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本文引用的文献

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泰氏蝎毒素Kα可阻断电压门控性非失活钾通道，并使在突触体中被α-树眼镜蛇毒素阻断的失活钾通道去阻断。

Tityustoxin K alpha blocks voltage-gated noninactivating K+ channels and unblocks inactivating K+ channels blocked by alpha-dendrotoxin in synaptosomes.

作者信息

Rogowski R S, Krueger B K, Collins J H, Blaustein M P

机构信息

Department of Physiology, University of Maryland School of Medicine, Baltimore.

出版信息

Proc Natl Acad Sci U S A. 1994 Feb 15;91(4):1475-9. doi: 10.1073/pnas.91.4.1475.

DOI:10.1073/pnas.91.4.1475

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC43182/

Abstract

Two nonhomologous polypeptide toxins, tityustoxin K alpha (TsTX-K alpha) and tityustoxin K beta (TsTX-K beta), purified from the venom of the Brazilian scorpion Tityus serrulatus, selectively block voltage-gated noninactivating K+ channels in synaptosomes (IC50 values of 8 nM and 30 nM, respectively). In contrast, alpha-dendrotoxin (alpha-DTX) and charybdotoxin (ChTX) block voltage-gated inactivating K+ channels in synaptosomes (IC50 values of 90 nM and 40 nM, respectively). We studied interactions among these toxins in 125I-alpha-DTX binding and 86Rb efflux experiments. Both TsTX-K alpha and ChTX completely displaced specifically bound 125I-alpha-DTX from synaptic membranes, but TsTX-K beta had no effect on bound alpha-DTX. TsTX-K alpha and TsTX-K beta blocked the same noninactivating component of 100 mM K(+)-stimulated 86Rb efflux in synaptosomes. Both alpha-DTX and ChTX blocked the same inactivating component of the K(+)-stimulated 86Rb efflux in synaptosomes. Both the inactivating and the noninactivating components of the 100 mM K(+)-stimulated 86Rb efflux were completely blocked when 200 nM TsTX-K beta and either 600 nM alpha-DTX or 200 nM ChTX were present. The effects of TsTX-K alpha and ChTX on 86Rb efflux were also additive. When TsTX-K alpha was added in the presence of alpha-DTX, however, only the noninactivating component of the K(+)-stimulated efflux was blocked. The inactivating component could then be blocked by ChTX, which is structurally homologous to TsTX-K alpha. We conclude that TsTX-K alpha unblocks the voltage-gated inactivating K+ channels in synaptosomes when they are blocked by alpha-DTX, but not when they are blocked by ChTX. TsTX-K alpha binds to a site on the inactivating K+ channel that does not occlude the pore; its binding apparently prevents alpha-DTX (7054 Da), but not ChTX (4300 Da), from blocking the pore. The effects of TsTX-K alpha on 125I-alpha-DTX binding and 86Rb efflux are mimicked by noxiustoxin, which is homologous to TsTX-K alpha and ChTX.

摘要

从巴西蝎子锯脂鲤属毒腺中纯化得到的两种非同源多肽毒素，即tityustoxin Kα（TsTX-Kα）和tityustoxin Kβ（TsTX-Kβ），可选择性阻断突触体中的电压门控非失活钾通道（IC50值分别为8 nM和30 nM）。相比之下，α-树眼镜蛇毒素（α-DTX）和蝎毒素（ChTX）可阻断突触体中的电压门控失活钾通道（IC50值分别为90 nM和40 nM）。我们在125I-α-DTX结合和86Rb外流实验中研究了这些毒素之间的相互作用。TsTX-Kα和ChTX均可完全取代突触膜上特异性结合的125I-α-DTX，但TsTX-Kβ对结合的α-DTX没有影响。TsTX-Kα和TsTX-Kβ可阻断突触体中100 mM K(+)刺激的86Rb外流的相同非失活成分。α-DTX和ChTX均可阻断突触体中K(+)刺激的86Rb外流的相同失活成分。当存在200 nM TsTX-Kβ和600 nM α-DTX或200 nM ChTX时，100 mM K(+)刺激的86Rb外流的失活和非失活成分均被完全阻断。TsTX-Kα和ChTX对86Rb外流的作用也是相加的。然而，当在α-DTX存在的情况下加入TsTX-Kα时，只有K(+)刺激外流的非失活成分被阻断。然后失活成分可被与TsTX-Kα结构同源的ChTX阻断。我们得出结论，当突触体中的电压门控失活钾通道被α-DTX阻断时，TsTX-Kα可使其解除阻断，但当被ChTX阻断时则不能。TsTX-Kα与失活钾通道上不阻塞孔道的位点结合；其结合显然可阻止α-DTX（7054 Da）而非ChTX（4300 Da）阻塞孔道。与TsTX-Kα和ChTX同源的诺毒素可模拟TsTX-Kα对125I-α-DTX结合和86Rb外流的作用。