Effects of recB21, recF143, and uvrD152 on recombination in lambda bacteriophage-prophage and Hfr by F- crosses.

The effects of the mutation pairs recB21 recF143 and recB21 uvrD152 on the frequency of genetic recombination were investigated in lambda phage-prophage crosses under homoimmune conditions. To prevent recombinants from being formed by the phage red system, these experiments were performed with phages and prophages carrying red and gam mutations. Both spontaneous and damage-induced recombination was measured, the phages being either undamaged or treated with trimethylpsoralen and 360-nm light to cross-link the phage DNA. Control and damaged phages were allowed to infect lysogenic host cells under conditions in which phage gene expression was repressed and phage DNA replication was blocked by lambda immunity. Although the double mutations recB21 recF143 and recB21 uvrD152 reduced recombination in Hfr by F- crosses to 0.3 to 0.02% of the wild-type controls, the presence of these pairs of mutations in the host lysogens had relatively little effect on the results of the phage-prophage crosses. In the latter system, recB21 recF143 reduced spontaneous and damaged-induced recombination by less than threefold whereas recB21 uvrD152 increased it to three times the wild-type level, the increase being attributable to the uvrD mutation. Evidently, the gene products of recB,C uvrD, and recF wee not needed for lambda phage-prophage recombination under repressed conditions.     

Hyper-recombination in uvrD mutants of Escherichia coli K-12

Summary A mutant strain of E. coli which was isolated initially because of its strong hyper-recombination phenotype was shown to carry a lesion in uvrD. The presence of this mutation, designated uvrD210, increased the frequency of recombination between chromosomal duplications in F-prime repliconant cells and reduced linkage between closely linked markers in crosses with Hfr donors. A comparable hyper-rec phenotype was demonstrated in strains carrying other alleles of uvrD previously referred to as mutU4, uvr502 and recL152. The recombination activity of a uvrD210 strain was abolished by mutation of recA but the mutator activity associated with this allele proved to be independent of recA. It is suggested that uvrD mutations reduce the fidelity of DNA replication and that the accumulation of lesions in the newly synthesized strand provides additional sites for initiating recombination.     

Hyper-recombination in Escherichia coli K-12 mutants constitutive for protein X synthesis.

Genetic recombination was studied in Escherichia coli F- strains in which synthesis of the recA gene product protein X is increased due to mutation in either recA (tif-1) or lexA (spr). When a single donor marker was selected, the recombination proficiency of these strains was not significantly altered in Hfr crosses. However, linkage of unselected, proximal Hfr markers was found to be much reduced among the progeny tested, and more of the progeny showed evidence of multiple exchanges between donor and recipient DNA. These effects were much more apparent when the recipient carried both tif-1 and spr mutations, but in this case recombination proficiency was reduced compared with those strains carrying either mutation alone, particularly in crosses with Hfr Cavalli. A lexA mutation was found to suppress the effect of tif-1 on the recombinant genotype.     

uvrD mutations enhance tandem repeat deletion in the Escherichia coli chromosome via SOS induction of the RecF recombination pathway

It has previously been shown that recombination between tandem repeats is not significantly affected by a recA mutation in Escherichia coli . Here, we describe the activation of a RecA-dependent recombination pathway in a hyper-recombination mutant. In order to analyse how tandem repeat deletion may proceed, we searched for mutants that affect this process. Three hyper-recombination clones were characterized and shown to be mutated in the uvrD gene. Two of the mutations were identified as opal mutations at codons 130 and 438. A uvrD  ::Tn 5 mutation was used to investigate the mechanism of deletion formation in these mutants. The uvrD -mediated stimulation of deletion was abolished by a lexAind3 mutation or by inactivation of either the recA , recF , recQ or ruvA genes. We conclude that (i) this stimulation requires SOS induction and (ii) tandem repeat recombination in uvrD mutants occurs via the RecF pathway. In uvrD ⁺ cells, constitutive expression of SOS genes is not sufficient to stimulate deletion formation. This suggests that the RecF recombination pathway activated by SOS induction is antagonized by the UvrD protein. Paradoxically, we observed that the overproduction of UvrD from a plasmid also stimulates tandem repeat deletion. However, this stimulation is RecA independent, as is deletion in a wild-type strain. We propose that the presence of an excess of the UvrD helicase favours replication slippage. This work suggests that the UvrD helicase controls a balance between different routes of tandem repeat deletion.     

Conjugational Recombination in Escherichia Coli: Genetic Analysis of Recombinant Formation in Hfr X F(-) Crosses

The formation of recombinants during conjugation between Hfr and F(-) strains of Escherichia coli was investigated using unselected markers to monitor integration of Hfr DNA into the circular recipient chromosome. In crosses selecting a marker located ~500 kb from the Hfr origin, 60-70% of the recombinants appeared to inherit the Hfr DNA in a single segment, with the proximal exchange located >300 kb from the selected marker. The proportion of recombinants showing multiple exchanges increased in matings selecting more distal markers located 700-2200 kb from the origin, but they were always in the minority. This effect was associated with decreased linkage of unselected proximal markers. Mutation of recB, or recD plus recJ, in the recipient reduced the efficiency of recombination and shifted the location of the proximal exchange (s) closer to the selected marker. Mutation of recF, recO or recQ produced recombinants in which this exchange tended to be closer to the origin, though the effect observed was rather small. Up to 25% of recombinant colonies in rec(+) crosses showed segregation of both donor and recipient alleles at a proximal unselected locus. Their frequency varied with the distance between the selected and unselected markers and was also related directly to the efficiency of recombination. Mutation of recD increased their number by twofold in certain crosses to a value of 19%, a feature associated with an increase in the survival of linear DNA in the absence of RecBCD exonuclease. Mutation of recN reduced sectored recombinants in these crosses to ~1% in all the strains examined, including recD. A model for conjugational recombination is proposed in which recombinant chromosomes are formed initially by two exchanges that integrate a single piece of duplex Hfr DNA into the recipient chromosome. Additional pairs of exchanges involving the excised recipient DNA, RecBCD enzyme and RecN protein, can subsequently modify the initial product to generate the spectrum of recombinants normally observed.     

lexA dependent recombination in uvrD strains of Escherichia coli

Mutation of the uvrD gene of Escherichia coli is associated with an increased capacity for genetic recombination. The hyper-recombination effect is abolished by an additional mutation in lexA that limits synthesis of RecA protein and other gene products regulated by LexA repressor, and is not restored when increased synthesis of RecA protein is facilitated by a recAoc mutation. The viability of uvrD lexA strains is reduced and revertants selected on the basis of improved growth fall into three categories: those that are lexA+, or carry another mutation in lexA that directly suppresses the lexA defect; recA mutants that have lost the capacity for recombination altogether; and a third class which carry a mutation that is not in lexA or recA and which restores the hyper-rec phenotype but does not otherwise suppress the lexA defect. These results indicate that the hyper-recombination effect of a uvrD mutation is an induced response catalysed by RecA protein and at least one other lexA regulated activity.     

Studies on bacterial conjugational crosses via model populations. III. Reproduction of results of Hfr x F- crosses in Escherichia coli

Hfr x F- recombinational genome interactions are simulated by a computer program. Genotype spectrums of selected samples from Hfr x F- crosses of Escherichia coli, found in the published literature, are reproduced. Relevance of the findings for interpretation of conjugational results in Escherichia coli is discussed.     

Isolation and characterization of mutator strains of Escherichia coli K-12.

A selection procedure was devised to select for mutants of Escherichia coli K-12 with enhanced rates of spontaneous frameshift mutation. Three types of mutants were isolated. Two of the mutations apparently represent alleles of previously isolated mutL13 and mutS3. The third type of mutation, represented by two alleles, lies between lysA and thyA, and has been designated mutR. mutR increases the rate of spontaneous frameshift mutation and also the rate of base substitution mutations. The mutator phenotype is recessive. Reversion of a lac amber mutation located on an episome is increased in the presence of the mutator, indicating that mutR can act in trans. No change in sensitivity to ultraviolet irradiation or mitomycin C could be found when mutR34 was compared to the isogenic mutR+ strain. The mutator's activity was little affected by the type of medium in which the strain was grown. Deoxyribonucleoside triphosphate pools were normal in mutR34. Intergenic recombination frequencies were the same in mutR and mutR and mutR+ strains, but a two- to threefold increase in intragenic recombination was observed in Hfr times Fminus crosses when the recipeint was mutR34 as compared with mutR+. This increase appeared independent of the distance between the two markers within the gene in which the crossover took place.     

Isolation and Characterization of a Recombination-Deficient Hfr Strain

The isolation of a rec(-) Hfr strain of Escherichia coli K-12 is described. The method used consisted of mating AB2463 F(-) Rec(-) His(-) Lac(-) with P4X6 Hfr Rec(+) His(+) Lac(+), selecting Rec(-) His(-) Lac(+) recombinants, and searching for Hfr strains. One Hfr rec(-) strain, no. 12, was used as donor in crosses with Rec(+) and Rec(-) recipients. Crosses with Rec(+) recipients are fertile, and those with Rec(-) recipients are almost infertile, the frequency of recombinants being 10(-2) to 10(-3) that found with Rec(+) recipients. The Rec(-) mutant marker is transfered to and integrated into Rec(+) recipients. Zygotic induction of prophage lambda is observed in crosses between two Rec(-) strains. In crosses of F(-) Rec(-) with Hfr Rec(-), the gradient of integration frequencies for markers progressively more distant from the origin is steeper than in the Rec(+) x Rec(-) or the Rec(-) x Rec(+) crosses.     

Effect of transient lambda prophage induction on ultraviolet light resistance and recombination in Escherichia coli.

Transient induction of lambda prophage increases the ultraviolet light resistance of most exponentially growing Escherichia coli lysogens. Resistance is increased in wild-type, recB, recB recC, recB recC recF, and recB recC recL hosts. No enhancement in recA lysogens was found, nor was there enhancement in stationary cultures. Enhancement was dependent upon the lambdared recombination system. Transient induction also increases the genetic recombination rate in recB lysogens as measured in Hfr X F- matings.     

Seventeen Complementation Groups of Mutations Decreasing Meiotic Recombination in Schizosaccharomyces Pombe

We have analyzed 43 recessive mutations reducing meiotic intragenic recombination in Schizosaccharomyces pombe. These mutations were isolated by a screen for reduced plasmid-by-chromosome recombination at the ade6 locus. Sixteen of the mutations define 10 new complementation groups, bringing to 17 the number of genes identified to be involved in meiotic recombination. The mutations were grouped into three discrete classes depending on the severity of the recombination deficiency in crosses involving the ade6-M26 recombination hotspot. Class I mutations caused at least a 1000-fold reduction in M26-stimulated intragenic recombination at the ade6 locus. Class II mutations reduced M26-stimulated recombination approximately 100-fold. Class III mutations caused a 3-10-fold reduction in either M26-stimulated or non-hotspot recombination. We obtained multiple alleles of class I and class II mutations, suggesting that we may be nearing saturation for mutations of this type. As a first step toward mapping, we used mitotic segregation to assign fourteen of the rec genes to chromosomes. Mutations in the six rec genes tested also caused a decrease in intragenic recombination at the ura4 locus; five of these mutations also reduced intergenic recombination between the pro2 and arg3 genes. These results indicate that these multiple rec gene products are required for high level meiotic recombination throughout the S. pombe genome.     

Effects of intragenic recombination on Est-alpha allele frequencies in natural populations of Drosophila virilis

Relationships between the occurrence frequencies of intragenic recombinants and the allele frequencies at the Est-alpha locus were examined in two ecological populations of Drosophila virilis. The effective occurrence rate of recombinant alleles is on the average 0.95 X 10(-5). The effects of the recombination were slightly recognized in terms of the allele frequencies.     

The influence of the PO1A1 mutation upon recombination in Escherichia coli K12.

Genetic recombination in Escherichia coli is a highly regulated process involving multiple gene products. We have investigated the role of DNA polymerase I in this process by studying the effect of the po1A1 mutation upon DNA transfer and conjugation in otherwise isogenic suppressor-free strains of E. coli K-12. It was found that the po1A1 mutation greatly reduces recombination in Hfr crosses (a factor of 20 in Pol+ x Po1A1 crosses and more than a factor of 100 in Po1A1 X Po1A1 crosses). However, since the po1A1 mutation reduces the strains capacity to act as a recipient for an F-prime and the analysis of recombination transfer gradients revealed no differences between Po1+ and Po1- strains, it is concluded that DNA polymerase I probably affects the transfer and/or stability of donor DNA rather than the recombinational process itself.     

Plasmid control of recombination in E. coli K 12

Summary The recombination proficiency of three recipient strains of Escherichia coli K 12 carrying different plasmids was investigated by conjugal mating with Hfr Cavalli. Some plasmids (e.g. R1drd 19, R6K) caused a marked reduction in the yield of recombinants formed in crosses with Hfr but did not reduce the ability of host strains to accept plasmid F104. The effect of plasmids on recombination was host-dependent. In Hfr crosses with AB1157 (R1-19) used as a recipient the linkage between selected and unselected proximal markers of the donor was sharply decreased. Plasmid R1-19 also decreased the yield of recombinants formed by recF, recL, and recB recC sbcA mutants, showed no effect on the recombination proficiency of recB recC sbcB mutant, and increased the recombination proficiency of recB, recB recC sbcB recF, and recB recC sbcB recL mutants. An ATP-dependent exonuclease activity was found in all tested recB recC mutants carrying plasmid R1-19, while this plasmid did not affect the activity of exonuclease I in strain AB1157 and its rec ^– derivatives. The same plasmid was also found to protect different rec ^– derivatives of the strain AB1157 against the lethal action of UV light. We suppose that a new ATP-dependent exonuclease determined by R1-19 plays a role in both repair and recombination of the host through the substitution of or competition with the exoV coded for by the genes recB and recC.     

Studies on bacterial conjugational crosses via model populations. I. The model populations

A procedure is presented in which model populations, simulating progenies obtained from Escherichia coli Hfr x F- crosses, are generated. The procedure seems to be appropriate for visualizing hidden features of the genetic analysis, which are not detected by the conjugational crosses.     

Indirect stimulation of recombination in Escherichia coli K-12: dependence on recJ, uvrA, and uvrD.

Direct and indirect UV-stimulated homologous genetic recombination was investigated in Escherichia coli strains blocked in several host-encoded functions. Genetic recombination was assayed by measuring beta-galactosidase produced after recombination between two noncomplementing lacZ ochre alleles. Both types of stimulation (direct and indirect) were found to be primarily RecF pathway-mediated. In a rec+ background, both direct and indirect stimulation were found to be dependent on uvrD (coding for helicase II). In a recB21 sbcB15 background, direct and indirect stimulation were uvrD dependent only when the strain was additionally deficient in the UvrABC excision repair pathway. Indirect but not direct stimulation was also dependent on recJ (coding for a 5'-to-3' exonuclease specific for single-stranded DNA) regardless of sbcA or sbcB configuration. The methyl-directed mismatch repair system (mutSLH) also appeared to play an important role in stimulation. On the basis of these findings, we suggest that excision of UV-induced DNA damage is a prelude to UV-mediated stimulation of genetic recombination.     

Conversion of large heterologies in Streptococcus pneumoniae

In genetic transformation, long deletions dramatically increase the frequency of wild-type recombinants in 2-point crosses. In 3-point crosses in which the deletion was localized between 2 point mutations we demonstrated that this hyper-recombination was the result of genetic conversion extending over several scores of bases outside the deletion. As this conversion did not require an active DNA polymerase A gene, it was proposed that the mechanism of conversion involves breakage and ligation between DNA molecules. A similar hyper-recombination was observed when donor DNA carried an insertion. These results suggest that long heterologies participated in recombination so that surrounding homologous regions are almost completely paired and that these long heterologies are converted. It appears that it is a process that evolved to correct errors of replication which lead to long deletions and which are not eliminated by other systems.     

Linkage distortion following conjugational transfer of sbcC+ to recBC sbcBC strains of Escherichia coli.

Conjugational recombination in Escherichia coli depends normally on RecBCD enzyme, a multifunctional nuclease and DNA helicase produced by the recB, recC, and recD genes. However, recombination can proceed efficiently without RecBCD in recB or recC strains carrying additional mutations in both the sbcB and sbcC genes. Recombination in these strains, sometimes referred to as the RecF pathway, requires gene products that are not essential in the RecBCD-dependent process predominating in the wild type. It has also been reported to produce a different spectrum of recombinant genotypes in crosses with Hfr donors. However, the sbcC+ gene was unknowingly transferred to the recipient strain in some of these crosses, and this may have affected the outcome. This possibility was examined by conducting parallel crosses with Hfr donors that were either wild type or mutant for sbcC. Transfer of sbcC+ from an Hfr donor is shown to alter the frequency of recombinant genotypes recovered. There is a severe reduction in progeny that inherit donor markers linked to the sbcC+ allele and an increase in the incidence of multiple exchanges. Colonies of mixed genotype for one or more of the unselected proximal markers are also much more prevalent. Since the yield of recombinants is lower than normal, these changes are attributed to the reduced viability of recombinants that inherit sbcC+ from the Hfr donor. When the Hfr donor used is also mutant for sbcC, the yield of recombinants is greater and the frequencies of the different genotypes recovered are similar to those obtained in crosses with a rec+ sbc+ recipient, in which transfer of sbcC+ has no apparent effect. Earlier studies are re-examined in light of these findings. It is concluded that, while recombination in recBC sbcBC strains involves different enzymes, the underlying molecular mechanism is essentially the same as that in the wild type.     

Some Genetic Consequences of Changes in the Level of recA Gene Function in ESCHERICHIA COLI K-12

Genetic recombination was studied in E. coli mutants that carry lesions in the recA gene but retain some capacity for generating recombinant progeny. We observed that recombination was detectable only at a very low level during the incubation of leaky RecA^- merozygotes in broth. However, recombination appeared to occur at much higher frequencies when recombinant progeny were assayed by selection on minimal agar. Analysis of the recombinants obtained with Hfr donors revealed a deficiency of multiple exchanges per unit length of DNA in leaky RecA ^- strains. In many of these crosses recombinants that inherited donor alleles close to the transfer origin were much reduced in frequency, except when the recipient was also RecB^-.     

Antipairing and strand transferase activities of E. coli helicase II (UvrD).

The product of the uvrD gene of Escherichia coli, UvrD (helicase II), is known to be involved in methyl-directed mismatch repair, transposon excision and uvrABC excision repair. In conjugational crosses, various uvrD mutants have been reported to result in higher, lower or unaffected recombination frequencies. In an attempt to clarify the role of UvrD in recombination, we have studied in vitro its effects on two key reactions driven by RecA, homologous pairing and strand exchange. We show here that UvrD efficiently prevents or reverses RecA-mediated homologous pairing. Unexpectedly, we also found that it can stimulate RecA-driven branch migration and even catalyze strand exchange in the absence of RecA. A possible in vivo role for these antagonistic activities is discussed.