Abstract
The aryl hydrocarbon receptor (Ahr) is a highly conserved nuclear receptor that plays an important role in the manifestation of toxicity induced by polycyclic aromatic hydrocarbons. As a xenobiotic sensor, Ahr is involved in chemical biotransformation through activation of drug metabolizing enzymes. The activated Ahr cooperates with coactivator complexes to induce epigenetic modifications at target genes. Thus, it is conceivable that 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), a potent Ahr ligand, may elicit robust epigenetic changes in vivo at the Ahr target gene cytochrome P450 1a1 (Cyp1a1). A single dose of TCDD administered to adult mice induced Ahr-dependent CpG hypomethylation, changes in histone modifications, and thymine DNA glycosylase (Tdg) recruitment at the Cyp1a1 promoter in the liver within 24 hrs. These epigenetic changes persisted until 40 days post-TCDD treatment and there was Cyp1a1 mRNA hyperinduction upon repeat administration of TCDD at this time-point. Our demethylation assay using siRNA knockdown and an in vitro methylated plasmid showed that Ahr, Tdg, and the ten-eleven translocation methyldioxygenases Tet2 and Tet3 are required for the TCDD-induced DNA demethylation. These results provide novel evidence of Ahr-driven active DNA demethylation and epigenetic memory. The epigenetic alterations influence response to subsequent chemical exposure and imply an adaptive mechanism to xenobiotic stress.
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Introduction
The aryl hydrocarbon receptor (Ahr) is a highly conserved nuclear receptor that mediates toxic response to environmentally persistent organic pollutants (POPs) including polycyclic aromatic hydrocarbons (PAHs) and halogenated aromatic hydrocarbons (HAHs), such as 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD)1. As a xenobiotic sensor, Ahr plays a role in chemical biotransformation through activation of drug metabolizing enzymes2. Ahr belongs to the basic helix-loop-helix (bHLH) superfamily of proteins that are involved in environmental response3. The ligand-activated Ahr dimerizes with its partner factor, Ahr nuclear translocator (Arnt), and binds xenobiotic responsive elements (XREs) found on target gene promoters, including phase I and phase II drug metabolizing enzymes2. Cyp1a1 is the classical Ahr target gene that is induced by Ahr activation and is involved in the metabolism of PAHs to carcinogenic derivatives. Ahr also has critical roles in cardiovascular physiology4, immune regulation5, and hematopoiesis6.
DNA methylation and histone modifications are well characterized epigenetic marks that respond dynamically to diverse environmental factors7,8. As a regulator of multiple gene transcription networks, epigenetic modifications are anticipated to play a significant role in Ahr signalling. Indeed, the ligand-activated Ahr is known recruit several co-factors that have epigenetic modulatory functions, including the histone acetylase complexes (CBP/p300, p160 SRC1, NCoA-2 and p/CIP) and ATP dependent chromatin remodelers SWI/SNF9. The resultant changes in histone modifications have been described at the Cyp1a1 enhancer and promoter regions10,11. Given the stability and dynamicity of epigenetic modifications, we hypothesized that Ahr activation may induce lasting epigenetic modifications and Cyp1a1 transcription memory.
Enhanced drug metabolism is one of the major adaptive strategies during the development of pharmacokinetic xenobiotic tolerance12. Persistent epigenetic changes following initial drug metabolizing gene activation can ensure rapid and robust expression of drug metabolizing genes during subsequent drug exposures, resulting in enhanced deactivation of target chemicals13. DNA methylation can be altered in response to xenobiotic exposure14. Recent reports indicate that active DNA demethylation involves iterative oxidation of the methylated cytosine by the ten-eleven translocation proteins (Tet1, Tet2, Tet3) followed by recognition of the modified cytosine by thymine DNA glycosylase (Tdg), base excision repair (BER), and finally replacement with an unmodified cytosine15. There are a limited number of studies that describe coordinated targeting of the DNA demethylation proteins to specific genomic locations16. Nuclear receptors are likely candidates given their specificity in transcriptional regulation of target genes. Whether Ahr activation by TCDD induces DNA methylation alterations at the Cyp1a1 promoter remains unclear. Furthermore, information on the potential role of epigenetic mechanisms in Ahr signalling is still limited.
This study provides novel evidence of Ahr-driven robust epigenetic modulation. The initial events involve Ahr-directed DNA demethylation and changes in histone modifications, followed by a long-term maintenance of this epigenetic configuration and Cyp1a1 transcriptional memory. These epigenetic alterations influence response to subsequent chemical exposure and imply an adaptive mechanism to xenobiotic stress.
Materials and Methods
Reagents
Reagents used in this study were purchased from the manufacturers indicated in parentheses: 2,3,7,8-TCDD (purity >99.5%) (Cambridge Isotope Laboratory, Andover, MA, USA); DNeasy Blood & Tissue Kit, AllPrep DNA/RNA Mini Kit, RNeasy Mini Kit, QIAquick PCR Purification Kit and QIAquick Gel Extraction Kit (Qiagen, Hilden, Germany); PrimeScript RT reagent kit, TaKaRa Ex Taq and LA Taq (Takara Bio, Otsu, Japan); LightCycler 480 SYBR Green I Master (Roche Diagnostics GmbH, Mannheim, Germany); SimpleChIP Plus Enzymatic Chromatin IP Kit (Cell Signaling Technology, Danvers, MA, USA); Restriction enzymes HinP1I, HpaII, XbaI, Epimark 5 hmC and 5 mC Analysis Kit, HhaI and HpaII methyltransferases (New England Biolabs, MA, USA); MluI and XhoI (Toyobo, Osaka, Japan); Tissue-Tek O.C.T. Compound (Sakura Finetek, CA, USA); BrdU (Sigma-Aldrich, MO, USA); Hoechst 33342 (Dojindo, Japan); Hanks’ balanced salt solution (HBSS), Collagenase type IV, Lipofectamine2000, α-MEM, DMEM, fetal bovine serum (FBS), penicillin/streptomycin, and β-mercaptoethanol (Invitrogen, Carlsbad, CA, USA); pGL3-Basic Vector, phRL-TK Vector, and Dual-Luciferase Reporter Assay System (Promega, Madison, WI, USA); Site-Directed Mutagenesis Kit (Stratagene, CA, USA); HEPES, and Chemi-Lumi One reagents (Nacalai Tesque, Kyoto, Japan); porcine skin collagen (Nitta Gelatin Inc, Tokyo, Japan); siRNA oligos against mouse Ahr, Apex1, Tdg (Gm5806), and Non-targeting siRNA pool 1 (Dharmacon, PA, USA); siRNA against Tet1 (sc-154204), Tet2 (sc-154205), Tet3(sc-154206), and mouse monoclonal Ahr antibody A-2 (Santa Cruz Biotechnology, Santa Cruz, CA, USA), mouse monoclonal Anti-BrdU antibody (Becton Dickinson, CA, USA); Goat Anti-Mouse Alexa Fluor 488 (Abcam, MA, USA); Anti-Tet2 mouse monoclonal antibody and Immobilon-P PVDF membrane (Millipore, CA, USA).
Animals
Adult C57BL/6J female mice aged 10 weeks were purchased from CLEA Japan (Tokyo, Japan). Ahr knockout (Ahr−/−) mice used in this experiment have been described previously17,18. Heterozygous (Ahr+/−) males and females were bred to obtain Ahr−/− progeny. Animals were maintained on a 12/12 hour light/dark cycle, at a mean temperature of 23 ± 1 °C and 40% to 60% humidity. Laboratory rodent chow (Lab MR Stock; Nosan, Yokohama, Japan) and clean water were provided ad libitum. Animal experimentation protocols were reviewed and approved by the Animal Care and Use Committee, The University of Tokyo; and all experiments were performed in accordance with the relevant guidelines and regulations of the University of Tokyo.
Treatment
Wild type female mice aged 10 weeks were orally treated with a single dose of TCDD (3 μg/kg bw) or vehicle (corn oil). This dose was selected on the basis that it does not cause overt toxic response in directly exposed mice and is approximately 60 times lower than the LD50 (182 μg/kg bw)19. Liver, kidney and brain samples were obtained at 6 hrs, 12 hrs, 24 hrs, 7 days, 20 days and 40 days post-TCDD treatment (n = 3). The tissues were snap-frozen in liquid nitrogen before being stored at −80 °C. Similarly, age-matched Ahr−/− mice (n = 3) were given a single dose of TCDD (3 μg/kg bw) or corn oil. Liver samples were collected 24 hrs after TCDD treatment. Next, two groups of female mice (n = 3) were treated either with 3 μg/kg TCDD orally or corn oil. On day 40 after the initial dose, 100 ng/kg bw of TCDD was re-administered to both the TCDD pretreated group and the control group. Liver samples were collected 24 hrs after TCDD treatment for Cyp1a1 expression analysis.
DNA and RNA isolation
DNA was isolated from tissue and cell samples using the DNeasy Blood & Tissue Kit or AllPrep DNA/RNA Mini Kit. Total RNA was isolated using the RNeasy Mini Kit or AllPrep DNA/RNA Mini Kit. The purity and concentration of DNA and RNA were determined by spectrophotometry.
RT-qPCR
The reverse transcription-quantitative PCR (RT-qPCR) technique used in this study has been previously described20. Briefly, RNA samples were first reverse-transcribed using the PrimeScript RT Reagent Kit. Subsequently, the cDNA was amplified using the LightCycler® 480 SYBR Green I Master in a LightCycler® 480 Instrument II. The primers that were used are listed in Supplementary Table S1. All oligonucleotides purified by gel-filtration were purchased from Hokkaido System Science (Sapporo, Japan). Absolute quantification of gene expression was performed using a standard curve derived from DNA amplicons prepared by the QIAquick Gel Extraction Kit followed by calculation of mRNA copy numbers per ng RNA20. The PCR was ran in duplicate and the average was used for quantification.
Chromatin immunoprecipitation assay
The SimpleChIP® Plus Enzymatic Chromatin IP Kit was utilized to perform chromatin immunoprecipitation (ChIP), as per the manufacturer’s protocol. Fresh liver tissue (50 mg) was crosslinked with 10% formaldehyde for 30 min. The chromatin fraction was digested with micrococcal nuclease and sonicated to give the desired fragment length (150 to 600 bp). The resulting protein-DNA complexes were then immunoprecipitated using the appropriate antibodies (Supplementary Table S2), followed by de-crosslinking. Next, qPCR was performed on the ChIP DNA (ChIP-qPCR) using the primer sets described in Supplementary Table S3. Relative amplicon levels were derived from a standard curve generated from serially diluted input DNA and fold enrichment was calculated relative to the control samples. The specificity of the assay was validated by normal rabbit IgG as the negative control.
DNA methylation analysis
Locus specific quantification of methylation level was achieved using methylation-sensitive restriction enzyme-dependent quantitative PCR (MSRE-qPCR). Two methylation-sensitive restriction enzymes HinP1I and HpaII were used in this study. HinP1I targets the CpG sites −1039 and −500; while HpaII targets the −420 CpG upstream of the transcription start site (TSS) of the Cyp1a1 gene. Briefly, an aliquot of genomic DNA was digested overnight (12 hrs) at 37 °C with either HinP1I or HpaII. Another DNA aliquot of similar concentration was digested with XbaI as a negative control since the target amplicon does not contain an XbaI site. The digested DNA was then subjected to qPCR using a primer set flanking the 3 CpGs of interest at the Cyp1a1 promoter (see primer sets in Supplementary Table S4). Percentage of methylation level was calculated as the ratio of the copy number obtained from the HinP1I or HpaII digested DNA divided by the copy number obtained from the XbaI digested DNA.
BrdU staining
Mice treated with 3 μg/kg TCDD or vehicle were administered with 50 mg/kg bw of BrdU intraperitoneally at 23 hrs post-TCDD treatment. One hour later, the animals were deeply anaesthetized with isoflurane and perfused with 4% paraformadehyde. The fixed livers and testes were cryoprotected in increasing concentrations of sucrose and then mounted in cryostat sectioning medium (Tissue-Tek® O.C.T. Compound). 6 μm sections were stained with mouse monoclonal Anti-BrdU antibody and Goat Anti-Mouse Alexa Fluor® 488. The sections were counterstained with Hoechst and visualised by fluorescence microscopy. Testes sections were used as the positive control where BrdU incorporating proliferating stem cells (spermatogonia) can be readily observed.
5 hydroxymethylcytosine analysis
Single CpG 5-hydroxymethylcytosine (5 hmC) level was analyzed using the Epimark 5 hmC and 5 mC Analysis Kit. Briefly, 10 μg of DNA was glucosylated using T4 Phage β-glucosyltransferase (T4-BGT) overnight, followed by simultaneous restriction enzyme digestion with MspI (sensitive to glucosylated-5 hmC), and HpaII (sensitive to the cytosine modifications 5 mC, 5 hmC, and glucosylated-5 hmC). The digested DNA was then analyzed by qPCR using primers flanking the −420 CpG site (Supplementary Table S4). The 5 hmC levels were calculated from the copy numbers using the following formula described by the manufacturer.
Where M2 is the qPCR copy number in the sample of genomic DNA treated with T4-BGT and digested with MspI, C1 is the copy number in the sample with genomic DNA only, C2 is the copy number in the sample of genomic DNA treated with T4-BGT only and M1 is the copy number in the sample of genomic DNA digested with MspI.
Plasmid construction, point-mutation, and in vitro methyaltion
A Cyp1a1 promoter fragment spanning −1534 bp upstream of the TSS through + 23 of exon1 was cloned from C57BL/6J mouse genomic DNA using LA Taq polymerase and gene-specific primers (Supplementary Table S5). The DNA amplicon was digested with MluI and XhoI, and then inserted into a pGL3-Basic luciferase vector to generate a pmCyp1a1-Luc reporter vector.
In order to exclusively amplify the Cyp1a1 promoter fragment from the plasmid DNA, but not the Hepa1c1c7 genomic DNA, we carried out site-directed mutagenesis of the pmCyp1a1-Luc reporter vector targeting dinucleotides (TG to CA) at the 3′end of the forward primer using the Site-Directed Mutagenesis Kit. The mutation oligonucleotide sets are shown in Supplementary Table S6. The reporter plasmid pmCyp1a1-Luc was methylated in vitro using HhaI and HpaII methyltransferases. HhaI methylates GCGC (HinP1I recognized-CpG site), while HpaII methylates CCGG (HpaII recognized-CpG site). Briefly, 5 μg of the plasmid was incubated for 5 hrs with the methyltransferase, supplemented with 32 mM S-adenosylmethionine. Successful methylation was verified by complete protection from respective restriction enzyme digestion.
Cell culture and luciferase assay
The mouse hepatoma cell line, Hepa1c1c7, was cultured in α-MEM supplemented with 10% FBS, penicillin/streptomycin, and β-mercaptoethanol. Plasmid transfection was carried out using Lipofectamine2000. After co-transfection with the phRL-TK vector, luciferase gene reporter activity was measured by the Dual-Luciferase Reporter Assay System according to the manufacturer’s instructions.
siRNA knockdown
The siRNA oligos for knockdown of Tet1, Tet2, Tet3, Ahr, Apex1, Tdg, and Non-targeting siRNA pool 1 were utilised. Non-targeting siRNA pool 1 (scramble) was used as the negative control. For knockdown experiments, the cells were plated on 24 well plates and 50 nM of the selected siRNA oligonucleotides were transfected with Lipofectamine2000. The transfection medium was changed 24 hrs post-transfection and target gene knockdown was verified after 48 hrs by RT-qPCR and western blot.
In vitro demethylation assay
HhaI methyltransferase-treated pmCyp1a1-Luc vector plasmid was co-transfected with siRNAs on day 0. The cells were then treated with 10 nM TCDD on day 1 and harvested 24 hrs post-treatment. DNA was isolated by the DNeasy Blood & Tissue Kit and plasmid methylation level was analyzed by MSRE-qPCR using primers targeting the mutated site (Supplementary Table S7). The cells used in this study were of the same origin and were treated on similar days.
Primary hepatocyte isolation
Mouse primary hepatocytes were isolated by the two-step retrograde collagenase perfusion method described by Klaunig et al.21 Briefly, adult C57BL/6J mice were anaesthetized using isoflurane and the liver perfused with calcium and magnesium-free HBSS containing 5 mM glucose, 0.5 mM EGTA, and 25 mM HEPES through the inferior vena cava. Next, DMEM containing collagenase type IV at 100 CDU/ml, 5 mM glucose, 15 mM HEPES, and penicillin/streptomycin was used for liver digestion. The free hepatocytes were then filtered using a 100 μm nylon strainer and washed in DMEM containing 25 mM glucose, 10% FBS, 15 mM HEPES, and 100 nM dexamethasone. The cells were then plated on porcine skin collagen coated plates and cultured overnight in serum free low-glucose DMEM containing penicillin/streptomycin, 10 nM dexamethasone, and 5 mM HEPES. The hepatocytes were exposed to 10 nM TCDD dissolved in DMSO. Control cells were exposed to DMSO only. Samples were obtained at 0 hrs, 12 hrs, 18 hrs, 24 hrs, and 48 hrs post-TCDD exposure.
Western blot
Hepa1c1c7 cells were quickly homogenized in 50 μl of ice-cold tissue sample buffer, sonicated, and then boiled for 5 min before storage at −80 °C. The cell lysate was separated on a 12% polyacrylamide and blotted onto the PVDF membrane. The membrane bound proteins were probed with the appropriate antibodies shown in Supplementary Table S7, mouse monoclonal Ahr antibody A-2, and anti-Tet2 antibody. The bands were visualized by the Chemi-Lumi-One chemiluminescence system.
Immunocytochemistry
Cells were cultured in 24 well plates and fixed for 10 min using 4% paraformaldehyde in 0.2 M sucrose. The cells were then permeabilized with 0.1% TritonX-100 for 30 min. Nonspecific binding was blocked with 1% bovine serum albumin for 30 min before overnight incubation with mouse monoclonal Ahr antibody. Goat Anti-Mouse Alexa Fluor 488 was used as the secondary antibody. The cells were finally counterstained with Hoechst 33342.
Statistics
All statistical analyses were done using StatView for Windows version 5.0 (SAS Institute, Cary, NC, USA). All results are represented as mean ± SE. Two-way analysis of variance (ANOVA) was used to analyze the effect of treatment in the MSRE-qPCR and 5 hmC data across all time points. The MSRE-qPCR data after siRNA knockdown was analyzed by one-way ANOVA followed by Fisher’s PLSD post hoc test. Student’s t-test was employed for the rest of the data. P-value less than 0.05 were considered statistically significant.
Results
Dioxin elicits Cyp1a1 transcriptional memory
A single dose of TCDD induced Cyp1a1 mRNA expression within 6 hrs which peaked at 12 hrs, and was followed by a gradual decrease after 24 hrs (Fig. 1a). Notably, at 40 days post-TCDD exposure, the level of Cyp1a1 mRNA was very low (Fig. 1a). The Ahr−/− animals did not respond to TCDD (Fig. 1b). To compare the inducibility of Cyp1a1 transcription between control and TCDD-treated mice, we re-administered TCDD to the pretreated animals 40 days after the initial dose. There was an approximately three-fold higher induction of Cyp1a1 in the TCDD-pretreated animals compared to non-treated control animals (Fig. 1c), indicating potential transcriptional memory.
Dioxin induces stable changes in histone modifications at the Cyp1a1 promoter
Histone modifications at the Cyp1a1 promoter were analyzed 24 hrs and 40 days after TCDD treatment. At 24 hrs, the transcriptionally competent trimethylation of H3K4 (H3K4me3) and H4Ac were significantly increased while the repressive marker H4K20me3 was significantly decreased (Fig. 2a–c and Supplementary Fig. S1). Importantly, these epigenetic modifications were propagated to 40 days post-TCDD treatment (Fig. 2d–f). In particular, the increase in H3K4me3 and H4Ac at −500, and a decrease in H4K20me3 at the −1000 region were significantly enriched until 40 days post-TCDD exposure. On the other hand, Ahr−/− mice did not show a treatment-related increase in H3K4me3 (Supplementary Fig. S2), indicating that this is an Ahr-dependent phenomenon. β-actin was used as the control gene (Supplementary Fig. S3). These stable changes in histone modifications, taken together with observed Cyp1a1 hyperinduction indicate an Ahr-driven Cyp1a1 epigenetic memory.
Dioxin lowers methylation levels at the Cyp1a1 promoter region
To examine if Ahr activation elicits changes in the CpG methylation level on Cyp1a1 gene promoter region, we measured DNA methylation levels in mouse liver samples after dioxin exposure. Treatment with TCDD induced the demethylation of two CpGs at the Cyp1a1 proximal promoter (−500 and −420) within 24 hrs (Fig. 3a,b). The CpG at −1039 was entirely unmethylated (Supplementary Fig. S4). The DNA hypomethylation progressed steadily up until day 7 and the hypomethylated state was maintained to 40 days post-TCDD treatment (Fig. 3a,b). On the other hand, TCDD treated Ahr−/− animals did not show lowered DNA methylation levels by 24 hrs, indicating that the TCDD-induced hypomethylation at the Cyp1a1 promoter is an Ahr-dependent process (Fig. 3a,b). The relatively short duration taken for dioxin to induce DNA hypomethylation argued for involvement of an active demethylation mechanism. Passive DNA demethylation involves a cellular replication-dependent dilution of methylated cytosines in conditions where the DNA methylation maintenance methyltransferase is inhibited22,23. To clarify whether the demethylation involved passive removal of the methylated cytosine through cellular proliferation within 24 hrs, we performed BrdU staining on the TCDD treated livers. It was observed that TCDD does not induce cellular division in the mouse liver at 24 hrs post exposure (Supplementary Fig. S5). This suggests that the TCDD-induced hypomethylation is not a result of passive demethylation but is likely to result from active demethylation.
It is also worth noting that Cyp1a1 transcriptional activation preceded Cyp1a1 promoter demethylation. Cyp1a1 mRNA was detectable by 6 hrs (Fig. 1a), earlier than CpG demethylation, which was observed at 24 hrs (Fig. 3a,b). Furthermore, Cyp1a1 transcriptional extinction occurred by 40 days in the absence of CpG re-methylation, implying that CpG methylation loss possibly plays a role in epigenetic memory rather than in the induction of Cyp1a1 gene transcription. The DNA demethylation was specific to the mouse liver, as the kidney and brain showed minimal or no methylation changes in response to TCDD exposure, respectively (Supplementary Fig. S6). Similarly, there was minimal Cyp1a1 activation upon TCDD exposure in the kidney and brain (Supplementary Fig. S6).
Ahr-driven active demethylation involves 5 hmC and the active DNA demethylation mediators Apex1, Tdg, and Tet3
Active DNA demethylation involves Tet protein-mediated enzymatic conversion of methylated cytosine (5 mC) to 5 hmC, 5-formylcytosine (5fC), and 5-carboxycytosine (5caC), followed by excision by Tdg and replacement with an unmethylated cytosine through the BER pathway24,25.
We show here that TCDD induced a gradual decline in 5 hmC content at the −420 CpG (Fig. 4a), a trend that is in agreement with the progressive CpG demethylation observed in Fig. 3b. ChIP assay for the demethylation factors Apex1, Tdg, and Tet3 revealed significant association of Tdg to the Cyp1a1 proximal promoter (Fig. 4c). On the other hand, while there was an increase in Apex1 and Tet3 binding at the Cyp1a1 promoter, it was found no to be statistically significant (Fig. 4b,d). This increase was especially noticeable at the −1000 region in TCDD treated Ahr+/+ mice but was absent in Ahr−/− mice. Furthermore, TCDD did not alter the mRNA expression levels of Apex1, Tdg, Tet1, Tet2, and Tet3 (Supplementary Fig. S7). Tet1 had exceptionally an low mRNA copy number (Supplementary Fig. S7).
Ahr, Tet2, Tet3, and Tdg are required for TCDD-induced DNA demethylation
To evaluate the functional involvement of DNA demethylation factors in Ahr-driven DNA demethylation, we utilized an artificially methylated plasmid (bearing a 1500 bp Cyp1a1 promoter fragment) and siRNA knockdown against Ahr, Apex1, Tdg, Tet1, Tet2, and Tet3. Hepa1c1c7 was chosen as an optimal test cell line for the in vitro demethylation assay due to the low methylation levels in the endogenous Cyp1a1 promoter (Fig. 5a). Other efforts to utilize primary hepatocytes for the functional study revealed that isolated Ahr+/+ hepatocytes have low Cyp1a1 promoter methylation in comparison to the adult mouse liver and Ahr−/− hepatocytes (Supplementary Fig. S8). Intranuclear Ahr localization in untreated hepatocytes was also observed (Supplementary Fig. S8). In contrast, Hepa1c1c7 cells showed nuclear Ahr localization only after TCDD treatment (Supplementary Fig. S8).
We found that methylation with HhaI methyltransferase (targeting HinP1I sites) did not change Cyp1a1 reporter gene activation by TCDD. However, methylation with HpaII methyltransferase (targeting HpaII sites) or methylation with both HhaI and HpaII inhibited Cyp1a1 reporter transactivation (Fig. 5b). Thus, HhaI methyltransferase was chosen for further experiments. Notably, 10 nM TCDD treatment of Hepa1c1c7 cells induced demethylation of the in vitro methylated plasmid within 24 hrs post exposure (Fig. 5c,d), replicating the in vivo findings (Fig. 3a,b). There was efficient target knockdown by 48 hrs post siRNA transfection (Fig. 5e).
Importantly, in vitro knockdown of Ahr, Tdg, Tet2, Tet3, and to a lesser extent Apex1, prevented TCDD-induced Cyp1a1 promoter demethylation, suggesting that these genes are required for the Ahr-driven, TCDD-induced DNA demethylation (Fig. 5f). As expected, Tet1 did not ameliorate TCDD demethylation due to the low copy number (Supplementary Fig. S7).
Discussion
Nuclear receptors are an attractive model for understanding the targeting of epigenetic modifier proteins to specific loci in the genome, given their wide roles in development, reproduction and homeostasis26. The present study provides novel evidence that Ahr drives robust epigenetic modulation at the Cyp1a1 promoter. Ahr activation by dioxin led to Ahr-dependent changes in histone modifications (Fig. 2) and active DNA demethylation of the Cyp1a1 proximal promoter in the adult mouse liver (Fig. 3). Maintenance of this hypomethylated state and open chromatin conformation contributed to Cyp1a1 transcriptional memory.
The present findings suggest that Cyp1a1 transcriptional memory may play a role in adaptive response to xenobiotic exposure and sheds light on the role of epigenetic memory in the development of xenobiotic tolerance. These findings are in agreement with a previous report, where the constitutive androstane receptor ligand TCPOBOP elicited epigenetic memory at the Cyp2b10 promoter and increased zoxazolamine metabolism and hepatocyte Cyp2b10 transcription memory27. Transcriptional memory of the Cyp1a1 gene may imply increased detoxification of Cyp1a1 substrates and possible activation of pro-carcinogens, such as benzo[a]pyrene. DNA hypomethylation after initial demethylation can remain for a long time after interleukin 2 activation in CD4 + cells28 or after demethylation of the Tat gene following glucocorticoid exposure in rat hepatoma cells29. In both cases, subsequent stimulation with antibody and dexamethasone, respectively, led to a faster and robust response, indicating that CpG demethylation acted as an epigenetic memory of initial exposure. Therefore, maintenance of histone modifications as well as DNA hypomethylation co-exist as epigenetic bookmarks for Cyp1a1 hyperinduction in the liver of dioxin re-exposed mice.
In agreement with Ahr-driven DNA demethylation, nuclear receptor-directed active DNA demethylation has been observed at the pS2 gene after estrogen receptor activation30, at the Tat promoter after glucocorticoid receptor activation29,31, and at adipocyte-specific genes by PPARγ-directed PARylation, Tet1 and Tet2 targeting32. The current model of active DNA demethylation involves enzymatic oxidation of 5 mC to 5 hmC, 5 fC, and finally 5 caC by the Tet proteins24,33. The latter two products are then recognized by Tdg and removed through base excision repair25,34. We observed a gradual decline in 5 mC and 5 hmC at the same CpG (−420) indicating that there was progressive demethylation that involved transition of 5 mC to the 5 hmC intermediate observed in Tet-mediated demethylation. A similar decline of 5 hmC has been observed in PPARγ-directed DNA demethylation in adipocytes32 as well as in DNA demethylation induced by hydroquinone35, phenobarbital36,37, and hydralazine38. In support of Tet protein involvement in Ahr-dependent active demethylation, we observed Ahr-dependent occurrence of Tet3 at the Cyp1a1 promoter. Additionally, Tet2 and Tet3 knockdown suppressed dioxin-induced demethylation of an artificially methylated promoter. Tet1 has low expression levels in the adult liver39 and was thus not expected to contribute to the demethylation. ChIP assay of the BER proteins revealed that Apex1 and Tdg also occurred at the Cyp1a1 promoter in an Ahr-directed manner, although only Tdg knockdown inhibited dioxin-induced demethylation of the methylated plasmid. Apex1 haploinsufficiency only results in a 35% decrease in BER in the mouse liver40, suggesting that another endonuclease such as Apex2 may compensate for low Apex1 protein levels.
Our analysis showed that the Cyp1a1 promoter demethylation in the liver correlated with high Cyp1a1 mRNA induction. However the brain and kidney, which had minimal DNA methylation changes after TCDD exposure, exhibited lower Cyp1a1 expression. Differential tissue response to dioxin has been observed41, with the liver having considerably higher Cyp1a1 response to dioxin than the brain42 and kidney43. The epigenetic configuration of the Cyp1a1 promoter in various tissues may play an important role in tissue sensitivity and responsiveness. The role of differential CpG methylation in Cyp1a1 inducibility has been demonstrated in various human cell lines44,45,46,47, as well as other species48.
Unexpectedly, the isolated hepatocytes used in the present study had low Cyp1a1 promoter methylation in comparison to the adult mouse liver in vivo. Disruption of liver architecture during hepatocyte isolation has been shown to enhance cell cycle entry and binucleation (polyploidy) due to the oxidative stress resulting from liver digestion and cellular agitation49,50. Additionally, we observed intranuclear localization of Ahr in untreated hepatocytes. A similar picture has been observed in HepG2 cells being cultured under low glucose medium51, resulting in partial activation of Cyp1a1. The combined impact of increased hepatocyte binucleation and nuclear Ahr translocation on Cyp1a1 promoter methylation may be of importance given that Ahr−/− hepatocytes had higher methylation levels. In light of our findings at the Cyp1a1 promoter and in consideration of the wider roles of Ahr in physiological function, we also anticipate the possibility of genome-wide epigenetic programming at Ahr binding elements and downstream target genes, possibly in a tissue- and cell-specific manner.
In conclusion, this study provides novel evidence of Ahr-dependent epigenetic regulation of target genes including active DNA demethylation. The Ahr-driven epigenetic memory influences response to subsequent chemical exposure and imply an adaptive mechanism to toxicological insult by xenobiotic chemicals.
Additional Information
How to cite this article: Amenya, H. Z. et al. Dioxin induces Ahr-dependent robust DNA demethylation of the Cyp1a1 promoter via Tdg in the mouse liver. Sci. Rep. 6, 34989; doi: 10.1038/srep34989 (2016).
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Acknowledgements
We are grateful to Sailendra N Sarma, Nanoha Sato, Eiki Kimura, Mohamed Nassef, Toshiki Aiba, Kana Matsuda, Norie Aoki, Hisaka Kurita and Keiko Aida-Yasuoka for their technical input and useful suggestions during the experimental phase of this work. This work was supported by the Japan Society for the Promotion of Science [KAKENHI Grant Numbers 23310044 and 20380168 to SO].
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S.O. performed preceding experiments, and formulated the hypothesis of this study together with H.Z.A. H.Z.A. conducted the experiments, analyzed the data, and drafted the manuscript. H.Z.A., S.O. and C.T. revised the manuscript.
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Amenya, H., Tohyama, C. & Ohsako, S. Dioxin induces Ahr-dependent robust DNA demethylation of the Cyp1a1 promoter via Tdg in the mouse liver. Sci Rep 6, 34989 (2016). https://doi.org/10.1038/srep34989
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DOI: https://doi.org/10.1038/srep34989
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