Prediction of the binding mechanism of a selective DNA methyltransferase 3A inhibitor by molecular simulation.

DNA methylation is an epigenetic mechanism that introduces a methyl group at the C5 position of cytosine. This reaction is catalyzed by DNA methyltransferases (DNMTs) and is essential for the regulation of gene transcription. The DNMT1 and DNMT3A or -3B family proteins are known targets for the inhibition of DNA hypermethylation in cancer cells. A selective non-nucleoside DNMT3A inhibitor was developed that mimics S-adenosyl-l-methionine and deoxycytidine; however, the mechanism of selectivity is unclear because the inhibitor-protein complex structure determination is absent. Therefore, we performed docking and molecular dynamics simulations to predict the structure of the complex formed by the association between DNMT3A and the selective inhibitor. Our simulations, binding free energy decomposition analysis, structural isoform comparison, and residue scanning showed that Arg688 of DNMT3A is involved in the interaction with this inhibitor, as evidenced by its significant contribution to the binding free energy. The presence of Asn1192 at the corresponding residues in DNMT1 results in a loss of affinity for the inhibitor, suggesting that the interactions mediated by Arg688 in DNMT3A are essential for selectivity. Our findings can be applied in the design of DNMT-selective inhibitors and methylation-specific drug optimization procedures.

Identification of a conserved α-helical domain at the N terminus of human DNA methyltransferase 1.

In vertebrates, DNA methyltransferase 1 (DNMT1) contributes to preserving DNA methylation patterns, ensuring the stability and heritability of epigenetic marks important for gene expression regulation and the maintenance of cellular identity. Previous structural studies have elucidated the catalytic mechanism of DNMT1 and its specific recognition of hemimethylated DNA. Here, using solution nuclear magnetic resonance spectroscopy and small-angle X-ray scattering, we demonstrate that the N-terminal region of human DNMT1, while flexible, encompasses a conserved globular domain with a novel α-helical bundle-like fold. This work expands our understanding of the structure and dynamics of DNMT1 and provides a structural framework for future functional studies in relation with this new domain.

Histone H3 Inhibits Ubiquitin-Ubiquitin Intermolecular Interactions to Enhance Binding to DNA Methyl Transferase 1.

DNA methyltransferase 1 (Dnmt1) is crucial for cell maintenance and preferentially methylates hemimethylated DNA. Recently, a study revealed that Dnmt1 is timely and site-specifically activated by several types of two-mono-ubiquitinated histone H3 tails (H3Ts). However, the molecular mechanism of Dnmt1 activation has not yet been determined, in addition to the role of H3T. Based on experimental data, two-mono-ubiquitinated H3Ts activate Dnmt1 by binding, with different binding affinities. In contrast, ubiquitin molecules unlinked with H3T do not bind to Dnmt1. Despite the existence of experimental data, it is unclear why the binding affinities for Dnmt1 are different. To obtain new insights into the activation mechanism of Dnmt1, we performed all-atom molecular dynamics (MD) simulations on three systems: (1) K14/K18, (2) K14/K23 mono-ubiquitinated H3Ts, and (3) two ubiquitin molecules unlinked with H3T. As an analysis of our MD trajectories, these ubiquitylation patterns modulated ubiquitin-ubiquitin intermolecular interactions. More specifically, the intermolecular contacts between a pair of ubiquitin molecules linked with H3T became weak in the presence of H3T, indicating that H3T makes a cleft between them to inhibit their intermolecular interactions. For these three systems, the intermolecular interactions between the ubiquitin molecules calculated by our MD simulations are in good agreement with the binding affinities for Dnmt1 experimentally measured in a previous study. Therefore, we conclude that H3T acts as a spacer to inhibit ubiquitin-ubiquitin intermolecular interactions, enhancing binding to Dnmt1.

Z-DNA as a Tool for Nuclease-Free DNA Methyltransferase Assay.

Methylcytosines in mammalian genomes are the main epigenetic molecular codes that switch off the repertoire of genes in cell-type and cell-stage dependent manners. DNA methyltransferases (DMT) are dedicated to managing the status of cytosine methylation. DNA methylation is not only critical in normal development, but it is also implicated in cancers, degeneration, and senescence. Thus, the chemicals to control DMT have been suggested as anticancer drugs by reprogramming the gene expression profile in malignant cells. Here, we report a new optical technique to characterize the activity of DMT and the effect of inhibitors, utilizing the methylation-sensitive B-Z transition of DNA without bisulfite conversion, methylation-sensing proteins, and polymerase chain reaction amplification. With the high sensitivity of single-molecule FRET, this method detects the event of DNA methylation in a single DNA molecule and circumvents the need for amplification steps, permitting direct interpretation. This method also responds to hemi-methylated DNA. Dispensing with methylation-sensitive nucleases, this method preserves the molecular integrity and methylation state of target molecules. Sparing methylation-sensing nucleases and antibodies helps to avoid errors introduced by the antibody's incomplete specificity or variable activity of nucleases. With this new method, we demonstrated the inhibitory effect of several natural bio-active compounds on DMT. All taken together, our method offers quantitative assays for DMT and DMT-related anticancer drugs.

Epigenetic modulation and apoptotic induction by a novel imidazo-benzamide derivative in human lung adenocarcinoma cells.

PURPOSE: Lung cancer is the most commonly diagnosed and leading cause of cancer death worldwide. Imidazo-benzamides are considered to be good anti-cancer agents. The present study was aimed to investigate the cytotoxicity of a novel imidazo-benzamide derivative N-(2-(3-(tert-butyl)ureido)ethyl)-4-(1H-imidazol-1-yl)benzamide (TBUEIB) in lung cancer cell line A549. METHODS: The antiproliferative activity of TBUEIB was investigated using MTT, LDH and trypan blue assay. The apoptotic potential was investigated using various staining techniques and further confirmed by DNA fragmentation assay and western blotting. RESULTS: TBUEIB inhibited fifty precent A549 cells at a dose of 106 µM. The novel compound was found to exert a modulatory effect on apoptotic marker caspase-3 as well as epigenetic regulatory proteins like DNA Methyltransferase 1 (DNMT1). In silico studies with the compound and other epigenetic proteins such as Histone deacetylase (HDAC) and ubiquitin-like with PHD (plant homeodomain) and RING (Really Interesting New Gene) finger domains 1(UHRF1) showed good modulatory effects. CONCLUSION: The overall results obtained in the study conclude that the novel compound TBUEIB has potential anti-cancer activities, mainly by targeting the expression of DNMT1 enzyme, which may have re-activated the major tumor suppressor genes involved in the cell cycle, leading to the apoptosis of the cancer cells. The results also indicate that the compound has more than one target in the epigenetic pathway implying that the compound may be a potential multi-target compound.

DNA sequence-dependent activity and base flipping mechanisms of DNMT1 regulate genome-wide DNA methylation.

DNA methylation maintenance by DNMT1 is an essential process in mammals but molecular mechanisms connecting DNA methylation patterns and enzyme activity remain elusive. Here, we systematically analyzed the specificity of DNMT1, revealing a pronounced influence of the DNA sequences flanking the target CpG site on DNMT1 activity. We determined DNMT1 structures in complex with preferred DNA substrates revealing that DNMT1 employs flanking sequence-dependent base flipping mechanisms, with large structural rearrangements of the DNA correlating with low catalytic activity. Moreover, flanking sequences influence the conformational dynamics of the active site and cofactor binding pocket. Importantly, we show that the flanking sequence preferences of DNMT1 highly correlate with genomic methylation in human and mouse cells, and 5-azacytidine triggered DNA demethylation is more pronounced at CpG sites with flanks disfavored by DNMT1. Overall, our findings uncover the intricate interplay between CpG-flanking sequence, DNMT1-mediated base flipping and the dynamic landscape of DNA methylation.

Structure-based screening of chemical libraries to identify small molecules that are likely to bind with the SET and RING-associated (SRA) domain of Ubiquitin-like, PHD and Ring Finger-containing 1 (UHRF1).

OBJECTIVES: UHRF1 is a multi-domain protein that recognizes both histone and DNA modification marks on chromatin. UHRF1 is involved in various cellular processes that lead to tumorigenesis and thus attracted considerable attention as a potential anti-cancer drug target. The SRA domain is a unique to the UHRF family. SRA domain recognizes 5-methylcytosine in hemimethylated DNA and necessary for maintenance DNA methylation mediated by DNMT1. Small molecules capable of interacting with the SRA domain may reduce aberrant methylation levels by preventing the interaction of 5-methylcytosine with the SRA domain and thereby blocking substrate access to the catalytic center of DNMT1. The data were collected to identify and predict an initial set of small molecules that are expected to bind to the SRA domain. DATA DESCRIPTION: Nearly 2.4 million molecules from various chemical libraries were screened with the SRA domain of UHRF1 using Schrodinger's Small Molecule Drug Discovery Suite. The data is available in the form of a methodology presentation, MS Excel files listing the top hits, and Maestro pose viewer files that provide visualization of how the identified ligands interact with the SRA domain.

Both Configuration and QM Region Size Matter: Zinc Stability in QM/MM Models of DNA Methyltransferase.

Quantum-mechanical/molecular-mechanical (QM/MM) methods are essential to the study of metalloproteins, but the relative importance of sampling and degree of QM treatment in achieving quantitative predictions is poorly understood. We study the relative magnitude of configurational and QM-region sensitivity of energetic and electronic properties in a representative Zn2+ metal binding site of a DNA methyltransferase. To quantify property variations, we analyze snapshots extracted from 250 ns of molecular dynamics simulation. To understand the degree of QM-region sensitivity, we perform analysis using QM regions ranging from a minimal 49-atom region consisting only of the Zn2+ metal and its four coordinating Cys residues up to a 628-atom QM region that includes residues within 12 Å of the metal center. Over the configurations sampled, we observe that illustrative properties (e.g., rigid Zn2+ removal energy) exhibit large fluctuations that are well captured with even minimal QM regions. Nevertheless, for both energetic and electronic properties, we observe a slow approach to asymptotic limits with similarly large changes in absolute values that converge only with larger (ca. 300-atom) QM region sizes. For the smaller QM regions, the electronic description of Zn2+ binding is incomplete: the metal binds too tightly and is too stabilized by the strong electrostatic potential of MM point charges, and the Zn-S bond covalency is overestimated. Overall, this work suggests that efficient sampling with QM/MM in small QM regions is an effective method to explore the influence of enzyme structure on target properties. At the same time, accurate descriptions of electronic and energetic properties require a larger QM region than the minimal metal-coordinating residues in order to converge treatment of both metal-local bonding and the overall electrostatic environment.

Molecular characterization of DNA methyltransferase 1 and its role in temperature change of armyworm Mythimna separata Walker.

DNA methylation refers to the addition of cytosine residues in a CpG context (5'-cytosine-phosphate-guanine-3'). As one of the most common mechanisms of epigenetic modification, it plays a crucial role in regulating gene expression and in a diverse range of biological processes across all multicellular organisms. The relationship between temperature and DNA methylation and how it acts on the adaptability of migratory insects remain unknown. In the present work, a 5,496 bp full-length complementary DNA encoding 1,436 amino acids (named MsDnmt1) was cloned from the devastating migratory pest oriental armyworm, Mythimna separata Walker. The protein shares 36.8-84.4% identity with other insect Dnmt1 isoforms. Spatial and temporal expression analysis revealed that MsDnmt1 was highly expressed in adult stages and head tissue. The changing temperature decreased the expression of MsDnmt1 in both high and low temperature condition. Besides, we found that M. separata exhibited the shortest duration time from the last instar to pupae under 36°C environment when injected with DNA methylation inhibitor. Therefore, our data highlight a potential role for DNA methylation in thermal resistance, which help us to understand the biological role adaptability and colonization of migratory pest in various environments.

Interactions between core histone marks and DNA methyltransferases predict DNA methylation patterns observed in human cells and tissues.

DNA methylation and histone modifications are two major epigenetic marks in mammalian cells. Previous studies have revealed that these two mechanisms interact although a quantitative model of these is still lacking in mammalian cells. Here we sought to develop such a model by systematically evaluating the quantitative relationship between DNA methylation and the core histone modification marks in human epigenomes. This model reflects the interactions of ADD and PWWP domains of DNA methyltransferase (DNMTs) with histone 3 lysine tails. Our analysis integrated 35 whole genome bisulphite sequencing data sets (about 800 million CpG sites), 35 chromatin states and 175 ChIP-Seq histone modification profiles across 35 human cell types. The logistic regression model we built shows that more than half of the variance across DNA methylomes can be explained by the five-core histone modification across varied types of human cell and tissue samples. Importantly, we find that H3K4me3 has a dramatic effect in DNA methylation patterning, highlighting the essential interaction between ADD domain of DNMTs and histone 3 lysine 4 in human. Moreover, our model suggests DNA methylation is generally inhibited by the presence of H3K4me3, H3K4me1 and H3K27me3, while increased levels are found in regions that are marked by H3K9me3 and H3K36me3. In summary, our results provide a comprehensive evaluation of the crosstalk between DNA methylation and histone modification in a variety of human cell types, and shows that DNA methylation patterns can be largely explained by interactions between histone 3 lysine tails and specific domains of DNA methyltransferases.

Disease-Associated Mutations G589A and V590F Relieve Replication Focus Targeting Sequence-Mediated Autoinhibition of DNA Methyltransferase 1.

In eukaryotes, the most common epigenetic DNA modification is methylation of carbon 5 of cytosines, predominantly in CpG dinucleotides. Methylation patterns are established and maintained by a family of proteins known as DNA methyltransferases (DNMTs). DNA methylation is an important epigenetic mark associated with gene repression, and disruption of the normal DNA methylation pattern is known to play a role in several disease states. Methylation patterns are primarily maintained by DNMT1, which possesses specificity for methylation of hemimethylated DNA. DNMT1 is a multidomain protein with a C-terminal catalytic methyltransferase domain and a large N-terminal regulatory region. The replication focus targeting sequence (RFTS) domain, found in the regulatory region, is an endogenous inhibitor of DNMT1 activity. Recently, several mutations in the RFTS domain were shown to be causal for two adult onset neurodegenerative diseases; however, little is known about the impact of these mutations on the structure and function of DNMT1. Two of these mutations, G589A and V590F, are associated with development of autosomal dominant cerebellar ataxia, deafness, and narcolepsy (ADCA-DN). We have successfully expressed and purified G589A and V590F DNMT1 for in vitro studies. The mutations significantly decrease the thermal stability of DNMT1, yet the mutant proteins exhibit 2.5-3.5-fold increases in DNA binding affinity. In addition, the mutations weaken RFTS-mediated inhibition of DNA methylation activity. Taken together, these data suggest these disease-associated mutations decrease protein stability and, at least partially, relieve normal RFTS-mediated autoinhibition of DNMT1.

In silico evaluation of pesticides as potential modulators of human DNA methyltransferases.

DNA methylations are carried out by DNA methyltransferases (DNMTs) that are key enzymes during gene expression. Many chemicals, including pesticides, have shown modulation of epigenetic functions by inhibiting DNMTs. In this work, human DNMTs were evaluated as a potential target for pesticides through virtual screening of 1038 pesticides on DNMT1 (3SWR) and DNMT3A (2QRV). Molecular docking calculations for DNMTs-pesticide complexes were performed using AutoDock Vina. Binding-affinity values and contact patterns were employed as selection criteria of pesticides as virtual hits for DNMTs. The best three DNMT-pesticides complexes selected according to their high absolute affinity values (kcal/mol), for both DNMT1 and DNMT3A, were flocoumafen (-12.5; -9.9), brodifacoum (-12.4; -8.4) and difenacoum (-12.1; -8.7). These chemicals belong to second-generation rodenticides. The most frequent predicted interacting residues for DNMT1-pesticide complexes were Trp1170A, Phe1145A, Asn1578A, Arg1574A and Pro1225A; whereas for DNMT3A those were Arg271B, Lys740A, and Glu303B. These results suggest that rodenticides used for pest control are potential DNMT ligands and therefore, may modulate DNA methylations. This finding has important environmental and clinical implications, as epigenetic pathways are critical in many biochemical processes leading to diseases.

Metformin and sitagliptin combination therapy ameliorates polycystic ovary syndrome with insulin resistance through upregulation of lncRNA H19.

Insulin resistance (IR) is prevalent in women with polycystic ovary syndrome (PCOS). Improvement in insulin sensitivity remains one of the most effective treatment strategies for women with PCOS. This study aims to investigate the efficacy and potential mechanism of the combination therapy with metformin (DMBG) and sitagliptin (TECOS) in PCOS. To address this, insulin was used to treat rat ovarian granulosa cells to establish the cellular PCOS model. Insulin and human chorionic gonadotropin (HCG) were subcutaneously injected into SD rats to establish a rat model of hyperandrogenism with pathogenesis similar to PCOS. Our results showed that co-treatment with TECOS and DMBG attenuated the induced apoptosis and insulin resistance (IR) in PCOS model cells, and improved reproductive hormone disorders, ovarian polycystic changes, and IR of PCOS rats. Mechanistically, upregulation of H19 by H19-expressing lentiviruses enhanced efficacy of combination therapy. Furthermore, co-treatment with TECOS and DMBG induced H19 expression via suppressing the PI3K/AKT-DNMT1 pathway. Collectively, these findings demonstrate that combination treatment with TECOS and DMBG ameliorates PCOS with IR, at least partially, through upregulation of lncRNA H19.

Substituted anthraquinones represent a potential scaffold for DNA methyltransferase 1-specific inhibitors.

In humans, the most common epigenetic DNA modification is methylation of the 5-carbon of cytosines, predominantly in CpG dinucleotides. DNA methylation is an important epigenetic mark associated with gene repression. Disruption of the normal DNA methylation pattern is known to play a role in the initiation and progression of many cancers. DNA methyltransferase 1 (DNMT1), the most abundant DNA methyltransferase in humans, is primarily responsible for maintenance of the DNA methylation pattern and is considered an important cancer drug target. Recently, laccaic acid A (LCA), a highly substituted anthraquinone natural product, was identified as a direct, DNA-competitive inhibitor of DNMT1. Here, we have successfully screened a small library of simplified anthraquinone compounds for DNMT1 inhibition. Using an endonuclease-coupled DNA methylation assay, we identified two anthraquinone compounds, each containing an aromatic substituent, that act as direct DNMT1 inhibitors. These simplified anthraquinone compounds retain the DNA-competitive mechanism of action of LCA and exhibit some selectivity for DNMT1 over DNMT3a. The newly identified compounds are at least 40-fold less potent than LCA, but have significantly less complex structures. Collectively, this data indicates that substituted anthraquinone compounds could serve as a novel scaffold for developing DNMT1-specific inhibitors.

A Molecular Tool Targeting the Base-Flipping Activity of Human UHRF1.

During DNA replication, ubiquitin-like, containing PHD and RING fingers domains 1 (UHRF1) plays key roles in the inheritance of methylation patterns to daughter strands by recognizing through its SET and RING-associated domain (SRA) the methylated CpGs and recruiting DNA methyltransferase 1 (DNMT1). Herein, our goal is to identify UHRF1 inhibitors targeting the 5'-methylcytosine (5mC) binding pocket of the SRA domain to prevent the recognition and flipping of 5mC and determine the molecular and cellular consequences of this inhibition. For this, we used a multidisciplinary strategy combining virtual screening and molecular modeling with biophysical assays in solution and cells. We identified an anthraquinone compound able to bind to the 5mC binding pocket and inhibit the base-flipping process in the low micromolar range. We also showed in cells that this hit impaired the UHRF1/DNMT1 interaction and decreased the overall methylation of DNA, highlighting the critical role of base flipping for DNMT1 recruitment and providing the first proof of concept of the druggability of the 5mC binding pocket. The selected anthraquinone appears thus as a key tool to investigate the role of UHRF1 in the inheritance of methylation patterns, as well as a starting point for hit-to-lead optimizations.

Insight into the selective binding mechanism of DNMT1 and DNMT3A inhibitors: a molecular simulation study.

DNA methyltransferases (DNMTs), responsible for the regulation of DNA methylation, have been regarded as promising drug targets for cancer therapy. However, high structural conservation of the catalytic domains of DNMTs poses a big challenge to design selective inhibitors for a specific DNMT isoform. In this study, molecular dynamics (MD) simulations, end-point free energy calculations and umbrella sampling (US) simulations were performed to reveal the molecular basis of the binding selectivity of three representative DNMT inhibitors towards DNMT1 and DNMT3A, including SFG (DNMT1 and DNMT3A dual inhibitors), DC-05 (DNMT1 selective inhibitor) and GSKex1 (DNMT3A selective inhibitor). The binding selectivity of the studied inhibitors reported in previous experiments is reproduced by the MD simulation and binding free energy prediction. The simulation results also suggest that the driving force to determine the binding selectivity of the studied inhibitors stems from the difference in the protein-inhibitor van der Waals interactions. Meanwhile, the per-residue free energy decomposition reveals that the contributions from several non-conserved residues in the binding pocket of DNMT1/DNMT3A, especially Val1580/Trp893, Asn1578/Arg891 and Met1169/Val665, are the key factors responsible for the binding selectivity of DNMT inhibitors. In addition, the binding preference of the studied inhibitors was further validated by the potentials of mean force predicted by the US simulations. This study will provide valuable information for the rational design of novel selective inhibitors targeting DNMT1 and DNMT3A.

Structure of PCNA in complex with DNMT1 PIP box reveals the basis for the molecular mechanism of the interaction.

DNMT1 is a C5-DNA methyltransferase that plays a pivotal role in DNA methylation maintenance. During early and mid S-phase, DNMT1 accumulates at DNA replication sites by binding to proliferating cell nuclear antigen (PCNA), an essential factor for DNA replication, through a PIP box motif. However, the molecular mechanism by which the DNMT1 PIP box motif binds to PCNA remains unclear. Here, we report the crystal structure of PCNA bound to DNMT1 PIP box peptide. The structure reveals the detailed interaction between PCNA and DNMT1 PIP box; conserved glutamine and hydrophobic/aromatic residues in the PIP box are recognized by the Q- and hydrophobic pockets of PCNA, respectively. The structure also shows novel intramolecular interactions within the PIP box motif, which stabilize the helix conformation in the PIP box. Our data provide structural insight into the recruitment of DNMT1 to replication sites by PCNA.

BAH domains and a histone-like motif in DNA methyltransferase 1 (DNMT1) regulate de novo and maintenance methylation in vivo.

DNA methyltransferase 1 (DNMT1) is a multidomain protein believed to be involved only in the passive transmission of genomic methylation patterns via maintenance methylation. The mechanisms that regulate DNMT1 activity and targeting are complex and poorly understood. We used embryonic stem (ES) cells to investigate the function of the uncharacterized bromo-adjacent homology (BAH) domains and the glycine-lysine (GK) repeats that join the regulatory and catalytic domains of DNMT1. We removed the BAH domains by means of a CRISPR/Cas9-mediated deletion within the endogenous Dnmt1 locus. The internally deleted protein failed to associate with replication foci during S phase in vivo and lost the ability to mediate maintenance methylation. The data indicate that ablation of the BAH domains causes DNMT1 to be excluded from replication foci even in the presence of the replication focus-targeting sequence (RFTS). The GK repeats resemble the N-terminal tails of histones H2A and H4 and are normally acetylated. Substitution of lysines within the GK repeats with arginines to prevent acetylation did not alter the maintenance activity of DNMT1 but unexpectedly activated de novo methylation of paternal imprinting control regions (ICRs) in mouse ES cells; maternal ICRs remained unmethylated. We propose a model under which DNMT1 deposits paternal imprints in male germ cells in an acetylation-dependent manner. These data reveal that DNMT1 responds to multiple regulatory inputs that control its localization as well as its activity and is not purely a maintenance methyltransferase but can participate in the de novo methylation of a small but essential compartment of the genome.

Maintenance DNA Methyltransferase Activity in the Presence of Oxidized Forms of 5-Methylcytosine: Structural Basis for Ten Eleven Translocation-Mediated DNA Demethylation.

A precise balance of DNA methylation and demethylation is required for epigenetic control of cell identity, development, and growth. DNA methylation marks are introduced by de novo DNA methyltransferases DNMT3a/b and are maintained throughout cell divisions by DNA methyltransferase 1 (DNMT1), which adds methyl groups to hemimethylated CpG dinucleotides generated during DNA replication. Ten eleven translocation (TET) dioxygenases oxidize 5-methylcytosine (mC) to 5-hydroxymethylcytosine (hmC), 5-formylcytosine (fC), and 5-carboxylcytosine (caC), a process known to induce DNA demethylation and gene reactivation. In this study, we investigated the catalytic activity of human DNMT1 in the presence of oxidized forms of mC. A mass spectrometry-based assay was employed to study the kinetics of DNMT1-mediated cytosine methylation in CG dinucleotides containing C, mC, hmC, fC, or caC across from the target cytosine. Homology modeling, coupled with molecular dynamics simulations, was used to explore the structural consequences of mC oxidation with regard to the geometry of protein-DNA complexes. The DNMT1 enzymatic activity was strongly affected by the oxidation status of mC, with the catalytic efficiency decreasing in the following order: mC > hmC > fC > caC. Molecular dynamics simulations revealed that DNMT1 forms an unproductive complex with DNA duplexes containing oxidized forms of mC as a consequence of altered interactions of the target recognition domain of the protein with the C-5 substituent on cytosine. Our results provide new structural and mechanistic insight into TET-mediated DNA demethylation.

Chromatin structure and its chemical modifications regulate the ubiquitin ligase substrate selectivity of UHRF1.

Mitotic inheritance of DNA methylation patterns is facilitated by UHRF1, a DNA- and histone-binding E3 ubiquitin ligase that helps recruit the maintenance DNA methyltransferase DNMT1 to replicating chromatin. The DNA methylation maintenance function of UHRF1 is dependent on its ability to bind chromatin, where it facilitates monoubiquitination of histone H3 at lysines 18 and 23, a docking site for DNMT1. Because of technical limitations, this model of UHRF1-dependent DNA methylation inheritance has been constructed largely based on genetics and biochemical observations querying methylated DNA oligonucleotides, synthetic histone peptides, and heterogeneous chromatin extracted from cells. Here, we construct semisynthetic mononucleosomes harboring defined histone and DNA modifications and perform rigorous analysis of UHRF1 binding and enzymatic activity with these reagents. We show that multivalent engagement of nucleosomal linker DNA and dimethylated lysine 9 on histone H3 directs UHRF1 ubiquitin ligase activity toward histone substrates. Notably, we reveal a molecular switch, stimulated by recognition of hemimethylated DNA, which redirects UHRF1 ubiquitin ligase activity away from histones in favor of robust autoubiquitination. Our studies support a noncompetitive model for UHRF1 and DNMT1 chromatin recruitment to replicating chromatin and define a role for hemimethylated linker DNA as a regulator of UHRF1 ubiquitin ligase substrate selectivity.