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The products of glnL and glnG are bifunctional regulatory proteins

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Summary

The role of the two glnA linked genes, glnL and glnG, in regulation of glnA expression and nitrogen metabolism in Escherichia coli has been studied by analysis of 131 glnL and 164 glnG genetically characterized mutations. A comparison of phenotypes with genetic position was performed for all mutations in glnL and glnG. We determined the ability of mutants to derepress GS, to grow on a variety of nitrogen sources in the absence of glutamine, and to suppress the glutamine requirement caused by a glnF mutation. The results indicate that both glnL and glnG products mediate negative regulation of glnA. The glnG product, but not that of glnL, is required for derepression of glnA. Both glnL and glnG products are required for positive regulation of gene products involved in the utilization of poor nitrogen sources. In each gene, point mutations were found which confer a phenotype dramatically different than that caused by insertion mutations. These point mutations fall into several frequently occurring classes. The phenotypes of these classes suggests that each gene product has bifunctional regulatory properties. Further, each class tends to be located in only a portion of a gene suggesting that the region encoding each function is genetically distinct.

The role of glutamine synthetase in the regulation of glnA expression was investigated using two-dimensional polyacrylamide gel electrophoresis on extracts of 38 GlnA- mutants. Results of this analysis argue that glutamine synthetase is not structurally involved in the regulation of glnA expression.

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Authors and Affiliations

  1. Fermentation Microbiology, Merck Sharp & Dohme Research Laboratories, 07065, Rahway, New Jersey, USA

    Tanya MacNeil, Gary P. Roberts, Douglas MacNeil & Bonnie Tyler

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  1. Tanya MacNeil
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  2. Gary P. Roberts
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  3. Douglas MacNeil
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  4. Bonnie Tyler
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Communicated by J. Schell

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MacNeil, T., Roberts, G.P., MacNeil, D. et al. The products of glnL and glnG are bifunctional regulatory proteins. Mol Gen Genet 188, 325–333 (1982). https://doi.org/10.1007/BF00332696

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  • DOI: https://doi.org/10.1007/BF00332696

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