Bacterial Protein Toxin Research Cluster, Institute of Molecular Biosciences, Mahidol University, Salaya Campus, Nakorn Pathom 73170, Thailand.
Division of Biology, Department of Science, Faculty of Science and Technology, Prince of Songkla University, Pattani 94000, Thailand.
Biochim Biophys Acta Biomembr. 2017 Mar;1859(3):312-318. doi: 10.1016/j.bbamem.2016.12.011. Epub 2016 Dec 18.
Previously, the ~130-kDa CyaA-hemolysin domain (CyaA-Hly) from Bordetella pertussis co-expressed with CyaC-acyltransferase in Escherichia coli was demonstrated to be palmitoylated at Lys and thus activated its hemolytic activity against target erythrocytes. Here, we report the functional importance of Lys-palmitoylation for membrane insertion and pore formation of CyaA-Hly. Intrinsic fluorescence emissions of both non-acylated CyaA-Hly (NA/CyaA-Hly) and CyaA-Hly were indistinguishable, suggesting no severe conformational change upon acylation at Lys. Following pre-incubation of sheep erythrocytes with NA/CyaA-Hly, there was a drastic decrease in CyaA-Hly-induced hemolysis. Direct interactions between NA/CyaA-Hly and target erythrocyte membranes were validated via membrane-binding assays along with Western blotting, suggestive of acylation-independent capability of NA/CyaA-Hly to interact with erythrocyte membranes. As compared with CyaA-Hly, NA/CyaA-Hly displayed a slower rate of incorporation into DOPC:DOPE:Ch or DiPhyPC bilayers under symmetrical conditions (1M KCl, 10mM HEPES, pH7.4) and formed channels exhibiting different conductance. Further analysis revealed that channel-open lifetime in DOPC:DOPE:Ch bilayers of NA/CyaA-Hly was much shorter than that of the acylated form, albeit slightly shorter lifetime found in DiPhyPC bilayers. Sequence alignments of the Lys-containing CyaA-segment with those of related RTX-cytolysins revealed a number of highly conserved hydrophobic residues and a Lys/Arg cluster that is predicted be important for toxin-membrane interactions. Altogether, our data disclosed that the Lys-linked palmitoyl group is not directly involved in either binding to target erythrocyte membranes or toxin-induced channel conductivity, but rather required for efficient membrane insertion and pore formation of the acylated CyaA-Hly domain.
先前,在大肠杆菌中与 CyaC-酰基转移酶共表达的百日咳博德特氏菌~130kDa CyaA-溶血素结构域(CyaA-Hly)被证明在赖氨酸残基上发生棕榈酰化,从而激活其对靶红细胞的溶血活性。在这里,我们报告了赖氨酸棕榈酰化对于 CyaA-Hly 的膜插入和孔形成的功能重要性。非酰化的 CyaA-Hly(NA/CyaA-Hly)和 CyaA-Hly 的固有荧光发射没有区别,这表明在赖氨酸残基上发生酰化后没有严重的构象变化。在用 NA/CyaA-Hly 预孵育绵羊红细胞后,CyaA-Hly 诱导的溶血急剧下降。通过膜结合测定和 Western blot 验证了 NA/CyaA-Hly 与靶红细胞膜之间的直接相互作用,提示 NA/CyaA-Hly 具有与红细胞膜相互作用的酰化独立能力。与 CyaA-Hly 相比,NA/CyaA-Hly 在对称条件下(1M KCl、10mM HEPES、pH7.4)掺入 DOPC:DOPE:Ch 或 DiPhyPC 双层的速度较慢,并且形成的通道表现出不同的电导。进一步分析表明,NA/CyaA-Hly 在 DOPC:DOPE:Ch 双层中的通道开放寿命明显短于酰化形式,尽管在 DiPhyPC 双层中发现的寿命略短。含有赖氨酸的 CyaA 片段与相关 RTX 细胞毒素的序列比对揭示了许多高度保守的疏水性残基和一个赖氨酸/精氨酸簇,该簇被预测对于毒素-膜相互作用很重要。总之,我们的数据表明,赖氨酸连接的棕榈酰基基团不直接参与与靶红细胞膜的结合或毒素诱导的通道电导率,而是需要酰化的 CyaA-Hly 结构域的有效膜插入和孔形成。
