Characterization of a gene, glnL, the product of which is involved in the regulation of nitrogen utilization in Escherichia coli
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DNA was prepared from a strain of Escherichia coli bearing a mutation which confers the GlnC phenotype (inability to reduce the expression of glnA and other nitrogen-regulated operons in response to ammonia in the growth medium). A fragment of this DNA carrying glnA, the structural gene for glutamine synthetase, was cloned on plasmid pBR322. By using recombination in vitro, we mapped the GlnC mutation to a region between glnA and glnG. This region defines a gene, glnL, which codes for a trans-acting product; the GlnC mutant produces an altered product. The glnL product plays a key role in the communication of information concerning the quality and abundance of the nitrogen source in the growth medium to a destination responsible for the regulation of glnA and other genes for enzymes responsible for nitrogen utilization.Keywords:
Structural gene
Glutamine synthetase could be repressed several hundredfold rather than 6- to 10-fold as previously reported. Ammonia was not the primary repression signal for glutamine synthetase. Repression appeared to be mediated by a high level of glutamine and probably by a high ratio of glutamine to alpha-ketoglutarate. Mutations in glnA (the structural gene for glutamine synthetase) were seen to fall into three phenotypic groups: glutamine auxotrophs that produced no detectable glnA product; glutamine auxotrophs that produced a glnA product lacking enzymatic activity (and hence repressibility by ammonia) but were repressible under appropriate conditions; and glutamine synthetase regulatory mutants, whose glnA product was enzymatically active and not repressible under any conditions.
Structural gene
Enzyme Repression
Enterobacter aerogenes
Auxotrophy
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The sfrB gene of Escherichia coli K-12 and the rfaH gene of Salmonella typhimurium LT2 are homologous, controlling expression of the tra operon of F and the rfa genes for lipopolysaccharide synthesis. We have determined a restriction map of the 19-kilobase ColE1 plasmid pLC14-28 which carries the sfrB gene of E. coli. After partial Sau3A digestion of pLC14-28, we cloned a 2.5-kilobase DNA fragment into the BamHI site of pBR322 to form pKZ17. pKZ17 complemented mutants of the sfrB gene of E. coli and the rfaH gene of S. typhimurium for defects of both the F tra operon and the rfa genes. pKZ17 in minicells determines an 18-kilodalton protein not determined by pBR322. A Tn5 insertion into the sfrB gene causes loss of complementing activity and loss of the 18-kilodalton protein in minicells, indicating that this protein is the sfrB gene product. These data indicate that the sfrB gene product is a regulatory element, since the single gene product elicits the expression of genes for many products for F expression and lipopolysaccharide synthesis.
ColE1
Structural gene
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Anthocyanins are important natural water-soluble, health-promoting pigments that have much effect on the quality of fruits. The anthocyanin biosynthetic pathway in fruits is clear. Anthocyanin accumulation depends on coordinated expression of structural genes encoding anthocyanin biosynthesis. Structural gene expression is regulated by regulatory genes, including MYB, basic helix-loop-helix(b HLH), and WD40 classes. The structural genes and the key regulatory genes controlling the pathway have been isolated in many fruits. Here we reviewed the recent advances in molecular mechanisms of regulatory genes in anthocyanin biosynthesis, including classes, concentration and functions of anthocyanins, transcriptional regulation of the anthocyanin biosynthesis, micro RNAs regulation, as well as the internal and external infl uences on anthocyanin biosynthesis in fruits. Especially, we pointed many gaps remain in the regulatory network of MYB, b HLH and WD40 transcription factors. Furthermore, new discoveries have begun to reveal links between the internal infl uences(plant hormones, genetics, maturity, biological clock, etc.), external environmental infl uences(light, temperature, p H, nutrition, etc.) and the regulatory genes in anthocyanin biosynthesis during fruit ripening. These reserches favor the anthocyanin biosynthesis of fruits at the molecular level from the point of view of interaction between the regulatory networks.
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MYB
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The anthocyanin biosynthesis pathway is a little complex with branches responsible for the synthesis of a variety of metabolites. In fruit tree crops, during the past decade, many structural genes encoding enzymes in the anthocyanin biosynthetic pathway and various regulatory genes encoding transcription factors that regulate the expression of structural genes have been cloned and then functionally characterized in detail. In general, the structural genes involved in anthocyanin synthesis were coordinately expressed and their levels of expression were positively related to the degree of anthocyanin concentration; while, the coordinated expression pattern is striking a diverse among fruit crop species. Regulatory genes regulate spatiotemporally the structural genes and then form complicated metabolic network. Anthocyanin biosynthesis can be affected by external and internal factors, such as light, UV-B, low temperature and ABA through changes in expression of structural and regulatory genes. Key words: Anthocyanin, regulatory genes, structural genes, fruit tree crops, factors.
Structural gene
Metabolic pathway
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Mutations at two sites of the Klebsiella aerogenes chromosome, unlinked by transduction with phages PW52 and P1, result in the lack of enzymatically active glutamine synthetase. A mutation in the glnB site leads to a marked decrease in the formation of an apparently normal enzyme. Some of the mutations in the glnA site lead to the production of enzymatically inactive material capable of reacting with anti-glutamine synthetase serum. The revertant of a glnA mutant was found to produce a glutamine synthetase with less activity and less stability to heat than the enzyme of the wild type. These results locate the structural gene to the production of enzymatically inactive glutamine synthetase antigen, not subject to repression by exogenously added ammonia. This observation suggests that glutamine synthetase is itself involved in the regulation of the synthesis of glutamine synthetase.
Enterobacter aerogenes
Structural gene
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One of the suspected regulators of glutamine synthetase [L-glutamate:ammonia ligase (ADP-forming), EC 6.3.1.2] in enteric bacteria is glutamine synthetase itself. We isolated Escherichia coli strains carrying fusions of the beta-galactosidase structural gene to the promoter of the glutamine synthetase gene, with the aid of the Casadaban Mud1 (ApR, lac, cts62) phage. Some aspects of regulation were retained in haploid fusion strains despite the absence of glutamine synthetase, whereas other aspects required glutamine synthetase catalytic or regulatory activity or both. The direction of transcription of the glutamine synthetase gene was also determined.
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Structural gene
Restriction map
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Mutations at two sites, glnA and glnB, of the Klebsiella aerogenes chromosome result in the loss of glutamine synthetase. The locations of these sites on the chromosome were established by complementation by episomes of Escherichia coli and by determination of their linkage to other genetic sites by transduction with phage P1. The glnB gene is located at a position corresponding to 48 min on the Taylor map of the E. coli chromosome; it is linked to tryA, nadB, and GUA. The glnA gene is at a position corresponding to 77 min on the Taylor map and is linked to rha and metB; it is also closely linked to rbs, located in E. coli at 74 min, indicating a difference in this chromosomal region between E. coli and K. aerogenes. Mutations in the glnA site can also lead to nonrepressible synthesis of active glutamine synthetase. The examination of the fine genetic structure of glnA revealed that one such mutation is located between two mutations leading to the loss of enzymatic activity. This result, together with evidence that the structural gene for glutamine synthetase is at glnA, suggests that glutamine synthetase controls expression of its own structural gene by repression.
Structural gene
Enterobacter aerogenes
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We isolated an F' episome of Escherichia coli carrying the glnA+ gene from K. aerogenes and an F' episome of E. coli carrying the glnA4 allele from K. aerogenes responsible for the constitutive synthesis of glutamine synthetase. Complementation tests with these episomes showed that the glnA4 mutation (leading to the constitutive synthesis of active glutamine synthetase) was in the gene identified by mutations glnA20, glnA51, and glnA5 as the structural gene for glutamine synthetase. By using these merodiploid strains we were able to show that the glnA51 mutation lead to the synthesis of a glutamine synthetase that lacked enzymatic activity but fully retained its regulatory properties. Finally, we discuss a model that explains the several phenotypes associated with mutations such as glnA4 located within the structural gene for glutamine synthetase leading to constitutive synthesis of active glutamine synthetase.
Enterobacter aerogenes
Structural gene
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We studied the physiology of cells of Klebsiella aerogenes containing the structural gene for glutamine synthetase (glnA) of Escherichia coli on an episome. The E. coli glutamine synthetase functioned in cells of K. aerogenes in a manner similar to that of the K. aerogenes enzyme: it allowed the level of histidase to increase and that of glutamate dehydrogenase to decrease during nitrogen-limited growth. The phenotype of mutations in the glnA site was restored to normal by the introduction of the episomal glnA+ gene. These results are consistent with the hypothesis that glutamine synthetase regulates the function of its own structural gene.
Enterobacter aerogenes
Structural gene
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Citations (30)