Identification of the genes coding for the second-largest subunits of RNA polymerases I and III of Drosophila melanogaster

Summary Colony forming ability of Escherichia coli strains carrying the rnh-339::cat mutant allele is strongly dependent on the recBCD and sbcB genes. A mutation inactivating either the RecBCD nuclease or exonuclease I (sbcB) is sufficient to restrict severely the efficiency of plating of strains carrying the rnh-339::cat mutation. Combining a non-lethal temperature-sensitive mutation in the RecBCD nuclease, recB270 (Ts) or recC271 (Ts), with rnh-339::cat renders strains temperature sensitive for growth, even though rnh ⁺ strains with the recB270 (Ts) or recC271 (Ts) alleles are viable at 42 C. The recombinational functions of the RecBCD nuclease can be excluded as the source of lethality on the basis of the following observations. Introduction of a recombination proficient, exonuclease defective recD1009 allele or production of the phage GamS protein (an inhibitor of the RecBCD exonuclease activity) in an rnh-339::cat strain dramatically delays or impairs the ability of such strains to form colonies. Restoration of recombination proficiency by inclusion of an sbcB15 mutation with recB21 recC22 mutations does not restore the ability of the rnh-339::cat mutant strains to plate normally. A recBCD ⁺ strain bearing the rnh-339::cat and sbcB15 mutations forms very few visible colonies after 24 h but forms colonies at normal frequencies after 48 h of incubation. Finally, plating efficiencies of strains are unaffected when the RecBCD recombination pathway is inactivated by introduction of recA56 into an rnh-339::cat strain. These results imply that the defective growth of rnh-339::cat recBCD strains is due to a defect in repair and not recombination mediated by either the RecBCD or the RecF pathway.     

A protein, connected with the integrity of the recF gene in Escherichia coli K-12

Summary A protein of molecular weight 74,000, called protein Z, has been identified in cells of the genotype recB21 recC22 sbcB15 by SDS-polyacrylamide gel electrophoresis. This protein has not been detected in cells of the genotype recB21 recC22 sbcB15 recF144. The transductional transfer of recF144 into the rec ⁺ cells leads to the disappearance of the protein Z band. These results demonstrate that the recF gene is essential for protein Z synthesis. Of two recF ^– mutants studied, recF144 completely lacks protein Z, while recF143 preserves a functionally inactive protein Z, probably resulting from a missense mutation.The recF144 cells are characterizied by a very low frequency of genetic exchange between the donor and recipient chromosomes after conjugation. The scale of the genetic map for these cells is 3-fold higher than for wild-type cells.     

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.     

Evidence of abortive recombination in ruv mutants of Escherichia coli K12

Summary Genetic recombination in Escherichia coli was investigated by measuring the effect of mutations in ruv and rec genes on F-prime transfer and mobilization of nonconjugative plasmids. Mutation of ruv was found to reduce the recovery of F-prime transconjugants in crosses with recB recC sbcA strains by about 30-fold and with recB recC sbcB sbcC strains by more than 300-fold. Conjugative plasmids lacking any significant homology with the chromosome were transferred normally to these ruv mutants. Mobilization of the plasmid cloning vectors pHSG415, pBR322, pACYC184 and pUC18 were reduced by 20- to 100-fold in crosses with ruv rec ⁺ sbc ⁺ strains, depending on the plasmid used. Recombinant plasmids carrying ruv ⁺ were transferred efficiently. With both F-prime transfer and F-prime cointegrate mobilization, the effect of ruv was suppressed by inactivating recA. It is proposed that the failure to recover transconjugants in ruv recA ⁺strains is due to abortive recombination and that the ruv genes define activities which function late in recombination to help convert recombination intermediates into viable products.     

Involvement of the recB-recC Nuclease (Exonuclease V) in the Process of X-Ray-Induced Deoxyribonucleic Acid Degradation in Radiosensitive Strains of Escherichia coli K-12

The ras, polA, exrA, recA, and uvrD3 strains of Escherichia coli K-12 degrade their deoxyribonucleic acid more extensively than wild-type strains after X irradiation. The relationship of the recB-recC nuclease (exonuclease V) to the degradation process in these strains was determined by comparing the degradation response of the original strains with that of strains containing an additional recB21 or recC22 mutation. The initial rate of degradation in ras, polA12, exrA, and recA13 strains after an exposure of 20 to 30 kR was reduced more than 10-fold by the presence of an additional recB21 or recC22 mutation. The extent of degradation in these irradiated strains after 90 to 120 min of incubation was reduced two- to fivefold. In the uvrD3 strain, a recC22 mutation caused a fourfold decrease in initial degradation rate and reduced the extent of degradation after 90 min of incubation by a factor of 1.6. The results are consistent with the statement that the degradation process is normally dependent on exonuclease V activity. However, the observation that 10 to 30% degradation always occurred even in recB or recC strains, which lack this enzyme, suggests that alternative degradation mechanisms exist.     

Phenotypic instability in a tif-1 mutant of Escherichia coli

Summary A recent study showed that in E. coli T44 () carrying the tif-1 mutation, elevated temperature and adenine can interfere with the translation process. The present study shows that the expression of tif phenotypes (thermoinduction and filamentation) is suppressed by factors which affect ribosomal function. Ethanol suppresses thermoinduction and, in some spc ^r mutants, both thermoinduction and filamentation are suppressed. An unknown factor(s) in yeast extract suppresses both thermoinduction and filamentation. In thermoresistant revertant (ts⁺), the expression of the ts⁺ phenotype is suppressed by yeast extract, ethanol, guanosine+cytidine and by the addition of a spc ^r mutation. This indicates that this phenotype could be due to suppressor mutations, and the interaction between factors affecting ribosomal function and the ts⁺ phenotype suggests that the suppression of tif in the ts⁺ strains could operate on the ribosomal level. In vitro studies show that in extracts from either spc ^r or ts⁺ strains, or in the presence of ethanol, translational restriction is relieved, suggesting that the suppression of tif phenotypes could involve the translation process.     

The segregation of the SbcA and Rac phenotypes in an Escherichia coli recB mutant

Summary In certain HfrxF^– recB ^– crosses recombinant progeny were examined for their SbcA and Rac phenotypes. Recombinants which inherited either his ⁺ or trp ⁺ from the donor in an Hfr recB21 sbcA8xF^– recB21 Rac^–SbcA⁺ cross acquired the RecB⁺ phenotype in most instances (presumably by inheriting the sbcA8 allele). Several independent Rec⁺ (sbcA8) recombinants from this cross were converted back to the Rec^– (sbcA ⁺) phenotype by mating with a Rac⁺ SbcA⁺ Hfr. Ten out of 14 of these Rec^– recombinants retained the Rac^– phenotype of the original parent. It was concluded that these results were inconsistent with the hypothesis that sbcA is a gene carried by a Rac prophage.     

Genetic analysis of the het and nif genes in the blue-green alga Nostoc muscorum

Summary Two multiply marked complementary strains namely Het ⁺ Nif⁺ Str-R and Het ^- Nif^- Ery-R MSO-R were constructed and crossed under conditions counterselective for the Het ⁺ Nif⁺ Str-R parent and selective only for recombinants of Str-R and Ery-R or Str-R and MSO-R constitution. The results of the recombinant analysis with regard to the selected and unselected markers suggested that the Het ^- Nif^- Ery-R MSO-R parent acted as a recipient and the Het ⁺ Nif⁺ Str-R parent as donor of the genetic markers in the cross. The joint inheritance of Het ⁺ and Nif ⁺ unselected markers among the recombinants was found to occur more frequently than the inheritance of the Het ⁺ or Nif ⁺ markers alone. The observed joint inheritance of Het ⁺ and Nif ⁺ markers among the recombinants probably results from the inheritance of the regulatory gene(s) required for the activation of latent het and nif genes. This interpretation is fully supported by (a) the frequency distribution of unselected Het ⁺ and Nif ⁺ markers and (b) the reversion frequency of Het ^- Nif ^- strains to Het ⁺ Nif⁺ prototrophy. Accordingly the apparent close genetic linkage of het and nif genes is not due to their organization in a single operon but to their common regulation by regulatory gene(s) of a positive control nature. The Het ⁺ Nif⁺ wild type, mutant, revertant, and recombinant strains all appear similar in their NO ₃ ^- repression of both heterocyst and nitrogenase. The Het ⁺ Nif^- and Het ^- Nif⁺ recominants also show similar NO ₃ ^- repression of their heterocyst and nitrogenase respectively. The presence of only microaerobic acetylene reducing activity in Het ^- Nif⁺ recombinants clearly indicates the heterocyst to be an organ for protection of nitrogenase against oxygen toxicity.Abbreviations CFU Colony forming units - Ery erythromycin - Ery-R erythromycin resistance - het genotypic designation of genes required for heterocyst differentiation - Het phenotype designation of genes required for heterocyst differentiation - MSO l-Methionine-dl-sulfoximine - MSO-R MSO-resistance - N₂ medium Chu 10 medium without combined nitrogen - NH ₄ ⁺ medium basic mineral medium with ammonium nitrogen - nif genotype designation of genes required for N₂ fixation - Nif phenotype designation of genes required for N₂ fixation - NO ₃ ^- medium Chu 10 medium supplemented with KNO₃ - NTG N-methyl-N-nitro-N-nitrosoguanidine - r gene(s) regulatory gene(s) - Str streptomycin - Str-R streptomycin resistance - Str-S streptomycin sensitive     

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

Summary F-prime heterogenotes of dam-3 bacteria segregate F-prime homogenotes at a frequency 30–200 times higher than the isogenic dam ⁺ strain. A hyperrecombination mutant which shows increased recombination between chromosomal duplications was characterized as a dam mutant. The dam-3 allele causes a reduction in linkage of proximal unselected markers in transconjugants and increases the recombination frequency between a pair of closely linked markers. It is concluded that dam mutations confer a hyperrecombination phenotype to the cell.     

Properties of strains of Escherichia coli K12 carrying mutant lex and rec alleles

Summary Strains of Escherichia coli K12 have been constructed which carry the lex-3 mutation in combination with recA56, recB21, or recC22. The lex ^– recA ^–strain is equally as sensitive to ultraviolet light (UV) and ionizing radiation and as recombination-deficient as the corresponding lex ⁺ recA ^–strain, whereas the lex ^– recB ^–and lex ^– recC ^–strains are somewhat more sensitive to UV and ionizing radiation than the corresponding lex ^– rec ⁺strain and have approximately the same recombination deficiencies as the respective lex ⁺ recB ^–and Lex ⁺ recC ^–strains. When cultures of the lex ^– recB ^–and lex ^–recC^–strains are UV-irradiated, they degrade their DNA at the low rate characteristic of lex ⁺ recB ^–and lex ⁺ recC ^–single mutants, in contrast to the high rate of degradation seen with lex ^– rec ⁺single mutants.These results imply that the lex ⁺and recA ⁺products act in the same pathway of DNA repair and that both are needed to limit the DNA breakdown due to the recB ⁺/C⁺nuclease.     

Isolation of a formamidopyrimidine-DNA glycosylase (fpg) mutant of Escherichia coli K12

Summary The fpg ⁺ gene of Escherichia coli coding for formamidopyrimidine-DNA glycosylase was previously cloned on a multicopy plasmid. The plasmid copy of the fpg ⁺ gene was inactivated by cloning a kanamycin resistance gene into the open reading frame, yielding the fpg-1:: Kn^r mutation. This mutation was transferred to the chromosome in the following steps: (i) linearization of the plasmid bearing the fpg-1::Kn^r mutation and transformation of competent bacteria (recB recC sbcB); (ii) selection for chromosomal integration of the fpg-1::Kn^r mutation; (iii) phage P1 mediated transduction of the fpg-1::Kn^r mutation in the AB1157 background. The resulting fpg ^- mutant exhibited no detectable Fapy-DNA glycosylase activity in crude lysates. The insertion mutation was localized by means of genetic crosses between mtl and pyrE, at 81.7 min on the E. coli linkage map. Sequence analysis confirmed this mapping and further showed that fpg is adjacent to rpmBG in the order fpg, rpmGB, pyrE. The formamidopyrimidine-DNA glycosylase defective strain does not show unusual sensitivity to the following DNA damaging treatments: (i) methylmethanesulfonate, (ii) N-methyl-N-nitro-N-nitrosoguanidine, (iii) ultraviolet light, (iv) -radiation. The fpg gene is neither part of the SOS regulon nor the adaptive response to alkylating agents.     

Identification of the recR locus of Escherichia coli K-12 and analysis of its role in recombination and DNA repair

Summary A new recombination gene called recR has been identified and located near dnaZ at minute 11 on the current linkage map of Escherichia coli. The gene was detected after transposon mutagenesis of a recB sbcB sbcC strain and screening for insertion mutants that had a reduced efficiency of recombination in Hfr crosses. The recR insertions obtained conferred a recombination deficient and extremely UV sensitive phenotype in both recB recC sbcA and recB recC sbcB sbcC genetic backgrounds. recR derivatives of recBC ⁺ sbc ⁺ strains were proficient in conjugational and transductional recombination but deficient in plasmid recombination and sensitive to UV light. Strains carrying recR insertions combined with mutations uvrA and other rec genes revealed that the gene is involved in a recombinational process of DNA repair that relies also on recF and recO, and possibly recJ, but which is independent of recB, recC and recD. The properties of two other insertions, one located near pyrE and the other near guaA, are discussed in relation to their proximity to recG and xse (the gene for exonuclease VII), respectively.     

Exonucleases I, III, and V are required for stability of ColE1-related plasmids in Escherichia coli.

The stability of two ColE1-related plasmids (pRSF2124 and pMB9) was examined in strains of Escherichia coli multiply deficient in exonucleases I (sbcB), III (xthA), or V (recB recC). Any combination of exonuclease I, III, and V deficiency resulted in dramatically decreased stability of both pRSF2124 and pMB9. Inactivation of the RecF pathway by introducing either recF or recJ mutations to the recB recC subcB background resulted in nearly wild-type levels of stability for both plasmids. In contrast, the introduction of uvrD3 uvr-257, uvrE100, or recL152 into the recB21 recC22 sbcB15 strain did not affect plasmid stability. Furthermore, the amount of plasmid DNA recovered from pRSF2124 or pMB9 transformants of a xthA1 sbcB15 strain was strikingly reduced relative to that of a wild-type control. Taken together, these results suggest that some aspect of DNA repair is required for stable maintenance of ColE1-related plasmids in E. coli.     

Complementation studies with the repair-deficient uvrD3, uvrE156, and recL152 mutations in Escherichia coli

Summary Previous work showed that the mutations uvrD3, uvrE156, and recL152 were closely linked and increased UV-sensitivity. They were phenotypically distinguishable in that only the uvrD3 mutation significantly decreases host cell reactivation of UV-irradiated phage (Hcr^-) and repair of methylmethane sulfonate (MMS)-induced damage, and only the uvrE156 mutation increased mutation rates (Mut^-). MMS-resistant revertants of a uvrD3 mutant were still UV-sensitive and fell into two phenotypic classes, Hcr^- Mut⁺ (non-mutator) and Hcr⁺ Mut^-. In this work complementation tests were done by examining UV-and MMS-sensitivity and host cell reactivation in heterogenotes containing combinations of uvrD3, uvrE156, recL152, and the MMS-resistant mutations derived from uvrD3. The mutations could not complement each other in the repair of UV-damage, the one trait all had in common, indicating that they were in one gene. For the most part, the different mutations were able to complement each other in respect to traits in which one was deficient and the other had wild type activity.     

Intrachromosomal recombination between direct repeats in Penicillium chrysogenum : gene conversion and deletion events

Recombination between direct repeats has been studied in Penicillium chrysogenum using strain TD7-88 (lys⁻ pyr⁺), which contains two inactive copies of the lys2 gene separated by 4.5 kb of DNA (including the pyrG gene) in its genome. Gene conversion leading to products with the lys⁺ pyr⁺ phenotype was observed at a frequency of 1 in 3.2 × 10³ viable spores. Two types of deletion events giving rise to lys⁺ pyr⁻ and lys⁻ pyr⁻ phenotypes were obtained with different frequencies. Southern analysis revealed that gene conversion occurs mainly as a result of crossing over events that remove the BamHI frameshift mutation present in one of the repeats. In lys⁻ pyr⁻ recombinants, the deletion events do not affect the frameshift mutation in the BamHI site, while lys⁺ pyr⁻ recombinants showed repair of the BamHI frameshift mutation and the genotype of the parental non-disrupted strain was restored. In summary, deletion events in P. chrysogenum tend to favor the restoration of the phenotype and genotype characteristic of the parental non-disrupted strain. Received: 9 November 1998 / Accepted: 14 April 1999     

Isolation of Hem3 mutants from Candida albicans by sequential gene disruption

Summary Molecular methods for directed mutagenesis in Candida albicans have relied on a combination of gene disruption by transformation to inactivate one allele and UV-induced mitotic recombination or point mutation to produce lesions in the second allele. An alternate method which uses two sequential gene disruptions was developed and used to construct a C. albicans mutant defective in a gene essential for synthesizing tetrapyrrole (uroporphyrinogen I synthase). The Candida gene was cloned from a random library by complementation of the hem3 mutation in Saccharomyces cerevisiae. The complementing region was limited to a 2.0 kb fragment by subcloning and a BglII site was determined to be within an essential region. Linear fragments containing either the Candida URA3 or LEU2 gene inserted into the BglII site were used to disrupt both alleles of a leu2, ura3 mutant by sequential transformation. Ura⁺, Leu⁺ heme-requiring strains were recovered and identified as hem3 mutants by Southern hybridization, transformation to heme independence by the cloned gene, and enzyme assays.     

Kinetics of recA function in conjugational recombinant formation.

Summary Genetic recombination was studied in F^- strains of E. coli carrying a mutation (recA200) that confers a thermosensitive Rec^- phenotype. Recombination during Hfr matings at 35C was monitored by raising the temperature of incubation to 42C at various intervals so that only merozygotes that had completed those functions dependent on the activity of the recA gene product could form recombinant progeny. The results indicated that no more than 1–2% of the merozygotes present while mating was in progress were able to form recombinant colonies at 42C. Separation of mating pairs reduced the yield of recombinants obtained at 35C by 50 to 200-fold if plating on agar medium was delayed for 15–30min by continuing incubation in broth medium. recA200 merozygotes that were also recB21 sbcB15 proved relatively stable when plating was delayed in this manner, which suggested that Hfr DNA is prone to exonuclease inactivation in recA200 merozygotes after mating pairs have separated. Post-mating incubation in high salt medium or on agar plates promoted the recovery of recombinants at 35C. However, the majority of recA200 merozygotes did not acquire the ability to form recombinant colonies at 42C under these more stable conditions until mating pairs had been separated and incubation continued at 35C for 40–60 min. It was concluded that recA200 strains are partially defective for recombination even at low temperature but that terminating mating promotes the recovery of recombinants. A mechanism involving the stimulation of RecA activity by mating pair separation is postulated to account for the efficient recovery of recombinants from HfrxF^- recA200 crosses at 35C.     

Strand targeting signal(s) for in vivo mutation avoidance by post-replication mismatch repair in Escherichia coli

Summary The involvement of GATC sites in directing mismatch correction for the elimination of replication errors in Escherichia coli was investigated in vivo by analyzing mutation rates for a gene carried on a series of related plasmids that contain 2, 1 and 0 such sites. This gene encoding chloramphenicol acetyl transferase (Cat protein) was inactivated by a point mutation. In vivo mutations restoring resistance to chloramphenicol were scored in mismatch repair proficient (mut ⁺) and deficient (mutHLS^-) strains. In mut ⁺ cells, reduction of GATC sites from 2 to 0 increased mutation rates approximately 10-fold. Removal of the GATC site distal to the cat ^- mutation increased the rate of mutation less than 2-fold, indicating that mismatch repair can proceed normally with a single site. The mutation rate increased 3-fold after removal of the GATC site proximal to the mutation. In the absence of a GATC site, mutL^- and mutS^- strains exhibited a 2- to 3-fold increased mutation rate as compared to isogenic mutH^- and mut ⁺ strains. This indicates that 50%–70% of replication errors can be corrected in a mutLS-dependent way in the absence of any GATC site to target mismatch correction to newly synthesized DNA strands. Other strand targeting signals, possibly single strand discontinuities, might be used in mutLS-dependent repair     

Directed transposon Tn5 mutagenesis and complementation in slow-growing, broad host range cowpea Rhizobium

Summary Site-directed Tn5 mutagenesis by gene replacement method, via homologous recombination, was used to identify symbiotically essential regions in the genome of cowpea Rhizobium spp. IRc78. Transposon insertions with-in the nifK hybridizing region or in the regions spanning 10 kb downstream of the nifK have revealed the presence of functional genes required for nitrogen fixation. Six single Tn5 insertions resulted in nod⁺ fix^– phenotypes and one in nod⁺ but reduced fix⁺ phenotype. All seven Tn5 insertions were stable before, during and after plant passage. However, IRc78 transconjugants containing duplicated nif copies, (a normal and a Tn5 inserted copy separated by vector sequences) were unstable. In five IRc78::Tn5 strains, the mutant phenotypes were corrected by an extrachromosomally stable vector containing wild type nif alleles. Our experiments suggest that the correction to nod⁺ fix⁺ phenotype is by complementation although correction by recombination cannot be completely excluded.     

New mutations in cloned Escherichia coli umuDC genes: Novel phenotypes of strains carrying a umuC125 plasmid

The umuDC locus of Escherichia coli is required for most mutagenesis by UV and many chemicals. Mutations in E. coli umuDC genes cloned on pBR322-derived plasmids wer e isolated by two methods. First, spontaneously-arising mutant umuDC plasmids that failed to confe cold-sensitive growth on a lexA51(Def) strain were isolated by selection. Second, mutant umuDC plasmids that affected apparent mutant yield after UV-irradiation in a strain carrying umuD⁺C⁺ in the chromosome were isolated by screening hydroxylamine-mutagenized umuD⁺C⁺ plasmids. pBR322-derived umuD⁺C⁺ plasmids inhibited the induction of the SOS response of lexA⁺ strains as measured by expression of din::Mu dl(lac) Ap) fusionsbut most mutant plasmids did not. Mutant plasmids defective in complementation of chromosomal umuD44, umuC36, or both were found among those selected for failure to confer cold-sensitivity, whereas those identified by the screening procedure yielded mostly mutant plasmids with more complex phenotypes. We studied in greater detail a plasmid pLM109, carrying the umuC125 mutation. This plasmid increased the sensitivity of lexA⁺ strainsto killing by UV-irradiation but was able to complement the deficiencies of umuC mutants in UV mutagenesis. pLM109 failed to confer cold-sensitive growth on lexA(Def) strains but inhibited SOS induction in lexA⁺ strains. The effect of pLM109 on the UV sensitivity of lexA(Def)strains was similar to that of the parental umuD⁺C⁺ plasmid. The mutation responsible for the phenotypes of pLM109 was localized to a 615-bp fragment. DNA sequencing revealed that the umuC125mutation was a G:C → A:T transition that changed codon 39 of umuC from GCC → GTC thus changing Ala39 to Val39. The implications of the umuC125 mutation for umuDC-dependent effects on UV-mutagenesis and cell survival after UV damage are discussed.