常州市运河水和饮用水的致突变研究及其评价

1984年1月、3月和9月,取京抗大运河常州-武进段四个断面的水样,作Ames试验.结果是:上游的河水厂断面为阴性,其余三个断面都是阳性,其中石化厂断面尤为严重;检测丁堰断面运河水不同组分的致突变性,表明致突变物主要在碱性组分.结果还表明,所检水样的致突变作用一般不受S9活化系统存在与否的影响,致突变物主要是移码型的.另外,常州市第二水厂源水和出厂自来水的Ames试验结果表明,在源水加氯处理过程中会产生致突变物,从而增加饮用水的潜在危害.     

The E-site story: the importance of maintaining two tRNAs on the ribosome during protein synthesis

In the sixties James Watson suggested a twosite model for the ribosome comprising the P site for the peptidyl transfer RNA (tRNA) before peptide-bond formation and the A site, where decoding takes place according to the codon exposed there. In the eighties a third tRNA binding site was detected, the E site, which was specific for deacylated tRNA and turned out to be a universal feature of ribosomes. However, despite having three tRNA binding sites, only two tRNAs occupy the ribosome at a time during protein synthesis: at the A and P sites before translocation (PRE state) and at the P and E sites after translocation (POST state). The importance of having two tRNAs in the POST state has been revealed during the last 25 years, showing that the E site contributes two fundamental features: (i) the fact that incorporation of a wrong amino acid is not harmful for the cell (only 1 in about 400 misincorporations destroys the function of a protein) stems from the presence of an E-tRNA; (ii) maintenance of the reading frame is one of the most remarkable achievements of the ribosome, essential for faithful translation of the genetic information. The presence of the POST state E-tRNA prevents loss of the reading frame. Received 14 March 2006; received after revision 8 June 2006; accepted 4 August 2006     

Yeast as a sensor of factors affecting the accuracy of protein synthesis

The cell monitors and maintains the fidelity of translation during the three stages of protein synthesis: initiation, elongation and termination. Errors can arise by multiple mechanisms, such as altered start site selection, reading frame shifts, misincorporation or nonsense codon suppression. All of these events produce incorrect protein products. Translational accuracy is affected by both cis- and trans-acting elements that insure the proper peptide is synthesized by the protein synthetic machinery. Many cellular components are involved in the accuracy of translation, including RNAs (transfer RNAs, messenger RNAs and ribosomal RNAs) and proteins (ribosomal proteins and translation factors). The yeast Saccharomyces cerevisiae has proven an ideal system to study translational fidelity by integrating genetic approaches with biochemical analysis. This review focuses on the ways studies in yeast have contributed to our understanding of the roles translation factors and the ribosome play in assuring the accuracy of protein synthesis.Received 27 November 2002; received after revision 16 April 2003; accepted 25 April 2003