Abstract
Purpose
To investigate the association between DNA methylation and childhood simple obesity.
Methods
Genome-wide analysis of DNA methylation was conducted on peripheral blood samples from 41 children with simple obesity and 31 normal controls to identify differentially methylated sites (DMS). Subsequently, gene functional analysis of differentially methylated genes (DMGs) was carried out. After screening the characteristic DMGs based on specific conditions, the methylated levels of these DMS were evaluated and verified by pyrosequencing. Receiver operating characteristic (ROC) curve analysis assessed the predictive efficacy of corresponding DMGs. Finally, Pearson correlation analysis revealed the correlation between specific DMS and clinical data.
Results
The overall DNA methylation level in the obesity group was significantly lower than in normal. A total of 241 DMS were identified. Functional pathway analysis revealed that DMGs were primarily involved in lipid metabolism, carbohydrate metabolism, amino acid metabolism, human diseases, among other pathways. The characteristic DMS within the genes Transcription factor A mitochondrial (TFAM) and Piezo type mechanosensitive ion channel component 1(PIEZO1) were recognized as CpG-cg05831083 and CpG-cg14926485, respectively. Furthermore, the methylation level of CpG-cg05831083 significantly correlated with body mass index (BMI) and vitamin D.
Conclusions
Abnormal DNA methylation is closely related to childhood simple obesity. The altered methylation of CpG-cg05831083 and CpG-cg14926485 could potentially serve as biomarkers for childhood simple obesity.
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Introduction
Obesity is a chronic and complex disease caused by abnormal or excessive fat accumulation which has become a significant global public health concern. The prevalence of childhood obesity is increasing every year, and about 206 million children and adolescents aged 5–19 worldwide are projected to have obesity by 2025 [1]. Childhood obesity could lead to various health complications, including vascular endothelial damage, vascular sclerosis, left ventricular diastolic dysfunction, insulin resistance, precocious puberty, kidney injury, asthma, etc. Additionally, childhood obesity could negatively impact cognitive functions such as memory and concentration [2,3,4,5,6,7]. Overall, obesity has a profound impact on the physical and mental health of children. Moreover, childhood obesity will increase the risk of obesity-related complications in adulthood, such as hyperlipidemia, type 2 diabetes mellitus, hypertension, cardiovascular and cerebrovascular diseases, various cancers, and other diseases [8,9,10]. These conditions not only diminish the quality of life but also shorten life expectancy. Therefore, early detection and intervention for childhood obesity are crucial to minimize potential complications.
Obesity is a multifactorial disease influenced by both genetic and environmental factors [11]. Epigenetics, as an essential interface of the gene-environment interaction, is closely related to obesity [12]. DNA methylation is the most common epigenetic modification, and abnormal DNA methylation contributes to the initiation and development of multiple diseases, such as metabolic disorders, cardiovascular diseases, and cancer [13]. Previous studies have shown that the DNA methylation profile of children with obesity exhibited hypomethylation compared to normal children [14, 15]. Furthermore, it has been observed that for every 1% increase in mean DNA methylation, the body mass index (BMI) increased by 0.33 kg/m2, and the weight increased by 1.16 kg [15]. Compared to the offspring of mothers with a normal weight, the umbilical cord blood from the offspring of mothers with obesity exhibited numerous differential DNA methylated cytosine-phosphate-guanine (CpG) sites [16]. These findings highlight a connection between obesity and DNA methylation and focus primarily on adult obesity. However, the DNA methylation profiles related to childhood obesity remain incompletely understood.
This study aimed to investigate the DNA methylation profile and its alterations in peripheral blood samples from children with simple obesity and normal-weight children. It identified differentially methylated sites (DMS) specifically associated with childhood simple obesity. The results of this study not only contribute to a better understanding of the relationship between DNA methylation and obesity but also could help to recognize potential diagnostic markers and therapeutic intervention targets in childhood obesity.
Material and methods
Subjects
The subjects in this study were selected from children (6–14 years) who underwent routine physical examinations at HK Hospital of the Maternal and Child Health from January 2020 to January 2021. The Body Mass Index (BMI) (kg/m2) was computed based on their measured body weight (kg) and height (cm).
Considering variations in ethnicity, age, and gender, this study utilized specific BMI thresholds for Chinese children. Children with a BMI ≥ 97th percentile for their age and sex were classified as obese, while those with a BMI between the 15th and 85th percentile were placed in the normal group [17]. Subjects with secondary obesity resulting from metabolic diseases, endocrine conditions, hereditary disorders, other diseases, and glucocorticoid treatment were excluded. Clinical data were collected from the selected subjects.
Genome-wide DNA methylation analysis
About 3ml venous blood samples were collected from subjects after an overnight fasting of at least 8 h and stored at – 70 °C. Genomic DNA was extracted from peripheral blood lymphocyte samples utilizing a DNA purification kit (QIAGEN, USA) following the manufacturer’s instructions. The Illumina Infinium MethylationEPIC BeadChip (Illumina 850k, San Diego, CA) was applied for analyzing the whole-genome DNA methylation. The minfi R package was used to process the original data and calculate the raw beta (β) value (β = the signal intensity of methylated probes divided by the overall signal intensity). Probes with a detection p-value < 0.01 were retained.
To minimize differences within groups and improve data quality, color correction, background adjustment, and quantile normalization were performed. Subsequently, the normalized β value was extracted, and the delta β (indicating methylation difference) corresponding to each methylated site was calculated by subtracting the β value of the methylated site in the obesity group minus in the normal group. The student t-test was then applied to the data. Only sites with |delta β|> 0.1 and p-value < 0.05 were regarded as differentially methylated sites (DMS). A delta β < 0 indicates hypomethylation, while delta β > 0 means hypermethylation.
Distributions analysis of DMS regarding gene and CpG island regions
Based on the UCSC annotation, DMS were categorized into specific regions, including the promoter region (transcription start site (TSS) 200, TSS1500, 5′UTR, and 1st Exon), Body, and 3′UTR. Additionally, the DMS was also annotated for CpG island (CGI), CpG shore (within 2kb of CGI), and CpG shelf (within 2 kb-4 kb of CGI).
Functional pathway analysis of differentially methylated genes (DMG)
Using the ‘clusterprofile R package’ to carry out Gene ontology (GO) enrichment and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analysis on DMGs corresponding to the identified DMS.
Screening of characteristic DMS and DMGs
To identify characteristic DMS, we established the following criteria: (i) the mean β value between the obesity and normal group was ≥ 0.6; (ii) the DMS were in or around CGI region; (iii) the DMS were not located on sex chromosomes and were within intergenic regions. Eventually, a total of 18 DMS were recognized. However, due to unsuccessful amplification reactions, only 2 DMS were successfully designed for primer amplification, specifically targeting gene TFAM (CpG-cg05831083), and PIEZO1 (CpG-cg14926485), respectively.
Pyrosequencing validation of characteristic DMS
The EZ DNA Methylation-Gold kit was applied to transform and purify genomic DNA. Primers of each DMS were designed through PyroMark Assay Design 2.0.2 software (QIAGEN, Inc). Supplementary Table 1 displayed the sequences of primers. The methylation levels of each DMS were calculated using the PyroMark Q48 software (Version 10.6).
ROC curve analysis of characteristic DMS
To evaluate the predictive value of the characteristic DMS for childhood obesity, the area under the receiver operating characteristic (ROC) curve (AUC) was figured.
Clinical relevance analysis of characteristic DMS
The correlation between the methylation levels of the characteristic DMS and clinical variables was assessed using the Pearson correlation coefficient (r).
Statistical analysis
Statistical analysis was performed using SPSS version 25.0 (IBM). Descriptive analysis was used for general data. The Mann–Whitney test was employed for continuous variables comparison, while categorical variables were summarized as frequencies and percentages. The χ2 test was used for categoric variables. A p-value < 0.05 was considered statistically significant.
Results
Demographics and clinical features of two groups
A total of 72 subjects were included in the study, with 41 in the obesity group and 31 in the normal. Table 1 provides a summary and comparison of the demographic and specific clinical data between the two groups. The results visualized that the body weight, height, BMI, triglycerides (TG), and uric acid (UA) in the obesity group were significantly higher compared to the normal group, while vitamin D was significantly lower. However, there were no substantial differences between the two groups in terms of gender, age, total cholesterol (TC), low-density lipoprotein (LDL), Ca2+, fasting glucose (Glu), thyroid stimulating hormone (TSH), and parathyroid hormone (PTH).
Quality control results of samples and probes
After normalizing the raw data, the quality of all enrolled samples was assessed. Figure 1A shows that all samples were satisfied with the quality control standards. The PCA analysis indicated incomplete separation between the two sample groups. However, upon introducing age and gender as covariates in PCA analyses, respectively, it was observed that the two groups could be better distinguished (Fig. 1B and C). This observation suggests that there are some DMS between the obesity and normal groups and, age and gender might be important factors influencing DNA methylation levels in childhood obesity. Figure 1D indicates a good internal consistency within the two groups.
DNA methylation in children with obesity
A total of 865,721 methylated sites were identified in the two groups. The methylation levels in the obesity group and normal group displayed bimodal distribution (Fig. 2A). In comparison to the normal group, the number of unmethylated sites (0 < β ≤ 0.2) was greater in the obesity group, and the number of methylated sites (0.8 ≤ β ≤ 1) was lower (Fig. 2A). Importantly, the median β-value of the obesity group was lower than that of the normal group (p < 2e-16) (Fig. 2B), indicating a lower reduced genomic DNA methylation level in the obesity group compared to the normal group. Within the obesity group, the methylation level was lower in boys than in girls (p < 0.05) (Fig. 2C).
Among all the detected methylated sites, we identified 241 differential methylated sites (DMS), comprising 118 hypermethylated sites (delta β > 0.1, p-value < 0.05) and 123 hypomethylated sites (delta β < − 0.1, p-value < 0.05) (Fig. 3A), which were associated with 132 genes referred to as differential methylated genes (DMGs). Furthermore, the majority of DMS were found on autosome 6 (Fig. 3B).
Distribution analysis of DMS in correlation with gene features and CpG island regions
To explore the potential impact of DMS on gene expression, we conducted a comprehensive examination of their distribution. Among the 241 identified DMS, 155 were associated with gene features, including 78 hypermethylated sites and 77 hypomethylated sites, with 78 found in genic regions and the remaining in intergenic regions. Figure 3B illustrates the distribution of DMS in relation to their genomic locations. Notably, within the annotated region, the majority of DMS were situated in the gene body region (Fig. 3C). Interestingly, despite an equal count of differentially hypermethylated and hypomethylated sites in the promoter region (encompassing TSS1500, TSS200, 5'UTR, and first exon regions), there was a discernible elevation in methylation levels (mean delta β of DMS in the region was 0.0075) as opposed to low methylation (Fig. 3C) (Supplementary Table 2). Furthermore, there are a total of 79 DMS situated within CpG island (CGI) regions, consisting of 43 hypermethylated sites and 36 hypomethylated sites. Figure 3D shows the distribution of DMS in CGI regions, highlighting a notably elevated average methylation level within these genomic loci.
GO enrichment and KEGG pathway analysis
To gain deeper understand the functions of DMGs and the potential mechanistic pathways underlying the onset and progression of obesity, we performed GO enrichment and KEGG pathway analyses. GO enrichment analysis revealed associations with 74 out of the 241 DMGs, with the predominant clusters of GO terms encompassing binding, cell part, cell, cellular process, and organelle. Notably, the top 30 significantly enriched terms included functions such as ATPase activity and T-cell aggregation (Fig. 4A and B).
According to the KEGG pathway classification, a total of 51 DMGs were matched to 118 KEGG pathways. The top 3 KEGG pathways were “Environmental Information Processing, Signal transduction”, “Human disease, Cancers: Overview”, and “Organismal System, Endocrine”. Furthermore, KEGG pathway enrichment analysis highlighted 14 pathways with significant enrichment, including Cell adhesion molecules, PI3K-AKT signaling pathway, and FoxO signaling pathway (Fig. 4C and D).
Identification of the characteristic DMGs
According to our filter standards, just 2 DMS were recognized as characteristic: CpG-cg05831083 and CpG-cg14926485, corresponding to the genes TFAM and PIEZO1, respectively. And the methylation level of CpG-cg05831083 was significantly lower in the obesity group, while CpG-cg14926485 showed significantly higher (Fig. 5A and B).
Pyrosequencing results of characteristic DMS
To validate the methylation levels of characteristic differentially methylated sites selected from Illumina 850K results, we randomly chose ten obesity cases and ten normal cases from two groups to for pyrosequencing. The results of pyrosequencing demonstrated a high degree of concordance in the methylation level of TFAM CpG-cg05831083 and PIEZO1 CpG-cg14926485 with Illumina 850K results (Fig. 5A and B). Although the observed differences in the methylation levels of CpG-cg05831083 and CpG-cg14926485 between the two groups in the pyrosequencing data were not statistically significant, possibly attributed to the limited sample size, the consistent trends observed reinforce the validity of our findings from another perspective. To further evaluate the reliability of the results, we conducted correlation analyses between Illumina 850K chip data and pyrosequencing data. The correlation analysis revealed a significant positive correlation between the methylation levels of CpG-cg05831083 (r = 0.50, p-value < 0.05) and CpG-cg14926485 (r = 0.62, p-value < 0.05) in pyrosequencing results and the corresponding Illumina 850K results (Fig. 5C and D). Considering age and gender as covariates, we were able to clearly distinguish between the normal and obese groups. Consequently, utilizing age and gender as covariates, we separately examined the expression levels of differentially methylated sites. The results indicate that the expression trends of the two differentially methylated sites in both groups align with those observed without covariates (Supplementary Fig. 1). This suggests that these two distinct methylated sites are minimally influenced by age and gender, possibly having little to no impact.
The AUC of characteristic DMS
ROC curve analysis based on methylation values reveals the potential value of TFAM CpG-cg05831083 and PIEZO1 CpG-cg14926485 in predicting childhood obesity, with the AUC values of 67.6% and 65.2%, respectively (Fig. 6A and B). Specifically, TFAM CpG-cg05831083 shows high specificity and low sensitivity, indicating its accuracy in excluding non-obese individuals but lower accuracy in identifying obese children. Conversely, PIEZO1 CpG-cg14926485 exhibits high sensitivity and low specificity, suggesting its accuracy in correctly identifying obesity. When considering both sites together, the AUC increases to 74%, with a significant enhancement in specificity to 96.8%, highlighting their synergistic effect (Fig. 6C).
Overall, these findings suggest that methylation patterns of CpG-cg05831083 and CpG-cg14926485 could serve as potential biomarkers for childhood obesity, especially when considered jointly for improved predictive capability.
Correlations between characteristic DMS and clinical variables
The methylation level of TFAM CpG-cg05831083 was remarkably positively related to Vitamin D (r = 0.2643, p-value < 0.05) and inversely correlated with BMI (r = − 0.2822, p-value < 0.05). However, the methylation level of PIEZO1 CpG-cg14926485 showed no significant association with collected clinical indicators (Fig. 7).
Discussion
Obesity exhibits a strong genetic background, with an estimated heritability of approximately 75% [18]. Up to 60%–80% of the difference in body weight could be explained by heritable factors [18]. The modulation of gene expression crucial to the pathogenesis of childhood obesity, such as fatty acid synthase (Fasn), and fibroblast growth factor-21 gene (FGF21) [19, 20], is intricately linked to DNA methylation in specific genomic regions. Through genome-wide analyses, we found the global DNA methylation level in peripheral blood cells was significantly lower in children with obesity compared to normal controls. Within this context, we identified 241 methylated sites exhibiting differences exceeding 10% between the two groups. Strikingly, only 155 of these DMS were situated in genic regions, while the remaining were distributed across intergenic regions. The human genome consists of intergenic and intragenic regions. During the occurrence and development of diseases, changes in the DNA methylation status in these regions may influence gene expression through actively participating in transcriptional regulation [21,22,23]. Our research found that childhood obesity is mainly regulated by the DNA methylation of genic regions. A previous study reported that DMS, associated with obesity and epigenetic changes induced by exercise intervention, are enriched in intergenic regions [24]. In our study, we discovered that more than one-third of DMS are in the intergenic region. This implies that many regulatory elements in the intergenic region, such as enhancers and insulators, might also play a role in regulating childhood obesity.
The previous study reported that chronic low-grade inflammation observed in obesity aligns with changes in immune-related pathways [25]. Our study also found the regulation of the innate immune response was highlighted in the GO enrichment analysis, supporting the connection between immune response and obesity. KEGG pathway analysis of DMG reveals that the pathogenesis of obesity is not only related to lipid and carbohydrate metabolism but also to amino acids, cofactors, and vitamin metabolism, which are aspects often overlooked. Additionally, DMG might play a role in complications related to obesity through signaling pathways like PI3K-AKT and FoxO, contributing to issues like insulin resistance, type II diabetes, and cardiovascular disease.
Although genome-wide analysis has recognized numerous genes associated with obesity, the connection between the methylation alterations at specific CpG sites of these genes and obesity, as well as their diagnostic value for obesity remains unclear. This study successfully pinpointed two CpG loci (TFAM CpG-cg05831083 and PIEZO1 CpG-cg14926485) through pyrosequencing in individual samples. The analysis of the methylation levels of CpG-cg05831083 and CpG-cg14926485 in both obese and normal groups will help us understand the role of epigenetic changes in TFAM and PIEZO1 in obesity. Furthermore, ROC curve analysis suggested that CpG-cg05831083 and CpG-cg14926485 could provide better predictions for the occurrence of obesity.
TFAM gene is an extremely critical mitochondrial transcription factor [26]. Koh et al. found that specific overexpression of TFAM in mice muscles led to increased fatty acid β-oxidation, glycolysis, and mitochondrial metabolic rate in muscle tissues. This overexpression was accompanied by the reduction in high-fat diet-induced fat accumulation, insulin resistance, and obesity-induced [27]. Their findings indicate TFAM could play a role in regulating the occurrence of obesity. The impact of DNA methylation may depend on the genomic location, and methylation in the gene body tends to be associated with increased gene expression levels [28]. In our study, we identified differentially methylated sites, specifically CpG-cg05831083 located in the gene body region of TFAM. This site was significantly hypomethylated in the obesity group. This suggests that the methylation of CpG-cg05831083 may promote TFAM expression. If this is the case, TFAM expression in obese children is exceedingly likely to be lower than in normal, potentially weakening the function of the TFAM gene and ultimately promoting obesity. Our observation exemplifies this, showing a significant negative relationship between the methylation level of CpG-cg05831083 and BMI. Another concern is that the methylation level of CpG-cg05831083 is significantly positively correlated with Vitamin D (Vit D). Vit D, a fat-soluble vitamin, regulates processes such as adipogenesis, immune response, and oxidative stress in mature adipocytes [29]. Increasingly studies have shown an association between Vitamin D deficiency and obesity [29]. Further exploration of the relationship between CpG-cg05831083 methylation and Vitamin D could contribute to a better understanding of the roles of TFAM and Vitamin D in the occurrence and progression of obesity.
PIEZO1 gene encodes the protein which acts as an ion channel, responding to mechanical stimulation by converting it into electrical and chemical signals within cells. This enables cells to respond to changes in membrane tension [30, 31]. Wang et al. [31]. found that PIEZO1 is highly expressed in mature adipocytes. Knocking out PIEZO1 in mice fed a high-fat diet, resulted in issues with preadipocyte differentiation into mature adipocytes, larger adipocyte volume, and enlarged inflammation in white adipose tissue. These findings suggested that PIEZO1-mediated mechanical signal transduction is involved in adipocyte remodeling and function. The CpG-cg14926485 site was significantly hypermethylated in the obesity group and located in the gene body region. This hypermethylation possibly increases the PIEZO1 gene expression in childhood with obesity, contributing to its development. However, more studies are needed to uncover the potential mechanisms involved.
There were several limitations in this study. We only explored the DNA methylation profile of peripheral blood. Considering the significant tissue-specific characteristics of DNA methylation, it is necessary to research the DNA methylation profile in other tissues, such as adipose tissue. Additionally, due to a lack of redundant samples, direct links between methylation and gene expression for TFAM and PIEZO1 in obesity and normal groups could not be established. Furthermore, the causal relationship between changes in DNA methylation and obesity remains unclear. Further studies are required to clarify these issues.
Conclusions
This study revealed the close connection between childhood obesity and DNA Methylation by examining the DNA methylation profile in blood samples from children with simple obesity. The specific CpG sites, CpG-cg05831083 within TFAM and CpG-cg14926485 within PIEZO1 may serve as the potential biomarkers for diagnosing, treating, and preventing childhood simple obesity.
Data availability
The dataset generated during the current study are available in the NCBI repository (https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE221864).
Abbreviations
- AUC:
-
Area under the ROC
- BMI:
-
Body mass index
- BP:
-
Biological process
- CC:
-
Cellular component
- CGI:
-
CpG island
- CpG:
-
Cytosine-phosphate-guanine
- DMG:
-
Differentially methylated genes
- DMS:
-
Differentially methylated sites
- FGF21:
-
Fibroblast growth factor-21 gene
- Fasn:
-
Fatty acid synthase
- Glu:
-
Fasting glucose
- GO:
-
Gene ontology
- KEGG:
-
Kyoto encyclopedia of genes and genomes
- LDL:
-
Low-density lipoprotein
- MF:
-
Molecular function
- PCA:
-
Principal component analysis
- PIEZO1:
-
Piezo type mechanosensitive ion channel component 1
- PTH:
-
Parathyroid hormone
- ROC:
-
Receiver operating characteristic curve
- TC:
-
Total cholesterol
- TFAM:
-
Transcription factor A mitochondrial
- TG:
-
Triglycerides
- TSH:
-
Thyroid stimulating hormone
- TSS:
-
Transcription start site
- UA:
-
Uric acid
- Vit D:
-
Vitamin D
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Acknowledgements
We express our great gratitude to all participants in this study. We are also grateful to Shanghai Biotechnology Corporation for the technical support. We also thank the Excellent Talent Team Program of HN Province (Child Health and Early Development-1000 Days of Life).
Funding
The funders listed below play a role in the analysis of data, but no role in the design of the study, interpretation of data, and in writing the manuscript. This study was supported by Hainan Provincial Natural Science Foundation of China (Grant No.820MS168 and No. 822RC871), the Major Science and Technology Plan Project of Hainan Province (Grant No. ZDKJ2019010), the Key Research and Development Project of Hainan Province (Grant No. ZDYF2021SHFZ226) and Hainan Basic and Applied Basic Research Program (Grant No. 2019RC390). The Science and Technology Program of Hunan Province (Grant No. 2023SK4018).
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YR and PH: contributed to the conception and design of the study. YR and PH: designed methods, analyzed the data, and wrote the draft of the manuscript. XYH: participated in the refinement of design methods. LZ: helped to perform the statistical analysis. LJL designed the arrangement of figures and tables. PH and YR: collected clinical data and peripheral blood of subjects. WX, LQL, and XJH: reviewed and revised the manuscript. All authors contributed to the manuscript and approved the final manuscript.
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The study was performed in strict accordance with the ethical standards of the Declaration of Helsinki (1964) and its subsequent amendments. Approval for the present study was granted by the Medical Ethics Committee of Haikou Hospital of the Maternal and Child Health (Batch number: [2019]01001). Parents or legal guardians of all participants signed informed consent for the use of DNA methylation and clinical data for research purposes, and assent from over 12-year-old children was obtained.
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Parents or legal guardians of all participants signed informed consent for the use of DNA methylation and clinical data for research purposes, and assent from over 12-year-old children was obtained.
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Ren, Y., Huang, P., Huang, X. et al. Alterations of DNA methylation profile in peripheral blood of children with simple obesity. Health Inf Sci Syst 12, 26 (2024). https://doi.org/10.1007/s13755-024-00275-w
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DOI: https://doi.org/10.1007/s13755-024-00275-w