Suppressed catalytic activity of base excision repair enzymes on rotationally positioned uracil in nucleosomes

ATP-dependent chromatin remodeling is required for base excision repair in conventional but not in variant H2A.Bbd nucleosomes

In eukaryotes, base excision repair (BER) is responsible for the repair of oxidatively generated lesions. The mechanism of BER on naked DNA substrates has been studied in detail, but how it operates on chromatin remains unclear. Here we have studied the mechanism of BER by introducing a single 8-oxo-7,8-dihydroguanine (8-oxoG) lesion in the DNA of reconstituted positioned conventional and histone variant H2A.Bbd nucleosomes. We found that 8-oxoguanine DNA glycosylase, apurinic/apyrimidinic endonuclease, and polymerase beta activities were strongly reduced in both types of nucleosomes. In conventional nucleosomes SWI/SNF stimulated the processing of 8-oxoG by each one of the three BER repair factors to efficiencies similar to those for naked DNA. Interestingly, SWI/SNF-induced remodeling, but not mobilization of conventional nucleosomes, was required to achieve this effect. A very weak effect of SWI/SNF on the 8-oxoG BER removal in H2A.Bbd histone variant nucleosomes was observed. The possible implications of our data for the understanding of in vivo mechanisms of BER are discussed.

Different structural states in oligonucleosomes are required for early versus late steps of base excision repair

Chromatin in eukaryotic cells is folded into higher order structures of folded nucleosome filaments, and DNA damage occurs at all levels of this structural hierarchy. However, little is known about the impact of higher order folding on DNA repair enzymes. We examined the catalytic activities of purified human base excision repair (BER) enzymes on uracil-containing oligonucleosome arrays, which are folded primarily into 30 nm structures when incubated in repair reaction buffers. The catalytic activities of uracil DNA glycosylase (UDG) and apyrimidinic/apurinic endonuclease (APE) digest G:U mismatches to completion in the folded oligonucleosomes without requiring significant disruption. In contrast, DNA polymerase β (Pol β) synthesis is inhibited in a major fraction (∼80%) of the oligonucleosome array, suggesting that single strand nicks in linker DNA are far more accessible to Pol β in highly folded oligonucleosomes. Importantly, this barrier in folded oligonucleosomes is removed by purified chromatin remodeling complexes. Both ISW1 and ISW2 from yeast significantly enhance Pol β accessibility to the refractory nicked sites in oligonucleosomes. These results indicate that the initial steps of BER (UDG and APE) act efficiently on highly folded oligonucleosome arrays, and chromatin remodeling may be required for the latter steps of BER in intact chromatin.

Chromatin disassembly and reassembly during DNA repair

Current research is demonstrating that the packaging of the eukaryotic genome together with histone proteins into chromatin is playing a fundamental role in DNA repair and the maintenance of genomic integrity. As is well established to be the case for transcription, the chromatin structure dynamically changes during DNA repair. Recent studies indicate that the complete removal of histones from DNA and their subsequent reassembly onto DNA accompanies DNA repair. This review will present evidence indicating that chromatin disassembly and reassembly occur during DNA repair and that these are critical processes for cell survival after DNA repair. Concomitantly, candidate proteins utilized for these processes will be highlighted.

Oxidative DNA damage repair in mammalian cells: a new perspective

Oxidatively induced DNA lesions have been implicated in the etiology of many diseases (including cancer) and in aging. Repair of oxidatively damaged bases in all organisms occurs primarily via the DNA base excision repair (BER) pathway, initiated with their excision by DNA glycosylases. Only two mammalian DNA glycosylases, OGG1 and NTH1 of E. coli Nth family, were previously characterized, which excise majority of the oxidatively damaged base lesions. We recently discovered and characterized two human orthologs of E. coli Nei, the prototype of the second family of oxidized base-specific glycosylases and named them NEIL (Nei-like)-1 and 2. NEILs are distinct from NTH1 and OGG1 in structural features and reaction mechanism but act on many of the same substrates. Nth-type DNA glycosylases after base excision, cleave the DNA strand at the resulting AP-site to produce a 3'-alphabeta unsaturated aldehyde whereas Nei-type enzymes produce 3'-phosphate terminus. E. coli APEs efficiently remove both types of termini in addition to cleaving AP sites to generate 3'-OH, the primer terminus for subsequent DNA repair synthesis. In contrast, the mammalian APE, APE1, which has an essential role in NTH1/OGG1-initiated BER, has negligible 3'-phosphatase activity and is dispensable for NEIL-initiated BER. Polynucleotide kinase (PNK), present in mammalian cells but not in E. coli, removes the 3' phosphate, and is involved in NEIL-initiated BER. NEILs show a unique preference for excising lesions from a DNA bubble, while most DNA glycosylases, including OGG1 and NTH1, are active only with duplex DNA. The dichotomy in the preference of NEILs and NTH1/OGG1 for bubble versus duplex DNA substrates suggests that NEILs function preferentially in repair of base lesions during replication and/or transcription and hence play a unique role in maintaining the functional integrity of mammalian genomes.

Nucleotide excision repair in chromatin and the right of entry

DNA is packaged with histones and other accessory proteins into chromatin in eukaryotic cells. It is well established that the assembly of DNA into chromatin affects induction of DNA damage as well as repair of the damage. How the DNA repair machinery detects a lesion and 'fixes it' in chromatin has been an intriguing question since the dawn of understanding DNA packaging in chromatin. Direct recognition/binding by damaged DNA binding proteins is one obvious tactic to detect a lesion. Rearrangement of chromatin structure during DNA repair was reported more than two decades ago. This early observation suggests that unfolding of chromatin structure may be required to facilitate DNA repair after lesions are detected. Cells can also exploit DNA processing events to assist DNA repair. Transcription coupled repair (TCR) is such an example. During TCR, an RNA polymerase blocked by a lesion, may act as a signal to recruit DNA repair machinery. Possible roles of histone modification enzymes, ATP-dependent chromatin remodeling complexes and chromatin assembly factors in DNA repair are discussed.

Five repair pathways in one context: chromatin modification during DNA repair

The eukaryotic cell is faced with more than 10 000 various kinds of DNA lesions per day. Failure to repair such lesions can lead to mutations, genomic instability, or cell death. Therefore, cells have developed 5 major repair pathways in which different kinds of DNA damage can be detected and repaired: homologous recombination, nonhomologous end joining, nucleotide excision repair, base excision repair, and mismatch repair. However, the efficient repair of DNA damage is complicated by the fact that the genomic DNA is packaged through histone and nonhistone proteins into chromatin, a highly condensed structure that hinders DNA accessibility and its subsequent repair. Therefore, the cellular repair machinery has to circumvent this natural barrier to gain access to the damaged site in a timely manner. Repair of DNA lesions in the context of chromatin occurs with the assistance of ATP-dependent chromatin-remodeling enzymes and histone-modifying enzymes, which allow access of the necessary repair factors to the lesion. Here we review recent studies that elucidate the interplay between chromatin modifiers / remodelers and the major DNA repair pathways.

Attenuation of DNA charge transport by compaction into a nucleosome core particle

The nucleosome core particle (NCP) is the fundamental building block of chromatin which compacts approximately 146 bp of DNA around a core histone protein octamer. The effects of NCP packaging on long-range DNA charge transport reactions have not been adequately assessed to date. Here we study DNA hole transport reactions in a 157 bp DNA duplex (AQ-157TG) incorporating multiple repeats of the DNA TG-motif, a strong NCP positioning sequence and a covalently attached Anthraquinone photooxidant. Following a thorough biophysical characterization of the structure of AQ-157TG NCPs by Exonuclease III and hydroxyl radical footprinting, we compared the dynamics of DNA charge transport in ultraviolet-irradiated free and NCP-incorporated AQ-157TG. Compaction into a NCP changes the charge transport dynamics in AQ-157TG drastically. Not only is the overall yield of oxidative lesions decreased in the NCPs, but the preferred sites of oxidative damage change as well. This NCP-dependent attenuation of DNA charge transport is attributed to DNA-protein interactions involving the folded histone core since removal of the histone tails did not perturb the charge transport dynamics in AQ-157TG NCPs.

Genomic instability and aging-like phenotype in the absence of mammalian SIRT6

The Sir2 histone deacetylase functions as a chromatin silencer to regulate recombination, genomic stability, and aging in budding yeast. Seven mammalian Sir2 homologs have been identified (SIRT1-SIRT7), and it has been speculated that some may have similar functions to Sir2. Here, we demonstrate that SIRT6 is a nuclear, chromatin-associated protein that promotes resistance to DNA damage and suppresses genomic instability in mouse cells, in association with a role in base excision repair (BER). SIRT6-deficient mice are small and at 2-3 weeks of age develop abnormalities that include profound lymphopenia, loss of subcutaneous fat, lordokyphosis, and severe metabolic defects, eventually dying at about 4 weeks. We conclude that one function of SIRT6 is to promote normal DNA repair, and that SIRT6 loss leads to abnormalities in mice that overlap with aging-associated degenerative processes.

Base excision repair in nucleosome substrates

Eukaryotic cells must repair DNA lesions within the context of chromatin. Much of our current understanding regarding the activity of enzymes involved in DNA repair processes comes from in-vitro studies utilizing naked DNA as a substrate. Here we review current literature investigating how enzymes involved in base excision repair (BER) contend with nucleosome substrates, and discuss the possibility that some of the activities involved in BER are compatible with the organization of DNA within nucleosomes. In addition, we examine evidence for the role of accessory factors, such as histone modification enzymes, and the role of the histone tail domains in moderating the activities of BER factors on nucleosomal substrates.

Nucleotide sequence and DNA secondary structure, as well as replication protein A, modulate the single-stranded abasic endonuclease activity of APE1

A major role of the multifunctional human Ape1 protein is to incise at apurinic/apyrimidinic (AP) sites in DNA via site-specific endonuclease activity. This nuclease function has been well characterized on double-stranded (ds) DNA substrates, where the complementary strand provides a template for subsequent base excision repair events. Recently, Ape1 was found to incise efficiently at AP sites positioned within the single-stranded (ss) regions of various biologically relevant DNA configurations. The studies within indicated that the ss endonuclease activity of Ape1 is poorly active on ss AP site-containing polyadenine or polythymine oligonucleotides, suggesting a requirement for some form of DNA secondary structure for efficient cleavage. Computational, footprinting, and biochemical analyses indicated that the nature of the secondary structure and the proximity of the AP site influence Ape1 incision efficiency significantly. Replication protein A (RPA), the major ssDNA-binding protein in mammalian cells, was found to bind ss AP-DNA with similar affinity as unmodified ssDNA and ds AP-DNA with lower affinity. Consistent with their known relative DNA binding affinities, RPA blocks/inhibits the ss, but not ds, AP endonuclease function of Ape1. Moreover, RPA inactivates Ape1 incision activity at an AP site within the ss region of a fork duplex, but not a transcription-like bubble intermediate. The data herein suggested a model whereby RPA selectively suppresses the nontemplated ss cleavage activity of Ape1 in vivo, particularly at sites of ongoing replication/recombination, by coating the ssDNA.

DNA repair in a protein-DNA complex: searching for the key to get in

An obstacle encountered by nucleotide excision repair (NER) proteins during repair of the genome is the masking of bulky lesions by DNA binding proteins. For example, certain transcription factors are known to be impediments, and suppress damage removal at their recognition sequences. We have used well-defined protein-DNA complexes to study the molecular mechanism(s) used by repair proteins in gaining access to DNA lesions in chromatin. Using transcription factor IIIA (TFIIIA) and the 5S ribosomal RNA gene (5S rDNA), we previously measured position-dependent effects of cyclobutane pyrimidine dimers (CPDs) at five different sites within the internal control region (ICR) on complex formation [Y. Kwon, M.J. Smerdon, Binding of zinc finger protein transcription factor IIIA to its cognate DNA sequence with single UV photoproducts at specific sites and its effect on DNA repair, J. Biol. Chem. 278 (2003) 45451-45459]. We found that CPDs at two of these sites enhance the TFIIIA-rDNA dissociation rate, which correlates with enhanced repair at these two sites. Here, we used a novel approach to directly compare dissociation of randomly damaged rDNA with NER. We refined the relationship between dissociation and repair of the complex by examining all CPD sites in the transcribed strand. A 214 bp 5S rDNA fragment was irradiated with UV light to produce CPDs at dipyrimidine sites and approximately 1 CPD per fragment. Positions of CPDs that alter binding of TFIIIA were determined by T4 endonuclease V mapping of TFIIIA-bound and unbound fractions of UV-irradiated DNA. As expected, the results reveal that dissociation of TFIIIA from the complex is significantly enhanced by CPDs within the ICR. Moreover, the levels of dissociation induced by CPDs were quantitatively compared with their repair efficiency, and indicate that repair rates of most CPDs in the complex closely correlate with the dissociation rates. In addition, changes in dissociation rate are similar to changes in CPD frequency induced by TFIIIA binding. These findings indicate that structural compatibility of a DNA lesion within a protein-DNA complex can determine both lesion frequency and repair efficiency.

Accommodation and repair of a UV photoproduct in DNA at different rotational settings on the nucleosome surface

Cyclobutane-thymine dimers (CTDs), the most common DNA lesion induced by UV radiation, cause 30 degrees bending and 9 degrees unwinding of the DNA helix. We prepared site-specific CTDs within a short sequence bracketed by strong nucleosome-positioning sequences. The rotational setting of CTDs over one turn of the helix near the dyad center on the histone surface was analyzed by hydroxyl radical footprinting. Surprisingly, the position of CTDs over one turn of the helix does not affect the rotational setting of DNA on the nucleosome surface. Gel-shift analysis indicates that one CTD destabilizes histone-DNA interactions by 0.6 or 1.1 kJ/mol when facing away or toward the histone surface, respectively. Thus, 0.5 kJ/mol energy penalty for a buried CTD is not enough to change the rotational setting of sequences with strong rotational preference. The effect of rotational setting on CTD removal by nucleotide excision repair (NER) was examined using Xenopus oocyte nuclear extracts. The NER rates are only 2-3 times lower in nucleosomes and change by only 1.5-fold when CTDs face away or toward the histone surface. Therefore, in Xenopus nuclear extracts, the rotational orientation of CTDs on nucleosomes has surprisingly little effect on rates of repair. These results indicate that nucleosome dynamics and/or chromatin remodeling may facilitate NER in gaining access to DNA damage in nucleosomes.

Nucleosomal structure of undamaged DNA regions suppresses the non-specific DNA binding of the XPC complex

The XPC protein complex is a DNA damage detector of human nucleotide excision repair (NER). Although the XPC complex specifically binds to certain damaged sites, it also binds to undamaged DNA in a non-specific manner. The addition of a large excess of undamaged naked DNA competitively inhibited the specific binding of the XPC complex to (6-4) photoproducts and the NER dual incision step in cell-free extracts. In contrast, the addition of undamaged nucleosomal DNA as a competitor suppressed both of these inhibitory effects. Although nucleosomes positioned on the damaged site inhibited the binding of the XPC complex, the presence of nucleosomes in undamaged DNA regions may help specific binding of the XPC complex to damaged sites by excluding its non-specific binding to undamaged DNA regions.

Role of high mobility group (HMG) chromatin proteins in DNA repair

While the structure and composition of chromatin not only influences the type and extent of DNA damage incurred by eukaryotic cells, it also poses a major obstacle to the efficient repair of genomic lesions. Understanding how DNA repair processes occur in the context of nuclear chromatin is a current experimental challenge, especially in mammalian cells where the powerful tools of genetic analysis that have been so successful in elucidating repair mechanisms in yeast have seen only limited application. Even so, work over the last decade with both yeast and mammalian cells has provided a rather detailed description of how nucleosomes, the basic subunit of chromatin, influence both DNA damage and repair in all eukaryotic cells. The picture that has emerged is, nonetheless, incomplete since mammalian chromatin is far more complex than simply consisting of vast arrays of histone-containing nucleosome core particles. Members of the "High Mobility Group" (HMG) of non-histone proteins are essential, and highly dynamic, constituents of mammalian chromosomes that participate in all aspects of chromatin structure and function, including DNA repair processes. Yet comparatively little is known about how HMG proteins participate in the molecular events of DNA repair in vivo. What information is available, however, indicates that all three major families of mammalian HMG proteins (i.e., HMGA, HMGB and HMGN) participate in various DNA repair processes, albeit in different ways. For example, HMGN proteins have been shown to stimulate nucleotide excision repair (NER) of ultraviolet light (UV)-induced cyclobutane pyrimidine dimer (CPD) lesions of DNA in vivo. In contrast, HMGA proteins have been demonstrated to preferentially bind to, and inhibit NER of, UV-induced CPDs in stretches of AT-rich DNA both in vitro and in vivo. HMGB proteins, on the other hand, have been shown to both selectively bind to, and inhibit NER of, cisplatin-induced DNA intrastrand cross-links and to bind to misincorporated nucleoside analogs and, depending on the biological circumstances, either promote lesion repair or induce cellular apoptosis. Importantly, from a medical perspective, the ability of the HMGA and HMGB proteins to inhibit DNA repair in vivo suggests that they may be intimately involved with the accumulation of genetic mutations and chromosome instabilities frequently observed in cancers. Not surprisingly, therefore, the HMG proteins are being actively investigated as potential new therapeutic drug targets for the treatment of cancers and other diseases.

Viral RNA is required for the association of APOBEC3G with human immunodeficiency virus type 1 nucleoprotein complexes

APOBEC3G (APO3G) is a host cytidine deaminase that is incorporated into human immunodeficiency virus type 1 (HIV-1) particles. We report here that viral RNA promotes stable association of APO3G with HIV-1 nucleoprotein complexes (NPC). A target sequence located within the 5'-untranslated region of the HIV-1 RNA was identified to be necessary and sufficient for efficient APO3G packaging. Fine mapping revealed a sequence normally involved in viral genomic RNA dimerization and Gag binding to be important for APO3G packaging and association with viral NPC. Our data suggest that packaging of APO3G into HIV-1 NPC is enhanced by viral RNA.

Base excision repair in nucleosomes lacking histone tails

Recently, we developed an in vitro system using human uracil DNA glycosylase (UDG), AP endonuclease (APE), DNA polymerase beta (pol beta) and rotationally positioned DNA containing a single uracil associated with a 'designed' nucleosome, to test short-patch base excision repair (BER) in chromatin. We found that UDG and APE carry out their catalytic activities with reduced efficiency on nucleosome substrates, showing a distinction between uracil facing 'out' or 'in' from the histone surface, while DNA polymerase beta (pol beta) is completely inhibited by nucleosome formation. In this report, we tested the inhibition of BER enzymes by the N-terminal 'tails' of core histones that take part in both inter- and intra-nucleosome interactions, and contain sites of post-translational modifications. Histone tails were removed by limited trypsin digestion of 'donor' nucleosome core particles and histone octamers were exchanged onto a nucleosome-positioning DNA sequence containing a single G:U mismatch. The data indicate that UDG and APE activities are not significantly enhanced with tailless nucleosomes, and the distinction between rotational settings of uracil on the histone surface is unaffected. More importantly, the inhibition of pol beta activity is not relieved by removal of the histone tails, even though these tails interact with DNA in the G:U mismatch region. Finally, inclusion of X-ray cross complement group protein 1 (XRCC1) or Werner syndrome protein (WRN) had no effect on the BER reactions. Thus, additional activities may be required in cells for efficient BER of at least some structural domains in chromatin.

Phosphorylation of linker histones by DNA-dependent protein kinase is required for DNA ligase IV-dependent ligation in the presence of histone H1

DNA nonhomologous end-joining in vivo requires the DNA-dependent protein kinase (DNA-PK) and DNA ligase IV/XRCC4 (LX) complexes. Here, we have examined the impact of histone octamers and linker histone H1 on DNA end-joining in vitro. Packing of the DNA substrate into dinucleosomes does not significantly inhibit ligation by LX. However, LX ligation activity is substantially reduced by the incorporation of linker histones. This inhibition is independent of the presence of core histone octamers and cannot be restored by addition of Ku alone but can be partially rescued by DNA-PK. The kinase activity of DNA-PK is essential for the recovery of end-joining. DNA-PK efficiently phosphorylates histone H1. Phosphorylated histone H1 has a reduced affinity for DNA and a decreased capacity to inhibit end-joining. Our findings raise the possibility that DNA-PK may act as a linker histone kinase by phosphorylating linker histones in the vicinity of a DNA break and coupling localized histone H1 release from DNA ends, with the recruitment of LX to carry out double-stranded ligation. Thus, by using histone H1-bound DNA as a template, we have reconstituted the end-joining step of DNA nonhomologous end-joining in vitro with a requirement for DNA-PK.

Repair and Genetic Consequences of Endogenous DNA Base Damage in Mammalian Cells

Living organisms dependent on water and oxygen for their existence face the major challenge of faithfully maintaining their genetic material under a constant attack from spontaneous hydrolysis and active oxygen species and from other intracellular metabolites that can modify DNA bases. Repair of endogenous DNA base damage by the ubiquitous base-excision repair pathway largely accounts for the significant turnover of DNA even in nonreplicating cells, and must be sufficiently accurate and efficient to preserve genome stability compatible with long-term cellular viability. The size of the mammalian genome has necessitated an increased complexity of repair and diversification of key enzymes, as revealed by gene knock-out mouse models. The genetic instability characteristic of cancer cells may be due, in part, to mutations in genes whose products normally function to ensure DNA integrity.

Production of infectious human immunodeficiency virus type 1 does not require depletion of APOBEC3G from virus-producing cells

BACKGROUND

The human immunodeficiency virus Vif protein overcomes the inhibitory activity of the APOBEC3G cytidine deaminase by prohibiting its packaging into virions. Inhibition of APOBEC3G encapsidation is paralleled by a reduction of its intracellular level presumably caused by the Vif-induced proteasome-dependent degradation of APOBEC3G.

RESULTS

In this report we employed confocal microscopy to study the effects of Vif on the expression of APOBEC3G on a single cell level. HeLa cells dually transfected with Vif and APOBEC3G expression vectors revealed efficient co-expression of the two proteins. Under optimal staining conditions approximately 80% of the transfected cells scored double-positive for Vif and APOBEC3G. However, the proportion of double-positive cells observed in identical cultures varied dependent on the fixation protocol and on the choice of antibodies used ranging from as low as 40% to as high as 80% of transfected cells. Importantly, single-positive cells expressing either Vif or APOBEC3G were observed both with wild type Vif and a biologically inactive Vif variant. Thus, the lack of APOBEC3G in some Vif-expressing cells cannot be attributed to Vif-induced degradation of APOBEC3G. These findings are consistent with our results from immunoblot analyses that revealed only moderate effects of Vif on the APOBEC3G steady state levels. Of note, viruses produced under such conditions were fully infectious demonstrating that the Vif protein used in our analyses was both functional and expressed at saturating levels.

CONCLUSIONS

Our results suggest that Vif and APOBEC3G can be efficiently co-expressed. Thus, depletion of APOBEC3G from Vif expressing cells as suggested previously is not a universal property of Vif and thus is not imperative for the production of infectious virions.

De novo protein synthesis is required for activation-induced cytidine deaminase-dependent DNA cleavage in immunoglobulin class switch recombination

Activation-induced cytidine deaminase is required for the DNA cleavage step of Ig class switch recombination (CSR). However, its molecular mechanism is controversial. RNA-editing hypothesis postulates that activation-induced cytidine deaminase deaminates cytosine in an unknown mRNA to generate a new mRNA encoding an endonuclease for CSR and thus predicts that DNA cleavage depends on de novo protein synthesis. On the other hand, DNA deamination hypothesis proposes that DNA cleavage is initiated by cytosine deamination in DNA, followed by uracil removal by uracil DNA glycosylase. By using the chromatin immunoprecipitation assay to detect gamma-H2AX focus formation as a marker for DNA cleavage, we found that cycloheximide inhibited DNA cleavage in the Ig heavy-chain locus during CSR. Requirement of protein synthesis in the DNA cleavage step of CSR strengthens the RNA-editing hypothesis.

Oxidative DNA damage background estimated by a system model of base excision repair

Human DNA can be damaged by natural metabolism through free radical production. It has been suggested that the equilibrium between innate damage and cellular DNA repair results in an oxidative DNA damage background that potentially contributes to disease and aging. Efforts to quantitatively characterize the human oxidative DNA damage background level, based on measuring 8-oxoguanine lesions as a biomarker, have led to estimates that vary over three to four orders of magnitude, depending on the method of measurement. We applied a previously developed and validated quantitative pathway model of human DNA base excision repair, integrating experimentally determined endogenous damage rates and model parameters from multiple sources. Our estimates of at most 100 8-oxoguanine lesions per cell are consistent with the low end of data from biochemical and cell biology experiments, a result robust to model limitations and parameter variation. Our findings show the power of quantitative system modeling to interpret composite experimental data and make biologically and physiologically relevant predictions for complex human DNA repair pathway mechanisms and capacity.

Maintenance DNA methylation of nucleosome core particles

The enzyme responsible for maintenance methylation of CpG dinucleotides in vertebrates is DNMT1. The presence of DNMT1 in DNA replication foci raises the issue of whether this enzyme needs to gain access to nascent DNA before its packaging into nucleosomes, which occurs very rapidly behind the replication fork. Using nucleosomes positioned along the 5 S rRNA gene, we find that DNMT1 is able to methylate a number of CpG sites even when the DNA major groove is oriented toward the histone surface. However, we also find that the ability of DNMT1 to methylate nucleosomal sites is highly dependent on the nature of the DNA substrate. Although nucleosomes containing the Air promoter are refractory to methylation irrespective of target cytosine location, nucleosomes reconstituted onto the H19 imprinting control region are more accessible. These results argue that although DNMT1 is intrinsically capable of methylating some DNA sequences even after their packaging into nucleosomes, this is not the case for at least a fraction of DNA sequences whose function is regulated by DNA methylation.