通过突变循环分析确定的新石房蛤毒素与钠离子通道外前庭的特异性相互作用。
Specific neosaxitoxin interactions with the Na+ channel outer vestibule determined by mutant cycle analysis.
作者信息
Penzotti J L, Lipkind G, Fozzard H A, Dudley S C
机构信息
Departments of Neurobiology, Pharmacology, and Physiology, University of Chicago, Chicago, Illinois 60637, USA.
出版信息
Biophys J. 2001 Feb;80(2):698-706. doi: 10.1016/S0006-3495(01)76049-3.
The voltage-gated Na+ channel alpha-subunit consists of four homologous domains arranged circumferentially to form the pore. Several neurotoxins, including saxitoxin (STX), block the pore by binding to the outer vestibule of this permeation pathway, which is composed of four pore-forming loops (P-loops), one from each domain. Neosaxitoxin (neoSTX) is a variant of STX that differs only by having an additional hydroxyl group at the N1 position of the 1,2,3 guanidinium (N1-OH). We used this structural variant in mutant cycle experiments to determine interactions of the N1-OH and its guanidinium with the outer vestibule. NeoSTX had a higher affinity for the adult rat skeletal muscle Na+ channel (muI or Scn4a) than for STX (DeltaG approximately = 1.3 kcal/mol). Mutant cycle analysis identified groups that potentially interacted with each other. The N1 toxin site interacted most strongly with muI Asp-400 and Tyr-401. The interaction between the N1-OH of neoSTX and Tyr-401 was attractive (DeltaDeltaG = -1.3 +/- 0.1 kcal/mol), probably with formation of a hydrogen bond. A second possible attractive interaction to Asp-1532 was identified. There was repulsion between Asp-400 and the N1-OH (DeltaDeltaG = 1.4 +/- 0.1 kcal/mol), and kinetic analysis further suggested that the N1-OH was interacting negatively with Asp-400 at the transition state. Changes in pH altered the affinity of neoSTX, as would be expected if the N1-OH site were partially deprotonated. These interactions offer an explanation for most of the difference in blocking efficacy between neoSTX and STX and for the sensitivity of neoSTX to pH. Kinetic analysis suggested significant differences in coupling energies between the transition and the equilibrium, bound states. This is the first report to identify points of interaction between a channel and a non-peptide toxin. This interaction pattern was consistent with previous proposals describing the interactions of STX with the outer vestibule (Lipkind, G. M., and H. A. Fozzard. 1994. Biophys. J. 66:1-13; Penzotti, J. L., G. Lipkind, H. A. Fozzard, and S. C. Dudley, Jr. 1998. Biophys. J. 75:2647-2657).
电压门控性钠离子通道α亚基由四个同源结构域环绕排列形成孔道。包括石房蛤毒素(STX)在内的几种神经毒素通过结合该通透途径的外前庭来阻断孔道,该外前庭由四个成孔环(P环)组成,每个结构域各有一个。新石房蛤毒素(neoSTX)是STX的一种变体,仅在1,2,3 - 胍基的N1位置(N1 - OH)多一个羟基。我们在突变循环实验中利用这种结构变体来确定N1 - OH及其胍基与外前庭的相互作用。NeoSTX对成年大鼠骨骼肌钠离子通道(μ1或Scn4a)的亲和力高于STX(ΔG约为 = 1.3千卡/摩尔)。突变循环分析确定了可能相互作用的基团。N1毒素位点与μ1的天冬氨酸 - 400和酪氨酸 - 401相互作用最强。NeoSTX的N1 - OH与酪氨酸 - 401之间的相互作用具有吸引力(ΔΔG = -1.3 ± 0.1千卡/摩尔),可能形成了氢键。还确定了与天冬氨酸 - 1532的第二种可能的吸引性相互作用。天冬氨酸 - 400与N1 - OH之间存在排斥作用(ΔΔG = 1.4 ± 0.1千卡/摩尔),动力学分析进一步表明在过渡态N1 - OH与天冬氨酸 - 400发生负性相互作用。pH值的变化改变了neoSTX的亲和力,如果N1 - OH位点部分去质子化,这是可以预期的。这些相互作用解释了neoSTX和STX在阻断效力上的大部分差异以及neoSTX对pH值的敏感性。动力学分析表明在过渡态与平衡结合态之间的耦合能存在显著差异。这是首次报道确定通道与非肽类毒素之间的相互作用点。这种相互作用模式与先前描述STX与外前庭相互作用的提议一致(Lipkind, G. M., and H. A. Fozzard. 1994. Biophys. J. 66:1 - 13; Penzotti, J. L., G. Lipkind, H. A. Fozzard, and S. C. Dudley, Jr. 1998. Biophys. J. 75:2647 - 2657)。
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