Uracil-DNA glycosylase affects mismatch repair efficiency in transformation and bisulfite-induced mutagenesis in Streptococcus pneumoniae

Dynamics of Mismatch and Alternative Excision-Dependent Repair in Replicating Bacillus subtilis DNA Examined Under Conditions of Neutral Selection

Spontaneous DNA deamination is a potential source of transition mutations. In Bacillus subtilis, EndoV, a component of the alternative excision repair pathway (AER), counteracts the mutagenicity of base deamination-induced mispairs. Here, we report that the mismatch repair (MMR) system, MutSL, prevents the harmful effects of HNO2, a deaminating agent of Cytosine (C), Adenine (A), and Guanine (G). Using Maximum Depth Sequencing (MDS), which measures mutagenesis under conditions of neutral selection, in B. subtilis strains proficient or deficient in MutSL and/or EndoV, revealed asymmetric and heterogeneous patterns of mutations in both DNA template strands. While the lagging template strand showed a higher frequency of C → T substitutions; G → A mutations, occurred more frequently in the leading template strand in different genetic backgrounds. In summary, our results unveiled a role for MutSL in preventing the deleterious effects of base deamination and uncovered differential patterns of base deamination processing by the AER and MMR systems that are influenced by the sequence context and the replicating DNA strand.

Processing of abasic site damaged lesions by APE1 enzyme on DNA adsorbed over normal and organomodified clay

The efficiency of the apurinic/apyrimidinic endonuclease (APE1) DNA repair enzyme in the processing of abasic site DNA damage lesions at precise location in DNA oligomer duplexes that are adsorbed on clay surfaces was evaluated. Three different forms of clay namely montmorillonite, quaternary ammonium salt modified montmorillonite and its boiled counterpart i.e. partially devoid of organic moiety were used for a comparative study of adsorption, desorption and DNA repair efficiency on their surfaces. The interaction between the DNA and the clay was analysed by X-ray diffraction, Atomic force microscopy, UV-Vis spectroscopy and Infrared spectroscopy. The abasic site cleavage efficiency of APE1 enzyme was quantitatively evaluated by polyacrylamide gel electrophoresis. Apart from the difference in the DNA adsorption or desorption capacity of the various forms of clay, substantial variation in the repair efficiency of abasic sites initiated by the APE1 enzyme on the clay surfaces was observed. The incision efficiency of APE1 enzyme at abasic sites was found to be greatly diminished, when the DNA was adsorbed over organomodified montmorillonite. The reduced repair activity indicates an important role of the pendant surfactant groups on the clay surfaces in directing APE1 mediated cleavage of abasic site DNA damage lesions.

Cloning and expression of pneumococcal genes in Streptococcus pneumoniae

An overview of gene cloning in Streptococcus pneumoniae is presented. The advantages of such cloning, especially for pneumococcal genes, are enumerated. The molecular fate of DNA in transformation of S. pneumoniae, in particular, the conversion of DNA to single-strand segments on entry, determines the mechanisms for plasmid establishment and interaction with the chromosome. One of these mechanisms, the chromosomal facilitation of plasmid establishment, is useful for obtaining recombinant plasmids and for introducing an allele from the chromosome into a plasmid. The difference between linear and circular synapsis of donor DNA strands with the chromosome is illustrated. Circular synapsis can give rise to circular integration, which is useful for insertional mutagenesis of chromosomal genes, for coupled cloning in Escherichia coli, and for sequential cloning of DNA along the pneumococcal chromosome. Cloning in S. pneumoniae is not notably affected by DNA mismatch repair or restriction systems in the host cell. Unusual features of gene expression in S. pneumoniae are discussed. Transcription begins most often at promoters with extended -10 sequences, and in a small but significant number of cases, translation does not require a ribosome-binding site with a Shine-Dalgarno sequence.

Gene targeting by linear duplex DNA frequently occurs by assimilation of a single strand that is subject to preferential mismatch correction

To study targeted recombination, a single linear 2-kb fragment of LEU2 DNA was liberated from a chromosomal site within the nucleus of Saccharomyces cerevisiae, by expression of the site-specific HO endonuclease. Gene targeting was scored by gene conversion of a chromosomal leu2 mutant allele by the liberated LEU2 fragment. This occurred at a frequency of only 2 x 10(-4), despite the fact that nearly all cells successfully repaired, by single-strand annealing, the chromosome break created by liberating the fragment. The frequency of Leu+ recombinants was 6- to 25-fold higher in pms1 strains lacking mismatch repair. In 70% of these cases, the colony was sectored for Leu+/Leu-. Similar results were obtained when a 4. 1-kb fragment containing adjacent LEU2 and ADE1 genes was liberated, to convert adjacent leu2 and ade1 mutations on the chromosome. These results suggest that a linear fragment is not assimilated into the recipient chromosome by two crossovers each close to the end of the fragment; rather, heteroduplex DNA between the fragment and the chromosome is apparently formed over the entire region, by the assimilation of one of the two strands of the linear duplex DNA. Moreover, the recovery of Leu+ transformants is frequently defeated by the cell's mismatch repair machinery; more than 85% of mismatches in heteroduplex DNA are corrected in favor of the resident, unbroken (mutant) strand.

Identification of mismatch repair genes and their role in the development of cancer

Mismatched base pairs are generated by damage to DNA, by damage to nucleotide precursors, by errors that occur during DNA replication, and during the formation of intermediates in genetic recombination. Enzyme systems that faithfully repair these DNA aberrations have been identified in a wide variety of organisms. At lease some of the components of these repair systems have been conserved, both structurally and functionally, throughout evolutionary time. In humans, defective mismatch repair genes have been linked to hereditary nonpolyposis colon cancer as well as to sporadic cancers that exhibit length polmorphisms in simple repeat (microsatellite) DNA sequences. The involvement of mismatch repair defects in microsatellite instability and tumorigenesis suggests that a generalized mutator phenotype is responsible for the large number of genetic alterations observed in tumors.

Defective transformation of chromosomal markers in DNA polymerase I mutants of the radioresistant bacterium Deinococcus radiodurans

The transformation efficiency of six independently selected chromosomal markers (four for rifampicin resistance and two for acriflavine resistance) was found to be reduced by about 3 logs in a Deinococcus radiodurans strain that was isogenic with wild type except for an insertional mutation in the pol gene that eliminated DNA polymerase I activity (strain 6R1A). D. radiodurans strains UV17 and 303, previously obtained by chemical mutagenesis, were determined to be partially deficient in DNA Pol I activity as assessed in a permeabilized cell system. Both UV17 and 303 demonstrated intermediate transforming efficiencies that correlated with their levels of residual polymerase activity. The transformation efficiency of strain 6R1A could be greatly restored by expression of cloned E. coli DNA Pol I, but not to wild-type levels. Plasmid transfer and chromosomal duplication insertion were not substantially affected by lack of DNA Pol I activity. D. radiodurans is known to possess extraordinarily efficient repair pathways for DNA damage, and is refractory to DNA damage-induced mutagenesis caused by numerous agents, including several that cause base mispairing. We suggest that D. radiodurans may differ from other naturally transformable bacteria in that DNA Pol I is needed to efficiently convert most drug-resistance markers. This unusual mechanism may be required to accomplish chromosomal conversion prior to correction of donor DNA by this organism's efficient repair pathways.

Characterization of the mutX gene of Streptococcus pneumoniae as a homologue of Escherichia coli mutT, and tentative definition of a catalytic domain of the dGTP pyrophosphohydrolases

We show that deletion of a gene of Streptococcus pneumoniae, which we call mutX, confers a mutator phenotype to resistance to streptomycin. Analysis of the DNA sequence changes that occurred in several streptomycin-resistant mutants showed that mutations are unidirectional AT to CG transversions. The mutX gene is located immediately downstream of the previously identified ung gene and genetic evidence suggests that the two genes are co-ordinately regulated. Nucleotide sequence determination reveals that the mutX gene encodes a 17,870 Da protein (154 residues) which exhibits significant homology with the MutT protein of Escherichia coli, a nucleoside triphosphatase (dGTP pyrophosphohydrolase). The mutX gene complements the E. coli mutT mutator phenotype when introduced on a plasmid. Site-directed mutagenesis and analysis of nitrosoguanidine-induced mutT mutants suggest that a small region of high homology between the two proteins (61% identity over 23 residues) is part of the catalytic site of the nucleoside triphosphatase. Computer searching for sequence homology to MutX uncovered a second E. coli protein, the product of orf17, a gene of unknown function located near the ruvC gene. The region of high homology between MutX and MutT is also conserved in this protein, which raises the interesting possibility that the orf17 gene plays some role in determining mutation rates in E. coli. Finally, a small set of proteins, including a family of virus-encoded proteins and two evolutionarily conserved proteins encoded by an antisense transcript from the Xenopus laevis and human bFGF genes, were also found to harbour significant homology to this highly conserved region.

Physical and genetic map of the chromosome of Lactococcus lactis subsp. lactis IL1403

A combined physical and genetic map of the chromosome of Lactococcus lactis subsp. lactis IL1403 was determined. We constructed a restriction map for the NotI, ApaI, and SmaI enzymes. The order of the restriction fragments was determined by using the randomly integrative plasmid pRL1 and by performing indirect end-labeling experiments. The strain IL1403 chromosome was found to be circular and 2,420 kb in size. A total of 24 chromosomal markers were mapped on the chromosome by performing hybridization experiments with gene probes for L. lactis and various other bacteria. Integration of pRC1-derived plasmids via homologous recombination allowed more precise location of some lactococcal genes and allowed us to determine the orientation of these genes on the chromosome. Recurrent sequences, such as insertion elements and rRNA gene (rrn) clusters, were also mapped. At least seven copies of IS1076 were present and were located on 50% of the chromosome. In contrast, no copy of ISS1RS was detected. Six ribosomal operons were found on the strain IL1403 chromosome; five were located on 16% of the chromosome and were transcribed in the same direction. A comparison of the physical maps of L. lactis subsp. lactis IL1403 and DL11 showed that these two strains are closely related and that the variable regions are located mainly near the rrn gene clusters. In contrast, despite major restriction pattern dissimilarities between L. lactis IL1403 and MG1363, the overall genetic organization of the genome seems to be conserved between these two strains.