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)

The effect of pyrimidine photodimers on transmethylation reactions catalyzed by a highly purified rat liver DNA (cytosine-5-)-methyltransferase (EC 2.1.1.37) that exhibits maintenance and de novo methylation activities was studied in vitro, using the viral substrates M13 mp9 replicative form (RF) DNA and the hemimethylated analog formed from primed synthesis of phage DNA in the presence of 2'-deoxy-5-methylcytidine 5'-triphosphate. These DNAs were irradiated with UVB (280-340 nm) at 900-3600 J/m2 in the presence of the triplet-state sensitizers acetone or 3-dimethylaminopropiophenone. Under these conditions of irradiation, which approximate solar UV, pyrimidine cyclobutane photodimers were introduced without producing any evidence of single-strand breaks or alkali-sensitive sites [i.e., no (6-4)pyrimidine-pyrimidone photoproducts]. This was confirmed by gel analysis, a T4 UV endonuclease nicking assay specific for cyclobutane-type dimers, and HPLC analysis of the photoproducts. The methylation of irradiated templates by DNA methyltransferase was inhibited in an approximately linear fashion as a function of increasing UVB dose. This inhibition was correlated with the number of lethal photoproducts detected by the simultaneous measurement of the surviving fraction of infectious phage DNA. For approximately the same number of pyrimidine cyclobutane photoproducts introduced, de novo methylation activity was approximately 2-fold more sensitive than the maintenance mode of methylation. The ability of these putatively carcinogenic, pyrimidine photoproducts to inhibit DNA methylation suggests a common mechanism of action with several chemical carcinogens that are known to modify bases.
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PMID:Perturbation of maintenance and de novo DNA methylation in vitro by UVB (280-340 nm)-induced pyrimidine photodimers. 386 17

The mutagenicity of O6-methylguanine (O6MeGua), a chemical carcinogen-DNA adduct, has been studied in vivo by using a single-stranded M13mp8 genome in which a single O6MeGua residue was positioned in the unique recognition site for the restriction endonuclease Pst I. Transformation of Escherichia coli MM294A cells with this vector gave progeny phage, of which 0.4% were mutated in their Pst I site. In a separate experiment, cellular levels of O6MeGua-DNA methyltransferase (an O6MeGua-repair protein) were depleted by treatment with N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) prior to viral DNA uptake. In these cells, the mutation frequency due to O6MeGua increased with increasing MNNG dose (the highest mutation frequency observed was 20%). DNA sequence analysis of 60 mutant genomes revealed that O6MeGua induced exclusively G-to-A transitions.
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PMID:In vivo mutagenesis by O6-methylguanine built into a unique site in a viral genome. 609 94

Plasmids carrying 24- or 32-base-pair inserts of alternating (dG-dC) residues were used to analyze the level of methylation of the G-C-G-C sites by Hha I DNA methyltransferase and their cleavage by Hha I endonuclease in the B-DNA or Z-DNA conformation. In supercoiled plasmids in which the inserts formed Z-DNA, the extent of methylation at the insert G-C-G-C sites was dramatically lower than the level of methylation at the G-C-G-C sites located outside the insert in the same plasmid. Similarly, cleavage by Hha I endonuclease was sharply lowered when the insert was in the Z-DNA form. In the relaxed plasmid, all its G-C-G-C sites were methylated to the same extent and the unmethylated sites were readily cleaved. After treatment with the methylase, the supercoiled plasmid was linearized and then digested with Hha I restriction endonuclease. This exposed unmethylated G-C-G-C sites from the insert that had been protected against cleavage in the Z conformation. A chemical reaction was used to study the distribution of the unmethylated cytosine residues. No accumulation of unmethylated cytosine residues was found anywhere along the entire 32-base-pair insert, which is consistent with a cooperative B-Z transition.
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PMID:In Z-DNA the sequence G-C-G-C is neither methylated by Hha I methyltransferase nor cleaved by Hha I restriction endonuclease. 632 8

The PvuII restriction-modification system has been found to contain three genes which code for a DNA methyltransferase (MTase), a restriction endonuclease (ENase) and a small protein required for expression of the ENase-encoding gene. In addition, there is a small open reading frame (ORF) within and opposite to the MTase-encoding gene. The region containing this ORF is transcribed, and the ORF has an excellent Shine-Dalgarno sequence with an ATA start codon. A closely related ORF is present in the SmaI system. The 28-amino-acid (aa) predicted peptide from the PvuII ORF resembles a region of the PvuII ENase at the dimer interface. We have cloned this ORF, giving it an ATG start codon and putting it under the control of an inducible promoter: induction leads to a slight but significant decrease in restriction of bacteriophage lambda. We also have obtained the 28-aa synthetic peptide, and are exploring the possibility that it modulates ENase subunit association. While this peptide has no detectable effect on dimeric PvuII ENase, it inhibits renaturation of urea-denatured ENase in a concentration-dependent manner. The ORF may represent an additional safeguard during establishment of the PvuII restriction-modification system in a new host cell, helping to delay the appearance of active ENase dimers, while the MTase accumulates and protects the host chromosome.
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PMID:Gene pvuIIW: a possible modulator of PvuII endonuclease subunit association. 760 91

The salIR and salIM genes of Streptomyces albus G encode the restriction endonuclease (ENase) and DNA methyltransferase (MTase) of the SalI restriction-modification (R-M) system. In S. albus G, the genes constitute an operon that is mainly transcribed from a promoter located upstream from salIR, the first gene of the operon. In addition, a second promoter, at the 3' end of salIR, allows independent transcription of the MTase gene. Expression of salIR and salIM in Escherichia coli was investigated. The ENase gene was not expressed in the heterologous host, probably due to inactivity of the main promoter of the salI operon. In contrast to salIR, salIM was functional in E. coli. Preliminary S1 nuclease mapping experiments suggest that the alternative promoter of the MTase gene can initiate transcription in the heterologous, as well as in the homologous host.
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PMID:Expression of the SalI restriction-modification system of Streptomyces albus G in Escherichia coli. 760 97

The Bsp6I restriction and modification (R-M) system has been localized on the plasmid pXH13, naturally occurring in the Bacillus sp. strain RFL6. The genes coding for the Bsp6I R-M system, a Fnu4HI isoschizomer recognizing the sequence GCNGC, have been cloned in Escherichia coli by two steps. The nucleotide sequence of a 2126-bp region containing the genes for restriction endonuclease (ENase; bsp6IR) and DNA methyltransferase (MTase; bsp6IM) has been determined. The genes are separated by 99 bp and are arranged tandemly with bsp6IR preceding bsp6IM. The DNA sequence predicts an ENase of 174 amino acids (aa) (19.9 kDa) and a MTase of 315 aa (36.3 kDa). M.Bsp6I contains all the conserved aa sequence motifs characteristic for m5C-MTases. In addition, its variable region exhibits a slight similarity to the 5'-GCNGC-3'-specific target-recognition domain (TRD) from M.phi 3T. No aa sequence similarity was found between R.Bsp6I and M.Bsp6I, nor among R.Bsp6I and other known ENases. We have tested recombinant plasmids carrying the complete R-M system for their ability to transform native and pre-methylated Escherichia coli hosts. The results indicate that pre-methylation increases the efficiency of establishment of the complete R-M system. In addition, we have obtained orientation-dependent differences in transformation efficiency.
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PMID:Cloning and analysis of the plasmid-borne genes encoding the Bsp6I restriction and modification enzymes. 760 1

Overproduction of the NlaX DNA methyltransferase (M.NlaX) in an Escherichia coli host conferred resistance to SsoII restriction endonuclease (R.SsoII) digestion. This suggested an overlap of sequence specificity between M.NlaX and M.SsoII, the latter of which modifies the internal cytosine of the target sequence 5'-CCNGG-3'. A variant of M.NlaX (M.Sso/Nla), containing an N-terminal extension from M.SsoII, was also enzymatically active. Using deletion analysis, the N-terminal 71 amino-acid residues of M.SsoII were shown to be essential for modification activity.
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PMID:The SsoII and NlaX DNA methyltransferases: overproduction and functional analysis. 760 33

Type-II restriction-modification (R-M) systems comprise two enzymes, a DNA methyltransferase (MTase) and a restriction endonuclease (ENase), each of which specifically interact with the same 4-8 bp sequence. All type-II MTases share several amino acid (aa) sequence motifs, which makes an evolutionary relatedness among these enzymes probable. The type-II ENases, in contrast, except for some homologous isoschizomers, do not share significant aa sequence similarity. Therefore, ENases in general have been considered unrelated. Here we show that in addition to the analysis of the genotype (aa sequence), a comparison of the phenotype (recognition sequence) of these enzymes can provide independent information regarding evolutionary relationships, and thereby, help to analyze the significance of weak aa sequence similarities. Multistep Monte-Carlo analyses were employed to demonstrate that the recognition sequences of those ENases, which were found to be related by a progressive multiple aa sequence alignment, are more similar to each other than would be expected by chance. This analysis supports the notion that not only type-II MTases, but also type-II ENases did not arise independently in evolution, but rather evolved from one or a few primordial DNA-modifying and DNA-cleaving enzymes, respectively.
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PMID:Evidence for an evolutionary relationship among type-II restriction endonucleases. 762 20

Three genes that participate in the repair of DNA alkylation damage were recently cloned from Saccharomyces cerevisiae: the MGT1 O6-methylguanine DNA methyltransferase gene, the MAG 3-methyladenine DNA glycosylase gene, and the APN1 apurinic/apyrimidinic (AP) endonuclease gene. Altering the expression levels of these three genes produced significant changes in the S. cerevisiae spontaneous mutation rate. Spontaneous mutation increased in the absence of the MGT1 DNA methyltransferase, presumably because unrepaired, spontaneously produced, O6-alkylguanine lesions mispair during replication. Moreover, changing the ratios of the MAG 3-methyladenine DNA glycosylase and the APN1 AP endonuclease had profound effects on spontaneous mutation rates. In the absence of APN1, the overexpression of MAG increased spontaneous mutation, and the underexpression of MAG decreased spontaneous mutation. We infer that the MAG glycosylase acts upon spontaneously produced 3-alkyladenine and 7-alkylguanine DNA lesions to produce mutagenic abasic sites, and that if the repair of these abasic sites is not initiated by the APN1 AP endonuclease they cause mutations during replication. Our results indicate that eukaryotic cells harbor endogenous metabolites that alkylate nuclear DNA at both oxygens and nitrogens.
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PMID:In vivo evidence for endogenous DNA alkylation damage as a source of spontaneous mutation in eukaryotic cells. 768 84

NaeI, a type-II restriction-modification (R-M) system from the bacterium Nocardia aerocolonigenes, recognizes the sequence 5'-GCCGGC. The NaeI DNA methyltransferase (MTase)-encoding gene, naeIM, had been cloned previously in Escherichia coli [Van Cott and Wilson, Gene 74 (1988) 55-59]. However, none of these clones expressed detectable levels of the restriction endonuclease (ENase). The absence of the intact ENase-encoding gene (naeIR) within the isolated MTase clones was confirmed by recloning the MTase clones into Streptomyces lividans. The complete NaeI system was finally cloned using E. coli AP1-200 [Piekarowicz et al., Nucleic Acids Res. 19 (1991) 1831-1835] and less stringent MTase-selection conditions. The naeIR gene was expressed first by cloning into S. lividans, and later by cloning under control of a regulated promoter in an E. coli strain preprotected by the heterologous MspI MTase (M.MspI). The DNA sequence of the NaeI R-M system has been determined, analyzed and compared to previously sequenced R-M systems.
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PMID:Cloning and expression of the NaeI restriction endonuclease-encoding gene and sequence analysis of the NaeI restriction-modification system. 769 63

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