DNA ligases in the repair and replication of DNA

DNA ligases are critical enzymes of DNA metabolism. The reaction they catalyse (the joining of nicked DNA) is required in DNA replication and in DNA repair pathways that require the re-synthesis of DNA.Most organisms express DNA ligases powered by ATP, but eubacteria appear to be unique in having ligases driven by NAD(+). Interestingly, despite protein sequence and biochemical differences between the two classes of ligase, the structure of the adenylation domain is remarkably similar. Higher organisms express a variety of different ligases, which appear to be targetted to specific functions. DNA ligase I is required for Okazaki fragment joining and some repair pathways; DNA ligase II appears to be a degradation product of ligase III; DNA ligase III has several isoforms, which are involved in repair and recombination and DNA ligase IV is necessary for V(D)J recombination and non-homologous end-joining. Sequence and structural analysis of DNA ligases has shown that these enzymes are built around a common catalytic core, which is likely to be similar in three-dimensional structure to that of T7-bacteriophage ligase. The differences between the various ligases are likely to be mediated by regions outside of this common core, the structures of which are not known. Therefore, the determination of these structures, along with the structures of ligases bound to substrate DNAs and partner proteins ought to be seen as a priority.     

Rate of DNA replication in the DNA synthetic period of the barley chromosomes

The rate of DNA replication, as judged by H³-thymidine incorporation, at the specific time of the S-period in chromosomes of barley (Hakata No. 2) is studied by means of autoradiography.In the barley chromosomes, two different DNA units with respect to replication-time are distinguishable. The early replicating DNA is replicated at least within 1 hour ab init. of the S-period, and the late replicating DNA within 1/2 to 1 hour before the end of the S-period. The replication scarcely occurs in the middle of the S-period. These evidences suggest that the replication of chromosomal DNA in the present material does, therefore, not proceed in a continuous time sequence. Topographically, the early replicating DNA is almost confined exclusively to the distal regions of the chromosomes 1 and 5, and this situation seems applicable to other chromosomes as well, whereas the late replicating DNA is close to the centromere on its both sides. Hence, the replication of chromosomal DNA does not proceed uniformly in a longitudinal sequence along the chromosomes. The interrelationships among chromosome structure in its cytological expression, replication -pattern and -time of chromosomes, and regulating mechanisms of DNA replication are discussed.     

DNA length-dependent cooperative interactions in the binding of Ku to DNA

Despite its central role in the nonhomologous DNA end joining process, we still have an incomplete picture of the interaction between Ku and DNA. Here we describe both kinetic (surface plasmon resonance or SPR) and equilibrium (electrophoretic mobility shift assay or EMSA) studies of Ku binding to linear double-stranded DNA. Ku interaction with 1-site DNA is noncooperative, as expected. Electrophoretic mobility shift assays indicate cooperativity in the binding of Ku molecules to DNA long enough for two Ku molecules to bind (2-site DNA). For the kinetic studies, we use surface plasmon resonance in which one end of the DNA molecules is linked to a surface while the other end is free to interact with Ku. We find that one Ku molecule dissociates from 1-site DNA with simple Langmuir (i.e., independent) kinetics. However, two Ku molecules associate and dissociate from 2-site DNA with a time course that cannot be described as a simple Langmuir interaction. On 3- and 4-site DNA, EMSA and SPR studies do not reveal any cooperativity, suggesting that the middle Ku does not exhibit cooperative interaction with the two Ku molecules bound at the DNA ends. These results indicate that Ku molecules can demonstrate cooperative interaction, and this is influenced by their positions along the DNA.     

DNA synthesis at a fork in the presence of DNA helicases

In a mixture of Escherichia coli DNA polymerase III holoenzyme, single-strand-binding protein, artificially forked lambda bacteriophage DNA with primer annealed to the leading side of the fork, dNTPs and ATP, DNA synthesis is enhanced by helicase II, less so by helicases, I, III or rep protein of E. coli or T4 phage helicase. The effect of helicase II depends on ATP, it is enhanced by helicase III, and it is not observed using DNA polymerase I or T4 DNA polymerase. In the absence of dNTPs helicase II is less active than helicase I or T4 helicase in unwinding the forked DNA. We believe that helicase II both shifts the forks and stimulates DNA polymerase III. The results support the conclusion derived from previous studies that helicase II is part of the DNA-synthesizing system of E. coli.     

DNA methylation and the frequency of CpG in animal DNA.

An analysis of nearest neighbour dinucleotide frequencies and the level of DNA methylation in animals strongly supports the suggestion that 5-methylcytosine (5mC) tends to mutate abnormally frequently to T. This tendency is the likely cause of the CpG deficiency in heavily methylated genomes.     

Activation of the DNA damage checkpoint in mutants defective in DNA replication initiation

In the fission yeast, Schizosaccharomyces pombe, blocks to DNA replication elongation trigger the intra-S phase checkpoint that leads to the activation of the Cds1 kinase. Cds1 is required to both prevent premature entry into mitosis and to stabilize paused replication forks. Interestingly, although Cds1 is essential to maintain the viability of mutants defective in DNA replication elongation, mutants defective in DNA replication initiation require the Chk1 kinase. This suggests that defects in DNA replication initiation can lead to activation of the DNA damage checkpoint independent of the intra-S phase checkpoint. This might result from reduced origin firing that leads to an increase in replication fork stalling or replication fork collapse that activates the G2 DNA damage checkpoint. We refer to the Chk1-dependent, Cds1-independent phenotype as the rid phenotype (for replication initiation defective). Chk1 is active in rid mutants, and rid mutant viability is dependent on the DNA damage checkpoint, and surprisingly Mrc1, a protein required for activation of Cds1. Mutations in Mrc1 that prevent activation of Cds1 have no effect on its ability to support rid mutant viability, suggesting that Mrc1 has a checkpoint-independent role in maintaining the viability of mutants defective in DNA replication initiation.     

Retrotransfer of DNA in the rhizosphere

Retrotransfer of DNA refers to the phenomenon by which a plasmid travels from a host strain to a recipient one and returns to the original host, bringing with it DNA from the recipient. The resultant host strain with DNA from the recipient is called a retrotransconjugant. The retrotransfer phenomenon mediated by the TOL plasmid pWW0 and other plasmids has been documented on plates under optimal laboratory culture conditions, but never under natural conditions. In this work, we show that retrotransfer mediated by the IncP9 TOL pWW0 plasmid occurs in the rhizosphere, a niche in which the continuous supply of nutrients via root exudates allows cells to reach a high density. This suggests that this unusual sexual fertilization may be of great importance in lateral gene transfer. We also show that retrotransfer of DNA seems to require co-integration of the plasmid and the host chromosome and subsequent resolution, because a TOL plasmid with a mutation in the tnpR gene, encoding the resolvase of the Tn 4653 of the TOL plasmid, was self-transferred between Pseudomonas strains, but unable to mobilize chromosome.     

DNA methylation reprogramming and DNA repair in the mouse zygote

Here, we summarize current knowledge about epigenetic reprogramming during mammalian preimplantation development, as well as the potential mechanisms driving these processes. We will particularly focus on changes taking place in the zygote, where the paternally derived DNA and chromatin undergo the most striking alterations, such as replacement of protamines by histones, histone modifications and active DNA demethylation. The putative mechanisms of active paternal DNA demethylation have been studied for over a decade, accumulating a lot of circumstantial evidence for enzymatic activities provided by the oocyte, protection of the maternal genome against such activities and possible involvement of DNA repair. We will discuss the various facets of dynamic epigenetic changes related to DNA methylation with an emphasis on the putative involvement of DNA repair in DNA demethylation.     

Investigating the effects of the presence of foreign DNA on DNA methylation and DNA repair events in cultured eukaryotic cells

Methylation of DNA in eukaryotic cells, global as well as gene-specific, is affected by endogenous and endogenous factors. In this paper, it is reported that deviations in DNA methylation and expression of genes involved in DNA repair and the cell cycle are affected in 143B cultured cells containing an expression vector. Global DNA methylation analysis with cytosine-extension assay revealed a decreased global DNA methylation in the presence of the expression vector. Less promoter-specific methylation, as measured by bisulfite-MS PCR, was observed for MGMT and p16INK4a in vector-containing cells. Comet assay investigations revealed a negative effect on the DNA repair capacity of both BER and NER in Complex III compromised cells. This was reflected in the down-regulation of hOGG1 and ERCC1 expression. The results presented in this paper support the existence of a strong relationship between impaired mitochondrial function and deviations in DNA methylation and extend this relationship to impaired DNA repair.     

DNA Repair Mechanisms and the Bypass of DNA Damage in Saccharomyces cerevisiae

DNA repair mechanisms are critical for maintaining the integrity of genomic DNA, and their loss is associated with cancer predisposition syndromes. Studies in Saccharomyces cerevisiae have played a central role in elucidating the highly conserved mechanisms that promote eukaryotic genome stability. This review will focus on repair mechanisms that involve excision of a single strand from duplex DNA with the intact, complementary strand serving as a template to fill the resulting gap. These mechanisms are of two general types: those that remove damage from DNA and those that repair errors made during DNA synthesis. The major DNA-damage repair pathways are base excision repair and nucleotide excision repair, which, in the most simple terms, are distinguished by the extent of single-strand DNA removed together with the lesion. Mistakes made by DNA polymerases are corrected by the mismatch repair pathway, which also corrects mismatches generated when single strands of non-identical duplexes are exchanged during homologous recombination. In addition to the true repair pathways, the postreplication repair pathway allows lesions or structural aberrations that block replicative DNA polymerases to be tolerated. There are two bypass mechanisms: an error-free mechanism that involves a switch to an undamaged template for synthesis past the lesion and an error-prone mechanism that utilizes specialized translesion synthesis DNA polymerases to directly synthesize DNA across the lesion. A high level of functional redundancy exists among the pathways that deal with lesions, which minimizes the detrimental effects of endogenous and exogenous DNA damage.     

Rates of DNA Duplication and Mitochondrial DNA Insertion in the Human Genome

The hundreds of mitochondrial pseudogenes in the human nuclear genome sequence (numts) constitute an excellent system for studying and dating DNA duplications and insertions. These pseudogenes are associated with many complete mitochondrial genome sequences and through those with a good fossil record. By comparing individual numts with primate and other mammalian mitochondrial genome sequences, we estimate that these numts arose continuously over the last 58 million years. Our pairwise comparisons between numts suggest that most human numts arose from different mitochondrial insertion events and not by DNA duplication within the nuclear genome. The nuclear genome appears to accumulate mtDNA insertions at a rate high enough to predict within-population polymorphism for the presence/absence of many recent mtDNA insertions. Pairwise analysis of numts and their flanking DNA produces an estimate for the DNA duplication rate in humans of 2.2 × 10^–9 per numt per year. Thus, a nucleotide site is about as likely to be involved in a duplication event as it is to change by point substitution. This estimate of the rate of DNA duplication of noncoding DNA is based on sequences that are not in duplication hotspots, and is close to the rate reported for functional genes in other species.     

DNA polymerase epsilon: the latest member in the family of mammalian DNA polymerases

DNA polymerase epsilon is a mammalian polymerase that has a tightly associated 3'----5' exonuclease activity. Because of this readily detectable exonuclease activity, the enzyme has been regarded as a form of DNA polymerase delta, an enzyme which, together with DNA polymerase alpha, is in all probability required for the replication of chromosomal DNA. Recently, it was discovered that DNA polymerase epsilon is both catalytically and structurally distinct from DNA polymerase delta. The most striking difference between the two DNA polymerases is that processive DNA synthesis by DNA polymerase delta is dependent on proliferating cell nuclear antigen (PCNA), a replication factor, while DNA polymerase epsilon is inherently processive. DNA polymerase epsilon is required at least for the repair synthesis of UV-damaged DNA. DNA polymerases are highly conserved in eukaryotic cells. Mammalian DNA polymerases alpha, delta and epsilon are counterparts of yeast DNA polymerases I, III and II, respectively. Like DNA polymerases I and III, DNA polymerase II is also essential for the viability of cells, which suggests that DNA polymerase II (and epsilon) may play a role in DNA replication.     

Nature of the single-stranded DNA in replicating adenovirus type 5 DNA.

Single-stranded regions in replicating adenovirus type 5 DNA were isolated and hybridized in solution to the separated strands of adenovirus 2 or 5 DNA. The results showed that the two strands of adenovirus 5 DNA are exposed to almost the same extent during replication, suggesting that displacement synthesis may start from either end of the viral DNA.     

Endophytic fungal DNA, the source of contamination in spruce needle DNA

DNA isolated and amplified from higher plants may originate from symbiotic microbes occupying plant tissues. A recent report on the phylogeny of Picea contained sequence data that upon later analysis proved to originate from filamentous ascomycetes. Isolates of endophytic fungi from Picea foliage collected from the same location as the original samples were examined to identify the source of the contaminating DNA. The ITS region of isolates was screened by Southern blotting using an oligonucleotide probe homologous to a unique portion of the reported 'spruce' sequences. This study identifies a DNA sequence originally attributed to Picea engelmannii (Engelmann spruce) as Hormonema dematioides , a ubiquitous foliar endophyte of conifers. Infections of plants by endophytic fungi are common and their presence is not revealed by external symptoms. Plant molecular researchers should be aware of the potential for this type of DNA contamination.     

Termination of vitro DNA synthesis at AAF adducts in the DNA.

DNA synthesis catalyzed by E. coli polymerases I or III is inhibited on templates containing N-acetoxy-acetylaminofluorene-reacted adducts. Termination of synthesis occurs just before the site of the adduct. Synthesis on 0X174 templates primed with restriction fragments and treated with AAAF can be visualized on DNA sequencing gels. Comparison of the amounts of the different newly synthesized fragments with those calculated from the probability of termination as determined from the average number of adducts per molecule shows that synthesis terminates, rather than stutters, at each adduct. This method may be useful for detecting the bypass of lesions.