|Category||Ion channel toxin, Neurotoxin|
|Target||voltage-gated sodium channel |
|Symptoms||Lethal, tachypnea, convulsions, tremors|
|Taxonomic ID||170972 |
|Sequence length||58 AA |
- Source 1
- Chemistry 2
- Mode of action 3
- Toxicity 4
- References 5
Birtoxin was isolated from the venom of the South African Spitting scorpion. It is a peptide that is moderately toxic but very abundant in the venom. Other peptide toxins found in the venom include: dortoxin, a lethal peptide; bestoxin, which causes writhing in mice; and altitoxin, a highly depressant peptide.
Generally, peptide neurotoxins can be divided into two major families, the ‘long chain neurotoxins’ (LCN) with 60- to 70-residue range and known to contain eight cysteine residues; and the ‘short chain neurotoxins’ (SCN) with 30 to 40 peptides with six or eight cysteine residues. Birtoxin, together with other birtoxin-like peptides including bestoxin, is 58 amino-acid residues long, close to the ‘long chain’ family but with six cysteine residues. Birtoxin is reticulated by three disulfide bridges, instead of four, compared to other LCNs . Therefore it is considered to be the evolutionary link between ‘long chain’- and ‘short chain’- families.
Mode of action
Birtoxin affects the gating mechanism of sodium channels by binding to neurotoxin receptor site 4 of the channel, resulting in the lowering of the voltage threshold of the channel and a reduction in the current amplitude. Due to the change in the activation the sodium channel will open at smaller depolarisations. This causes increased excitability, which leads to symptoms such as convulsions, continuous urination, tremors and tachypnea (faster breathing).
Birtoxin only affects mammals. No effect is found on reptiles, insects or fish. In experiments performed on mice, symptoms such as convulsions, continuous urination, tremors and tachypnea occurred 10 minutes after injection and increased during 30 minutes. An injection of 1 μg of birtoxin resulted in severe neurotoxic effects for 24 hours, but this dose is not lethal to mice. LD99 in mice is achieved at 2 μg.
An antibody against the N-terminus of the birtoxin protein structure has been shown to neutralize the venom of the South African spitting scorpion, and such antibodies may be useful clinically to treat envenomation.
- Inceoglu, B.; Lango, J.; Wu, J.; Hawkins, P.; Southern, J.; Hammock, B.D. (2001). "Isolation and characterization of a novel type of neurotoxic peptide from the venom of the South African scorpion Parabuthus transvaalicus (Buthidae)". European Journal of Biochemistry 268: 5407–5413.
- Inceoglu, B; J Lango; I Pessah; B Hammock (2005). "Three structurally related, highly potent, peptides from the venom of possess divergent biological activity". Toxicon 45 (6): 727–733.
- Martin-Eauclaire, M-F; Cearda, B.; Bosmans, F.; Rossoa, J-P.; Tytgat, J.; Bougisa, P.E. (1999). "New “Birtoxin analogs” from
- Possani, L.D.; Becerrill, B.; Delepierre, M.; Tytgat Hammock, J. (1999). "Scorpion toxins specific for Na+-channels". European Journal of Biochemistry 264: 287–300.
- Lebreton, F.; Delepierre, M.; Ramirez, A.N.; Balderas, C.; Possani, L.D. (1994). "Primary and NMR three-dimensional structure determination of a novel crustacean toxin from the venom of the scorpion Centruroides limpidus limpidus Karsch". Biochemistry. 33(37): 11135–11149.
- Lebreton, F.; Delepierre, M.; Ramirez, A.N.; Balderas, C.; Possani, L.D. (1994). "Purification and primary structure of low molecular mass peptides from scorpion (Buthus sindicus) venom". Comparative Biochemistry and Physiology – Part A: Molecular & Integrative Physiology 121 (4): 323–332.
- Gordon, D.; Savarin, P.; Gurevitz, M.; Zinn-Justin, S. (1998). "Functional anatomy of scorpion toxins affecting sodium channels".
- Cestèle, S.; Catterall, W.A. (2000). "Molecular mechanisms of neurotoxin action on voltage-gated sodium channels". Biochimie 82 (9–10): 883–892.
- Inceoglu, B; J Lango; A Rabinovich; P Whetstone; B Hammock (2006). "The neutralizing effect of a polyclonal antibody raised against the N-terminal eighteen-aminoacid residues of birtoxin towards the whole venom of Parabuthus transvaalicus". Toxicon 47 (2): 144–149.