DNA repair in Bacillus subtilis: excision repair capacity of competent cells.

Competent Bacillus subtilis were investigated for their ability to support the repair of UV-irradiated bacteriophage and bacteriophage DNA. UV-irradiated bacteriophage DNA cannot be repaired to the same level as UV-irradiated bacteriophage, suggesting a deficiency in the ability of competent cells to repair UV damage. However, competent cells were as repair proficient as noncompetent cells in their ability to repair irradiated bacteriophage in marker rescue experiments. The increased sensitivity of irradiated DNA is shown to be due to the inability of excision repair to function on transfecting DNA in competent bacteria. Furthermore, competent cells show no evidence of possessing an inducible BsuR restriction system to complement their inducible BsuR modification enzyme.     

Transfection of Bacillus subtilis protoplasts by bacteriophage phi do7 DNA.

DNA from the Bacillus subtilis temperate bacteriophage phi do7 was found to efficiently transfect B. subtilis protoplasts; protoplast transfection was more efficient than competent cell transfection by a magnitude of 10(3). Unlike competent cell transfection, protoplast transfection did not require primary recombination, suggesting that phi do7 DNA enters the protoplast as double-stranded molecules.     

Postreplication repair of ultraviolet-irradiated transforming deoxyribonucleic acid in Bacillus subtilis

Repair of ultraviolet-irradiated transforming deoxyriboinucleic acid (DNA) in several strains of Bacillus subtilis was studied in order to determine the effects of excision repair and postreplication repair on transformation. Two mutations that cause a Uvr- and phenotype (uvr-1 and uvr-42) were shown to have strikingly different effects on repair of ultraviolet-irradiated transforming DNA. Genetic and kinetic evidence is presented to show that integrated DNA was apparently repaired by both excision and postreplication repair in wild-type and in uvr-1 recipients, although the latter excise pyrimidine dimers very slowly. In uvr-42 mutants, which are defective in incision at pyrimidine dimers, dimer-containing DNA was integrated. Postreplication repair apparently saved uvr-42 recipient cells from the lethal effects of integrated dimers, but the recombination events accompanying postreplication repair greatly reduced the linkage between closely linked genetic markers in the donor DNA. Repair of transforming DNA in a recG recipient, which does excision repair but not postreplication repair, was nearly as efficient as in wild-type cells. However, in this recipient linkage was altered only slightly, if at all, compared with wild-type cells. The apparent reduction in size of integrated regions of ultraviolet-irradiation transforming DNA probably results mainly from postreplication repair of larger integrated regions.     

Interactions of homologous and heterologous deoxyribonucleic acids and competent Bacillus subtilis cells.

Glucosylated and nonglucosylated bacteriophage T4 deoxyribonucleic acids (DNAs) are able to bind to competent cells of Bacillus subtilis, although the former does so in a rather unstable fashion, probably because of the glucosylation. Several heterologous DNAs compete with homologous DNA for the same receptors in binding and in transformation. A different pattern in competition for DNA binding was observed for homologous and T4 glucosylated DNAs in intact cells as compared with protoplasts or membrane vesicles. The results are consistent with the existence of two types of receptor sites on the membrane of competent B. subtilis cells.     

Transformation of a Bacillus subtilis L-form with bacteriophage deoxyribonucleic acid.

A stable L-form, sal-1, of Bacillus subtilis was transformed with deoxyribonucleic acid (DNA) from bacteriophages phi 25 and phi 29 to determine whether exogenous DNA can be introduced into this organism. The viral transformation (transfection) was successful with the use of polyethylene glycol. In the presence of the fusogen, bacteriophage phi 25 DNA initiated a single cycle of infection. When compared with transfection of competent cells of Bacillus subtilis, the appearance of viral particles was delayed and their production occurred over a longer time period. L-form cells were best able to support intracellular replication of phi 25 viral particles when in balanced growth in a rich medium. The addition of polyethylene glycol also induced infection of sal-1 with whole bacteriophage phi 25 particles which could not otherwise infect the L-form and enhanced infection by intact phi 29 particles. Primary recombination was shown to be required for polyethylene glycol-mediated phi 25 transfection, but not phi 29 transfection or for whole bacteriophage phi 25 infection mediated by polyethylene glycol. Successful transfection of sal-1 suggests that the L-form may be amenable to genetic modification with exogenous DNA.     

Excision repair of ultraviolet-irradiated deoxyribonucleic acid in plasmolyzed cells of Escherichia coli.

A system of cells made permeable by treatment with high concentrations of surcrose (plasmolysis) has been exploited to study the excision repair of ultraviolet-irradiated deoxyribonucleic acid in Escherichia coli. It is demonstrated that adenosine 5'-triphosphate is required for incision breaks to be made in the bacterial chromosome as well as in covalently closed bacteriophage lambda deoxyribonucleic acid. After plasmolysis, uvrC mutant strains appear as defective in the incision step as the uvrA-mutated strains. This is in contrast to the situation in intact cells where uvrC mutants accumulate single-strand breaks during postirradiation incubation. These observations have led to the proposal of a model for excision repair, in which the ultraviolet-specific endonuclease, coded for by the uvrA and uvrB genes, exists in a complex with the uvrC gene product. The complex is responsible for the incision and possibly also the excision steps of repair. The dark-repair inhibitors acriflavine and caffeine are both shown to interfere with the action of the adenosine 5'-triphosphate-dependent enzyme.     

Effect of lysogeny on transfection and transfection enhancement in Bacillus subtilis.

Strains of Bacillus subtilis 168 lysogenic for bacteriophage phi105 transfer with deoxyribonucleic acid (DNA) isolated from bacteriophage SPO2 at a higher efficiency than non-lysogenic strains. This enhancement of transfection was not the result of recombination between bacteriophages SPO2 and phi105. Superinfection marker rescue increased transfection with DNA from bacteriophage phi105 occurred simultaneously with the addition of the transfecting DNA. Again, this enhancement of transfection was not the result of recombination but rather a protection of the transfecting DNA by the superinfecting bacteriophage. The ability of the superinfecting bacteriophage to protect the transfecting DNA from inactivation was maximal when the bacteria were just becoming competent. Bacteriophage phi1 cannot replicate after the transfection of competent bacteria lacking a functional DNA replication system, whereas bacteriophage phi1 was able to replicate after infection of competent bacteria grown under comparable conditions. These observations support the hypothesis that GAPase and an inducible repair system play an important role in the development of competence.     

Effect of deoxyribonucleic acid replication inhibitors on bacterial recombination.

Two inhibitors of replicative deoxyribonucleic acid (DNA) synthesis, nalidixic acid (NAL) and 6-(p-hydroxyphenylazo)-uracil (HPUra), showed different effects on genetic recombination and DNA repair in Bacillus subtilis. Previous work (Pedrini et al., 1972) showed that NAL does not interfere with the transformation process of B. subtilis. The results reported in this work demonstrated that the drug was also without effect on the transfection by SPP1 or SPO-1 phage DNA (a process that requires a recombination event). The drug was also ineffective on the host cell reactivation of ultraviolet-irradiated SPP1 phage, as well as on transfection with ultraviolet-irradiated DNA of the same phage. HPUra instead markedly reduced the transformation process, as well as transfection, by SPO-1 DNA, but it did not affect the host cell reactivation of SPO-1 phage. In conclusion, whereas the NAL target seems to be specific for replicative DNA synthesis, the HPUra target (i.e., the DNA polymerase III of B. subtilis) seems to be involved also in recombination, but not in the excision repair process. The mutations conferring NAL and HPUra resistance used in this work were mapped by PBS-1 transduction.     

Transformation and transfection in lysogenic strains of Bacillus subtilis: evidence for selective induction of prophage in competent cells.

Lysogenic strains of Bacillus subtilis 168 were reduced in their level of transformation as compared to non-lysogenic strains. The level of transformation decreased even further if the competent lysogenic cells were allowed to incubate in growth media prior to selection on minimal agar. This reduction in the frequency of transformation was attributable to the selective elimination of transformed lysogenic cells from the competent population. Concurrent with the decrease in the number of transformants from a lysogenic competent population was the release of bacteriophage by these cells. The lysogenic bacteria demonstrated this dramatic release of bacteriophage only if the cells were grown to competence. Both the selective elimination of transformed lysogens and the induction of prophage was prevented by the inhibition of protein synthesis. Additionally, competent lysogenic cells released significantly higher amounts of exogenous donor transforming deoxyribonucleic acid than did competent non-lysogenic cells or competent lysogenic cells incubated with erythromycin. These data establish that the induction of the prophage from the competent lysogenic cells was responsible for the selective elmination of the lysogenic transformants. A model is presented that accounts for the induction of the prophage from competent lysogenic bacteria via the induction of a repair system. It is postulated that a repair system is induced or derepressed by the accumulation of gaps in the chromosomes of competent bacteria. This hypothetical enzyme(s) is ultimately responsible for the induction of the prophage and the selective elimination of transformants.     

Protoplast transformation of glutamate-producing bacteria with plasmid DNA

A method for polyethylene glycol-induced protoplast transformation of glutamate-producing bacteria with plasmid DNA was established. Protoplasts were prepared from cells grown in the presence of penicillin by treatment with lysozyme in a hypertonic medium. The concentration of penicillin during growth affected the efficiency of formation, regeneration, and polyethylene glycol-induced DNA uptake of protoplasts. Regeneration of protoplasts was accomplished on a hypertonic agar medium containing sodium succinate and yeast extract. The spectinomycin and streptomycin resistance plasmid pCG4, originally from Corynebacterium glutamicum T250, could transform various glutamate-producing bacteria such as C. glutamicum, Corynebacterium herculis, Brevibacterium flavum, and Microbacterium ammoniaphilum. The plasmid was structurally unchanged and stably maintained in new hosts. The transformation frequency of most competent protoplasts with pCG4 DNA isolated from primary transformants was high (ca. 10(6) transformants per microgram of covalently closed circular DNA) but was still two orders of magnitude below the frequency of transfection with modified DNA of the bacteriophage phi CGI. The difference was ascribed to the involvement of regeneration in transformation.     

Construction of improved bacteriophage phi 105 vectors for cloning by transfection in Bacillus subtilis

A series of improved phage vectors have been constructed, based on Bacillus subtilis bacteriophage phi 105, which can be used to clone genes in B. subtilis by direct transfection of protoplasts. The new vectors, designated phi 105J23, phi 105J24, phi 105J27 and phi 105J28, show frequencies of plaque formation that are equal to those of wild-type phi 105. This represents at least a 10-fold improvement over phi 105J9, the vector used in previous cloning experiments. Two of the new vectors phi 105J27 and phi 105J28 incorporate a mutation, cts-52, that renders the prophage temperature inducible. This has made it possible to devise a rapid small-scale procedure for screening progeny phage for the presence of inserted DNA. The usefulness of the new vectors is illustrated in the accompanying paper by cloning more than 20 B. subtilis sporulation genes.     

Genetic Recombination of Transforming Deoxyribonucleic Acid Molecules with the Recipient Genome and Among Themselves in Protoplasts of Bacillus subtilis

Hirokawa, Hideo (Southwest Center for Advanced Studies, Dallas, Tex.), and Yonosuke Ikeda. Genetic recombination of transforming deoxyribonucleic acid molecules with the recipient genome and among themselves in protoplasts of Bacillus subtilis. J. Bacteriol. 92:455-463. 1966.-Re-extraction of transforming deoxyribonucleic acid (DNA) from protoplasts of Bacillus subtilis is much more efficient than from intact competent cells. This facilitated the detection of physical recombination between donor and recipient DNA molecules, as indicated by a high cotransfer index of ind(+) and his(+) markers which were originally located in exogenous and endogenous DNA molecules, respectively. This recombinant DNA was extracted after 30 min of incubation of ind his(+) protoplasts with ind(+)his DNA, previously extracted from a corresponding mutant strain of B. subtilis. The intracellular formation of recombinant molecules (ind(+)his(+)) bearing markers from two different exogenous DNA species was also detected 15 min after exposure of ind his recipient protoplasts to a mixture of ind(+)his and ind his(+) donor DNA molecules. The unity of the recombinant molecule was ascertained by dilution experiments and by its being resistant to ribonuclease and trypsin treatment (but being sensitive to deoxyribonuclease). The formation of recombinant molecules showed an inverse kinetics to that of the intracellularly induced loss of linkage between the corresponding markers in the wild-type DNA, thus suggesting a breakage and reunion process which is also favored by the absence of DNA synthesis in the protoplasts and the effect of some specific inhibitors.     

Evidence for circular permutation of the prophage genome of Bacillus subtilis bacteriophage phi 105.

Analysis of DNA extracted from Bacillus subtilis lysogenic for bacteriophage phi 105 was performed by restriction endonuclease digestion and Southern hybridization using mature phi 105 DNA as a probe. The data revealed that the phi 105 prophage is circularly permuted. Digests using the enzymes EcoRI, SmaI, PstI, and HindIII localized the bacteriophage attachment site (att) to a region 63.4 to 65.7% from the left end of the mature bacteriophage genome. The phi 105 att site-containing SmaI C, PstI J, and HindIII L fragments were not present in digests of phi 105 prophage DNA. phi 105-homologous "junction" fragments were visualized by probing digests of prophage DNA with the purified PstI J fragment isolated from the mature bacteriophage genome. The excision of the phi 105 prophage was detected by observing the appearance of the mature PstI J fragment and the concomitant disappearance of a junction fragment during the course of prophage induction.     

Sensitivity of carcinogen-treated DNA to inactivation by ultraviolet radiation

The DNA of bacteriophage SPO2c12 was treated with methylmethane sulfonate (MMS), beta-propiolactone (BPL), 2-anthramine (AA) or benzo[a]pyrene (BP) and then exposed to 254-nm radiation. Competent Bacillus subtilis host cells were transfected with DNA subjected to the carcinogen-UV treatment or with DNA treated with carcinogen only. Survival curves were obtained for loss of plaque-forming ability as a function of UV dose. The UV sensitivity of DNA treated with MMS, BPL or AA was not significantly different from that of untreated DNA. The results indicate that in competent B. subtilis the pathways for repair of alkylating agent damage and for repair of UV damage are probably different.     

Studies on transfection and transformation of protoplasts of Bacillus larvae, Bacillus subtilis, and Bacillus popilliae

Protoplasts of Bacillus larvae NRRL b-3555 and Bacillus subtilis RM125 (restrictionless, modificationless mutant) were transfected with DNA from the B. larvae bacteriophage PBL1c in the presence of polyethylene glycol. B. subtilis 168 and Bacillus popilliae NRRL B-2309M protoplasts could not be transfected with PBL1c DNA. Protoplasts of B larvae NRRL B-3555 were transformed with plasmids pC194 and pHV33 in the presence of polyethylene glycol. The frequency of transformation was much higher when the plasmids were isolated from B. larvae NRRL B-3555 transformants than when they were isolated from B. subtilis 168. These results indicate that the restriction-modification systems found in B. larvae NRRL B-3555 and B. subtilis 168 may be different. Conditions for protoplast formation and cell wall regeneration were developed for B. popilliae NRRL B-2309S. However, no transformation occurred with plasmids pC194 and pHV33 (isolated from B. subtilis 168).     

Morphology and Physiology of the Intracellular Development of Bacillus subtilis Bacteriophage φ25

The morphology of the intracellular development of bacteriophage phi25 in Bacillus subtilis 168M has been correlated with nucleic acid synthesis in infected cells. Host deoxyribonucleic acid (DNA) synthesis was shut off by a phage-induced enzyme within 5 min after infection, and another phage-mediated function extensively degraded host DNA at the time of cell lysis. Synthesis of phage DNA in infected cells began within 5 min and continued until late in the rise period. After phage DNA synthesis and coinciding with lysis, much of the unpackaged, newly synthesized phage DNA was degraded. Studies of thin sections of phi25 infected cells suggested that unfilled capsids may be precursors to filled capsids in the packaging process. To assess dependence of capsid formation on phage DNA replication, cells were either treated with mitomycin C and infected with normal phage or infected with ultraviolet-irradiated (99% killed) phi25. Only empty capsids were found in these cells, indicating that capsid production may be independent of the presence of newly synthesized viral DNA.     

Studies on transfection and transformation of protoplasts of Bacillus larvae, Bacillus subtilis, and Bacillus popilliae.

Protoplasts of Bacillus larvae NRRL b-3555 and Bacillus subtilis RM125 (restrictionless, modificationless mutant) were transfected with DNA from the B. larvae bacteriophage PBL1c in the presence of polyethylene glycol. B. subtilis 168 and Bacillus popilliae NRRL B-2309M protoplasts could not be transfected with PBL1c DNA. Protoplasts of B larvae NRRL B-3555 were transformed with plasmids pC194 and pHV33 in the presence of polyethylene glycol. The frequency of transformation was much higher when the plasmids were isolated from B. larvae NRRL B-3555 transformants than when they were isolated from B. subtilis 168. These results indicate that the restriction-modification systems found in B. larvae NRRL B-3555 and B. subtilis 168 may be different. Conditions for protoplast formation and cell wall regeneration were developed for B. popilliae NRRL B-2309S. However, no transformation occurred with plasmids pC194 and pHV33 (isolated from B. subtilis 168).     

DNA polymerase activity in a repair-deficient human cell line

A human low-density-lipoprotein (LDL) receptor-deficient diploid fibroblast cell line (GM1915) was determined to be short patch competent (DNA polymerase-beta) and long patch deficient (DNA polymerase-alpha) for DNA excision repair. Analysis of DNA from GM1915 cells or from WI38 control cells, following treatment with a mutagen known to initiate long patch excision repair, showed that GM1915 cells exhibited decreased resynthesis of oligonucleotide segments excised during repair. When cells deficient in DNA polymerase-alpha activity were permeabilized to permit LDL entry, repair synthesis immediately increased. These data suggest that DNA polymerase-alpha is not activated by mutagen treatment in GM1915 cells and that introduction of LDL into the cells results in activation of the enzyme.     

Repair of U.V. damages in Bacillus subtilis cultures competent for transformation: difference between competent and non-competent fractions.

The repair of U.V. damages to DNA in B. subtilis cultures competent for genetic transformation has been studied. The comparison of survival curves for competent and non competent fractions shows that: i) excision repair is more effective in competent than in non competent bacteria; ii) recombination repair is more effective in non competent than in competent bacteria. These facts support the hypothesis that metabolic conditions and, very likely, DNA replication play a role in the regulation of the efficiency of the two different mechanisms of repair.