Diphtheria toxin

Exotoxin From Wikipedia, the free encyclopedia

Diphtheria toxin is an exotoxin secreted mainly by Corynebacterium diphtheriae (but also by Corynebacterium ulcerans and Corynebacterium pseudotuberculosis), the pathogenic bacterium that causes diphtheria. The toxin gene is encoded by a prophage[annotation 1] called corynephage β.[1][2] The toxin causes the disease in humans by gaining entry into the cell cytoplasm and inhibiting protein synthesis.[3]

Quick facts tox diphtheria toxin precursor, Identifiers ...
tox diphtheria toxin precursor
Cartoon representation of the diphtheria toxin protein
Identifiers
OrganismCorynebacterium diphtheriae
Symboltox
Entrez2650491
RefSeq (Prot)NP_938615
UniProtP00587
Other data
EC number2.4.2.36
Chromosomegenome: 0.19 - 0.19 Mb
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StructuresSwiss-model
DomainsInterPro
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Quick facts Identifiers, Symbol ...
Diphtheria toxin, C domain
Identifiers
SymbolDiphtheria_C
PfamPF02763
Pfam clanCL0084
InterProIPR022406
SCOP21ddt / SCOPe / SUPFAM
TCDB1.C.7
Available protein structures:
PDB  IPR022406 PF02763 (ECOD; PDBsum)  
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Diphtheria toxin, T domain
Identifiers
SymbolDiphtheria_T
PfamPF02764
InterProIPR022405
SCOP21ddt / SCOPe / SUPFAM
TCDB1.C.7
Available protein structures:
PDB  IPR022405 PF02764 (ECOD; PDBsum)  
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Diphtheria toxin, R domain
Identifiers
SymbolDiphtheria_R
PfamPF01324
InterProIPR022404
SCOP21ddt / SCOPe / SUPFAM
TCDB1.C.7
Available protein structures:
PDB  IPR022404 PF01324 (ECOD; PDBsum)  
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Structure

Diphtheria toxin is a single polypeptide chain of 535 amino acids consisting of two subunits linked by disulfide bridges, known as an A-B toxin. Binding of the cell surface by the B subunit (the less stable of the two subunits) allows the A subunit (the more stable part of the protein) to penetrate the host cell.[4]

The crystal structure of the diphtheria toxin homodimer has been determined to 2.5 Ångstrom resolution. The structure reveals a Y-shaped molecule consisting of three domains. Fragment A contains the catalytic C domain, and fragment B consists of the T and R domains:[5]

Mechanism

Diphthamide

The diphtheria toxin has the same mechanism of action as the enzyme NAD(+)—diphthamide ADP-ribosyltransferase (EC 2.4.2.36). It catalyzes the ADP ribosylation of the unusual amino acid diphthamide in eEF-2 by transferring the ADP-ribosyl group from NAD+. The ADP ribosylation of diphthamide inactivates the eEF-2 protein, thus, inhibiting the translation of mRNA. The catalysed reaction is as follows:

NAD+ + peptide diphthamide nicotinamide + peptide N-(ADP-D-ribosyl)diphthamide.

The exotoxin A of Pseudomonas aeruginosa uses a similar mechanism of action.

The steps involved in generating toxicity are as follows:[citation needed]

  1. Processing
    1. The leader region is cleaved during secretion.
    2. Proteolytic nicking separates A and B subunits, which remain joined by disulfide bonds until they reach the cytosol.
  2. The toxin binds to heparin-binding epidermal growth factor precursor (HB-EGF).[9]:116
  3. The complex undergoes endocytosis by the host cell.
  4. Acidification inside the endosome induces translocation of the A subunit into the cytosol.
    1. Disulfide bonds are broken.
    2. The B subunit remains in the endosome as a pore.
  5. The A subunit ADP-ribosylates host eEF-2, which is required for protein synthesis; when it is inactivated, the host cannot make protein and thus dies.

Lethal dose and effects

Diphtheria toxin is extraordinarily potent.[4] The lethal dose for humans is about 0.1 μg of toxin per kg of body weight. Death occurs through necrosis of the heart and liver.[10] Diphtheria toxin has also been associated with the development of myocarditis. Myocarditis secondary to diphtheria toxin is considered one of the biggest risks to unimmunized children.

History

Diphtheria toxin was discovered in 1888 by Émile Roux and Alexandre Yersin. In 1890, Emil Adolf von Behring developed an anti-toxin based on the blood of horses immunized with attenuated bacteria.[11] In 1951, Freeman found that the toxin gene was not encoded on the bacterial chromosome, but by a lysogenic phage (corynephage β)[2] infecting all toxigenic strains.[12][13][14]

Clinical use

The drug denileukin diftitox uses diphtheria toxin as an antineoplastic agent.

Resimmune is an immunotoxin that is in clinical trials in cutaneous T cell lymphoma patients. It uses diphtheria toxin (truncated by the cell binding domain) coupled to an antibody to CD3ε (UCHT1).[15]

Research

Similar to other A-B toxins, diphtheria toxin is adept at transporting exogenous proteins across mammalian cell membranes, which are usually impermeable to large proteins. This unique ability can be repurposed to deliver therapeutic proteins, instead of the catalytic domain of the toxin.[16][17]

This toxin has also been used in neuroscientific and cancer research to ablate specific populations of cells which express the diphtheria toxin receptor (heparin-binding EGF-like growth factor). Administration of the toxin into the organism which does not naturally express this receptor (e.g. mice) will result in the selective ablation of the cell population which do express it.[18][19]

Annotations

  1. A prophage is a virus that has inserted itself into the genome of the host bacterium.

References

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