生长缓慢的酵母细胞中存在高比例无活性核糖体的证据。

Evidence for a high proportion of inactive ribosomes in slow-growing yeast cells.

作者信息

Waldron C, Jund R, Lacroute F

出版信息

Biochem J. 1977 Dec 15;168(3):409-15. doi: 10.1042/bj1680409.

DOI:10.1042/bj1680409

PMID:343781

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1183787/

Abstract

From the protein and RNA content of Saccharomyces cerevisiae growing in different media we calculate that ribosome efficiency is changed: incorporation of amino acids into protein decreases from 8.8 amino acids/s per ribosome in fast-growing cells (0.54 doubling/h) to 5.2 amino acids/s per ribosome in slow-growing cells (0.30 doubling/h). We could not detect significant protein turnover in either fast-or slow-growing cultures, so the lower ribosome efficiency does not seem to be an artifact caused by changes in unstable protein production at different growth rates. Nor is the lower ribosome efficiency due to slower migration of ribosomes along mRNA: the times required to complete polypeptides of known molecular weights are the same in slow-growing cells as those previously determined for fast-growing cells [Waldron, Jund & Lacroute (1974) FEBS Lett. 46, 11-16]. We therefore deduce that ribosome efficiency changes in yeast because the fraction of ribosomes engaged in protein synthesis falls (from 84% in fast-growing cells to 50% in slow-growing cells.

摘要

根据在不同培养基中生长的酿酒酵母的蛋白质和RNA含量，我们计算出核糖体效率发生了变化：氨基酸掺入蛋白质的速率从快速生长细胞（每小时0.54代）中每个核糖体每秒8.8个氨基酸降至缓慢生长细胞（每小时0.3代）中每个核糖体每秒5.2个氨基酸。在快速生长或缓慢生长的培养物中，我们均未检测到显著的蛋白质周转，因此较低的核糖体效率似乎不是由不同生长速率下不稳定蛋白质产量的变化所导致的假象。较低的核糖体效率也不是由于核糖体沿mRNA迁移速度较慢所致：在缓慢生长的细胞中完成已知分子量多肽所需的时间与先前在快速生长细胞中测定的时间相同[Waldron, Jund & Lacroute (1974) FEBS Lett. 46, 11 - 16]。因此，我们推断酵母中核糖体效率的变化是因为参与蛋白质合成的核糖体比例下降了（从快速生长细胞中的84%降至缓慢生长细胞中的50%）。

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