EC:6.5.1.2 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

Query: EC:6.5.1.2 (DNA ligase)
2,749 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The functional compatibility of vaccinia virus DNA ligase with eukaryotic counterparts was demonstrated by its ability to complement Saccharomyces cerevisiae cdc9. The vaccinia DNA ligase is a 63 kDa protein expressed early during infection that is non-essential for virus DNA replication and recombination in cultured cells. This implies complementation by a mammalian DNA ligase, yet no obvious recruitment of host DNA ligase I from the nucleus to the cytoplasm was observed during infection. An antiserum raised against a peptide conserved in eukaryotic DNA ligases identified the virus enzyme in discrete cytoplasmic 'factories', the sites of virus DNA synthesis, demonstrating immunological cross-reactivity between host DNA ligase I and the vaccinia enzyme. DNA ligase was not detected in the factories of a mutant virus lacking the ligase gene. Despite this, no difference in growth between wild-type (WT) and mutant virus was detectable even in Bloom's syndrome cells which have reduced DNA ligase I activity. However, DNA ligase negative virus showed an increased sensitivity to UV or bleomycin in cultured cells, and the importance of DNA ligase for virus virulence in vivo was demonstrated by the attenuated phenotype of the deletion mutant in intranasally infected mice.
...
PMID:Vaccinia DNA ligase complements Saccharomyces cerevisiae cdc9, localizes in cytoplasmic factories and affects virulence and virus sensitivity to DNA damaging agents. 175 39

Alteration of DNA ligase I activity is a consistent biochemical feature of Bloom's syndrome (BS) cells. DNA ligase I activity in BS cells either is reduced and abnormally thermolabile or is present in an anomalously dimeric form. To assess the role of DNA ligase function in the etiology of BS, we have cloned the DNA ligase I cDNA from normal human cells by a PCR strategy using degenerate oligonucleotide primers based on conserved regions of the Saccharomyces cerevisiae and Schizosaccharomyces pombe DNA ligase genes. Human DNA ligase I cDNAs from normal and BS cells complemented a S. cerevisiae DNA ligase mutation, and protein extracts prepared from S. cerevisiae transformants expressing normal and BS cDNA contained comparable levels of DNA ligase I activity. DNA sequencing and Northern blot analysis of DNA ligase I expression in two BS human fibroblast lines representing each of the two aberrant DNA ligase I molecular phenotypes demonstrated that this gene was unchanged in BS cells. Thus, another factor may be responsible for the observed reduction in DNA ligase I activity associated with this chromosomal breakage syndrome.
...
PMID:A wild-type DNA ligase I gene is expressed in Bloom's syndrome cells. 188 2

This critical review considers recent work on alterations in DNA repair capacity in Bloom's syndrome as a molecular mechanism for this human disorder. Four main types of DNA repair deficiencies are discussed. These include perturbations in the temporal regulation of DNA repair pathways during the cell cycle, failure to enhance DNA repair pathways during cell proliferation, reduced levels of DNA ligase in Bloom's syndrome cells, and the identification of mutant repair enzyme proteins. These deficiencies are considered in relation to the cellular characteristics of Bloom's syndrome, including delays in DNA replication, hypermutability, and increased incidence of chromosomal aberrations (spontaneously occurring or observed after exposure to environmental agents). The relationship between DNA repair deficiencies and the genetic basis of Bloom's syndrome is described. Previous evidence suggested an autosomal recessive mode of inheritance for Bloom's syndrome. A discussion is presented as to the molecular mechanism through which an alteration in a single gene could result in multiple DNA repair defects.
...
PMID:DNA repair and the molecular mechanisms of Bloom's syndrome. 209 48

Photosensitive genodermatoses associated with established defects of DNA repair currently include the autosomal recessive diseases xeroderma pigmentosum (XP), Cockayne's syndrome (CS), trichothiodystrophy (TTD), and Bloom's syndrome (BS). XP is a heterogeneous disorder associated with defective excision repair or daughter strand repair of ultraviolet (UV)-induced DNA damage. It is characterized by cutaneous and ocular abnormalities predominantly on sun-exposed sites and in some cases, neurological features resulting from progressive neuronal loss. Skin involvement includes easy sunburning, pigmentary abnormalities, telangiectasia, dryness, scarring, and susceptibility to multiple benign and malignant neoplasms. In CS, defective repair of actively transcribing DNA is clinically associated with acute photosensitivity, growth retardation, demyelinating neurological abnormalities, and pigmentary retinal degeneration, but without increased cancer susceptibility. TTD is characterized by sulphur-deficient brittle hair, variable growth delay, mental retardation, ichthyosis, and in some cases photosensitivity. Although in some patients there is a deficiency of DNA excision repair identical to that in certain xeroderma pigmentosum patients, no increased cancer risk is present in trichothiodystrophy. In BS, deficient cellular DNA ligase is associated with congenital telangiectasia, photosensitivity, growth retardation, immune deficiency, increased susceptibility to infection, and predominantly internal rather than cutaneous malignancy. Immunological factors may at least determine the varying susceptibility to malignancy of these conditions.
...
PMID:DNA repair deficient photodermatoses. 220 44

Recent studies on eukaryotic DNA ligases are briefly reviewed. The two distinguishable enzymes from mammalian cells, DNA ligase I and DNA ligase II, have been purified to homogeneity and characterized biochemically. Two distinct DNA ligases have also been identified in Drosophila melanogaster embryos. The genes encoding DNA ligases from Schizosaccharomyces pombe, Saccharomyces cerevisiae and vaccinia virus have been cloned and sequenced. These 3 proteins exhibit about 30% amino acid sequence identity; the 2 yeast enzymes share 53% amino acid sequence identity or conserved changes. Altered DNA ligase I activity has been found in cell lines from patients with Bloom's syndrome, although a causal link between the enzyme deficiency and the disease has not yet been proven.
...
PMID:Eukaryotic DNA ligases. 220 27

DNA ligases play obligatory roles during replication, repair, and recombination. Multiple forms of DNA ligase have been reported in mammalian cells including DNA ligase I, the high molecular mass species which functions during replication, and DNA ligase II, the low molecular mass species which is associated with repair. In addition, alterations in DNA ligase activities have been reported in acute lymphocytic leukemia cells, Bloom's syndrome cells, and cells undergoing differentiation and development. To better distinguish the biochemical and molecular properties of the various DNA ligases from human cells, we have developed a method of purifying multiple species of DNA ligase from HeLa cells by chromatography through DEAE-Bio-Gel, CM-Bio-Gel, hydroxylapatite, Sephacryl S-300, Mono P, and DNA-cellulose. DNA-cellulose chromatography of the partially purified enzymes resolved multiple species of DNA ligase after labeling the enzyme with [alpha-32P]ATP to form the ligase-[32P]AMP adduct. The early eluting enzyme activity (0.25 M NaCl) contained a major 67-kDa-labeled protein, while the late eluting activity (0.48 M NaCl) contained two major labeled proteins of 90 and 78 kDa. Neutralization experiments with antiligase I antibodies indicated that the early and late eluting activity peaks were DNA ligase II and I, respectively. The three major ligase-[32P]AMP polypeptides (90, 78, and 67 kDa) were subsequently purified to near homogeneity by elution from preparative sodium dodecyl sulfate-polyacrylamide gels. All three polypeptides retained DNA ligase activities after gel elution and renaturation. To further reveal the relationship between these enzymes, partial digestion by V8-protease was performed. All three purified polypeptides gave rise to a common 22-kDa-labeled fragment for their AMP-binding domains, indicating that the catalytic sites of ligase I and II are quite similar, if not identical. Similar findings were obtained from the two-dimensional gel electrophoresis of their AMP-binding domains in the trypsin-digested protein fragments. The results also suggested that these isozymes have been derived from the same primordial DNA sequence or from the same precursor protein. The purification scheme and the data obtained will be instrumental for the further elucidation of the biological roles of various DNA ligases from human cells.
...
PMID:Fingerprinting of near-homogeneous DNA ligase I and II from human cells. Similarity of their AMP-binding domains. 221 88

DNA ligase activity was studied in several untransformed or virus-transformed human cell lines from normal donors and from Bloom's syndrome (BS) patients. This proneness genetic disease is characterized by several cytological abnormalities and cancer proneness and, recently, some transformed cell lines from these patients were described to present a reduced activity of DNA ligase I. Results presented in this work indicate that: (i) the total DNA ligase activity in crude extract from untransformed or transformed cell lines from several BS patients was significantly higher than in control cells; (ii) the partial purification of the enzyme after gel filtration on fast protein liquid chromatography of crude extracts from lymphoblastoid BS cells showed that the enzyme activity was eluted in a major 180 kDa form in which activity was higher than in control cells; (iii) the activity gel analysis of these enzyme fractions revealed that DNA ligase of human cells was correlated to a major 130 kDa polypeptide and, in BS cells, the extent of the activity of this band was equal or higher than that in control untransformed or transformed cells.
...
PMID:DNA ligase activity in human cell lines from normal donors and Bloom's syndrome patients. 272 53

Cells from patients with Bloom's syndrome, a rare human disease with autosomal recessive mode of inheritance, exhibit cytological abnormalities involving DNA metabolism. Bloom's syndrome is characterized by a greatly increased cancer frequency which may reflect a specific defect in DNA repair and replication. Evidence has recently been presented of the existence in Bloom's syndrome of an abnormality of the DNA ligase involved in semiconservative DNA replication. Another abnormality, in the excision-repair pathway of Bloom's syndrome cells, is reportedly due to an aberrant immunological reactivity of the DNA-repair enzyme uracil-DNA glycosylase. In this investigation we show, however, that the catalytic activity of uracil-DNA glycosylase appears to be normal in Bloom's syndrome lymphoblastoid cells.
...
PMID:Normal uracil-DNA glycosylase activity in Bloom's syndrome cells. 290 71

An increased DNA ligase activity is observed in extracts of Bloom's syndrome (BS) fibroblast cell line GM1492. The activity is 2-3-fold higher in this cell line compared to normal human fibroblasts, and 5-20-fold higher than in three other BS cell lines investigated. The DNA ligase activity in GM1492 cells is promoted by a heat-resistant, protease-sensitive factor comigrating with DNA ligases on single-stranded-DNA--cellulose. The factor stimulates DNA ligase I as well as DNA ligase II, and is not identical to the activity-promoting homologous DNA pairing, which is also enhanced in GM1492 cell extracts.
...
PMID:Expression of a DNA-ligase-stimulatory factor in Bloom's syndrome cell line GM1492. 339 Nov 63

Certain rare human diseases with autosomal recessive mode of inheritance are associated with a greatly increased cancer frequency which may reflect specific defects in DNA repair or replication. These disorders include xeroderma pigmentosum, ataxia-telangiectasia, Fanconi's anaemia and Bloom's syndrome. Cells from individuals with Bloom's syndrome usually grow slowly in culture and exhibit increased chromosomal breakage and rearrangement, an elevated frequency of sister chromatid exchanges, retarded rates of progression of DNA replication forks, delayed conversion of replication intermediates to high-molecular-weight DNA, and slightly increased sensitivity to DNA-damaging agents. Several of these features are also characteristic of Escherichia coli and yeast mutants with a defective DNA ligase. In this investigation we show that one of the two DNA ligases of human cells, ligase I, is defective in a representative lymphoid cell line of Bloom's syndrome origin.
...
PMID:DNA ligase I deficiency in Bloom's syndrome. 380 31

1 2 Next >>