[Expression of gene recA of Deinococcus radiodurans in Escherichia coli cells].

Plasmids pKS5 and pKSrec30 carrying normal and mutant alleles of Deinococcus radiodurans recA gene controlled by the lactose promoter slightly increase radioresistance of Escherichia coli cells with mutations at genes recA and ssb. The RecA protein of D. radiodurans is expressed in E. coli cells, and its synthesis can be supplementary induced. The radioprotective effect of the xenologic protein does not exceed 1.5 times and is essentially to the contribution of plasmid pUC 19-recA1.1 harboring the E. coli recA+ gene in the recovery of resistance of the deltarecA deletion mutant. These data suggest that the expression of D. radiodurans recA gene in E. coli cells does not complement mutations at gene recA in the chromosome possibly due to structural and functional peculiarities of the D. radiodurans RecA protein.

[Operator-constitutive mutation in the recA gene enhances radiation resistance of Escherichia coli].

Plasmid pUC19-recAoc carrying a mutant allele of the recA gene, which plays the key role in the control of the SOS repair system and homologous recombinational repair, causes a 1.5-fold increase in radiation resistance of Escherichia coli DeltarecA cells, as compared to the wild-type recA+ cells. The protective effect of this plasmid is drastically reduced in mutant lexA3 recADelta21 deficient in the LexA protein and in induction of the SOS regulon. Plasmid pUC19-recAoc effectively suppresses UV sensitivity of the DeltarecA mutant. Mutation recAo20 allows constitutive high-level synthesis of the RecA protein. This mutation impairs the SOS box in the operator site of the recA gene and enhances heterology of the dimer LexA binding site. These data confirm that high level of the RecA protein synthesis per se is not sufficient for the expression of gamma-inducible functions and that the derepression of lexA-dependent genes, other than recA gene, is necessary for the complete induction of the SOS repair system.

[Constitutive inhibition of DNA degradation due to the enzyme RecBCD in the radiation-resistant Escherichia coli K-12 mutant Gam(r)444]. / Konstitutivnoe ingibirovanie degradatsii DNK, vyzvannoi fermentom RecBCD, u radioustoichivogo mutanta Gam(r)444 Escherichia coli K-12.

Exonucleolytic degradation of [3]H-labeled DNA was examined in partially purified fractions of lysates obtained from nonirradiated RecBCD enzyme-containing cells of Escherichia coli and in the radiation-resistant mutant Gamr444. The degradative activity was shown to be lowered in these cells to the same extent as in the recBC mutant. The efficiency of plating of the mutant phage T4 2-, DNA of which can be degraded by exonuclease V, was 400-fold higher on the strain Gamr444 than on the wild-type strain AB1157. This value was shown to be only twice as low as that on the recB mutant or on the strain AB1157 carrying plasmid pGam26 with a radiation-resistance allele gam26 cloned from mutant Gamr444. The data obtained confirmed the hypothesis that the Gamr444 mutant contains a constitutive inhibitor of exonucleolytic activity of the RecBCD enzyme in nonirradiated cells. This inhibitor was shown to be encoded by the gam26 allele that had previously been mapped at 56.8 min of the E. coli chromosome. A possible mechanism of the involvement of this inhibitor in enhanced radiation resistance of the mutant Gamr444 is considered.

[A mutant allele gam18, participating in the RecF repair path in Escherichia coli K-12]. / Mutantnyi allel' gam18, uchastvuiushchii v RecF-puti reparatsii u Escherichia coli K-12.

Plasmid pGam18 carrying one of the cloned mutant loci, responsible for enhanced radiation resistance in the strain Escherichia coli Gamr444, was shown to increase resistance to the lethal effect of gamma-rays with a dose modification factor DMF = 2. Enhanced resistance was observed in wild-type cells and in the mutant recBC sbcB, but not recFBC sbcA. This indicates the involvement of a product of the gam18 locus in the RecF pathway of recombinational repair. The protective effect of plasmid pGam18 against radiation was completely abolished by mutations in the most RecF pathway genes (recF, recJ, recR, recO, recQ, recN, and ruvB). However, three mutations in the uvrD gene, which encodes DNA helicase II and belongs to the RecF pathway, can be partially complemented by plasmid pGam18. These data suggest that the mutant allele gam18 affects the DNA helicase II activity at the presynaptic stage of the RecF pathway-mediated repair of DNA double-stranded breaks induced by gamma-irradiation.