人类eIF4A/4G/4H解旋酶复合体在翻译起始中的拓扑结构与调控
Topology and regulation of the human eIF4A/4G/4H helicase complex in translation initiation.
作者信息
Marintchev Assen, Edmonds Katherine A, Marintcheva Boriana, Hendrickson Elthea, Oberer Monika, Suzuki Chikako, Herdy Barbara, Sonenberg Nahum, Wagner Gerhard
机构信息
Department of Biological Chemistry and Molecular Pharmacology, Harvard Medical School, Boston, MA, USA.
出版信息
Cell. 2009 Feb 6;136(3):447-60. doi: 10.1016/j.cell.2009.01.014.
Abstract
The RNA helicase eIF4A plays a key role in unwinding of mRNA and scanning during translation initiation. Free eIF4A is a poor helicase and requires the accessory proteins eIF4G and eIF4H. However, the structure of the helicase complex and the mechanisms of stimulation of eIF4A activity have remained elusive. Here we report the topology of the eIF4A/4G/4H helicase complex, which is built from multiple experimentally observed domain-domain contacts. Remarkably, some of the interactions are continuously rearranged during the ATP binding/hydrolysis cycle of the helicase. We show that the accessory proteins modulate the affinity of eIF4A for ATP by interacting simultaneously with both helicase domains and promoting either the closed, ATP-bound conformation or the open, nucleotide-free conformation. The topology of the complex and the spatial arrangement of the RNA-binding surfaces offer insights into their roles in stimulation of helicase activity and the mechanisms of mRNA unwinding and scanning.
摘要
RNA解旋酶eIF4A在翻译起始过程中mRNA的解旋和扫描中起关键作用。游离的eIF4A是一种低效解旋酶,需要辅助蛋白eIF4G和eIF4H。然而,解旋酶复合物的结构以及eIF4A活性刺激机制仍不清楚。在此我们报道了eIF4A/4G/4H解旋酶复合物的拓扑结构,它是由多个实验观察到的结构域-结构域相互作用构建而成。值得注意的是,在解旋酶的ATP结合/水解循环过程中,一些相互作用会持续重排。我们表明辅助蛋白通过同时与两个解旋酶结构域相互作用,并促进闭合的、ATP结合构象或开放的、无核苷酸构象,来调节eIF4A对ATP的亲和力。复合物的拓扑结构和RNA结合表面的空间排列为它们在刺激解旋酶活性以及mRNA解旋和扫描机制中的作用提供了见解。
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