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全长 Toll 样受体 3 在磷脂双层中的结构与动力学的计算研究

A Computational Probe into the Structure and Dynamics of the Full-Length Toll-Like Receptor 3 in a Phospholipid Bilayer.

机构信息

Department of Molecular Science and Technology, Ajou University, 16499 Suwon, Korea.

出版信息

Int J Mol Sci. 2020 Apr 19;21(8):2857. doi: 10.3390/ijms21082857.

DOI:10.3390/ijms21082857
PMID:32325904
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7215789/
Abstract

Toll-like receptor 3 (TLR3) provides the host with antiviral defense by initiating an immune signaling cascade for the production of type I interferons. The X-ray structures of isolated TLR3 ectodomain (ECD) and transmembrane (TM) domains have been reported; however, the structure of a membrane-solvated, full-length receptor remains elusive. We investigated an all-residue TLR3 model embedded inside a phospholipid bilayer using molecular dynamics simulations. The TLR3-ECD exhibited a ~30°-35° tilt on the membrane due to the electrostatic interaction between the N-terminal subdomain and phospholipid headgroups. Although the movement of dsRNA did not affect the dimer integrity of TLR3, its sugar-phosphate backbone was slightly distorted with the orientation of the ECD. TM helices exhibited a noticeable tilt and curvature but maintained a consistent crossing angle, avoiding the hydrophobic mismatch with the bilayer. Residues from the αD helix and the CD and DE loops of the Toll/interleukin-1 receptor (TIR) domains were partially absorbed into the lower leaflet of the bilayer. We found that the previously unknown TLR3-TIR dimerization interface could be stabilized by the reciprocal contact between αC and αD helices of one subunit and the αC helix and the BB loop of the other. Overall, the present study can be helpful to understand the signaling-competent form of TLR3 in physiological environments.

摘要

Toll 样受体 3(TLR3)通过启动 I 型干扰素的产生来为宿主提供抗病毒防御。已报道了分离的 TLR3 胞外域(ECD)和跨膜(TM)结构域的 X 射线结构;然而,完整的膜结合全长受体的结构仍然难以捉摸。我们使用分子动力学模拟研究了嵌入磷脂双层中的全残基 TLR3 模型。由于 N 端亚结构域和磷脂头基之间的静电相互作用,TLR3-ECD 在膜上倾斜约 30°-35°。尽管 dsRNA 的运动不会影响 TLR3 的二聚体完整性,但它的糖磷酸主链略有扭曲,ECD 的方向也随之改变。TM 螺旋表现出明显的倾斜和曲率,但保持一致的交叉角度,避免与双层的疏水性不匹配。来自 αD 螺旋和 Toll/白细胞介素-1 受体(TIR)结构域的 CD 和 DE 环的残基部分被吸收到双层的下叶。我们发现,以前未知的 TLR3-TIR 二聚化界面可以通过一个亚基的 αC 和 αD 螺旋与另一个亚基的 αC 螺旋和 BB 环的相互接触来稳定。总体而言,本研究有助于理解生理环境中信号传导功能完整的 TLR3。

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