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)

Analyses of cleavage ends of DNA fragments in apoptotic rat thymocytes induced by gamma-ray irradiation or by treatment with dexamethasone revealed that in both cases the fragments produced had 3'-hydroxyl (OH) and 5'-phosphoryl (P) ends of DNA chains. Rat thymocyte nuclei contained at least three endonuclease activities (deoxyribonucleases alpha, beta and gamma) that were able to cleave chromatin to mononucleosomal and oligonucleosomal fragments. The nuclei of apoptotic rat thymocytes induced by gamma-ray irradiation or dexamethasone retained considerable deoxyribonuclease gamma activity, but not alpha or beta deoxyribonuclease activity. During the induction of apoptosis, treatment with cycloheximide, which suppressed apoptosis, resulted in marked decreases of deoxyribonucleases alpha and beta activities. After release of cycloheximide inhibition, DNA fragmentation associated with apoptosis occurred in the cycloheximide-treated thymocyte nuclei, in which deoxyribonuclease gamma activity was only observed. The purified deoxyribonucleases alpha and beta were divalent cation-independent acidic endonucleases, which were separated on a CM5PW column by HPLC. The molecular masses of deoxyribonucleases alpha and beta were 28 kDa and 30 kDa, respectively, as determined by TSK G-2000SW gel-filtration HPLC, and both were 32 kDa in molecular mass as determined by SDS/PAGE. In contrast, deoxyribonuclease gamma, a neutral endonuclease, required both Ca2+ and Mg2+ for full activity and was inhibited by Zn2+. The molecular mass of deoxyribonuclease gamma was 31 kDa and 33 kDa when measured by gel filtration and SDS/PAGE, respectively. Under these optimal conditions, deoxyribonuclease gamma was shown to produce 3'-OH/5'-P ends of nucleosomal DNA fragments, while deoxyribonucleases alpha and beta both formed DNA fragments with 3'-P/5'-OH ends. The ends formed by cleavage with deoxyribonuclease gamma were the same as those produced in apoptotic rat thymocytes. On the basis of these results, it seems likely that deoxyribonuclease gamma is responsible for internucleosomal cleavage of chromatin during thymic apoptosis.
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PMID:Identification of an endonuclease responsible for apoptosis in rat thymocytes. 795 53

The DNA of wild-type Streptomyces lividans 66 is degraded during electrophoresis in buffers containing traces of ferrous iron. S. lividans ZX1, a mutant selected for resistance to DNA degradation, simultaneously became sensitive to phi HAU3, a wide-host-range temperate bacteriophage. A DNA fragment conferring phi HAU3 resistance was cloned; it contains a phage resistance gene whose deduced amino acid sequence is similar to the phage lambda Ea59 endonuclease. The S. lividans phi HAU3 resistance does not seem to be a classical restriction-modification system, because no host-modified phages able to propagate on the wild-type strain could be isolated. The cloned fragment did not make the host DNA prone to degradation during electrophoresis, indicating that the two phenotypes are controlled by different genes which were deleted together from the chromosome of ZX1.
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PMID:Streptomyces lividans 66 contains a gene for phage resistance which is similar to the phage lambda ea59 endonuclease gene. 805 30

To examine bacteriophage recombination in vivo, independent of such other processes as replication and packaging, substituted lambda phages bearing restriction site polymorphisms were employed in a direct physical assay. Bacteria were infected with two phage variants; DNA was extracted from the infected cells and cut with a restriction endonuclease. The production of a unique recombinant fragment was measured by Southern blotting and hybridization with a substitution sequence-specific probe. High frequency recombination was observed under the following conditions: the substituted lambda phages infected a wild-type host cell bearing a lambda repressor-expressing plasmid designed to shut down phage transcription and inhibit phage DNA replication as well. The same plasmid expressed the lambda red and gam genes. In addition, the host cell bore a second plasmid which expressed the EcoRI restriction-modification system. Both phage chromosomes possessed a single EcoRI site in the middle of the marked substitution sequence; however, as the site was modified in one of the parent phages, only the other partner was cut. Recombination was found to be dependent upon (1) red, (2) recA, (3) inactivation of the host recBCD function, either by Gam protein or by mutation and (4) double-strand breaks. The homologous recombination system of phage P22 could substitute for that of lambda.
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PMID:Efficient double-strand break-stimulated recombination promoted by the general recombination systems of phages lambda and P22. 810 56

High-resolution S1 nuclease mapping of mRNA synthesised in vivo, in vitro run-off transcription with RNA polymerase from Streptomyces lividans and gene fusions were used to analyse the transcriptional organization of the SalI restriction-modification system of Streptomyces albus G. The salIR and salIM genes that encode the restriction endonuclease and its cognate methyltransferase constitute an operon which is mainly transcribed from sal-pR1, a promoter located immediately upstream of salIR, with two possible minor promoters further upstream. Another promoter, sal-pM, is within the 3' end of the salIR coding region, and allows expression of the modification gene in the absence of sal-pR1. The sal-pM promoter might be involved in the establishment of modification prior to restriction endonuclease activity. Sequences upstream of the apparent transcriptional start sites for sal-pR1 and sal-pM show similarity with the -10 region of typical vegetatively expressed eubacterial promoters, but appropriately centered -35 regions are absent.
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PMID:Complex transcription of an operon encoding the SalI restriction-modification system of Streptomyces albus G. 831 78

The contribution of nonspecific DNA to enzyme efficiency (k(cat)/K(m)) is described for a sequence-specific DNA-modifying enzyme. Our investigation focuses on the EcoRI DNA methyltransferase which transfers a methyl group from the cofactor S-adenosylmethionine to the second adenine in the double-stranded DNA sequence GAATTC. k(cat)/K(m) increases 4-fold as DNA length increases from 14 to 429 base pairs and increases 2-fold as the distance from the site to the nearest end is increased from 29 to 378 base pairs. No changes in k(cat)/K(m) result from further increases in either case. A facilitated diffusion mechanism is proposed in which the methyltransferase scans an average of <400 base pairs prior to dissociation from a DNA molecule. The methyltransferase was found to methylate two sites on a single DNA molecule in a distributive rather than a processive manner, suggesting that the enzyme dissociates from the DNA prior to release of the reaction product S-adenosylhomocysteine. A direct competition experiment with the EcoRI endonuclease shows the methyltransferase to be slightly more efficient at specific site location and catalysis. A rationale for the role of facilitated diffusion in this type II restriction-modification system is proposed.
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PMID:Contribution of facilitated diffusion and processive catalysis to enzyme efficiency: implications for the EcoRI restriction-modification system. 865 61

Substituting lysine for leucine at position 43 (L43K) transforms NaeI from restriction endonuclease to topoisomerase and makes NaeI hypersensitive to intercalative anticancer drugs. Here we investigated DNA recognition by Nael-L43K. Using DNA competition and gel retardation assays, NaeI-L43K showed reduced affinity for DNA substrate and the ability to bind both single- and double-stranded DNA with a definite preference for the former. Sedimentation studies showed that under native conditions NaeI-L43K, like NaeI, is a dimer. Introduction of mismatched bases into double-stranded DNA significantly increased that DNA's ability to inhibit NaeI-L43K. Wild-type NaeI showed no detectable binding of either single-stranded DNA or mismatched DNA over the concentration range studied. These results demonstrate that the L43K substitution caused a significant change in recognition specificity by NaeI and imply that NaeI-L43K's topoisomerase activity is related to its ability to bind single-stranded and distorted regions in DNA. A mechanism is proposed for the evolution of the NaeI restriction-modification system from a topoisomerase/ligase by a mutation that abolished religation activity and provided a needed change in DNA recognition.
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PMID:Effects on NaeI-DNA recognition of the leucine to lysine substitution that transforms restriction endonuclease NaeI to a topoisomerase: a model for restriction endonuclease evolution. 893 68

The ApaLI restriction-modification system from Acetobacter pasteurianus IFO 13753 recognizes the nucleotide sequence GTGCAC. The gene coding for the ApaLI methylase (M.ApaLI) was cloned into Escherichia coli DH5 alpha MCR, and the nucleotide sequence of the gene was analyzed. The M.ApaLI gene coded for a protein of 429 amino acid residues (molecular mass, 46,554 daltons). The ApaLI restriction endonuclease (R.ApaLI) gene was analyzed by inverse polymerase chain reaction. The R.ApaLI gene coded for a protein of 375 amino acid residues (molecular mass, 42,143 daltons). The two genes had the same orientation separated by two base pairs. The deduced amino acid sequence of M.ApaLI shows significant similarities to the family of cytosine-5 methylases. However, the deduced amino acid sequence of R.ApaLI did not have as much relatedness in the nucleotide sequence, when compared with those of the other restriction endonucleases already reported.
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PMID:Cloning and nucleotide sequence of ApaLI restriction-modification system from Acetobacter pasteurianus IFO 13753. 898 85

The salIR and salIM genes encode the endonuclease and methyltransferase components of the SalI restriction-modification system from Streptomyces albus G. Expression of the salI genes in Escherichia coli was investigated and major differences with Streptomyces were found. In E. coli there is no detectable expression of the salI R gene due to inactivity of the sal-pR promoter region. In the natural host of the system this region directs transcription of the salI genes as a bicistronic message. In contrast to salIR, salIM is transcribed in the heterologous host from a promoter within the salI DNA. Since sal-pR is not active, the gene cannot be expressed as part of the salI operon. It is probably transcribed from sal-pM, a promoter internal to the operon which allows independent expression of the modification gene in Streptomyces. Replacement of sal-pR by the strong pLac promoter allows expression of salIR in E. coli and enhances expression of salIM. The resulting strain produces about 10 times more endonuclease than a Streptomyces clone containing the SalI system under the control of sal-pR.
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PMID:Comparative analysis of expression of the SalI restriction-modification system in Escherichia coli and Streptomyces. 900 89

BsoBI is a type II restriction enzyme found in Bacillus stearothermophilus JN209 that recognizes the symmetric sequence 5'-CYCGRG-3' (Y=C or T; R=A or G) and cleaves between the first and second base to generate a four-base 5' extension. The cloning and sequencing of BsoBI restriction-modification system has been described by Ruan et al. [Mol. Gen. Genet. 252 (1996) 695-699]. Here we report the overexpression of BsoBI restriction endonuclease gene in E. coli by insertion of the endonuclease gene into an expression vector pRRS. The recombinant BsoBI was purified to homogeneity and its N-terminus sequence was determined. It has the same N-terminal aa sequence as the native enzyme. The constitutive expression of BsoBI from pRRS is lethal to E. coli in the absence of the cognate methylase. The bsoBIR gene was mutagenized with either hydroxylamine or by error-prone polymerase chain reaction in vitro and transferred into E. coli via plasmid vectors in the absence of the cognate methylase. Surviving transformants were selected that carry BsoBI variants which lost endonuclease activity. DNA sequencing of the mutant alleles revealed that G123, D124, D212, D246, E252 and H253 are important residues for enzymatic activity. An electrophoretic mobility shift assay was used to identify binding-proficient and cleavage-deficient variants. Seven variants I95M&D124Y, G123R, D212N, K207R&D212V, D246N, D246G and E252K can still bind DNA despite the loss of cleavage activity. Thus, residues D124, D212, D246 and E252 may be located near or within the catalytic center, and are likely involved in metal ion binding.
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PMID:Overexpression of BsoBI restriction endonuclease in E. coli, purification of the recombinant BsoBI, and identification of catalytic residues of BsoBI by random mutagenesis. 909 56

The gene (xamIM) encoding the DNA methyltransferase of the XamI restriction-modification system from Xanthomonas campestris pv. amaranithicola (M.XamI) has been cloned in Escherichia coli and its nucleotide sequence determined. The sequence predicts a protein of 527 amino acids that contains nine conserved motifs characteristic of DNA amino methyltransferases. In fact, M.XamI shows significant similarity with N6-adenine methyltransferases of the gamma group of amino methyltransferases, including M.SalI (from the isoschizomeric SalI restriction-modification system) and M.TaqI (the only N6-adenine methyltransferase for which a three-dimensional structure is available). M.XamI and M.SalI share two highly conserved regions within the C-terminal domain, one of which aligns with one of the DNA recognition loops proposed for M.TaqI. Analysis of the chromosomal DNA adjacent to xamIM led to the identification of an additional ORF (275 codons), downstream, in the same transcriptional orientation. Although some limited similarities between the SalI restriction enzyme and the product deduced from this ORF were found, the clone carrying xamIM did not express the expected endonuclease function.
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PMID:Isolation and nucleotide sequence of the gene encoding the XamI DNA methyltransferase of Xanthomonas campestris pv. amaranthicola. 913 May 89

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