Hershey P E, McWhirter S M, Gross J D, Wagner G, Alber T, Sachs A B
Department of Molecular and Cell Biology, University of California at Berkeley, Berkeley, California 94720, USA.
J Biol Chem. 1999 Jul 23;274(30):21297-304. doi: 10.1074/jbc.274.30.21297.
The association of eucaryotic translation initiation factor eIF4G with the cap-binding protein eIF4E establishes a critical link between the mRNA and the ribosome during translation initiation. This association requires a conserved seven amino acid peptide within eIF4G that binds to eIF4E. Here we report that a 98-amino acid fragment of S. cerevisiae eIF4G1 that contains this eIF4E binding peptide undergoes an unfolded to folded transition upon binding to eIF4E. The folding of the eIF4G1 domain was evidenced by the eIF4E-dependent changes in its protease sensitivity and (1)H-(15)N HSQC NMR spectrum. Analysis of a series of charge-to-alanine mutations throughout the essential 55.4-kDa core of yeast eIF4G1 also revealed substitutions within this 98-amino acid region that led to reduced eIF4E binding in vivo and in vitro. These data suggest that the association of yeast eIF4E with eIF4G1 leads to the formation of a structured domain within eIF4G1 that could serve as a specific site for interactions with other components of the translational apparatus. They also suggest that the stability of the native eIF4E-eIF4G complex is determined by amino acid residues outside of the conserved seven-residue consensus sequence.
真核生物翻译起始因子eIF4G与帽结合蛋白eIF4E的结合在翻译起始过程中建立了mRNA与核糖体之间的关键联系。这种结合需要eIF4G内一个保守的七氨基酸肽与eIF4E结合。在此我们报道,酿酒酵母eIF4G1的一个包含该eIF4E结合肽的98氨基酸片段在与eIF4E结合后会发生从解折叠到折叠的转变。eIF4G1结构域的折叠通过其蛋白酶敏感性和(1)H - (15)N HSQC NMR谱中依赖于eIF4E的变化得以证明。对酵母eIF4G1必需的55.4 kDa核心区域一系列电荷到丙氨酸的突变分析还揭示,在这个98氨基酸区域内的替换导致体内和体外eIF4E结合减少。这些数据表明,酵母eIF4E与eIF4G1的结合导致eIF4G1内形成一个结构化结构域,该结构域可作为与翻译装置其他组分相互作用的特定位点。它们还表明,天然eIF4E - eIF4G复合物的稳定性由保守的七残基共有序列之外的氨基酸残基决定。
