Identification of temperature-sensitive dnaD mutants of Staphylococcus aureus that are defective in chromosomal DNA replication

The DnaD protein in Gram-positive bacteria is thought to be essential for the initiation step in DNA replication. In the present study, we characterized two Staphylococcus aureus mutants whose temperature-sensitive growth phenotype could be complemented by a plasmid carrying the dnaD gene. These mutants each had a single amino acid substitution in the DnaD protein and showed decreased DNA synthesis at restrictive temperature. Analyses of the origin to terminus ratio by Southern blotting, and of origin numbers per cell by flow cytometry, revealed that, at the restrictive temperature, one mutant continued ongoing DNA replication but failed to initiate DNA replication. The other mutant, in contrast, could not complete ongoing DNA replication and proceeded to degrade the chromosome. However, if protein synthesis was inhibited, the second mutant could complete DNA replication. These results suggest that DnaD protein is necessary not only for the initiation step, but also to avoid replication fork blockage. Moreover, both mutants were sensitive to mitomycin C, a drug that induces DNA damage, suggesting that the DnaD protein is also involved in DNA repair.Communicated by H. Ikeda     

Fate of plasmid DNA in transformation of Bacillus subtilis protoplasts

Summary Polyethylene glycol-treated protoplasts of B. subtilis can be transformed by plasmid DNA at very high frequencies (Chang and Cohen 1979). From analysis of plasmid mediated transformation of transformation-deficient mutants it appeared that mutants, reduced in the transformation by plasmid DNA in the competent state, were plasmid transformation-proficient when transformed as protoplasts. By means of CsCl-gradient centrifugation of re-extracted plasmid DNA it could be demonstrated that plasmid DNA enters the protoplasts in the double-stranded form. In addition, sucrose gradient centrifugation of the re-extracted plasmid DNA showed that the entered DNA is predominantly present as covalently closed circular DNA. The efficiency of plasmid transformation in protoplasts was found to be close to one (each plasmid molecule having entered into the protoplasts gives rise to a transformed cell). This is in good agreement with the observation that little, if any, damage is done to this DNA during or after entry into protoplasts.     

Gene recombination in X-ray-sensitive hamster cells.

Recombination was measured in Chinese hamster ovary (CHO-K1) cells and in the X-ray-sensitive mutants xrs1 and xrs7, which show a defect in DNA double-strand break repair. To assay recombination, pairs of derivatives of the plasmid pSV2gpt were constructed with nonoverlapping deletions in the gpt gene region and cotransferred into the different cell types. Recombination efficiencies, measured as the transformation frequency with a pair of deletion plasmids relative to that with the complete pSV2gpt plasmid, were about 6% in both CHO-K1 and the xrs mutants for plasmids linearized at a site outside the gpt gene. However, these efficiencies were substantially enhanced by the introduction of a double-strand break into the homologous region of the gpt gene in one of a pair of deletion plasmids before cotransfer. This enhancement was apparently only about half as great for the xrs cells as for CHO-K1, but variation in the data was considerable. A much larger difference between CHO-K1 and the xrs mutants was found when the DNA concentration dependence of transformation was explored. While the transformation frequency of CHO-K1 increased linearly with DNA concentration, no such increase occurred with the xrs mutants irrespective of whether complete plasmids or pairs of deletion plasmids were transferred. The fraction of cells taking up DNA, assayed autoradiographically, was similar in all cell types. Therefore we suggest that while homologous recombination of plasmid molecules may not be substantially reduced in the xrs mutants,processes involved in the stable integration of plasmid DNA into genomic DNA are significantly impaired.     

Cloning and characterization of mutL and mutS genes of Vibrio cholerae: nucleotide sequence of the mutL gene.

The mutL and mutS genes of Vibrio cholerae have been identified using interspecific complementation of Escherichia coli mutL and mutS mutants with plasmids containing the gene bank of V. cholerae. The recombinant plasmid pJT470, containing a 4.7 kb fragment of V. cholerae DNA codes for a protein of molecular weight 92,000. The product of this gene reduces the spontaneous mutation frequency of the E. coli mutS mutant. The plasmid, designated pJT250, containing a 2.5 kb DNA fragment of V. cholerae and coding for a protein of molecular weight 62,000, complements the mutL gene function of E. coli mutL mutants. These gene products are involved in the repair of mismatches in DNA. The complete nucleotide sequence of mutL gene of V. cholerae has been determined.     

An inverse PCR technique to rapidly isolate the flanking DNA of Dictyostelium insertion mutants

Restriction enzyme mediated integration is a widely used and effective method for insertional mutagenesis in Dictyostelium discoideum. In this method, plasmid rescue is used to clone the genomic deoxyribonucleic acid (DNA) sequences that flank the insertion site. For this to be effective, it is necessary to first find a convenient restriction enzyme site within the genomic DNA. This is a time-consuming process that requires Southern blot analysis of the mutant DNA. In addition, plasmid rescue requires transformation into highly competent Escherichia coli. Problems can arise owing to unstable genomic sequences, damage to the plasmid DNA and exogenous plasmid contamination. We have established a simple and rapid polymerase chain reaction-based technique that works for all mutants and circumvents the need for Southern blot analysis and plasmid rescue.     

Rapid construction of sequencing templates by random insertion of antibiotic resistance genes

We describe a novel and handy method for generating a population of templates for sequencing. The method is based on the random insertion of antibiotic resistance gene in plasmid DNA digested by DNase I. The advantages of this approach are the small quantity of DNA necessary for mutagenesis and the complete independence from the restriction map of the plasmid. DNase I digestion provides a random distribution of the insertions, while antibiotic selection provides low background. We also present a convenient PCR-based procedure for the analysis and ordering of obtained insertion mutants.     

Molecular cloning and characterization of a Streptococcus sanguis DNase necessary for repair of DNA damage induced by UV light and methyl methanesulfonate.

We developed a method for cloning cellular nucleases from streptococci. Recombinant lambda gt11 bacteriophage containing streptococcal nuclease determinants were identified by the production of pink plaques on toluidine blue O DNase plates. We used this technique to clone a 3.2-kilobase-pair EcoRI fragment with DNase activity from the chromosome of Streptococcus sanguis. The locus was designated don (DNase one) and could be subcloned and stably maintained on plasmid vectors in Escherichia coli. Minicell analyses of various subclones of the don locus allowed us to determine the coding region and size of the Don nuclease in E. coli. The don gene product had an apparent molecular mass of 34 kilodaltons and degraded native DNA most efficiently, with lesser activity against denatured DNA and no detectable activity against RNA. S. sanguis don deletion mutants were constructed by transformation of competent cells with in vitro-prepared plasmid constructs. S. sanguis don deletion mutants retained normal transformation frequencies for exogenously added donor DNA. However, when compared with Don+ wild-type cells, these mutants were hypersensitive to DNA damage induced by UV light and methyl methanesulfonate. An S. sanguis don-specific DNA probe detected homology to chromosomal DNA isolated from Streptococcus pneumoniae and Streptococcus mutans Bratthall serogroups d and g. Our results suggested that the don locus was the S. sanguis allele of the previously described S. pneumoniae major exonuclease and was involved in repair of DNA damage. Furthermore, hybridization studies suggested that the don locus was conserved among species of oral streptococci.     

Concatemer formation of ColE1-type plasmids in mutants of Escherichia coli lacking RNase H activity

rnh mutants harboring pBR322 were found to contain several slowly migrating DNA species when examined by agarose gel electrophoresis. The plasmid DNA from rnh mutants included large molecules, i.e. plasmids two, three or four times the size of a single plasmid unit. That this DNA contained concatemeric plasmid joined in a head-to-tail fashion was determined by digestion with restriction endonucleases that cleaved the monomeric plasmid DNA at a unique site. This treatment resulted in migration of the plasmid DNA at a mobility identical to that of linearized monomeric plasmid by agarose gel electrophoresis. This was confirmed by electron microscopy. Plasmid concatemer formation was detected with several high-copy-number (relaxed type) plasmids but not with low-copy-number (stringent) plasmids. Concatemer formation was dependent on RecA+ and RecF+ functions since several recA and recF mutations abolished concatemer formation. ColE1-type plasmids were previously shown to replicate in rnh mutants in the absence of DNA polymerase I (PolI) activity. This DNA PolI-independent plasmid replication was also examined for its dependence on the recF and recA gene products. rnh- polA(Ts) recF- strains were efficiently transformed with these plasmids at 30 degrees C and 42 degrees C, indicating the presence of DNA PolI-independent replication under recF- conditions. The presence or absence of plasmid replication in rnh- polA- recA(Ts) strains was also examined by measuring the increase in total amounts of plasmid. The results indicated that DNA PolI-independent replication occurred in these triple mutants at 42 degrees C as well as at 30 degrees C. It was concluded that the recombination event giving rise to concatemer formation was not essential for DNA PolI-independent replication in rnh mutants.     

Effect of the molecular weight of DNA on the effectiveness of plasmid transformation of E. coli K12

The level of plasmid transformation and transfection by the high molecular mass DNA was studied for Escherichia coli mutants having increased efficiency of plasmid transformation by low molecular mass DNA. Decreased level of plasmid transformation and transfection registered in some mutants as compared to the one in wild type strain suggests the specificity of Escherichia coli cells penetration for DNA of different molecular mass.     

The spectrum of mutations generated by passage of a hydrogen peroxide damaged shuttle vector plasmid through a mammalian host.

Treatment of a plasmid shuttle vector (pZ189) with a combination of hydrogen peroxide and a ferric iron/EDTA complex prior to transfection and passage in simian (CV-1) cells increases the frequency of mutations at the supF locus by up to 60-fold over the spontaneous background. This increase in mutation frequency is abolished when the inhibitors desferrioxamine, superoxide dismutase, catalase or dimethyl sulfoxide are included in the initial reaction or when the iron/EDTA complex is omitted, a strong indication that the premutagenic damage arises as a result of direct attack by hydroxyl radical generated in a superoxide driven Fenton reaction. DNA sequence analysis of the mutated plasmids shows that 1) Deletions occuring in combination with base-substitutions arise in 22.5 percent of the induced mutants compared with only 3 percent of spontaneous mutants 2) Sixty percent of all induced deletion mutations involve the loss of a single base and 77 percent of these (20 out of 26) occur at two adenine-containing sites 3) The base-change spectrum of mutants arising in the treated plasmid population is marked by the predominance of mutants containing a single base-change and by an increase in changes at AT base pairs. These results provide direct information concerning the nature of mutations arising in mammalian cells as a result of hydroxyl radical mediated DNA damage.     

Repair of UV-irradiated plasmid DNA in mutants of Saccharomyces cerevisiae and Escherichia coli deficient in repair of pyrimidine dimers

The repair of in vitro UV-irradiated DNA of plasmid pBB29 was studied in excision defective yeast mutants rad1, rad2, rad3, rad4, rad10 and in Escherichia coli mutants uvr- and recA-, by measuring the cell transformation frequency. Rad2, rad3, rad4, and rad10 mutants could repair plasmid DNA despite their inability to repair nuclear DNA, whereas the reduced ability of rad1 mutant for plasmid DNA repair demonstrated alone the same dependence on the host functions that are needed for nuclear DNA repair. In E. coli the repair of UV-irradiated plasmid DNA is carried out only by the excision-repair system dependent on uvr genes. Treatment of UV-irradiated plasmid DNA with UV endonuclease from Micrococcus luteus greatly enhances the efficiency of transformation of E. coli uvr- mutants. Similar treatment with cell-free extracts of yeast rad1 mutant or wild-type strains as well as with nuclease BaL31, despite their ability for preferential cutting of UV damaged DNA, showed no influence on cell transformation.     

Activation of the DNA damage checkpoint in yeast lacking the histone chaperone anti-silencing function 1

The packaging of the eukaryotic genome into chromatin is likely to be important for the maintenance of genomic integrity. Chromatin structures are assembled onto newly synthesized DNA by the action of chromatin assembly factors, including anti-silencing function 1 (ASF1). To investigate the role of chromatin structure in the maintenance of genomic integrity, we examined budding yeast lacking the histone chaperone Asf1p. We found that yeast lacking Asf1p accumulate in metaphase of the cell cycle due to activation of the DNA damage checkpoint. Furthermore, yeast lacking Asf1p are highly sensitive to mutations in DNA polymerase alpha and to DNA replicational stresses. Although yeast lacking Asf1p do complete DNA replication, they have greatly elevated rates of DNA damage occurring during DNA replication, as indicated by spontaneous Ddc2p-green fluorescent protein foci. The presence of elevated levels of spontaneous DNA damage in asf1 mutants is due to increased DNA damage, rather than the failure to repair double-strand DNA breaks, because asf1 mutants are fully functional for double-strand DNA repair. Our data indicate that the altered chromatin structure in asf1 mutants leads to elevated rates of spontaneous recombination, mutation, and DNA damage foci formation arising during DNA replication, which in turn activates cell cycle checkpoints that respond to DNA damage.     

Inefficient replication reduces RecA-mediated repair of UV-damaged plasmids introduced into competent Escherichia coli

Transformation of Escherichia coli with purified plasmids containing DNA damage is frequently used as a tool to characterize repair pathways that operate on chromosomes. In this study, we used an assay that allowed us to quantify plasmid survival and to compare how efficiently various repair pathways operate on plasmid DNA introduced into cells relative to their efficiency on chromosomal DNA. We observed distinct differences between the mechanisms operating on the transforming plasmid DNA and the chromosome. An average of one UV-induced lesion was sufficient to inactivate ColE1-based plasmids introduced into nucleotide excision repair mutants, suggesting an essential role for repair on newly introduced plasmid DNA. By contrast, the absence of RecA, RecF, RecBC, RecG, or RuvAB had a minimal effect on the survival of the transforming plasmid DNA containing UV-induced damage. Neither the presence of an endogenous homologous plasmid nor the induction of the SOS response enhanced the survival of transforming plasmids. Using two-dimensional agarose-gel analysis, both replication- and RecA-dependent structures that were observed on established, endogenous plasmids following UV-irradiation, failed to form on UV-irradiated plasmids introduced into E. coli. We interpret these observations to suggest that the lack of RecA-mediated survival is likely to be due to inefficient replication that occurs when plasmids are initially introduced into cells, rather than to the plasmid's size, the absence of homologous sequences, or levels of recA expression.     

Effect of DNA topology on plasmid DNA repair in vivo

Escherichia coli nucleotide excision repair (NER) is responsible for removing bulky DNA adducts by dual incisions of the UvrABC endonuclease. Although the activity of the UvrAB complex which can induce DNA conformational change is employed in NER, the involvement of DNA topology and DNA topoisomerases remains unclear. We examined the effect of topoisomerase inhibitions on a NER in vivo system. The repair analysis of intracellular plasmid revealed that the DNA damage on positive supercoils generated by gyrase inhibition remained unrepaired, whereas the DNA damage was repaired in topoisomerase I mutants. These results suggest that DNA topology affects the NER process and the removal of positive supercoils by gyrase is vital for the efficiency of the E. coli NER system.     

Temperature-Sensitive Mutants for the Replication of Plasmids in ESCHERICHIA COLI II. Properties of Host and Plasmid Mutations

Host mutations in Escherichia coli K12 selected for the temperature-sensitive replication of the bacterial plasmid colicinogenic factor E(1) (ColE(1)) exhibit a pleiotropic effect with respect to the effect of the mutation on other extra-chromosomal elements. The mutations also vary with respect to the time of incubation of the cells at 43 degrees C required for complete cessation of ColE(1) DNA synthesis. While the synthesis of the bacterial chromosome appears unaffected, supercoiled ColE(1) DNA replication stops immediately in some mutants and gradually decreases during several generations of cell growth before stopping in others. Mutations isolated in the ColE(1) plasmid resulted in only a gradual cessation of ColE(1) DNA synthesis over several generations of cell growth at 43 degrees C. Conjugal transfer of the ColE(1) and ColV factors occurs normally in the host mutants when the transfer is carried out at the permissive temperature; however, the presence of a group I mutation in the donor cell prohibited conjugal transfer of either plasmid DNA at 43 degrees C to a normal recipient cell. Similarly, the presence of this mutation in the recipient prevented the establishment of ColE(1) or ColV in the mutant recipient cell upon conjugation with a normal donor at 43 degrees C. Various host ColE(1) replication mutants carrying either ColE(1) or ColE(2) were also defective in the mitomycin C-induced production of colicin E(1) or colicin E(2) at 43 degrees C. The majority of the host mutations examined exhibited a temperature sensitivity to growth in deoxycholate in addition to the inhibition of plasmid DNA replication, suggesting a membrane alteration in these mutants when grown at the restrictive temperature.     

Repair of a double-stranded gap in plasmid DNA in radiosensitive mutants of Saccharomyces cerevisiae: effectiveness and precision

The repair of a double strand gap in plasmid DNA in radiosensitive mutants of Saccharomyces cerevisiae has been studied. The proportion of repair events resulting in the complete doublestrand gap recovery of the plasmid DNA has been found to be close to 100% in Rad+ cells. The mutation rad55 did not interfere in the doublestrand gap repair efficiency and accuracy. The mutant rad57 is capable of the effective doublestrand gap repair without restoration of the DNA sequence deleted by the gap. The mutation rad53 substantially inhibited the efficiency of the doublestrand gap repair but did not influence the accuracy of the repair. Plasmid DNA doublestranded gap repair is completely blocked by mutations rad50 and rad54.     

Evaluation of the database on mutant frequencies and DNA sequence alterations of vermilion mutations induced in germ cells of Drosophila shows the importance of a neutral mutation detection system

The vermilion gene in Drosophila has extensively been used for the molecular analysis of mutations induced by chemicals in germ cells in vivo. The gene is located on the X-chromosome and is a useful target for the study of mutagenesis since all types of mutations are generated. We have critically evaluated this system with respect to sensitivity for mutation induction and selectivity for different types of mutations, using a database of more than 600 vermilion mutants induced in postmeiotic male germ cells by 18 mutagens. From most of these mutants the mutation has been analysed. These data showed 336 base substitutions, 96 intra-locus DNA rearrangements and 78 multi-locus deletions (MLD). Mutants containing a MLD were either heterozygous sterile or homozygous and hemizygous lethal. The distribution of both basepair (bp) changes and intra-locus rearrangements over the coding region of the vermilion gene was uniform with no preferences concerning 5' or 3' regions, certain exons, splice sites, specific amino acid changes or nonsense mutations. Possible hotspots for base substitutions seem to be related to the type of DNA damage rather than to the vermilion system. Gene mutations other than bp changes were examined on sequence characteristics flanking the deletion breakpoints. Induction frequencies of vermilion mosaic mutants were, in general, higher than those of vermilion complete mutants, suggesting that persistent lesions are the main contributors to the molecular spectra. Comparison of induction frequencies of vermilion mutants and sex-linked recessive lethal (SLRL) mutants for the 18 mutagens showed that the sensitivity of the vermilion gene against a mutagenic insult is representative for genes located on the X-chromosome. The effect of nucleotide excision repair (NER) on the formation of SLRL mutants correlated with an increase of transversions in the vermilion spectra under NER deficient conditions. Furthermore, the clastogenic potency of the mutagens, i.e., the efficiency to induce chromosomal-losses vs. SLRL forward mutations, shows a positive correlation with the percentage of DNA deletions in the molecular spectra of vermilion mutants.     

DNA damage is a late event in resveratrol-mediated inhibition of Escherichia coli

Resveratrol is an important phytoalexin notable for a wide variety of beneficial activities. Resveratrol has been reported to be active against various pathogenic bacteria. However, it is not clear at the molecular level how this important activity is manifested. Resveratrol has been reported to bind to cupric ions and reduce it. In the process, it generates copper-peroxide complex and reactive oxygen species (ROS). Due to this ability, resveratrol has been shown to cleave plasmid DNA in several studies. To this end, we envisaged DNA damage to play a role in resveratrol mediated inhibition in Escherichia coli. We employed DNA damage repair deficient mutants from keio collection to demonstrate the hypersensitive phenotype upon resveratrol treatment. Analysis of integrity and PCR efficiency of plasmid DNA from resveratrol-treated cells revealed significant DNA damage after 6?h or more compared to DNA from vehicle-treated cells. RAPD-PCR was performed to demonstrate the damage in genomic DNA from resveratrol-treated cells. In addition, in situ DNA damage was observed under fluorescence microscopy after resveratrol treatment. Further resveratrol treatment resulted in cell cycle arrest of significant fraction of population revealed by flow cytometry. However, a robust induction was not observed in phage induction assay and induction of DNA damage response genes quantified by promoter fused fluorescent tracker protein. These observations along with our previous observation that resveratrol induces membrane damage in E. coli at early time point reveal, DNA damage is a late event, occurring after a few hours of treatment.     

Streptococcus pneumoniae polA gene is expressed in Escherichia coli and can functionally substitute for the E. coli polA gene.

The Streptococcus pneumoniae polA+ gene was introduced into Escherichia coli on the recombinant plasmid pSM31, which is based on the pSC101 replicon. Extracts of E. coli polA5 mutants containing pSM31 showed DNA polymerase activity, indicating that the pneumococcal DNA polymerase I was expressed in the heterospecific host. Complete complementation of the E. coli polA5 mutation by the pneumococcal polA+ gene was detected in excision repair of DNA damage.     

Mutations predetermined by the primary structure of DNA

This study is concerned with an experimental verification of hypotheses postulating the involvement of self-complementary nucleotide sequences in the formation of deletions and insertions. It was suggested that deletions can arise in the regions of self-complementary nucleotide sequences, which allows the formation of the hairpin structures in a single-stranded DNA, arising during excision repair. These hairpin structures can be eliminated by nucleases or during DNA replication. Insertions can arise as a result of homologous recombination, when a migrating DNA strand contains a self-complementary sequence which forms hairpin structure. Model experiments were carried out with the pBR322 plasmid. A plasmid DNA with premutational damage in the palindrome-containing region was constructed by in vitro dimethylsulfate modification of one strand of EcoRI-BamHI restriction fragment. The plasmid was used for transformation of Escherichia coli. Restriction mapping and nucleotide analysis of the mutant DNAs demonstrated that they all contained deletions. The end points of the deletions coincide with the palindrome. To model homologous recombination, a plasmid with D-loop was constructed. A single-stranded DNA fragment containing palindrome forming a hairpin structure was introduced into the plasmid DNA and covalently fixed in the complex. When E. coli cells were transfected with this DNA, plasmid mutants containing insertions predetermined by palindromic structure arose. The evolutionary role of mutations predetermined by primary DNA structure is discussed.