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大肠杆菌中适应性甘油激酶 (GLPK) 突变体的功能和代谢效应。

Functional and metabolic effects of adaptive glycerol kinase (GLPK) mutants in Escherichia coli.

机构信息

Department of Chemistry & Biochemistry, University of California San Diego, La Jolla, California 92093, USA.

出版信息

J Biol Chem. 2011 Jul 1;286(26):23150-9. doi: 10.1074/jbc.M110.195305. Epub 2011 May 6.

Abstract

Herein we measure the effect of four adaptive non-synonymous mutations to the glycerol kinase (glpK) gene on catalytic function and regulation, to identify changes that correlate to increased fitness in glycerol media. The mutations significantly reduce affinity for the allosteric inhibitor fructose-1,6-bisphosphate (FBP) and formation of the tetramer, which are structurally related, in a manner that correlates inversely with imparted fitness during growth on glycerol, which strongly suggests that these enzymatic parameters drive growth improvement. Counterintuitively, the glpK mutations also increase glycerol-induced auto-catabolite repression that reduces glpK transcription in a manner that correlates to fitness. This suggests that increased specific GlpK activity is attenuated by negative feedback on glpK expression via catabolite repression, possibly to prevent methylglyoxal toxicity. We additionally report that glpK mutations were fixed in 47 of 50 independent glycerol-adapted lineages. By far the most frequently mutated locus (nucleotide 218) was mutated in 20 lineages, strongly suggesting this position has an elevated mutation rate. This study demonstrates that fitness correlations can be used to interrogate adaptive processes at the protein level and to identify the regulatory constraints underlying selection and improved growth.

摘要

在此,我们测量了甘油激酶(glpK)基因中四个适应性非同义突变对催化功能和调节的影响,以确定与甘油介质中适应性增加相关的变化。这些突变显著降低了与变构抑制剂果糖-1,6-二磷酸(FBP)的亲和力,以及形成四聚体的能力,这与在甘油上生长时赋予的适应性呈反比,这强烈表明这些酶学参数可促进生长改善。与预期相反的是,glpK 突变还增加了甘油诱导的自分解物抑制作用,以与适应性相关的方式降低了 glpK 的转录。这表明,通过分解物抑制对 glpK 表达的负反馈可能会减弱特定 GlpK 活性的增加,以防止甲基乙二醛毒性。我们还报告说,glpK 突变在 50 个独立的甘油适应谱系中的 47 个中被固定。迄今为止,最常突变的基因座(核苷酸 218)在 20 个谱系中发生突变,强烈表明该位置的突变率很高。这项研究表明,适应性与适应能力相关,可以用于在蛋白质水平上研究适应性过程,并确定选择和生长改善的基础的调节限制。

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