Evidence of participation of McrB(S) in McrBC restriction in Escherichia coli K-12.

The McrBC restriction system has the ability to restrict DNA containing 5-hydroxymethylcytosine, N4-methylcytosine, and 5-methylcytosine at specific sequences. The mcrB gene produces two gene products. The complete mcrB open reading frame produces a 51-kDa protein (McrB(L)) and a 33-kDa protein (McrB(S)). The smaller McrB polypeptide is produced from an in-frame, internal translational start site in the mcrB gene. The McrB(S) sequence is identical to that of McrB(L) except that it lacks 161 amino acids present at the N-terminal end of the latter protein. It has been suggested that McrB(L) is the DNA binding restriction subunit. The function of McrB(S) is unknown, although there has been speculation that it plays some role in the modulation of McrBC restriction. Studies of the function of McrB(S) have been challenging since it is produced in frame with McrB(L). In this study, we tested the effects of underproduction (via antisense RNA) and overproduction (via gene dosage) of mcrBC gene products on restriction levels of the mcrBC+ strain JM107. Among the parameters monitored was the induction of SOS responses, which indicate of DNA damage. Evidence from this study suggests that McrB(S) is necessary for stabilization of the McrBC restriction complex in vivo.     

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.     

McrB: a prokaryotic protein specifically recognizing DNA containing modified cytosine residues.

Restriction of DNA by the Escherichia coli K-12 McrBC restriction endonuclease, which consists of the two subunits McrB and McrC, depends on the presence of modified cytosine residues in a special constellation. From previous work by others it was known that restriction of 5-methylcytosine-containing DNA requires two methylated 5'-PuC sites separated by approximately 40-80 non-defined base pairs. Here we show that binding of the McrBC nuclease is mediated exclusively by the McrB subunit. McrB has a low affinity for non-methylated DNA, with which it forms low molecular weight complexes. The affinity for DNA is significantly increased, with variations depending on the sequence context, by hemi- or fully methylated 5'-PuC sites. Binding to such substrates yields high molecular weight complexes, presumably involving several McrB molecules. Methylation at unique 5'-PuC sites can be sufficient to stimulate DNA binding by McrB. As such substrates are not cleaved by the nuclease, restriction apparently requires the coordinated interaction of molecules bound to neighbouring 5'-PumC sites. The binding properties of McrB exhibit some similarities to recently identified eukaryotic proteins interacting in a non-sequence-specific manner with DNA containing methylated 5'-CpG sequences and might point to a common molecular origin of these proteins. In addition to DNA, McrB also binds GTP, an essential cofactor in DNA restriction by McrBC. McrC neither binds to DNA nor modulates the DNA binding potential of McrB. As McrC is essential for restriction it appears to predominantly function in catalysis.     

A mutational analysis of the PD...D/EXK motif suggests that McrC harbors the catalytic center for DNA cleavage by the GTP-dependent restriction enzyme McrBC from Escherichia coli

McrBC is a unique restriction enzyme which binds specifically to the bipartite recognition sequence R(m)CN( approximately )(30)(-)( approximately )(2000)R(m)C and in the presence of GTP translocates the DNA and cleaves both strands at multiple positions within the two R(m)C "half-sites". It is known that McrBC is composed of two subunits: McrB which binds and hydrolyzes GTP and specifically interacts with DNA and McrC whose function is not clear but which has been suspected to harbor the catalytic center for DNA cleavage. A multiple-sequence alignment of the amino acid sequence of Escherichia coli McrC and of six presumably homologous open reading frames from various bacterial species shows that a sequence motif found in many restriction enzymes, but also in other nucleases, the PD.D/EXK motif, is conserved among these sequences. A mutational analysis, in which the carboxylates (aspartic acid in McrC) of this motif were substituted with alanine or asparagine and lysine was substituted with alanine or arginine, strongly suggests that Asp244, Asp257, and Lys259 represent the catalytic center of E. coli McrC. Whereas the variants D244A (or -N), D257A (or -N), and K259A are inactive in DNA cleavage (K259R has residual DNA cleavage activity), they interact with McrB like wild-type McrC, as can be deduced from the finding that they stimulate the McrB-catalyzed GTP hydrolysis to the same extent as wild-type McrC. Thus, whereas McrC variants defective in DNA cleavage can stimulate the GTPase activity of McrB, the DNase activity of McrC is not supported by McrB variants defective in GTP hydrolysis.     

The McrBC restriction endonuclease assembles into a ring structure in the presence of G nucleotides

McrBC from Escherichia coli K-12 is a restriction enzyme that belongs to the family of AAA(+) proteins and cuts DNA containing modified cytosines. Two proteins are expressed from the mcrB gene: a full-length version, McrB(L), and a short version, McrB(S). McrB(L) binds specifically to the methylated recognition site and is, therefore, the DNA-binding moiety of the McrBC endonuclease. McrB(S) is devoid of DNA-binding activity. We observed that the quaternary structure of the endonuclease depends on binding of the cofactors. In gel filtration experiments, McrB(L) and McrB(S) form high molecular weight oligomers in the presence of Mg(2+) and GTP, GDP or GTP-gamma-S. Oligomerization did not require the presence of DNA and was independent of GTP hydrolysis. Electron micrographs of negatively stained McrB(L) and McrB(S) revealed ring-shaped particles with a central channel. Mass analysis by scanning transmission electron microscopy indicates that McrB(L) and McrB(S) form single heptameric rings as well as tetradecamers. In the presence of McrC, a subunit that is essential for DNA cleavage, the tetradecameric species was the major form of the endonuclease.     

Identification and characterization of a gene responsible for inhibiting propagation of methylated DNA sequences in mcrA mcrB1 Escherichia coli strains.

Identifying and eliminating endogenous bacterial enzyme systems can significantly increase the efficiency of propagation of eukaryotic DNA in Escherichia coli. We have recently examined one such system which inhibits the propagation of lambda DNA rescued from transgenic mouse tissues. This rescue procedure utilizes lambda packaging extracts for excision of the lambda DNA from the transgenic mouse genome, as well as E. coli cells for subsequent infection and propagation. This assay, in combination with conjugal mating, P1 transduction, and gene cloning, was used to identify and characterize the E. coli locus responsible for this difference in efficiency. It was determined that the E. coli K-12 mcrB gene when expressed on a high-copy-number plasmid can cause a decrease in rescue efficiency despite the presence of the mcrB1 mutation, which inactivates the classic McrB restriction activity. (This mutation was verified by sequence analysis.) However, this McrB1 activity is not observed when the cloned mcrB1 gene is inserted into the E. coli genome at one copy per chromosome. A second locus was identified which causes a decrease in rescue efficiency both when expressed on a high-copy-number plasmid and when inserted into the genome. The data presented here suggest that this locus is mrr and that the mrr gene product can recognize and restrict cytosine-methylated sequences. Removal of this DNA region including the mrr gene from E. coli K-12 strains allows high rescue efficiencies equal to those of E. coli C strains. These modified E. coli K-12 plating strains and lambda packaging extract strains should also allow a significant improvement in the efficiency and representation of eukaryotic genomic and cDNA libraries.     

Defining the location and function of domains of McrB by deletion mutagenesis

The GTP-dependent restriction endonuclease McrBC of E. coli K12, which recognizes cytosine-methylated DNA, consists of two protein subunits, McrB and McrC. We have investigated the structural assignment and interdependence of the McrB subunit functions, namely (i) specific DNA recognition and (ii) GTP binding and hydrolysis. Extending earlier work, we have produced McrB variants comprising N- and C-terminal fragments. The variants McrB1-162 and McrB1-170 are still capable of specific DNA binding. McrB169-465 shows GTP binding and hydrolysis characteristics indistinguishable from full-length McrB as well as wild-type like interaction with McrC. Thus, DNA and GTP binding are spatially separated on the McrB molecule, and the respective domains function quite independently.     

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).     

The GTP-binding domain of McrB: more than just a variation on a common theme?

The methylation-dependent restriction endonuclease McrBC from Escherichia coli K12 cleaves DNA containing two R(m)C dinucleotides separated by about 40 to 2000 base-pairs. McrBC is unique in that cleavage is totally dependent on GTP hydrolysis. McrB is the GTP binding and hydrolyzing subunit, whereas MrC stimulates its GTP hydrolysis. The C-terminal part of McrB contains the sequences characteristic for GTP-binding proteins, consisting of the GxxxxGK(S/T) motif (position 201-208), followed by the DxxG motif (position 300-303). The third motif (NKxD) is present only in a non-canonical form (NTAD 333-336). Here we report a mutational analysis of the putative GTP-binding domain of McrB. Amino acid substitutions were initially performed in the three proposed GTP-binding motifs. Whereas substitutions in motif 1 (P203V) and 2 (D300N) show the expected, albeit modest effects, mutation in the motif 3 is at variance with the expectations. Unlike the corresponding EF-Tu and ras -p21 variants, the D336N mutation in McrB does not change the nucleotide specificity from GTP to XTP, but results in a lack of GTPase stimulation by McrC. The finding that McrB is not a typical G protein motivated us to perform a search for similar sequences in DNA databases. Eight microbial sequences were found, mainly from unfinished sequencing projects, with highly conserved sequence blocks within a presumptive GTP-binding domain. From the five sequences showing the highest homology, 17 invariant charged or polar residues outside the classical three GTP-binding motifs were identified and subsequently exchanged to alanine. Several mutations specifically affect GTP affinity and/or GTPase activity. Our data allow us to conclude that McrB is not a typical member of the superfamily of GTP-binding proteins, but defines a new subfamily within the superfamily of GTP-binding proteins, together with similar prokaryotic proteins of as yet unidentified function.     

Purification and N-terminal amino acid sequences of two polypeptides encoded by the mcrB gene from Escherichia coli K-12.

This report provides a purification method for the two proteins, 51 kDa and 33 kDa, both encoded by the same mcrB gene of the McrBC restriction system in Escherichia coli K-12. The two proteins were produced in large quantity using a T7 expression system and copurified to near homogeneity by DEAE-Sepharose and Affi-Gel blue column chromatography. The N-terminal amino acid sequences of these purified McrB proteins were the same as those predicted from the mcrB DNA sequence by Ross et al. [J. Bacteriol. 171 (1989b) 1974-1981]. The 33-kDa protein totally overlaps the C-terminal part of the 51-kDa protein.     

Genetic and Physical Mapping of the Mcra (Rgla) and Mcrb (Rglb) Loci of Escherichia Coli K-12

We have genetically analyzed, cloned and physically mapped the modified cytosine-specific restriction determinants mcrA (rglA) and mcrB (rglB) of Escherichia coli K-12. The independently discovered Rgl and Mcr restriction systems are shown to be identical by three criteria: 1) mutants with the RglA- or RglB- phenotypes display the corresponding McrA- or McrB- phenotypes, and vice versa; 2) the gene(s) for RglA and McrA reside together at one locus, while gene(s) for RglB and McrB are coincident at a different locus; and 3) RglA+ and RglB+ recombinant clones complement for the corresponding Mcr-deficient lesions. The mcrA (rglA) gene(s) is on the excisable element e14, just clockwise of purB at 25 min. The mcrB (rglB) gene(s), at 99 min, is in a cluster of restriction functions that includes hsd and mrr, determinants of host-specific restriction (EcoK) and methyladenine-specific restriction respectively. Gene order is mcrB-hsdS-hsdM-hsdR-mrr-serB. Possible models for the acqusition of these restriction determinants by enteric bacteria are discussed.     

Localization of a genetic region involved in McrB restriction by Escherichia coli K-12.

A 5,500-base-pair BglII-EcoRI fragment proximal to the hsd genes of Escherichia coli K-12 has been cloned in the plasmid vector pUC9. The resultant hybrid plasmid was shown to complement the mcrB mutation of E. coli K802. The presence of the hybrid plasmid in strain K802 caused an 18.3-fold drop in transformation efficiency with AluI-methylated pACYC184 relative to unmethylated pACYC184. These results indicate that the cloned DNA is involved in the McrB system restriction of 5-methylcytosine DNA.     

The GTP-dependent restriction enzyme McrBC from Escherichia coli forms high-molecular mass complexes with DNA and produces a cleavage pattern with a characteristic 10-base pair repeat

The GTP-dependent restriction enzyme McrBC consists of two polypeptides: one (McrB) that is responsible for GTP binding and hydrolysis as well as DNA binding and another (McrC) that is responsible for DNA cleavage. It recognizes two methylated or hemimethylated RC sites (R(m)C) at a distance of approximately 30 to more than 2000 base pairs and cleaves the DNA close to one of the two R(m)C sites. This process is strictly coupled to GTP hydrolysis and involves the formation of high-molecular mass complexes. We show here using footprinting techniques, surface plasmon resonance, and scanning force microscopy experiments that in the absence of McrC, McrB binds to a single R(m)C site. If a second R(m)C site is present on the DNA, it is occupied independently by McrB. Whereas the DNA-binding domain of McrB forms 1:1 complexes with each R(m)C site and shows a clear footprint on both R(m)C sites, full-length McrB forms complexes with a stoichiometry of at least 4:1 at each R(m)C site, resulting in a slightly more extended footprint. In the presence of McrC, McrB forms high-molecular mass complexes of unknown stoichiometry, which are considerably larger than the complexes formed with McrB alone. In these complexes and when GTP is present, the DNA is cleaved next to one of the R(m)C sites at distances differing by one to five helical turns, suggesting that in the McrBC-DNA complex only a few topologically well-defined phosphodiester bonds of the DNA are accessible for the nucleolytic center of McrC.     

Identification of a second polypeptide required for McrB restriction of 5-methylcytosine-containing DNA in Escherichia coli K12

Summary The McrB restriction system in Escherichia coli K12 causes sequence-specific recognition and inactivation of DNA containing 5-methylcytosine residues. We have previously located the mcrB gene near hsdS at 99 min on the E. coli chromosome and demonstrated that is encodes a 51 kDa polypeptide required for restriction of M.AluI methylated (A-G-5mC-T) DNA. We show here, by analysis of maxicell protein synthesis of various cloned fragments from the mcrB region, that a second protein of approximately 39 kDa is also required for McrB-directed restriction. The new gene, designated mcrC, is adjacent to mcrB and located distally to hsdS. The McrB phenotype has been correlated previously with restriction of 5-hydroxy-methylcytosine (HMC)-containing T-even phage DNA that lacks the normal glucose modification of HMC, formally designated RglB (for restriction of glucoseless phage). This report reveals a difference between the previously correlated McrB and RglB restriction systems: while both require the mcrB gene product only the McrB system requires the newly identified mcrC-encoded 39-kDa polypeptide.     

Methyl-cytosine specific restriction in Escherichia coli K-12

Experiments on transformation of Escherichia coli K-12 cells by plasmids carrying RM systems with different recognition sites containing 5-methylcytosine have shown that the gene mcrB determines the function of restriction. The data obtained made it possible to believe that E. coli possesses no restriction system recognizing specifically cytosine methylated in position 4.     

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.     

The location of a temperature-sensitive trans-dominant mutation and its effect on restriction and modification in Escherichia coli K12

An Escherichia coli K12 chromosomal EcoRI-BamHI fragment containing a mutant hsdS locus was cloned into plasmid pBR322. The mcrB gene, closely linked to hsdS, was used for selection of clones with the inserted fragment using T4 alpha gt57 beta gt14 and lambda vir. PvuII phages; the phage DNAs contain methylated cytosines and hence can be used to demonstrate McrB restriction. For the efficient expression of the hsdS gene, a BglII fragment of phage lambda carrying the pR promoter was inserted into the BamHI site of the hybrid plasmid. Under these conditions a trans-dominant effect of the hsdXts+d mutation on restriction and modification was detected. Inactivation of the hsdS gene by the insertion of the lambda phage BglII fragment into the BglII site within this gene resulted in the disappearance of the trans-dominant effect. When the cloned BamHI-EcoRI fragment was shortened by HpaI and EcoRI restriction enzymes, the trans-dominant effect was fully expressed. The results indicate that the Xts+d mutation is located in the hsdS gene. The effect of gene dosage of the HsdS subunit on the expression of Xts+d mutation was studied. The results of complementation experiments, using F'-merodiploids or plasmid pBR322 with an inserted Xts+d mutation, support the idea that the HsdSts+d product competes with the wild-type HsdS product, and has a quantitatively different effect on restriction and modification.     

McrA and McrB restriction phenotypes of some E. coli strains and implications for gene cloning.

The McrA and McrB (modified cytosine restriction) systems of E. coli interfere with incoming DNA containing methylcytosine. DNA from many organisms, including all mammalian and plant DNA, is expected to be sensitive, and this could interfere with cloning experiments. The McrA and B phenotypes of a few strains have been reported previously (1-4). The Mcr phenotypes of 94 strains, primarily derived from E. coli K12, are tabulated here. We briefly review some evidence suggesting that McrB restriction of mouse-modified DNA does occur in vivo and does in fact interfere with cloning of specific mouse sequences.     

Methyl-specific DNA binding by McrBC, a modification-dependent restriction enzyme

McrBC, a GTP-requiring, modification-dependent endonuclease of Escherichia coli K-12, specifically recognizes DNA sites of the form 5' R(m)C 3'. DNA cleavage normally requires translocation-mediated coordination between two such recognition elements at distinct sites. We have investigated assembly of the cleavage-competent complex with gel-shift and DNase I footprint analysis. In the gel-shift system, McrB(L) binding resulted in a fast-migrating specific shifted band, in a manner requiring both GTP and Mg(2+). The binding was specific for methylated DNA and responded to local sequence changes in the same way that cleavage does. Single-stranded DNA competed for McrB(L)-binding in a modification and sequence-specific fashion. A supershifted species was formed in the presence of McrC and GTPgammaS. DNase I footprint analysis showed modest cooperativity in binding to two sites, and a two-site substrate displayed protection in non-specific spacer DNA in addition to the recognition elements. The addition of McrC did not affect the footprint obtained. We propose that McrC effects a conformational change in the complex rather than a reorganization of the DNA:protein interface.     

Characterization of the mcrBC region of Escherichia coli K-12 wild-type and mutant strains.

We have carried out an analysis of the Escherichia coli K-12 mcrBC locus in order to (1) elucidate its genetic organization, (2) to identify the proteins encoded by this region, and (3) to characterize their involvement in the restriction of DNA containing methylated cytosine residues. In vitro expression of recombinant plasmids carrying all or portions of the mcrBC region revealed that the mcrB and mcrC genes are organized as an operon. The mcrBC operon specifies five proteins, as evident from parallel in vitro and in in vivo expression studies. Three proteins of 53, 35 and 34 kDa originate from mcrB expression, while two proteins of 37 and 16 kDa arise from mcrC expression. Products of both the mcrB and mcrC genes are required to restrict the methylated substrate DNA used in this study. We also determined the nature of mutant mcrBC loci in comparison to the E. coli K-12 wild-type mcrBC locus. A major goal of these studies was to clarify the nature of the mcrB-1 mutation, which is carried by some strains employed in previous analyses of the E. coli K-12 McrBC system. Based on our analyses the mutant strains investigated could be divided into different complementation groups. The mcrB-1 mutation is a nonsense or frameshift mutation located within mcrB. It causes premature termination of mcrB gene product synthesis and reduces the level of mcrC gene expression. This finding helps to understand an existing conflict in the literature. We also describe temperature-sensitive McrA activity in some of the strains analysed and its relationship to the previously defined differences in the tolerance levels of E. coli K-12 mcrBC mutants to cytosine methylation.