Mutational Analysis of the Bacillus subtilis purA Operator Site

The Bacillus subtilis purine repressor, PurR, regulates many genes involved in purine metabolism. These genes contain a conserved 14-nucleotide inverted repeat (PurBox). Both pur operon and purA, which are regulated by PurR, have this inverted repeat with a 16- or 17-nucleotide spacer, respectively. Mutational studies have earlier shown that PurR binding is dependent on the PurBox of pur operon. In contrast, these studies failed to establish the importance of purA PurBox to PurR binding. To examine this inconsistency, we studied the effects of PurBox mutations both in vivo and in vitro. The data presented here indicate that purA PurBox has a similar role as pur operon PurBox in PurR binding. In addition, our data suggest that the previously proposed classification of the two halves of the Purbox into weak and strong may need to be revised.     

Mutations in the Bacillus subtilis Purine Repressor That Perturb PRPP Effector Function In Vitro and In Vivo

The Bacillus subtilis pur operon repressor (PurR) has a PRPP (5-phosphoribosyl 1-pyrophosphate) binding motif at residues 199–211. Two PurR PRPP binding region mutations (D203A and D204A) were constructed, and the effects on binding of repressor to the pur operon control site in vitro and on regulation of pur operon expression in vivo were investigated. PRPP significantly inhibited the binding of wild-type but not mutant PurR to pur operon control site DNA. In strains with the D203A and D204A mutations, pur operon expression in vivo was super-repressed by addition of adenine to the growth medium. These results support the role of PRPP in modulating the regulatory function of PurR in vivo. YabJ, the product of the distal gene in the bicistronic purR operon, is also required for PurR function in vivo. Received: 5 January 2000 / Accepted: 9 February 2000     

色氨酸操纵子调控机理详析

色氨酸操纵子是最早被研究的细菌合成代谢调控、基因表达调控的模型之一。其中阻遏蛋白对转录起始的抑制作用、色氨酸作为辅阻遏物的作用以及通过定点突变揭示的弱化作用的分子机制已基本被阐明。此外,色氨酸操纵子RNA结合弱化蛋白、NusA、NusG、TrpY等调节蛋白对细菌色氨酸操纵子弱化作用的调节机制也在近年来得到进一步揭示。特别是在枯草芽孢杆菌中,色氨酸操纵子主要依赖于转录衰减机制调控,包括由色氨酸激活的色氨酸操纵子RNA结合弱化蛋白与新生转录产物结合形成内部终止子,导致5′非翻译区（5′UTR）转录终止。NusA、NusG通过刺激RNA聚合酶在5′UTR的U107和U144位点暂停,释放出RNA聚合酶,最终造成转录终止。不同的是,在U144位点NusA参与的转录弱化机制依赖其发夹结构,且NusA与RNA聚合酶作用促进了RNA结合弱化蛋白与新生转录产物的结合,使转录终止。而NusG是通过与非模板DNA链中的一段富含T碱基序列和RNA聚合酶同时互作,阻止了RNA聚合酶向下游移动,从而引起RNA聚合酶高效停滞。但在细菌操纵子中,绝大多数调节因子参与的弱化机制最终依赖于ρ因子,从而导致多达一半的转录终止事件发生。近年来,随着学科的发展,越来越多关于色氨酸操纵子调节机制新概念被挖掘报道,这也使人类对色氨酸操纵子的表达调控机制的认知愈加详尽。