Uno M, Ito K, Nakamura Y
Department of Tumor Biology, University of Tokyo, Japan.
Biochimie. 1996;78(11-12):935-43. doi: 10.1016/s0300-9084(97)86715-6.
The termination of protein synthesis in bacteria requires codon-specific polypeptide release factors RF-1 (UAG/UAA specific) and RF-2 (UGA/UAA specific). We have proposed that release factors mimic tRNA and recognize the stop codon for polypeptide release (Nakamura et al (1996) Cell 87, 147-150). In contrast to the textbook view, genetic experiments have indicated that Escherichia coli RF-2 terminates translation very weakly at UAA while Salmonella RF-2 decodes this signal efficiently. Moreover, an excess of E coli RF-2 was toxic to cells while an excess of Salmonella RF-2 was not. These two RF-2 proteins are identical except for 16 out of 365 amino acids. Fragment swap experiments and site-directed mutagenesis revealed that a residue at position 246 is solely responsible for these two phenotypes. Upon substituting Ala (equivalent to Salmonella RF-2) for Thr-246 of E coli RF-2, the protein acquired increased release activity for UAA as well as for UGA. These results led us to conclude that E coli RF-2 activity is potentially weak and that the amino acid at position 246 plays a crucial role, not for codon discrimination, but for stop codon recognition or polypeptide release, presumably constituting an essential moiety of tRNA mimicry or interacting with peptidyltransferase centers of the ribosome.
细菌中蛋白质合成的终止需要密码子特异性的多肽释放因子RF-1(识别UAG/UAA)和RF-2(识别UGA/UAA)。我们曾提出释放因子模拟tRNA并识别终止密码子以实现多肽释放(Nakamura等人,(1996)《细胞》87卷,147 - 150页)。与教科书观点不同的是,遗传学实验表明大肠杆菌的RF-2在UAA处终止翻译的能力非常弱,而沙门氏菌的RF-2能高效解码这个信号。此外,过量的大肠杆菌RF-2对细胞有毒性,而过量的沙门氏菌RF-2则没有。这两种RF-2蛋白除了365个氨基酸中有16个不同外其余完全相同。片段交换实验和定点诱变表明,第246位的一个残基是造成这两种表型的唯一原因。将大肠杆菌RF-2的第246位苏氨酸替换为丙氨酸(等同于沙门氏菌RF-2)后,该蛋白对UAA以及UGA的释放活性都增强了。这些结果使我们得出结论,大肠杆菌RF-2的活性可能较弱,并且第246位的氨基酸起着关键作用,不是用于密码子识别,而是用于终止密码子识别或多肽释放,大概构成了模拟tRNA的一个必需部分或与核糖体的肽基转移酶中心相互作用。
