与 α1A-肾上腺素受体选择性相互作用的蛇毒天然肽 ρ-Da1a 的正位结合。

Orthosteric binding of ρ-Da1a, a natural peptide of snake venom interacting selectively with the α1A-adrenoceptor.

机构信息

Commissariat à l'Énergie Atomique Et Aux Énergies Alternatives, iBiTec-S, Service d'Ingénierie Moléculaire des Protéines, Gif sur Yvette, France.

出版信息

PLoS One. 2013 Jul 25;8(7):e68841. doi: 10.1371/journal.pone.0068841. Print 2013.

DOI:10.1371/journal.pone.0068841

PMID:23935897

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3723878/

Abstract

ρ-Da1a is a three-finger fold toxin from green mamba venom that is highly selective for the α1A-adrenoceptor. This toxin has atypical pharmacological properties, including incomplete inhibition of (3)H-prazosin or (125)I-HEAT binding and insurmountable antagonist action. We aimed to clarify its mode of action at the α1A-adrenoceptor. The affinity (pKi 9.26) and selectivity of ρ-Da1a for the α1A-adrenoceptor were confirmed by comparing binding to human adrenoceptors expressed in eukaryotic cells. Equilibrium and kinetic binding experiments were used to demonstrate that ρ-Da1a, prazosin and HEAT compete at the α1A-adrenoceptor. ρ-Da1a did not affect the dissociation kinetics of (3)H-prazosin or (125)I-HEAT, and the IC50 of ρ-Da1a, determined by competition experiments, increased linearly with the concentration of radioligands used, while the residual binding by ρ-Da1a remained stable. The effect of ρ-Da1a on agonist-stimulated Ca(2+) release was insurmountable in the presence of phenethylamine- or imidazoline-type agonists. Ten mutations in the orthosteric binding pocket of the α1A-adrenoceptor were evaluated for alterations in ρ-Da1a affinity. The D106(3.32)A and the S188(5.42)A/S192(5.46)A receptor mutations reduced toxin affinity moderately (6 and 7.6 times, respectively), while the F86(2.64)A, F288(6.51)A and F312(7.39)A mutations diminished it dramatically by 18- to 93-fold. In addition, residue F86(2.64) was identified as a key interaction point for (125)I-HEAT, as the variant F86(2.64)A induced a 23-fold reduction in HEAT affinity. Unlike the M1 muscarinic acetylcholine receptor toxin MT7, ρ-Da1a interacts with the human α1A-adrenoceptor orthosteric pocket and shares receptor interaction points with antagonist (F86(2.64), F288(6.51) and F312(7.39)) and agonist (F288(6.51) and F312(7.39)) ligands. Its selectivity for the α1A-adrenoceptor may result, at least partly, from its interaction with the residue F86(2.64), which appears to be important also for HEAT binding.

摘要

ρ-Da1a 是一种来自绿曼巴蛇毒液的三指折叠毒素，对 α1A-肾上腺素受体具有高度选择性。这种毒素具有非典型的药理学特性，包括不完全抑制 (3)H-哌唑嗪或 (125)I-HEAT 结合以及无法克服的拮抗剂作用。我们旨在阐明其在 α1A-肾上腺素受体上的作用模式。通过比较在真核细胞中表达的人肾上腺素受体的结合，证实了 ρ-Da1a 对 α1A-肾上腺素受体的亲和力 (pKi9.26) 和选择性。平衡和动力学结合实验用于证明 ρ-Da1a、哌唑嗪和 HEAT 在 α1A-肾上腺素受体上竞争。ρ-Da1a 不影响 (3)H-哌唑嗪或 (125)I-HEAT 的解离动力学，通过竞争实验确定的 ρ-Da1a 的 IC50 值随所用放射性配体浓度的线性增加而增加，而 ρ-Da1a 的残留结合保持稳定。在苯乙胺或咪唑啉类激动剂存在下，ρ-Da1a 对激动剂刺激的 Ca(2+)释放的作用是不可逾越的。评估了 α1A-肾上腺素受体的正位结合口袋中的 10 个突变，以改变 ρ-Da1a 的亲和力。D106(3.32)A 和 S188(5.42)A/S192(5.46)A 受体突变适度降低毒素亲和力 (分别为 6 倍和 7.6 倍)，而 F86(2.64)A、F288(6.51)A 和 F312(7.39)A 突变则使亲和力显著降低 18-93 倍。此外，残基 F86(2.64)被确定为 (125)I-HEAT 的关键相互作用点，因为变体 F86(2.64)A 诱导 HEAT 亲和力降低 23 倍。与 M1 毒蕈碱乙酰胆碱受体毒素 MT7 不同，ρ-Da1a 与人类 α1A-肾上腺素受体正位口袋相互作用，并与拮抗剂 (F86(2.64)、F288(6.51)和 F312(7.39))和激动剂 (F288(6.51)和 F312(7.39))配体共享受体相互作用点。它对 α1A-肾上腺素受体的选择性可能至少部分来自于与残基 F86(2.64)的相互作用，该残基似乎对 HEAT 结合也很重要。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ba59/3723878/b38055937948/pone.0068841.g001.jpg

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与 α1A-肾上腺素受体选择性相互作用的蛇毒天然肽 ρ-Da1a 的正位结合。

Orthosteric binding of ρ-Da1a, a natural peptide of snake venom interacting selectively with the α1A-adrenoceptor.

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