Accuracy of DNA methylation pattern preservation by the Dnmt1 methyltransferase

DNA methyltransferase 1 (Dnmt1) has a central role in copying the pattern of DNA methylation after replication which is one manifestation of epigenetic inheritance. With oligonculeotide substrates we show that mouse Dnmt1 has a 30- to 40-fold preference for hemimethylated DNA that is almost lost after addition of fully methylated oligonucleotides. Using long hemimethylated DNA substrates that carry defined methylation patterns and bisulfite analysis of the methylation reaction products, we show a 15-fold preference for hemimethylated CG sites. Dnmt1 moves along the DNA in a random walk methylating hemimethylated substrates with high processivity (>50 sites are visited on average which corresponds to linear diffusion over 6000 bp). The frequency of skipping sites is very low (<0.3%) and there is no detectable flanking sequence preference. CGCTC sites tend to terminate the processive methylation of DNA by Dnmt1. Unmethylated DNA is modified non-processively with a preference for methylation at CCGG sites. We simulate the propagation of methylation patterns using a stochastic model with the specificity of Dnmt1 observed here and conclude that either methylation of several sites is required to propagate the methylation information over several cellular generations or additional epigenetic information must be used.     

Processive methylation of hemimethylated CpG sites by mouse Dnmt1 DNA methyltransferase

DNA methyltransferase Dnmt1 ensures clonal transmission of lineage-specific DNA methylation patterns in a mammalian genome during replication. Dnmt1 is targeted to replication foci, interacts with PCNA, and favors methylating the hemimethylated form of CpG sites. To understand the underlying mechanism of its maintenance function, we purified recombinant forms of full-length Dnmt1, a truncated form of Dnmt1-(291-1620) lacking the binding sites for PCNA and DNA and examined their processivity using a series of long unmethylated and hemimethylated DNA substrates. Direct analysis of methylation patterns using bisulfite-sequencing and hairpin-PCR techniques demonstrated that full-length Dnmt1 methylates hemimethylated DNA with high processivity and a fidelity of over 95%, but unmethylated DNA with much less processivity. The truncated form of Dnmt1 showed identical properties to full-length Dnmt1 indicating that the N-terminal 290-amino acid residue region of Dnmt1 is not required for preferential activity toward hemimethylated sites or for processivity of the enzyme. Remarkably, our analyses also revealed that Dnmt1 methylates hemimethylated CpG sites on one strand of double-stranded DNA during a single processive run. Our findings suggest that these inherent enzymatic properties of Dnmt1 play an essential role in the faithful and efficient maintenance of methylation patterns in the mammalian genome.     

The activity of the murine DNA methyltransferase Dnmt1 is controlled by interaction of the catalytic domain with the N-terminal part of the enzyme leading to an allosteric activation of the enzyme after binding to methylated DNA

The mammalian DNA methyltransferase Dnmt1 is responsible for the maintenance of the pattern of DNA methylation in vivo. It is a large multidomain enzyme comprising 1620 amino acid residues. We have purified and characterized individual domains of Dnmt1 (NLS-containing domain, NlsD, amino acid residues: 1-343; replication foci-directing domain, 350-609; Zn-binding domain (ZnD), 613-748; polybromo domain, 746-1110; and the catalytic domain (CatD), 1124-1620). CatD, ZnD and NlsD bind to DNA, demonstrating the existence of three independent DNA-binding sites in Dnmt1. CatD shows a preference for binding to hemimethylated CpG-sites; ZnD prefers methylated CpGs; and NlsD specifically binds to CpG-sites, but does not discriminate between unmethylated and methylated DNA. These results are not compatible with the suggestion that the target recognition domain of Dnmt1 resides in the N terminus of the enzyme. We show by protein-protein interaction assays that ZnD and CatD interact with each other. The isolated catalytic domain does not methylate DNA, neither alone nor in combination with other domains. Full-length Dnmt1 was purified from baculovirus-infected insect cells. Under the experimental conditions, Dnmt1 has a strong (50-fold) preference for hemimethylated DNA. Dnmt1 is stimulated to methylate unmodified CpG sites by the addition of fully methylated DNA. This effect is dependent on Zn, suggesting that binding of methylated DNA to ZnD triggers the allosteric activation of the catalytic center of Dnmt1. The allosteric activation model can explain kinetic data obtained by others. It suggests that Dnmt1 might be responsible for spreading of methylation, a process that is observed during aging and carcenogenesis but may be important for de novo methylation of DNA.     

Enzymatic properties of recombinant Dnmt3a DNA methyltransferase from mouse: the enzyme modifies DNA in a non-processive manner and also methylates non-CpG [correction of non-CpA] sites

We present the first in vitro study investigating the catalytic properties of a mammalian de novo DNA methyltransferase. Dnmt3a from mouse was cloned and expressed in Escherichia coli. It was shown to be catalytically active in E. coli cells in vivo. The methylation activity of the purified protein was highest at pH 7.0 and 30 mM KCl. Our data show that recombinant Dnmt3a protein is indeed a de novo methyltransferase, as it catalyzes the transfer of methyl groups to unmethylated substrates with similar efficiency as to hemimethylated substrates. With oligonucleotide substrates, the catalytic activity of Dnmt3a is similar to that of Dnmt1: the K(m) values for the unmethylated and hemimethylated oligonucleotide substrates are 2.5 microM, and the k(cat) values are 0.05 h(-1) and 0.07 h(-1), respectively. The enzyme catalyzes the methylation of DNA in a distributive manner, suggesting that Dnmt3a and Dnmt1 may cooperate during de novo methylation of DNA. Further, we investigated the methylation activity of Dnmt3a at non-canonical sites. Even though the enzyme shows maximum activity at CpG sites, with oligonucleotide substrates, a high methylation activity was also found at CpA sites, which are modified only twofold slower than CpG sites. Therefore, the specificity of Dnmt3a is completely different from that of the maintenance methyltransferase Dnmt1, which shows a 40 to 50-fold preference for hemimethylated over unmethylated CpG sites and has almost no methylation activity at non-CpG sites.     

Mouse Oocyte Methylomes at Base Resolution Reveal Genome-Wide Accumulation of Non-CpG Methylation and Role of DNA Methyltransferases

DNA methylation is an epigenetic modification that plays a crucial role in normal mammalian development, retrotransposon silencing, and cellular reprogramming. Although methylation mainly occurs on the cytosine in a CG site, non-CG methylation is prevalent in pluripotent stem cells, brain, and oocytes. We previously identified non-CG methylation in several CG-rich regions in mouse germinal vesicle oocytes (GVOs), but the overall distribution of non-CG methylation and the enzymes responsible for this modification are unknown. Using amplification-free whole-genome bisulfite sequencing, which can be used with minute amounts of DNA, we constructed the base-resolution methylome maps of GVOs, non-growing oocytes (NGOs), and mutant GVOs lacking the DNA methyltransferase Dnmt1, Dnmt3a, Dnmt3b, or Dnmt3L. We found that nearly two-thirds of all methylcytosines occur in a non-CG context in GVOs. The distribution of non-CG methylation closely resembled that of CG methylation throughout the genome and showed clear enrichment in gene bodies. Compared to NGOs, GVOs were over four times more methylated at non-CG sites, indicating that non-CG methylation accumulates during oocyte growth. Lack of Dnmt3a or Dnmt3L resulted in a global reduction in both CG and non-CG methylation, showing that non-CG methylation depends on the Dnmt3a-Dnmt3L complex. Dnmt3b was dispensable. Of note, lack of Dnmt1 resulted in a slight decrease in CG methylation, suggesting that this maintenance enzyme plays a role in non-dividing oocytes. Dnmt1 may act on CG sites that remain hemimethylated in the de novo methylation process. Our results provide a basis for understanding the mechanisms and significance of non-CG methylation in mammalian oocytes.     

Studies on the biological role of DNA methylation: V. The pattern of E.coli DNA methylation.

The distribution of the methylatable sites GATC and CCATGG was studied by analyzing the molecular average size of restriction fragments of E. coli DNA. Both sites were found to be randomly distributed, reflecting a random pattern of methylation. The methylation pattern of specific sequences such as the origin of replication and rRNA genes has been studied in wild type E. coli and a methylation deficient (dam- dcm-) mutant. These sequences were found to be methylated in wild type cells and unmethylated in the mutant indicating that there is no effect of the state of methylation of these sequences on their expression. Analysis of the state of methylation of GATC sites in newly replicating DNA using the restriction enzyme Dpn I (cleaves only when both strands are methylated) revealed no detectable hemimethylated DNA suggesting that methylation occurs at the replication fork. Taking together the results presented here and previously published data (5), we arrive at the conclusion that the most likely function of E. coli DNA methylations is probably in preventing nuclease activity.     

De novo and maintenance DNA methylation by a mouse plasmacytoma cell DNA methyltransferase

A DNA methyltransferase of Mr = 140,000 that is active on both unmethylated and hemimethylated DNA substrates has been purified from the murine plasma-cytoma cell line MPC 11. The maximal rate of methylation was obtained with maintenance methylation of hemimethylated Micrococcus luteus or M13 DNAs. At low enzyme concentrations, the highest rate of de novo methylation occurred with single-stranded DNA or relatively short duplex DNA containing single-stranded regions. Strong substrate inhibition was observed with hemimethylated but not unmethylated DNA substrates. Fully methylated single-stranded M13 phage DNA inhibited neither the de novo nor the maintenance reactions, but unmethylated single-stranded M13 DNA strongly inhibited the maintenance reaction. The kinetics observed with hemimethylated and single-stranded substrates could be explained if the enzyme were to bind irreversibly to a DNA molecule and to aggregate if present in molar excess. Such aggregates would be required for activity upon hemimethylated but not single-stranded DNA. For de novo methylation of duplex DNA, single-stranded regions or large amounts of methyltransferase appear to be required. The relative substrate preference for the enzyme is hemimethylated DNA greater than fully or partially single-stranded DNA greater than fully duplex DNA.     

Collaboration between CpG sites is needed for stable somatic inheritance of DNA methylation states

Inheritance of 5-methyl cytosine modification of CpG (CG/CG) DNA sequences is needed to maintain early developmental decisions in vertebrates. The standard inheritance model treats CpGs as independent, with methylated CpGs maintained by efficient methylation of hemimethylated CpGs produced after DNA replication, and unmethylated CpGs maintained by an absence of de novo methylation. By stochastic simulations of CpG islands over multiple cell cycles and systematic sampling of reaction parameters, we show that the standard model is inconsistent with many experimental observations. In contrast, dynamic collaboration between CpGs can provide strong error-tolerant somatic inheritance of both hypermethylated and hypomethylated states of a cluster of CpGs, reproducing observed stable bimodal methylation patterns. Known recruitment of methylating enzymes by methylated CpGs could provide the necessary collaboration, but we predict that recruitment of demethylating enzymes by unmethylated CpGs strengthens inheritance and allows CpG islands to remain hypomethylated within a sea of hypermethylation.     

Transgene-induced CCWGG methylation does not alter CG methylation patterning in human kidney cells

Several reports suggest that C^mCWGG methylation tends not to co-exist with ^mCG methylation in human cells. We have asked whether or not methylation at CCWGG sites can influence CG methylation. DNA from cells expressing an M.EcoRII–GFP fusion was actively methylated at CCWGG sites. CG methylation as measured by R.HpaII/R.MspI ratios was unchanged in cells expressing the transgene. Cloned representatives of C^mCWGG methylated DNA often contained, or were adjacent to an ALU repeat, suggesting that M.EcoRII-GFP actively methylated gene-rich R-band DNA. The transgenic methyltransferase applied C^mCWGG methylation to a representative human promoter that was heavily methylated at CG dinucleotides (the SERPINB5 promoter) and to a representative promoter that was essentially unmethylated at CG dinucleotides (the APC promoter). In each case, the CG methylation pattern remained in its original state, unchanged by the presence of neighboring C^mCWGG sites. Q-PCR measurements showed that RNA expression from the APC gene was not significantly altered by the presence of C^mCWGG in its promoter. Kinetic studies suggested that an adjacent C^mCWGG methylation site influences neither the maintenance nor the de novo methylation activities of purified human Dnmt1. We conclude that C^mCWGG methylation does not exert a significant effect on CG methylation in human kidney cells.     

Chromosome methylation and measurement of faithful, once and only once per cell cycle chromosome replication in Caulobacter crescentus

Caulobacter crescentus exhibits cell-type-specific control of chromosome replication and DNA methylation. Asymmetric cell division yields a replicating stalked cell and a nonreplicating swarmer cell. The motile swarmer cell must differentiate into a sessile stalked cell in order to replicate and execute asymmetric cell division. This program of cell division implies that chromosome replication initiates in the stalked cell only once per cell cycle. DNA methylation is restricted to the predivisional cell stage, and since DNA synthesis produces an unmethylated nascent strand, late DNA methylation also implies that DNA near the replication origin remains hemimethylated longer than DNA located further away. In this report, both assumptions are tested with an engineered Tn5-based transposon, Tn5Omega-MP. This allows a sensitive Southern blot assay that measures fully methylated, hemimethylated, and unmethylated DNA duplexes. Tn5Omega-MP was placed at 11 sites around the chromosome and it was clearly demonstrated that Tn5Omega-MP DNA near the replication origin remained hemimethylated longer than DNA located further away. One Tn5Omega-MP placed near the replication origin revealed small but detectable amounts of unmethylated duplex DNA in replicating stalked cells. Extra DNA synthesis produces a second unmethylated nascent strand. Therefore, measurement of unmethylated DNA is a critical test of the "once and only once per cell cycle" rule of chromosome replication in C. crescentus. Fewer than 1 in 1,000 stalked cells prematurely initiate a second round of chromosome replication. The implications for very precise negative control of chromosome replication are discussed with respect to the bacterial cell cycle.     

Preferential methylation of unmethylated DNA by Mammalian de novo DNA methyltransferase Dnmt3a

DNA methylation is an epigenetic modification of DNA. There are currently three catalytically active mammalian DNA methyltransferases, DNMT1, -3a, and -3b. DNMT1 has been shown to have a preference for hemimethylated DNA and has therefore been termed the maintenance methyltransferase. Although previous studies on DNMT3a and -3b revealed that they act as functional enzymes during development, there is little biochemical evidence about how new methylation patterns are established and maintained. To study this mechanism we have cloned and expressed Dnmt3a using a baculovirus expression system. The substrate specificity of Dnmt3a and molecular mechanism of its methylation reaction were then analyzed using a novel and highly reproducible assay. We report here that Dnmt3a is a true de novo methyltransferase that prefers unmethylated DNA substrates more than 3-fold to hemimethylated DNA. Furthermore, Dnmt3a binds DNA nonspecifically, regardless of the presence of CpG dinucleotides in the DNA substrate. Kinetic analysis supports an Ordered Bi Bi mechanism for Dnmt3a, where DNA binds first, followed by S-adenosyl-l-methionine.     

Mechanism of allosteric regulation of Dnmt1's processivity

We have analyzed the relationship between the allosteric regulation and processive catalysis of DNA methyltransferase 1 (Dnmt1). Processivity is described quantitatively in terms of turnover rate, DNA dissociation rate, and processivity probability. Our results provide further evidence that the active site and the allosteric sites on Dnmt1 can bind DNA independently. Dnmt1's processive catalysis on unmethylated DNA is partially inhibited when the allosteric site binds unmethylated DNA and fully inhibited when the allosteric site binds a single-stranded oligonucleotide inhibitor. The partial inhibition by unmethylated DNA is caused by a decrease in the turnover rate and an increase in the substrate DNA dissociation rate. Processive catalysis with premethylated DNA is not affected if the allosteric site is exposed to premethylated DNA but is fully inhibited if the allosteric site binds unmethylated DNA or poly(dA-dT). In sum, the occupancy of the allosteric site modulates the enzyme's commitment to catalysis, which reflects the nature of the substrate and the DNA bound at the allosteric site. Our in vitro results are consistent with the possibility that the processive action of Dnmt1 may be regulated in vivo by specific regulatory nucleic acids such as DNA, RNA, or poly(ADP-ribose).     

Detection of vesicular stomatitis virus RNA and its defective-interfering particles in individual mouse brains.

Over 20% of the cytosine bases in frog virus 3 DNA are methylated at the 5-carbon position. To determine whether this high degree of methylation is the result of a virus-specific enzyme, we examined the kinetics of induction and the substrate specificity of a DNA methyltransferase from frog virus 3-infected fathead minnow cells. A novel DNA methyltransferase activity appeared in the cytoplasm of infected cells at 3 h postinfection. This activity was induced in the absence of viral DNA replication and was therefore probably an early viral enzyme. In contrast to the methyltransferase activity extracted from uninfected cell nuclei, the cytoplasmic enzyme showed a strong template preference for double-stranded over single-stranded and for unmethylated over hemimethylated DNA. The dinucleotide sequence dCpdG was a necessary and sufficient exogenous substrate for methylation in vitro. A mutant of frog virus 3, isolated as resistant to 5-azacytidine and having unmethylated virion DNA, did not induce cytoplasmic DNA methyltransferase, leading to the conclusion that this activity is coded for by the virus.     

DNA methylation. Inhibition of de novo and maintenance methylation in vitro by RNA and synthetic polynucleotides

A partially purified HeLa cell DNA methylase will methylate a totally unmethylated DNA (de novo methylation) at about 3-4% the rate it will methylate a hemimethylated DNA template (maintenance methylation). Our evidence suggests that many, if not most, dCpdG sequences in a natural or synthetic DNA can be methylated by the enzyme. There is a powerful inhibitor of DNA methylase activity in crude extracts which has been identified as RNA. The inhibition of DNA methylase by RNA may indicate that this enzyme is regulated in vivo by the presence of RNA at specific chromosomal sites. The pattern of binding of RNA to DNA in the nucleosome structure and the DNA replication complex may determine specific sites of DNA methylation. An even more potent inhibition of DNA methylase activity is observed with poly(G), but not poly(C), poly(A), or poly(U). The only other synthetic polynucleotides studied which inhibit DNA methylation as well as poly(G) are the homopolymers poly(dC).poly(dG) and poly (dA).poly(dT). These results point out the unique importance of the guanine residue itself in the binding of the DNA methylase to dCpdG, the site of cytosine methylation. The surprising inhibition of the methylation reaction by poly(dA).poly(dT), which is itself not methylated by the enzyme, suggests the possible involvement of adjacent A and T residues in influencing the choice of sites of methylation by the enzyme.     

Detection of DNA Methylation by Dnmt3a Methyltransferase using Methyl-Dependent Restriction Endonucleases

DNA methylation at cytosine residues in CpG sites by DNA methyltransferases (MTases) is associated with various cell processes. Eukaryotic MTase Dnmt3a is the key enzyme that establishes the de novo methylation pattern. A new in vitro assay for DNA methylation by murine MTase Dnmt3a was developed using methyl-dependent restriction endonucleases (MD-REs), which specifically cleave methylated DNA. The Dnmt3a catalytic domain (Dnmt3a-CD) was used together with KroI and PcsI MD-REs. The assay consists in consecutive methylation and cleavage of fluorescently labeled DNA substrates, then the reaction products are visualized in polyacrylamide gel to determine the DNA methylation efficiency. Each MD-RE was tested with various substrates, including partly methylated ones. PcsI was identified as an optimal MDRE. PcsI recognizes two methylated CpG sites located 7 bp apart, the distance roughly corresponding to the distance between the active centers of the Dnmt3a-CD tetramer. An optimal substrate was designed to contain two methylated cytosine residues and two target cytosines in the orientation suitable for methylation by Dnmt3a-CD. The assay is reliable, simple, and inexpensive and, unlike conventional methods, does not require radioactive compounds. The assay may be used to assess the effectiveness of Dnmt3a inhibitors as potential therapeutic agents and to investigate the features of the Dnmt3a-CD function.     

Cooperative DNA Binding and Protein/DNA Fiber Formation Increases the Activity of the Dnmt3a DNA Methyltransferase

The Dnmt3a DNA methyltransferase has been shown to bind cooperatively to DNA and to form large multimeric protein/DNA fibers. However, it has also been reported to methylate DNA in a processive manner, a property that is incompatible with protein/DNA fiber formation. We show here that the DNA methylation rate of Dnmt3a increases more than linearly with increasing enzyme concentration on a long DNA substrate, but not on a short 30-mer oligonucleotide substrate. We also show that addition of a catalytically inactive Dnmt3a mutant, which carries an amino acid exchange in the catalytic center, increases the DNA methylation rate by wild type Dnmt3a on the long substrate but not on the short one. In agreement with this finding, preincubation experiments indicate that stable protein/DNA fibers are formed on the long, but not on the short substrate. In addition, methylation experiments with substrates containing one or two CpG sites did not provide evidence for a processive mechanism over a wide range of enzyme concentrations. These data clearly indicate that Dnmt3a binds to DNA in a cooperative reaction and that the formation of stable protein/DNA fibers increases the DNA methylation rate. Fiber formation occurs at low μm concentrations of Dnmt3a, which are in the range of Dnmt3a concentrations in the nucleus of embryonic stem cells. Understanding the mechanism of Dnmt3a is of vital importance because Dnmt3a is a hotspot of somatic cancer mutations one of which has been implicated in changing Dnmt3a processivity.     

In vitro methylation of the 5'-flanking regions of the mouse beta-globin gene

The enzymatic methylation of the 5'-flanking region of the mouse beta-globin (major) gene containing putative regulatory regions has been investigated. In vitro methylation of this 368-base pair regulatory DNA by a DNA methyltransferase obtained from mouse erythroleukemia cells yields an asymmetric methylation pattern. Of the 10 available CG pairs, only 5-6 are modified, leading to one hemimethylated site and two apparently fully methylated sites. Only CG pairs which are localized in a 29-base pair cluster are methylated. The data suggest that a CG cluster approximately 100 base pairs upstream from the CAP site may be the in vivo site of methylation in the 5'-regulator region of the mouse beta-globin gene.     

Murine De Novo Methyltransferase Dnmt3a Demonstrates Strand Asymmetry and Site Preference in the Methylation of DNA In Vitro

CpG methylation is involved in a wide range of biological processes in vertebrates as well as in plants and fungi. To date, three enzymes, Dnmt1, Dnmt3a, and Dnmt3b, are known to have DNA methyltransferase activity in mouse and human. It has been proposed that de novo methylation observed in early embryos is predominantly carried out by the Dnmt3a and Dnmt3b methyltransferases, while Dntm1 is believed to be responsible for maintaining the established methylation patterns upon replication. Analysis of the sites methylated in vivo using the bisulfite genomic sequencing method confirms the previous finding that some regions of the plasmid are much more methylated by Dnmt3a than other regions on the same plasmid. However, the preferred targets of the enzyme cannot be determined due to the presence of other methylases, DNA binding proteins, and chromatin structure. To discern the DNA targets of Dnmt3a without these compounding factors, sites methylated by Dnmt3a in vitro were analyzed. These analyses revealed that the two cDNA strands have distinctly different methylation patterns. Dnmt3a prefers CpG sites on a strand in which it is flanked by pyrimidines over CpG sites flanked by purines in vitro. These findings indicate that, unlike Dnmt1, Dnmt3a most likely methylates one strand of DNA without concurrent methylation of the CpG site on the complementary strand. These findings also indicate that Dnmt3a may methylate some CpG sites more frequently than others, depending on the sequence context. Methylation of each DNA strand independently and with possible sequence preference is a novel feature among the known DNA methyltransferases.     

On the Enzymatic Properties of Dnmt1: Specificity,Processivity, Mechanism of Linear Diffusion and Allosteric Regulation of the Enzyme

In this short review the enzymatic properties of Dnmt1 are summarized. Studies on the specificity of Dnmt1 have shown that the enzymes has 30-40 fold preference for hemimethylated target sites. It methylates hemimethylated DNA in a processive reaction, moving on the DNA in a random walk. Binding of DNA to allosteric site(s) in the N-terminal part of the enzyme can lead to stimulation and inhibition of its catalytic activity depending on the nature of the substrate and effector.