Role of DNA methylation at GATC sites in the dnaA promoter, dnaAp2

DnaA protein is required for the initiation of DNA replication at the bacterial chromosomal origin, oriC, and at the origins of many plasmids. The concentration of DnaA protein is an important factor in determining when initiation occurs during the cell cycle. Methylation of GATC sites in the dnaAp2 promoter, two of which are in the -35 and -10 sequences, has been predicted to play an important role in regulating dnaA gene expression during the cell cycle because the promoter is sequestered from methylation immediately following replication. Mutations that eliminate these two GATC sites but do not substantially change the activity of the promoter were introduced into a reporter gene fusion and into the chromosome. The chromosomal mutants are able to initiate DNA replication synchronously at both moderately slow and fast growth rates, demonstrating that GATC methylation at these two sites is not directly involved in providing the necessary amount of DnaA for precise timing of initiation during the cell cycle. Either sequestration does not involve these GATC sites, or cell cycle control of DnaA expression is not required to supply the concentration necessary for correct timing of initiation.     

Site-specific methylation of adenine in the nuclear genome of a eucaryote, Tetrahymena thermophila.

DNA in the polyploid macronucleus of the ciliated protozoan Tetrahymena thermophila contains the modified base N6-methyladenine. We identified two GATC sites which are methylated in most or all of the 45 copies of the macronuclear genome. One site is 2 kilobases 5' to the histone H4-I gene, and the other is 5 kilobases 3' to the 73-kilodalton heat shock protein gene. These sites are de novo methylated between 10 and 16 h after initiation of conjugation, during macronuclear anlage development. The methylation states of these two GATC sites and four other unmethylated GATC sites do not change in the DNA of cells cultured under conditions which change the activity of the genes, including logarithmic growth, starvation, and heat shock.     

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.     

Proximal recognition sites facilitate intrasite hopping by DNA adenine methyltransferase: mechanistic exploration of epigenetic gene regulation

The methylation of adenine in palindromic 5'-GATC-3' sites by Escherichia coli Dam supports diverse roles, including the essential regulation of virulence genes in several human pathogens. As a result of a unique hopping mechanism, Dam methylates both strands of the same site prior to fully dissociating from the DNA, a process referred to as intrasite processivity. The application of a DpnI restriction endonuclease-based assay allowed the direct interrogation of this mechanism with a variety of DNA substrates. Intrasite processivity is disrupted when the DNA flanking a single GATC site is longer than 400 bp on either side. Interestingly, the introduction of a second GATC site within this flanking DNA reinstates intrasite methylation of both sites. Our results show that intrasite methylation occurs only when GATC sites are clustered, as is found in gene segments both known and postulated to undergo in vivo epigenetic regulation by Dam methylation. We propose a model for intrasite methylation in which Dam bound to flanking DNA is an obligate intermediate. Our results provide insights into how intrasite processivity, which appears to be context-dependent, may contribute to the diverse biological roles that are carried out by Dam.     

Competitive Lrp and Dam assembly at the pap regulatory region: implications for mechanisms of epigenetic regulation

Escherichia coli DNA adenine methyltransferase (Dam) and Leucine-responsive regulatory protein (Lrp) are key regulators of the pap operon, which codes for the pilus proteins necessary for uropathogenic E. coli cellular adhesion. The pap operon is regulated by a phase variation mechanism in which the methylation states of two GATC sites in the pap regulatory region and the binding position of Lrp determine whether the pilus genes are expressed. The post-replicative reassembly of Dam, Lrp, and the local regulator PapI onto a hemimethylated pap intermediate is a critical step of the phase variation switching mechanism and is not well understood. We show that Lrp, in the presence and in the absence of PapI and nonspecific DNA, specifically protects pap regulatory GATC sites from Dam methylation when allowed to compete with Dam for assembly on unmethylated and hemimethylated pap DNA. The methylation protection is dependent upon the concentration of Lrp and does not occur with non-regulatory GATC sites. Our data suggest that only at low Lrp concentrations will Dam compete effectively for binding and methylation of the proximal GATC site, leading to a phase switch resulting in the expression of pili.     

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.     

Dam methyltransferase sites located within the loop region of the oligopurine-oligopyrimidine sequences capable of forming H-DNA are undermethylated in vivo.

Several derivatives of pUC18 plasmid were constructed that contained oligopurine-oligopyrimidine (pur-pyr) motifs surrounded by Dam methylation sites. Inserts of two of the molecules (pPP1 and pPP2) were able to adopt the triple-stranded conformation in vitro and show in vivo a remarkable undermethylation of specific sites when grown in JM105 dam+ strain. Mapping experiments revealed that undermethylated GATC sequences were located exclusively within the single-stranded loop region of the sequence involved in H-DNA formation. Control molecules which either contained the pur-pyr tracts (pPPK and pKK42) or not (pUC18) and were not able to form the triple-stranded conformation were found to be normally methylated by the dam gene product in vivo. Location of GATC within the triplex forming sequence seems to be a prerequisite for achieving its in vivo undermethylation. E.coli host factors are involved in the observed phenomenon. This has been deduced from the fact that the undermethylated state of pPP1 and pPP2 does not depend on the phase of growth of host cells and is steadily maintained up to 50 hours, whereas the kinetics of Dam methylation in vitro of sites located within the triplex loop does not differ substantially from the kinetics of methylation of other sites on the vector. Full methylation can be readily achieved in vitro. Additional factor(s) that operate in vivo to control the undermethylated state are most likely proteins since the observed effect can be suppressed by chloramphenicol administration to the cell cultures.     

The combination of DNA methylation and H1 histone binding inhibits the action of a restriction nuclease on plasmid DNA.

To investigate the potentials of DNA methylation and H1 histone in regulating the action of DNA binding proteins, well ordered complexes were formed by slow salt gradient dialysis of mixtures of H1 histone with either methylated or nonmethylated DNA. The sites methylated in the plasmids were CCGG. Methylation of cytosine in this site protects the DNA against HpaII endonuclease but not against MspI. However, when the methylated DNA was complexed to H1, it was protected against MspI. The protection was only effective for a subset of the MspI restriction sites. The protection of DNA afforded by the combination of H1 binding and DNA methylation did not apply to EcoRI, PstI, or BamHI sites and so did not seem to be due to aggregation of the DNA by H1 histone. Gel retardation assays indicated that the affinity of H1 for methylated DNA was not detectably different from its affinity for nonmethylated DNA. Probably methylated DNA when bound to H1 is in a conformation that is resistant to MspI endonuclease. Such conformational changes induced by DNA methylation and H1 binding might affect the action of other DNA binding proteins, perhaps in chromatin as well as in H1.DNA complexes.     

Arrangement of Dam methylation sites (GATC) in the Escherichia coli chromosome.

The occurrence of GATC (Dam-recognition) sites in available E. coli DNA sequences (representing about 2% of the chromosome) has been determined by a simple numerical analysis. Our approach was to analyze the nucleotide composition of nine large sequenced DNA stretches ("cantles") in order to identify patterns of GATC distribution and to rationalize such patterns in biological/structural terms. The following observations were made: (i) In addition to oriC, GATC-rich regions are present in numerous locations. (ii) There is a wide variation in GATC frequency both between and within DNA cantles which led to the identification of a void-cluster pattern of GATC arrangement. The distance between two GATCs was never greater than 2 kb. (iii) GATC sites are found more frequently in translated regions than (in decreasing order) non-coding or non-translated regions. In particular, rRNA and tRNA encoding genes exhibit the lowest GATC content.     

An oriC-like distribution of GATC sites mediates full sequestration of non-origin sequences in Escherichia coli

Sequestration of newly replicated origins is one of the mechanisms required to limit initiation of Escherichia coli chromosome replication to once per generation. Origin sequestration lasts for a considerably longer period of time than the sequestration of other newly replicated regions of the chromosome. The reason for this may be the high number of GATC sites present in the origin. Alternatively, other sequence elements in the origin region may be important for its prolonged sequestration. To distinguish between these possibilities we constructed a DNA fragment containing ten GATC sites distributed with the same spacing as the ten GATC sites in the left half of oriC, but with random sequence between the GATC sites, and inserted it at a non-sequestered chromosome location. Sequestration of this GATC-cluster lasted as long as that of oriC, or even longer. The result shows that the presence of ten GATC sites, distributed as in oriC, is sufficient to cause full sequestration, and that other sequence elements most likely do not contribute to sequestration.     

Stochastic modeling of the phase-variable pap operon regulation in uropathogenic Escherichia coli

Regulation of the pap operon in uropathogenic Escherichia coli is phase variable. This phase variation arises from competition between regulatory proteins at two sites within the regulatory region, GATC(dist) and GATC(prox). We have used the available literature data to design a stochastic model of the molecular interactions of pap regulation and expression during growth in a non-glucose environment at 37 degrees C. The resulting wild-type model is consistent with reported data. The wild-type model served as a basis for two "in silico" mutant models for investigating the role of key regulatory components, the GATC(dist) binding site and the PapI interaction with Lrp at the GATC(prox) site. Our results show that competition at GATC(dist) is required for phase variation, as previously reported. However, our results suggest that removal of competition at GATC(dist) does not affect initial state dependence. Additionally, the PapI involvement in Lrp translocation from GATC(prox) to GATC(dist) is required for the initial state dependence but not for phase variation. Our results also predict that pap expression is maximized at low growth rates and minimized at high growth rates. These predictions provide a basis for further experimental investigation.     

Methylation of spore DNA in Bacillus coagulans strain 26

The modification status of DNA throughout the life cycle of Bacillus coagulans strain 26 was analysed by restriction analysis with methylation-sensitive enzymes. A significant fraction of the GATC sequences (dam target) in spore DNA contain N6-methyladenine, a modification that is lacking during the vegetative phase. From the modulation of the modification pattern of GATC sites, the existence of a de novo methylase may be inferred. Spore DNA was more sensitive than vegetative cell DNA to BamHI, HpaI, SalI and XhoI, indicating that the sites for these enzymes are modified during the vegetative growth phase.