Studies on the mechanism of repression of arginine biosynthesis in Escherichia coli. IV. Further studies on the role of arginine transfer RNA repression of the enzymes of arginine biosynthesis

Two column Chromatographic procedures have been utilized to purify and fractionate arginyl-transfer RNA: DEAE-Sephadex and reverse-phase column chromatography. Five iso-accepting species of tRNA^Arg were found and they recognize the six arginine codons.     

Regulatory gene mutations affecting arginine biosynthesis in Escherichia coli

Summary Mutants of Escherichia coli with altered regulation of arginine biosynthesis were isolated. The alterations in all of the mutants with increased levels of the biosynthetic enzymes were found to map in the argR locus. The mutants were grouped into three classes based on their effect on the regulatory behavior. Complementation studies with stable merodiploid strains demonstrated that the derepressed synthesis in the mutants was recessive to wild-type regulation.     

The arginine repressor of Escherichia coli.

This review tells the story of the arginine repressor of Escherichia coli from the time of its discovery in the 1950s until the present. It describes how the research progressed through physiological, genetic, and biochemical phases and how the nature of the repressor and its interaction with its target sites were unraveled. The studies of the repression of arginine biosynthesis revealed unique features at every level of the investigations. In the early phase of the work they showed that the genes controlled by the arginine repressor were scattered over the linkage map and were not united, as in other cases, in a single operon. This led to the concept of the regulon as a physiological unit of regulation. It was also shown that different alleles of the arginine repressor could result in either inhibition of enzyme formation, as in E. coli K-12, or in stimulation of enzyme formation, as in E. coli B. Later it was shown that the arginine repressor is a hexamer, whereas other repressors of biosynthetic pathways are dimers. As a consequence the arginine repressor binds to two palindromic sites rather than to one. It was found that the arginine repressor not only acts in the repression of enzyme synthesis but also is required for the resolution of plasmid multimers to monomers, a completely unrelated function. Finally, the arginine repressor does not possess characteristic structural features seen in other prokaryotic repressors, such as a helix-turn-helix motif or an antiparallel beta-sheet motif. The unique features have sustained continuous interest in the arginine repressor and have made it a challenging subject of investigation.     

大肠杆菌分解代谢产物阻遏效应研究进展

细菌在多种碳源共存的环境中优先利用一种(通常是葡萄糖)的现象被称为分解代谢产物阻遏效应。国内现有分子生物学及相关课程教材普遍对该效应的机理解释不清甚至给出错误的解释。大肠杆菌葡萄糖-乳糖分解代谢产物阻遏效应产生的根本原因不是胞内葡萄糖的存在, 而是葡萄糖经PTS(Phosphoenolpyruvate: carbohydrate phosphotransferase system)系统向胞内运输同时藕联磷酸化的过程。磷酸向葡萄糖的传递导致PTS关键组分EⅡA^Glc去磷酸化形式的积累。该形式的EⅡA^Glc可以与质膜上本底表达的乳糖透性酶LacY结合, 阻止诱导物乳糖的吸收。cAMP的影响也是通过激活参与PTS系统的关键基因而加强了诱导物排斥作用。此外, 去磷酸化形式的EⅡBGlc和YeeⅠ对全局性转录阻遏蛋白Mlc活性的抑制也保证了PTS系统关键组分蛋白的基因表达。文章综述了近年来有关大肠杆菌分解代谢产物阻遏效应机理的最新研究进展, 并对相关教材有关这一内容的阐述提出了修改建议。     

Regulation of arginine biosynthesis,catabolism and transport in Escherichia coli

Amino Acids - Already very early, the study of microbial arginine biosynthesis and its regulation contributed significantly to the development of new ideas and concepts. Hence, the term...     

Independent regulation of transport and biosynthesis of arginine in Escherichia coli K-12.

From an arginine auxotrophic strain, a mutant was isolated which is able to utilize d-arginine as a source of l-arginine and shows a high sensitivity to inhibition of growth by canavanine. Transport studies revealed a four- to five-fold increased uptake of arginine and ornithine in cells from the mutant strain. The kinetics of entry of arginine and ornithine evidenced elevated maximal influx values for the arginine- and ornithine-specific transport systems. A close parallel between arginine transport activity and arginine binding activity with one arginine-specific binding periplasmic protein in the mutant strongly suggests that such binding protein is a component of the arginine-specific permease. The affinity between arginine and the binder, isolated from the mutant cells, as well as the electrophoretic mobility of the protein, remain unchanged. The enhanced transport activity of arginine and ornithine with mutant cells is insensitive to repression by arginine or ornithine, whereas the biosynthesis of arginine-forming enzymes is normally repressible. When transport activity was examined in strains with mutations leading to derepression of arginine biosynthesis, the regulation of arginine transport was found to be normal. These studies support the conclusion that arginine transport and arginine biosynthesis, in Escherichia coli K-12, are not regulated in a concerted manner, although both systems may have components in common.     

The mechanism of sugar-mediated catabolite repression of the propionate catabolic genes in Escherichia coli

Carbon catabolite repression (CCR) is a well-known phenomenon that involves the preferential utilization of glucose as a carbon source. Cyclic adenosine monophosphate (cAMP) and the cAMP receptor protein (CRP) mediate CCR. Recently, a second CCR hierarchy that leads to the preferential consumption of arabinose over xylose, mediated by arabinose-bound AraC, has been identified. In this study, we report yet another CCR hierarchy that causes the preferential utilization of sugars (arabinose, galactose, glucose, mannose, and xylose) over a short-chain fatty acid (propionate). Expression of the propionate catabolic (prpBCDE) genes is down-regulated in the presence of these sugars. Sugar-mediated repression of the propionate catabolic genes is independent of sugar-specific regulators such as AraC and dependent on global regulators of sugar transport such as the cAMP-CRP complex and the Phosphotransferase System (PTS). Inhibition of the prpBCDE promoter is encountered during rapid sugar uptake and metabolism. This unique regulatory crosstalk between sugar metabolism and fatty acid metabolism may help provide new insights into CRP-dependent catabolite repression acting in conjunction with non-carbohydrate metabolism.     

Roles of arginine and canavanine in the synthesis and repression of ornithine transcarbamylase by Escherichia coli

Conditions were found under which the processes of repression and derepression of ornithine transcarbamylase were separated from the process of enzyme synthesis. After 10 min of arginine deprivation followed by the addition of 2 to 200 mug of l-arginine per ml, a number of strains of Escherichia coli exhibited a significant burst of ornithine transcarbamylase synthesis which lasted 3 to 4 min before the onset of repression. The rapid increase of enzyme activity was shown to require protein synthesis, and was not due to a slow uptake of arginine or induction of an arginine-inducible ornithine transcarbamylase. The capacity of E. coli to synthesize the burst of ornithine transcarbamylase reached a maximum after 10 min of arginine deprivation and then remained constant. The observed increase in enzyme synthesis may reflect the level of unstable messenger ribonucleic acid (RNA) for ornithine transcarbamylase present in the cell at the time protein synthesis was reinitiated. After the addition of arginine in the absence of protein synthesis, the burst of ornithine transcarbamylase decayed with a half-life of about 3 min. The data implied that arginine prevents synthesis of new messenger RNA that can translate this enzyme. Repression of ornithine transcarbamylase by l-canavanine (100 to 200 mug/ml) was observed, and no active enzyme was formed in the presence of this analogue. The action of canavanine as a repressor was distinguished from the inhibitory effect of this compound on protein synthesis.