Studies on the biological role of dna methylation; IV. Mode of methylation of DNA in E. coli cells

Two pairs of restriction enzyme isoschizomers were used to study in vivo methylation of E. coli and extrachromosomal DNA. By use of the restriction enzymes MboI (which cleaves only the unmethylated GATC sequence) and its isoschizomer Sau3A (indifferent to methylated adenine at this sequence), we found that all the GATC sites in E. coli and in extrachromosomal DNAs are symmetrically methylated on both strands. The calculated number of GATC sites in E. coli DNA can account for all its m6Ade residues. Foreign DNA, like mouse mtDNA, which is not methylated at GATC sites became fully methylated at these sequences when introduced by transfection into E. coli cells. This experiment provides the first evidence for the operation of a de novo methylation mechanism for E. coli methylases not involved in restriction modification. When the two restriction enzyme isoschizomers, EcoRII and ApyI, were used to analyze the methylation pattern of CCTAGG sequences in E. coli C and phi X174 DNA, it was found that all these sites are methylated. The number of CCTAGG sites in E. coli C DNA does not account for all m5Cyt residues.     

The effect of differential methylation by Escherichia coli of plasmid DNA and phage T7 and lambda DNA on the cleavage by restriction endonuclease MboI from Moraxella bovis.

The nucleotide sequence recognized and cleaved by the restriction endonuclease MboI is 5' GATC and is identical to the central tetranucleotide of the restriction sites of BamHI and BglII. Experiments on the restriction of DNA from Escherichia coli dam and dam+ confirm the notion that GATC sequences are adenosyl-methylated by the dam function of E. coli and thereby are made refractory to cleavage by MboI. On the basis of this observation the degree of dam methylation of various DNAs was examined by cleavage with MboI and other restriction endonucleases. In plasmid DNA essentially all of the GATC sequences are methylated by the dam function. The DNA of phage lambda is only partially methylated, extended methylation is observed in the DNA of a substitution mutant of lambda, lambda gal8bio256, and in the lambda derived plasmid, lambdadv93, which is completely methylated. In contrast, phage T7 DNA is not methylated by dam. A suppression of dam methylation of T7 DNA appears to act only in cis dam. A suppression of dam methylation of T7 DNA appears to act only in cis since plasmid DNA replicated in a T7-infected cell is completely methylated. The results are discussed with respect to the participation of the dam methylase in different replication systems.     

Methylation of GATC sites is required for precise timing between rounds of DNA replication in Escherichia coli.

We have used the Koppes and Nordstr?m (Cell 44:117-124, 1986) CsCl density transfer approach for analysis of DNA from exponentially growing, isogenic Escherichia coli dam+ and dam mutant cells to show that timing between DNA replication initiation events is precise in the dam+ cells but is essentially random in the dam cells. Thus, methylation of one or more GATC sites, such as those found in unusual abundance within the origin, oriC, is required for precise timing between rounds of DNA replication, and precise timing between initiation events is not required for cell viability. Both the dam-3 point mutant and the delta(dam)100 complete deletion mutant were examined. The results were independent of the mismatch repair system; E. coli mutH cells showed precise timing, whereas timing in the isogenic E. coli mutH delta(dam)100 double mutant was random. The mechanism is thus different from the role of Dam methylation in mismatch repair and probably involves conversion of hemimethylated GATC sites present in daughter origins just after initiation to a fully methylated state.     

Importance of state of methylation of oriC GATC sites in initiation of DNA replication in Escherichia coli.

In vivo and in vitro evidence is presented implicating a function of GATC methylation in the Escherichia coli replication origin, oriC, during initiation of DNA synthesis. Transformation frequencies of oriC plasmids into E. coli dam mutants, deficient in the GATC-specific DNA methylase, are greatly reduced compared with parental dam+ cells, particularly for plasmids that must use oriC for initiation. Mutations that suppress the mismatch repair deficiency of dam mutants do not increase these low transformation frequencies, implicating a new function for the Dam methylase. oriC DNA isolated from dam- cells functions 2- to 4-fold less well in the oriC-specific in vitro initiation system when compared with oriC DNA from dam+ cells. This decreased template activity is restored 2- to 3-fold if the DNA from dam- cells is first methylated with purified Dam methylase. Bacterial origin plasmids or M13-oriC chimeric phage DNA, isolated from either base substitution or insertion dam mutants of E. coli, exhibit some sensitivity to digestion by DpnI, a restriction endonuclease specific for methylated GATC sites, showing that these dam mutants retain some Dam methylation activity. Sites of preferred cleavage are found within the oriC region, as well as in the ColE1-type origin.     

Effect of dam methylation on the activity of the E. coli replication origin, oriC.

Methylation of GATC sites by the dam methylase is required for efficient initiation of DNA replication at the replication origin, oriC, of Escherichia coli. This is demonstrated by the inability of minichromosomes to be maintained in dam mutant strains. The requirement for methylated GATC sites is less stringent in vitro than in vivo. The time required for complete methylation of the origin region apparently determines the minimal spacing of replication forks on the chromosome.     

Modulation of Escherichia coli DNA methyltransferase activity by biologically derived GATC-flanking sequences

Escherichia coli DNA adenine methyltransferase (EcoDam) methylates the N-6 position of the adenine in the sequence 5'-GATC-3' and plays vital roles in gene regulation, mismatch repair, and DNA replication. It remains unclear how the small number of critical GATC sites involved in the regulation of replication and gene expression are differentially methylated, whereas the approximately 20,000 GATCs important for mismatch repair and dispersed throughout the genome are extensively methylated. Our prior work, limited to the pap regulon, showed that methylation efficiency is controlled by sequences immediately flanking the GATC sites. We extend these studies to include GATC sites involved in diverse gene regulatory and DNA replication pathways as well as sites previously shown to undergo differential in vivo methylation but whose function remains to be assigned. EcoDam shows no change in affinity with variations in flanking sequences derived from these sources, but methylation kinetics varied 12-fold. A-tracts immediately adjacent to the GATC site contribute significantly to these differences in methylation kinetics. Interestingly, only when the poly(A) is located 5' of the GATC are the changes in methylation kinetics revealed. Preferential methylation is obscured when two GATC sites are positioned on the same DNA molecule, unless both sites are surrounded by large amounts of nonspecific DNA. Thus, facilitated diffusion and sequences immediately flanking target sites contribute to higher order specificity for EcoDam; we suggest that the diverse biological roles of the enzyme are in part regulated by these two factors, which may be important for other enzymes that sequence-specifically modify DNA.     

GATC flanking sequences regulate Dam activity: evidence for how Dam specificity may influence pap expression

Escherichia coli DNA adenine methyltransferase (Dam) plays essential roles in DNA replication, mismatch repair and gene regulation. The differential methylation by Dam of the two GATC sequences in the pap promoter regulates the expression of pili genes necessary for uropathogenic E.coli cellular adhesion. Dam processively methylates GATC sites in various DNA substrates, yet the two pap GATC sites are not processively methylated. We previously proposed that the flanking sequences surrounding the two pap GATC sites contribute to the enzyme's distributive methylation. We show here that replacement of the poorly methylated pap GATC sites with sites predicted to be processively methylated indeed results in an increase in Dam processivity. The increased processivity is due to a change in the methyltransfer kinetics and not the binding efficiency of Dam. A competition experiment in which the flanking sequences of only one pap GATC site were altered demonstrates that the GATC flanking sequences directly regulate the enzyme's catalytic efficiency. The GATC flanking sequences in Dam-regulated promoters in E.coli and other bacteria are similar to those in the pap promoter. Gene regulation from some of these promoters involves mechanisms and proteins that are quite different from those in the pap operon. Further, GATC sequences previously identified to remain unmethylated within the E.coli genome, but whose function remains largely unassigned, are flanked by sequences predicted to be poorly methylated. We conclude that the GATC flanking sequences may be critical for expression of pap and other Dam-regulated genes by affecting the activity of Dam at such sites and, thus, its processivity. A model is proposed, illustrating how the sequences flanking the GATC sites in Dam-regulated promoters may contribute to this epigenetic mechanism of gene expression, and how flanking sequences contribute to the diverse biological roles of Dam.     

DNA methylation at mammalian replication origins.

In Escherichia coli, DNA methylation regulates both origin usage and the time required to reassemble prereplication complexes at replication origins. In mammals, at least three replication origins are associated with a high density cluster of methylated CpG dinucleotides, and others whose methylation status has not yet been characterized have the potential to exhibit a similar DNA methylation pattern. One of these origins is found within the approximately 2-kilobase pair region upstream of the human c-myc gene that contains 86 CpGs. Application of the bisulfite method for detecting 5-methylcytosines at specific DNA sequences revealed that this region was not methylated in either total genomic DNA or newly synthesized DNA. Therefore, DNA methylation is not a universal component of mammalian replication origins. To determine whether or not DNA methylation plays a role in regulating the activity of origins that are methylated, the rate of remethylation and the effect of hypomethylation were determined at origin beta (ori-beta), downstream of the hamster DHFR gene. Remethylation at ori-beta did not begin until approximately 500 base pairs of DNA was synthesized, but it was then completed by the time that 4 kilobase pairs of DNA was synthesized (<3 min after release into S phase). Thus, DNA methylation cannot play a significant role in regulating reassembly of prereplication complexes in mammalian cells, as it does in E. coli. To determine whether or not DNA methylation plays any role in origin activity, hypomethylated hamster cells were examined for ori-beta activity. Cells that were >50% reduced in methylation at ori-beta no longer selectively activated ori-beta. Therefore, at some loci, DNA methylation either directly or indirectly determines where replication begins.     

The oriC unwinding by dam methylation in Escherichia coli.

It has been shown that dam methylation is important in the regulation of initiation of DNA replication in E.coli. The question then arises as to whether dam methylation in the oriC region mediates any structural changes in DNA involved in the regulation of initiation of DNA replication. We demonstrate that the thermal melting temperature of the oriC region is lowered by adenine methylation at GATC sites. The regulation of initiation of DNA replication by dam methylation may be attributed to the ease of unwinding at GATC sites in oriC.     

The Escherichia coli dam DNA methyltransferase modifies DNA in a highly processive reaction

The Escherichia coli dam adenine-N6 methyltransferase modifies DNA at GATC sequences. It is involved in post-replicative mismatch repair, control of DNA replication and gene regulation. We show that E. coli dam acts as a functional monomer and methylates only one strand of the DNA in each binding event. The preferred way of ternary complex assembly is that the enzyme first binds to DNA and then to S-adenosylmethionine. The enzyme methylates an oligonucleotide containing two dam sites and a 879 bp PCR product with four sites in a fully processive reaction. On lambda-DNA comprising 48,502 bp and 116 dam sites, E. coli dam scans 3000 dam sites per binding event in a random walk, that on average leads to a processive methylation of 55 sites. Processive methylation of DNA considerably accelerates DNA methylation. The highly processive mechanism of E. coli dam could explain why small amounts of E. coli dam are able to maintain the methylation state of dam sites during DNA replication. Furthermore, our data support the general rule that solitary DNA methyltransferase modify DNA processively whereas methyltransferases belonging to a restriction-modification system show a distributive mechanism, because processive methylation of DNA would interfere with the biological function of restriction-modification systems.     

Hemimethylation prevents DNA replication in E. coli

The DNA adenine methylase of E. coli methylates adenines at GATC sequences. Strains deficient in this methylase are transformed poorly by methylated plasmids that depend on either the pBR322 or the chromosomal origins for replication. We show here that hemimethylated plasmids also transform dam- bacteria poorly but that unmethylated plasmids transform them at high frequencies. Hemimethylated daughter molecules accumulate after the transformation of dam- strains by fully methylated plasmids, suggesting that hemimethylation prevents DNA replication. We also show that plasmids purified from dam+ bacteria are hemimethylated at certain sites. These results can explain why newly formed daughter molecules are not substrates for an immediate reinitiation of DNA replication in wild-type E. coli.     

DNA adenine methylation changes dramatically during establishment of symbiosis

The DNA adenine methylation status on specific 5'-GANTC-3' sites and its change during the establishment of plant-microbe interactions was demonstrated in several species of alpha-proteobacteria. Restriction landmark genome scanning (RLGS), which is a high-resolution two dimensional DNA electrophoresis method, was used to monitor the genomewide change in methylation. In the case of Mesorhizobium loti MAFF303099, real RLGS images obtained with the restriction enzyme MboI, which digests at GATC sites, almost perfectly matched the virtual RLGS images generated based on genome sequences. However, only a few spots were observed when the restriction enzyme HinfI was used, suggesting that most GANTC (HinfI) sites were tightly methylated and specific sites were unmethylated. DNA gel blot analysis with the cloned specifically unmethylated regions (SUMs) showed that some SUMs were methylated differentially in bacteroids compared to free-living bacteria. SUMs have also been identified in other symbiotic and parasitic bacteria. These results suggest that DNA adenine methylation may contribute to the establishment and/or maintenance of symbiotic and parasitic relationships.     

Preferential site-specific hemimethylation of GATC sites in pBR322 DNA by Dam methyltransferase from Escherichia coli

The methylation pattern of the 22 GATC sites of pBR322 (dam-) by Dam methyltransferase from Escherichia coli has been studied. Preferential hemimethylation took place at positions 3042 and 349. It was found that these preferential methylations were the same in supercoiled circular and linear DNAs. The flanking regions of these preferentially methylated sites contain three G.C pairs on one side and two A.T pairs and one G.C pair on the other. This preferential methylation was confirmed on a 126-base pair oligonucleotide containing two GATC sites with different flanking sequences. The next sites methylated were, in both cases, the first GATC site on the A.T-rich side, although the orientation was different. The rapid methylation of a second and third neighboring GATC site on the same plasmid suggests a processive mechanism. The implications of the orientation of hemimethylation are discussed in the context of the recognition of a palindromic target site by a monomeric DNA-binding protein.     

Evidence that Escherichia coli virus T1 induces a DNA methyltransferase

DNA of Escherichia coli virus T1 is resistant to MboI cleavage and appears to be heavily methylated. Analysis of methylation by the isoschizomeric restriction enzymes Sau3AI and DpnI revealed that recognition sites for E. coli DNA adenine methylase (dam methylase) are methylated. The same methylation pattern was found for virus T1 DNA grown on an E. coli dam host, indicating a T1-specific DNA methyltransferase.     

Biological role of DNA methylation: sequence-specific single-strand breaks associated with hypomethylation of GATC sites in Escherichia coli DNA.

The effect of methylation of GATC sites in Escherichia coli DNA on the formation of single-strand breaks was studied with dam+, dam mutant, and Dam-overproducer strains. Single-strand breaks have been observed in dam mutant cells predominantly at TpT and, to a lesser extent, at CpC. In dam mutant cells harboring pTP166 (a plasmid containing the dam gene), no such nicks were observed.     

Analysis of nucleotide methylation in DNA from Corynebacterium glutamicum and related species

Abstract Plasmid DNA (pCSL17) isolated from Corynebacterium glutamicum transformed recipient McrBC⁺ strains of Escherichia coli with lower efficiency than McrBC⁻ strains, confirming a previous report by Tauch et al. (FEMS Microbiol. Lett. 123 (1994) 343–348) which inferred that C. glutamicum DNA contains methylcytidine. Analysis of nucleotides in C. glutamicum -derived chromosomal and plasmid DNA failed to detect significant levels of methylated adenosine, but methylated cytidine was readily detected. Restriction enzymes which are inhibited by the presence of methylcytidine in their recognition sequence failed to cut pCSL17 from C. glutamicum , whereas enzymes which require methylation at adenosine in GATC sequences failed to cut. Failure of Hae III to cut two specific sites of C. glutamicum -denved pCSL17 identified the first cytidine in the sequence GGCCGC as one target of methylation in this species, which contains the methyltransferase recognition sequence. Although Brevibacterium lactofermentum -derived DNA showed a similar methylation pattern by HPLC analysis, Hae III cleaved these GGCCGC sites, suggesting differences in the specificity of methylation between these two species. Results for all analyses of B. flavum DNA were identical to those for C. glutamicum .