Recombination of bacteriophage lambda in recD mutants of Escherichia coli

RecBCD enzyme is centrally important in homologous recombination in Escherichia coli and is the source of ExoV activity. Null alleles of either the recB or the recC genes, which encode the B and C subunits, respectively, manifest no recombination and none of the nuclease functions characteristic of the holoenzyme. Loss of the D subunit, by a recD mutation, likewise results in loss of ExoV activity. However, mutants lacking the D subunit are competent for homologous recombination. We report that the distribution of exchanges along the chromosome of Red-Gam-phage lambda is strikingly altered by recD null mutations in the host. When lambda DNA replication is blocked, recombination in recD mutant strains is high near lambda's right end. In contrast, recombination in isogenic recD+ strains is approximately uniform along lambda unless the lambda chromosome contains a chi sequence. Recombination in recD mutant strains is focused toward the site of action of a type II restriction enzyme acting in vivo on lambda. The distribution of exchanges in isogenic recD+ strains is scarcely altered by the restriction enzyme (unless the phage contains an otherwise silent chi). The distribution of exchanges in recD mutants is strongly affected by lambda DNA replication. The distribution of exchanges on lambda growing in rec+ cells is not influenced by DNA replication. The exchange distribution along lambda in recD mutant cells is independent of chi in a variety of conditions. Recombination in rec+ cells is chi influenced. Recombination in recD mutants depends on recC function, occurs in strains deleted for rac prophage, and is independent of recJ, which is known to be required for lambda recombination via the RecF pathway. We entertain two models for recombination in recD mutants: (i) recombination in recD mutants may proceed via double-chain break--repair, as it does in lambda's Red pathway and E. coli's RecE pathway; (ii) the RecBC enzyme, missing its D subunit, is equivalent to the wild-type, RecBCD, enzyme after that enzyme has been activated by a chi sequence.     

Exonuclease requirements for recombination of lambda-phage in recD mutants of Escherichia coli

Recombination of lambda red gam phage in recD mutants is unaffected by inactivation of RecJ exonuclease. Since nucleases play redundant roles in E. coli, we inactivated several exonucleases in a recD mutant and discovered that 5'-3' exonuclease activity of RecJ and exonuclease VII is essential for lambda-recombination, whereas exonucleases of 3'-5' polarity are dispensable. The implications of the presented data on current models for recombination initiation in E. coli are discussed.     

Conjugation is not required for adaptive reversion of an episomal frameshift mutation in Escherichia coli.

Adaptive reversion of a lac allele on an F' episome in a strain of Escherichia coli is dependent on the RecA-BCD pathway for recombination and is enhanced by conjugal functions. However, conjugation, i.e., transfer of the episome, whether between distinct populations of cells or between newly divided siblings, does not contribute to the mutational process.     

Linear multimer formation of plasmid DNA in Escherichia coli hopE (recD) mutants

Summary The hopE mutants of Escherichia coli, which cannot stably maintain a mini-F plasmid during cell division, have mutations in the recD gene coding for subunit D of the RecBCD enzyme (exonuclease V). A large amount of linear multimer DNA of mini-F and pBR322 plasmids accumulates in these hopE mutants. The linear multimers of plasmid DNA in the hopE (recD) mutants accumulate in sbc ⁺ genetic backgrounds and this depends on the recA ⁺ gene function. Linear plasmid multimers also accumulated in a recBC xthA triple mutant, but not an isogenic xthA mutant or an isogenic recBC mutant. The recBC xthA mutant is defective in the conjugative type of recombination. Linear plasmid multimers were not detected in the recBC strain. We propose models to account for linear multimer formation of plasmids in various mutants.     

Chromosome replication pattern in dam mutants of Escherichia coli

Summary The replication cycle of Escherichia coli dam mutants was analysed and compared with that of isogenic Dam⁺ strains. Marker frequency analyses indicated no gross difference between the strains. In the Dam^– as well as in the Dam⁺ bacteria, initiation most likely occurs at oriC, replication forks move at a constant and invariant velocity, and termination takes place in the terC region. An analysis of replication terminator activity indicated that this activity is unaffected by the methylation status. Taken together with previous results, our data are compatible with Dam methylation controlling initiation timing but no subsequent step of the replication process.     

Perturbed chromosomal replication in recA mutants of Escherichia coli.

When initiation of DNA replication is inhibited in wild-type Escherichia coli cells by rifampin or chloramphenicol, completion of ongoing rounds of replication (runout of replication) leads to cells containing two, four, or eight fully replicated chromosomes, as measured by flow cytometry. In recombination-deficient recA strains, a high frequency of cells with three, five, six, or seven fully replicated chromosomes was observed in addition to cells with two, four, or eight chromosomes. recA mutants affected only in the protease-stimulating function behaved like wild-type cells. Thus, in the absence of the recombinase function of RecA protein, the frequency of productive initiations was significantly reduced compared with that in its presence. DNA degradation during runout of replication in the presence of rifampin was about 15%. The DNA degradation necessary to account for the whole effect described above was in this range or even lower. However, a model involving selective and complete degradation of partially replicated chromosomes is considered unlikely. It is suggested that the lack of RecA protein causes initiations or newly formed replication forks to stall but remain reactivatable for a period of time by functional RecA protein.     

Evidence that recBC-dependent degradation of duplex DNA in Escherichia coli recD mutants involves DNA unwinding.

Infection of Escherichia coli with phage T4 gene 2am was used to transport 3H-labeled linear duplex DNA into cells to follow its degradation in relation to the cellular genotype. In wild-type cells, 49% of the DNA was made acid soluble within 60 min; in recB or recC cells, only about 5% of the DNA was made acid soluble. Remarkably, in recD cells about 25% of the DNA was rendered acid soluble. The DNA degradation in recD cells depended on intact recB and recC genes. The degradation in recD cells was largely decreased by mutations in recJ (which eliminates the 5' single-strand-specific exonuclease coded by this gene) or xonA (which abolishes the 3' single-strand-specific exonuclease I). In a recD recJ xonA triple mutant, the degradation of linear duplex DNA was roughly at the level of a recB mutant. Results similar to those with the set of recD strains were also obtained with a recC++ mutant (in which the RecD protein is intact but does not function) and its recJ, xonA, and recJ xonA derivatives. The observations provide evidence for a recBC-dependent DNA-unwinding activity that renders unwound DNA susceptible to exonucleolytic degradation. It is proposed that the DNA-unwinding activity causes the efficient recombination, DNA repair, and SOS induction (after application of nalidixic acid) in recD mutants. The RecBC helicase indirectly detected here may have a central function in Chi-dependent recombination and in the recombinational repair of double-strand breaks by the RecBCD pathway.     

Chromosome structure of Escherichia coli mutants temperature sensitive for deoxyribonucleic acid replication.

Folded chromosomes were isolated from Eschericia coli thermosensitive dnaA initiation mutants incubated at the nonpermissive temperature and were analyzed by neutral sucrose density gradient centrifugation. A chromosomal structure that sedimented at approximately 1,500S accumulated when the dnaA gene product was inactive. When the cells were returned to a permissive temperature, the folded chromosomes exhibited a decrease in sedimentation velocity to 1,300S but still retained their uniform structure. Very little deoxyribonucleic acid synthesis occurred during the period in which the chromosomes exhibited the reduction in sedimentation velocity. A dnaG elongation mutant showed no unique chromosome structure when the dnaG gene product was inactive.     

Effects of recJ, recQ, and recFOR mutations on recombination in nuclease-deficient recB recD double mutants of Escherichia coli

The two main recombination pathways in Escherichia coli (RecBCD and RecF) have different recombination machineries that act independently in the initiation of recombination. Three essential enzymatic activities are required for early recombinational processing of double-stranded DNA ends and breaks: a helicase, a 5'-->3' exonuclease, and loading of RecA protein onto single-stranded DNA tails. The RecBCD enzyme performs all of these activities, whereas the recombination machinery of the RecF pathway consists of RecQ (helicase), RecJ (5'-->3' exonuclease), and RecFOR (RecA-single-stranded DNA filament formation). The recombination pathway operating in recB (nuclease-deficient) mutants is a hybrid because it includes elements of both the RecBCD and RecF recombination machineries. In this study, genetic analysis of recombination in a recB (nuclease-deficient) recD double mutant was performed. We show that conjugational recombination and DNA repair after UV and gamma irradiation in this mutant are highly dependent on recJ, partially dependent on recFOR, and independent of recQ. These results suggest that the recombination pathway operating in a nuclease-deficient recB recD double mutant is also a hybrid. We propose that the helicase and RecA loading activities belong to the RecBCD recombination machinery, while the RecJ-mediated 5'-->3' exonuclease is an element of the RecF recombination machinery.     

Functions of multiple exonucleases are essential for cell viability, DNA repair and homologous recombination in recD mutants of Escherichia coli

Heterotrimeric RecBCD enzyme unwinds and resects a DNA duplex containing blunt double-stranded ends and directs loading of the strand-exchange protein RecA onto the unwound 3'-ending strand, thereby initiating the majority of recombination in wild-type Escherichia coli. When the enzyme lacks its RecD subunit, the resulting RecBC enzyme, active in recD mutants, is recombination proficient although it has only helicase and RecA loading activity and is not a nuclease. However, E. coli encodes for several other exonucleases that digest double-stranded and single-stranded DNA and thus might act in consort with the RecBC enzyme to efficiently promote recombination reactions. To test this hypothesis, I inactivated multiple exonucleases (i.e., exonuclease I, exonuclease X, exonuclease VII, RecJ, and SbcCD) in recD derivatives of the wild-type and nuclease-deficient recB1067 strain and assessed the ability of the resultant mutants to maintain cell viability and to promote DNA repair and homologous recombination. A complex pattern of overlapping and sometimes competing activities of multiple exonucleases in recD mutants was thus revealed. These exonucleases were shown to be essential for cell viability, DNA repair (of UV- and gamma-induced lesions), and homologous recombination (during Hfr conjugation and P1 transduction), which are dependent on the RecBC enzyme. A model for donor DNA processing in recD transconjugants and transductants was proposed.     

Amplification of lac cannot account for adaptive mutation to Lac+ in Escherichia coli

When the Lac- strain of Escherichia coli, FC40, is incubated with lactose as its sole carbon and energy source, Lac+ revertants arise at a constant rate, a phenomenon known as adaptive mutation. Two alternative models for adaptive mutation have been proposed: (i) recombination-dependent mutation, which specifies that recombination occurring in nongrowing cells stimulates error-prone DNA synthesis, and (ii) amplification-dependent mutation, which specifies that amplification of the lac region and growth of the amplifying cells creates enough DNA replication to produce mutations at the normal rate. Here, we examined several of the predictions of the amplification-dependent mutation model and found that they are not fulfilled. First, inhibition of adaptive mutation by a gene that is toxic when overexpressed does not depend on the proximity of the gene to lac. Second, mutation at a second locus during selection for Lac+ revertants is also independent of the proximity of the locus to lac. Third, mutation at a second locus on the episome occurs even when the lac allele under selection is on the chromosome. Our results support the hypothesis that most Lac+ mutants that appear during lactose selection are true revertants that arise in a single step from Lac- cells, not from a population of growing or amplifying precursor cells.     

Initiation of DNA replication in delta cya mutants of Escherichia coli K12

The purified DnaA protein has a high affinity for cyclic AMP (cAMP). Using equilibrium dialysis, we determined the K(A) value for cAMP as 0.819 muM(-1). The number of cAMP binding sites per DnaA protein molecule was calculated to be 1.04. This binding was quite specific for cAMP. ATP was also bound by DnaA protein and inhibited cAMP binding. This inhibition was non-competitive in nature with an inhibition constant (K(i)) of about 8.25 muM. However, in vivo we have found not only that the DnaA protein level is reduced in a cyclase deletion mutant strain, Delta++ cya, but also that DnaA protein is not degraded. The Delta cya mutants of E. coli are unable to continue DNA synthesis in the absence of de novo protein synthesis and the initiation of DNA replication in these mutants takes place from oriC.     

Chlorambucil-induced high mutation rate and suicidal gene downregulation in a base excision repair-deficient Escherichia coli strain

Chlorambucil (CLB; N,N-bis(2-chloroethyl)-p-aminophenylbutyric acid) is a bifunctional alkylating agent widely used as an anticancer drug and also as an immunosuppressant. Its chemical structure and clinical experience indicate that CLB is mutagenic and carcinogenic. We have investigated the ability of CLB to induce mutations and gene expression changes in the wild-type (WT) Escherichia coli strain AB1157 and in the base excision repair-deficient (alkA1, tag-1) E. coli strain MV1932 using a rifampicin (rif) forward mutation system and a cDNA array method. The results showed that CLB is a potent mutagen in MV1932 cells compared with the E. coli WT strain AB1157, emphasizing the role of 3-methyladenine DNA glycosylases I and II in protecting the cells from CLB-induced DNA damage and subsequent mutations. Global gene expression profiling revealed that nine genes in WT E. coli and 100 genes in MV1932, of a total of 4290 genes, responded at least 2.5-fold to CLB. Interestingly, all of these MV1932 genes were downregulated, while 22% were upregulated in WT cells. The downregulated genes in MV1932 represented most (19/23) functional categories, and unexpectedly, many of them code for proteins responsible for genomic integrity. These include: (i) RecF (SOS-response, adaptive mutation), (ii) RecC (resistance to cross-linking agents), (iii) HepA (DNA repair, a possible substitute of RecBCD), (iv) Ssb (DNA recombination repair, controls RecBCD), and (v) SbcC (genetic recombination). Our results strongly suggest that in addition to the DNA damage itself, the downregulation of central protecting genes is responsible for the decreased cell survival (demonstrated in a previous work) and the increased mutation rate (this work) of DNA repair-deficient cells, when exposed to CLB.     

dnaT, dominant conditional-lethal mutation affecting DNA replication in Escherichia coli.

Normally, bacteria cease DNA replication in the absence of protein synthesis. A variety of treatments, such as thymine starvation or a shift-up to rich medium, lead to continued DNA replication in the absence of protein synthesis. Mutants are described which always terminate replication under these conditions. These conditional lethal mutants, dnaT1 and dnaT2, contransduce with serB and dnaC. The mutation also affects cell division. All aspects of the mutant phenotype (obligatory termination of replication, temperature sensitivity of DNA replication and growth, and aberrant cell division at permissive growth temperatures) were transdominant to the wild-type phenotype. Episomes carrying the dnaT mutation appeared to be unstable. The existence of such a dominant mutation was predicted by a model of chromosome termination proposed by Kogoma and Lark (J. Mol. Biol. 94:243-256, 1975).