ABSTRACT
In early embryos, DNA methylation is remodelled to initiate the developmental program but for mostly unknown reasons, methylation marks are acquired unequally between embryonic and placental cells. To better understand this, we generated high-resolution DNA methylation maps of mouse mid-gestation (E10.5) embryo and placenta. We uncovered specific subtypes of differentially methylated regions (DMRs) that contribute directly to the developmental asymmetry existing between mid-gestation embryonic and placental DNA methylation patterns. We show that the asymmetry occurs rapidly during the acquisition of marks in the post-implanted conceptus (E3.5-E6.5), and that these patterns are long-lasting across subtypes of DMRs throughout prenatal development and in somatic tissues. We reveal that at the peri-implantation stages, the de novo methyltransferase activity of DNMT3B is the main driver of methylation marks on asymmetric DMRs, and that DNMT3B can largely compensate for lack of DNMT3A in the epiblast and extraembryonic ectoderm, whereas DNMT3A can only partially palliate in the absence of DNMT3B. However, as development progresses and as DNMT3A becomes the principal de novo methyltransferase, the compensatory DNA methylation mechanism of DNMT3B on DMRs becomes less effective.
Summary statement The kinetics of asymmetric DNA methylation acquisition of embryoplacenta differentially methylated regions is not a stepwise process occurring in embryonic and extraembryonic lineages, but a prompt progression in the early post-implanted conceptus.
INTRODUCTION
Throughout the eutherian mammalian gestation, the placenta plays an essential role in mediating maternal–embryonic exchanges of gas, nutrients and waste, and also provides the developing embryo with a protective layer against adverse environmental exposures and the maternal immune system (Rossant and Cross, 2001). These unique placental functions are orchestrated by several distinct trophoblast cell subtypes organized in separate layers (Cross, 2000). The initial steps of lineage specialization of both placental and embryonic cells occur promptly following fertilization during the first few embryonic cleavages as DNA methylation marks are being reprogrammed (Morgan et al., 2005).
DNA methylation is an epigenetic mechanism that is critical in the determination of lineage-specific differentiation and development, and is mainly recognized for its involvement in processes such as transcriptional repression, genomic imprinting and X-inactivation (Bestor, 2000). DNA methylation marks are mediated by the action of DNA methyltransferases (DNMTs). Establishment of new or de novo DNA methylation patterns required for cell lineage determination during development is mediated by DNMT3A and DNMT3B, with cofactor DNMT3L, (Okano et al., 1999, Li, 2002), whereas DNMT1 maintains heritable DNA methylation patterns during cellular divisions (Leonhardt et al., 1992, Lei et al., 1996). These enzymes are critical, as deletion of Dnmt3b or Dnmt1 is embryonic lethal, while Dnmt3a-deficient offspring die shortly after birth (Li et al., 1992, Okano et al., 1999). During gametogenesis, the acquisition of genome-wide and allele-specific methylation patterns (i.e. genomic imprinting) in both oocytes and sperm is essentially due to the activity of DNMT3A (Kaneda et al., 2004, Kato et al., 2007). Following fertilization, a reprogramming wave removes most methylation signatures across the genome, except for imprinted regions, some types of repeat sequences, as well as imprinted-like sequences, to trigger the developmental program (Hirasawa et al., 2008, Howell et al., 2001, McGraw et al., 2015). Then, during the peri-implantation process, DNA methylation profiles are re-acquired in a sex-, cell- and tissuespecific manner across most parts of the genome by the combined action of DNMT3A and DNMT3B. In the early stages of the de novo methylation wave (E4.5-E7.5), the expression of Dnmt3b is more robust than Dnmt3a in the epiblast and embryonic-derived cells (Watanabe et al., 2002, Auclair et al., 2014, Smith et al., 2017), with the relative expression of Dnmt3b and Dnmt3a being considerably reduced in the extraembryonic ectoderm (ExE) and trophoblast lineages (Smith et al., 2017, Senner et al., 2012). This discrepancy in Dnmt3a and Dnmt3b expression levels coincides with the initiation of divergent DNA methylation acquisition between the trophoblast and the inner cell mass of the blastocyst (Monk, 1987, Nakanishi et al., 2012, Oda et al., 2013, Santos et al., 2002, Fulka et al., 2004, Guo et al., 2014, Smith et al., 2014), a difference that becomes extremely apparent by E6.5, as the epiblast has acquired most of its global DNA methylation compared to the lower-methylation state of the ExE (Auclair et al., 2014, Smith et al., 2017). This divergence is a common feature across mammalian placenta, as a heterogeneous and lower-methylation state compared to somatic tissues and other cell types is constantly observed (Smith et al., 2017, Decato et al., 2017, Schroeder et al., 2013, Chatterjee et al., 2016).
Although the functional role of reduced methylation levels observed across the placental genome is still not fully understood, studies suggest that it may activate transposable elements that are typically silenced in other tissues (Chuong, 2013). DNA methylation plays an important role in suppressing retrotransposons in mammalian cells, for which the activity has been associated with genomic instability and disease development (Church et al., 2009, Slotkin and Martienssen, 2007). Following the de novo methylation wave, in embryonic-derived cells from the inner cell mass, transposable elements acquire higher levels of DNA methylation causing transcriptional silencing, whereas in the trophectoderm-derived cells that will form the placenta, these transposable elements are maintained in a relaxed methylation state and preferentially expressed (Price et al., 2012, Okahara et al., 2004, Warren et al., 2015). The low-methylation levels on these elements contributed to the evolution and diversification of the placenta function through the regulation of gene expression by providing placenta-specific enhancers, cryptic promoters and other cis-regulatory elements (Haig, 2012, Mi et al., 2000, Cohen et al., 2011, Xie et al., 2013, Macaulay et al., 2011, Emera and Wagner, 2012).
Despite the evident distinction between embryonic and placental DNA methylation levels, it remains unclear how, when and where methylation levels are acquired unequally across these genomes. To better understand the developmental dynamics of epigenetic asymmetry that exists between embryo and placenta, we first generated high-resolution maps of DNA methylation marks using Reduced Representation Bisulfite Sequencing (RRBS) at mid-gestation, when the mouse placenta is first considered mature (E10.5), to identify embryo-placenta differentially methylated regions (DMRs). Then, using publicly available DNA methylation data sets and computational analyses, we defined how various categories of DMRs are established in early stages and maintained throughout development. In addition, we outlined the contribution of Dnmt3a and Dnmt3b in the acquisition and maintenance of embryonic and extraembryonic specific DMR patterns.
METHODS
Animals and Sample Collection
Female C57BL/6 (8-10 week-old) were purchased from Harlan Sprague-Dawley Laboratories (Indianapolis, IN) and were mated with male C57BL/6 (4 months of age). Following natural mating, embryos and placental tissues were collected at E10.5 (presence of vaginal plug at E0.5). Samples were frozen immediately in liquid nitrogen and stored at −80 °C until analyzed.
DNA Methylation Analyses
RRBS libraries were generated as published protocols (Boyle et al., 2012, Gu et al., 2011) with our specifications (Magnus et al., 2014, McGraw et al., 2015, Legault et al., 2019). 500 ng of extracted DNA (Qiagen) from placenta (male n=2, female n=2) and embryo (male n=2, female n=2) samples was MspI digested, adaptor ligated and PCR amplified (multiplex). Multiplexed samples were pooled and 100 bp paired-end sequenced (HiSeq-2000, Illumina). The data analyses were done according to the pipeline established at the McGill Epigenomics Mapping and Data Coordinating Centers (Magnus et al., 2014, McGraw et al., 2015) that include BSMAP and methylKit. Specific parameters were chosen including 100 bp step-wise tiling windows, containing a minimum of 2 CpGs per tile and a minimum 15× CpG coverage of each tile per sample. The methylation level of a 100-bp tile was the result of all CpG C/T read counts within the tile after coverage normalization between samples, and the methylation level reported for a sample on autosomal chromosomes was the average methylation level across replicates. Significant DNA methylation changes were designated as ±≥20% average differences between groups of replicates and a q-value < 0.01 using the logistic regression function of methylKit (Akalin et al., 2012). Direct comparisons between DNA methylation averages were done using Wilcoxon-Mann-Whitney test in R. Gene ontology (GO) terms and pathway analyses for RefSeqs associated to promoter-TSS were conducted using Metascape gene annotation and analysis resource (Zhou et al., 2019).
Sequencing Data
Publicly available DNA methylation data sets (Auclair et al., 2014, Decato et al., 2017, Smith et al., 2014, Smith et al., 2017, Whidden et al., 2016, Hon et al., 2013) were analyzed using a custom script to intersect single CpG site methylation calls from these data sets within defined 100bp tiles associated to the embryo-placenta DMRs categories
RESULTS
Increased Fluctuation in Genome-Wide DNA Methylation Levels in Placental Cells
To identify the overall epigenetic asymmetry that exists between placental and embryonic genomes during mouse in utero development, we first established genome-wide DNA methylation profiles using RRBS (McGraw et al., 2015, Magnus et al., 2014, Legault et al., 2019) of embryos and their corresponding placentas at mid-gestation (E10.5), the developmental stage at which the mouse placenta is considered mature (Cross et al., 1994). Using this approach, we quantified the DNA methylation profiles of ~1.8 million CpG sites in each sample (embryo n=4, placenta n=4). We found that the accumulation of CpG methylation was very distinct between the placenta and the embryo. In the placenta, we detected a greater proportion of CpGs in the 0-50% methylation range and a lower proportion of CpGs in the 80-100% methylation range (Figure 1A). Although we observed that a large proportion of CpGs within the examined regions had no methylation marks in both the embryo and the placenta, interestingly, most CpGs with partial methylation (20-50%) in placenta showed high methylation levels (>80%) in embryos (Figure 1B). The divergence in global DNA methylation profiles conferred a high degree of clustering between both tissue types (Figure S1). These results are consistent with previous studies indicating lower levels of overall DNA methylation in extraembryonic tissues (Price et al., 2012, Schroeder et al., 2013, Smith et al., 2017), reviewed in (Robinson and Price, 2015).
To further investigate the dynamics of DNA methylation between placental and embryonic genomes and enable direct comparison of precise regions, we segmented the genome of autosomal chromosomes into 100bp non-overlapping genomic windows (tiles; see methods section). After removal of sex chromosomes, we identified 245 048 unique sequenced tiles (referred to as All-tiles) containing 896 820 common CpGs between all placenta and embryo samples and with a minimum of 15x sequencing depth. We observed a strong reduction in the fraction of highly methylated tiles (80-100%) in the placenta compared to the embryo (Figure 1C), which correlated with a sharp increase in the number of placenta tiles in the 0-20%, 20-40% and 40-60% methylation range. Globally, we found that the average DNA methylation level across all placental tiles was significantly lower compared to all embryo tiles (27% vs 45%, p<0.0001) (Figure 1C). This overall epigenetic disparity in embryo and placenta DNA methylation levels was especially noticeable when we mapped the methylation mean of All-tiles with respect to regions surrounding the transcription start sites (TSS) (Figure 1D). When we focused on a specific chromosome section (e.g., chr 7, 35Mb) (Figure 1E), we observed that genomic segments with high DNA methylation levels in embryos were predominantly hypomethylated in placenta. We also observed that gene or CpG island (CGI) poor regions had consistently high methylation levels in embryos and lower methylation levels in the placenta. Together, these results indicate that the mid-gestation placenta has very distinctive global DNA methylation profiles compared to the embryo, and that this lower level of global DNA methylation (i.e., DNA hypomethylation) across the placental genome is due to a significant lower number of highly methylated (≥80%) genomic regions. We can also conclude that despite the cellular heterogeneity in E10.5 placental and embryonic tissues, the vast majority of the conceptus possesses specific genomic regions with either low (0-20%) or high (80-100%) levels of methylation. However, the placenta genome presents an increased number of regions having a broader distribution of DNA methylation (20-80%), revealing a greater diversity in methylation levels across placental cell types compared to embryonic cell types.
Embryonic and Placental DNA Methylation Divergences Across Genomic Features
To explain the developmentally divergent methylated states between the mouse embryo and the placenta, we next sought to precisely determine the genomic features revealing DNA methylation differences. We defined differentially methylated regions (DMRs) as 100bp genomic segments showing a significant difference of methylation levels between embryonic and placental samples with an absolute mean methylation difference of 20% or higher (McGraw et al., 2015, Shaffer et al., 2015, Piche et al., 2019). Using these conditions, we screened the 245 048 unique tiles common between all samples and identified 110 240 DMRs (~45% of All-tiles; Supplementary Table 1) with tissue- and/or developmental-specific DNA methylation variations between the embryo and the placenta (Figure 2A; random subset of 20,000 DMRs shown). Consistent with our findings (Figure 1), the majority (96.8%; n=106 712) of DMRs had lower DNA methylation in the placenta (referred to as Hypo-DMRs) and only a small proportion (3.2%; n=3 528) showed increased methylation levels (referred to as Hyper-DMRs) compared to the embryo (Figure S2). For Hypo-DMRs, tiles mainly overlapped (96%; n=102 982) with intergenic, intron, exon and promoter-TSS regions (Figure S2). For each of the genomic feature categories of Hypo-DMRs, the average DNA methylation levels in the placenta were essentially half of those present in the embryo (Figure 2B). As for DMRs with higher methylation levels in the placenta (Hyper-DMRs), we noticed that the vast majority of these tiles (83%; n=2 929) had very low methylation levels in the embryo (<20%) (Figure 2A-B). Most of Hyper-DMRs overlapped intergenic, intron, exon and promoter-TSS regions (93%; n=3 272, Figure S2). We then investigated the relationship between gene expression and DMR DNA methylation levels. Highly expressed genes in placental tissue such as Syna (Syncytin A) (Mi et al., 2000) showed overall lower methylation levels in the placenta when compared to the embryo (Figure 2D, smoothed representation) (Hansen et al., 2012). Similar observations were made in the gene body of Atf6b (Activating Transcription Factor 6 Beta), a gene implicated in the transcriptional downregulation of Pgf (Placental Growth Factor) in response to endoplasmic reticulum stress in pathological placentas (Mizuuchi et al., 2016). As for genes predominantly expressed in the embryo, Mir219a-2/Mir219b, a brain-specific non-coding microRNA, showed higher methylation in the placenta (Figure 2D). It was recently shown that Mir219 was abnormally expressed during pregnancy in amnion retrieved specifically from obese women (Nardelli et al., 2014) and, interestingly, obesity has been suggested to cause epigenetic changes (Lillycrop and Burdge, 2011). Another example of placenta Hyper-DMRs is Sox6 (SRY-Box 6), which is implicated in the terminal differentiation of muscle (Figure 2D) (Kamachi and Kondoh, 2013). These observations point to an association between tissue-specific DNA methylation levels of DMRs and biological functions. Gene ontology enrichment analyses further support that Hypo-DMRs were strongly associated to germline functions and reproduction (e.g., male and female gamete generation, reproduction, piRNA metabolic process, meiotic cell cycle, germ cell development) (Figure 2C). As for Hyper-DMRs, top biological processes were mostly associated with developmental and differentiation processes (e.g., regionalization, embryo development, pattern specification process, skeletal system, head development) (Figure 2C). Fittingly, the biological functions were completely divergent between Hypo- and Hyper-DMRs. Altogether, these results denote that Hypo- and Hyper-DMRs are present across genomic features between mid-gestation embryo and placenta, and that these DNA methylation divergences are implicated in promoting/repressing specific processes during embryonic and placental development.
Presence of Distinctive DMR Categories between Mid-Gestation Embryo and Placenta
Amongst DMRs, our analyses also suggest the presence of particular DMR categories based on their level of DNA methylation in the embryo and placenta (Figure 2A). By defining subsets of DMRs and establishing their dynamic properties between tissues, we might better understand the genome-wide asymmetry in DNA methylation levels observed between the embryo and the placenta. To do so, we first clustered DMR-associated tiles in 6 different categories based on their range of low, mid and high methylation level (Low; <20%, Mid; ≥20 to <80%, High; ≥80%) in the embryo and the placenta, and followed the DMR category transitions between both tissues. We observed that DMRs with High-levels of methylation in the embryo overlapped with a large proportion of DMRs that showed Mid-levels of methylation in the placenta (Figure 3A,B; High-Mid n=72 715), whereas only a fraction corresponded to DMRs with Low-levels of methylation in the placenta (Figure 3A,B; High-Low n=1 889). As for DMRs with Mid-levels of methylation in embryo, the largest part remained in that same Mid-levels category in the placenta (Figure 3A; Mid-Mid n=23 640). Nonetheless, a portion of these embryonic Mid-levels DMRs were directed to DMRs with either Low- (Figure 3A; Mid-Low n=9 055) or High- (Figure 3A; Mid-High n= 21) levels of methylation in the placenta. Finally, DMRs with Low-levels of methylation in the embryo all showed Mid-levels of methylation in the placenta (Figure 3A; Low-Mid n=2 920). Thus, when we subdivide our DMRs into distinctive categories, we uncover that embryonic cells possess a large proportion of DMRs of High-level (>80%) of DNA methylation, which remain potentially static in embryonic tissues, whereas the vast majority of these DMRs have inferior and wide-range DNA methylation levels within placental tissue.
Specific Genomic Features Associated with DMR Categories
We next aimed to determine if the genomic distribution of embryo-placenta DMR categories was associated with distinct genomic features. First, by classifying by genomic annotations, we observed that DMRs with reduced methylation levels in the placenta (High-Mid, High-Low, Mid-Low) were prevailingly found in intergenic regions (>50% of tiles) (Figure 3C), whereas DMR categories with equivalent (Mid-Mid) or superior methylation level (Mid-High, Low-Mid) in the placenta were more frequent in genic associated regions (>50% of tiles). However, divergence between DMR categories was observed when we performed ontology analyses on promoter regions (Figure S3), as each DMR subtype clearly showed distinct biological functions. For example, High-Mid DMRs top functions were related to genes (e.g., Aszl, Tnp1, Piwil2) associated with male gamete generation, piRNA metabolic process and male meiotic nuclear division, whereas those of the Low-Mid category were mostly associated with developmental aspects (e.g., skeletal system development, regionalization, nervous system development). Since we know that in placenta, activation of retrotransposon-derived genes is interrelated with low DNA methylation levels (Macaulay et al., 2011, Reiss et al., 2007, Cohen et al., 2011), we next assessed how DMR categories overlapped with major types of retrotransposons (LINE; long interspersed nuclear elements, SINE; short interspersed nuclear element, and LTR; long terminal repeats). Out of the DMR categories, those with High-levels of methylation in the embryo and either Mid- or Low-levels in the placenta (High-Mid and High-Low) showed the most enriched overlap with retrotransposons, with 92% and 96% respectively (Figure 3D). DMR categories associated with gain of methylation in the placenta (Mid-High and Low-Mid) showed the least overlap with retrotransposons, especially the Low-Mid subtype. This highlights that during the de novo acquisition of DNA methylation patterns, DMRs with High-levels of methylation in the embryo and lower levels in the placenta are almost exclusively within retrotransposons-associated sequences, whereas DMRs with Low-levels of methylation in the embryo and higher DNA methylation in the placenta are preferentially outside retrotransposons-associated sequences. Finally, we investigated the proximity of the DMR categories in regards to CpG rich (CpG islands; CGI), neighbouring (shore; < 2kb away from CGIs, shelf; 2-4kb away from CGIs) and distant (open sea; > 4kb away from CGIs) regions (Figure 3E). We observed that most DMR categories are depleted from CGIs and are mostly found in open sea regions. In contrast, ~60% of tiles in Low-Mid DMRs overlapped with CGI, shores and shelves, revealing that the acquisition of de novo methylation for these genomic fragments in the extraembryonic lineage preferentially targets sequences inside or surrounding CGIs.
Altogether, these results indicate that the asymmetry within DMR categories, based on their methylation levels in the embryo and the placenta, can be associated to specific biological functions and genomic-derived features (e.g., CpG, retrotransposon contents). This is particularly apparent for DMRs with High-levels in the embryo (High-Mid, High-Low) and those with higher methylation levels in the placenta (Low-Mid).
DMR Categories are Established During the De Novo Methylation Wave and Maintained Throughout Development
To gain insights into the kinetics of lineage-specific DMR establishment between mid-gestation embryo and placenta, as well as their status during development, we assessed the levels of methylation associated with tiles for each DMR category as a function of their developmental stage. Publicly available sequencing data (Smith et al., 2012, Whidden et al., 2016) were analyzed using our custom script to generate 100bp tiles, and the DNA methylation levels for each tile were calculated. In E3.5 blastocysts, when the mouse genome is mostly depleted from DNA methylation marks, we observed low global DNA methylation levels (average <20%) for all DMR subtypes, with similar median levels between the committed cells of the inner cell mass (ICM) and trophectoderm lineages (Figure 4). DNA methylation levels tended to be higher in the trophectoderm for regions falling in the Mid-High DMRs, although measurements are based on very few DMRs for this specific category (n=21, Figure 3B, Mid-High). Since global DNA methylation is re-acquired in the next few subsequent developmental stages, we then asked whether the contrast in DNA methylation levels associated with the various DMR categories at mid-gestation would already be present between E6.5 epiblast and extraembryonic ectoderm (ExE) cell lineages, layers that are mostly composed of homogeneous and undifferentiated cell populations. For all DMR categories, DNA methylation levels in the E6.5 epiblast and ExE already showed similar pattern trends to those observed in the E10.5 embryo and placenta (Figure 4, Table S2). Interestingly, for all DMR categories we observed slightly higher DNA methylation levels in E6.5 ExE compared to E10.5 placenta (Figure 4, Table S2). However, when measured in the subsequent developmental stages (E10.5, E11.5, E15 and E18), levels associated with each category stabilized and remained in the same methylation range. This is true for all categories, except for the Mid-High DMRs where methylation levels are reduced by ~20% at E18. As for the E6.5 epiblast DNA methylation profiles, they closely matched those observed in the E10.5 embryo, except again for the Mid-High DMRs. For each of the DMR subtypes, the DNA methylation levels were largely stable and persisted across other time points (E6.5, E10.5, E11.5) in embryonic cells. Although no public DNA methylation data were available for whole embryos at later stages, when we overlapped tiles associated with E10.5 DMR categories with data from differentiated tissues of adult mice, the global DNA methylation profiles closely matched those for the majority of DMR categories (High-Mid, High-Low, Mid-Mid and Mid-Low) (Figure 4, Figure S4). We conclude that the various DMR categories observed at E10.5 are established during the embryonic and extraembryonic lineage-specification processes occurring during the peri-implantation wave of de novo methylation, and that these DNA methylation landscapes are widely retained throughout embryo and placenta development. Furthermore, for most DMR categories, the DNA methylation levels observed in developing embryos are long-lasting and conserved throughout somatic cell differentiation.
Dnmt3a- or Dnmt3b-Deficiency Alters Proper Establishment of DMR-Associated Patterns
Since the combined activity of DNMT3A and DNMT3B is essential for proper establishment of DNA methylation profiles and normal development, we next sought to define the contribution of each enzyme in the de novo establishment of DNA methylation in subtypes of DMRs in embryonic and extraembryonic cell lineages. To do so, we used DNA methylation data from publicly available datasets (whole genome bisulfite sequencing and RRBS) at E6.5 (epiblast and ExE) and E8.5 (embryo) with various inactive forms of Dnmts. First, when we overlapped our All-tiles subset, we observed a substantial reduction (p□0.0001) in average DNA methylation in absence of DNMT3A (37.81%) or DNMT3B (31.48%) in the E6.5 epiblast compared to wild-type (44.81%), whereas in the E6.5 ExE such a comparable loss was only associated with a Dnmt3b-deficiency (wt: 34.38% vs Dnmt3b’-/-: 19.33%, p 0.0001) (Figure S5). Similarly, in the E8.5 embryo, a significant reduction in average DNA methylation level was measured with lack of Dnmt3a or Dnmt3b expression compared to wild-type (wt: 47.5%; Dnmt3a-/-: 43.6%; Dnmt3b-/-: 34%, p□0.0001) (Figure S5). For most DMR subtypes, absence of DNMT3A caused modest or no reduction on overall DNA methylation levels in E6.5 epiblast and ExE (Figure 5A and S6, Table S3). Intriguingly, Dnmt3a-deficiency caused a slight gain of methylation (wt: 76.9% vs Dnmt3a-/-: 81.5%, p 0.0001) level in the E6.5 epiblast for High-Mid DMRs, suggesting a potential overcompensation effect by DNMT3B in the epiblast on this specific DMR subtype. In comparison, Dnmt3b-depletion led to a substantial loss of average methylation levels in all DMR categories in the E6.5 epiblast and ExE, except for epiblast High-Mid DMRs (Figure 5A, Table S3) for which a compensatory mechanism provided high levels of methylation (wt: 76.9% vs Dnmt3b-/-: 71.6%). The compensatory mechanism on High-Mid DMRs in response to Dnmt3b-deficiency was ineffective in the E6.5 ExE. When we focused on promoter-TSS for each DMR categories, we observed again that loss of methylation for these regulatory regions was principally associated with Dnmt3b-deficiency (Figure 5B). The promoter-TSS regions associated with High-Mid DMRs retained relatively high methylation levels for either Dnmt3a-/- or Dnmt3b-/- epiblast samples, demonstrating a robust and compensatory de novo methylation mechanism. To further underline the impact of DNMT3A or DNMT3B on the de novo methylation of DMRs, we measured methylation levels for DMRs selected from our gene enrichment analyses (Fgb, P2rx7, Pcyt2, Etnppl, Ralgds, Lrp5) and other genomic segments covered by multiple tiles (Cxxc1, Fcgrt, Lamp5, Mbd1, Lphn1, Pick1, Irf1) (Figure S7 & S8) in Dnmt3a- or Dnmt3b-deficient epiblast and ExE. In line with our global observations, for most DMR-associated tiles, a Dnmt3b-deficiency in E6.5 epiblast or ExE caused a more severe loss of methylation compared to lack of Dnmt3a. However, for some regions in the E6.5 epiblast (e.g., Pick1, Irf1), Dnmt3a-/- methylation levels were inferior to those of Dnmt3b-/-. Noteworthy, for most DMRs, lack of co-factor Dnmt3l affected DNA methylation levels to greater extent than Dnmt3a-deficiency (Figure S6). Overall, we show that of DNMT3A and DNMT3B participate in the establishment of the asymmetric methylation patterns associated with the various DMR categories in both embryonic and extraembryonic cells, with DNMT3B being the principal contributor in both cell lineages during the de novo reprogramming wave as it can compensate almost entirely for the absence of DNMT3A.
Decline in Compensatory DNA Methylation Mechanisms in Response to Dnmt3a- or Dnmt3b-Deficiency
As embryonic development progresses from E6.5 to E8.5, our data suggest that lack of DNMT3A or DNMT3B further reduces global methylation levels of DMRs (High-Mid, High-Low, Mid-Low and Mid-Mid), evoking that absence of either enzymatic activity causes an additive and extended effect (Figure 5A-B). To further define the robustness in compensatory mechanism between DNMT3A or DNMT3B in the establishment and maintenance of DNA methylation on DMRs categories, we focused on High-Mid promoter-TSS-associated DMRs as they have the highest DNA methylation levels and require the most de novo methyltransferase activity. Methylation differences of ≥20% between wild-type and Dnmt3a- or Dnmt3b-deficient samples were considered as regions showing substantial lack of compensation. In agreement with our results (Figure 5A-B), we observed that at E6.5, DNMT3B can compensate almost entirely for DNMT3 Aloss by maintaining methylation levels on most promoters-TSS associated tiles in the epiblast (410/437 = 93.8%) and ExE (558/602 = 92.7%), whereas DNMT3A can only partially alleviate the lack of DNMT3B in the epiblast (315/410 = 78.6%) and ExE (244/524 = 46.6%) (Figure 6A-B). As embryonic cell lineages development evolves between E6.5 and E8.5, global methylation levels increase on promoter-TSS of High-Mid DMRs. However, we detected a sharp decline in the compensatory mechanism to rescue the de novo and/or maintenance of methylation levels of promoter-TSS DMRs in the Dnmt3a- (524/627 = 80.9%) or Dnmt3b- (256/622 = 41.2%) deficient E8.5 embryos. This is further highlighted when we focus on a subgroup of 314 promoter-TSS associated tiles overlapping all of 9 data sets (Figure 6C), including gene promoters (e.g., Asz1, Catsper1, Ccdc42, Dmrtb1, Piwil2, Rpl10l, Sox30, Sycp1, Tnp1, Ttll1, Zfn42) related to our top enriched biological functions (i.e., piRNA, gamete generation and germ cells, meiotic nuclear division). Although E8.5 Dnmt3a- or Dnmt3b- deficient ExE data was not available, our data suggest that greater compensation failure would also be observed in this tissue. Thus, embryonic-placental DMRs need the combined action of DNMT3Aand DNMT3Bto both establish and maintain proper asymmetric levels during early development as compensatory DNA methylation mechanisms during the de novo wave of methylation decline overtime and fail to overcome methyltransferase shortage in later development stages.
DISCUSSION
With recent breakthroughs in high-throughput sequencing, we now have a better understanding of the dynamic of DNA methylation erasure occurring in early cleavage stage embryos following fertilization. However, the discrepancies in acquisition of genome-wide DNA methylation patterns in early post-implantation embryonic and extraembryonic cell lineages remain to be methodically delineated. To address this issue and further our understanding of the DNA methylation asymmetry that guides the developmental trajectory of embryonic and extraembryonic cell lineages, we established genome-wide DNA methylation profiles of mouse embryo and placenta at mid-gestation, and analyzed various publicly available developmental stage specific embryo and placenta DNA methylation datasets. Using this strategy, we uncovered that 45% of the genomic regions analyzed differ in DNA methylation status (≥20%) between mid-gestation embryo and placenta, and that these DMRs can be further divided into categories based on their levels of DNA methylation (Low; <20%, Mid; ≥20 to <80%, High; ≥80%) in the embryo and placenta. We show that the embryo and placenta acquire specific DMR categories during the early stage of the de novo DNA methylation wave, and that these DMRs persist throughout prenatal development, as well as into somatic adult tissues. Furthermore, we show that Dnmt3b primarily drives the divergence in DNA methylation levels associated with these specific DMRs and that de novo methyltransferase activity of Dnmt3b can almost entirely compensate for lack of Dnmt3a in the asymmetric establishment of embryonic and placental DMRs, but that Dnmt3a can only partially palliate the absence of Dnmt3b. However, with developmental progression, this compensatory DNA methylation mechanism becomes less effective.
Our results indicate that the kinetics of DNA methylation acquisition leading to specific embryo-placenta DMR categories is not a stepwise process occurring throughout cell fate decisions and patterning of embryonic and extraembryonic lineages, but a prompt progression in the early post-implanted conceptus. These results are in line with studies reflecting that the initiation of asymmetric DNA methylation levels begins within the trophoblast and the inner cell mass of the blastocyst (Santos et al., 2002), and becomes highly evident by the time the epiblast acquires its initial global DNA methylation patterns at E6.5 during the de novo reprogramming wave (Auclair et al. 2014, Smith et al. 2017). Our results show that the acquisition period between E4.5 and E6.5 is particularly key to establishing asymmetric DNA methylation patterns associated with mid-gestation embryo-placenta DMR classes, and that these DMR associated-patterns are long-lasting across stages of prenatal development. Since we studied cell populations derived from embryonic and placental tissues, we cannot dismiss the prevalence of cell-to-cell heterogeneity in the acquisition kinetics of specific DMR patterns. Despite this concern, our results indicate that embryonic cells have a large body of DMRs with High-levels (≥80%) and Low-levels (<20%) of methylation that remain static across development, as well as in somatic cell types (High-Mid & High-Low DMRs), whereas compared to the embryo, the placental DMRs have overall lower methylation levels and are more broadly distributed amongst methylation levels, which has also been shown in other studies where genome-wide DNA methylation profiles of placental cells were compared to other tissues and specific cell types (Schroeder et al., 2013; Chatterjee et al., 2016; Smith et al., 2017). Lower methylation levels in the placenta have been associated with reduced de novo methyltransferase activity in the ExE during the de novo reprogramming wave (Fulka et al., 2004, Santos et al., 2002). Nevertheless, we observe methylation level peaks for all DMR categories within the ExE at E6.5 before levels stabilize at E10.5. As of now, the implication of these methylation level peaks on future regulation mechanisms and methylation profiles is unknown. Moreover, it remains to be determined whether global reduction in DNA methylation marks on DMRs between the E6.5 and E10.5 extraembryonic cell lineages is stochastic or targeted, and whether it occurs through passive or active mechanisms.
We also observed an enrichment of retrotransposons (i.e., LINE, SINE, LTR) in DMRs especially in those with High-levels of methylation in the embryo and lower-levels in the placenta, whereas DMRs with Low-levels of methylation in the embryo and higher levels in the placenta are preferentially outside retrotransposons-associated sequences. Earlier findings of Chapman et al. (Chapman et al., 1984) revealed that repeat regions in the placenta appear to lack tight control of their methylation patterns, perhaps indicating that maintaining methylation, and therefore repression of these elements for genome stability and integrity, is not critical given the relatively short lifespan of this organ. However, we do observe Mid-range methylation levels (20-80%) in the placenta for a substantial portion of DMRs that are associated with retrotransposons, revealing that specific genomic regions associated with repetitive elements do need tight regulation in extraembryonic cell lineages for proper development. These results are in line with findings exposing that the deletion of genome-defense gene Tex19.1 leads to the derepression of LINE1 and compromises placental development, suggesting that disparities between retrotransposon suppression and genome-defense mechanisms might contribute to placenta dysfunction and disease (Reichmann et al., 2013).
DNMT3A and DNMT3B are required to establish proper methylation profiles on the embryonic genome during the de novo reprogramming wave, as both methyltransferase enzymes have redundant, but also specific functions. However, the activity of DNMT3B is the main contributor in the acquisition of profiles in epiblast cells, and especially commands methylation on CGIs associated with developmental genes (Auclair et al., 2014). Auclair et al. highlighted that in the absence of DNMT3B, DNMT3A was not able to counterbalance, leading to the loss of promoter-CGI methylation and gain of expression of germline genes (e.g., Sycp1, Sycp2, Mae1, Rpl101, Dmrtb1) in somatic cells of the embryo. Here, we show that the promoter of these germline genes, associated with meiotic and piRNA processes as well as other genes with similar biological functions, are highly enriched in High-Mid DMRs. We also reveal that for this particular set of High-Mid DMRs, mainly deprived of CGIs, DNMT3A is able to substantially counterbalance the lack of DNMT3B in the E6.5 epiblast and establish global DNA methylation levels, whereas in the ExE, this compensatory mechanism is rather inefficient. Globally, we show that DNMT3B is much more potent at compensating than DNMT3A in both the epiblast and ExE for all DMR categories, indicating that DNMT3B is the main de novo enzyme driving asymmetric DNA methylation patterns between the embryo and placenta. Although compensatory mechanisms have been observed in Dnmt3a or Dnmt3b-depleted conceptuses, we still do not fully understand the process as Dnmt3a and Dnmt3b have cell lineage specific expression during the peri-implantation developmental period. As development progresses, we observed that the compensation mechanism in Dnmt3a or Dnmt3b-deficient embryos remains apparent at E8.5 on most DMR categories, but is less effective as the methylation gaps increase compared to wild-type. This correlates with a developmental period where DNMT3A is now the main de novo methyltransferase enzyme in both the embryo and placenta (Okano et al., 1999, Watanabe et al., 2002), and with a compensatory activity of DNMT3A being less effective. This suggests that DNMT3B activity is critical to ensure proper establishment of DNA methylation asymmetry between the embryonic and extraembryonic cell lineages during the de novo reprogramming wave, but that DNMT3A is required during the developmental progression to safeguard methylation levels on DMR categories.
CONCLUSION
We demonstrate that asymmetry between embryo and placenta DNA methylation patterns occurs rapidly during de novo acquisition of methylation marks in the early post-implanted conceptus, and that these patterns are long-lasting across subtypes of DMRs. We also reveal that at the peri-implantation stages, de novo methyltransferase activity of DNMT3B is the main provider of asymmetric methylation marks on DMRs, and that it largely palliates the lack of DNMT3A in the epiblast and ExE. However, as development progresses, DNMT3A becomes the principal de novo methyltransferase by mid-gestation, and DNMT3B methyltransferase activity is less effective at promoting compensation. These results further underline why embryos developing without DNMT3B have severe DNA methylation defects and die at mid-gestation, whereas those without DNMT3A only die postnatally. Further investigation is required to determine the molecular mechanisms controlling the precise de novo acquisition of long-lasting methylation marks on specific DMR subtypes in the embryonic and extraembryonic cell lineages, and how errors in this process could lead to abnormal development and diseases.
COMPETING INTERESTS
No competing interests declared
FUNDING
This work was supported by a research grant from the Natural Sciences and Engineering Research Council of Canada. We acknowledge the Fonds de Recherche du Québec en Santé (S.M, L.M.L) and the Réseau Québécois en Reproduction and Fonds de recherche du Québec – Nature et technologies (K.D) for salary awards.
DATA AVAILABILITY
The data from this study have been submitted to the Gene Expression Omnibus (#GSE95610). Reviewer link: https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?token=ghsnmqoctlgjlcj&acc=GSE95610
Table S1. Annotation and DNA methylation values associated with DMRs.
Table S2. DNA methylation levels for DMR categorises across development.
Table S3. DNA methylation levels for DMR categories in various Dnmt knockout mouse models.
Table S4. Number of 100bp tiles in each category of public data that overlap with Embryo-Placenta DMRs (related to Figure 4; 5A; S4; S5; S6)
ACKNOWLEDGMENTS
We thank the McGraw lab for critical comments and suggestions, as well as Elizabeth Maurice-Elder for editing.