膜融合中的脂质和脂化。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2022-12-01 DOI:10.1007/s00232-022-00267-5
Avijit Sardar, Nikesh Dewangan, Bishvanwesha Panda, Debosmita Bhowmick, Pradip K Tarafdar
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引用次数: 8

摘要

膜融合在囊泡运输、神经传递、线粒体动力学和病毒感染中起主导作用。有一些融合蛋白催化和调节融合。有趣的是,自然界中存在各种类型的融合蛋白,它们具有不同的作用机制。我们强调了细胞内异型融合、同型内质网(ER)、同型线粒体和i型病毒融合的功能域的重要性。在细胞内异型融合过程中,SNAREs和四螺旋束形成是普遍存在的。i型病毒融合受融合肽的膜不稳定特性和六螺旋束的形成控制。内质网/线粒体同型融合受GTPase活性和两亲螺旋的膜不稳定特性控制。虽然这些融合蛋白的作用机制不同,但它们有一些相似之处。在所有情况下,膜的脂质组成极大地影响膜融合。接下来,讨论了融合蛋白脂化的例子。我们认为脂肪酰基疏水尾部不仅可以作为锚,还可以调节膜融合中间体的能量学。脂化对于设计更有效的肽基融合抑制剂也很重要。总之,我们已经表明,膜脂组成和脂化是重要的调节膜融合。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Lipid and Lipidation in Membrane Fusion.

Membrane fusion plays a lead role in the transport of vesicles, neurotransmission, mitochondrial dynamics, and viral infection. There are fusion proteins that catalyze and regulate the fusion. Interestingly, various types of fusion proteins are present in nature and they possess diverse mechanisms of action. We have highlighted the importance of the functional domains of intracellular heterotypic fusion, homotypic endoplasmic reticulum (ER), homotypic mitochondrial, and type-I viral fusion. During intracellular heterotypic fusion, the SNAREs and four-helix bundle formation are prevalent. Type-I viral fusion is controlled by the membrane destabilizing properties of fusion peptide and six-helix bundle formation. The ER/mitochondrial homotypic fusion is controlled by GTPase activity and the membrane destabilization properties of the amphipathic helix(s). Although the mechanism of action of these fusion proteins is diverse, they have some similarities. In all cases, the lipid composition of the membrane greatly affects membrane fusion. Next, examples of lipidation of the fusion proteins were discussed. We suggest that the fatty acyl hydrophobic tail not only acts as an anchor but may also modulate the energetics of membrane fusion intermediates. Lipidation is also important to design more effective peptide-based fusion inhibitors. Together, we have shown that membrane lipid composition and lipidation are important to modulate membrane fusion.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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