TY - JOUR
T1 - An excitatory scorpion toxin with a distinctive feature
T2 - An additional α helix at the C terminus and its implications for interaction with insect sodium channels
AU - Oren, Deena A.
AU - Froy, Oren
AU - Amit, Efrat
AU - Kleinberger-Doron, Nurit
AU - Gurevitz, Michael
AU - Shaanan, Boaz
N1 - Funding Information:
This research was supported by the Da'at Consortium, a Magnet project administered by the office of the Chief Scientist of the Ministry of Industry & Trade, Israel (BS); Grant IS-2486-94C from BARD, the United States–Israel Binational Agricultural Research & Development Fund (MG and BS); Grant 891-0112-95 from the Israeli Ministry of Agriculture (MG) and Grant 466/97 from the Israel Academy of Sciences and Humanities (MG).
PY - 1998/9/15
Y1 - 1998/9/15
N2 - Background: Scorpion neurotoxins, which bind and modulate sodium channels, have been divided into two groups, the α and β toxins, according to their activities. The β-toxin class includes the groups of excitatory and depressant toxins, which differ in their mode of action and are highly specific against insects. The three-dimensional structures of several α and β toxins have been determined at high resolution, but no detailed 3D structure of an excitatory toxin has been presented so far. Results: The crystal structure of an anti-insect excitatory toxin from the scorpion Buthotus judaicus, Bj-xtrlT, has been determined at 2.1 Å resolution and refined to an R factor of 0.209. The first 59 residues form a closely packed module, structurally similar to the conserved α and β toxins ('long toxins') affecting sodium channels. The last 17 residues form a C-terminal extension not previously seen in scorpion toxins. It comprises a short α helix anchored to the N-terminal module by a disulfide bridge and is followed by a highly mobile stretch of seven residues, of which only four are seen in the electron-density map. This mobile peptide covers part of a conserved hydrophobic surface that is thought to be essential for interaction with the channel in several long toxins. Conclusions: Replacement of the last seven residues by a single glycine abolishes the activity of Bj-xtrlT, strongly suggesting that these residues are intimately involved in the interaction with the channel. Taken together with the partial shielding of the conserved hydrophobic surface and the proximity of the C terminus to an adjacent surface rich in charged residues, it seems likely that the bioactive surface of Bj-xtrlT is formed by residues surrounding the C terminus. The 3D structure and a recently developed expression system for Bj-xtrlT pave the way for identifying the structural determinants involved in the bioactivity and anti-insect specificity of excitatory toxins.
AB - Background: Scorpion neurotoxins, which bind and modulate sodium channels, have been divided into two groups, the α and β toxins, according to their activities. The β-toxin class includes the groups of excitatory and depressant toxins, which differ in their mode of action and are highly specific against insects. The three-dimensional structures of several α and β toxins have been determined at high resolution, but no detailed 3D structure of an excitatory toxin has been presented so far. Results: The crystal structure of an anti-insect excitatory toxin from the scorpion Buthotus judaicus, Bj-xtrlT, has been determined at 2.1 Å resolution and refined to an R factor of 0.209. The first 59 residues form a closely packed module, structurally similar to the conserved α and β toxins ('long toxins') affecting sodium channels. The last 17 residues form a C-terminal extension not previously seen in scorpion toxins. It comprises a short α helix anchored to the N-terminal module by a disulfide bridge and is followed by a highly mobile stretch of seven residues, of which only four are seen in the electron-density map. This mobile peptide covers part of a conserved hydrophobic surface that is thought to be essential for interaction with the channel in several long toxins. Conclusions: Replacement of the last seven residues by a single glycine abolishes the activity of Bj-xtrlT, strongly suggesting that these residues are intimately involved in the interaction with the channel. Taken together with the partial shielding of the conserved hydrophobic surface and the proximity of the C terminus to an adjacent surface rich in charged residues, it seems likely that the bioactive surface of Bj-xtrlT is formed by residues surrounding the C terminus. The 3D structure and a recently developed expression system for Bj-xtrlT pave the way for identifying the structural determinants involved in the bioactivity and anti-insect specificity of excitatory toxins.
KW - Crystal structure
KW - Excitatory toxin
KW - Insecticides
KW - Scorpion toxin
KW - Sodium channels
UR - http://www.scopus.com/inward/record.url?scp=0032530987&partnerID=8YFLogxK
U2 - 10.1016/S0969-2126(98)00111-7
DO - 10.1016/S0969-2126(98)00111-7
M3 - Article
AN - SCOPUS:0032530987
SN - 0969-2126
VL - 6
SP - 1095
EP - 1103
JO - Structure
JF - Structure
IS - 9
ER -