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

A 21.8 kbp region of the genome of variola major virus (strain Harvey), a virus that caused haemorrhagic-type smallpox, has been sequenced and shown to possess 96% nucleotide identity to the corresponding region of vaccinia virus, the smallpox vaccine. Overall the gene arrangement in the two viruses is highly similar and individual open reading frames (ORFs) display a high degree of amino acid identity, for instance 26 of the 32 variola virus ORFs have > or = 90% identity with their vaccinia virus counterparts. A remarkable difference is the disruption of seven vaccinia virus ORFs into small fragments in variola virus. These include the variola virus homologue of vaccinia virus SalF2R, which encodes a protein related to C-type animal lectins, and SalF7L, which encodes an active 3 beta-hydroxysteroid dehydrogenase enzyme that contributes to vaccinia virus virulence. Upstream of the variola virus haemagglutinin gene there is a deletion of 1910 bp so that the equivalent of vaccinia virus gene SalF17R is truncated, and SalF16R, which shows amino acid similarity to the tumour necrosis factor receptor, is absent. The region sequenced includes the genes for thymidylate kinase and DNA ligase both of which are active in vaccinia virus and are highly conserved in variola virus. Other conserved ORFs with interesting homologies are those encoding profilin, superoxide dismutase and part of guanylate kinase. Two vaccinia virus genes encoding glycoproteins of the outer envelope of extracellular enveloped virus are also conserved in variola virus and this homology is likely to have contributed to the immunological protection which vaccinia virus evoked against smallpox. Lastly, there are multiple instances in which short oligonucleotide direct repeats flank a region absent from either variola or vaccinia virus.
J Gen Virol 1992 Nov
PMID:Nucleotide sequence of 21.8 kbp of variola major virus strain Harvey and comparison with vaccinia virus. 133 Dec 92

In this study we present the characterization of the temperature-sensitive mutant allele cdc9-1 encoding DNA ligase, of Saccharomyces cerevisiae strain A364A by DNA sequencing. Comparison with the published wild-type sequence from strain SK1 revealed 13 nucleotide exchanges between these two sequences, which are derived from non-isogenic genetic backgrounds. Only four of these changes, distributed over the whole coding region, lead to amino acid exchanges in the protein chain. Our analysis of the sequence of the wild-type CDC9 allele from strain A364A revealed differences from the isogenic cdc9-1 allele in only two nucleotides: one silent change and one leading to a single amino acid exchange. The latter is therefore responsible for the temperature-sensitive phenotype. A mosaic protein, in which a region carrying this amino acid exchange has been inserted in place of the corresponding part of CDC9 from the non-isogenic strain SK1, is not temperature sensitive. The exchange of a longer stretch of DNA leading to atteration of three amino acids of the protein compared with the original sequence of SK1 is required to obtain a temperature-sensitive DNA ligase in this strain, while in strain A364A a single amino acid change is sufficient for expression of a temperature-sensitive protein.
Mol Gen Genet 1992 Mar
PMID:Temperature sensitivity of the cdc9-1 allele of Saccharomyces cerevisiae DNA ligase is dependent on specific combinations of amino acids in the primary structure of the expressed protein. 155 39

The nucleotide sequence of 42090 bp of vaccinia virus strain WR is presented. The sequence includes the SalI L, F, G and I fragments and starts near the centre of the HindIII A fragment and extends rightwards towards the genomic terminus, finishing approximately 0.5 kb internal of the inverted terminal repeat (ITR). Translation of this region has identified 65 open reading frames (ORFs) of greater than 65 amino acids in length. Fifty-one of these which do not extensively overlap other larger ORFs have been subjected to further analysis; the other 14 are termed minor ORFs. In the rightmost 28.7 kb, the genes are, with one exception, transcribed towards the genomic terminus, similar to the arrangement of genes at the left end of the virus genome. Internal of this region the genes are expressed off either DNA strand but still predominately rightwards. ORFs are tightly packed with few intergenic non-coding regions of greater than 250 bp. Protein sequence comparisons have established a remarkably high number of homologies with entries in existing protein databases. Of these, DNA ligase, thymidylate kinase, two serine-threonine protein kinases, two serine proteinase inhibitors (serpins), two interleukin-1 receptor homologous and a discontinuous ORF related to tumour necrosis factor receptor have been reported. Other homologies include lectins, profilin, 3 beta-hydroxy steroid dehydrogenase, superoxide dismutase, guanylate kinase, ankyrin and complement factor H. In addition, there are a number of polypeptides with predicted properties of membrane-associated, secretory or glyco-proteins. Twelve gene families are described here and elsewhere. There is considerable similarity between genes from the right and left end of the virus genome that may have arisen by terminal transposition events. Several differences from the corresponding region of vaccinia virus strain Copenhagen sequence are noted. Near the right terminus the sequences diverge completely, and internal of this there are multiple examples of deletion of short sequences (eight to 10 nucleotides) that lie within penta- or hexanucleotide direct repeats.
J Gen Virol 1991 Jun
PMID:Nucleotide sequence of 42 kbp of vaccinia virus strain WR from near the right inverted terminal repeat. 204 93

We have previously shown that Mu can sustain the growth at non-permissive temperature of an Escherichia coli strain harbouring a thermosensitive mutation in the DNA ligase structural gene. This "complementation" reaches a maximal level with the Mu lig3 mutant which restores the viability of a ligts7 strain to the level of the wild type (Ghelardini et al. 1980; Paolozzi et al. 1980). In this study we analysed the characteristics of this phenotypic suppression in order to clarify its molecular mechanism. We found that an E. coli ligts7 strain lysogenic for the Mu lig3 mutant shows: (i) an increment in the host DNA ligase activity; (ii) an increase in the specific mRNA of the host lig gene; (iii) an increase (towards the relaxed state) in the average linking number of a resident plasmid; and (iv) a reduction in DNA gyrase activity. These results are compatible with the hypothesis that the Mu lig gene product by interfering with the host enzymatic apparatus controlling DNA topology leads to a reduction in chromosomal supercoiling. The relaxation of the chromosome could affect the transcription of the DNA ligase gene, amongst others. Thus, through this mechanism, the Mu lig gene product is able to modulate gene expression and hence suppress the effects of the E. coli ligts7 mutation. On the basis of the identification of this mechanism of action, we propose to change the name of the Mu lig gene (thought originally to be the structural gene for a bacteriophage ligase) to gem (gene expression modulation).
Mol Gen Genet 1989 Mar
PMID:Suppression of the thermosensitive DNA ligase mutations in Escherichia coli K12 through modulation of gene expression induced by phage Mu. 254 6

DNA sequence analysis of genetic deletions in bacteriophage T7 has shown that these chromosomal rearrangements frequently occur between directly repeated DNA sequences. To study this type of spontaneous deletion in more quantitative detail synthetic fragments of DNA, made by hybridizing two complementary oligonucleotides, were introduced into the non-essential T7 gene 1.3 which codes for T7 DNA ligase. This insert blocked synthesis of functional ligase and made the phage that carried an insert unable to form plaques on a host strain deficient in bacterial ligase. The sequence of the insert was designed so that after it is put into the T7 genome the insert is bracketed by direct repeats. Perfect deletion of the insert between the directly repeated sequences results in a wild-type phage. It was found that these deletion events are highly sensitive to the length of the direct repeats at their ends. In the case of 5 bp direct repeats excision from the genome occurred at a frequency of less than 10(-10), while this value for an almost identical insert bracketed by 10 bp direct repeats was approximately 10(-6). The deletion events were independent of a host recA mutation.
Mol Gen Genet 1989 Jun
PMID:Genetic deletions between directly repeated sequences in bacteriophage T7. 254 73

The DNA homology and adsorption specificity of newly isolated virulent bacteriophages of P. aeruginosa have been studied. On the basis of this analysis all phages were divided into four groups: phi k, phi m, phi mnP78-like and phi mnF82-like bacteriophages. DNA's of phi k as well as phi m phages were shown to possess different restriction patterns although they have an extensive homology. Unlike other groups, phi k phages were characterized by the presence of T4 DNA ligase--repaired, single-chain breaks.
Mol Gen Genet 1985
PMID:DNA homology and adsorption specificity of Pseudomonas aeruginosa virulent bacteriophages. 299 7

The DNA ligase of Escherichia coli catalyses the NAD-dependent formation of phosphodiester linkages between 5'-phosphoryl and 3'-hydroxyl groups in DNA. It is essential for DNA replication and repair of damaged DNA strands. We determined the nucleotide sequence of the lig gene of Escherichia coli coding for DNA ligase and flanking regions. The coding frame of the gene was confirmed by the amino acid composition and the amino- and carboxyl-terminal amino acid sequences of the purified ligase. The ligase consists of 671 amino acid residues with a molecular weight of 73,690.
Mol Gen Genet 1986 Jul
PMID:Nucleotide sequence of the lig gene and primary structure of DNA ligase of Escherichia coli. 301 36

It was shown that bacteriophage tf as well as bacteriophages phi p4/40, phi p25/42, phi p23/40 and phi p6/40, which are specific to different P. putida strains, contain the single strand breaks in their DNA. The breaks are localized in one strand of DNA molecules and are repairable with T4 DNA ligase. Bacteriophage tf has no detectable DNA homology with phi p4/40, phi p25/42, phi p23/40 and phi p6/40 bacteriophages. All the phages studied have no relation with other known Pseudomonas phages. Bacteriophages phi p4/40 and phi p25/42 share the extensive DNA homology.
Mol Gen Mikrobiol Virusol 1988 May
PMID:[Bacteriophages of Pseudomonas putida containing single-stranded canonical DNA breaks]. 313 62

A DNA sequence has been isolated from Schizosaccharomyces pombe which promotes high frequency transformation of plasmids in the same organism. It is closely linked to the DNA ligase gene CDC17 and has therefore been named ARS17 although in structure it differs substantially from ARS elements in Saccharomyces cerevisiae. ARS17 spans some 1.8 kb of DNA and deletion of any part of this region affects activity. Moreover, there does not appear to be any short sequence which is, by itself, sufficient for high frequency transformation. ARS17 lies between and partly overlaps two divergently transcribed genes and it is extremely AT rich. It lacks the consensus sequence found in S. cerevisiae ARSs and it has no ARS activity in S. cerevisiae.
Mol Gen Genet 1987 Apr
PMID:Characterisation of an autonomously replicating sequence from the fission yeast Schizosaccharomyces pombe. 329

We have investigated the fate of the yeast 2 micron DNA plasmid in strains with a temperature sensitive mutation of DNA ligase. At the restrictive temperature the plasmid DNA collects as an open circular form with single strand interruptions. Both alpha factor pheromone, which arrests cells before the start of S phase, and hydroxyurea, which blocks progression through S phase, prevent the appearance of the open circular form. Thus, interrupted plasmid DNA does not accumulate in the absence of DNA replication. On average the interrupted molecules contain four to five interruptions per newly replicated strand. Most of the interruptions are nicks (breaks in a single phosphate ester bond) rather than gaps (absence of one or more nucleotides in a strand) as judged by the in vitro conversion of the interrupted molecules into a covalently closed form by DNA ligase. Mapping of the position of the interruptions reveals no predominate sites.
Mol Gen Genet 1986 Jun
PMID:Accumulation of single strand interruptions within the yeast 2 microns DNA plasmid during replication in a DNA ligase mutant. 352 47

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