Procaryotic and eucaryotic traits of DNA methylation in spiroplasmas (mycoplasmas).

Differences in the type of base methylated (cytosine or adenine) and in the extent of methylation were detected by high-pressure liquid chromatography in the DNAs of five spiroplasmas. Nearest neighbor analysis and digestion by restriction enzyme isoschizomers also revealed differences in methylation sequence specificity. Whereas in Spiroplasma floricola and Spiroplasma sp. strain PPS-1 5-methylcytosine was found on the 5' side of each of the four major bases, the cytosine in Spiroplasma apis DNA was methylated only when its 3' neighboring base was adenine or thymine. In Spiroplasma sp. strain MQ-1 over 95% of the methylated cytosine was in C-G sequences. Essentially all of the C-G sequences in the MQ-1 DNA were methylated. Partially purified extracts of S. apis and Spiroplasma sp. strain MQ-1 were used to study substrate and sequence specificity of the methylase activity. Methylation by the MQ-1 enzyme was exclusively at C-G sequences, resembling in this respect eucaryotic DNA methylases. However, the MQ-1 methylase differed from eucaryotic methylases by showing high activity on nonmethylated DNA duplexes, low activity with hemimethylated DNA duplexes, and no activity on single-stranded DNA.     

Unusual Modification of Bacteriophage Mu DNA

Bacteriophage Mu DNA was labeled after induction in the presence of [2-(3)H]adenine or [8-(3)H]adenine. Both Mu mom(+).dam(+) DNA and Mu mom(-).dam(+) DNA have similar N(6)-methyladenine (MeAde) contents, as well as similar frequencies of MeAde nearest neighbors. Both DNAs are sensitive to in vitro cleavage by R.DpnI but resistant to cleavage by R.DpnII. These results indicate that the mom(+) protein does not alter the sequence specificity of the host dam(+) methylase to produce MeAde at new sites. However, we have discovered a new modified base, denoted A(x), in Mu mom(+).dam(+) DNA; approximately 15% of the adenine residues are modified to A(x). Although the precise nature of the modification is not yet defined, analysis by electrophoresis and chromatography indicates that the N(6)-amino group is not the site of modification, and that the added moiety contains a free carboxyl group. A(x) is not present in Mu mom(+).dam(+) or Mu mom(-).dam(+) phage DNA or in cellular DNA from uninduced Mu mom(+).dam(+) lysogens. These results suggest that expression of the dam(+) and mom(+) genes are required for the A(x) modification and that this modification is responsible for protecting Mu DNA against certain restriction nucleases. Mu mom(+).dam(-) DNA and Mu mom(-).dam(-) DNA contain a very low level of MeAde (ca. 1 MeAde per 5,000 adenine residues). Since the only nearest neighbor to MeAde appears to be cytosine, we suggest that the methylated sequence is 5'... C-A(*)-C... 3' and that this methylation is mediated by the EcoK modification enzyme.     

Determination of DNA sequences containing methylcytosine in Bacillus subtilis Marburg.

The methylcytosine-containing sequences in the DNA of Bacillus subtilis 168 Marburg (restriction-modification type BsuM) were determined by three different methods: (i) examination of in vivo-methylated DNA by restriction enzyme digestion and, whenever possible, analysis for methylcytosine at the 5' end; (ii) methylation in vitro of unmethylated DNA with B. subtilis DNA methyltransferase and determination of the methylated sites; and (iii) the methylatability of unmethylated DNA by B. subtilis methyltransferase after potential sites have been destroyed by digestion with restriction endonucleases. The results obtained by these methods, taken together, show that methylcytosine was present only within the sequence 5'-TCGA-3'. The presence of methylcytosine at the 5' end of the DNA fragments generated by restriction endonuclease AsuII digestion and the fact that in vivo-methylated DNA could not be digested by the enzyme XhoI showed that the recognition sequences of these two enzymes contained methylcytosine. As these two enzymes recognized a similar sequence containing a 5' pyrimidine (Py) and a 3' purine (Pu), 5'-PyTCGAPu-3', the possibility that methylcytosine is present in the complementary sequences 5'-TTCGAG-3' and 5'-CTCGAA-3' was postulated. This was verified by the methylation in vitro, with B. subtilis enzyme, of a 2.6-kilobase fragment of lambda DNA containing two such sites and devoid of AsuII or XhoI recognition sequences. By analyzing the methylatable sites, it was found that in one of the two PyTCGAPu sequences, cytosine was methylated in vitro in both DNA strands. It is concluded that the sequence 5'-PyTCGAPu-3' is methylated by the DNA methyltransferase (of cytosine) of B. subtilis Marburg.     

Sse8387I, a useful eight base cutter for mammalian genome analysis (influence of methylation on the activity of Sse8387I).

To develop restriction enzymes that are useful for genome analysis, we previously performed screening and isolated Sse8387I from Streptomyces sp. strain 8387. Sse8387I is a restriction enzyme that recognizes 5'-CCTGCA/GG-3' and cleaves DNA at the site shown by the diagonal (Nucleic Acid Res., 18, 5637-5640). The present study evaluated the effects of methylation that is important when Sse8387I is used for genome analysis. Sse8387I lost cleavage activity after methylation of adenine or methylation of cytosine at any site in the recognition sequence. However, the recognition sequence of Sse8387I contains no CG sequence, which is the mammalian methylation sequence. In addition, we evaluated the effects of methylation of CG at sites other than the recognition sequence. The cleavage activity of Sse8387I was maintained even when CG sequences were present immediately before or after, or near the recognition sequence, and cytosine was methylated. These results suggest that CG methylation does not affect the cleavage activity of Sse8387I. Therefore, Sse8387I seems to be very useful for mammalian genome analysis.     

Crystal structure of MboIIA methyltransferase

DNA methyltransferases (MTases) are sequence-specific enzymes which transfer a methyl group from S-adenosyl-L-methionine (AdoMet) to the amino group of either cytosine or adenine within a recognized DNA sequence. Methylation of a base in a specific DNA sequence protects DNA from nucleolytic cleavage by restriction enzymes recognizing the same DNA sequence. We have determined at 1.74 A resolution the crystal structure of a beta-class DNA MTase MboIIA (M.MboIIA) from the bacterium Moraxella bovis, the smallest DNA MTase determined to date. M.MboIIA methylates the 3' adenine of the pentanucleotide sequence 5'-GAAGA-3'. The protein crystallizes with two molecules in the asymmetric unit which we propose to resemble the dimer when M.MboIIA is not bound to DNA. The overall structure of the enzyme closely resembles that of M.RsrI. However, the cofactor-binding pocket in M.MboIIA forms a closed structure which is in contrast to the open-form structures of other known MTases.     

Strand scission of deoxyribonucleic acid by neocarzinostatin, auromomycin, and bleomycin: studies on base release and nucleotide sequence specificity

The nucleotide sequence specificity of neocarzinostatin (NCS), auromomycin (AUR), bleomycin (Blm), phleomycin (Phlm), and tallysomycin (Tlm) has been determined by using these antibiotics and their associated chromophores to create strand scissions in end-labeled restriction fragments of DNA and then determining the base sequence of the oligonucleotides formed. NCS and the NCS chromophore induce similar patterns of cleavage in DNA fragments labeled at the 5' terminus. The pattern produced by the AUR chromophore also resembles that of its holoantibiotic. Dithiothreitol enhances the rate of cleavage of DNA by the AUR chromophore but does not alter the sequence specificity. The results suggest that the polypeptide component of AUR and NCS serves primarily as a carrier for the chromophore. When tested with a fragment labeled at the 3' terminus, the products of NCS and AUR cleavage do not display the patterns of chemically produced oligonucleotides cleaved at phosphodiester bonds, suggesting that the 5' terminus is modified by a sugar fragment. NCS primarily attacks thymine (75% of the total bases attacked) and, to a lesser extent, adenine (19%) and cytosine (6%). AUR preferentially attacks guanine (67% of total bases), while attacking less often thymine (24%) and adenine (9%). Bleomycin and its analogues preferentially cleave purine--pyrimidine (5' leads to 3') and pyrimidine--pyrimidine (3' leads to 5') sequences. All (5' leads to 3') GT and GC sequences were cleaved. Phlm G and Phlm-Pep are less active than bleomycin toward purines while Tlm was more active. The patterns of cleavage produced by Blm A2 and Blm B6 are similar, while those produced by Phlm-Pep, Phlm G, Blm-B1', and Blm-Pep resemble one another. The cleavage pattern of Tlm shows quantitative differences from the other analogues tested. Differences between bleomycin and its analogues may be related to structural differences in these molecules.     

Evidence that cytosine residues within 5'-CCTGG-3' pentanucleotides can be methylated in human DNA independently of the methylating system that modifies 5'-CG-3' dinucleotides

In contrast to the complex sequence specificities of the prokaryotic DNA methylating systems, the mammalian machinery identified thus far methylates cytosine residues within the context of a 5'-CG-3' dinucleotide. To explore the possibility that cytosine residues that do not precede guanine may be independently methylated in mammalian DNA, we have examined a region of the human myogenic gene, Myf-3, which is not targeted by the methylating system that methylates 5'-CG-3' dinucleotides. Our investigations have revealed cytosine methylation within the 5'-CCTGG-3' pentanucleotides specified by the 0.8-kb Myf-3 probe. We have also found that in DNA from neoplastic cells, in which 5'-CG-3' dinucleotides within Myf-3 become abnormally hypermethylated, cytosine residues within 5'-CCTGG-3' pentanucleotides are not methylated. Moreover, methylation of 5'-CCTGG-3' pentanucleotides was not detected within the closely related Myf-4 gene, which is normally 5'-CG-3' hypermethylated. These findings indicate the existence of a system that methylates 5'-CCTGG-3' pentanucleotides independently of the system that methylates cytosine residues within 5'-CG-3' dinucleotides. It is possible that the 5'-CCTGG-3' methylating system influences the fate of foreign integrated DNA.     

New restriction endonuclease CviRI cleaves DNA at TG/CA sequences.

A new type II restriction endonuclease, CviRI, was isolated from virus XZ-6E infected chlorella cells. CviRI is the first restriction endonuclease to recognize the sequence 5'-TGCA-3' and cleaves DNA between the G and C residues to produce blunt-end termini. Methylation of the adenine or cytosine in 5'-TGCA-3' sequences prevents CviRI cleavage. Due to its sequence specificity, CviRI may be especially useful for detecting mutant alleles of many heritable human genetic diseases.     

On the chemical nature of DNA and RNA modification by a hemin model system.

In order to model the interaction of hemin with DNA and other polynucleotides, we have studied the degradation of DNA, RNA, and polynucleotides of defined structure by [meso-tetrakis(N-methyl-4-pyridyl)porphinato]manganese(III) (MnTMPP) + KHSO5. The activated porphyrin was shown to release adenine, thymine, and cytosine from DNA; RNA degradation afforded adenine, uracil, and cytosine. The same products were obtained from single- and double-stranded DNA oligonucleotides of defined sequence, and also from single-stranded DNA and RNA homopolymers. The overall yield of bases from the dode-canucleotide d(CGCT3A3GCG) was equal to 14% of the nucleotides present initially, indicating that each porphyrin catalyzed the release of approximately 4 bases. Although no guanine was detected as a product from any of the substrates studied, the ability of MnTMPP + KHSO5 to degrade guanine nucleotides was verified by the destruction of pGp, and by the appearance of bands corresponding to guanosine cleavage following treatment of 32P end labeled DNA restriction fragments with activated MnTMPP. Inspection of a number of sites of MnTMPP-promoted cleavage indicated that the process was sequence-selective, occurring primarily at G residues that were part of 5'-TG-3' or 5'-AG-3' sequences, or at T residues. Also formed in much greater abundance were alkali-labile lesions; these were formed largely at guanosine residues. Also studied was the degradation of a 47-nucleotide RNA molecule containing two hairpins. Degradation of the 5'-32P end labeled RNA substrate afforded no distinct, individual bands, suggesting that multiple modes of degradation may be operative.(ABSTRACT TRUNCATED AT 250 WORDS)     

Restriction endonuclease isoschizomers ItaI, BsoFI and Fsp4HI are characterised by differences in their sensitivities to CpG methylation.

BsoFI , ItaI and Fsp4HI are isoshizomers of Fnu4HI (5'-GC NGC-3'). Both Fnu4HI and BsoFI have previously been shown to be inhibited by cytosine-specific methylation within the recognition sequence. Fnu4HI is inhibited if either the internal cytosine at position 2 or the external cytosine at position 5 of the restriction sequence is methylated, but the precise nature of the methylation sensitivity of BsoFI is unclear from the literature. The methylation sensitivities of ItaI and Fsp4HI have not previously been reported. By methylating the plasmid pUC18 with M.SssI (a DNA cytosine-5'-methyltransferase with a specificity for CpG), we have determined that ItaI is sensitive only to methylation of internal CpG sites within the restriction sequence. The methylation sensitivity of Fsp4HI is identical to that of Fnu4HI, being inhibited by methylation of either internal CpG sites or overlapping CpG sites. BsoFI , like the other isoschizomers tested, is sensitive to a combination of internal and overlapping CpG methylation. BsoFI is also sensitive to overlapping CpG methylation (in the absence of internal CpG methylation) if CpG overlap with both sides of the recognition sequence. Sites containing one overlapping CpG (in the absence of internal CpG) are cut when methylated but show marked individual variation in their rates of cleavage. Considerable variation in the rate of cleavage by BsoFI is also observed at sites containing only internal methylated CpG. Some sites are cut slowly, whilst others fail to cut even after prolonged incubation with excess of enzyme.     

Restriction enzyme BstZ17I is sensitive to cytosine methylation

The cleavage patterns of a subset of restriction enzymes are blocked or impaired when a methylated CpG is overlapped with either the 5' or 3' end of the canonical restriction site. BstZ17I restriction endonuclease is a blunt-end cutter, which recognises the hexanucleotide sequence GTA(downward arrow)TAC. In this report, I show that the BstZ17I restriction enzyme is sensitive to cytosine methylation. Using both in vitro-methylated episomal plasmids and lambdaDNA, I demonstrate that the BstZ17I restriction enzyme is sensitive to cytosine methylation that occurs 3' and/or 5' of the canonical recognition sequence.     

Sequence specificity of DNA adenine methylase in the protozoan Tetrahymena thermophila.

The sequence specificity of the Tetrahymena DNA-adenine methylase was determined by nearest-neighbor analyses of in vivo and in vitro methylated DNA. In vivo all four common bases were found to the 5' side of N6-methyladenine, but only thymidine was 3'. Homologous DNA already methylated in vivo and heterologous Micrococcus luteus DNA were methylated in vitro by a partially purified DNA-adenine methylase activity isolated from Tetrahymena macronuclei. The in vitro-methylated sequence differed from the in vivo sequence in that both thymidine and cytosine were 3' nearest neighbors of N6-methyladenine.     

DNA interaction and nucleotide sequence cleavage of copper-streptonigrin

The copper-accelerated DNA binding and cleavage of streptonigrin have been investigated by 1H-NMR, ESR spectrometry and nucleotide sequence analysis. In the DNA breakage by the streptonigrin-Cu(II)-NADPH system, the somewhat preferred cleavage sites were several cytosine bases adjacent to purine bases such as GCGG(5'----3'), ACGC(5'----3') and GGCG(5'----3') sequences. The proton chemical shifts for the streptonigrin-Cu(I)-poly(dA-dT) complex demonstrated the interaction between the pyridine ring of the drug and the purine bases of the nucleic acid. Indeed, the temperature profile of adenine H-2 proton clearly showed the Tm to shift from 70 degrees C in the binary streptonigrin-poly(dA-dT) system to 75 degrees C in the ternary streptonigrin-Cu(I)-poly(dA-dT) system. The interaction of the streptonigrin-Cu(II) complex with DNA also induced the apparent change of ESR parameters. The tricyclic phenanthidium ring system including the copper chelate ring appears to significantly contribute to the present DNA interaction and cleavage of copper-streptonigrin.     

Single-strand and double-strand cleavage at half-modified and fully modified recognition sites for the restriction nucleases Sau3a and Taqi

The influence of cytosine methylation on the cleavage of DNA by the restriction nucleases Sau3A and TaqI has been investigated. Bovine satellite DNA fragments containing a GATCGA sequence, i.e. a Sau3A site overlapping with a TaqI site have been used in this study. The methylation of these fragments has been determined by sequence analysis. It has been found that a TaqI site (TCGA) methylated at cytosine in both DNA strands is still sensitive to double-strand cleavage. A Sau3A site (GATC), however, is rendered resistant to double-strand cleavage by methylation of a single cytosine. Fragments containing the "half-modified" Sau3A site are nicked in the unmethylated DNA strand. It has been shown by sequence analysis of nicked DNA that the single-strand break occurs at the same position which is cleaved in unmodified DNA.     

Arthrobacter viscosus DNA is modified at GATC sequence

Arthrobacter viscosus DNA was resistance to digestion by restriction enzymes that are sensitive to methylation of the cytosine residue (but not of adenine) within the GATC recognition sequence. Restriction enzymes sensitive to methylation of cytosine in other recognition sequences were not affected. A. viscosus DNA thus appeared to contain methylated cytosine specifically at the GATC sequence.     

Restriction enzyme digestion of hemimethylated DNA.

Hemimethylated duplex DNA of the bacteriophage phi X 174 was synthesized using primed repair synthesis is in vitro with E. coli DNA polymerase I followed by ligation to produce the covalently closed circular duplex (RFI). Single-stranded phi X DNA was used as a template, a synthetic oligonucleotide as primer and 5-methyldeoxycytidine-5'-triphosphate (5mdCTP) was used in place of dCTP. The hemimethylated product was used as substrate for cleavage by various restriction enzymes. Out of the 17 enzymes tested, only 5 (BstN I, Taq I, Hinc II, Hinf I and Hpa I) cleaved the hemimethylated DNA. Two enzymes (Msp I and Hae III) were able to produce nicks on the unmethylated strand of the cleavage site. Msp I, which is known to cleave at CCGG when the internal cytosine residue is methylated, does not cleave when both cytosines are methylated. Another enzyme, Apy I, cleaves at the sequence CCTAGG when the internal cytosine is methylated, but is inactive on hemimethylated DNA in which both cytosines are methylated. Hemimethylated molecules should be useful for studying DNA methylation both in vivo and in vitro.     

Determination of the recognition sites of cytosine DNA-methylases from Escherichia coli SK.

Two different cytosine DNA-methylases, NI and GII, are present in Escherichia coli SK. The GII methylase recognizes the five-member symmetric sequence: 5'...NpCpCpApGpGpN...3'. This sequence is identical with the recognition site of the hsp II type determined by RII plasmid but, in contrast to RII methylase, the GII enzyme methylates cytosine located on the 5' side of the site. By analogy with the isoshizomery of the restricting endonucleases, RII and GII DNA methylaeses may be called isomethymers which recognize the same site but methylate different bases. Since the phage of the SK and hsp II phenotypes is effectively restricted in respective cells it may be assumed that the isomethymeric modification does not provide any protection against the corresponding restrictases. NI methylase recognizes the five-member symmetric site which represents an inverted sequence of the GII site: 5'...NpGpGpApCpCpN...3'. In this case cytosine at the 3'-end of the recognition site is methylated.     

Recognition sequence of the dam methylase of Escherichia coli K12 and mode of cleavage of Dpn I endonuclease.

The recognition sequence for the dam methylase of Escherichia coli K12 has been determined directly by use of in vivo methylated ColE1 DNA or DNA methylated in vitro with purified enzyme. The methylase recognizes the symmetric tetranucleotide d(pG-A-T-C) and introduces two methyl groups per site in duplex DNA with the product of methylation being 6-methylaminopurine. This work has also demonstrated that Dpn I restriction endonuclease cleaves on the 3' side of the modified adenine within the methylated sequence to yield DNA fragments possessing fully base-paired termini. All sequences in ColE1 DNA methylated by the dam enzyme are subject to double strand cleavage by Dpn I endonuclease. Therefore, this restriction enzyme can be employed for mapping the location of sequences possessing the dam modification.     

Cytosine methylation of the sequence GATC in a mycoplasma

Mycoplasma virus L2 is subject to host-specific restriction and modification in Acholeplasma laidlawii strains JA1 and K2. We have examined the DNAs from both host cells and viruses propagated on these strains with respect to susceptibility to cleavage by restriction endonucleases and for DNA base modifications. We show that, in strain K2 and L2 virus grown on K2 cells, cytosine in the sequence GATC is methylated to 5-methylcytosine and, although strain K2 and L2 viruses grown on K2 contain N6-methyladenine in their DNA, adenine in the sequence GATC is not methylated. In contrast to K2, strain JA1 and L2 virus grown on JA1 cells contain no detectable methylated bases. It is not known which of the methylated bases in K2 is the basis for the K2 restriction-modification system operative on L2 virus.