Johnson D R, Duronio R J, Langner C A, Rudnick D A, Gordon J I
Department of Molecular Biology and Pharmacology, Washington University School of Medicine, St. Louis, Missouri 63110.
J Biol Chem. 1993 Jan 5;268(1):483-94.
Saccharomyces cerevisiae myristoyl-CoA:protein N-myristoyltransferase (Nmt1p) is an essential enzyme that transfers myristate from CoA to the amino-terminal glycine residue of at least 12 cellular proteins. Its reaction mechanism is Ordered Bi Bi with myristoyl-CoA binding occurring before binding of nascent polypeptides and release of CoA preceding release of the myristoylprotein product. nmt1-72 is a temperature-sensitive allele, identified by Stone et al. (Stone, D. E., Cole, G. M., Lopes, M. B., Goebl, M., and Reed, S. I. (1991) Genes & Dev. 5, 1969-1981) that causes arrest in the G1 phase of the cell cycle due to reduced acylation of Gpa1p. We have recovered this mutant allele and determined that it contains a single point mutation resulting in a Leu99 (CTA) to Pro (CCA) substitution. Addition of > or = 500 microM myristate but not palmitate to synthetic or rich media rescues the growth arrest caused by nmt1-72 at 37-39 degrees C, consistent with the observation that purified nmt72p has reduced affinity for myristoyl-CoA and that exogenous myristate but not palmitate increases cellular myristoyl-CoA pools. Metabolic labeling studies in S. cerevisiae and co-expression of nmt72p with several protein substrates of Nmt1p in Escherichia coli indicate that the Leu99-->Pro substitution causes a reduction in the acylation of some but not all protein substrates. Since formation of a myristoyl-CoA.Nmt1p complex appears to be required for synthesis/formation of a peptide binding site, these defects in acylation appear to arise either because Leu99 is a component of the enzyme's functionally distinguishable myristoyl-CoA and peptide recognition sites or because Pro99 alters the interaction between myristoyl-CoA and enzyme in a way that precludes formation of a normal peptide binding site. The reduction in affinity for myristoyl-CoA produced by Leu99-->Pro in nmt72p is less than that produced by the Gly451-->Asp mutation in nmt181p, which also produces temperature-sensitive myristic acid auxotrophy. Isogenic, haploid strains containing NMT1, nmt1-72, and nmt1-181 do not manifest any obvious differences in steady state levels of the acyltransferases during growth at permissive temperatures or in the biosynthesis of long chain saturated acyl-CoAs. The spectrum of cellular N-myristoylproteins whose level of acylation is affected by nmt1-72 and nmt1-181 is distinct.(ABSTRACT TRUNCATED AT 400 WORDS)
酿酒酵母肉豆蔻酰辅酶A:蛋白质N-肉豆蔻酰转移酶(Nmt1p)是一种必需酶,它将肉豆蔻酸从辅酶A转移至至少12种细胞蛋白的氨基末端甘氨酸残基上。其反应机制为有序双底物机制,肉豆蔻酰辅酶A先结合,然后新生多肽结合,辅酶A在肉豆蔻酰化蛋白产物释放之前释放。nmt1-72是一个温度敏感等位基因,由斯通等人鉴定(斯通,D.E.,科尔,G.M.,洛佩斯,M.B.,戈布尔,M.,和里德,S.I.(1991年)《基因与发育》5,1969 - 1981),由于Gpa1p酰化减少,该等位基因导致细胞周期在G1期停滞。我们已找回这个突变等位基因,并确定它包含一个单点突变,导致亮氨酸99(CTA)被脯氨酸(CCA)取代。在合成培养基或丰富培养基中添加≥500微摩尔肉豆蔻酸而非棕榈酸,可挽救nmt1-72在37 - 39摄氏度时引起的生长停滞,这与以下观察结果一致:纯化的nmt72p对肉豆蔻酰辅酶A的亲和力降低,且外源性肉豆蔻酸而非棕榈酸可增加细胞内肉豆蔻酰辅酶A池。酿酒酵母中的代谢标记研究以及nmt72p与Nmt1p的几种蛋白质底物在大肠杆菌中的共表达表明,亮氨酸99→脯氨酸取代导致部分而非全部蛋白质底物的酰化减少。由于肉豆蔻酰辅酶A·Nmt1p复合物的形成似乎是肽结合位点合成/形成所必需的,这些酰化缺陷似乎是因为亮氨酸99是该酶功能上可区分的肉豆蔻酰辅酶A和肽识别位点的一个组成部分,或者是因为脯氨酸99以一种排除正常肽结合位点形成的方式改变了肉豆蔻酰辅酶A与酶之间的相互作用。nmt72p中亮氨酸99→脯氨酸导致的对肉豆蔻酰辅酶A亲和力的降低小于nmt181p中甘氨酸451→天冬氨酸突变导致的降低,后者也产生温度敏感型肉豆蔻酸营养缺陷型。含有NMT1、nmt1-72和nmt1-181的同基因单倍体菌株在允许温度下生长期间或长链饱和酰基辅酶A的生物合成过程中,酰基转移酶的稳态水平没有表现出任何明显差异。其酰化水平受nmt1-72和nmt1-181影响的细胞N-肉豆蔻酰化蛋白谱是不同的。(摘要截断于400字)
