Pannucci J A, Haas E S, Hall T A, Harris J K, Brown J W
Department of Microbiology, North Carolina State University, Raleigh, NC 27695, USA.
Proc Natl Acad Sci U S A. 1999 Jul 6;96(14):7803-8. doi: 10.1073/pnas.96.14.7803.
The RNA subunits of RNase Ps of Archaea and eukaryotes have been thought to depend fundamentally on protein for activity, unlike those of Bacteria that are capable of efficient catalysis in the absence of protein. Although the eukaryotic RNase P RNAs are quite different than those of Bacteria in both sequence and structure, the archaeal RNAs generally contain the sequences and structures of the bacterial, phylogenetically conserved catalytic core. A spectrum of archaeal RNase P RNAs were therefore tested for activity in a wide range of conditions. Many remain inactive in ionically extreme conditions, but catalytic activity could be detected from those of the methanobacteria, thermococci, and halobacteria. Chimeric holoenzymes, reconstituted from the Methanobacterium RNase P RNA and the Bacillus subtilis RNase P protein subunits, were functional at low ionic strength. The properties of the archaeal RNase P RNAs (high ionic-strength requirement, low affinity for substrate, and catalytic reconstitution by bacterial RNase P protein) are similar to synthetic RNase P RNAs that contain all of the catalytic core of the bacterial RNA but lack phylogenetically variable, stabilizing elements.
与细菌的核糖核酸酶P(RNase P)不同,古生菌和真核生物的RNase P的RNA亚基一直被认为其活性基本上依赖于蛋白质,而细菌的RNase P在没有蛋白质的情况下能够进行高效催化。尽管真核生物的RNase P RNA在序列和结构上与细菌的有很大不同,但古生菌的RNA通常包含细菌的、系统发育上保守的催化核心的序列和结构。因此,在广泛的条件下对一系列古生菌的RNase P RNA进行了活性测试。许多在极端离子条件下仍无活性,但在甲烷杆菌、嗜热球菌和嗜盐菌的RNase P RNA中可检测到催化活性。由甲烷杆菌RNase P RNA和枯草芽孢杆菌RNase P蛋白质亚基重组而成的嵌合全酶在低离子强度下具有功能。古生菌RNase P RNA的特性(高离子强度需求、对底物的低亲和力以及由细菌RNase P蛋白质进行催化重组)与合成的RNase P RNA相似,合成的RNase P RNA包含细菌RNA的所有催化核心,但缺乏系统发育上可变的稳定元件。