of eukaryotic mono-ADP-ribosyltransferases

ADP-ribosylation of proteins has been observed in numerous animal tissues including chicken heterophils, rat brain, human platelets, and mouse skeletal muscle. ADP-ribosylation in these tissues is thought to modulate critical cellular functions such as muscle cell development, actin polymerization, and cytotoxic T lymphocyte proliferation. Specific substrates of the ADP-ribosyltransferases have been identified; the skeletal muscle transferase ADP-ribosylates integrin alpha 7 whereas the chicken heterophil enzyme modifies the heterophil granule protein p33 and the CTL enzyme ADP-ribosylates the membrane-associated protein p40. Transferase sequence has been determined which should assist in elucidating the role of ADP-ribosylation in cells. There is sequence similarity among the vertebrate transferases and the rodent RT6 alloantigens. The RT6 family of proteins are NAD glycohydrolases that have been shown to possess auto-ADP-ribosyltransferase activity whereas the mouse Rt6-1 is also capable of ADP-ribosylating histone. Absence of RT6+ T cells has been associated with the development of an autoimmune-mediated diabetes in rodents. Humans have an RT6 pseudogene and do not express RT6 proteins. The reversal of ADP-ribosylation is catalyzed by ADP-ribosylarginine hydrolases, which have been purified and cloned from rodent and human tissues. In principle, the transferases and hydrolases could form an intracellular ADP-ribosylation regulatory cycle. In skeletal muscle and lymphocytes, however, the transferases and their substrates are extracellular membrane proteins whereas the hydrolases described thus far are cytoplasmic. In cultured mouse skeletal muscle cells, processing of the ADP-ribosylated integrin alpha 7 was carried out by phosphodiesterases and possibly phosphatases, leaving a residual ribose attached to the (arginine)protein. Several bacterial toxin and eukaryotic mono-ADP-ribosyltransferases, and perhaps other NAD-utilizing enzymes such as the RT6 alloantigens share regions of amino acid sequence similarity, which form, in part, the catalytic site. The catalytic cleft, found in the bacterial toxins that have been studied thus far, contains a critical glutamate and other amino acids that function to position NAD for nucleophilic attack at the N-glycosidic linkage, for either ADP-ribose transfer or NAD hydrolysis. Amino acid differences among the transferases at the active site may be required for accommodating the different ADP-ribose acceptor molecules.

Site-directed mutagenic alteration of potential active-site residues of the A subunit of Escherichia coli heat-labile enterotoxin. Evidence for a catalytic role for glutamic acid 112

Escherichia coli heat-labile enterotoxin (LT) and the related cholera toxin exert their effects on eukaryotic cells through the ADP-ribosylation of guanine nucleotide-binding proteins of the adenylate cyclase complex. The availability of the crystal structure for LT has permitted the tentative identification of residues that lie within or are vicinal to a presumptive NAD(+)-binding site and thus may play a role in substrate binding or catalysis. Using a plasmid clone encoding the A subunit of LT, we have introduced substitutions at such potential active-site residues and analyzed the enzymatic properties of the resultant mutant analogs. Enzymatic analyses, employing both transducin and agmatine as acceptor substrates, revealed that substitutions at serine 61, glutamic acid 110, and glutamic acid 112 resulted in reduction of enzyme activity to < 10% of wild-type levels. Kinetic analyses indicated that alteration of these sites affected the catalytic rate of the enzyme and had little or no effect on the binding of either NAD+ or agmatine. Of the mutant analogs analyzed, only glutamic acid 112 appeared to represent an essential catalytic residue as judged by the relative effects on kcat and kcat/Km. The results provide formal evidence that glutamic acid 112 of the A subunit of LT represents a functional homolog or analog of catalytic glutamic acid residues that have been identified in several other bacterial ADP-ribosylating toxins and that it may play an essential role in rendering NAD+ susceptible to nucleophilic attack by an incoming acceptor substrate.

The Arg7Lys mutant of heat-labile enterotoxin exhibits great flexibility of active site loop 47-56 of the A subunit

The heat-labile enterotoxin from Escherichia coli (LT) is a member of the cholera toxin family. These and other members of the larger class of AB5 bacterial toxins act through catalyzing the ADP-ribosylation of various intracellular targets including Gs alpha. The A subunit is responsible for this covalent modification, while the B pentamer is involved in receptor recognition. We report here the crystal structure of an inactive single-site mutant of LT in which arginine 7 of the A subunit has been replaced by a lysine residue. The final model contains 103 residues for each of the five B subunits, 175 residues for the A1 subunit, and 41 residues for the A2 subunit. In this Arg7Lys structure the active site cleft within the A subunit is wider by approximately 1 A than is seen in the wild-type LT. Furthermore, a loop near the active site consisting of residues 47-56 is disordered in the Arg7Lys structure, even though the new lysine residue at position 7 assumes a position which virtually coincides with that of Arg7 in the wild-type structure. The displacement of residues 47-56 as seen in the mutant structure is proposed to be necessary for allowing NAD access to the active site of the wild-type LT. On the basis of the differences observed between the wild-type and Arg7Lys structures, we propose a model for a coordinated sequence of conformational changes required for full activation of LT upon reduction of disulfide bridge 187-199 and cleavage of the peptide loop between the two cysteines in the A subunit.(ABSTRACT TRUNCATED AT 250 WORDS)

Both allelic forms of the rat T cell differentiation marker RT6 display nicotinamide adenine dinucleotide (NAD)-glycohydrolase activity, yet only RT6.2 is capable of automodification upon incubation with NAD

The finding that recently cloned mono-ADP-ribosyltransferases show sequence similarity to the rat T cell differentiation marker RT6 has led us to investigate the enzymatic activity of this alloantigenic system. To search for ADP-ribosylation of cell surface proteins, T cell populations from RT6.1- and RT6.2-expressing rat strains, as well as RT6.1+ and RT6.2+ T-T hybridoma cell lines, were incubated with [32P]nicotinamide adenine dinucleotide (NAD). All RT6.2+, but no RT6.1+ or RT6- cells, show incorporation of radioactivity into a single protein which could be identified as RT6.2 by immunoprecipitation with monoclonal antibodies. This automodification of RT6.2 is covalent, requires intact NAD as substrate, and displays characteristics typical for linkage of ADP-ribose to arginine. The alloantigens RT6.1 and RT6.2 differ in ten amino acids, RT6.2 having two arginine residues not present in RT6.1. Both alloantigens were found to display potent NAD-glycohydrolase activity.

AB5 toxins

Crystal structures of shiga and pertussis toxins have recently revealed a remarkable degree of structural homology among the members of the AB5 class of bacterial toxins. Other structures have provided a detailed view of the molecular basis of receptor binding specificity of cholera toxin, and of the heat-labile enterotoxin of Escherichia coli. These structures also provide tantalizing, but as yet incomplete, information on the site of ADP-ribosylation in the homologous A-subunits of the Escherichia coli heat-labile toxin, cholera toxin, and pertussis toxin.

The family of bacterial ADP-ribosylating exotoxins

Pathogenic bacteria utilize a variety of virulence factors that contribute to the clinical manifestation of their pathogenesis. Bacterial ADP-ribosylating exotoxins (bAREs) represent one family of virulence factors that exert their toxic effects by transferring the ADP-ribose moiety of NAD onto specific eucaryotic target proteins. The observations that some bAREs ADP-ribosylate eucaryotic proteins that regulate signal transduction, like the heterotrimeric GTP-binding proteins and the low-molecular-weight GTP-binding proteins, has extended interest in bAREs beyond the bacteriology laboratory. Molecular studies have shown that bAREs possess little primary amino acid homology and have diverse quaternary structure-function organization. Underlying this apparent diversity, biochemical and crystallographic studies have shown that several bAREs have conserved active-site structures and possess a conserved glutamic acid within their active sites.

Importance of ADP-ribosylation in the morphological changes of PC12 cells induced by cholera toxin

Cholera toxin (CTX) is composed of two subunits, subunit A, which possesses ADP-ribosyltransferase activity, and subunit B, which is responsible for receptor binding. It has previously been shown that agents that increase cyclic AMP (cAMP) levels in cells induce differentiation of PC12 cells into neurite-like cells. In this report, we show that as little as 100 pg of CTX per ml induces such changes. CTX was found to ADP-ribosylate at least four membrane proteins of PC12 cells in vitro and in vivo and to increase intracellular cAMP levels. We have developed an inducible ctx gene expression system in Vibrio cholerae by using the tac promoter. The culture medium of the CTX-producing bacteria was able to induce the morphological changes and the ADP-ribosylation of the PC12 cell membrane proteins. We have constructed two CTX-cross-reactive mutant proteins (CTX-CRM) by site-directed mutagenesis. The choice of glutamic acid 29 as the target amino acid was based on sequence similarities with other bacterial toxins. CTX-CRM-E29 delta, in which the Glu-29 of the A subunit was deleted, showed strongly reduced ADP-ribosyltransferase activity and did not induce significant morphological changes of PC12 cells. In contrast, CTX-CRM-E29D, in which the Glu-29 was replaced by an aspartic acid, was as active as the wild-type protein. We conclude that the ADP-ribosylation activity of CTX is important for the toxin-induced differentiation of PC12 cells. Pertussis toxin, which had no visible effect on PC12 cell morphology, was also able to ADP-ribosylate a membrane-bound protein(s) in vitro and in vivo. Pertussis toxin alone did not significantly increase cAMP levels in PC12 cells, but it acted synergistically with CTX.

Common features of the NAD-binding and catalytic site of ADP-ribosylating toxins

Computer analysis of the three-dimensional structure of ADP-ribosylating toxins showed that in all toxins the NAD-binding site is located in a cavity. This cavity consists of 18 contiguous amino acids that form an alpha-helix bent over a beta-strand. The tertiary folding of this structure is strictly conserved despite the differences in the amino acid sequence. Catalysis is supported by two spatially conserved amino acids, each flanking the NAD-binding site. These are: a glutamic acid that is conserved in all toxins, and a nucleophilic residue, which is a histidine in the diphtheria toxin and Pseudomonas exotoxin A, and an arginine in the cholera toxin, the Escherichia coli heat-labile enterotoxins, the pertussis toxin and the mosquitocidal toxin of Bacillus sphaericus. The latter group of toxins presents an additional histidine that appears important for catalysis. This structure suggests a general mechanism of ADP-ribosylation evolved to work on different target proteins.