蝎毒素通过 Zn 样长程构象偶联机制抑制电压门控质子通道。
Scorpion toxin inhibits the voltage-gated proton channel using a Zn -like long-range conformational coupling mechanism.
机构信息
The National and Local Joint Engineering Laboratory of Animal Peptide Drug Development, College of Life Sciences, Hunan Normal University, Changsha, China.
Kuang Yaming Honors School, Nanjing University, Nanjing, China.
出版信息
Br J Pharmacol. 2020 May;177(10):2351-2364. doi: 10.1111/bph.14984. Epub 2020 Mar 3.
BACKGROUND AND PURPOSE
Blocking the voltage-gated proton channel H 1 is a promising strategy for the treatment of diseases like ischaemia stroke and cancer. However, few H 1 channel antagonists have been reported. Here, we have identified a novel H 1 channel antagonist from scorpion venom and have elucidated its action mechanism.
EXPERIMENTAL APPROACH
H 1 and NaV channels were heterologously expressed in mammalian cell lines and their currents recorded using whole-cell patch clamp. Site-directed mutagenesis was used to generate mutants. Toxins were recombinantly produced in Escherichia coli. AGAP/W38F-H 1 interaction was modelled by molecular dynamics simulations.
KEY RESULTS
The scorpion toxin AGAP (anti-tumour analgesic peptide) potently inhibited H 1 currents. One AGAP mutant has reduced Na channel activity but intact H 1 activity (AGAP/W38F). AGAP/W38F inhibited H 1 channel activation by trapping its S4 voltage sensor in a deactivated state and inhibited H 1 currents with less pH dependence than Zn . Mutation analysis showed that the binding pockets of AGAP/W38F and Zn in H 1 channel partly overlapped (common sites are His140 and His193). The E153A mutation at the intracellular Coulombic network (ICN) in H 1 channel markedly reduced AGAP/W38F inhibition, as observed for Zn . Experimental data and MD simulations suggested that AGAP/W38F inhibited H 1 channel using a Zn -like long-range conformational coupling mechanism.
CONCLUSION AND IMPLICATIONS
Our results suggest that the Zn binding pocket in H 1 channel might be a hotspot for modulators and valuable for designing H 1 channel ligands. Moreover, AGAP/W38F is a useful molecular probe to study H 1 channel and a lead compound for drug development.
背景与目的
阻断电压门控质子通道 H 1 是治疗缺血性中风和癌症等疾病的一种很有前途的策略。然而,目前报道的 H 1 通道拮抗剂较少。在这里,我们从蝎子毒液中鉴定出一种新型的 H 1 通道拮抗剂,并阐明了其作用机制。
实验方法
在哺乳动物细胞系中异源表达 H 1 和 NaV 通道,并使用全细胞膜片钳记录电流。通过定点突变生成突变体。毒素在大肠杆菌中重组表达。通过分子动力学模拟构建 AGAP/W38F-H 1 相互作用模型。
主要结果
蝎子毒素 AGAP(抗肿瘤止痛肽)可强烈抑制 H 1 电流。AGAP 的一个突变体(AGAP/W38F)具有降低的钠通道活性但保留完整的 H 1 活性。AGAP/W38F 通过将其 S4 电压传感器锁定在失活状态来抑制 H 1 通道的激活,并比 Zn 更依赖于 pH 来抑制 H 1 电流。突变分析表明,AGAP/W38F 和 Zn 在 H 1 通道中的结合口袋部分重叠(共同的结合位点为 His140 和 His193)。H 1 通道的细胞内库仑网络(ICN)中的 E153A 突变明显降低了 AGAP/W38F 的抑制作用,这与 Zn 的情况相似。实验数据和 MD 模拟表明,AGAP/W38F 通过类似 Zn 的长程构象偶联机制抑制 H 1 通道。
结论与意义
我们的研究结果表明,H 1 通道中的 Zn 结合口袋可能是调节剂的热点,对设计 H 1 通道配体具有重要价值。此外,AGAP/W38F 是研究 H 1 通道的有用分子探针,也是开发药物的先导化合物。
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