Screening for genes that accelerate the epigenetic aging clock in humans reveals a role for the H3K36 methyltransferase NSD1

The main goal of this study is to identify genes, mainly components of the epigenetic machinery, that can affect the rate of epigenetic aging in humans (as measured by Horvath’s epigenetic clock) [8]. For this purpose, we conducted an unbiased screen for epigenetic age acceleration (EAA) in samples from patients with developmental disorders that we could access and for which genome-wide DNA methylation data was available (Table 1, Additional file 2). Horvath’s epigenetic clock, unlike other epigenetic clocks available in the literature, works across the entire human lifespan (even in prenatal samples), and it is therefore well suited for this type of analysis [5, 8, 32]. All the DNA methylation data were generated from the blood using the Illumina HumanMethylation450 array (450K array).

The main step in the screening methodology is to compare the EAA distribution for the samples with a given developmental disorder against a robust control (Fig. 1a). In our case, the control set was obtained from human blood samples in a healthy population of individuals that matched the age range of the developmental disorder samples (Additional file 3). Given that the EAA reflects deviations between the epigenetic (biological) age and the chronological age of a sample, we would expect the EAA distributions of the controls to be centered around zero, which is equivalent to the situation when the median absolute error (MAE) of the model prediction is close to zero (see the “Methods” section). This was not the case for the samples obtained from several control batches (Additional file 1: Figure S1A, S1B), both in the case of EAA models with and without cell composition correction (CCC). It is worth noting that these results were obtained even after applying the internal normalization step against a blood gold standard suggested by Horvath [8]. Therefore, we hypothesized that part of the deviations observed might be caused by technical variance that was affecting epigenetic age predictions in the different batches.

We decided to correct for the potential batch effects by making use of the control probes present on the 450K array, which have been shown to carry information about unwanted variation from a technical source (i.e., technical variance) [33–35]. Performing principal components analysis (PCA) on the raw intensities of the control probes showed that the first two components (PCs) capture the batch structure in both controls (Fig. 1b) and cases (Additional file 1: Figure S1C). Including the first 17 PCs as part of the EAA modeling strategy (see the “Methods” section), which together accounted for 98.06% of the technical variance in controls and cases (Additional file 1: Figure S1D), significantly reduced the median absolute error (MAE) of the predictions in the controls (MAE _{without CCC} = 2.8211 years, MAE _{with CCC} = 2.7117 years, mean MAE = 2.7664 years, Fig. 1c). These values are below the original MAE reported by Horvath in his test set (3.6 years) [8].

Finally, deviations from a median EAA close to zero in some of the control batches after batch effect correction (Fig. 1d, Additional file 1: Figure S1E) could be explained by other variables, such as a small batch size or an overrepresentation of young samples (Additional file 1: Figure S1F). The latter is a consequence of the fact that Horvath’s model underestimates the epigenetic ages of older samples, a phenomenon which has also been observed by other authors [36, 37]. If there is a high number of old samples (generally > 60 years) in the control model, this can lead to a lower model slope, which would incorrectly assign negative EAA to young samples. This highlights the importance of having an age distribution in the control samples that matches that of the cases to be tested for differences in EAA.

Thus, we have shown that correcting for batch effects in the context of the epigenetic clock is important, especially when combining datasets from different sources for meta-analysis purposes. Batch effect correction is essential to remove technical variance that could affect the epigenetic age of the samples and confound biological interpretation.

Once we had corrected for potential batch effects in the data, we compared the epigenetic age acceleration (EAA) distributions between each of the developmental disorders studied and our control set. For a given sample, a positive EAA indicates that the epigenetic (biological) age of the sample is higher than the one expected for someone with that chronological age. In other words, it means that the epigenome of that person resembles the epigenome of an older individual. The opposite is true when a negative EAA is found (i.e., the epigenome looks younger than expected).

For the main screen, we selected those control samples with the same age range as the one present when aggregating all the cases (0 to 55 years), since this permits the development of a common control (background) model and to compare the statistical significance of the results across developmental disorders. Only those developmental disorders that satisfied our filtering criteria were considered for the screen (at least 5 samples available for the developmental disorder, with 2 of them presenting a chronological age ≥ 20 years, Fig. 1a, Table 1 and Additional file 2). Given that the blood composition changes with age (changes in the different cell type proportions, which can affect bulk DNA methylation measurements), we used models with and without cell composition correction (CCC), correcting for batch effects in both of them (see the “Methods” section). It is important to mention that EAA_{with CCC} is conceptually similar to the previously reported measure of “intrinsic EAA” (IEAA) [18, 38].

The results from the screen are portrayed in Fig. 2a. Most syndromes do not show evidence of accelerated epigenetic aging, but Sotos syndrome presents a clear positive EAA (median EAA_{with CCC} = + 7.64 years, median EAA_{without CCC} = + 7.16 years), with p values considerably below the significance level of 0.01 after Bonferroni correction (p value_{corrected, with CCC} = 3.40 × 10⁻⁹, p value_{corrected, without CCC} = 2.61 × 10⁻⁷). Additionally, Rett syndrome (median EAA_{with CCC} = + 2.68 years, median EAA_{without CCC} = + 2.46 years, p value_{corrected, with CCC} = 0.0069, p value_{corrected, without CCC} = 0.0251) and Kabuki syndrome (median EAA_{with CCC} = − 1.78 years, median EAA_{without CCC} = − 2.25 years, p value_{corrected, with CCC} = 0.0011, p value_{corrected, without CCC} = 0.0035) reach significance, with a positive and negative EAA, respectively. Finally, fragile X syndrome (FXS) shows a positive EAA trend (median EAA_{with CCC} = + 2.44 years, median EAA_{without CCC} = + 2.88 years) that does not reach significance in our screen (p value_{corrected, with CCC} = 0.0680, p value_{corrected, without CCC} = 0.0693).

Next, we tested the effect of changing the median age used to build the healthy control model (i.e., the median age of the controls) on the screening results (Additional file 1: Figure S2A). Sotos syndrome is robust to these changes, whilst Rett, Kabuki, and FXS are much more sensitive to the control model used. This again highlights the importance of choosing an appropriate age-matched control when testing for epigenetic age acceleration, given that Horvath’s epigenetic clock underestimates epigenetic age for advanced chronological ages [36, 37].

Moreover, all but one of the Sotos syndrome patients (19/20 = 95%) show a consistent deviation in EAA (with CCC) in the same direction (Fig. 2b, c), which is not the case for the rest of the disorders, with the exception of Rett syndrome (Additional file 1: Figure S2B). Even though the data suggest that there are already some methylomic changes at birth, the EAA seems to increase with age in the case of Sotos patients (Fig. 2c; p values for the slope coefficient of the EAA ~ Age linear regression: p value_{with CCC} = 0.00569, p value_{without CCC} = 0.00514). This could imply that at least some of the changes that normally affect the epigenome with age are happening at a faster rate in Sotos syndrome patients during their lifespan (as opposed to the idea that the Sotos epigenetic changes are only acquired during prenatal development and remain constant afterwards). Nevertheless, this increase in EAA with chronological age is highly influenced by a single patient with a chronological age of 41 years (i.e., if this patient is removed, the p values for the slope coefficient are p value_{with CCC} = 0.1785 and p value_{without CCC} = 0.1087 respectively). Therefore, more data of older Sotos patients are required to be certain about the dynamics of these methylomic changes.

In order to further validate the epigenetic age acceleration observed in Sotos patients, we calculated their epigenetic age according to other widely used epigenetic clocks: Hannum’s clock [9], Lin’s clock [40], and the skin-blood clock [41]. These analyses confirmed that Sotos patients clearly present accelerated epigenetic aging when compared with healthy individuals (with the exception of the EAA_{without CCC} in the skin-blood clock, which showed the same trend but did not reach significance; Additional file 1: Figure S2C-E).

Finally, we investigated whether Sotos syndrome leads to a higher rate of (stem) cell division in the blood when compared with our healthy population. We used a reported epigenetic mitotic clock (pcgtAge) that makes use of the fact that some CpGs in promoters that are bound by Polycomb group proteins become hypermethylated with age. This hypermethylation correlates with the number of cell divisions in the tissue and is also associated with an increase in cancer risk [39]. We found a trend suggesting that the epigenetic mitotic clock might be accelerated in Sotos patients (p value = 0.0112, Fig. 2d, e), which could explain the higher cancer predisposition reported in these patients and might relate to their overgrowth [42]. Again, this trend could be influenced by the 41-year-old Sotos patient (after removing this patient: p value = 0.0245), and more data of older Sotos patients is required to confirm this observation.

Consequently, we report that individuals with Sotos syndrome present an accelerated epigenetic age, which makes their epigenome look, on average, more than 7 years older than expected. These changes could be the consequence of a higher ticking rate of the epigenetic clock (or at least part of its machinery), with epigenetic age acceleration potentially increasing during lifespan: the youngest Sotos patient (1.6 years) has an EAA_{with CCC} = 5.43 years and the oldest (41 years) has an EAA_{with CCC} = 24.53 years. Additionally, Rett syndrome, Kabuki syndrome, and fragile X syndrome could also have their epigenetic ages affected, but more evidence is required to be certain about this conclusion.

Sotos syndrome is caused by loss-of-function heterozygous mutations in the NSD1 gene, a histone H3K36 methyltransferase [43, 44]. These mutations lead to a specific DNA methylation signature in Sotos patients, potentially due to the crosstalk between the histone and DNA methylation machinery [44]. In order to gain a more detailed picture of the reported epigenetic age acceleration, we decided to compare the genome-wide (or at least array-wide) changes observed in the methylome during aging with those observed in Sotos syndrome. For this purpose, we identified differentially methylated positions (DMPs) for both conditions (see the “Methods” section). Aging DMPs (aDMPs), were composed almost equally of CpG sites that gain methylation with age (i.e., become hypermethylated, 51.69%) and CpG sites that lose methylation with age (i.e., become hypomethylated, 48.31%, barplot in Fig. 3a), a picture that resembles previous studies [45]. On the contrary, DMPs in Sotos were dominated by CpGs that decrease their methylation level in individuals with the syndrome (i.e., hypomethylated, 99.27%, barplot in Fig. 3a), consistent with previous reports [44].

Then, we compared the intersections between the hypermethylated and hypomethylated DMPs in aging and Sotos. Most of the DMPs were specific for aging or Sotos (i.e., they did not overlap), but a subset of them was shared (table in Fig. 3a). Interestingly, there were 1728 DMPs that became hypomethylated both during aging and in Sotos (Hypo-Hypo DMPs). This subset of DMPs is of special interest because it could be used to understand in more depth some of the mechanisms that drive hypomethylation during physiological aging. Thus, we tested whether the different subsets of DMPs are found in specific genomic contexts (Additional file 1: Figure S3A,B). DMPs that are hypomethylated during aging and in Sotos were both enriched (odds ratio > 1) in enhancer categories (such as “active enhancer 1” or “weak enhancer 1”, see the chromatin state model used, from the K562 cell line, in the “Methods” section) and depleted (odds ratio < 1) for active transcription categories (such as “active TSS” or “strong transcription”), which was also observed in the “Hypo-Hypo DMPs” subset (Fig. 3b). Interestingly, age-related hypomethylation in enhancers seems to be a characteristic of both humans [46, 47] and mice [25]. Furthermore, both de novo DNA methyltransferases (DNMT3A and DNMT3B) have been shown to bind in an H3K36me3-dependent manner to active enhancers [48], consistent with our results.

When looking at the levels of total RNA expression (depleted for rRNA) in the blood, we confirmed a significant reduction in the RNA levels around these hypomethylated DMPs when compared with the control sets (Fig. 3c, see the “Methods” section for more details on how the control sets were defined). Interestingly, hypomethylated DMPs in both aging and Sotos were depleted from the gene bodies (Fig. 3b) and were located in areas with lower levels of H3K36me3 when compared with the control sets (Fig. 3d, see Additional file 1: Figure S3B for a comprehensive comparison of all the DMPs subsets). Moreover, hypomethylated aDMPs and hypomethylated Sotos DMPs were both generally enriched or depleted for the same histone marks in the blood (Additional file 1: Figure S3B), which adds weight to the hypothesis that they share the same genomic context and could become hypomethylated through similar molecular mechanisms.

Intriguingly, we also identified a subset of DMPs (2550) that were hypermethylated during aging and hypomethylated in Sotos (Fig. 3a). These “Hyper-Hypo DMPs” seem to be enriched for categories such as “bivalent promoter” and ‘repressed polycomb’ (Additional file 1: Figure S3A), which are normally associated with developmental genes [49, 50]. These categories are also a defining characteristic of the hypermethylated aDMPs, highlighting that even though the direction of the DNA methylation changes is different in some aging and Sotos DMPs, the genomic context in which they happen is shared.

Finally, we looked at the DNA methylation patterns in the 353 Horvath’s epigenetic clock CpG sites for the Sotos samples. For each clock CpG site, we modeled the changes of DNA methylation during the lifespan in the healthy control individuals and then calculated the deviations from these patterns for the Sotos samples (Additional file: Figure S3C, see the “” section). As expected, the landscape of clock CpG sites is dominated by hypomethylation in the Sotos samples, although only a small fraction of the clock CpG sites seem to be significantly affected (Additional file: Figure S3D, Additional file). Overall, we confirmed the trends reported for the genome-wide analysis (Additional file: Figure S3E-G). However, given the much smaller number of CpG sites to consider in this analysis, very few comparisons reached significance. 1 Methods 1 6 1

We have demonstrated that the aging process and Sotos syndrome share a subset of hypomethylated CpG sites that are characterized by an enrichment in enhancer features and a depletion of active transcription activity. This highlights the usefulness of developmental disorders as a model to study the mechanisms that may drive the changes in the methylome with age, since they permit stratification of the aging DMPs into different functional categories that are associated with alterations in the function of specific genes and hence specific molecular components of the epigenetic aging clock.

Shannon entropy can be used in the context of DNA methylation analysis to estimate the information content stored in a given set of CpG sites. Shannon entropy is minimized when the methylation levels of all the CpG sites are either 0% or 100% and maximized when all of them are 50% (see the “Methods” section). Previous reports have shown that the Shannon entropy associated with the methylome increases with age, which implies that the epigenome loses information content [9, 12, 46]. We confirmed this genome-wide effect (i.e., considering all the CpG sites that passed our pre-processing pipeline) in our healthy samples, where we observed a positive Spearman correlation coefficient between chronological age and genome-wide Shannon entropy of 0.3984 (p value = 3.21 × 10⁻⁴⁴). This result was robust when removing outlier batches (Additional file 1: Figure S4C). Next, we tested whether Sotos patients present genome-wide Shannon entropy acceleration, i.e., deviations from the expected genome-wide Shannon entropy for their age (see the “Methods” section). Despite detailed analysis, we did not find evidence that this was the case when looking genome-wide (p value = 0.71, Fig. 4a, b; Additional file 1: Figure S4A). This conclusion held when the comparison was performed inside the batch that contained the Sotos samples (GSE74432↗), therefore providing evidence that it is not confounded by batch effect (p value = 0.73, Additional file 1: Figure S4E).

When we considered only the 353 clock CpG sites for the entropy calculations, the picture was different. Shannon entropy for the 353 clock sites slightly decreased with age in the controls when we included all the batches, showing the opposite direction when compared with the genome-wide entropy (Spearman correlation coefficient = − 0.1223, p value = 3.8166 × 10⁻⁵, Fig. 4c). However, when we removed the “Europe” batch (which was an outlier even after pre-processing, Additional file 1: Figure S4D), this trend was reversed and we observed a weak increase of clock Shannon entropy with age (Spearman correlation coefficient = 0.1048, p value = 8.6245 × 10⁻⁵). This shows that Shannon entropy calculations are very sensitive to batch effects, especially when considering a small number of CpG sites, and the results must be interpreted carefully.

Interestingly, the mean Shannon entropy across all the control samples was higher in the epigenetic clock sites (mean = 0.4726, Fig. 4c) with respect to the genome-wide entropy (mean = 0.3913, Fig. 4a). Sotos syndrome patients displayed a lower clock Shannon entropy when compared with the control (p value = 5.0449 × 10⁻¹², Fig. 4d, Additional file 1: Figure S4B), which is probably driven by the hypomethylation of the clock CpG sites. Importantly, this conclusion held when the comparison was performed inside the batch that contained the Sotos samples (GSE74432↗), again providing evidence that it is not confounded by batch effect (p value = 7.3757 × 10⁻¹¹, Additional file 1: Figure S4F). Furthermore, this highlights that the Horvath clock sites could have slightly different characteristics in terms of the methylation entropy associated with them when compared with the genome as a whole, something that to our knowledge has not been reported before.

We collected DNA methylation data generated with the Illumina Infinium HumanMethylation450 BeadChip (450K array) from human blood. In the case of the developmental disorder samples, we combined public data with the data generated in-house for other clinical studies (Table 1, Additional file 2) [31]. We took all the data for developmental disorders that we could find in order to perform unbiased screening. The healthy samples used to build the control were mainly obtained from public sources (Additional file 3). Basic metadata (including the chronological age) was also stored. All the mutations in the developmental disorder samples were manually curated using Variant Effect Predictor [81] in the GRCh37 (hg19) human genome assembly. Those samples with a variant of unknown significance that had the characteristic DNA methylation signature of the disease were also included (they are labelled as “YES_predicted” in Additional file 2). In the case of fragile X syndrome (FXS), only male samples with full mutation (> 200 repeats) [80] were included in the final screen. As a consequence, only the samples with a clear molecular and clinical diagnosis were kept for the final screen.

Raw DNA methylation array data (IDAT files) were processed using the minfi R package [82]. Raw data were background-corrected using noob [83] before calculating the beta values. In the case of the beta values which are input to Horvath’s model, we observed that background correction did not have a major impact in the final predictions of epigenetic age acceleration in the control as long as we corrected for batch effects (Fig. 1c, Additional file 1: Figure S5A). We decided to keep the noob background correction step for consistency with the rest of the pipelines. Epigenetic age (DNAmAge) was calculated using the code from Horvath, which includes an internal normalization step against a blood gold standard [8]. The scripts are available in our GitHub repository (https://github.com/demh/epigenetic_ageing_clock↗) for the use of the community [84].

Quality control (QC) was performed in all samples. Following the guidelines from the minfi package [82], only those samples that satisfied the following criteria were kept for the analysis: the sex predicted from the DNA methylation data was the same as the reported sex in the metadata, they passed BMIQ normalization and medianlog2M+medianlog2U2≥10.5, where M is the methylated intensity and U the unmethylated intensity for the array probes.

In order to correct for batch effects that could confound the conclusions from our analysis, we decided to make use of the control probes available in the 450K array. These probes capture only the technical variance in negative controls and different steps of the array protocol, such as bisulfite conversion, staining or hybridization [34, 85]. We performed PCA (with centering but not scaling using the prcomp function in R) on the raw intensities of the control probes (847 probes × 2 channels = 1694 intensity values) for all our controls (N = 2218) and cases (N = 666) that passed QC (Fig. 1a). Including the technical PCs as covariates in the models to calculate epigenetic age acceleration (EAA) improved the error from the predictions in the controls (Fig. 1c, Additional file 1: Figure S5A). The optimal number of PCs was found by making use of the findElbow function from [86].

The proportions of different blood cell types change with age and this can affect the methylation profiles of the samples. Therefore, when calculating the epigenetic age acceleration, it is important to compare the models with and without cell type proportions included as covariates [38]. Cell type proportions can be estimated from DNA methylation data using different deconvolution algorithms [87]. In the context of the epigenetic clock, most of the studies have used the Houseman method [88]. We have benchmarked different reference-based deconvolution strategies (combining different pre-processing steps, references, and deconvolution algorithms) against a gold standard dataset (GSE77797↗) [89]. Our results suggest that using the IDOL strategy [89] to build the blood reference (from the Reinius et al. dataset, GSE35069↗) [90], together with the Houseman algorithm [88] and some pre-processing steps (noob background correction, probe filtering, BMIQ normalization), leads to the best cell type proportions estimates, i.e., those that minimize the deviations between our estimates and the real cell type composition of the samples in the gold standard dataset (Additional file 1: Figure S5B, Additional file 4). We used the epidish function from the EpiDISH R package [91] for these purposes.

Only those developmental disorders for which we had at least 5 samples, with 2 of them with an age ≥ 20 years, were included in the main screen (N = 367). Healthy samples that matched the age range of those disorders (0–55 years, N = 1128) were used to train the following linear models (the control models):

where DNAmAge is the epigenetic age calculated using Horvath’s model [8], Age is the chronological age, PCN is the Nth technical PC obtained from the control probes (N = 17 was the optimal, Fig. 1c) and Gran, CD4T, CD8T, B, Mono, and NK are the different proportions of the blood cell types as estimated with our deconvolution strategy. The linear models were fitted in R with the lm function, which uses least-squares.

The residuals from a control model represent the epigenetic age acceleration (EAA) for the different healthy samples, which should be centered around zero after batch effect correction (Additional file 1: Figure S1E, Fig. 1d). Then, the median absolute error (MAE) can be calculated as (Fig. 1c, Additional file 1: Figure S5A):

where EAA_i is the epigenetic age acceleration for a healthy sample from the control.

Once the control models are established, we can calculate the EAA for the different samples with a developmental disorder (cases) by taking the difference between the epigenetic age (DNAmAge) for the case sample and the predicted value from the corresponding control model (with or without cell composition correction). Finally, the distributions of the EAA for the different developmental disorders were compared against the EAA distribution for the healthy controls using a two-sided Wilcoxon’s test. p values were adjusted for multiple testing using Bonferroni correction and a significance level of α = 0.01 was applied.

A similar approach was used in the case of the other epigenetic clocks assessed. The linear coefficients for the different probes were obtained from the original publications [9, 40, 41]. In the case of the skin-blood clock, the same age transformation employed for the Horvath’s clock was applied [41]. Due to our filtering criteria, some array probes were missing, which could slightly affect the predictions of the different epigenetic clocks: Hannum’s clock [9] (68/71 probes available), Lin’s clock [40] (97/99 probes available), and the skin-blood clock [41] (385/391 probes available). This may be the reason behind the offset observed, particularly prominent in the predictions of Lin’s clock (Additional file 1: Figure S2C-E). Nevertheless, this bias is present in both Sotos and control samples, and therefore, it is unlikely that it affects the main conclusions.

Raw DNA methylation data (IDAT files) was background-corrected using noob [83]. Next, we filtered out the probes associated with SNPs, cross-reactive probes [92], and probes from the sex chromosomes, before performing BMIQ intra-array normalization to correct for the bias in probe design [93]. Then, we calculated pcgtAge as the average of the beta values for the probes that constitute the epigenetic mitotic clock [39]. It is worth noting that only 378 out of the 385 probes were left after our filtering criteria.

Shannon entropy was calculated as previously described [9]:

where β_i represents the methylation beta value for the ith probe (CpG site) in the array, N = 428,266 for the genome-wide entropy, and N = 353 for Horvath clock sites entropy.

In order to calculate the pcgtAge and Shannon entropy acceleration, we followed a similar strategy to the one reported for EAA with CCC, fitting the following linear models:

It is worth mentioning that we observed a remarkable effect of the batch on the Shannon entropy calculations, which generated high entropy variability for a given age (Additional file: Figure S4C,D). Thus, accounting for technical variation becomes crucial when assessing this type of data, even after background correction, probe filtering, and BMIQ normalization. 1

DMPs were identified using a modified version of the dmpFinder function in the minfi R package [82], where we accounted for other covariates. The aging DMPs (aDMPs) were calculated using the control samples that were included in the screen (age range 0–55 years, N = 1128) and the following linear model (p values and regression coefficients were extracted for the Age covariate):

where β_i represents the methylation beta value for the ith probe (CpG site) in the array.

The Sotos DMPs were calculated by comparing the Sotos samples (N = 20) against the control samples (N = 51) from the same dataset (GSE74432↗) [44] using the following linear model (p values and regression coefficients were extracted for the Disease_status covariate):

We selected as our final DMPs those CpG probes that survived our analysis after Bonferroni multiple testing correction with a significance level of α = 0.01.

Different (epi) genomic features were extracted for the CpG sites of interest. All the data were mapped to the hg19 assembly of the human genome.

The continuous features were calculated by extracting the mean value in a window of ± 200 bp from the CpG site coordinate using the pyBigWig package [94]. We chose this window value based on the methylation correlation observed between neighboring CpG sites in previous studies [95]. The continuous features included (Additional file 5) the following:

where RNA_i represents the RNA signal (that then needs to be scaled to obtain the “normalised RNA expression” or NRE) for the ith CpG site.

The categorical features were obtained by looking at the overlap (using the pybedtools package) [98] of the CpG sites with the following:

We compared the different genomic features for each one of our subsets of CpG sites (hypomethylated aDMPs, hypomethylated Sotos DMPs) against a control set. This control set was composed of all the probes from the background set from which we removed the subset that we were testing. In the case of the comparisons against the 353 Horvath clock CpG sites, a background set of the 21,368 (21K) CpG probes used to train the original Horvath model [8] was used. In the case of the genome-wide comparisons for aging and Sotos syndrome, a background set containing all 428,266 probes that passed our pre-processing pipeline (450K) was used.

The distributions of the scores from the continuous features were compared using a two-sided Wilcoxon’s test. In the case of the categorical features, we tested for enrichment using Fisher’s exact test.

To compare the beta values of the Horvath clock CpG sites between our healthy samples and Sotos samples, we fitted the following linear models in the healthy samples (control CpG models, Additional file 1: Figure S3C, Additional file 6):

where β_i represents the methylation beta values for the ith probe (CpG site) in the 353 CpG clock sites. The Age² term allows accounting for non-linear relationships between chronological age and the beta values.

Finally, we calculated the difference between the beta values in Sotos samples and the predictions from the control CpG models and displayed these differences in an annotated heatmap (Additional file 1: Figure S3D).

All the code used to perform the analyses here presented can be found in our GitHub repository (https://github.com/demh/epigenetic_ageing_clock↗) under GNU General Public License v3.0 [84].

The review history is available at Additional file. 7

Part of the DNA methylation data and metadata was obtained from the GEO public repository and are available under the following accession numbers: GSE104812↗ [104], GSE111629↗ [105], GSE116300↗ [106], GSE35069↗ (to build the reference for cell composition estimation) [107], GSE40279↗ [108], GSE41273↗ [109], GSE42861↗ [110], GSE51032↗ [111], GSE55491↗ [112], GSE59065↗ [113], GSE61496↗ [114], GSE74432↗ [115], GSE77797↗ (gold-standard for cell composition estimation) [116], GSE81961↗ [117], and GSE97362↗ [118]. The rest of the raw DNA methylation data (Europe, Feb_2016, Jun_2015, Mar_2014, May_2015, May_2016, Nov_2015, Oct_2014) are not publicly available at the time of the study as part of the conditions of the research ethical approval of the study. All the code used to perform the analyses here presented can be found in the following GitHub repository (https://github.com/demh/epigenetic_ageing_clock↗) under the GNU General Public License v3.0 [84].