The leucine operon carrying theleu-500 promoter mutation is expressed under anaerobic conditions

TheSalmonella typhimurium leu-500 auxotrophic mutant grew when cultivated in minimal medium anaerobically, but not aerobically. This mutant carries an AT CG mutation in the Pribnow box of the promoter region of the leucine operon and was found to be suppressible by anaerobic conditions. Analysis of the anaerobic gases revealed that hydrogen in the anaerobic gas mixture (85% N₂, 10% CO₂, 5% H₂) is essential for the suppression of theleu-500 mutation. Whenleu-500 mutant cells were incubated in the presence of the hydrogen gas, the synthetic rates for the first and last gene products of theleu-500 operon were similar to those of the wild-type cells. It was concluded that the entire leucine operon was efficiently expressed inleu-500 when the cells were grown under the hydrogen gas-containing anaerobic environment. Thus, theleu-500 promoter mutant is a model system for regulation of gene expression by a specific atmospheric environment, i.e., hydrogen gas found in the anaerobic environment.     

DNA supercoiling and suppression of the leu-500 promoter mutation.

top mutations (formerly supX) eliminate DNA topoisomerase I activity and suppress the leu-500 promoter mutation in Salmonella typhimurium (K. M. Overbye, S. K. Basu, and P. Margolin, Cold Spring Harbor Symp. Quant. Biol. 47:785-791, 1983). Sublethal doses of coumermycin which reduce intracellular levels of supercoiling activity in a top mutant eliminated suppression of the leu-500 mutation. This result provides evidence that increased DNA supercoiling suppresses the leu-500 promoter mutation in top mutants.     

Evidence for an Altered Operator Specificity: Catabolite Repression Control of the Leucine Operon in Salmonella typhimurium

A mutation, GD-1, in the leucine operon imposed unusual growth characteristics upon a leucine auxotrophic strain bearing the leucine operator mutation, leu-500. The strain with the GD-1 mutation was able to grow on a minimal salts medium when citrate was the sole carbon source, but required leucine when glucose was present. Tests with a large number of carbohydrates suggest that in the strain bearing the GD-1 mutation the leucine biosynthetic enzymes are under catabolite repressor control. Recombination studies indicate that the GD-1 mutation is a secondary alteration of the leucine operator at or very close to the site of the leu-500 mutation. Mutations at the supX locus (previously termed su leu 500 and located on the chromosome between the cysteine B and tryptophan gene clusters) result in elimination of the catabolite repression effect. The data are interpreted as an indication that the GD-1 and leu-500 mutations alter the leucine operator with respect to its specificity of response to repressors.