Pathogenicity of herpes simplex virus mutants containing drug resistance mutations in the viral DNA polymerase gene

Three herpes simplex virus mutants that contain drug resistance mutations in the DNA polymerase gene exhibited no significant reduction in replication in the ears of mice compared with the wild type after inoculation at that site but were attenuated for pathogenicity after intracerebral inoculation. Cataracts were common sequelae in mice that survived mutant infections.

Exonuclease III and endonuclease IV remove 3' blocks from DNA synthesis primers in H2O2-damaged Escherichia coli

Escherichia coli deficient in exonuclease III (xth gene mutants) are known to be hypersensitive to hydrogen peroxide. We now show that such mutants accumulate many more DNA single-strand breaks than do wild-type bacteria upon exposure to H2O2. DNA isolated from H2O2-treated xth- cells contains strand breaks that do not efficiently support synthesis by E. coli DNA polymerase I, indicating the presence of blocking groups at the DNA 3' termini. Purified E. coli exonuclease III activates this blocked DNA to allow substantial synthesis by polymerase I in vitro. Another E. coli enzyme, endonuclease IV, also activates primers for DNA polymerase. Exonuclease III accounts for greater than 95% of the total activity in E. coli crude extracts for removal of 3'-terminal phosphoglycolaldehyde esters from model DNA substrates. Purified exonuclease III and endonuclease IV can each efficiently remove 3'-terminal phosphoglycolaldehyde in vitro. An important physiological function for exonuclease III is thus the activation of blocked 3' ends for DNA repair synthesis. Endonuclease IV can also initiate the repair of ruptured 3'-deoxyribose in DNA.

Bacteriophage N4-coded 5'----3' exonuclease. Purification and characterization

Bacteriophage N4 DNA replication requires the activity of a phage-induced exonuclease. We show here that the activity is phage coded. We have purified this enzyme to apparent homogeneity. It has a denatured molecular weight of 45,000 and exists in solution as a dimer. Duplex DNA is the preferred substrate which it degrades in a 5'----3' direction to 5' mononucleotides by a distributive mechanism. The enzyme does not act at a nick or a gap; indeed, it requires an end for activity. A possible role for this exonuclease in N4 replication is discussed.

Escherichia coli xthA mutant is not hypersensitive to ascorbic acid/copper treatment--an H2O2 generating reaction

Ascorbate (vitamin C) in the presence of copper yields H2O2, which seems to be responsible for its toxic effects in bacteria. However, we found that the Escherichia coli xthA mutant strain, which is hypersensitive to H2O2, has almost the same sensitivity as the wild-type strain to ascorbate and copper treatment. Our results suggest that the DNA damage induced in E. coli by H2O2 generated in oxidized ascorbate solutions is different from that induced by direct H2O2 treatment.

Identification and characterization of recD, a gene affecting plasmid maintenance and recombination in Escherichia coli

We isolated mutations that reduce plasmid stability in dividing cell populations and mapped these mutations to a previously undescribed gene, recD, that affects recombination frequency and consequently the formation of plasmid concatemers. Insertions of the transposable element Tn10 into recD resulted in increased concatemerization and loss of pSC101 and ColE1-like replicons during nonselective growth. Both concatemer formation and plasmid instability in recD mutants require a functional recA gene. Mutations in recD are recessive to recD+ and map to a small region of the Escherichia coli chromosome located between recB and argA. Although the recD locus is distinct from loci encoding the two previously identified subunits of the RecBC enzyme, mutations in recD appear to affect the exonuclease activity of this enzyme.

recD: the gene for an essential third subunit of exonuclease V

Exonuclease V (EC 3.1.11.5) of Escherichia coli, an enzyme with multiple activities promoting genetic recombination, has previously been shown to contain two polypeptides, the products of the recB and recC genes. We report here that the enzyme contains in addition a third polypeptide (alpha) with a molecular mass of about 58 kDa. The alpha polypeptide is not synthesized by a class of mutants (previously designated recB) lacking the nuclease activity of exonuclease V but retaining recombination proficiency. The gene, recD, coding for the alpha polypeptide is located near recB in the order thyA-recC-ptr-recB-recD-argA on the E. coli chromosome. The recB and recD genes appear to be governed by a common promoter to the left of recB; a weaker promoter appears to govern recD alone. In the light of these results we discuss the relation between the structure and function of the three polypeptides of exonuclease V, hereby alternatively designated RecBCD enzyme.

Role of the radB gene in postreplication repair in UV-irradiated Escherichia coli uvrB

In UV-irradiated Escherichia coli, the radB101 mutation sensitized uvrB recF cells 4-fold and uvrB recB cells 1.2-fold, but did not sensitize uvrB recB recF cells. The radB mutation had very little effect (1.2-fold or less) on the repair of UV radiation-induced DNA daughter-strand gaps in uvrB cells, but it did cause about a 3-fold deficiency in the repair of the DNA double-strand breaks that arise in association with nonrepaired daughter-strand gaps in UV-irradiated uvrB recF cells. Thus, the radB gene does not appear to be involved in the recF-dependent or recF recB-independent processes for the repair of DNA daughter-strand gaps, but is involved in the recB-dependent postreplication repair of DNA double-strand breaks.

Repair of DNA double-strand breaks in UV-irradiated Escherichia coli uvrB recF cells is inhibited by rich growth medium

Ultraviolet (UV)-irradiated uvrB recF and uvrB recB cells of Escherichia coli K-12 showed similar radiation sensitivities when plated on minimal growth medium (MM), however, the uvrB recF cells were much more UV radiation-sensitive than the uvrB recB cells when plated on rich growth medium. Sedimentation analysis of the DNA from UV-irradiated uvrB recF cells suggests that the rich medium killing of uvrB recF cells is due to the inhibition of the repair of UV-radiation-induced DNA double-strand breaks, i.e., the killing is due to the inhibition of the recB-dependent pathway of postreplication repair. Furthermore, we demonstrated that the DNA double-strand breaks that were formed in UV-irradiated uvrB recA200(Ts) cells incubated at 42 degrees C in rich growth medium were not repaired whether the medium during subsequent repair incubation at 30 degrees C was MM or rich growth medium, while DNA double-strand breaks that were formed in MM at 42 degrees C could be repaired in MM or in rich growth medium at 30 degrees C. How the absence of an abrupt slowing of DNA synthesis when UV-irradiated cells are held in rich growth medium (Sharma and Smith, 1985b) may prevent the repair of these DNA double-strand breaks is discussed.

5-Azacytidine: survival and induction of the SOS response in Escherichia coli K-12

Survival and induction of the SOS system by 5-azacytidine, an analog of cytidine, were studied in Escherichia coli K-12. This compound did not produce any effect on the viability of dcm and dam dcm mutants. Furthermore, recA430 and lexA1 strains (both mutations interfere with LexA repressor cleavage but not recombination proficiency) were more resistant than the wild-type strain of E. coli K-12. In contrast, recBC and recA13 mutants were more sensitive to 5-azacytidine than the wild type. Transient exposure of E. coli to 5-azacytidine for 60 min induced both recA-dependent inhibition of cell division and induction of lambda prophage in Dcm+ strains but not in Dcm- mutants. Expression of both functions was dependent on recBC exonuclease. On the other hand, 5-azacytidine was unable to trigger the induction of umuCD and mucB genes and no amplification of RecA protein synthesis in either Dcm+ or Dcm- strains was observed. These last results are in agreement with previously reported data suggesting that there is a discrimination in the expression of the several SOS functions and that some SOS genes may be induced without amplification of RecA protein synthesis.

Complete nucleotide sequence of the Escherichia coli recC gene and of the thyA-recC intergenic region

The nucleotide sequence of a 6,000 bp region of the E. coli chromosome that includes the 3' end of the coding region for the thyA gene and the entire recC gene has been determined. The proposed coding region for the RecC protein is 3369 nucleotides long, which would encode a polypeptide consisting of 1122 amino acids with a calculated molecular mass of 129 kDa. Mung bean nuclease mapping of a recC specific transcript produced in vivo indicates that transcription of recC is initiated 80 bp upstream of the translational start point. A weak promoter sequence situated 5' to the transcription initiation point has been identified. In the 1953 bp thyA-recC intergenic region there are three open reading frames that would code for polypeptides of molecular mass 30 kDa, 13.5 kDa and 12 kDa, respectively. Although the first and third of these open reading frames are preceded by possible ribosome binding sites, no obvious promoter sequences could be identified. Moreover, transcripts for these reading frames could not be detected.

A phage P1 function that stimulates homologous recombination of the Escherichia coli chromosome

Recombination between two different defective lacZ genes in the Escherichia coli chromosome (lac- X lac- recombination) was stimulated 2- to 8-fold by prophage P1, depending on the nature of the phage c1 repressor. The P1 BamHI restriction fragment B8 in a lambda-P1:B8 hybrid phage, stimulated lac- X lac- recombination 90-fold in the absence of P1 repressor. A gene necessary for recombination enhancement, designated ref, was localized to one end of B8. Ref expression from lambda-P1:B8 was repressed in trans by a P1 c+ prophage. Two P1 regulatory mutations, bof and lxc, derepressed prophage expression of ref and depressed a prophage function that complemented an E. coli mutant (ssb) deficient in the single-stranded DNA binding protein. Ref stimulation was dependent on preexisting E. coli recombination functions (RecA-RecBC and RecA-RecF). However, other (phage and plasmid) recombination processes involving these functions were not stimulated. ref::Tn5 phages plated and formed lysogens normally. Thus ref appears to be an integral, but not essential, phage gene that stimulates recombination of the host chromosome specifically.

RecE-dependent lysogenic induction in the absence of repressor in Bacillus subtilis non-complementing diploids

The RecE protein of Bacillus subtilis, known to be required for induction of the SOS response and of phi 105 prophage, was shown to be involved in mitomycin C induction of B. subtilis diploid lysogens carrying a silent phi 105 prophage in their unexpressed chromosome. These stable non-complementing diploid lysogens, formed by protoplast fusion and regeneration, did not synthesize repressor, so that the induction observed must have resulted from RecE-dependent activation of the prophage rather than from RecE-dependent inactivation of repressor. Mitomycin C treatment does not induce permanent expression of the silent chromosome, so the activation seems to be temporary, perhaps reflecting the action of an SOS function under RecE control.

Lack of UV-induced respiration shutoff in a recF strain of Escherichia coli: temperature conditional suppression at 30 degrees C by the sfrA mutation

A mutation in the recF gene of Escherichia coli results in a radiation-sensitive strain. The RecF pathway and the RecBC pathway account for nearly all of the conjugative recombination occurring in E. coli. recBC cells are radiation-sensitive and carry only out a small amount of recombination but these deficiencies are suppressed by an sbcB as recombination is shunted to the RecF pathway. A recBC sbcB recF strain is very radiation-sensitive and is devoid of recombination ability. These deficiencies are suppressed by the srfA mutation; srfA is a recA allele. UV-induced respiration shutoff is a recA+, lexA+ and recBC+ dependent. We report in this paper that respiration does not shutoff in a recF strain at 37 and 30 degrees C. an srfA mutation suppresses this lack of respiration shutoff effect in a recF srfA mutant at 30 degrees C but not at 37 degrees C; no suppression by this mutation occurs at either temperature in a recF recBC sbcB strain. An srfA strain also does not shut off its respiration at 37 degrees C and shows a temperature conditional UV-induced respiration shutoff response at 30 degrees C. The srfA mutation is thought to cause an altered RecA protein to be produced and we suggest that at 37 degrees This altered protein is temperature sensitive. We conclude from the results in this paper that the recF gene product is required for UV-induced respiration shutoff and that the RecA protein plays a special role in the induction process.

Defect in expression of heat-shock proteins at high temperature in xthA mutants

Escherichia coli mutants lacking exonuclease III (xthA) are defective in the induction of heat-shock proteins upon severe heat-shock treatment (upshift from 30 to 50 degrees C) but not mild heat-shock treatment (upshift from 30 to 42 degrees C). We show that this defect is due to the xthA mutation by complementation. Furthermore, increasing the gene dosage of xthA+ prolongs the synthesis of heat shock proteins seen after a shift to 42 degrees C. Increasing the gene dosage of htpR+ partially suppresses the defect of xthA mutants in the synthesis of heat-shock proteins at 50 degrees C. When an xthA strain was incubated at 42 degrees C before a shift to 50 degrees C, it was then able to carry out the synthesis of heat-shock proteins at 50 degrees C.

The influence of repair systems on the presence of sensitive and resistant fractions in the relation of survival of colony-forming ability in Escherichia coli to UV exposure

In the experimentally observed relationship between survival of colony-forming ability and the amount of exposure to ultraviolet light, two characteristics are generally found. First, sensitive and resistant components often show. Second, there is often a shouldered character to the survival. We present evidence that the first is largely due to the presence of active replication forks in the genome, and that the second is related to the operation of the recombinational repair system. We are able to describe our data in terms of a superposition of single and multiple-hit fractions and to show that the latter are greatly increased, in excision-repair-competent strains, by prevention of protein synthesis for 1 h prior to irradiation. Applying this analysis and treatment to a number of mutant strains enables us to make suggestions as to the interaction between recombinational and excision repair.

Host/vector interactions which affect the viability of recombinant phage lambda clones

A class of recombinant phage lambda clones are recovered from human genomic libraries on Escherichia coli recB21 recC22 sbcB15 cells, which fail to form plaques on wild-type cells. We report experiments which address the mechanism of this inhibition. The introduction of the recombination-stimulating sequence chi into one such clone allows growth of this phage on Rec+ cells. In addition, the insertion of lambda gam+ gene into a rec+-inhibited clone results in the ability of the phage to form plaques on wild-type cells. Since lambda Gam protein is an inhibitor of host RecBC enzyme, we tested a collection of such phage for growth on a variety of hosts altered in RecBC function. Host permissiveness correlated with the inactivation of the RecBC nucleolytic activities and not with the recombinational activities. These observations suggest that the inserted DNA sequences of these phage limit the production of packageable chromosomes. This conclusion is easily reconciled with our current knowledge of the interaction of the host recombination systems with lambda replication and encapsidation. Based on these experiments we have constructed strains, both recombination-proficient and recombination-deficient, which serve as improved hosts for the recovery of genomic sequences which are otherwise inhibitory to the growth of phage lambda.

Factors which equalize the representation of genome segments in recombinant libraries

Genomic segments which contain inverted repetitions longer than 300 bp are frequently lost from recombinant libraries grown on rec+ hosts. We have found that 9% of phage lambda clones that contain 15-20-kb insertions of human or Drosophila DNA are inhibited on rec+ hosts and as a result will become under-represented in amplified genomic libraries. We have therefore examined several factors of both host and vector origin which affect the fidelity of representation of genomic sequences in recombinant DNA libraries constructed in bacteriophage lambda vectors. This loss may be diminished if the vector carries either a chi element or a functional gam gene. The most successful approach, however, involves using a host with mutations in recB, recC, and sbcB, or in recD. We have shown that recombinant clones which require such mutant hosts for growth are somewhat more likely to contain DNA derived from loci in the genome which are polymorphic than are clones recovered on conventional hosts.

Selective inhibition of Escherichia coli recBC activities by plasmid-encoded GamS function of phage lambda

The gam locus of bacteriophage lambda encompasses two coding sequences with the same reading frame and translational stop, one corresponding to an Mr 11646 polypeptide (gamS gene), the other to an Mr 16349 polypeptide (gamL gene). A DNA segment encoding gamS but not gamL was placed under lambda pR promoter control (regulated by the cIts857-coded repressor) on a multicopy plasmid, and an insertion mutation (gamS201) was constructed. Expression of gamS+, but not gamS201, inhibited Escherichia coli RecBC nuclease in vivo; the criteria were inhibition of chromosomal DNA degradation after UV irradiation and plating of T4 gene 2- phages. The recB+ C+ bacteria expressing gamS+ were completely or partially similar to recC- mutants with respect to certain phenotypes: defective plating of phages P1 and P2, ability to plate (in a recA- background) lambda red- gam- phages, reduced resistance to UV irradiation, defective SOS induction, decreased colony-forming ability.

Intramolecular recombination of linear DNA catalyzed by the Escherichia coli RecE recombination system

Transformation of different Escherichia coli strains by linear dimers of pBR322 containing different tet alleles was investigated. Linear dimers transformed wild-type strains 0.1 to 1% as efficiently as circular dimers. In contrast, linear dimers transformed recBrecCsbcA strains, where the RecE recombination system is functional, as efficiently as circular dimers. The transformants contained plasmids that had a single recombinant monomer genotype, indicating that transformation was mediated by a recombination-dependent cyclization reaction. Altering the position of the double-strand break changed the frequency of recovering different recombination products, but had no effect on the frequency of transformation. Both the frequency of transformation and the production of Tcr recombinants were decreased by recE mutations, while recA and recF mutations were slightly stimulatory (twofold). Several recombination models consistent with these results are presented.

Role of Escherichia coli RecBC enzyme in SOS induction

Induction of the SOS genes is required for efficient repair of damaged DNA in Escherichia coli. SOS induction by nalidixic acid or oxolinic acid, two inhibitors of DNA gyrase, requires the RecBC enzyme of E. coli. We report here that the nuclease activity of RecBC enzyme is not needed for SOS induction by these agents. We suggest that the unwinding activity of RecBC enzyme produces single-stranded DNA which activates the RecA protein to stimulate LexA repressor cleavage and SOS induction.

Mechanism of sbcB-suppression of the recBC-deficiency in postreplication repair in UV-irradiated Escherichia coli K-12

The mechanism by which an sbcB mutation suppresses the deficiency in postreplication repair shown by recB recC mutants of Escherichia coli was studied. The presence of an sbcB mutation in uvrA recB recC cells increased their resistance to UV radiation. This enhanced resistance was not due to a suppression of the minor deficiency in the repair of DNA daughter-strand gaps or to an inhibition of the production of DNA double-strand breaks in UV-irradiated uvrA recB recC cells; rather, the presence of an sbcB mutation enabled uvrA recB recC cells to carry out the repair of DNA double-strand breaks. In the uvrA recB recC sbcB background, a mutation at recF produced a huge sensitization to UV radiation, and it rendered cells deficient in the repair of both DNA daughter-strand gaps and DNA double-strand breaks. Thus, an additional sbcB mutation in uvrA recB recC cells restored their ability to perform the repair of DNA double-strand breaks, but the further addition of a recF mutation blocked this repair capacity.

Mini-F plasmid-induced SOS signal in Escherichia coli is RecBC dependent

Dispensable replicons such as F plasmid [95 kilobases (kb)] or its mini-derivatives such as mini-F (9.3 kb) or lambda mini-F efficiently induced cellular SOS genes such as sfiA (sulA) when they were damaged by UV irradiation and then introduced into a recipient bacterium. To generate an SOS signal, UV light-damaged mini-F or mini-F conditional mutants deficient in replication required that the bacterial RecBC enzyme retained some activity different from the nuclease activity that was dispensable. In contrast, UV light-damaged F plasmid produced an SOS signal independently of the activity of the RecBC enzyme and of the expression of the mini-F, -H, and -G proteins. Our findings are consistent with a picture in which the SOS signal is constituted by stretches of single-stranded DNA on a replicon. Moreover, our present data combined with other data previously published lead to the hypothesis that the SOS signal induced by mini-F plasmid is located in trans on the host chromosome, whereas the one generated by UV light-damaged F plasmid is in cis on the transferred DNA.

Purification and subunit structure of recBC DNase from Escherichia coli harboring a recB and recC genes-inserted plasmid

recBC DNase of Escherichia coli has been purified from the transformant, HB101/pFS11-04 (recB+ recC+), by successive ammonium sulfate fractionation, DEAE-cellulose chromatography, Sephadex G-150 gel filtration, hydroxyapatite chromatography, DNA cellulose affinity chromatography, and second DEAE-cellulose chromatography. The purified enzyme was obtained in an overall yield of 3%. The enzyme protein appeared as a single pure component on native polyacrylamide gel electrophoresis. The purified enzyme was analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and two-dimensional electrophoresis. The results show that recBC DNase consists of two nonidentical subunits with molecular weights of 125,000 and 135,000, and isoelectric points of 5.6 and 5.7, respectively.

Uvr-independent repair of 8-methoxypsoralen crosslinks in Escherichia coli: evidence for a recombinational process

On the basis of survival data, repair of 8-methoxypsoralen DNA crosslinks in Escherichia coli strains lacking a functional uvrABC endonuclease, is shown to require the products of the recA, recB, recF and recN genes. Bacteria, grown under conditions where most cells contain only a single genome, show no evidence of crosslink repair. Similarly, bacteriophage lambda shows evidence of crosslink repair only in SOS-induced cells, and only at multiplicities of infection greater than 1. The requirement for rec+ genes may be partly ascribed to the need for a functional SOS response, but taken together, the results suggest a recombinational step involving a homologous region of DNA may occur during uvr-independent crosslink repair.

Amplification of a chromosomal region in Bacillus subtilis

We report on the amplification in Bacillus subtilis of a defined DNA sequence after exposure of the bacteria to increasing levels of antibiotic. The experimental system consisted of transformation of competent cells with a plasmid (pRHA39) unable to replicate in the host and carrying the alpha-amylase gene derived from B. subtilis. Selection of transformants resistant to 5 micrograms of chloramphenicol per ml resulted in the isolation of strains with the plasmid integrated into the chromosome at the site of homology, by a Campbell type mechanism. Starting from such a nontandem duplication, amplification was achieved by growing the bacteria in increasing concentrations of chloramphenicol. By dilution, Southern blotting, and hybridization to a radioactive probe, we estimated a copy number of about 10 for the amplified sequence of samples grown in the presence of 50 micrograms of chloramphenicol per ml. No free plasmid could be detected in the amplified strains. The extent of the amplified region was the same for all transformants, and the endpoints appeared to be the same in all isolates. As a consequence of the amplification, there was a noticeable increase in amylase production, and the amount of enzyme produced correlated with gene dosage. The amplification did not occur in a recE genetic background.