Chelt, a cholera-like toxin from Vibrio cholerae, and Certhrax, an anthrax-like toxin from Bacillus cereus, are among six new bacterial protein toxins we identified and characterized using in silico and cell-based techniques. We also uncovered medically relevant toxins from Mycobacterium avium and Enterococcus faecalis. We found agriculturally relevant toxins in Photorhabdus luminescens and Vibrio splendidus. These toxins belong to the ADP-ribosyltransferase family that has conserved structure despite low sequence identity. Therefore, our search for new toxins combined fold recognition with rules for filtering sequences – including a primary sequence pattern – to reduce reliance on sequence identity and identify toxins using structure. We used computers to build models and analyzed each new toxin to understand features including: structure, secretion, cell entry, activation, NAD+ substrate binding, intracellular target binding and the reaction mechanism. We confirmed activity using a yeast growth test. In this era where an expanding protein structure library complements abundant protein sequence data – and we need high-throughput validation – our approach provides insight into the newest toxin ADP-ribosyltransferases.
The mono-ADP-ribosyltransferase toxins are bacterial virulence factors that contribute to many disease states in plants, animals, and humans. These toxins function as enzymes that target various host proteins and covalently attach an ADP-ribose moiety that alters target protein function. We tested compounds from a virtual screen of commercially available compounds combined with a directed poly(ADP-ribose) polymerase (PARP) inhibitor library and found several compounds that bind tightly and inhibit toxins from Pseudomonas aeruginosa and Vibrio cholerae. The most efficacious compounds completely protected human lung epithelial cells against the cytotoxicity of these bacterial virulence factors. Moreover, we determined high-resolution crystal structures of the best inhibitors in complex with cholix toxin to reveal important criteria for inhibitor binding and mechanism of action. These results provide new insight into development of antivirulence compounds for treating many bacterial diseases.Bacteria use virulence factors as tools to facilitate disease in plants, animals, and humans (14,26,30,34); one strategy to combat infection is to inhibit these factors by small-molecule therapy, thereby helping to neutralize the offending microbe (5,6,12,19,22). It is now generally appreciated that an antivirulence approach is a powerful alternative strategy for antibacterial treatment and vaccine development (27) and that it may require multiple tactics to resolve the current drug resistance dilemma (6,8). Antivirulence compounds offer significant advantages over conventional antibiotics since these inhibitors are directed toward specific mechanisms (targets) in the offending pathogen that promote infection rather than against an essential metabolic factor (12). Neutralizing the cytotoxic properties of virulence factors from microorganisms without threatening their survival offers reduced selection pressure, making the induction of drug resistance mutations less likely (6). Additionally, virulence-specific therapeutics avoid the undesirable effects on the host microbiota that are associated with current antibiotics.The mono-ADP-ribosyltransferase (mART) family is a group of toxic bacterial enzymes, some of which possess a long history against human civilization. The best-characterized and wellknown members of this lethal family are cholera toxin (CT) from Vibrio cholerae, diphtheria toxin (DT) produced by Corynebacterium diphtheriae, pertussis toxin (PT) from Bordella pertussis, heat-labile enterotoxin from Escherichia coli, C3-like exoenzyme produced by Clostridium botulinum and Clostridium limosum, and exotoxin A (ExoA) from Pseudomonas aeruginosa. These enzymes act on NAD ϩ and facilitate the scission of the glycosidic bond (C-N) between nicotinamide and its conjugated ribose followed by the transfer of the ADPribose group to a nucleophilic residue on a target macromolecule (35). This family can be divided into the CT and DT groups. The CT group consists of an ExoS-like subgroup (enzymatic A domain alone or paired with ano...
The emergence of bacterial antibiotic resistance poses a significant challenge in the pursuit of novel therapeutics, making new strategies for drug discovery imperative. We have developed a yeast growth-defect phenotypic screen to help solve this current dilemma. This approach facilitates the identification and characterization of a new diphtheria toxin (DT) group, ADP-ribosyltransferase toxins from pathogenic bacteria. In addition, this assay utilizes Saccharomyces cerevisiae, a reliable model for bacterial toxin expression, to streamline the identification and characterization of new inhibitors against this group of bacterial toxins that may be useful for antimicrobial therapies. We show that a mutant of the elongation factor 2 target protein in yeast, G701R, confers resistance to all DT group toxins and recovers the growth-defect phenotype in yeast. We also demonstrate the ability of a potent small-molecule toxin inhibitor, 1,8-naphthalimide (NAP), to alleviate the growth defect caused by toxin expression in yeast. Moreover, we determined the crystal structure of the NAP inhibitor-toxin complex at near-atomic resolution to provide insight into the inhibitory mechanism. Finally, the NAP inhibitor shows therapeutic protective effects against toxin invasion of mammalian cells, including human lung cells.
Photorhabdus luminescens is a pathogenic bacterium that produces many toxic proteins. The mono-ADP-ribosyltransferases (mARTs) are an enzyme class produced by numerous pathogenic bacteria and participate in disease in plants and animals, including humans. Herein we report a novel mART from P. luminescens called Photox. This 46-kDa toxin shows high homology to other actin-targeting mARTs in hallmark catalytic regions and a similar core catalytic fold. Furthermore, Photox shows in vivo cytotoxic activity against yeast, with protection occurring when catalytic residues are substituted with alanine. In vitro, enzymatic activity (k cat , 1680 ؎ 75 min ؊1 ) is higher than that of the related iota toxin, and diminishes by nearly 14,000-fold following substitution of the catalytic Glu (E355A). This toxin specifically ADP-ribosylates monomeric ␣-skeletal actin and nonmuscle -and ␥-actin at Arg 177 , inhibiting regular polymerization of actin filaments. These results indicate that Photox is indeed an ADP-ribosyltransferase, making it the newest member of the actin-targeting mART family.
Background: VahC toxin from Aeromonas hydrophila inactivates actin by transferring ADP-ribose from NAD ϩ .
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