Effect of a null mutation in the priA gene on radioresistance of Escherichia coli

According to Kogoma's model of DNA recombination by replication, the PriA protein is involved in the RecBCD pathway of double-strand break (DSB) repair, which is associated with extensive DNA degradation, at the stage of primosome assembly in D-loops (intermediates of strand exchange at the ends of DSB) for the subsequent switch to DSB-induced DNA resynthesis. Comparable data on possible involvement of the PriA protein in the repair of gamma-ray-induced lethal lesions in cells of the wild-type strain of Escherichia coli (strain AB1157) and in two radiation-resistant mutants Gamr445 and Gamr444 were obtained. In all the three strains examined, the null priA2::kan mutation in the structural priA gene was shown to markedly enhance the radiation sensitivity, causing a two- to threefold increase in the slopes of linear dose-survival curves. In the AB1157 strain, the inactivation of PriA is manifested most clearly in the range of low doses (up to 0.15 kGy) when the priA2::kan mutation had only a slight effect on the radiation resistance of Gamr mutants. It can be assumed that, in these mutants with a decreased level of postradiation DNA degradation, the PriA-dependent RecBCD pathway of DSB repair associated with extensive DNA resynthesis is not essential for the repair of lethal lesions at low doses. However, this pathway becomes crucial at higher doses (> 0.5 kGy) even for radiation-resistant strains, especially for the most resistant Gamr444 mutant.     

A mutant allele gam18, participating in the RecF repair path in 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.     

The adaptive response to mitomycin C exposure in the hyper-radioresistant mutant Escherichia coli Gamr444

Adaptive response to mitomycin C (MC) (lethal effect and recovery of molecular mass of DNA) in hyper-radioresistant mutant Escherichia coli Gamr444 have been investigated. This mutant is more resistant to MC than parent strain E. coli K12 AB1157. Adaptation of Gamr444 mutant to MC in nonlethal concentrations increases its resistance to MC in lethal concentrations with dose modification factor (DMF) 2.4 at the LD90 level. During the adaptation of this mutant to methyl-methane sulfonate (MMS) its resistance to this agent increases with DMF by 2.2 and resistance to MC with DMF by 1.5 times. During the adaptation of Gamr444 mutant to MC its resistance to MMS increases with DMF by 1.5 times. Adaptive response to MC abolishes by chloroamphenicol treatment during the adaptation. Adaptive response to nitrogen mustard (HN2) in E. coli Gamr444 is absent (HN2 induces cross-links in DNA as MC). Degradation of DNA following the formation of cross-links in DNA takes place. Adaptation to MC in Gamr444 mutant leads to restoration of DNA molecular mass which is more quicker than in the case without adaptation. Adaptive restoration of DNA molecular mass after the MC treatment is absent in E. coli K12 AB1157. The repair of cross-links in DNA after the treatment of HN2 in Gamr444 mutant takes place with equal rate both in the case of adaptation to HN2 and in the case without adaptation. It is proposed, that under the treatment of MC in E. coli Gamr444 the ada-alkA-dependent adaptive response takes place. This adaptive response is connected with alkylation of O6-guanine and elimination of the product by O6-alkyl-DNA-alkyltransferase. Partial recA-dependency of the adaptive response to MC allows to suggest the participation of another inducible system. The nature of this system is unknown.     

Escherichia coli K-12 mutants with enhanced resistance to ionizing radiation. III. The effect of rec and lexA mutations on radioresistance

Lethal action of gamma-rays on derivatives of the wild-type strain AB1157 and of two radiation-resistant mutants (Gamr444 and Gamr445) containing additional mutations dnaA46, recB21, recF143, recA56, recA430, lexA3, lexA102 or lexA3 recAo98, was studied. When the mean number of genomes per cell was reduced by means of pre-incubation at 43 degrees C, radioresistance of the strains AB1157 dnaA46 and Gamr445 dnaA46 was not changed, and that of the strain Gamr444 dnaA46 was reduced to the level of the Gamr445 dnaA46 strain. Introduction of additional mutations recB21, recA56 or lexA3 (lexA102) into the genome of the strains Gamr444 or Gamr445 made them as radiosensitive as the corresponding variants of AB1157. Additional mutations recF143 or recA430 (lexB30) significantly decreased the radioresistance of Gamr444 and Gamr445 mutants, although did not level them to corresponding derivatives of AB1157. Operator-constitutive mutation recAo98 enhanced radioresistance of all lexA3 derivatives tested but not to the level of the corresponding lexA+ strains. The role of recombinational repair and the inducible SOS system in enhanced radioresistance of Gamr mutants is discussed. The data of post-irradiation DNA degradation in various derivatives of the strains AB1157 and Gamr suggest that Gamr mutants have a constitutive inhibitor of degradation which does coincide with RecA protein.     

Mutants of Escherichia coli K-12 with increased resistance to ionizing radiation. VI. Increased radioresistance and heat shock proteins

By means of one-dimensional electrophoresis, it is shown that in radiation-resistant Gamr444 and Gamr445 mutants of Escherichia coli K-12 high-molecular weight heat shock proteins are hyperproduced at 32-37 degrees C and are induced more intensively during heat shock (in comparison to the parental wild-type strain AB1157). When the missense htpR15 mutation of the positive regulatory htpR gene for heat shock proteins was introduced by transduction into the genome of the Gamr444 mutant, its enhanced radiation-resistance disappeared but could be restored upon introduction of pKV3 plasmid bearing the htpR+ gene. These data show that heat shock proteins are participating in the enhanced radioresistance of Gamr mutants.     

Escherichia coli K-12 mutants with enhanced resistance to ionizing radiation. IV. Recombination characteristics of Gamr mutants

In the radiation-resistant Gamr444 mutant the inheritance frequency of long F' episomes ORF1 (purE+ tsx+ procC+ lac+) and F'14 (ilv+--argE+) is lower, and the frequencies of chromosome mobilization and integrative suppression of temperature-sensitive dnaA46 mutation by the sex factor F are much higher than those in the wild-type strain AB1157 and another radiation-resistant mutant Gamr445. In this respect, the mutant Gamr444 is very similar to the recRC sbcB mutant (RecF-pathway of recombination).     

Escherichia coli K-12 mutants with increased resistance to ionizing radiation. V. The effect of mutations on spontaneous and radiation mutagenesis

The frequencies of spontaneous mutations (reversions his-4----His+ and forward mutations to rifampicin-, nalidixic acid- or valine-resistance) in radiation-resistant mutants Gamr444 and Gamr445 are much lower than in the wild-type strain AB1157. His+ revertants and rifampicin-resistant mutants Rifr are induced by low doses of gamma-rays more efficiently than in the wild-type. Low doses of UV light only enhanced mutagenic activity in Gamr strains for induction of His+ reversions but not for Rifr mutations. For the wild-type strain the frequencies of His+ and Rifr mutations increase proportionally to the square of dose both of UV light and gamma-rays. For the most radioresistant Gamr444 mutant the frequencies of UV- and gamma-rays-induced Rifr mutations and of gamma-rays-induced reversions increase linearly with the dose. Possible reasons for these anomalies of radiation-induced mutagenesis in Gamr mutants are discussed.     

The lambda Gam protein inhibits RecBCD binding to dsDNA ends

Inactivation of the Escherichia coli RecBCD enzyme by the lambda Gam protein is an essential step that accompanies the lambda Red proteins for gene replacement using recombineering technology. It has been shown that Gam inhibits all the activities of RecBCD to the same extent. Nonetheless, some in vivo properties of recBCD mutants cannot be mimicked effectively by the expression of gam in vivo. An examination of the mechanism of Gam's inhibition of RecBCD was performed, and it was found that Gam inhibits the binding of RecBCD to double-stranded DNA ends, even if RecBCD is bound to DNA before its interaction with Gam. When ATP is added to the reaction to induce helicase activity, most of the reaction is inhibited by Gam, but residual amounts of unwinding are detected, despite a 40-fold excess of Gam/RecBCD. The same inhibitory effect of Gam was seen on RecBCD that had been modified by the P22 anti-RecBCD protein Abc2, though the inhibitory effect was diminished due to the tighter binding of Abc2-modified RecBCD to double-stranded DNA ends. These data suggest that cells containing Gam-expressing plasmids retain a small amount of uninhibited enzyme. Given the suspected instability of Gam in vivo, care must be taken when interpreting results from experiments containing Gam-inhibited RecBCD species. A revised model is proposed for Gam-induced radioresistance of E. coli to ionizing radiation.     

Effect of insertional mutation in the cspA gene encoding the major cold-shock protein on radiation resistance of Escherichia coli

Plasmid pCspA::Km carrying a cloned mutant allele of the cspA gene for the major Escherichia coli cold-shock protein CspA with an insertion of the kanamycin resistance gene cassette from transposon Tn903 into the core region of the coding sequence causes a 2.3-fold increase in radioresistance of wild-type E. coli cells (cspA+). The radioprotective effect of this plasmid is abolished or drastically reduced in mutants recA13 and rpoH15 defective in RecA protein and in induction of the heat-shock protein regulon, respectively. Plasmid pCspA::Km causes a 1.3-fold elevation in the resistance to gamma-irradiation of E. coli mutants with an intermediate level of radioresistance (Gamr445 and KS0160) but slightly diminishes resistance of a highly radiation-resistant Gamr445 mutant. In the chromosome of E. coli with normal DNA repair systems, the cspA::Km mutation in the homozygous state enhances resistance to the lethal effect of gamma-rays and UV light 2.9 and 1.4 times, respectively. These data suggest that the system of cold-shock proteins can modulate resistance of E. coli cells to the lethal effect of gamma-rays and UV light.     

Transgenic expression of RecA of the spirochetes Borrelia burgdorferi and Borrelia hermsii in Escherichia coli revealed differences in DNA repair and recombination phenotypes

After unsuccessful attempts to recover a viable RecA-deficient mutant of the Lyme borreliosis agent Borrelia burgdorferi, we characterized the functional activities of RecA of B. burgdorferi, as well as RecA of the relapsing fever spirochete Borrelia hermsii and the free-living spirochete Leptospira biflexa, in a recA mutant of Escherichia coli. As a control, E. coli RecA was expressed from the same plasmid vector. DNA damage repair activity was assessed after exposure of the transgenic cells to UV light or the radiomimetic chemicals methyl methanesulfonate and mitomycin C. Recombination activity in the cells was assessed by using an assay for homologous recombination between repeats in the chromosome and by measuring the ability of the cells to foster lytic growth by red gam mutant bacteriophage lambda. Overall, we found that transgenic cells with recA genes of B. burgdorferi, B. hermsii, and L. biflexa had approximately equivalent activities in promoting homologous recombination in the lacZ duplication assay, but cells with B. burgdorferi recA and, most notably, B. hermsii recA were significantly less capable than cells with L. biflexa recA or E. coli recA in responding to DNA damage or in facilitating plaque formation in the phage assay. The comparatively poor function of Borrelia recA in the latter set of assays may be the consequence of impaired coordination in the loading of the transgenic RecA by RecBCD and/or RecFOR in E. coli.     

Interaction of lambda Gam protein with the RecD subunit of RecBCD enzyme increases radioresistance of the wild-type Escherichia coli.

By making use of the gam(+)-plasmid, the so-called gam-dependent radioresistance was studied. This resistance is the result of the interaction between Gam protein (encoded by the gam gene of lambda) and RecBCD enzyme of Escherichia coli. gam-dependent radioresistance is observed in recB+ recC+ recD+ but not in recB+ recC+ recD- cells. It is suggested that Gam protein interacts specifically with the RecD subunit of RecBCD enzyme; the RecBC complex probably retains its activity in the presence of this viral protein.     

The recB gene product is essential for exonuclease V-dependent DNA degradation in vivo

The recB21 mutation abolishes the exonuclease activity of the RecBCD enzyme (exonuclease V) of Escherichia coli. This might be due to the polar effect of recB21 on expression of the recD gene, the product of which is an essential component of the RecBCD enzyme. To achieve synthesis of the recD gene product, the recD+ plasmid was introduced into the recB21 mutant. Degradation of the endogenous DNA damaged by gamma-rays and degradation of the DNA of a phage T4 gene 2 mutant were nevertheless abnormally small in this strain. Thus, the functional recB gene product is required for the degradative function of the RecBCD enzyme.     

Cloning of fragments of lambda phage DNA, containing red and gam genes

On the base of plasmid pCV20 (Apr, Tcr mol. weight 5.2 x 10(6) a recombinant plasmid pEH60 (Apr, mol. weight 17.0 x 10(6) with BamHI fragment of phage DNA, containing red+ and gam+ genes was constructed. Selection was found on the ability of phage red- and gam- to propagate in strain E. coli K12 recA-, which was transformed by recombinant plasmid with active red and gam genes. Influence of recombinant plasmid pEH60 on processes of repair and recombination of phage lambda DNA and bacterial DNA was studied. It was shown that red gene in plasmid pEH60 compensates deficiency of redA gene in these processes with phage lambda DNA; in the case of E. coli K12 AB2480 uvr- recA- (pEH60) the processes of multiple reactivation and decombination of phage red- were presented. In the case of bacterial cells, plasmid pEH60 did not compensate deficiency of recA function of bacteria, although it partly compensates deficiency of recBC function. Increase of survival after introduction of plasmid pEH60 in the cell was obtained only for recBC- strain, but not for wild type and recA- strains.     

Modulation of Escherichia coli RecBCD activity by the bacteriophage lambda Gam and P22 Abc functions.

Plasmids that express the bacteriophage lambda gam gene or the P22 abc2 gene (with and without abc1) at controllable levels were placed in Escherichia coli and tested for effects on the activity of RecBCD. Like Gam, Abc2 inhibited the ATP-dependent exonuclease activity of RecBCD, apparently not by binding to DNA. However, Abc2-mediated inhibition was partial, while Gam-mediated inhibition was complete. Both Abc2 and Gam inhibited host system-mediated homologous recombination in a Chi-containing interval in the chromosome of a hybrid lambda phage; Abc2 inhibited it more strongly than Gam. Gam but not Abc2 spared a phage T4 gene 2 mutant from restriction by RecBCD; Abc2 exhibited weak sparing activity in combination with Abc1 and substantial activity in combination with both Abc1 and P22 homologous recombination function Erf. Either Gam or the combination of the lambda recombination functions Exo and Bet was sufficient to induce a mode of plasmid replication that produced linear multimers. The combination of Abc2, Abc1, and Erf also exhibited this activity. However, Erf was inactive, both by itself and in combination with Abc1; Abc2 had weak activity. These results indicate that Gam and Abc2 modulate the activity of RecBCD in significantly different ways. In comparison with lambda Gam, P22 Abc2 has a weak effect on RecBCD nuclease activity but a strong effect on its recombination-promoting activity.     

A comparative study of the functions of recBCD-nuclease from Escherichia coli and "recombinase", encoded by plasmid R1drd-19]

The RecBCD nuclease of Escherichia coli and "recombinase" determined by R1drd-19 plasmid (the latter is able to replace at least partially the indicated cellular enzyme) were shown to differ from each other in some essential features. The product encoded by the plasmid as distinct from RecBCD nuclease practically is not sensitive to inhibition by GamS protein of the lambda phage. Earlier, it was found that the presence of R1drd-19 plasmid in the recBC cells restores the level of the total ATP-dependent exonuclease activity because of appearance in such cells of a new exonuclease activity also ATP-dependent. The exonuclease activity determined by R1drd-19 plasmid was found to differ from the corresponding activity of the RecBCD enzyme. The plasmid enzyme was able to prevent reproduction of T4g2- mutant on recBC cells. The ability of the plasmid "recombinase" to some stimulation of intrachromosomal recombination in recA mutant witness to incomplete RecA-dependence of its function. No significant homology was registered between Escherichia coli DNA fragment containing the recB, recC, recD genes and the EcoRI-C-fragment of R1drd-19 carrying the sequences responsible for recombination and repair functions of the plasmid.     

Inhibition of the recBCD-dependent activation of Chi recombinational hot spots in SOS-induced cells of Escherichia coli.

Nucleotide sequences called Chi (5'-GCTGGTGG-3') enhance homologous recombination near their location by the RecBCD enzyme in Escherichia coli (Chi activation). A partial inhibition of Chi activation measured in lambda red gam mutant crosses was observed after treatment of wild-type cells with DNA-damaging agents including UV, mitomycin, and nalidixic acid. Inhibition of Chi activation was not accompanied by an overall decrease of recombination. A lexA3 mutation which blocks induction of the SOS system prevented the inhibition of Chi activation, indicating that an SOS function could be responsible for the inhibition. Overproduction of the RecD subunit of the RecBCD enzyme from a multicopy plasmid carrying the recD gene prevented the induced inhibition of Chi activation, whereas overproduction of RecB or RecC subunits did not. It is proposed that in SOS-induced cells the RecBCD enzyme is modified into a Chi-independent recombination enzyme, with the RecD subunit being the regulatory switch key.     

The genetic dependence of RecBCD-Gam mediated double strand end repair in Escherichia coli

The repair of double strand breaks after gamma-irradiation in wild-type Escherichia coli lysogenic for lambda cI857 red3 is more efficient when lambda Gam protein is present. This phenomenon, called gam dependent radioresistance, requires the interaction of RecBCD enzyme and Gam protein. We compared cell survival after gamma-irradiation in wild-type and mutant lysogens with and without induction of Gam by transient heat treatment of the cells (6 min, 42 degrees C). The main conclusions are: (1) the RecBCD-Gam pathway of recombination repair is similar but not equivalent to RecBCD, a pathway operating in recD mutants; (2) the RecBCD-Gam pathway is dependent on recJ, recQ and recN gene products and it is proposed that the RecBCD-Gam complex has ability to load RecA protein onto single strand DNA.     

Lambda Gam protein inhibits the helicase and chi-stimulated recombination activities of Escherichia coli RecBCD enzyme.

The lambda Gam protein was isolated from cells containing a Gam-producing plasmid. The purified Gam protein was found to bind to RecBCD without displacing any of its subunits. Gam was shown to inhibit all known enzymatic activities of RecBCD: ATP-dependent single- and double-stranded DNA exonucleases, ATP-independent single-stranded endonuclease, and the ATP-dependent helicase. When produced in vivo, Gam inhibited chi-activated recombination in lambda red gam crosses but had little effect on the host's ability to act as a recipient in conjugational recombination. These experiments suggest that RecBCD possesses an additional "unknown" activity that is resistant to or induced by Gam. Additionally, the expression of Gam in recD mutants sensitizes the host to UV irradiation, indicating that Gam alters one or more of the in vivo activities of RecBC(D-).     

Induction by gamma irradiation of double-strand breaks of Escherichia coli chromosomes and their role in cell lethality

Viscoelastometric measurements of DNA from gamma-irradiated bacteria were used to identify the induction of double-strand breaks ( DSBs ) in the chromosome of Escherichia coli. It is shown by means of inhibitors of repair endonucleases and different repair mutants that most DSBs in DNA of E. coli, gamma-irradiated in buffer, arise from enzymatic incision of primary gamma-damages; therefore, previous conclusions regarding DSB repair must be reconsidered. Based on these results, much of the reparable damage is single-strand breaks, and this damage can initiate formation of gaps and ultimately, when repair is insufficient, generation of enzymatically caused DSBs . After extensive repair, the first residual DSB in the E. coli chromosome is generated at approximately 160 Gray (Gy), which corresponds to the D37 dose. We propose that DSBs induced directly by gamma-irradiation are not repaired in wild-type strains. In a recently isolated gamma-resistant strain, E. coli Gamr444 , the dose required for observation of DSB after postirradiation incubation is 1,000 Gy, which corresponds to the D37 of the strain. The resistance is proposed to be due to an ability to repair genuine DSBs .     

Methyl methane sulfonate-sensitive mutant of Escherichia coli deficient in an endonuclease specific for apurinic sites in deoxyribonucleic acid.

A methyl methane sulfonate (MMS)-sensitive mutant of Escherichia coli AB 1157 was obtained by N-methyl-N'-nitro-N-nitrosoguanidine treatment. The mutant strain, AB 3027, is defective both in endonuclease activity for apurinic sites in deoxyribonucleic acid (DNA) and in DNA polymerase I, as shown by direct enzyme assays. Derivative strains, which retained the deficiency in endonuclease activity for apurinic sties (approximately 10% of the wild-type enzyme level) but had normal DNA polymerase I activity, were obtained by P1-mediated transduction (strain NH5016) or by selection of revertants to decreased MMS sensitivity. These endonuclease-deficient strains are more MMS-sensitive than wild-type strains. Revertants of these deficients strains to normal MMS resistance were isolated. They had increased levels of the endonuclease activity but did not attain wild-type levels. The data suggest that endonuclease for apurinic sites is active in repair of lesions introduced in DNA as a consequence of MMS treatment. Two different endonucleases that specifically attack DNA containing apurinic sites arepresented in E coli K-12. A heat-labile activity, sensitive to inhibition by ethylenediaminetetraacetate, accounts for 90% of the total endonuclease activity for apurinic sties in crude cell extracts. The residual 10% is due to a more heat-resistant activity, refractory to ethylenediaminetetraacetate inhibition. The AB3027 and NH5016 strains have normal amounts of the latter endonuclease but no or very little of the former activity.