Complementary action of restriction enzymes endo R-DpnI and Endo R-DpnII on bacteriophage f1 DNA

Bacteriophage f1 duplex DNA was isolated from Escherichia coli strains containing different DNA methylases and assayed for its sensitivity to endonucleolytic cleavage by the enzymes endo R · DpnI and endo R · DpnII. The former enzyme is specific for methylated DNA, the latter for unmethylated DNA (Lacks &; Greenberg, 1975). The E. coli dam methylase was found to be responsible for making f1 resistant to endo R · DpnII and sensitive to endo R · DpnI. Endo R · DpnI cleaved f 1 DNA from dam⁺ cells at four sites. Additional methylation by enzymes other than the dam methylase gave no further cleavage. Endo R · DpnII cleaved f1 DNA from dam^? cells also at four sites to give restriction fragments identical to those obtained with endo R · DpnI cleavage. Thus, the two enzymes are complementary in that they recognize and cleave within the same DNA sequence, one if the DNA is methylated, the other if it is unmethylated. DNA duplexes containing one methylated strand (dam ⁺) and one unmethylated strand (dam^?) were prepared in vitro. These methylated hybrids were refractory to endonucleolytic cleavage by both endo R · DpnI and endo R · DpnII. Neither enzyme, therefore, appears to make even a single strand break at a methylated/unmethylated hybrid site.     

The effect of B specific restriction and modification of DNA on linkage relationships in f1 bacteriophage. II. Evidence for a heteroduplex intermediate in f1 recombination

We have analyzed the results of three gene II amber × gene II amber f1 phage crosses. Each was done in a non-restricting (K) host, and in a restricting (B) host. In each cross, only one parent was sensitive to B restriction. The other parent was protected from B restriction, either because of a combination of genetic mutation at one site governing sensitivity to B restriction, and B specific modification at the other, or because of genetic mutation at both sites. In all cases, B restriction resulted in the disruption of linkage relationships between the gene II region and the unselected sensitivity site markers.Previously we have shown that when such crosses involve a protected parent which is B modified at both sensitivity sites, linkage relationships remain the same under restricting and non-restricting conditions. Hence, the SB sites seem to manifest a striking marker effect in restricted crosses in which protection is conferred by mutation rather than modification. Taken together, these results imply that, in a restricted cross, the B host specificity system can distinguish a protected parent which is B modified from one which is a sensitivity site mutant.Since such a distinction could be made most easily on an intermediate structure containing hybrid DNA, we interpret these results in terms of a recombination mechanism mediated by an asymmetric heteroduplex.     

A unique family of Mrr-like modification-dependent restriction endonucleases

Mrr superfamily of homologous genes in microbial genomes restricts modified DNA in vivo. However, their biochemical properties in vitro have remained obscure. Here, we report the experimental characterization of MspJI, a remote homolog of Escherichia coli’s Mrr and show it is a DNA modification-dependent restriction endonuclease. Our results suggest MspJI recognizes ^mCNNR (R = G/A) sites and cleaves DNA at fixed distances (N₁₂/N₁₆) away from the modified cytosine at the 3′ side (or N₉/N₁₃ from R). Besides 5-methylcytosine, MspJI also recognizes 5-hydroxymethylcytosine but is blocked by 5-glucosylhydroxymethylcytosine. Several other close homologs of MspJI show similar modification-dependent endonuclease activity and display substrate preferences different from MspJI. A unique feature of these modification-dependent enzymes is that they are able to extract small DNA fragments containing modified sites on genomic DNA, for example ∼32 bp around symmetrically methylated CG sites and ∼31 bp around methylated CNG sites. The digested fragments can be directly selected for high-throughput sequencing to map the location of the modification on the genomic DNA. The MspJI enzyme family, with their different recognition specificities and cleavage properties, provides a basis on which many future methods can build to decode the epigenomes of different organisms.     

Deoxyribonucleic acid modification by intermediate-type modification mutants of Escherichia coli K-12 and B.

The modification of bacteriophages grown on r-m+/- restriction and modification mutants of Escherichia coli K-12 or B appears to be related to the number of restriction-specific sites in the viral genome. Bacteriophage fd and its mutant U1 fd, which carry two and one B-specific sites, respectively, are not modified in vivo by rB-mB+/- mutant strains. In vitro treatment of fd RF-B+/- deoxyribonucleic acid (DNA) or U1 fd RF-B+/- DNA by endo R-Eco B results in cleavage of the substrate DNA. Lambda bacteriophage, after growth in r-m+/- mutant host strains (lambda-K+/- or lambda-B+/-), is partially protected from in vivo degradation by wild-type homospecific strains. Its efficiency of plating on these strains is approximately 10(-2). However, a hybrid phi80-lambda phage which carries only one K-specific site (sklambda-1) is not modified by rK-mK+/- strains. Labeled DNAs from lambda-B+/- and lambda-K+/- phages were used as substrates for endo R-Eco B and endo R-Eco K nucleases. Zonal centrifugation analysis of the products of the reactions indicate that rK-mK+/- mutants do not protect lambda DNA from in vitro degradation by endo R-Eco K. In contrast, rB-mB+/- mutants appear to partially protect lambda DNA from attack by endo R-Eco B.     

Promiscuous methylation of non-canonical DNA sites by HaeIII methyltransferase

The cytosine C5 methyltransferase M.HaeIII recognises and methylates the central cytosine of its canonical site GGCC. Here we report that M.HaeIII can also, with lower efficiency, methylate cytosines located in a wide range of non-canonical sequences. Using bisulphite sequencing we mapped the methyl- cytosine residues in DNA methylated in vitro and in vivo by M.HaeIII. Methyl-cytosine residues were observed in multiple sequence contexts, most commonly, but not exclusively, at star sites (sites differing by a single base from the canonical sequence). The most frequently used star sites had changes at positions 1 and 4, but there is little or no methylation at star sites changed at position 2. The rate of methylation of non-canonical sites can be quite significant: a DNA substrate lacking a canonical site was methylated by M.HaeIII in vitro at a rate only an order of magnitude slower than an otherwise identical substrate containing the canonical site. In vivo methylation of non-canonical sites may therefore be significant and may have provided the starting point for the evolution of restriction–modification systems with novel sequence specificities.     

Different methylation pattern of melon satellite DNA sequences in hypocotyl and callus tissues

Satellite DNA sequences from Cucumis melo have been examined with respect to modification at CCGG sequences in hypocotyls and in callus tissues. For this purpose, restriction fragments given by HpaII and MspI were compared (both enzymes recognize CCGG sequences but have different sensitivity to methylation at this site). Whereas the methylation level of satellite DNA sequences is on average higher in hypocotyls than in callus tissues, the comparison of partially methylated repeat units of satellite DNA reveals that in callus tissues, all methylated restriction sites are doubly methylated.     

Mycoplasma restriction: identification of a new type of restriction specificity for DNA containing 5-methylcytosine.

Mycoplasma bacteriophage L51 single-stranded DNA and L2 double-stranded DNA are host cell modified and restricted when they transfect Acholeplasma laidlawii JA1 and K2 cells. The L51 genome has a single restriction endonuclease MboI site (recognition sequence GATC), which contains 5-methylcytosine when the DNA is isolated from L51 phage grown in K2 cells but is unmethylated when the DNA is from phage grown in JA1 cells. This GATC sequence is nonessential, since an L51 mutant in which the MboI site was deleted was still viable. DNA from this deletion mutant phage was not restricted during transfection of either strain K2 or JA1. Therefore, strain K2 restricts DNA containing the sequence GATC, and strain JA1 restricts DNA containing the sequence GAT 5-methylcytosine. We conclude that K2 cells have a restriction system specific for DNA containing the sequence GATC and protect their DNA by methylating cytosine in this sequence. In contrast, JA1 cells (which contain no methylated DNA bases) have a newly discovered type of restriction-modification system. From results of studies of the restriction of specifically methylated DNAs, we conclude that JA1 cells restrict DNA containing 5-methylcytosine, regardless of the nucleotide sequence containing 5-methylcytosine. This is the first report of a DNA restriction activity specific for a single (methylated) base. Modification in this system is the absence of cytosine methylating activity. A restriction-deficient variant of strain JA1, which retains the JA1 modification phenotype, was isolated, indicating that JA1 cells have a gene product with restriction specificity for DNA containing 5-methylcytosine.     

Chemical modification of Ce(IV)/EDTA-based artificial restriction DNA cutter for versatile manipulation of double-stranded DNA

A monophosphate group was attached to the terminus of pseudo-complementary peptide nucleic acid (pcPNA), and two of thus modified pcPNAs were combined with Ce(IV)/EDTA for site-selective hydrolysis of double-stranded DNA. The site-selective DNA scission was notably accelerated by this chemical modification of pcPNAs. These second-generation artificial restriction DNA cutters (ARCUTs) differentiated the target sequence so strictly that no scission occurred even when only one DNA base-pair was altered to another. By using two of the activated ARCUTs simultaneously, DNA substrate was selectively cut at two predetermined sites, and the desired fragment was clipped and cloned. The DNA scission by ARCUT was also successful even when the target site was methylated by methyltransferase and protected from the corresponding restriction enzyme. Furthermore, potentiality of ARCUT for manipulation of huge DNA has been substantiated by site-selective scission of genomic DNA of Escherichia coli (composed of 4,600,000bp) at the target site. All these results indicate promising applications of ARCUTs for versatile purposes.     

Endo R DpnI restriction of Escherichia coli DNA synthesized in vitro. Evidence that the ends of Okazaki pieces are determined by template deoxynucleotide sequence.

A restriction enzyme from Diplococcus pneumoniae, Endo R DpnI, cuts methylated DNA on cellophane discs into pieces which are about the same size as Okazaki pieces.DNA was synthesized in vitro on cellophane discs in the presence of β-nicotinamide mononucleotide to prevent joining of Okazaki pieces. This DNA was methylated by the addition of S-adenosyl methionine to the reaction mixture. When Endo R DpnI was used to cut methylated DNA made in vitro in the presence of S-adenosyl methionine and β-nicotinamide mononucleotide, no decrease in sedimentation of the Okazaki pieces was observed. Control experiments demonstrated that Okazaki pieces were methylated in vitro and that Endo R DpnI was capable of cutting double-stranded DNA containing methylated Okazaki pieces, that is, synthesized in β-nicotinamide mononucleotide and S-adenosyl methionine.These results are interpreted to mean that the ends of Okazaki pieces are non-randomly distributed with respect to 6-methyl adenine residues.     

Host specificity of DNA produced by Escherichia coli : XV. The role of nucleotide methylation in in vitro B-specific modification

It is shown that in vitro Escherichia coli strain B-specific modification of the replicative form of bacteriophage fd DNA is accompanied by the methylation of certain adenine moieties to form N-6-methyladenine. The reaction follows first order kinetics and saturation is reached when about four adenines are methylated per replicative form. No methyl groups are transferred to B-modified DNA.     

The DNA sequence recognised by the HinfIII restriction endonuclease

HinfIII is a type III restriction enzyme (Kauc &; Piekarowicz, 1978) isolated from Haemophilus influenzae Rf. Like other type III restriction endonucleases, the enzyme also catalyses the modification of susceptible DNA. It requires ATP for DNA cleavage and S-adenosyl methionine for DNA methylation. We have determined the DNA sequence recognised by HinfIII to be:

$\text{5′-C-G-A-A-T-3′}\text{·····3′-G-C-T-T-A-5′}$

In restriction, the enzyme cleaves the DNA about 25 base-pairs to the right of this sequence. In the modification reaction only one of the strands is methylated, that containing the 5′-C-G-A-A-T-3′ sequence.     

Heterogeneity of pumpkin ribosomal DNA

The ribosomal DNA (rDNA) of Cucurbita pepo L. has been found to consist of tandemly arrayed repeat units, most of which are 10 kilobases in length. Thirty-six repeat units, cloned into the HindIII site of pACYC 177, fall into seven classes which differ from each other in length and/or nucleotide sequence. Most of the heterogeneity occurs in noncoding portions of the repeat unit although there is some nucleotide sequence variation in the coding portion as well. Heterogeneity of base modification was observed in genomic rDNA of which two examples are: (a) all of the repeat units have three BamHI sites, one of which is unavailable for restriction in about half of the units and (b) all of the CCGG sites except one are methylated at the internal cytidine in many of the units; a second site is unmethylated in some of the units and in a very few units a third site remains unmethylated.     

SELEX_DB: a database on in vitro selected oligomers adapted for recognizing natural sites and for analyzing both SNPs and site-directed mutagenesis data

SELEX_DB is an online resource containing both the experimental data on in vitro selected DNA/RNA oligomers (aptamers) and the applets for recognition of these oligomers. Since in vitro experimental data are evidently system-dependent, the new release of the SELEX_DB has been supplemented by the database SYSTEM storing the experimental design. In addition, the recognition applet package, SELEX_TOOLS, applying in vitro selected data to annotation of the genome DNA, is accompanied by the cross-validation test database CROSS_TEST discriminating the sites (natural or other) related to in vitro selected sites out of random DNA. By cross-validation testing, we have unexpectedly observed that the recognition accuracy increases with the growth of homology between the training and test sets of protein binding sequences. For natural sites, the recognition accuracy was lower than that for the nearest protein homologs and higher than that for distant homologs and non-homologous proteins binding the common site. The current SELEX_DB release is available at http://wwwmgs.bionet.nsc.ru/mgs/systems/selex/.     

DNA modification by sulfur: analysis of the sequence recognition specificity surrounding the modification sites

The Dnd (DNA degradation) phenotype, reflecting a novel DNA modification by sulfur in Streptomyces lividans 1326, was strongly aggravated when one (dndB) of the five genes (dndABCDE) controlling it was mutated. Electrophoretic banding patterns of a plasmid (pHZ209), reflecting DNA degradation, displayed a clear change from a preferential modification site in strain 1326 to more random modifications in the mutant. Fourteen randomly modifiable sites on pHZ209 were localized, and each seemed to be able to be modified only once. Residues in a region (5′-c–cGGCCgccg-3′) including a highly conserved 4-bp central core (5′-GGCC-3′) in a well-documented preferential modification site were assessed for their necessity by site-directed mutagenesis. While the central core (GGCC) was found to be stringently required in 1326 and in the mutant, ‘gccg’ flanking its right could either abolish or reduce the modification frequency only in the mutant, and two separate nucleotides to the left had no dramatic effect. The lack of essentiality of DndB for S-modification suggests that it might only be required for enhancing or stabilizing the activity of a protein complex at the required preferential modification site, or resolving secondary structures flanking the modifiable site(s), known to constitute an obstacle for efficient modification.     

The c1 repressor of bacteriophage P1: I. Isolation of the c1 protein and determination of the P1 DNA region to which it Binds

A bacteriophage P1-specific DNA binding protein has been partially purified from P1-infected Escherichia coli and identified as the P1c1 repressor. This protein is absent from non-suppressing cells infected with a P1c1 amber mutant. The binding activity of the protein isolated from cells infected with a c1ts mutant is thermolabile in vitro, so the repressor protein is the product of the c1 gene. Studies on P1 DNA fragments generated by restriction endonuclease digestion indicate that the c1 repressor binds preferentially in vitro at a site or sites located close to the c1 gene itself.     

Restriction of bacteriophage lambda by Escherichia coli K

Derivatives of phage lambda, for which the numbers and positions of the recognition sites for endonuclease R. Eco_k are known, were used as substrates for the Escherichia coli K restriction system in vivo and in vitro. A single unmodified recognition site was sufficient for a DNA molecule to be bound and broken by the K restriction enzyme. Although discrete fragments of DNA were not produced, the breaks were made preferentially in the proximity of the recognition site. Breakage of a DNA molecule with only one recognition site required a 10 to 40-fold higher concentration of restriction enzyme than breakage of a DNA molecule with two or more recognition sites, but these substrates were all equally effective in a binding assay for the enzyme.The polynucleotide kinase reaction provided no evidence for new 5′-terminal sequences generated by restriction in vitro; the 5′ termini were either refractory to the polynucleotide kinase reaction or had no sequence specificity.     

Sequence specificity of the P1 modification methylase (M.Eco P1) and the DNA methylase (M.Eco dam) controlled by the Escherichia coli dam gene.

Labeled oligonucleotides have been fractionated from pancreatic DNase digests of DNA that had been methylated in vitro with the P1 modification enzyme (M·Eco P1) or with the DNA-adenine methylase (M·Eco dam) controlled by the Escherichia coli dam gene. The sequences of methylated oligonucleotides were established for M·Eco dam modification of calf thymus DNA. The results show that M·Eco dam inethylates adenine residues contained in the twofold symmetrical sequence, 5′ … G-A-T-C … 3′. The sequence for the site methylated by M·Eco P1 has also been deduced; we propose that M·Eco P1 modification produces the following methylated pentameric sequence: 5′ … A-G-A¹-C-Py … 3′ (where $\text{A}{}^1\text{= N}{}^6$ methyladenine and Py is C or T).     

Methylation and cleavage sequences of the EcoP1 restriction-modification enzyme.

EcoP1 is a restriction modification enzyme encoded by bacteriophage P1. It requires ATP for cleavage and S-adenosyl methionine for methylation of DNA. We have mapped the sites of both cleavage and methylation in simian virus 40 DNA and determined their sequences. The enzyme methylates the sequence A-G-mA-C-C and cuts the DNA 25 to 27 base-pairs from the site of methylation in the 3′ direction, with a two to four base-pair stagger between cuts. Consistent with the fact that the methylation sequence is asymmetric, the enzyme methylates only one strand in vitro. One variant of simian virus 40 has acquired an additional EcoP1 methylation and cleavage site by changing a A-G-A-A-C sequence to A-G-A-C-C.     

Restriction and modification in B. subtilis

Summary The content of 5-methylcytosine (5MC) and 6-methyladenine (6MA) in modified and nonmodified DNAs from B. subtilis and B. subtilis phage SPP1 were determined. Nonmodified SPP1 · O DNA contains about 15 5MC residues/molecule. Each modified SPP1 ·R DNA molecule carries 190 modification specific methyl groups. This number is sufficient to account for modification of the 80 restriction sites in SPP1 DNA (Bron and Murray, 1975) against endo R · Bsu R, assuming each modified site contains two 5MC residues. Resistance of SP01 DNA against endo R · Bsu R restriction both in vivo and in vitro is probably not due to methylation of endo R·Bsu R recognition sites.     

A sequence specific endonuclease from Micrococcus radiodurans

A new sequence specific endonuclease, MraI has been purified from Micrococcus radiodurans. This enzyme cleaves bacteriophage λ DNA at three sites, adenovirus type 2 DNA at more than 12 sites and has a unique site on ΦX174 DNA. It has no sites on SV40, PM2 and pBR322 DNA. The three sites on phage λ DNA are different from those cleaved by SmaI, XmaI and XorII. The sites of cleavage are located at 0.424, 0.447 and 0.834 fractional lengths on the physical map of λ DNA. MraI is shown to be an isoschizomer of SacII and SstII recognizing the palindromic nucleotide sequence ′5-CCGC↓GG-3′. The enzyme shows an absolute requirement of Mg²⁺, but is active in the absence of added 2-mercaptoethanol. The enzyme shows activity at a broad range of temperature and pH with an optimum at 45°C and pH 7.0. MraI represents the first restriction enzyme from a bacterium whose DNA lacks modified methylated bases.