Chung C H, Goldberg A L
Proc Natl Acad Sci U S A. 1981 Aug;78(8):4931-5. doi: 10.1073/pnas.78.8.4931.
In Escherichia coli, degradation of abnormal proteins is an energy-requiring process; it is decreased in mutants in the lon (capR or deg) gene. We find that the protein encoded by the lon gene is an ATP-dependent protease and is identical to protease La, recently described in E. coli. Both proteins are serine proteases that hydrolyze casein and globin, but not insulin, in the presence of ATP and Mg2+. Both respond to ATP, less well to other nucleoside triphosphates, and not to nonhydrolyzable ATP analogs. The purified lon protein has an apparent Mr of 450,000 and appears to be composed of four identical subunits. Its size, chromatographic behavior, and sensitivity to various inhibitors and heat are indistinguishable from those of protease La. Moreover, in a strain that carries additional copies of the lon+ allele on a plasmid, the content of protease La, but not of other proteases, is 2- to 10-fold greater than in the lon+ parent strain. Strains carrying the nonsense mutations capR9 and capR- also contain this ATP-dependent proteolytic activity, but it is present in substantially lower amounts and is inactivated by phosphocellulose chromatography, unlike the wild-type enzyme. Degradation of abnormal proteins in these lon- strains, which is slower than in the wild type, still requires ATP. Alterations in the ATP-dependent protease in the lon- mutants can account for the defect in intracellular proteolysis and perhaps also for the other phenotypic effects of this pleiotropic gene.
在大肠杆菌中,异常蛋白质的降解是一个需要能量的过程;在lon(capR或deg)基因突变体中,该过程会减弱。我们发现,lon基因编码的蛋白质是一种依赖ATP的蛋白酶,与最近在大肠杆菌中描述的蛋白酶La相同。这两种蛋白质都是丝氨酸蛋白酶,在ATP和Mg2+存在的情况下能水解酪蛋白和球蛋白,但不能水解胰岛素。它们都对ATP有反应,对其他核苷三磷酸的反应稍弱,对不可水解的ATP类似物则无反应。纯化后的lon蛋白表观分子量为450,000,似乎由四个相同的亚基组成。其大小、色谱行为以及对各种抑制剂和热的敏感性与蛋白酶La无法区分。此外,在一个携带质粒上lon+等位基因额外拷贝的菌株中,蛋白酶La的含量比lon+亲本菌株高2至10倍,而其他蛋白酶的含量则没有变化。携带无义突变capR9和capR-的菌株也含有这种依赖ATP的蛋白水解活性,但含量要低得多,并且与野生型酶不同,它会被磷酸纤维素色谱法灭活。这些lon-菌株中异常蛋白质的降解比野生型慢,且仍然需要ATP。lon-突变体中依赖ATP的蛋白酶的改变可以解释细胞内蛋白水解的缺陷,也许还能解释这个多效基因的其他表型效应。