Interaction of AluI, Cfr6I and PvuII restriction-modification enzymes with substrates containing either N4-methylcytosine or 5-methylcytosine

Transient N4 -Acyl-DNA Protection against Cleavage by Restriction Endonucleases

A set of five N⁴ -acyl-modified 2'-deoxycytidine 5'-triphosphates were incorporated into modified DNA by using phi29 DNA polymerase, and cleavage by selected restriction endonucleases was studied. Modified DNA containing N⁴ -acyl functional groups in either one or both strands of a DNA molecule was resistant to the majority of restriction enzymes tested, whereas modifications outside of the recognition sequences were well tolerated. The N⁴ -acylated cytidine derivatives were subjected to competitive nucleotide incorporation by using phi29 DNA polymerase, showing that a high-fidelity phi29 DNA polymerase efficiently used the modified analogues in the presence of its natural counterpart. These N⁴ modifications were also demonstrated to be easily removed in an aqueous ethanolamine solution, in which all steps, including primer extension, demodification, and cleavage by restriction endonuclease, could be performed in a one-pot procedure that eliminated additional purification stages. It is suggested that N⁴ -modified nucleotides are promising building blocks for a programmable; transient; and, most importantly, straightforward DNA protection against specific endonucleases.

Overexpression of a lethal methylase, M.TneDI, in E. coli BL21(DE3)

A pET-based vector pDH21 expressing the methylase, M.TneDI (recognizing CGCG) from Thermotoga was constructed, and transformed into E. coli BL21(DE3). Despite E. coli BL21(DE3) being McrBC positive, 30 transformants were isolated, which were suspected to be McrBC(-) mutants. The overexpression of M.TneDI was verified by SDS-PAGE analysis. Compared to the previously constructed pJC340 vector, a pACYC184 derivative expressing M.TneDI from a tet promotor, the newly constructed pDH21 vector improved the expression of the methylase about fourfold, allowing complete protection of DNA substrates. This study not only demonstrates a practical approach to overexpressing potential lethal proteins in E. coli but also delivers a production strain of M.TneDI that may be useful in various in vitro methylation applications.

Translational independence between overlapping genes for a restriction endonuclease and its transcriptional regulator

Background

Most type II restriction-modification (RM) systems have two independent enzymes that act on the same DNA sequence: a modification methyltransferase that protects target sites, and a restriction endonuclease that cleaves unmethylated target sites. When RM genes enter a new cell, methylation must occur before restriction activity appears, or the host's chromosome is digested. Transcriptional mechanisms that delay endonuclease expression have been identified in some RM systems. A substantial subset of those systems is controlled by a family of small transcription activators called C proteins. In the PvuII system, C.PvuII activates transcription of its own gene, along with that of the downstream endonuclease gene. This regulation results in very low R.PvuII mRNA levels early after gene entry, followed by rapid increase due to positive feedback. However, given the lethal consequences of premature REase accumulation, transcriptional control alone might be insufficient. In C-controlled RM systems, there is a ± 20 nt overlap between the C termination codon and the R (endonuclease) initiation codon, suggesting possible translational coupling, and in many cases predicted RNA hairpins could occlude the ribosome binding site for the endonuclease gene.

Results

Expression levels of lacZ translational fusions to pvuIIR or pvuIIC were determined, with the native pvuII promoter having been replaced by one not controlled by C.PvuII. In-frame pvuIIC insertions did not substantially decrease either pvuIIC-lacZ or pvuIIR-lacZ expression (with or without C.PvuII provided in trans). In contrast, a frameshift mutation in pvuIIC decreased expression markedly in both fusions, but mRNA measurements indicated that this decrease could be explained by transcriptional polarity. Expression of pvuIIR-lacZ was unaffected when the pvuIIC stop codon was moved 21 nt downstream from its WT location, or 25 or 40 bp upstream of the pvuIIR initiation codon. Disrupting the putative hairpins had no significant effects.

Conclusions

The initiation of translation of pvuIIR appears to be independent of that for pvuIIC. Direct tests failed to detect regulatory rules for either gene overlap or the putative hairpins. Thus, at least during balanced growth, transcriptional control appears to be sufficiently robust for proper regulation of this RM system.

Tuning the relative affinities for activating and repressing operators of a temporally regulated restriction-modification system

Most type II restriction-modification (R-M) systems produce separate endonuclease (REase) and methyltransferase (MTase) proteins. After R-M genes enter a new cell, MTase activity must appear before REase or the host chromosome will be cleaved. Temporal control of these genes thus has life-or-death consequences. PvuII and some other R-M systems delay endonuclease expression by cotranscribing the REase gene with the upstream gene for an autogenous activator/repressor (C protein). C.PvuII was previously shown to have low levels early, but positive feedback later boosts transcription of the C and REase genes. The MTase is expressed without delay, and protects the host DNA. C.PvuII binds to two sites upstream of its gene: O_L, associated with activation, and O_R, associated with repression. Even when symmetry elements of each operator are made identical, C.PvuII binds preferentially to O_L. In this study, the intra-operator spacers are shown to modulate relative C.PvuII affinity. In light of a recently reported C.Esp1396I-DNA co-crystal structure, in vitro and in vivo effects of altering O_L and O_R spacers were determined. The results suggest that the GACTnnnAGTC consensus is the primary determinant of C.PvuII binding affinity, with intra-operator spacers playing a fine-tuning role that affects mobility of this R-M system.

Cell death upon epigenetic genome methylation: a novel function of methyl-specific deoxyribonucleases

BACKGROUND

Alteration in epigenetic methylation can affect gene expression and other processes. In Prokaryota, DNA methyltransferase genes frequently move between genomes and present a potential threat. A methyl-specific deoxyribonuclease, McrBC, of Escherichia coli cuts invading methylated DNAs. Here we examined whether McrBC competes with genome methylation systems through host killing by chromosome cleavage.

RESULTS

McrBC inhibited the establishment of a plasmid carrying a PvuII methyltransferase gene but lacking its recognition sites, likely through the lethal cleavage of chromosomes that became methylated. Indeed, its phage-mediated transfer caused McrBC-dependent chromosome cleavage. Its induction led to cell death accompanied by chromosome methylation, cleavage and degradation. RecA/RecBCD functions affect chromosome processing and, together with the SOS response, reduce lethality. Our evolutionary/genomic analyses of McrBC homologs revealed: a wide distribution in Prokaryota; frequent distant horizontal transfer and linkage with mobility-related genes; and diversification in the DNA binding domain. In these features, McrBCs resemble type II restriction-modification systems, which behave as selfish mobile elements, maintaining their frequency by host killing. McrBCs are frequently found linked with a methyltransferase homolog, which suggests a functional association.

CONCLUSIONS

Our experiments indicate McrBC can respond to genome methylation systems by host killing. Combined with our evolutionary/genomic analyses, they support our hypothesis that McrBCs have evolved as mobile elements competing with specific genome methylation systems through host killing. To our knowledge, this represents the first report of a defense system against epigenetic systems through cell death.

Regulatory circuit based on autogenous activation-repression: roles of C-boxes and spacer sequences in control of the PvuII restriction-modification system

Type II restriction-modification (R-M) systems comprise a restriction endonuclease (REase) and a protective methyltransferase (MTase). After R-M genes enter a new cell, MTase must appear before REase or the chromosome will be cleaved. PvuII and some other R-M systems achieve this delay by cotranscribing the REase gene with the gene for an autogenous transcription activator (the controlling or 'C' protein C.PvuII). This study reveals, through in vivo titration, that C.PvuII is not only an activator but also a repressor for its own gene. In other systems, this type of circuit can result in oscillatory behavior. Despite the use of identical, symmetrical C protein-binding sequences (C-boxes) in the left and right operators, C.PvuII showed higher in vitro affinity for O(L) than for O(R), implicating the spacer sequences in this difference. Mutational analysis associated the repression with O(R), which overlaps the promoter -35 hexamer but is otherwise dispensable for activation. A nonrepressing mutant exhibited poor establishment in new cells. Comparing promoter-operator regions from PvuII and 29 R-M systems controlled by C proteins revealed that the most-highly conserved sequence is the tetranucleotide spacer separating O(L) from O(R). Any changes in that spacer reduced the stability of C.PvuII-operator complexes and abolished activation.

Mobility of a restriction-modification system revealed by its genetic contexts in three hosts

The flow of genes among prokaryotes plays a fundamental role in shaping bacterial evolution, and restriction-modification systems can modulate this flow. However, relatively little is known about the distribution and movement of restriction-modification systems themselves. We have isolated and characterized the genes for restriction-modification systems from two species of Salmonella, S. enterica serovar Paratyphi A and S. enterica serovar Bareilly. Both systems are closely related to the PvuII restriction-modification system and share its target specificity. In the case of S. enterica serovar Paratyphi A, the restriction endonuclease is inactive, apparently due to a mutation in the subunit interface region. Unlike the chromosomally located Salmonella systems, the PvuII system is plasmid borne. We have completed the sequence characterization of the PvuII plasmid pPvu1, originally from Proteus vulgaris, making this the first completely sequenced plasmid from the genus Proteus. Despite the pronounced similarity of the three restriction-modification systems, the flanking sequences in Proteus and Salmonella are completely different. The SptAI and SbaI genes lie between an equivalent pair of bacteriophage P4-related open reading frames, one of which is a putative integrase gene, while the PvuII genes are adjacent to a mob operon and a XerCD recombination (cer) site.

Recognition of native DNA methylation by the PvuII restriction endonuclease

Recognizing the methylation status of specific DNA sequences is central to the function of many systems in eukaryotes and prokaryotes. Restriction-modification systems have to distinguish between 'self' and 'non-self' DNA and depend on the inability of restriction endonucleases to cleave their DNA substrates when the DNA is appropriately methylated. These endonucleases thus provide a model system for studying the recognition of DNA methylation by proteins. We have characterized the interaction of R.PVU:II with DNA containing the physiologically relevant N4-methylcytosine modification. R.PVU:II binds (N4m)C-modified DNA and cleaves it very slowly. Methylated strands in hemimethylated duplexes were cleaved at a higher rate than in fully methylated duplexes, in parallel with a higher binding affinity for hemimethylated DNA. The co-crystal structures of R.PVU:II-DNA, together with a mutagenesis study, have implicated specific amino acids in recognition of the methylatable base; one of these is His84. We report that replacing His84 with Ala reduced the rate of cleavage of unmodified DNA but, in contrast, slightly increased the cleavage of (N4m)C-modified DNA.

Role and mechanism of action of C. PvuII, a regulatory protein conserved among restriction-modification systems

The PvuII restriction-modification system is a type II system, which means that its restriction endonuclease and modification methyltransferase are independently active proteins. The PvuII system is carried on a plasmid, and its movement into a new host cell is expected to be followed initially by expression of the methyltransferase gene alone so that the new host's DNA is protected before endonuclease activity appears. Previous studies have identified a regulatory gene (pvuIIC) between the divergently oriented genes for the restriction endonuclease (pvuIIR) and modification methyltransferase (pvuIIM), with pvuIIC in the same orientation as and partially overlapping pvuIIR. The product of pvuIIC, C. PvuII, was found to act in trans and to be required for expression of pvuIIR. In this study we demonstrate that premature expression of pvuIIC prevents establishment of the PvuII genes, consistent with the model that requiring C. PvuII for pvuIIR expression provides a timing delay essential for protection of the new host's DNA. We find that the opposing pvuIIC and pvuIIM transcripts overlap by over 60 nucleotides at their 5' ends, raising the possibility that their hybridization might play a regulatory role. We furthermore characterize the action of C. PvuII, demonstrating that it is a sequence-specific DNA-binding protein that binds to the pvuIIC promoter and stimulates transcription of both pvuIIC and pvuIIR into a polycistronic mRNA. The apparent location of C. PvuII binding, overlapping the -10 promoter hexamer and the pvuIICR transcriptional starting points, is highly unusual for transcriptional activators.

Asp34 of PvuII endonuclease is directly involved in DNA minor groove recognition and indirectly involved in catalysis

The PvuII restriction endonuclease is a homodimer that recognizes and cleaves the DNA sequence 5'-CAGCTG-3' in double-stranded DNA, and the structure of this enzyme has been reported. In the wild-type enzyme, Asp34 interacts with the internal guanine of the recognition sequence on the minor groove side. The Asp34 codon was altered to specify Gly (D34G), and in vitro studies have revealed that the D34G protein has lost binding specificity for the central G.C base-pairs, and that it cuts the canonical sequence with 10(-4)-fold reduced activity as compared to the wild-type enzyme. We have now determined the structure at 1.59 A resolution of the D34G PvuII endonuclease complexed with a 12 bp duplex deoxyoligonucleotide containing the cognate sequence. The D34G alteration results in several structural changes relative to wild-type protein/DNA complexes. First, the sugar moiety of the internal guanine changes from a C2'-endo to C3'-endo pucker while that of the 3' guanine changes from C3'-endo to C2'-endo pucker. Second, the axial rise between the internal G.C base-pairs is reduced while that between the G.C and flanking base-pairs is expanded. Third, two distinct monomeric active sites are observed that we refer to as being "primed" and "unprimed" for phosphodiester bond cleavage. The primed and unprimed sites differ in the conformation of the Asp58 side-chain, and in the absence from unprimed sites of four networked water molecules. These water molecules, present in the primed site, have been implicated in the catalytic mechanism of this and other endonucleases; some of them can be replaced by the Mg2+ necessary for cleavage. Taken together, these structural changes imply that the Asp34 side-chains from the two subunits maintain a distinct conformation of its DNA substrate, properly situating the target backbone phosphates and indirectly manipulating the active sites. This provides some insight into how recognition of the specific DNA sequence is linked to catalysis by the highly specific restriction endonucleases, and reveals one way in which the structural conformation of the DNA is modulated coordinately with that of the PvuII protein.

Identifying 5-methylcytosine and related modifications in DNA genomes

Intense interest in the biological roles of DNA methylation, particularly in eukaryotes, has produced at least eight different methods for identifying 5-methylcytosine and related modifications in DNA genomes. However, the utility of each method depends not only on its simplicity but on its specificity, resolution, sensitivity and potential artifacts. Since these parameters affect the interpretation of data, they should be considered in any application. Therefore, we have outlined the principles and applications of each method, quantitatively evaluated their specificity,resolution and sensitivity, identified potential artifacts and suggested solutions, and discussed a paradox in the distribution of m5C in mammalian genomes that illustrates how methodological limitations can affect interpretation of data. Hopefully, the information and analysis provided here will guide new investigators entering this exciting field.

Expression, purification, mass spectrometry, crystallization and multiwavelength anomalous diffraction of selenomethionyl PvuII DNA methyltransferase (cytosine-N4-specific)

The type II DNA-methyltransferase (cytosine N4-specific) M.PvuII was overexpressed in Escherichia coli, starting from the internal translation initiator at Met14. Selenomethionine was efficiently incorporated into this short form of M.PvuII by a strain prototrophic for methionine. Both native and selenomethionyl M.PvuII were purified to apparent homogeneity by a two-column chromatography procedure. The yield of purified protein was approximately 1.8 mg/g bacterial paste. Mass spectrometry analysis of selenomethionyl M.PvuII revealed three major forms that probably differ in the degree of selenomethionine incorporation and the extent of selenomethionine oxidation. Amino acid sequencing and mass spectrometry analysis of selenomethionine-containing peptides suggests that Met30, Met51, and Met261 were only partially replaced by selenomethionine. Furthermore, amino acid 261 may be preferentially oxidized in both native and selenomethionyl form. Selenomethionyl and native M.PvuII were crystallized separately as binary complexes of the methyl donor S-adenosyl-L-methionine in the monoclinic space group P2(1). Two complexes were present per asymmetric unit. Six out of nine selenium positions (per molecule), including the three that were found to be partially substituted, were identified crystallographically.

Structure of pvu II DNA-(cytosine N4) methyltransferase, an example of domain permutation and protein fold assignment

We have determined the structure of Pvu II methyltransferase (M. Pvu II) complexed with S -adenosyl-L-methionine (AdoMet) by multiwavelength anomalous diffraction, using a crystal of the selenomethionine-substituted protein. M. Pvu II catalyzes transfer of the methyl group from AdoMet to the exocyclic amino (N4) nitrogen of the central cytosine in its recognition sequence 5'-CAGCTG-3'. The protein is dominated by an open alpha/beta-sheet structure with a prominent V-shaped cleft: AdoMet and catalytic amino acids are located at the bottom of this cleft. The size and the basic nature of the cleft are consistent with duplex DNA binding. The target (methylatable) cytosine, if flipped out of the double helical DNA as seen for DNA methyltransferases that generate 5-methylcytosine, would fit into the concave active site next to the AdoMet. This M. Pvu IIalpha/beta-sheet structure is very similar to those of M. Hha I (a cytosine C5 methyltransferase) and M. Taq I (an adenine N6 methyltransferase), consistent with a model predicting that DNA methyltransferases share a common structural fold while having the major functional regions permuted into three distinct linear orders. The main feature of the common fold is a seven-stranded beta-sheet (6 7 5 4 1 2 3) formed by five parallel beta-strands and an antiparallel beta-hairpin. The beta-sheet is flanked by six parallel alpha-helices, three on each side. The AdoMet binding site is located at the C-terminal ends of strands beta1 and beta2 and the active site is at the C-terminal ends of strands beta4 and beta5 and the N-terminal end of strand beta7. The AdoMet-protein interactions are almost identical among M. Pvu II, M. Hha I and M. Taq I, as well as in an RNA methyltransferase and at least one small molecule methyltransferase. The structural similarity among the active sites of M. Pvu II, M. Taq I and M. Hha I reveals that catalytic amino acids essential for cytosine N4 and adenine N6 methylation coincide spatially with those for cytosine C5 methylation, suggesting a mechanism for amino methylation.

Host-mediated modification of PvuII restriction in Mycobacterium tuberculosis

Restriction endonuclease PvuII plays a central role in restriction fragment length polymorphism analysis of Mycobacterium tuberculosis complex isolates with IS6110 as a genetic marker. We have investigated the basis for an apparent dichotomy in PvuII restriction fragment pattersn observed among strains of the M. tuberculosis complex. The chromosomal regions of two modified PvuII restriction sites, located upstream of the katG gene and downstream of an IS1081 insertion sequence, were studied in more detail. An identical 10-bp DNA sequence (CAGCTGGAGC) containing a PvuII site was found in both regions, and site-directed mutagenesis analysis revealed that this sequence was a target for modification. Strain-specific modification of PvuII sites was identified in DNA from over 80% of the nearly 800 isolates examined. Furthermore, the proportion of modifying and nonmodifying strains differs significantly from country to country.

Biology of DNA restriction

Our understanding of the evolution of DNA restriction and modification systems, the control of the expression of the structural genes for the enzymes, and the importance of DNA restriction in the cellular economy has advanced by leaps and bounds in recent years. This review documents these advances for the three major classes of classical restriction and modification systems, describes the discovery of a new class of restriction systems that specifically cut DNA carrying the modification signature of foreign cells, and deals with the mechanisms developed by phages to avoid the restriction systems of their hosts.

Purification and properties of the Eco57I restriction endonuclease and methylase--prototypes of a new class (type IV)

The Eco57I restriction endonuclease and methylase were purified to homogeneity from the E.coli RR1 strain carrying the eco57IRM genes on a recombinant plasmid. The molecular weight of the denaturated methylase is 63 kDa. The restriction endonuclease exists in a monomeric form with an apparent molecular weight of 104-108 kDa. R.Eco57I also possesses methylase activity. The methylation activities of both enzymes modify the outer A residue in the target sequence 5'CTGAAG yielding N6-methyladenine. M.Eco57I modifies both strands of the substrate while R.Eco57I modifies only one. Only the methylase enzyme is stimulated by Ca2+. The restriction endonuclease shows an absolute requirement for Mg2+ and is stimulated by AdoMet. ATP has no influence on either activity of the enzymes. The subunit structure and enzymatic properties of the Eco57I enzymes distinguish them from all other restriction-modification enzymes that have been described previously. Therefore, RM.Eco57I may be regarded as a representative of a novel class of restriction-modification systems, and we propose to classify it as type IV.

Organization and function of the mcrBC genes of Escherichia coli K-12

Many natural DNA sequences are restricted in Escherichia coli K-12, not only by the classic Type I restriction system EcoK, but also by one of three modification-specific restriction systems found in K-12. The McrBC system is the best studied of these. We infer from the base composition of the mcrBC genes that they were imported from an evolutionarily distant source. The genes are located in a hypervariable cluster of restriction genes that may play a significant role in generation of species identity in enteric bacteria. Restriction activity requires the products of two genes for activity both in vivo and in vitro. The mcrB gene elaborates two protein products, only one of which is required for activity in vitro, but both of which contain a conserved amino acid sequence motif identified as a possible GTP-binding site. The mcrC gene product contains a leucine heptad repeat that could play a role in protein-protein interactions. McrBC activity in vivo and in vitro depends on the presence of modified cytosine in a specific sequence context; three different modifications are recognized. The in vitro activity of this novel multi-subunit restriction enzyme displays an absolute requirement for GTP as a cofactor.

Sequence and characterization of pvuIIR, the PvuII endonuclease gene, and of pvuIIC, its regulatory gene

An open reading frame partially overlaps pvuIIR, and genetic evidence implies that this open reading frame, named pvuIIC, specifies a positive regulator of pvuIIR (T. Tao, J. C. Bourne, and R. M. Blumenthal, J. Bacteriol. 173:1367-1375, 1991). Inducible constructs of pvuIIC produced a protein of the expected size. The site of C.PvuII action appears to lie within pvuIIC itself; thus, pvuIIC may be a self-contained regulatory cassette.

The effect of methylation outside the recognition sequence of restriction endonuclease PvuII on its cleavage efficiency

This study is to extend our earlier observation that Dam and Dcm methylation outside the PvuII recognition sequence inhibited PvuII cleavage in one of the three PvuII sites of pGEM4Z-ras DNA. In this paper, a new recombinant plasmid DNA, pGEM4-SV40ori-anti-ras, was constructed which has only two PvuII sites, I and II. The Dam and Dcm-methylated and unmethylated DNAs were produced in Escherichia coli and linearized by ScaI. The DNA molecules were digested with different amounts of PvuII. The results show that by comparing the DNA fragment number and intensity of the partial and final products in agarose gel, PvuII site I on the methylated DNA molecule was digested four- to eight-fold more slowly than site II. In the unmethylated plasmid DNA, the two PvuII sites were cleaved at about the same rate. The difference was caused only by methylation of Dam and Dcm sites outside the PvuII recognition sequence. A methylated Dam site immediately adjacent to the less efficiently cut PvuII site I may be responsible for the inhibitory effect. We suggest that a new parameter, involving methylation of sites outside the recognition sequence, be considered in kinetic experiments on cleavage.

The inhibition of restriction endonuclease PvuII cleavage activity by methylation outside its recognition sequence

The recombinant plasmid pGEM4Z-ras DNA which was methylated on dam and dcm sites outside the PvuII recognition sequence was digested with restriction endonuclease PvuII, and one of the three PvuII sites was about 16-fold less efficient to cleave than either of the other two. On the contrary, the three PvuII sites were cleaved at about the same rate on the unmethylated DNA molecule. The results show that the cleavage inhibition of the methylated DNA on the certain PvuII site was caused by methylation outside the PvuII recognition sequence. Maybe a adjacent methylated dam site *A was responsible for the less efficient cleavage. This observation suggests that methylation outside the recognition sequence may be considered a new factor in the kinetic experiment of restriction endonuclease.

Overproduction and purification of McrC protein from Escherichia coli K-12

The McrC protein, encoded by one of the two genes involved in the McrB restriction system, was produced in Escherichia coli cells by using a T7 expression system. Following sequential DEAE-Sepharose and hydroxylapatite column chromatography, the protein was purified to apparent homogeneity as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The N-terminal amino acid sequence of the purified McrC protein agreed exactly with the one deduced from the DNA sequence by Ross et al. (J. Bacteriol. 171:1974-1981, 1989).

A family of regulatory genes associated with type II restriction-modification systems

Restriction-modification systems must be regulated to avoid autorestriction and death of the host cell. An open reading frame (ORF) in the PvuII restriction-modification system appears to code for a regulatory protein from a previously unrecognized family. First, interruptions of this ORF result in a nonrestricting phenotype. Second, this ORF can restore restriction competence to such interrupted mutants in trans. Third, the predicted amino acid sequence of this ORF resembles those of known DNA-binding proteins and includes a probable helix-turn-helix motif. A survey of unattributed ORFs in 15 other type II restriction-modification systems revealed three that closely resemble the PvuII ORF. All four members of this putative regulatory gene family have a common position relative to the endonuclease genes, suggesting a common regulatory mechanism.

Genetic and sequence organization of the mcrBC locus of Escherichia coli K-12

The mcrB (rglB) locus of Escherichia coli K-12 mediates sequence-specific restriction of cytosine-modified DNA. Genetic and sequence analysis shows that the locus actually comprises two genes, mcrB and mcrC. We show here that in vivo, McrC modifies the specificity of McrB restriction by expanding the range of modified sequences restricted. That is, the sequences sensitive to McrB(+)-dependent restriction can be divided into two sets: some modified sequences containing 5-methylcytosine are restricted by McrB+ cells even when McrC-, but most such sequences are restricted in vivo only by McrB+ McrC+ cells. The sequences restricted only by McrB+C+ include T-even bacteriophage containing 5-hydroxymethylcytosine (restriction of this phage is the RglB+ phenotype), some sequences containing N4-methylcytosine, and some sequences containing 5-methylcytosine. The sequence codes for two polypeptides of 54 (McrB) and 42 (McrC) kilodaltons, whereas in vitro translation yields four products, of approximately 29 and approximately 49 (McrB) and of approximately 38 and approximately 40 (McrC) kilodaltons. The McrB polypeptide sequence contains a potential GTP-binding motif, so this protein presumably binds the nucleotide cofactor. The deduced McrC polypeptide is somewhat basic and may bind to DNA, consistent with its genetic activity as a modulator of the specificity of McrB. At the nucleotide sequence level, the G+C content of mcrBC is very low for E. coli, suggesting that the genes may have been acquired recently during the evolution of the species.

Specificity of restriction endonucleases and DNA modification methyltransferases a review (Edition 3)

The properties and sources of all known class-I, class-II and class-III restriction endonucleases (ENases) and DNA modification methyltransferases (MTases) are listed and newly subclassified according to their sequence specificity. In addition, the enzymes are distinguished in a novel manner according to sequence specificity, cleavage position and methylation sensitivity. Furthermore, new nomenclature rules are proposed for unambiguously defined enzyme names. In the various Tables, the enzymes are cross-indexed alphabetically according to their names (Table I), classified according to their recognition sequence homologies (Table II), and characterized within Table II by the cleavage and methylation positions, the number of recognition sites on the DNA of the bacteriophages lambda, phi X174, and M13mp7, the viruses Ad2 and SV40, the plasmids pBR322 and pBR328, and the microorganisms from which they originate. Other tabulated properties of the ENases include relaxed specificities (integrated within Table II), the structure of the generated fragment ends (Table III), interconversion of restriction sites (Table IV) and the sensitivity to different kinds of DNA methylation (Table V). Table VI shows the influence of class-II MTases on the activity of class-II ENases with at least partially overlapping recognition sequences. Table VII lists all class-II restriction endonucleases and MTases which are commercially available. The information given in Table V focuses on the influence of methylation of the recognition sequences on the activity of ENases. This information might be useful for the design of cloning experiments especially in Escherichia coli containing M.EcodamI and M.EcodcmI [H16, M21, U3] or for studying the level and distribution of site-specific methylation in cellular DNA, e.g., 5'- (M)CpG-3' in mammals, 5'-(M)CpNpG-3' in plants or 5'-GpA(M)pTpC-3' in enterobacteria [B29, E4, M30, V4, V13, W24]. In Table IV a cross index for the interconversion of two- and four-nt 5'-protruding ends into new recognition sequences is complied. This was obtained by the fill-in reaction with the Klenow (large) fragment of the E. coli DNA polymerase I (PolIk), or additional nuclease S1 treatment followed by ligation of the modified fragment termini [P3]. Interconversion of restriction sites generates novel cloning sites without the need of linkers. This should improve the flexibility of genetic engineering experiments [K56, P3].(ABSTRACT TRUNCATED AT 400 WORDS)

Sequence motifs characteristic of DNA[cytosine-N4]methyltransferases: similarity to adenine and cytosine-C5 DNA-methylases

The sequences coding for DNA[cytosine-N4]methyltransferases MvaI (from Micrococcus varians RFL19) and Cfr9I (from Citrobacter freundii RFL9) have been determined. The predicted methylases are proteins of 454 and 300 amino acids, respectively. Primary structure comparison of M.Cfr9I and another m4C-forming methylase, M.Pvu II, revealed extended regions of homology. The sequence comparison of the three DNA[cytosine-N4]-methylases using originally developed software revealed two conserved patterns, DPF-GSGT and TSPPY, which were found similar also to those of adenine and DNA[cytosine-C5]-methylases. These data provided a basis for global alignment and classification of DNA-methylase sequences. Structural considerations led us to suggest that the first region could be the binding site of AdoMet, while the second is thought to be directly involved in the modification of the exocyclic amino group.

Sequence, internal homology and high-level expression of the gene for a DNA-(cytosine N4)-methyltransferase, M.Pvu II

The base sequence of the pvuIIM gene has been determined. This gene codes for a DNA-(cytosine N4)-methyltransferase, M.Pvu II. The base sequence contains a single large open reading frame that predicts a 38.3kDa polypeptide, consistent with experimental data. The pvuIIM gene contains some sequences common to DNA methyltransferases in general, but includes none of the sequences specifically conserved among DNA-(cytosine 5)-methyltransferases. The pvuIIM sequence also reveals an internal homology at the amino acid level, each half of which spans over 100 amino acids and is itself homologous to the sequences of some DNA-(adenine N6)-methyltransferases. A derivative of the pvuIIM plasmid was constructed to allow high-level production of M.Pvu II. Specifically, the composite Ptac promoter was inserted 5' to pvuIIM, intervening DNA was deleted, and the resulting construct was used to transform an mcrB laclq strain of Escherichia coli. When this transformant was induced with isopropyl-B-D-galactopyranoside (IPTG), growth rapidly ceased and M.Pvu II accumulated to the point of comprising over 10% of the total soluble protein.

Nucleotide sequence of the McrB region of Escherichia coli K-12 and evidence for two independent translational initiation sites at the mcrB locus

The McrB restriction system of Escherichia coli K-12 is responsible for the biological inactivation of foreign DNA that contains 5-methylcytosine residues (E. A. Raleigh and G. Wilson, Proc. Natl. Acad. Sci. USA 83:9070-9074, 1986). Within the McrB region of the chromosome is the mcrB gene, which encodes a protein of 51 kilodaltons (kDa) (T. K. Ross, E. C. Achberger, and H. D. Braymer, Gene 61:277-289, 1987), and the mcrC gene, the product of which is 39 kDa (T. K. Ross, E. C. Achberger, and H. D. Braymer, Mol. Gen. Genet., in press). The nucleotide sequence of a 2,695-base-pair segment encompassing the McrB region was determined. The deduced amino acid sequence was used to identify two open reading frames specifying peptides of 455 and 348 amino acids, corresponding to the products of the mcrB and mcrC genes, respectively. A single-nucleotide overlap was found to exist between the termination codon of the mcrB gene and the proposed initiation codon of the mcrC gene. The presence of an additional peptide of 33 kDa in strains containing various recombinant plasmids with portions of the McrB region has been reported by Ross et al. (Gene 61:277-289, 1987). The analysis of frameshift and deletion mutants of one such hybrid plasmid, pRAB-13, provided evidence for a second translational initiation site within the McrB open reading frame. The proposed start codon for translation of the 33-kDa peptide lies 481 nucleotides downstream from the initiation codon for the 51-kDa mcrB gene product. The 33-kDa peptide may play a regulatory role in the McrB restriction of DNA containing 5-methylcytosine.