Forouhar Farhad, Huang Wei-Ning, Liu Jyung-Hurng, Chien Kun-Yi, Wu Wen-guey, Hsiao Chwan-Deng
Institute of Molecular Biology, Academia Sinica, Taipei, Taiwan 115.
J Biol Chem. 2003 Jun 13;278(24):21980-8. doi: 10.1074/jbc.M208650200. Epub 2003 Mar 26.
Cobra cardiotoxins (CTXs) have previously been shown to induce membrane fusion of vesicles formed by phospholipids such as cardiolipin or sphingomyelin. CTX can also form a pore in membrane bilayers containing a anionic lipid such as phosphatidylserine or phosphatidylglycerol. Herein, we show that the interaction of CTX with negatively charged lipids causes CTX dimerization, an important intermediate for the eventual oligomerization of CTX during the CTX-induced fusion and pore formation process. The structural basis of the lipid-induced oligomerization of CTX A3, a major CTX from Naja atra, is then illustrated by the crystal structure of CTX A3 in complex with SDS; SDS likely mimics anionic lipids of the membrane under micelle conditions at 1.9-A resolution. The crystal packing reveals distinct SDS-free and SDS-rich regions; in the latter two types of interconnecting CTX A3 dimers, D1 and D2, and several SDS molecules can be identified to stabilize D1 and D2 by simultaneously interacting with residues at each dimer interface. When the three CTXSDS complexes in the asymmetric unit are overlaid, the orientation of CTX A3 monomers relative to the SDS molecules in the crystal is strikingly similar to that of the toxin with respect to model membranes as determined by NMR and Fourier transform infrared methods. These results not only illustrate how lipid-induced CTX dimer formation may be transformed into oligomers either as inverted micelles of fusion intermediates or as membrane pore of anionic lipid bilayers but also underscore a potential role for SDS in x-ray diffraction study of protein-membrane interactions in the future.
此前已表明,眼镜蛇心脏毒素(CTXs)可诱导由心磷脂或鞘磷脂等磷脂形成的囊泡发生膜融合。CTX还能在含有阴离子脂质(如磷脂酰丝氨酸或磷脂酰甘油)的膜双分子层中形成孔道。在此,我们表明CTX与带负电荷脂质的相互作用会导致CTX二聚化,这是CTX在诱导融合和孔道形成过程中最终寡聚化的重要中间体。然后,通过CTX A3(眼镜蛇毒液中的一种主要CTX)与SDS复合物的晶体结构,阐明了脂质诱导的CTX A3寡聚化的结构基础;在1.9埃分辨率下,SDS在胶束条件下可能模拟膜的阴离子脂质。晶体堆积显示出明显的无SDS区域和富含SDS区域;在后者中,可以识别出两种相互连接的CTX A3二聚体D1和D2,以及几个SDS分子,它们通过与每个二聚体界面处的残基同时相互作用来稳定D1和D2。当不对称单元中的三个CTX-SDS复合物叠加时,晶体中CTX A3单体相对于SDS分子的取向与通过核磁共振和傅里叶变换红外方法测定的毒素相对于模型膜的取向惊人地相似。这些结果不仅说明了脂质诱导的CTX二聚体形成如何转化为作为融合中间体的反胶束或作为阴离子脂质双层膜孔的寡聚体,还强调了SDS在未来蛋白质-膜相互作用的X射线衍射研究中的潜在作用。