EC:3.1.30.2 - FACTA Search

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Query: EC:3.1.30.2 (endonuclease)
18,621 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Simian varicella virus (SVV) DNA was purified from viral nucleocapsids and the molecular structure of the SVV genome was determined. SVV DNA was analyzed by agarose gel electrophoresis of BamHI, BglII, EcoRI, and PstI restriction endonuclease digests. SVV and varicella zoster virus (VZV) DNAs were demonstrated to have distinct restriction endonuclease profiles. Summation of the sizes of individual restriction endonuclease fragments indicate the size of SVV DNA is congruent to 121 kilobase pairs (kbp) or congruent to 76.8 megadaltons (Md). Electron microscopy, lambda exonuclease analysis, and Southern blot DNA hybridizations were utilized to determine the molecular structure of the SVV genome and to construct restriction endonuclease maps. The results indicate that SVV DNA consists of a long component (L, congruent to 100 kbp) covalently linked to a short component (S, congruent to 20 kbp) which is composed of a unique short sequence (Us, 5.3 +/- 0.7 kbp) bracketed by inverted repeat sequences (TRs and IRs, congruent to 7.2 kbp). The presence of 0.5 M PstI restriction endonuclease fragments indicates that the S component may invert relative to the L component and that the genome exists in two major isomeric forms. The findings demonstrate that the SVV and VZV genomes are similar in size and structure.
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PMID:The simian varicella virus and varicella zoster virus genomes are similar in size and structure. 131 Jan 85

Binding mechanisms of ADPR-transferase to restricted double-stranded DNA fragments of SV40 and pBR322 DNA were determined by nuclease protection techniques. Top and bottom strands of double-stranded DNA were identified by specific labeling with 32P. Protection against specific exonucleases identified binding of ADPR-transferase to DNA termini, whereas binding to internal regions of linear DNAs was probed by protection against endonucleases. ADPR-transferase protein protected against exonucleolytic attack from lambda exo and exoIII in all DNA fragments tested, demonstrating that the enzyme protein binds indiscriminately to all DNA termini. Extending earlier results [Sastry, S.S., & Kun, E. (1988) J. Biol. Chem. 263, 1505-1512], the modifying effect of the binding of ADPR-transferase to DNA induced changes in DNA conformation, as evident from altered pause sites that appeared following digestion of DNA fragments by lambda exonuclease in the presence of ADPR-transferase. In contrast to the nonselective binding of ADPR-transferase to DNA termini, ADPR-transferase conferred protection endonuclease attack (DNase I and micrococcal nuclease) only to the 209-bp EcoRI-PstI SV40 DNA fragment. These results indicate that binding of ADPR-transferase to relatively rare internal regions of restricted DNA fragments exhibits some degree of specificity. Specificity of binding appears to be related to the coincidental relative A+T-rich regions in DNA, and to DNA bending, both identified in the 209-bp SV40 DNA fragment. Synthetic polydeoxyribonucleotides containing dA-dT bind ADPR-transferase stronger than polydeoxyribonucleotides containing dG-dC. It was deduced from endonuclease protection patterns that binding of the enzyme protein leaves no defined footprints on the 209-bp SV40 DNA fragment, but there is significant modification of DNA structure following binding of the enzyme protein. Methylation protection assays and the prevention of the binding of ADPR-transferase to T4 DNA by its glucosylation indicate that the enzyme binds in the major groove of DNA. The 36-kDa A peptide fragment of ADPR-transferase [Buki, K. G., & Kun, E. (1988) Biochemistry 27, 5990-5995] exhibits the same protection against endonucleolytic enzymes as the intact ADPR-transferase molecule.
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PMID:Binding of adenosine diphosphoribosyltransferase to the termini and internal regions of linear DNAs. 250 40

Restriction endonuclease (RE) mapping studies and molecular hybridization analyses were conducted to determine the molecular structure of the genome of equine cytomegalovirus (ECMV). The ECMV genome is a linear, double-stranded DNA with a molecular size of 126 +/- 0.6 MDa (189 kbp). A library of cloned BamHI, EcoRI, and HindIII fragments of the viral genome was used to construct RE maps. Individual 32P-labeled cloned DNA fragments were hybridized to Southern blots of viral genomic DNA digested to completion with BamHI, EcoRI, HindIII, or SalI. These analyses revealed that the ECMV genome consists of a 97-MDa unique long region which is bracketed by repeated sequences. At one terminus of the genome, a 21.3-MDa segment of repeated sequences with no apparent unique sequences was identified. At the other terminus, a 6-MDa unique region bracketed by 2.4-MDa repeat segments was identified. No submolar RE fragments were identified upon digestion of the ECMV genome with BamHI, EcoRI, HindIII, SalI, or other REs, including BclI, BglII, NruI, and XbaI. The genome possesses only two termini as judged by lambda exonuclease digestion and by T4 DNA polymerase end-labeling of the intact DNA followed by digestion with BamHI, EcoRI, HindIII, SalI, BclI, BglII, NruI, or XbaI. In addition, Southern blot analysis of DNA extracted from ECMV-infected rabbit kidney cells revealed that only one viral DNA fragment within the intracellular viral DNA pool contains fused genomic termini. Taken together, these observations indicate that the ECMV genome does not isomerize and suggest that the genome of ECMV may be unique among those of the herpesviruses and especially those of the betaherpesviruses (cytomegaloviruses) since it contains regions of extensive internal homology yet does not undergo isomerization. Lastly, the relatively small size of the viral genome indicates an evolutionary diversification among the cytomegaloviruses.
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PMID:Physical structure and molecular cloning of equine cytomegalovirus DNA. 255 43

The DNA intermediates and final products formed by the Type I restriction endonuclease, EcoB, were further characterized. DNA cleaved on only one strand (hemi-restricted DNA) contains gaps of approximately 70-100 nucleotides, while the fully restricted products contain 3'-single-stranded tails averaging approximately 70-100 nucleotides for each strand cleaved. The gaps and tails are formed with the release of an equal number of nucleotides as small oligonucleotides that are soluble in acid. After purification, neither the hemi-restricted nor the fully restricted DNAs are cleaved again by EcoB. There is no apparent specificity for which strand of a duplex is initially cleaved by EcoB, nor is there specificity with respect to the composition of the 3'-terminal nucleotide formed on the DNA or the 3'- or 5'-terminal nucleotides of the acid-soluble oligonucleotides released during DNA cleavage. The structure formed at the 5' terminus of the DNA product which blocks phosphorylation by T4 polynucleotide kinase remains unknown, but its removal with phage lambda exonuclease allows at least some reutilization of recognition sites by EcoB as well as phosphorylation of the newly formed 5' termini. To explain the complex mechanism of this enzyme, it is suggested that the unidentified 5'-tails prevent wasteful rerestriction from occurring, whereas the 3'-single-stranded tails create DNA which, when nonhomologous to chromosomal DNA, cannot be rescued because such tails are not substrate for DNA polymerases. However, when homologous chromosomal DNA exists, the randomly cleaved large fragments with these tails can easily be assimilated by recA-mediated genetic recombination, thus stimulating DNA exchange between related organisms.
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PMID:The DNA restriction endonuclease of Escherichia coli B. II. Further studies of the structure of DNA intermediates and products. 298 10

Double-stranded, 1.9-kilobase-pair (kbp) DNA molecules were found in 18 strains representing three pathogenic races of Fusarium oxysporum f. sp. conglutinans. The DNA element (pFOXC1) from a race 1 strain and the DNA element (pFOXC2) from a race 2 strain were shown by restriction endonuclease mapping to be linear. pFOXC2 was found in mitochondrial preparations and appears to have blocked 5' termini, as it was sensitive to 3'----5' exonuclease III but insensitive to 5'----3' lambda exonuclease. The major 1.8-kbp BglII restriction endonuclease fragment of pFOXC2 was cloned in plasmid pUC12. The recombinant plasmid (pCK1) was not homologous to the mitochondrial or nuclear genomes from F. oxysporum f. sp. conglutinans. This suggests that pFOXC2 is self-replicating. pCK1 was homologous to all 1.9-kbp DNA elements of race 2 but was not homologous to those of race 1 or race 5. All race 1 and 5 elements were also shown to share common DNA sequences.
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PMID:Linear plasmidlike DNA in the plant pathogenic fungus Fusarium oxysporum f. sp. conglutinans. 301 80

Wild-type bacteria which restrict the deoxyribonucleic acid (DNA) of infecting phage when the phage do not carry the proper host modification rapidly degrade that restricted DNA to acid-soluble products. The purified restriction enzyme acts as an endonuclease in vitro to cleave restrictable DNA and does not further degrade the DNA fragments produced. We have examined mutants of Escherichia coli K-12 which lack various nucleases in order to determine which nucleases are involved in the rapid acid solubilization in vivo of unmodified lambda DNA following restriction. Bacteria which are wild type, recA(-), or polA1(-) degrade about 50% of the unmodified phage DNA within 10 min of infection, with little subsequent degradation. Mutants which are recB(-) or recC(-) degrade unmodified DNA very slowly, solubilizing about 15% of the DNA by 10 min after infection. Two classes of phenotypic revertants of recB(-)/C(-) mutants were also tested. Bacteria which are sbcA(-) restrict poorly and do not degrade much of the restricted DNA. Bacteria which are sbcB(-) restrict normally. This mutation does not appear to affect degradation of restricted phage DNA in recB(-)/C(-) mutants, but such degradation is decreased in recB(+)/C(+) bacteria. The presence of a functional lambda exonuclease gene is not required for degradation after restriction.
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PMID:Degradation of bacteriophage lambda deoxyribonucleic acid after restriction by Escherichia coli K-12. 456 92

Degradation of bacterial deoxyribonucleic acid (DNA) after infection with T4 bacteriophage was studied in an endonuclease I-deficient host. The kinetics of degradation were similar to those seen in other hosts with a normal level of this enzyme. Irradiation of extracellular phage with ultraviolet (UV) destroyed the capacity of the infecting virus to induce extensive breakdown of host DNA, which was, however, converted to high-molecular-weight material. Addition of chloramphenicol to T4-infected cells provided data which can be interpreted to indicate the involvement of at least two endodeoxyribonucleases and one exodeoxyribonuclease having a high degree of specificity. A model is proposed showing the sequential action of two endodeoxyribonucleases followed by an exodeoxyribonuclease in the degradation of host DNA. The appearance of these hydrolytic enzymes requires protein synthesis. Infections leading to partial degradation only (UV-irradiated phages, gene 46 mutants) effectively inhibited the synthesis of bacterial messenger ribonucleic acid and of beta-galactosidase.
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PMID:Bacteriophage-induced inhibition of host functions. II. Evidence for multiple, sequential bacteriophage-induced deoxyribonucleases responsible for degradation of cellular deoxyribonucleic acid. 489 64

RecA- mutants of Escherichia coli extensively degrade their DNA following UV irradiation. Most of this degradation is due to the recBC DNase, which suggests that the recA gene is involved in the control of recBC DNase in vivo. We have shown that purified recA protein inhibits the endonuclease and exonuclease activities of recBC DNase on single-stranded DNA. The extent of inhibition is dependent on the relative concentration of recA protein, recBC DNase, and the DNA substrate; inhibition is greatest when the concentrations of DNA and recBC DNase are low and the concentrations of recA protein is high. At fixed concentrations of recA protein and recBC DNase, inhibition is eliminated at high concentrations of DNA. In the presence of adenosine 5'-O-(3-thiotriphosphate), an ATP analog which stabilizes the binding of recA protein to both single- and double-stranded DNA, recA protein is a more potent inhibitor of the nuclease activities on single-stranded DNA and is a weak inhibitor of the exonuclease activity on double-stranded DNA. Inhibition of the latter is enhanced by oligodeoxynucleotides, which stimulate the binding of recA protein to double-stranded DNA. In the presence of adenosine 5'-O-(3-thiotriphosphate), recA protein also inhibits the action of exonuclease I on single-stranded DNA and of lambda exonuclease on double-stranded DNA. These observations are most consistent with the idea that recA protein protects DNA from recBC DNase by binding to DNA. RecA protein also blocks the endonucleolytic cleavage of gapped circular DNA by recBC DNase. Since both recA protein and recBC DNase have the ability under certain conditions to unwind duplex DNA and to displace strands, we looked for evidence that their combined action would enlarge gaps but found no extensive enlargement. D-loops, a putative intermediate in genetic recombination, are effectively protected against the action of recBC DNase by the E. coli single strand binding protein and by recA protein in the presence of adenosine 5'-O-(3-thiotriphosphate).
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PMID:Escherichia coli recA protein protects single-stranded DNA or gapped duplex DNA from degradation by RecBC DNase. 626 52

Using complementation tests and nucleotide sequencing, we showed that the rad58-4 mutation was an allele of the MRE11 gene and have renamed the mutation mre11-58. Two amino acid changes from the wild-type sequence were identified; one is located at a conserved site of a phosphodiesterase motif, and the other is a homologous amino acid change at a nonconserved site. Unlike mre11 null mutations, the mre11-58 mutation allowed meiosis-specific double-strand DNA breaks (DSBs) to form at recombination hot spots but failed to process those breaks. DSB ends of this mutant were resistant to lambda exonuclease treatment. These phenotypes are similar to those of rad50S mutants. In contrast to rad50S, however, mre11-58 was highly sensitive to methyl methanesulfonate treatment. DSB end processing induced by HO endonuclease was suppressed in both mre11-58 and the mre11 disruption mutant. We constructed a new mre11 mutant that contains only the phosphodiesterase motif mutation of the Mre11-58 protein and named it mre11-58S. This mutant showed the same phenotypes observed in mre11-58, suggesting that the phosphodiesterase consensus sequence is important for nucleolytic processing of DSB ends during both mitosis and meiosis.
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PMID:A novel mre11 mutation impairs processing of double-strand breaks of DNA during both mitosis and meiosis. 941 73

Two flow cytometric apoptosis assays, the terminal deoxynucleotidyl transferase (TdT) assay and in situ nick translation (ISNT) assay, were assessed for their ability to quantitate drug-induced apoptosis in CLL lymphocytes. In contrast to HL60 cells, biotinylated dUTP could not be effectively incorporated into apoptotic CLL lymphocytes using exogenous TdT. This suggested that CLL lymphocytes possess a different type of endonuclease that cleaves DNA, leaving blunt or 3' recessed DNA breaks, which are poor substrates for TdT. This possibility was tested using lambda exonuclease, which can convert a blunt or 3' recessed DNA break into a 3' overhang. Apoptotic CLL lymphocytes pre-treated with lambda exonuclease demonstrated increased nucleotide incorporation with TdT. Single-strand DNA breaks are also present in apoptotic CLL lymphocytes, as labelled nucleotides could be incorporated using the in situ nick translation assay. This study suggests that the efficiency of tailing reactions may be limited by the nature of the endonuclease activity in certain cell types and that validation with other parameters is an essential prerequisite to their quantitative use.
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PMID:Flow cytometric apoptosis assays indicate different types of endonuclease activity in haematopoietic cells and suggest a cautionary approach to their quantitative use. 948 82

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