TY - CHAP
T1 - Molecular description of scorpion toxin interaction with voltage–gated sodium channels
AU - Gurevitz, Michael
AU - Gordon, Dalia
AU - Barzilai, Maya Gur
AU - Kahn, Roy
AU - Cohen, Lior
AU - Moran, Yehu
AU - Zilberberg, Noam
AU - Froy, Oren
AU - Altman-Gueta, Hagit
AU - Turkov, Michael
AU - Dong, Ke
AU - Karbat, Izhar
N1 - Publisher Copyright:
© Springer Science+Business Media Dordrecht 2015.
PY - 2015/1/1
Y1 - 2015/1/1
N2 - Scorpion alpha and beta toxins interact with voltage-gated sodium channels (Navs) at two pharmacologically distinct sites. Alpha toxins bind at receptor site 3 and inhibit channel inactivation, whereas beta toxins bind at receptor site 4 and shift the voltage-dependent activation toward more hyperpolarizing potentials. The two toxin classes are subdivided to distinct pharmacological groups according to their binding preferences and competition for receptor sites at Nav subtypes. To elucidate the surface of interaction of the two toxin classes with Navs and clarify the molecular basis of varying toxin preferences, an efficient expression system was established. Mutagenesis accompanied by toxicity, binding, and electrophysiological assays, in parallel to determination of the three-dimensional structure using NMR and X-ray crystallography, uncovered the bioactive surfaces of toxin representatives of all pharmacological groups. Exchange of external loops between channels that exhibit marked differences in sensitivity to various toxins accompanied by point mutagenesis highlighted channel determinants that play a role in toxin selectivity. These data were used in further mapping of the brain channel rNav1.2a receptor sites for the beta-toxin Css4 (from Centruroides suffusus suffusus) and the alpha-toxin Lqh2 (from Leiurus quinquestriatus hebraeus). On the basis of channel mutations that affected Css4 activity, the known structure of the toxin and its bioactive surface, and using the structure of a potassium channel as template, a structural model of Css4 interaction with the gating module of domain II was constructed. This initial model was the first step in the identification of part of receptor site 4. In parallel, a swapping and a mutagenesis approach employing the rNav1.2a mammalian and DmNav1 insect Navs and the toxin Lqh2 as a probe were used to search for receptor site 3. The channel mapping along with toxin dissociation assays and double-mutant cycle analyses using toxin and channel mutants identified the gating module of domain IV as the site of interaction with the toxin core domain, thus describing the docking orientation of an alpha toxin at the channel surface.
AB - Scorpion alpha and beta toxins interact with voltage-gated sodium channels (Navs) at two pharmacologically distinct sites. Alpha toxins bind at receptor site 3 and inhibit channel inactivation, whereas beta toxins bind at receptor site 4 and shift the voltage-dependent activation toward more hyperpolarizing potentials. The two toxin classes are subdivided to distinct pharmacological groups according to their binding preferences and competition for receptor sites at Nav subtypes. To elucidate the surface of interaction of the two toxin classes with Navs and clarify the molecular basis of varying toxin preferences, an efficient expression system was established. Mutagenesis accompanied by toxicity, binding, and electrophysiological assays, in parallel to determination of the three-dimensional structure using NMR and X-ray crystallography, uncovered the bioactive surfaces of toxin representatives of all pharmacological groups. Exchange of external loops between channels that exhibit marked differences in sensitivity to various toxins accompanied by point mutagenesis highlighted channel determinants that play a role in toxin selectivity. These data were used in further mapping of the brain channel rNav1.2a receptor sites for the beta-toxin Css4 (from Centruroides suffusus suffusus) and the alpha-toxin Lqh2 (from Leiurus quinquestriatus hebraeus). On the basis of channel mutations that affected Css4 activity, the known structure of the toxin and its bioactive surface, and using the structure of a potassium channel as template, a structural model of Css4 interaction with the gating module of domain II was constructed. This initial model was the first step in the identification of part of receptor site 4. In parallel, a swapping and a mutagenesis approach employing the rNav1.2a mammalian and DmNav1 insect Navs and the toxin Lqh2 as a probe were used to search for receptor site 3. The channel mapping along with toxin dissociation assays and double-mutant cycle analyses using toxin and channel mutants identified the gating module of domain IV as the site of interaction with the toxin core domain, thus describing the docking orientation of an alpha toxin at the channel surface.
UR - http://www.scopus.com/inward/record.url?scp=84943195411&partnerID=8YFLogxK
U2 - 10.1007/978-94-007-6404-0_10
DO - 10.1007/978-94-007-6404-0_10
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AN - SCOPUS:84943195411
SN - 9789400764033
SP - 471
EP - 491
BT - Scorpion Venoms
PB - Springer Netherlands
ER -