Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:4.1.2.42 (DTA)
 1,693 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A genetically engineered gene fusion was constructed which encoded a nontoxic derivative of the A fragment of diphtheria toxin joined to the C180 peptide of the S1 subunit of pertussis toxin. The product of this gene fusion, termed the DTA-C180 protein, was purified from the periplasm of Escherichia coli to approximately 80% purity. The DTA-C180 protein possessed an apparent molecular weight of 43,000 by reduced sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The DTA-C180 protein was cleaved into two tryptic peptides, which migrated with apparent molecular weights of approximately 22,000. One tryptic peptide reacted with diphtheria antitoxin, while the other tryptic peptide reacted with anti-C180 peptide immunoglobulin G. The DTA-C180 protein did not inhibit protein synthesis or stimulate clustering morphology in Chinese hamster ovary cells. The DTA-C180 protein elicited an immune response, in guinea pigs, against both the DTA and C180 peptide components of the fusion protein, with alum being a more efficient adjuvant than Freund's adjuvant for eliciting neutralization titers. Neutralization titers elicited by DTA-C180 protein were weaker than those elicited by diphtheria toxoid and pertussis toxin 9K/129G, a genetically engineered double mutant of pertussis toxin. Three doses of DTA-C180 protein yielded a neutralization titer of 1/750 against pertussis toxin in Chinese hamster ovary cells and a neutralization titer of 1/50 against diphtheria toxin in Vero cells. This is the first report of a protein derived from a recombinant S1 subunit that elicits a neutralizing titer against pertussis toxin.
 ...
PMID:Construction of a diphtheria toxin A fragment-C180 peptide fusion protein which elicits a neutralizing antibody response against diphtheria toxin and pertussis toxin. 145 39

The bacterial exotoxins, cholera toxin (CT), pertussis toxin (PT), and diphtheria toxin (DT), interfere with specific host proteins to cause tissue damage for their respective infections. The common toxic mechanism for these agents is mono-ADP-ribosylation of specific amino acids in G(s)(alpha), G(i)(alpha), and eEF-2 proteins, respectively, by the catalytic A chains of the toxins (CTA, PTA, and DTA). In the absence of acceptor proteins, these toxins also act as NAD(+)-N-ribosyl hydrolases. The transition-state structures for NAD(+) hydrolysis and ADP-ribosylation reactions have oxacarbenium ion character in the ribose. We designed and synthesized analogues of NAD(+) to resemble their oxacarbenium ion transition states. Inhibitors with oxacarbenium mimics replacing the NMN-ribosyl group of NAD(+) show 200-620-fold increased affinity in the hydrolytic and N-ribosyl transferase reactions catalyzed by CTA. These analogues are also inhibitors for the hydrolysis of NAD(+) by PTA with K(i) values of 24-40 microM, but bind with similar affinity to the NAD(+) substrates. Inhibition of the NAD(+) hydrolysis and ADP-ribosyl transferase reactions of DTA gave K(i) values from 19 to 48 microM. Catalytic rate enhancements by the bacterial exotoxins are small, and thus transition-state analogues cannot capture large energies of activation. In the cases of DTA and PTA, analogues known to resemble the transition states bind with approximately the same affinity as substrates. Transition-state analogue interrogation of the bacterial toxins indicates that CTA gains catalytic efficiency from modest transition-state stabilization, but DTA and PTA catalyze ADP-ribosyl transferase reactions more from ground-state destabilization. pH dependence of inhibitor action indicated that both neutral and cationic forms of transition-state analogues bind to DTA with similar affinity. The origin of this similarity is proposed to reside in the cationic nature of NAD(+) both as substrate and at the transition state.
 ...
PMID:Inhibitors of ADP-ribosylating bacterial toxins based on oxacarbenium ion character at their transition states. 1512 61