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流感 M2 跨膜域感知膜异质性并增强膜曲率。

Influenza M2 Transmembrane Domain Senses Membrane Heterogeneity and Enhances Membrane Curvature.

机构信息

Department of Physics and ‡Department of Chemistry, University of South Florida , Tampa, Florida 33620, United States.

出版信息

Langmuir. 2016 Jul 5;32(26):6730-8. doi: 10.1021/acs.langmuir.6b00150. Epub 2016 Jun 21.

DOI:10.1021/acs.langmuir.6b00150
PMID:27285399
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5131574/
Abstract

Targeting host cell membranes by M2 of influenza A virus is important for virus invasion and replication. We study the transmembrane domain of M2 (M2TM) interacting with mica-supported planar bilayers and free-standing giant unilamellar vesicles (GUVs). Using solution atomic force microscopy (AFM), we show that the size of M2TM oligomers is dependent on lipid composition. The addition of M2TM to lipid bilayers containing liquid-ordered (Lo) and liquid-disordered (Ld) phases reveals that M2TM preferentially partitions into the Ld phase; phase-dependent partitioning results in a larger rigidity of the Ld phase. We next use fluorescence microscopy to study the effects of M2TM on phase-coexisting GUVs. In particular, M2TM is found to increase GUVs' miscibility transition temperature Tmix. The augmented thermodynamic stability can be accounted for by considering an enhanced energy barrier of lipid mixing between coexisting phases. Our GUV study also shows that M2TM can elicit an array of vesicle shapes mimicking virus budding. M2TM enhanced membrane curvature is consistent with our AFM data, which show altered membrane rigidity and consequently line tension at domain edges. Together, our results highlight that in addition to conducting protons, M2TM can actively regulate membrane heterogeneity and augment membrane curvature.

摘要

流感 A 病毒 M2 靶向宿主细胞膜对于病毒入侵和复制非常重要。我们研究了 M2(M2TM)跨膜结构域与云母支持的平面双层膜和独立的巨大单层囊泡(GUV)的相互作用。通过溶液原子力显微镜(AFM),我们表明 M2TM 低聚物的大小取决于脂质组成。将 M2TM 添加到含有液晶有序(Lo)相和液晶无序(Ld)相的脂质双层中,表明 M2TM 优先分配到 Ld 相;相依赖性分配导致 Ld 相的刚性更大。我们接下来使用荧光显微镜研究 M2TM 对共存相 GUV 的影响。具体来说,发现 M2TM 会增加 GUV 的混合转变温度 Tmix。增强的热力学稳定性可以通过考虑共存相之间的脂质混合的能量势垒来解释。我们的 GUV 研究还表明,M2TM 可以引发一系列模仿病毒出芽的囊泡形状。M2TM 增强的膜曲率与我们的 AFM 数据一致,该数据显示了膜刚性的改变,进而导致了畴边缘的线张力改变。总之,我们的结果强调了 M2TM 除了传导质子外,还可以主动调节膜异质性并增加膜曲率。

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