核糖体超精确导致生长欠佳。

Suboptimal growth with hyper-accurate ribosomes.

作者信息

Andersson D I, van Verseveld H W, Stouthamer A H, Kurland C G

出版信息

Arch Microbiol. 1986 Feb;144(1):96-101. doi: 10.1007/BF00454963.

Abstract

Mutant bacteria with hyperaccurate ribosomes support their excessive accuracy of translation in vitro by dissipating 1.5 to 2.5 cognate ternary complexes per peptide bond formed. This is to be compared with a dissipation rate close to 1.1 for wild-type ribosomes. Here, we have tested the hypothesis that a corresponding loss of translational efficiency in vivo would lower the growth rate of the mutants. Such a growth inhibitory effect would explain why the lower accuracy of wild-type ribosomes is more fit. Our data show that as expected the mu of the hyperaccurate mutants is smaller than that of wild-type bacteria. In contrast, during glucose-limited growth in chemostats there is not the same simple correlation between growth yield and ribosomal efficiency for the hyperaccurate mutants.

摘要

具有超精确核糖体的突变细菌通过在体外每形成一个肽键消耗1.5至2.5个同源三元复合物来维持其过高的翻译准确性。相比之下，野生型核糖体的消耗率接近1.1。在此，我们检验了这样一个假设，即在体内相应的翻译效率损失会降低突变体的生长速率。这种生长抑制作用可以解释为什么野生型核糖体较低的准确性更具适应性。我们的数据表明，正如预期的那样，超精确突变体的倍增时间比野生型细菌的要短。相反，在恒化器中葡萄糖受限的生长过程中，超精确突变体的生长产量与核糖体效率之间不存在相同的简单相关性。

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Suboptimal growth with hyper-accurate ribosomes.核糖体超精确导致生长欠佳。

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核糖体超精确导致生长欠佳。

Suboptimal growth with hyper-accurate ribosomes.

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