分类: 生物学 >> 生物物理学 >> 生物物理、生物化学与分子生物学 提交时间: 2016-05-12
摘要: Talin, as the activator of integrin and the adaptor between the cytoskeleton and integrin, plays a key role in a series of processes such as cell adhesion and migration. The activation of integrin involves F3 subdomain of Talin-FERM domain binding the cytoplasmic tail of integrin beta-subunit. Talin has two states: auto-inhibited and activated. We previously reported the auto-inhibition complex structure of Talin F2F3/R9, in which the integrin binding site F3 interacts with R9(1654 similar to 1822 a.a.) of Talin-ROD, such that integrin cannot be activated. However, besides F3 and R9, it remains unclear what structural or functional roles the other domains of the 270 ku Talin play in the regulation of its activation. Here we solved the crystal structures of Talin R9-R10 (1654 similar to 1973 a.a.) and R10-R11 (1815 similar to 2140 a.a.), respectively. R9, R10 and R11 are all 5-helix bundles. R9 and R10 is joined together by a long alpha-helix instead of a flexible loop, and the two bundles are located at the opposite sides of the long helix with an angle of about 150 degrees. The linker between R10 and R11 is stabilized by neighboring hydrogen bonds, forming an angle of about 120 between the two bundles. These angles observed in our crystal structures are consistent with the previously reported SAXS and EM results. After superimposition of R9-10, R10-11 with previously reported structures of R7-8 and R11-12, a model of R7-12 was acquired, which adopts an elongated linear conformation, except that R8 protrudes from the ROD. According to this model, R10-12 does not intrude the interaction between F3 and R9, whereas R8 not only masks the F3 binding site of R9, but also might electrostatically hinders F2F3 approaching via its unique positively charged surface. This hypothesis was further verified by the results of size exclusion chromatography. Our work provides a new structural basis for studying the mechanism of Talin auto-inhibition.
分类: 生物学 >> 生物物理学 >> 生物力学与生物流变学 提交时间: 2016-05-12
Zeng Yan
Zhang Yong
Ji QingHua
Lou JiZhong
Song XianQiang
Ye Sheng
Zhang RongGuang
Zeng Yan
Song XianQiang
Ji QingHua
摘要: Talin is an integrin-binding protein located at focal adhesion site and serves as both an adapter and a force transmitter. Its integrin binding activity is regulated by the intramolecular autoinhibition interaction between its F3 and RS domains. Here, we used atomic force microscopy to measure the strength of talin autoinhibition complex. Our results suggest that the lifetime of talin autoinhibition complex shows weak catch bond behavior and does not change significantly at smaller forces, while it drops rapidly at larger forces (>10 pN). Moreover, besides the complex conformation revealed by crystal structure, our molecular dynamics (MD) simulations indicate the possible existence of another stable conformation. Further analysis indicates that forces may regulate the equilibrium of the two stable binding states and result in the non-exponential force dependence of the binding lifetime. Our findings reveal a negative regulation mechanism on talin activation and provide a new point of view on the function of talin in focal adhesion.
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