Sipley J, Goldman E
Department of Microbiology and Molecular Genetics, New Jersey Medical School, Newark.
Proc Natl Acad Sci U S A. 1993 Mar 15;90(6):2315-9. doi: 10.1073/pnas.90.6.2315.
We have tested the effect of increased ribosomal fidelity on a modified version of the programmed release factor 2 (RF2) translational frameshift. In the constructs tested, the original UGA codon at the site of the shift was replaced by either of two sense codons, UGG (tryptophan), which allows a frameshift of approximately 13%, or CUG (leucine), which allows a frameshift of only approximately 2%. We confirmed the results of Curran and Yarus [Curran, J. F. & Yarus, M. (1989) J. Mol. Biol. 209, 65-77] in a wild-type ribosomal host, including a reduction of the UGG shift following induction of tRNA(Trp) from a plasmid copy of the tRNA gene. But to our surprise, in a hyperaccurate streptomycin pseudo-dependent host, the UGG frameshift increased to more than 50%. When we added a tRNA(Trp) plasmid to these cells, induction of the tRNA(Trp) gene reduced the shift back to approximately 7%. Messenger RNA levels did not vary greatly under these different induced conditions. Other increased accuracy alleles also showed increased frameshifting with UGG at the frameshift site. All increased accuracy alleles led to slower translation rates, and there appeared to be a proportionality between the extent of reduction of synthesis for the in-frame reporter and the extent of UGG frameshift for the out-of-frame reporter. There were little effects of increased accuracy on the lower level CUG frameshift. However, over-production of the cognate tRNA(1Leu) dramatically reduced even this lower level of shift, despite the fact that tRNA(1Leu) is already the most abundant isoacceptor in Escherichia coli. These results can be rationalized by following the hypothesis of Curran and Yarus as follows: with wild-type ribosomes, limited availability of tRNA(Trp) (about 1% of total tRNA) facilitates a pause at the UGG codon (due to the vacant A site), allowing increased opportunity for ribosome realignment. Excess tRNA(Trp) reduces the time the A site is vacant and thus reduces the frameshift. The slower hyperaccurate ribosomes increase the pause time and thus increase the opportunity for shifting, a process again reversed by increasing the in-frame cognate tRNA(Trp). These data provide strong support for a model in which the extent of ribosome pause time at a programmed frameshift site is a major determinant in the efficiency of the frameshift and in which tRNA availability can be a major influence on this process.
我们测试了核糖体保真度提高对编程释放因子2(RF2)翻译移码修饰版本的影响。在所测试的构建体中,移码位点处的原始UGA密码子被两个有义密码子之一取代,即UGG(色氨酸),其允许约13%的移码,或CUG(亮氨酸),其仅允许约2%的移码。我们在野生型核糖体宿主中证实了柯伦和亚鲁斯[Curran, J. F. & Yarus, M. (1989) J. Mol. Biol. 209, 65 - 77]的结果,包括从tRNA基因的质粒拷贝诱导tRNA(Trp)后UGG移码的减少。但令我们惊讶的是,在超精确的链霉素假依赖宿主中,UGG移码增加到超过50%。当我们向这些细胞中添加tRNA(Trp)质粒时,tRNA(Trp)基因的诱导将移码减少回约7%。在这些不同的诱导条件下,信使RNA水平变化不大。其他提高准确性的等位基因在移码位点处也显示出UGG移码增加。所有提高准确性的等位基因都导致翻译速率减慢,并且框内报告基因合成减少的程度与框外报告基因UGG移码的程度之间似乎存在比例关系。提高准确性对较低水平的CUG移码影响很小。然而,同源tRNA(1Leu)的过量产生甚至显著降低了这种较低水平的移码,尽管tRNA(1Leu)已经是大肠杆菌中最丰富的同功受体。可以按照柯伦和亚鲁斯的假设对这些结果进行如下合理解释:对于野生型核糖体,tRNA(Trp)的有限可用性(约占总tRNA的1%)促进了在UGG密码子处的停顿(由于A位点空置),增加了核糖体重新排列的机会。过量的tRNA(Trp)减少了A位点空置的时间,从而减少了移码。较慢的超精确核糖体增加了停顿时间,从而增加了移码的机会,这一过程通过增加框内同源tRNA(Trp)再次逆转。这些数据为一个模型提供了有力支持,在该模型中,核糖体在编程移码位点处的停顿时间长短是移码效率的主要决定因素,并且tRNA可用性可能是对这一过程的主要影响因素。
