Site-specific methylases induce the SOS DNA repair response in Escherichia coli

Yeast and human genes that affect the Escherichia coli SOS response

The sequencing of the human genome has led to the identification of many genes whose functions remain to be determined. Because of conservation of genetic function, microbial systems have often been used for identification and characterization of human genes. We have investigated the use of the Escherichia coli SOS induction assay as a screen for yeast and human genes that might play a role in DNA metabolism and/or in genome stability. The SOS system has previously been used to analyze bacterial and viral genes that directly modify DNA. An initial screen of meiotically expressed yeast genes revealed several genes associated with chromosome metabolism (e.g., RAD51 and HHT1 as well as others). The SOS induction assay was then extended to the isolation of human genes. Several known human genes involved in DNA metabolism, such as the Ku70 end-binding protein and DNA ligase IV, were identified, as well as a large number of previously unknown genes. Thus, the SOS assay can be used to identify and characterize human genes, many of which may participate in chromosome metabolism.

McrBs, a modulator peptide for McrBC activity

McrBC is a methylation-dependent endonuclease from Escherichia coli K-12. The enzyme recognizes DNA with modified cytosines preceded by a purine. McrBC restricts DNA that contains at least two methylated recognition sites separated by 40-80 bp. Two gene products, McrBL and McrBs, are produced from the mcrB gene and one, McrC, from the mcrC gene. DNA cleavage in vitro requires McrBL, McrC, GTP and Mg2+. We found that DNA cleavage was optimal at a ratio of 3-5 McrBL per molecule of McrC, suggesting that formation of a multisubunit complex with several molecules of McrBL is required for cleavage. To understand the role of McrBs, we have purified the protein and analyzed its role in vitro. At the optimal ratio of 3-5 McrBL per molecule of McrC, McrBs acted as an inhibitor of DNA cleavage. Inhibition was due to sequestration of McrC and required the presence of GTP, suggesting that the interaction is GTP dependent. If McrC was in excess, a condition resulting in suboptimal DNA cleavage, addition of McrBs enhanced DNA cleavage, presumably due to sequestration of excess McrC. We suggest that the role of McrBs is to modulate McrBC activity by binding to McrC.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Temperature-sensitive mutants of the EcoRI endonuclease

The EcoRI endonuclease is an important recombinant DNA tool and a paradigm of sequence-specific DNA-protein interactions. We have isolated temperature-sensitive (TS) EcoRI endonuclease mutants (R56Q, G78D, P90S, V97I, R105K, M157I, C218Y, A235E, M255I, T261I and L263F) and characterized activity in vivo and in vitro. Although the majority were TS for function in vivo, all of the mutant enzymes were stably expressed and largely soluble at both 30 degrees C and 42 degrees C in vivo and none of the mutants was found to be TS in vitro. These findings suggest that these mutations may affect folding of the enzyme at elevated temperature in vivo. Both non-conservative and conservative substitutions occurred but were not correlated with severity of the mutation. Of the 12 residues identified, 11 are conserved between EcoRI and the isoschizomer RsrI (which shares 50% identity), a further indication that these residues are critical for EcoRI structure and function. Inspection of the 2.8 A resolution X-ray crystal structure of the wild-type EcoRI endonuclease-DNA complex revealed that: (1) the TS mutations cluster in one half of the globular enzyme; (2) several of the substituted residues interact with each other; (3) most mutations would be predicted to disrupt local structures; (4) two mutations may affect the dimer interface (G78D and A235E); (5) one mutation (P90S) occurred in a residue that is part of, or immediately adjacent to, the EcoRI active site and which is conserved in the distantly related EcoRV endonuclease. Finally, one class of mutants restricted phage in vivo and was active in vitro, whereas a second class did not restrict and was inactive in vitro. The two classes of mutants may differ in kinetic properties or cleavage mechanism. In summary, these mutations provide insights into EcoRI structure and function, and complement previous genetic, biochemical, and structural analyses.

Cloning of the BssHII restriction-modification system in Escherichia coli : BssHII methyltransferase contains circularly permuted cytosine-5 methyltransferase motifs

BssHII restriction endonuclease cleaves 5'-GCGCGC-3' on double-stranded DNA between the first and second bases to generate a four base 5'overhang. BssHII restriction endonuclease was purified from the native Bacillus stearothermophilus H3 cells and its N-terminal amino acid sequence was determined. Degenerate PCR primers were used to amplify the first 20 codons of the BssHII restriction endonuclease gene. The BssHII restriction endonuclease gene (bssHIIR) and the cognate BssHII methyltransferase gene (bssHIIM) were cloned in Escherichia coli by amplification of Bacillus stearothermophilus genomic DNA using PCR and inverse PCR. BssHII methyltransferase (M.BssHII) contains all 10 conserved cytosine-5 methyltransferase motifs, but motifs IX and X precede motifs I-VIII. Thus, the conserved motifs of M. BssHII are circularly permuted relative to the motif organizations of other cytosine-5 methyltransferases. M.BssHII and the non-cognate multi-specific phiBssHII methyltransferase, M.phiBss HII [Schumann,J. et al . (1995) Gene, 157, 103-104] share 34% identity in amino acid sequences from motifs I-VIII, and 40% identity in motifs IX-X. A conserved arginine is located upstream of a TV dipeptide in the N-terminus of M.BssHII that may be responsible for the recognition of the guanine 5' of the target cytosine. The BssHII restriction endonuclease gene was expressed in E.coli via a T7 expression vector.

Characterization of the interaction between the restriction endonuclease McrBC from E. coli and its cofactor GTP

McrBC, a GTP-dependent restriction enzyme from E. coli K-12, cleaves DNA containing methylated cytosine residues 40 to 80 residues apart and 3'-adjacent to a purine residue (PumCN40-80PumC). The presence of the three consensus sequences characteristic for guanine nucleotide binding proteins in one of the two subunits of McrBC suggests that this subunit is responsible for GTP binding and hydrolysis. We show here that (i) McrB binds GTP with an affinity of 10(6) M-1 and that GTP binding stabilizes McrB against thermal denaturation. (ii) McrB binds GDP about 50-fold and ATP at least three orders of magnitude more weakly than GTP. (iii) McrB hydrolyzes GTP in the presence of Mg2+ with a steady-state rate of approximately 0.5 min-1. (iv) McrC stimulates GTP hydrolysis 30-fold, but substrate DNA has no detectable effect on the GTPase activity of McrB, neither by itself nor in the presence of McrC. (v) Substitution of N339 and N376 with alanine allowed us to identify NTAD (339 to 342) rather than NKKA (376 to 379) as the equivalent of the third consensus sequence motif characteristic for guanine nucleotide binding proteins, NKXD.

A ColE1-type plasmid from Salmonella enteritidis encodes a DNA cytosine methyltransferase

The multicopy plasmid pFM366 was isolated from a virulent Salmonella enteritidis strain and was found to code for DNA methylase activity (Ibáñez and Rotger, 1993). The present work was aimed at characterizing the genetic organization and functional features of this 5.6 kb plasmid. We found pFM366 almost identical to the plasmid P4 isolated from Shigella sonnei, that encodes the SsoII restriction-modification system (Karyagina et al., 1993), and related to other ColE1-type plasmids. Examination of these plasmids revealed a common organization which suggests they were the result of similar recombinational events. The cytosine methylase of pFM366 is nearly identical to M. SsoII, whereas the gene encoding the restrictase homologous to R. SsoII is truncated and its product is inactive. The expression of the cytosine methylase encoded by pFM366 is strongly affected by deletion of regions located upstream and downstream of its ORF, and is negatively controlled by the rpoS gene in Escherichia coli. The methylase activity encoded by pFM366 induces the SOS response, which could be responsible for the observed delay in the growth of E. coli.

Overproduction of DNA cytosine methyltransferases causes methylation and C --> T mutations at non-canonical sites

Multicopy clones of Escherichia coli cytosine methyltransferases Dcm and EcoRII methylase (M. EcoRII) cause an approximately 50-fold increase in C --> T mutations at their canonical site of methylation, 5'-CmeCAGG (meC is 5-methylcytosine). These plasmids also cause transition mutations at the second cytosine in the sequences CCGGG at approximately 10-fold lower frequency. Similarly, M. HpaII was found to cause a significant increase in C --> T mutations at a CCAG site, in addition to causing mutations at its canonical site of methylation, CCGG. Using a plasmid that substantially overproduces M. EcoRII, in vivo methylation at CCSGG (S is C or G) and other non-canonical sites could be detected using a gel electrophoretic assay. There is a direct correlation between the level of M. EcoRII activity in cells, the extent of methylation at non-canonical sites and frequency of mutations at these same sites. Overproduction of M. EcoRII in cells also causes degradation of DNA and induction of the SOS response. In vitro, M. EcoRII methylates an oligonucleotide duplex containing a CCGGG site at a slow rate, suggesting that overproduction of the enzyme is essential for significant amounts of such methylation to occur. Together these results show that cytosine methyltransferases occasionally methylate cellular DNA at non-canonical sites and suggest that in E. coli, methylation-specific restriction systems and sequence specificity of the DNA mismatch correction systems may have evolved to accommodate this fact. These results also suggest that mutational effects of cytosine methyltransferases may be much broader than previously imagined.

Restriction-modification systems as genomic parasites in competition for specific sequences

Restriction-modification (RM) systems are believed to have evolved to protect cells from foreign DNA. However, this hypothesis may not be sufficient to explain the diversity and specificity in sequence recognition, as well as other properties, of these systems. We report that the EcoRI restriction endonuclease-modification methylase (rm) gene pair stabilizes plasmids that carry it and that this stabilization is blocked by an RM of the same sequence specificity (EcoRI or its isoschizomer, Rsr I) but not by an RM of a different specificity (PaeR7I) on another plasmid. The PaeR7I rm likewise stabilizes plasmids, unless an rm gene pair with identical sequence specificity is present. Our analysis supports the following model for stabilization and incompatibility: the descendants of cells that have lost an rm gene pair expose the recognition sites in their chromosomes to lethal attack by any remaining restriction enzymes unless modification by another RM system of the same specificity protects these sites. Competition for specific sequences among these selfish genes may have generated the great diversity and specificity in sequence recognition among RM systems. Such altruistic suicide strategies, similar to those found in virus-infected cells, may have allowed selfish RM systems to spread by effectively competing with other selfish genes.

On the regulation and diversity of restriction in Escherichia coli

The effect of UV irradiation on restriction mediated by four endogenous restriction systems of E. coli K-12 was investigated using a uniform testing method. Restriction by all four systems was reduced when treated cells were separately challenged with lambda phage carrying modification patterns that elicit restriction by each system. The response of each system was genetically and physiologically distinct.

Isolation of cryptic plasmids from moderately halophilic eubacteria of the genus Halomonas. Characterization of a small plasmid from H. elongata and its use for shuttle vector construction

Three cryptic plasmids have been isolated from moderately halophilic eubacteria belonging to three species of the genus Halomonas. These three plasmids were designated pHE1 (4.2 kb, isolated from H. elongata ATCC 33174), pHI1 (48 kb, isolated from "H. israelensis" ATCC 43985), and pHS1 (ca. 70 kb, isolated from H. subglaciescola UQM 2927). Because of its small size, the plasmid pHE1 was selected for further characterization and construction of a shuttle vector for Halomonas strains. pHE1 was cloned into pBluescript KS and a detailed restriction map was constructed. Hybridization experiments excluded the existence of sequences homologous to pHE1 in total DNA from other strains of the genus Halomonas. Moreover, no DNA homology with pMH1, the only plasmid described so far from moderate halophiles, was found. Since pHE1 appeared to be unable to replicate in Escherichia coli cells, a number of mobilizable pHE1-derived hybrid plasmids were constructed that could be selected and maintained both in E. coli and in H. elongata. Finally, an improved shuttle vector, pHS15, was generated. The vector pHS15 contains an origin of replication from E. coli as well as one from H. elongata, a streptomycin resistance gene for positive selection in moderate halophiles, a number of unique restriction sites commonly used for cloning, and the mobilization functions of the broad host range IncP plasmid RK2. The vector pHS15 was readily mobilized by the RK2 derivative pRK2013 to all Halomonas strains tested so far. This is the first report on the development of a cloning vector useful for moderately halophilic eubacteria.

Response to UV damage by four Escherichia coli K-12 restriction systems

To understand the role of restriction in regulating gene flow in bacterial populations, we would like to understand the regulation of restriction enzyme activity. Several antirestriction (restriction alleviation) systems are known that reduce the activity of type I restriction enzymes like EcoKI in vivo. Most of these do not act on type II or type III enzymes, but little information is available for the unclassified modification-dependent systems, of which there are three in E. coli K-12. Of particular interest are two physiological controls on type I enzymes: EcoKI restriction is reduced 2 to 3 orders of magnitude following DNA damage, and a similar effect is seen constitutively in Dam- cells. We used the behavior of EcoKI as a control for testing the response to UV treatment of the three endogenous modification-dependent restriction systems of K-12, McrA, McrBC, and Mrr. Two of these were also tested for response to Dam status. We find that all four resident restriction systems show reduced activity following UV treatment, but not in a unified fashion; each response was genetically and physiologically distinct. Possible mechanisms are discussed.

The 'endo-blue method' for direct cloning of restriction endonuclease genes in E. coli

A new E. coli strain has been constructed that contains the dinD1::LacZ+ fusion and is deficient in methylation-dependent restriction systems (McrA-, McrBC-, Mrr-). This strain has been used to clone restriction endonuclease genes directly into E. coli. When E. coli cells are not fully protected by the cognate methylase, the restriction enzyme damages the DNA in vivo and induces the SOS response. The SOS-induced cells form blue colonies on indicator plates containing X-gal. Using this method the genes coding for the thermostable restriction enzymes Taql (5'TCGA3') and Tth111l (5'GACNNNGTC3') have been successfully cloned in E. coli. The new strain will be useful to clone other genes involved in DNA metabolism.

The DNA damage-inducible dinD gene of Escherichia coli is equivalent to orfY upstream of pyrE

The DNA damage-inducible gene dinD, originally identified by Kenyon and Walker (C. J. Kenyon and G. C. Walker, Proc. Natl. Acad. Sci. USA 77:2819-2823, 1980) by selection of the dinD::MudI (Ap lac) fusion, is shown here to be equivalent to the open reading frame orfY near pyrE. The evidence for identity between the two genes includes results from P1 transduction, Southern hybridization, and cloning and sequencing of the dinD fusion. No data were obtained that reveal any hints about the function of the dinD gene.

The dam and dcm strains of Escherichia coli--a review

The construction of a variety of strains deficient in the methylation of adenine and cytosine residues in DNA by the methyltransferases (MTases) Dam and Dcm has allowed the study of the role of these enzymes in the biology of Escherichia coli. Dam methylation has been shown to play a role in coordinating DNA replication initiation, DNA mismatch repair and the regulation of expression of some genes. The regulation of expression of dam has been found to be complex and influenced by five promoters. A role for Dcm methylation in the cell remains elusive and dcm- cells have no obvious phenotype. dam- and dcm- strains have a range of uses in molecular biology and bacterial genetics, including preparation of DNA for restriction by some restriction endonucleases, for transformation into other bacterial species, nucleotide sequencing and site-directed mutagenesis. A variety of assays are available for rapid detection of both the Dam and Dcm phenotypes. A number of restriction systems in E. coli have been described which recognise foreign DNA methylation, but ignore Dam and Dcm methylation. Here, we describe the most commonly used mutant alleles of dam and dcm and the characteristics of a variety of the strains that carry these genes. A description of several plasmids that carry dam gene constructs is also included.

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.

Improved efficiency for T-DNA-mediated transformation and plasmid rescue inArabidopsis thaliana

A vector was constructed for the isolation of gene fusions to thelacZ reporter gene following T-DNA integration into the genome ofArabidopsis thaliana. To facilitate the generation of taggedA. thaliana plants, we established a modified method for high-frequency transformation ofA. thaliana byAgrobacterium tumefaciens. The main modification required was to inhibit the methylation of T-DNA in the transformed calli. Apparently, cytosine residues of thenos-nptII gene used as a selectable marker were methylated, and the expression of this gene was suppressed. Treatment of the calli with the cytosine methylation inhibitor 5-azacytidine led to a dramatic increase (from 3% to 96%) in the regeneration of transformed (kanamycin-resistant) shoots. A total of 150 transgenic plants were isolated, and in 17 of these expression of thelacZ reporter was detected byin situ staining. The T-DNA insert together with flanking plant DNA sequences was cloned intoEscherichia coli by plasmid rescue from some of the T3 transformants that harbored one copy of the integrated T-DNA. Comparison of the rescued DNA with the corresponding DNA of the transgenic plant showed that most of the rescued plasmids had undergone rearrangements. These rearrangements could be totally avoided if anmcrAB (modified cytosine restriction) mutant ofE. coli was used as the recipient in plasmid rescue.

Escherichia coli host strains SURE and SRB fail to preserve a palindrome cloned in lambda phage: improved alternate host strains

We have attempted to produce Escherichia coli strains with the optimal combination of host mutations required for the construction of genomic libraries in lambda and cosmid vectors. For lambda vectors, we defined this as a strain that combined high efficiency of phage plating with optimal tolerance to DNA methylation and the ability to propagate recombinants containing regions of potential secondary structure. To optimize this latter property, we have tested a series of strains for the ability to propagate a lambda phage containing a palindromic sequence. These included an mcr- derivative of a strain shown by Ishiura et al. [J. Bacteriol. 171 (1989) 1068-1074] to allow optimal stability of inserts in cosmid clones. All the sbcC strains allowed plaque formation of the palindrome-containing lambda phage. However, while the palindrome-containing phage plated with reasonable efficiency on SURE (recB sbcC recJ umuC uvrC) and SRB (sbcC recJ umuC uvrC), the majority of phage recovered from these strains no longer required an sbcC host for subsequent plating. These two strains also gave poorer titres with a low-yielding phage clone from the human Prader-Willi chromosome region. Optimal phage hosts appear to be those that are mcrA delta(mcrBC-hsd-mrr) combined with mutations in sbcC plus recBC or recD and without mutations in additional recombination functions such as recJ or recJ umuC uvrC (all of our E. coli strains are available on request).

Modified-cytosine restriction-system-induced recombinant cloning artefacts in Escherichia coli

We have tested whether, and to what extent, recombinant clones from DNA segments with 5-methylation of cytosines recovered in methylation-restrictive (mcr+) hosts contain mutations. We constructed a model system in which the tetracycline-resistance-encoding gene (tet) from pBR322 was cloned into the plasmid pGEM3Zf+. The central region of tet was removed from the construct, methylated in vitro and then religated back into the unmethylated remainder of the construct. The central region of tet was either (1) methylated with a combination of four bacterial methyltransferases (M.AluI, M.HaeIII, M.HpaII plus M.HhaI) or (2) methylated with M.SssI which methylates at all CpG dinucleotides. These two protocols generated theoretical levels of DNA methylation in the central fragment of 10.5% and 33%, respectively. The construct was transformed into a series of isogenic (recA+) bacterial strains that were mcrA+ mcrB+C+, mcrA+ mcrB-C+, mcrA- mcrB+C+, mcrA- mcrB-C+ or mcrA- delta mcrBC, and also into a set of isogenic recA- derivatives of these strains. With the two methylation protocols, there was an average 48- and 141-fold reduction, respectively, in the number of transformants recovered from the recA+ mcr+ hosts compared with a methylation-tolerant host (mcr-). Of the clones recovered in recA+mcr+ hosts, > 20% of clones had an inactivating mutation in tet. The majority of such mutant clones contained deletions that frequently extended into the unmethylated portion of tet and even into the plasmid sequences beyond the end of the polylinker. With the recA- mcr+ hosts, effective restriction was much more stringent, rendering the plasmid containing the methylated segment effectively unclonable.(ABSTRACT TRUNCATED AT 250 WORDS)

In vivo specificity of EcoRI DNA methyltransferase

The EcoRI adenine DNA methyltransferase forms part of a bacterial restriction/modification system; the methyltransferase modifies the second adenine within the canonical site GAATTC, thereby preventing the EcoRI endonuclease from cleaving this site. We show that five noncanonical EcoRI sites (TAATTC, CAATTC, GTATTC, GGATTC and GAGTTC) are not methylated in vivo under conditions when the canonical site is methylated. Only when the methyltransferase is overexpressed is partial in vivo methylation of the five sites detected. Our results suggest that the methyltransferase does not protect host DNA against potential endonuclease-mediated cleavage at noncanonical sites. Our related in vitro analysis of the methyltransferase reveals a low level of sequence-discrimination. We propose that the high in vivo specificity may be due to the active removal of methylated sequences by DNA repair enzymes (J. Bacteriology (1987), 169 3243-3250).

Improved plasmids containing the Escherichia coli dam gene under the control of the tac promoter

We report the construction of a series of plasmids containing the dam gene under the control of the tac promoter. Cells containing these plasmids produce about 8 to 10-fold more Dam methyltransferase (Mtase) than the previously used plasmid pTP166 and avoid the use of a high temperature step necessary for the expression of Dam Mtase in the plasmid pDOX1 and thus allow its use for the study of thermosensitive mutants.

Expression of Escherichia coli dam gene in Bacillus subtilis provokes DNA damage response: N6-methyladenine is removed by two repair pathways

The dam gene of Escherichia coli encodes a DNA methyltransferase that methylates the N6 position of adenine in the sequence GATC. It was stably expressed from a shuttle vector in a repair- and recombination-proficient strain of Bacillus subtilis. In this strain the majority of plasmid DNA molecules was modified at dam sites whereas most chromosomal DNA remained unmethylated during exponential growth. During stationary phase the amount of unmethylated DNA increased, suggesting that methylated bases were being removed. An ultraviolet damage repair-deficient mutant (uvrB) contained highly methylated chromosomal and plasmid DNA. High levels of Dam methylation were detrimental to growth and viability of this mutant strain and some features of the SOS response were also induced. A mutant defective in the synthesis of adaptive DNA alkyltransferases and induction of the adaptive response (ada) also showed high methylation and properties similar to that of the dam gene expressing uvrB strain. When protein extracts from B. subtilis expressing the Dam methyltransferase or treated with N-methyl-N'-nitro-N-nitroso-guanidine were incubated with [3H]-labelled Dam methylated DNA, the methyl label was bound to two proteins of 14 and 9 kD. Some free N6-methyladenine was also detected in the supernatant of the incubation mixture. We propose that N6-methyladenine residues are excised by proteins involved in both excision (uvrB) and the adaptive response (ada) DNA repair pathways in B. subtilis.

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.

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.

Cloning and sequencing of genes encoding the TthHB8I restriction and modification enzymes: comparison with the isoschizomeric TaqI enzymes

Genes encoding the TthHB8I restriction and modification (R-M) system from Thermus thermophilus HB8 (recognition sequence T decreases CGA) were cloned in Escherichia coli. The genes have the same transcriptional orientation, with the last 13 codons of the methyltransferase (MTase) overlapping the first 13 codons of the endonuclease (ENase). Nucleotide sequence analysis of the TthHB8I ENase revealed a single chain of 263 amino acid (aa) residues that share a 77% identity with the corrected isoschizomeric TaqI ENase. Likewise, the Tth MTase (428 aa) shares a 79% identity with the corrected sequence of the TaqI MTase. This high degree of aa conservation suggests a common origin between the Taq and Tth R-M systems. However, codon usage and G+C content for the R-M genes differed markedly from that of other cloned Thermus genes. This suggests that these R-M genes were only recently introduced into the genus Thermus.

Cloning, overexpression and nucleotide sequence of a thermostable DNA ligase-encoding gene

Thermostable DNA ligase has been harnessed for the detection of single-base genetic diseases using the ligase chain reaction [Barany, Proc. Natl. Acad. Sci. USA 88 (1991) 189-193]. The Thermus thermophilus (Tth) DNA ligase-encoding gene (ligT) was cloned in Escherichia coli by genetic complementation of a ligts 7 defect in an E. coli host. Nucleotide sequence analysis of the gene revealed a single chain of 676 amino acid residues with 47% identity to the E. coli ligase. Under phoA promoter control, Tth ligase was overproduced to greater than 10% of E. coli cellular proteins. Adenylated and deadenylated forms of the purified enzyme were distinguished by apparent molecular weights of 81 kDa and 78 kDa, respectively, after separation via sodium dodecyl sulfate-polyacrylamide-gel electrophoresis.

Use of cloned DNA methylase genes to increase the frequency of transfer of foreign genes into Xanthomonas campestris pv. malvacearum

In vitro-packaged cosmid libraries of DNA from the bacterium Xanthomonas campestris pv. malvacearum were restricted 200- to 1,000-fold when introduced into Mcr+ strains of Escherichia coli compared with restriction in the Mcr- strain HB101. Restriction was predominantly associated with the mcrBC+ gene in E. coli. A plasmid (pUFR052) encoding the XmaI and XmaIII DNA methylases was isolated from an X. campestris pv. malvacearum library by a screening procedure utilizing Mcr+ and Mcr- E. coli strains. Transfer of plasmids from E. coli strains to X. campestris pv. malvacearum by conjugation was enhanced by up to five orders of magnitude when the donor cells contained pUFR052 as well as the plasmid to be transferred. Subcloning of pUFR052 revealed that at least two regions of the plasmid were required for full modification activity. Use of such modifier plasmids is a simple, novel method that may allow the efficient introduction of genes into any organism in which restriction systems provide a potent barrier to such gene transfer.

Characterization and expression of the Escherichia coli Mrr restriction system

The mrr gene of Escherichia coli K-12 is involved in the acceptance of foreign DNA which is modified. The introduction of plasmids carrying the HincII, HpaI, and TaqI R and M genes is severely restricted in E. coli strains that are Mrr+. A 2-kb EcoRI fragment from the plasmid pBg3 (B. Sain and N. E. Murray, Mol. Gen. Genet. 180:35-46, 1980) was cloned. The resulting plasmid restores Mrr function to mrr strains of E. coli. The boundaries of the mrr gene were determined from an analysis of subclones, and plasmids with a functional mrr gene produce a polypeptide of 33.5 kDa. The nucleotide sequence of the entire fragment was determined; in addition to mrr, it includes two open reading frames, one of which encodes part of the hsdR. By using Southern blot analysis, E. coli RR1 and HB101 were found to lack the region containing mrr. The acceptance of various cloned methylases in E. coli containing the cloned mrr gene was tested. Plasmid constructs containing the AccI, CviRI, HincII, Hinfl (HhaII), HpaI, NlaIII, PstI, and TaqI N6-adenine methylases and SssI and HhaI C5-cytosine methylases were found to be restricted. Plasmid constructs containing 16 other adenine methylases and 12 cytosine methylases were not restricted. No simple consensus sequence causing restriction has been determined. The Mrr protein has been overproduced, an antibody has been prepared, and the expression of mrr under various conditions has been examined. The use of mrr strains of E. coli is suggested for the cloning of N6-adenine and C5-cytosine methyl-containing DNA.

A novel activity in Escherichia coli K-12 that directs restriction of DNA modified at CG dinucleotides

The restriction systems McrA and McrB of Escherichia coli K-12 are known to attack DNA containing modified cytosine. In strains lacking both activities, however, we observed that DNA methylated at CG dinucleotides (as is mammalian DNA) was still significantly restricted. We show that this substantial barrier to the acceptance of 5-methylcytosine-containing DNA is attributable to a hitherto unknown activity of the Mrr restriction system. Strikingly, the multiple systems used by this gut inhabitant to determine the fate of invading DNA will all limit genetic exchange with its mammalian host(s), reinforcing the idea that one role of DNA methylation is to serve as a "molecular passport" (E. A. Raleigh, R. Trimarchi, and H. Revel, Genetics 122:279-296, 1989).

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.

SOS induction as an in vivo assay of enzyme-DNA interactions

We have constructed strains which are convenient and sensitive indicators of DNA damage and describe their use. These strains utilize an SOS::lac Z fusion constructed by Kenyon and Walker [Proc. Natl. Acad. Sci. USA 77 (1980) 2819-2823] and respond to DNA damage by producing beta-galactosidase. They can be used to characterize restriction systems and screen for restriction endonuclease mutants. Applications include the study of other enzymes involved in DNA metabolism, such as DNA methyltransferases, topoisomerases, recombinases, and DNA replication and repair enzymes.

Construction and use of halobacterial shuttle vectors and further studies on Haloferax DNA gyrase

We report here on advances made in the construction of plasmid shuttle vectors suitable for genetic manipulations in both Escherichia coli and halobacteria. Starting with a 20.4-kb construct, pMDS1, new vectors were engineered which were considerably smaller yet retained several alternative cloning sites. A restriction barrier observed when plasmid DNA was transferred into Haloferax volcanii cells was found to operate via adenine methylation, resulting in a 10(3) drop in transformation efficiency and the loss of most constructs by incorporation of the resistance marker into the chromosome. Passing shuttle vectors through E. coli dam mutants effectively avoided this barrier. Deletion analysis revealed that the gene(s) for autonomous replication of pHK2 (the plasmid endogenous to Haloferax strain Aa2.2 and used in the construction of pMDS1) was located within a 4.2-kb SmaI-KpnI fragment. Convenient restriction sites were identified near the termini of the novobiocin resistance determinant (gyrB), allowing the removal of flanking sequences (including gyrA). These deletions did not appear to significantly affect transformation efficiencies or the novobiocin resistance phenotype of halobacterial transformants. Northern blot hybridization with strand- and gene-specific probes identified a single gyrB-gyrA transcript of 4.7 kb. This is the first demonstration in prokaryotes that the two subunits of DNA gyrase may be cotranscribed.

Organization of restriction-modification systems

The genes for over 100 restriction-modification systems have now been cloned, and approximately one-half have been sequenced. Despite their similar function, they are exceedingly heterogeneous. The heterogeneity is evident at three levels: in the gene arrangements; in the enzyme compositions; and in the protein sequences. This paper summarizes the main features of the R-M systems that have been cloned.

A new method for the rapid identification of genes encoding restriction and modification enzymes

We have constructed derivatives of Escherichia coli that can be used for the rapid identification of recombinant plasmids encoding DNA restriction enzymes and methyltransferases. The induction of the DNA-damage inducible SOS response by the Mcr and Mrr systems, in the presence of methylated DNA, is used to select plasmids encoding DNA methyltransferases. The strains of E. coli that we have constructed are temperature-sensitive for the Mcr and Mrr systems and have been further modified to include a lacZ gene fused to the damage-inducible dinD locus of E. coli. The detection of recombinant plasmids encoding DNA methyltransferases and restriction enzymes is a simple, one step procedure that is based on the induction at the restrictive temperature of the lacZ gene. Transformants encoding DNA methyltransferase genes are detected on LB agar plates supplemented with X-gal as blue colonies. Using this method, we have cloned a variety of DNA methyltransferase genes from diverse species such as Neisseria, Haemophilus, Treponema, Pseudomonas, Xanthomonas and Saccharopolyspora.

Nomenclature relating to restriction of modified DNA in Escherichia coli

At least three restriction systems that attack DNA containing naturally modified bases have been found in common Escherichia coli K-12 strains. These systems are McrA, McrBC, and Mrr. A brief summary of the genetic and phenotypic properties so far observed in laboratory strains is set forth, together with a proposed nomenclature for describing these properties.

Cloning and characterization of the MboII restriction-modification system

The two genes encoding the class IIS restriction-modification system MboII from Moraxella bovis were cloned separately in two compatible plasmids and expressed in E. coli RR1 delta M15. The nucleotide sequences of the MboII endonuclease (R.MboII) and methylase (M.MboII) genes were determined and the putative start codon of R.MboII was confirmed by amino acid sequence analysis. The mboIIR gene specifies a protein of 416 amino acids (MW: 48,617) while the mboIIM gene codes for a putative 260-residue polypeptide (MW: 30,077). Both genes are aligned in the same orientation. The coding region of the methylase gene ends 11 bp upstream of the start codon of the restrictase gene. Comparing the amino acid sequence of M.MboII with sequences of other N6-adenine methyltransferases reveals a significant homology to M.RsrI, M.HinfI and M.DpnA. Furthermore, M.MboII shows homology to the N4-cytosine methyltransferase BamHI.

Enzymatic cleavage of a bacterial chromosome at a transposon-inserted rare site

The sequential use of the methylase M.Xbal (5'.TCTAGm6A) and the methylation-dependent endonuclease Dpnl (5'-Gm6A decreases TC) results in cleavage at 5'.TCTAGA decreases TCTAGA. This recognition sequence was introduced into a transposon derived from the Mu bacteriophage and transposed into the genome of the bacterium Salmonella typhimurium. M.Xbal methylation was provided in vivo by a plasmid containing the M.Xbal gene and the S. typhimurium genome was cleaved to completion by Dpnl at one or more sites, depending on the number of transposon insertions. The resulting genomic fragments were resolved by pulsed-field electrophoresis. The potential use of single M.Xbal/Dpnl cleavage sites as reference positions to map rare restriction sites is discussed.

Effects of mcr restriction of methylated CpG islands of the L1 transposons during packaging and plating stages of mammalian genomic library construction

The use of optimally methylation-tolerant mcrA- mcrB- strains has been shown to produce an over tenfold increase in the plating efficiencies of mammalian genomic libraries, compared to a superior conventional phage host strain LE392 which is mcrB+. However, there is an even more significant effect of mcr restriction. Amongst the recombinants recovered with an mcrB+ host, we have found that there is an additional 30-fold reduction in the frequencies of clones containing the heavily methylated 5'-CpG island sequences of both the human and rat L1 repetitive elements. The mcrA product was also found to restrict clones of these methylated genomic segments, but not as strongly as mcrB. However, the use of packaging extracts made from mcrA+ lysogens did not result in convincing reductions in the recoveries of these dispersed methylated elements. The magnitude of mcr restriction during plating due to methylated dispersed elements is sufficient to make a significant proportion of mammalian genomes unclonable from genomic libraries constructed previously using conventional mcr+ hosts.