涉及多模蛋白的机械转导:将力转化为生化信号。

Viola Vogel
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引用次数: 425

摘要

细胞可以感知并将广泛的机械力转化为不同的生化信号,最终调节细胞过程,包括粘附、增殖、分化和凋亡。在纳米尺度上破译将感觉元件整合到结构蛋白基序(结构蛋白基序的构象可以机械地切换)的设计原理,对于理解力转导成生化信号的过程至关重要,而生化信号随后被整合以调节机械反应途径。虽然机械感觉单位的研究主要集中在膜蛋白上,如离子通道、整合素和相关的细胞质复合物,但在细胞外基质蛋白、细胞粘附分子和许多将跨膜蛋白物理连接到收缩细胞骨架的细胞内参与者中,普遍发现了各种结构基元串联重复的多模块设计。单分子研究揭示了意想不到的机械感觉基元的丰富性,包括环暴露的分子识别位点的力调节构象变化,解开途径中的中间状态,可能暴露隐结合或磷酸化位点,或只有在被力揭开时才显示酶活性的区域。对机械化学信号转换原理的见解也将影响从生物技术到组织工程和药物开发的各个技术领域。
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Mechanotransduction involving multimodular proteins: converting force into biochemical signals.

Cells can sense and transduce a broad range of mechanical forces into distinct sets of biochemical signals that ultimately regulate cellular processes, including adhesion, proliferation, differentiation, and apoptosis. Deciphering at the nanoscale the design principles by which sensory elements are integrated into structural protein motifs whose conformations can be switched mechanically is crucial to understand the process of transduction of force into biochemical signals that are then integrated to regulate mechanoresponsive pathways. While the major focus in the search for mechanosensory units has been on membrane proteins such as ion channels, integrins, and associated cytoplasmic complexes, a multimodular design of tandem repeats of various structural motifs is ubiquitously found among extracellular matrix proteins, as well as cell adhesion molecules, and among many intracellular players that physically link transmembrane proteins to the contractile cytoskeleton. Single-molecule studies have revealed an unexpected richness of mechanosensory motifs, including force-regulated conformational changes of loop-exposed molecular recognition sites, intermediate states in the unraveling pathway that might either expose cryptic binding or phosphorylation sites, or regions that display enzymatic activity only when unmasked by force. Insights into mechanochemical signal conversion principles will also affect various technological fields, from biotechnology to tissue engineering and drug development.

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