[The directed modification of Escherichia coli MG1655 to obtain histidine-producing mutants].

Strain MG 1655+hisGr hisL'-Delta, purR, which produces histidine with a weight yield of approximately 12% from glucose, was constructed through directed chromosomal modifications of the laboratory Escherichia coli strain MG 1655+, which has a known genome sequence. A feedback-resistant ATP-phosphoribosyl transferase encoded by the mutant hisGr (E271 K) was the main determinant of histidine production. A further increase in histidine production was achieved by the expression enhance of a mutant his operon containing hisGr through the deleting attenuator region (hisL'-Delta). An increase in the expression of the wildtype his operon did not result in histidine accumulation. Deletion of the transcriptional regulator gene purR increased the biomass produced and maintained the level of histidine production per cell under the fermentation conditions used.

[Recombinational origin of natural transposable phages of related species belonging to group B3, active in Pseudomonas aeruginosa species]. / Rekominatsionnoe proiskhozhdenie prirodnykh fagov-transpozonov rodstvennykh vidov gruppy B3, aktivnykh na bakteriiakh vida Pseudomonas aeruginosa.

A heteroduplex analysis of four related transposable phages--B3, PM57, PM62, and Hw12--of the Pseudomonas aeruginosa B3 group was performed. Heteroduplex structures, restriction maps, and data on DNA-DNA hybridization obtained upon hybridization of phage DNA restriction fragments with labeled probes representing different regions of the phage genomes are in good agreement. The data obtained strongly confirmed the recombinational origin of the analyzed phages. Thus, all natural transposable phages of P. aeruginosa, including phages from both group B3 and species D3112, were shown to have a recombinational origin.

[Role of divergence in evolution of group B3 Pseudomonas aeruginosa transposable phage evolution]. / Vyiavlenie roli divergentsii v évoliutsii fagov-transpozonov gruppy B3 Pseudomonas aeruginosa.

A heteroduplex analysis was performed to identify and map divergent DNA sequences in the genomes of the P. aeruginosa transposable phages (TPs) of group B3 using different formamide concentrations (30, 50, and 70%). Six PTs were classified into three related species--B3, PM681, and PM57. The role of DNA divergence in the evolution of TPs within one species is insignificant: the genomes of phages pM105 and PM681 (species PM681) and phages Hw12 and pM57 (species pM57) were shown to contain either homologous (98%) or nonhomologous DNA (2%). Homologous, divergent, and nonhomologous DNA regions (modules) were identified in the genomes of the TP of different species. Homologous modules with a level of DNA homology higher than 86% constitute approximately 30% of the phage genome; they are located at the left (1-5 kb) and right (29-38 kb) ends of the phage genome. Divergent modules with a DNA homology level between 50 and 67% and nonhomologous modules represent 30 to 35% and 25 to 30% of the phage genome, respectively. These regions form a mosaic structure in a 5-29-kb region. Thus, the key role of DNA divergence in the evolution of the natural TPs of three related species of group B3 was shown. A single region containing a 5-11-kb divergent DNA sequence was detected in the pM62 phage genome (species pM57). As shown by our previous data, this region was integrated into phage pM62 via interspecific recombination with a phage of species B3.