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天蓝色链霉菌核糖体S12蛋白中的一种新型插入突变导致巴龙霉素抗性和抗生素过量产生。

A novel insertion mutation in Streptomyces coelicolor ribosomal S12 protein results in paromomycin resistance and antibiotic overproduction.

作者信息

Wang Guojun, Inaoka Takashi, Okamoto Susumu, Ochi Kozo

机构信息

National Food Research Institute, Tsukuba, Ibaraki, Japan.

出版信息

Antimicrob Agents Chemother. 2009 Mar;53(3):1019-26. doi: 10.1128/AAC.00388-08. Epub 2008 Dec 22.

Abstract

We identified a novel paromomycin resistance-associated mutation in rpsL, caused by the insertion of a glycine residue at position 92, in Streptomyces coelicolor ribosomal protein S12. This insertion mutation (GI92) resulted in a 20-fold increase in the paromomycin resistance level. In combination with another S12 mutation, K88E, the GI92 mutation markedly enhanced the production of the blue-colored polyketide antibiotic actinorhodin and the red-colored antibiotic undecylprodigiosin. The gene replacement experiments demonstrated that the K88E-GI92 double mutation in the rpsL gene was responsible for the marked enhancement of antibiotic production observed. Ribosomes with the K88E-GI92 double mutation were characterized by error restrictiveness (i.e., hyperaccuracy). Using a cell-free translation system, we found that mutant ribosomes harboring the K88E-GI92 double mutation but not ribosomes harboring the GI92 mutation alone displayed sixfold greater translation activity relative to that of the wild-type ribosomes at late growth phase. This resulted in the overproduction of actinorhodin, caused by the transcriptional activation of the pathway-specific regulatory gene actII-orf4, possibly due to the increased translation of transcripts encoding activators of actII-orf4. The mutant with the K88E-GI92 double mutation accumulated a high level of ribosome recycling factor at late stationary phase, underlying the high level of protein synthesis activity observed.

摘要

我们在天蓝色链霉菌核糖体蛋白S12的rpsL中鉴定出一种新的与巴龙霉素抗性相关的突变,该突变是由92位插入一个甘氨酸残基引起的。这种插入突变(GI92)导致巴龙霉素抗性水平提高了20倍。与另一个S12突变K88E相结合,GI92突变显著提高了蓝色聚酮类抗生素放线紫红素和红色抗生素十一烷基灵菌红素的产量。基因替换实验表明,rpsL基因中的K88E-GI92双突变是观察到的抗生素产量显著提高的原因。具有K88E-GI92双突变的核糖体具有错误限制性(即超准确性)的特征。使用无细胞翻译系统,我们发现,在生长后期,携带K88E-GI92双突变的突变核糖体而非仅携带GI92突变的核糖体的翻译活性相对于野生型核糖体高六倍。这导致了放线紫红素产量过高,这是由途径特异性调节基因actII-orf4的转录激活引起的,可能是由于编码actII-orf4激活剂的转录本翻译增加所致。具有K88E-GI92双突变的突变体在稳定后期积累了高水平的核糖体循环因子,这是观察到高水平蛋白质合成活性的基础。

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