Your search keyword '"Methylation age"' showing total 21 results

1. Complementary value of molecular, phenotypic, and functional aging biomarkers in dementia prediction

Author

Engvig, Andreas, Kalleberg, Karl Trygve, Westlye, Lars T., and Leonardsen, Esten Høyland

Published

2024

2. The effect of polyphenols on DNA methylation-assessed biological age attenuation: the DIRECT PLUS randomized controlled trial

Author

Anat Yaskolka Meir, Maria Keller, Anne Hoffmann, Ehud Rinott, Gal Tsaban, Alon Kaplan, Hila Zelicha, Tobias Hagemann, Uta Ceglarek, Berend Isermann, Ilan Shelef, Matthias Blüher, Michael Stumvoll, Jun Li, Sven-Bastian Haange, Beatrice Engelmann, Ulrike Rolle-Kampczyk, Martin von Bergen, Frank B. Hu, Meir J. Stampfer, Peter Kovacs, Liming Liang, and Iris Shai

Subjects

Epigenetics, Weight loss, Green-MED diet, Urolithins, Tyrosol, Methylation age, Medicine

Abstract

Abstract Background Epigenetic age is an estimator of biological age based on DNA methylation; its discrepancy from chronologic age warrants further investigation. We recently reported that greater polyphenol intake benefitted ectopic fats, brain function, and gut microbiota profile, corresponding with elevated urine polyphenols. The effect of polyphenol-rich dietary interventions on biological aging is yet to be determined. Methods We calculated different biological aging epigenetic clocks of different generations (Horvath2013, Hannum2013, Li2018, Horvath skin and blood2018, PhenoAge2018, PCGrimAge2022), their corresponding age and intrinsic age accelerations, and DunedinPACE, all based on DNA methylation (Illumina EPIC array; pre-specified secondary outcome) for 256 participants with abdominal obesity or dyslipidemia, before and after the 18-month DIRECT PLUS randomized controlled trial. Three interventions were assigned: healthy dietary guidelines, a Mediterranean (MED) diet, and a polyphenol-rich, low-red/processed meat Green-MED diet. Both MED groups consumed 28 g walnuts/day (+ 440 mg/day polyphenols). The Green-MED group consumed green tea (3–4 cups/day) and Mankai (Wolffia globosa strain) 500-ml green shake (+ 800 mg/day polyphenols). Adherence to the Green-MED diet was assessed by questionnaire and urine polyphenols metabolomics (high-performance liquid chromatography quadrupole time of flight). Results Baseline chronological age (51.3 ± 10.6 years) was significantly correlated with all methylation age (mAge) clocks with correlations ranging from 0.83 to 0.95; p

Published

2023

3. The effect of polyphenols on DNA methylation-assessed biological age attenuation: the DIRECT PLUS randomized controlled trial.

Author

Yaskolka Meir, Anat, Keller, Maria, Hoffmann, Anne, Rinott, Ehud, Tsaban, Gal, Kaplan, Alon, Zelicha, Hila, Hagemann, Tobias, Ceglarek, Uta, Isermann, Berend, Shelef, Ilan, Blüher, Matthias, Stumvoll, Michael, Li, Jun, Haange, Sven-Bastian, Engelmann, Beatrice, Rolle-Kampczyk, Ulrike, von Bergen, Martin, Hu, Frank B., and Stampfer, Meir J.

Subjects

*MEDITERRANEAN diet, *POLYPHENOLS, *SKIN aging, *HIGH performance liquid chromatography, *AGE, *NUTRITION surveys, *DNA methylation, *GREEN tea

Abstract

Background: Epigenetic age is an estimator of biological age based on DNA methylation; its discrepancy from chronologic age warrants further investigation. We recently reported that greater polyphenol intake benefitted ectopic fats, brain function, and gut microbiota profile, corresponding with elevated urine polyphenols. The effect of polyphenol-rich dietary interventions on biological aging is yet to be determined. Methods: We calculated different biological aging epigenetic clocks of different generations (Horvath2013, Hannum2013, Li2018, Horvath skin and blood2018, PhenoAge2018, PCGrimAge2022), their corresponding age and intrinsic age accelerations, and DunedinPACE, all based on DNA methylation (Illumina EPIC array; pre-specified secondary outcome) for 256 participants with abdominal obesity or dyslipidemia, before and after the 18-month DIRECT PLUS randomized controlled trial. Three interventions were assigned: healthy dietary guidelines, a Mediterranean (MED) diet, and a polyphenol-rich, low-red/processed meat Green-MED diet. Both MED groups consumed 28 g walnuts/day (+ 440 mg/day polyphenols). The Green-MED group consumed green tea (3–4 cups/day) and Mankai (Wolffia globosa strain) 500-ml green shake (+ 800 mg/day polyphenols). Adherence to the Green-MED diet was assessed by questionnaire and urine polyphenols metabolomics (high-performance liquid chromatography quadrupole time of flight). Results: Baseline chronological age (51.3 ± 10.6 years) was significantly correlated with all methylation age (mAge) clocks with correlations ranging from 0.83 to 0.95; p < 2.2e − 16 for all. While all interventions did not differ in terms of changes between mAge clocks, greater Green-Med diet adherence was associated with a lower 18-month relative change (i.e., greater mAge attenuation) in Li and Hannum mAge (beta = − 0.41, p = 0.004 and beta = − 0.38, p = 0.03, respectively; multivariate models). Greater Li mAge attenuation (multivariate models adjusted for age, sex, baseline mAge, and weight loss) was mostly affected by higher intake of Mankai (beta = − 1.8; p = 0.061) and green tea (beta = − 1.57; p = 0.0016) and corresponded with elevated urine polyphenols: hydroxytyrosol, tyrosol, and urolithin C (p < 0.05 for all) and urolithin A (p = 0.08), highly common in green plants. Overall, participants undergoing either MED-style diet had ~ 8.9 months favorable difference between the observed and expected Li mAge at the end of the intervention (p = 0.02). Conclusions: This study showed that MED and green-MED diets with increased polyphenols intake, such as green tea and Mankai, are inversely associated with biological aging. To the best of our knowledge, this is the first clinical trial to indicate a potential link between polyphenol intake, urine polyphenols, and biological aging. Trial registration: ClinicalTrials.gov, NCT03020186. [ABSTRACT FROM AUTHOR]

Published

2023

4. Childhood sleep health and epigenetic age acceleration in late adolescence: Cross‐sectional and longitudinal analyses.

Author

Balfour, David, Melton, Phillip E., McVeigh, Joanne A., Huang, Rae‐Chi, Eastwood, Peter R., Wanstall, Sian, Reynolds, Amy C., and Cohen‐Woods, Sarah

Subjects

*SOMNOLOGY, *ADOLESCENCE, *CROSS-sectional method, *EPIGENETICS, *SLEEP

Abstract

Aim: Investigate if childhood measures of sleep health are associated with epigenetic age acceleration in late adolescence. Methods: Parent‐reported sleep trajectories from age 5 to 17, self‐reported sleep problems at age 17, and six measures of epigenetic age acceleration at age 17 were studied in 1192 young Australians from the Raine Study Gen2. Results: There was no evidence for a relationship between the parent‐reported sleep trajectories and epigenetic age acceleration (p ≥ 0.17). There was a positive cross‐sectional relationship between self‐reported sleep problem score and intrinsic epigenetic age acceleration at age 17 (b = 0.14, p = 0.04), which was attenuated after controlling for depressive symptom score at the same age (b = 0.08, p = 0.34). Follow‐up analyses suggested this finding may represent greater overtiredness and intrinsic epigenetic age acceleration in adolescents with higher depressive symptoms. Conclusion: There was no evidence for a relationship between self‐ or parent‐reported sleep health and epigenetic age acceleration in late adolescence after adjusting for depressive symptoms. Mental health should be considered as a potential confounding variable in future research on sleep and epigenetic age acceleration, particularly if subjective measures of sleep are used. [ABSTRACT FROM AUTHOR]

Published

2023

5. Telomere length and epigenetic clocks as markers of cellular aging: a comparative study.

Author

Pearce, Emily E., Alsaggaf, Rotana, Katta, Shilpa, Dagnall, Casey, Aubert, Geraldine, Hicks, Belynda D., Spellman, Stephen R., Savage, Sharon A., Horvath, Steve, and Gadalla, Shahinaz M.

Subjects

CELLULAR aging, TELOMERES, EPIGENETICS, IMMUNOSENESCENCE, BIOMARKERS

Abstract

Telomere length (TL) and DNA methylation–based epigenetic clocks are markers of biological age, but the relationship between the two is not fully understood. Here, we used multivariable regression models to evaluate the relationships between leukocyte TL (LTL; measured by qPCR [n = 635] or flow FISH [n = 144]) and five epigenetic clocks (Hannum, DNAmAge pan-tissue, PhenoAge, SkinBlood, or GrimAge clocks), or their epigenetic age acceleration measures in healthy adults (age 19–61 years). LTL showed statistically significant negative correlations with all clocks (qPCR: r = − 0.26 to − 0.32; flow FISH: r = − 0.34 to − 0.49; p < 0.001 for all). Yet, models adjusted for age, sex, and race revealed significant associations between three of five clocks (PhenoAge, GrimAge, and Hannum clocks) and LTL by flow FISH (p < 0.01 for all) or qPCR (p < 0.001 for all). Significant associations between age acceleration measures for the same three clocks and qPCR or flow FISH TL were also found (p < 0.01 for all). Additionally, LTL (by qPCR or flow FISH) showed significant associations with extrinsic epigenetic age acceleration (EEAA: p < 0.0001 for both), but not intrinsic epigenetic age acceleration (IEAA; p > 0.05 for both). In conclusion, the relationships between LTL and epigenetic clocks were limited to clocks reflecting phenotypic age. The observed association between LTL and EEAA reflects the ability of both measures to detect immunosenescence. The observed modest correlations between LTL and epigenetic clocks highlight a possible benefit from incorporating both measures in understanding disease etiology and prognosis. [ABSTRACT FROM AUTHOR]

Published

2022

6. Seven-CpG DNA Methylation Age Determined by Single Nucleotide Primer Extension and Illumina's Infinium MethylationEPIC Array Provide Highly Comparable Results.

Author

Vetter, Valentin Max, Kalies, Christian Humberto, Sommerer, Yasmine, Bertram, Lars, and Demuth, Ilja

Subjects

BLAND-Altman plot, DNA methylation, AGE, DATA conversion, INDEPENDENT sets, GUANINE

Abstract

DNA methylation age (DNAm age, epigenetic clock) is a novel and promising biomarker of aging. It is calculated from the methylation fraction of specific cytosine phosphate guanine sites (CpG sites) of genomic DNA. Several groups have proposed epigenetic clock algorithms and these differ mostly regarding the number and location of the CpG sites considered and the method used to assess the methylation status. Most epigenetic clocks are based on a large number of CpGs, e.g. as measured by DNAm microarrays. We have recently evaluated an epigenetic clock based on the methylation fraction of seven CpGs that were determined by methylation-sensitive single nucleotide primer extension (MS-SNuPE). This method is more cost-effective when compared to array-based technologies as only a few CpGs need to be examined. However, there is only little data on the correspondence in epigenetic age estimation using the 7-CpG clock and other algorithms. To bridge this gap, in this study we measured the 7-CpG DNAm age using two methods, via MS-SNuPE and via the MethylationEPIC array, in a sample of 1,058 participants of the Berlin Aging Study II (BASE-II), assessed as part of the GendAge study. On average, participants were 75.6 years old (SD: 3.7, age range: 64.9–90.0, 52.6% female). Agreement between methods was assessed by Bland-Altman plots. DNAm age was highly correlated between methods (Pearson's r = 0.9) and Bland-Altman plots showed a difference of 3.1 years. DNAm age by the 7-CpG formula was 71.2 years (SD: 6.9 years, SNuPE) and 68.1 years (SD: 6.4 years, EPIC array). The mean of difference in methylation fraction between methods for the seven individual CpG sites was between 0.7 and 13 percent. To allow direct conversion of DNAm age obtained from both methods we developed an adjustment formula with a randomly selected training set of 529 participants using linear regression. After conversion of the Illumina data in a second and independent validation set, the adjusted DNAm age was 71.44 years (SD: 6.1 years, n = 529). In summary, we found the results of DNAm clocks to be highly comparable. Furthermore, we developed an adjustment formula that allows for direct conversion of DNAm age estimates between methods and enables one singular clock to be used in studies that employ either the Illumina or the SNuPE method. [ABSTRACT FROM AUTHOR]

Published

2022

7. Seven-CpG DNA Methylation Age Determined by Single Nucleotide Primer Extension and Illumina’s Infinium MethylationEPIC Array Provide Highly Comparable Results

Author

Valentin Max Vetter, Christian Humberto Kalies, Yasmine Sommerer, Lars Bertram, and Ilja Demuth

Subjects

epigenetic clock, biological age, aging, methylation age, single-nucleotide primer extension assay, Berlin Aging Study II, Genetics, QH426-470

Abstract

DNA methylation age (DNAm age, epigenetic clock) is a novel and promising biomarker of aging. It is calculated from the methylation fraction of specific cytosine phosphate guanine sites (CpG sites) of genomic DNA. Several groups have proposed epigenetic clock algorithms and these differ mostly regarding the number and location of the CpG sites considered and the method used to assess the methylation status. Most epigenetic clocks are based on a large number of CpGs, e.g. as measured by DNAm microarrays. We have recently evaluated an epigenetic clock based on the methylation fraction of seven CpGs that were determined by methylation-sensitive single nucleotide primer extension (MS-SNuPE). This method is more cost-effective when compared to array-based technologies as only a few CpGs need to be examined. However, there is only little data on the correspondence in epigenetic age estimation using the 7-CpG clock and other algorithms. To bridge this gap, in this study we measured the 7-CpG DNAm age using two methods, via MS-SNuPE and via the MethylationEPIC array, in a sample of 1,058 participants of the Berlin Aging Study II (BASE-II), assessed as part of the GendAge study. On average, participants were 75.6 years old (SD: 3.7, age range: 64.9–90.0, 52.6% female). Agreement between methods was assessed by Bland-Altman plots. DNAm age was highly correlated between methods (Pearson’s r = 0.9) and Bland-Altman plots showed a difference of 3.1 years. DNAm age by the 7-CpG formula was 71.2 years (SD: 6.9 years, SNuPE) and 68.1 years (SD: 6.4 years, EPIC array). The mean of difference in methylation fraction between methods for the seven individual CpG sites was between 0.7 and 13 percent. To allow direct conversion of DNAm age obtained from both methods we developed an adjustment formula with a randomly selected training set of 529 participants using linear regression. After conversion of the Illumina data in a second and independent validation set, the adjusted DNAm age was 71.44 years (SD: 6.1 years, n = 529). In summary, we found the results of DNAm clocks to be highly comparable. Furthermore, we developed an adjustment formula that allows for direct conversion of DNAm age estimates between methods and enables one singular clock to be used in studies that employ either the Illumina or the SNuPE method.

Published

2022

8. Weight management intervention identifies association of decreased DNA methylation age with improved functional age measures in older adults with obesity.

Author

Petersen, Curtis L., Christensen, Brock C., and Batsis, John A.

Subjects

*DNA methylation, *OLDER people, *REGULATION of body weight, *AGING, *WALKING speed, *EPIGENOMICS, *DNA

Abstract

Background: Assessing functional ability is an important component of understanding healthy aging. Objective measures of functional ability include grip strength, gait speed, sit-to-stand time, and 6-min walk distance. Using samples from a weight loss clinical trial in older adults with obesity, we examined the association between changes in physical function and DNA-methylation-based biological age at baseline and 12 weeks in 16 individuals. Peripheral blood DNA methylation was measured (pre/post) with the Illumina HumanMethylationEPIC array and the Hannum, Horvath, and PhenoAge DNA methylation age clocks were used. Linear regression models adjusted for chronological age and sex tested the relationship between DNA methylation age and grip strength, gait speed, sit-to-stand, and 6-min walk. Results: Participant mean weight loss was 4.6 kg, and DNA methylation age decreased 0.8, 1.1, and 0.5 years using the Hannum, Horvath, and PhenoAge DNA methylation clocks respectively. Mean grip strength increased 3.2 kg. Decreased Hannum methylation age was significantly associated with increased grip strength (β = −0.30, p = 0.04), and increased gait speed (β = 0.02, p = 0.05), in adjusted models. Similarly, decreased methylation age using the PhenoAge clock was associated with significantly increased gait speed (β = 0.02, p = 0.04). A decrease in Horvath DNA methylation age and increase in physical functional ability did not demonstrate a significant association. Conclusions: The observed relationship between increased physical functional ability and decreased biological age using DNA methylation clocks demonstrate the potential utility of DNA methylation clocks to assess interventional approaches to improve health in older obese adults. Trial registration: National Institute on Aging (NIA), NCT03104192. Posted April 7, 2017, https://clinicaltrials.gov/ct2/show/NCT03104192 [ABSTRACT FROM AUTHOR]

Published

2021

9. CancerClock: A DNA Methylation Age Predictor to Identify and Characterize Aging Clock in Pan-Cancer

Author

Tongtong Zhu, Yue Gao, Junwei Wang, Xin Li, Shipeng Shang, Yanxia Wang, Shuang Guo, Hanxiao Zhou, Hongjia Liu, Dailin Sun, Hong Chen, Li Wang, and Shangwei Ning

Subjects

chronological age, methylation age, pan-cancer, LASSO, survival, Biotechnology, TP248.13-248.65

Abstract

Many biological indicators related to chronological age have been proposed. Recent studies found that epigenetic clock or DNA methylation age is highly correlated with chronological age. In particular, a significant difference between DNA methylation age (m-age) and chronological age was observed in cancers. However, the prediction and characterization of m-age in pan-cancer remains an explored area. In this study, 1,631 age-related methylation sites in normal tissues were discovered and analyzed. A comprehensive computational model named CancerClock was constructed to predict the m-age for normal samples based on methylation levels of the extracted methylation sites. LASSO linear regression model was used to screen and train the CancerClock model in normal tissues. The accuracy of CancerClock has proved to be 81%, and the correlation value between chronological age and m-age was 0.939 (P < 0.01). Next, CancerClock was used to evaluate the difference between m-age and chronological age for 33 cancer types from TCGA. There were significant differences between predicted m-age and chronological age in large number of cancer samples. These cancer samples were defined as “age-related cancer samples” and they have some differential methylation sites. The differences between predicted m-age and chronological age may contribute to cancer development. Some of these differential methylation sites were associated with cancer survival. CancerClock provided assistance in estimating the m-age in normal and cancer samples. The changes between m-age and chronological age may improve the diagnosis and prognosis of cancers.

Published

2019

10. The effect of polyphenols on DNA methylation-assessed biological age attenuation: the DIRECT PLUS randomized controlled trial

Author

Meir, A.Y., Keller, M., Hoffmann, A., Rinott, E., Tsaban, G., Kaplan, A., Zelicha, H., Hagemann, T., Ceglarek, U., Isermann, B., Shelef, I., Blüher, M., Stumvoll, M., Li, J., Haange, Sven Bastiaan, Engelmann, Beatrice, Rolle-Kampczyk, Ulrike, von Bergen, Martin, Hu, F.B., Stampfer, M.J., Kovacs, P., Liang, L., Shai, I., Meir, A.Y., Keller, M., Hoffmann, A., Rinott, E., Tsaban, G., Kaplan, A., Zelicha, H., Hagemann, T., Ceglarek, U., Isermann, B., Shelef, I., Blüher, M., Stumvoll, M., Li, J., Haange, Sven Bastiaan, Engelmann, Beatrice, Rolle-Kampczyk, Ulrike, von Bergen, Martin, Hu, F.B., Stampfer, M.J., Kovacs, P., Liang, L., and Shai, I.

Abstract

Background Epigenetic age is an estimator of biological age based on DNA methylation; its discrepancy from chronologic age warrants further investigation. We recently reported that greater polyphenol intake benefitted ectopic fats, brain function, and gut microbiota profile, corresponding with elevated urine polyphenols. The effect of polyphenol-rich dietary interventions on biological aging is yet to be determined. Methods We calculated different biological aging epigenetic clocks of different generations (Horvath2013, Hannum2013, Li2018, Horvath skin and blood2018, PhenoAge2018, PCGrimAge2022), their corresponding age and intrinsic age accelerations, and DunedinPACE, all based on DNA methylation (Illumina EPIC array; pre-specified secondary outcome) for 256 participants with abdominal obesity or dyslipidemia, before and after the 18-month DIRECT PLUS randomized controlled trial. Three interventions were assigned: healthy dietary guidelines, a Mediterranean (MED) diet, and a polyphenol-rich, low-red/processed meat Green-MED diet. Both MED groups consumed 28 g walnuts/day (+ 440 mg/day polyphenols). The Green-MED group consumed green tea (3–4 cups/day) and Mankai (Wolffia globosa strain) 500-ml green shake (+ 800 mg/day polyphenols). Adherence to the Green-MED diet was assessed by questionnaire and urine polyphenols metabolomics (high-performance liquid chromatography quadrupole time of flight). Results Baseline chronological age (51.3 ± 10.6 years) was significantly correlated with all methylation age (mAge) clocks with correlations ranging from 0.83 to 0.95; p < 2.2e − 16 for all. While all interventions did not differ in terms of changes between mAge clocks, greater Green-Med diet adherence was associated with a lower 18-month relative change (i.e., greater mAge attenuation) in Li and Hannum mAge (beta = − 0.41, p = 0.004 and beta = − 0.38, p = 0.03, respectively; multivariate models). Greater Li mAge attenuation (multivariate models adjusted for age, se

Published

2023

11. Report on the Evaluation of Methods for Improving Comparability of Cross-Omics Data from Different Cohorts

Author

Niehues, Anna, 't Hoen, Peter-Bram, de Visser, Casper, Vrbkova, Jana, Najdekr, Lukáš, Toth, Reka, and Fernandez, Val

Subjects

FAIR data, reference methylomes, biological interpretation, multiomics data, computational workflow, methylation age, best practice, unsupervised analysis, cross-omics, standardized quality assessment, data workflow, supervised analysis, confounding factors, data integration, reproducibility, multiomics integration, multiomics, data comparability, batch correction methods

Abstract

The key scientific output of the EATRIS-Plus project is to develop a Multi-omic Toolbox available for researchers in order to have a better understanding of the molecular profiles in personalised medicine. Within work packages 1, 2, and 3, we implement practices based on the FAIR (Findability, Accessibility, Interoperability, and Reusability) principles to ensure reproducibility of our work and to make the multi-omics cohort data reusable for future translational research. The aim of this deliverable (D2.2) is to describe methods developed and applied to the Czech multi-omics cohort 1 that can improve comparability of data when integrating omics data from different sources. Integration of omics data from different sources can be challenging when data and data processing steps are not sufficiently annotated, or sources of biological and technical variation are unknown. The Czech multi-omics demonstrator cohort serves as a demonstrator for the development and application of computational workflows for omics preprocessing and integrative analyses. &nbsp

Published

2023

12. Nutrition, DNA methylation and obesity across life stages and generations.

Author

Yaskolka Meir A, Yun H, Stampfer MJ, Liang L, and Hu FB

Subjects

Pregnancy, Female, Humans, Diet, Epigenesis, Genetic, DNA Methylation, Obesity genetics

Abstract

Obesity is a complex multifactorial condition that often manifests in early life with a lifelong burden on metabolic health. Diet, including pre-pregnancy maternal diet, in utero nutrition and dietary patterns in early and late life, can shape obesity development. Growing evidence suggests that epigenetic modifications, specifically DNA methylation, might mediate or accompany these effects across life stages and generations. By reviewing human observational and intervention studies conducted over the past 10 years, this work provides a comprehensive overview of the evidence linking nutrition to DNA methylation and its association with obesity across different age periods, spanning from preconception to adulthood and identify future research directions in the field.

Published

2023

13. Accelerated DNA methylation age and medication use among African Americans

Author

Scott M. Ratliff, Wei Zhao, Patricia A. Peyser, Dima Chaar, Jennifer A. Smith, Yi Zhe Wang, Sharon L.R. Kardia, Thomas H. Mosley, and Minjung Kho

Subjects

Adult, Male, Aging, medicine.medical_specialty, methylation age, medication use, Internal medicine, Diabetes mellitus, Hyperlipidemia, medicine, Humans, Epigenetics, African Americans, Sex Characteristics, Medication use, DNA methylation, business.industry, Anti-Inflammatory Agents, Non-Steroidal, dNaM, Cell Biology, Chronological age, Middle Aged, medicine.disease, Black or African American, Pharmaceutical Preparations, Genetic epidemiology, Multivariate Analysis, Female, business, epigenetic clock, Research Paper

Abstract

DNA methylation age acceleration, the discrepancy between epigenetic age and chronological age, is associated with mortality and chronic diseases, including diabetes, hypertension, and hyperlipidemia. In this study, we investigate whether medications commonly used to treat these diseases in 15 drug categories are associated with four epigenetic age acceleration measures: HorvathAge acceleration (HorvathAA), HannumAge acceleration (HannumAA), PhenoAge acceleration, and GrimAge acceleration (GrimAA) using cross-sectional (Phase 1, N=1,100) and longitudinal (Phases 1 and 2, N=266) data from African Americans in the Genetic Epidemiology Network of Arteriopathy (GENOA) study. In cross-sectional analyses, the use of calcium channel blockers was associated with 1.27 years lower HannumAA after adjusting for covariates including hypertension (p=0.001). Longitudinal analyses showed that, compared to those who never used antihypertensives, those who started to take antihypertensives after Phase 1 had a 0.97-year decrease in GrimAA (p=0.007). In addition, compared to those who never used NSAID analgesics, those who started to take them after Phase 1 had a 2.61-year increase in HorvathAA (p=0.0005). Our study demonstrates that three commonly used medications are associated with DNAm age acceleration in African Americans and sheds light on the potential epigenetic effects of pharmaceuticals on aging at the cellular level.

Published

2021

14. DNA methylation-based age estimation in pediatric healthy tissues and brain tumors

Author

Kling, Teresia, Wenger, Anna, and Carén, Helena

Subjects

Aging, DNA methylation, children, methylation age, Biological Clocks, Brain Neoplasms, Humans, Child, epigenetic clock, brain tumor, Research Paper, Epigenesis, Genetic

Abstract

Several DNA methylation clocks have been developed to reflect chronological age of human tissues, but most clocks have been trained on adult samples. The rapid methylome changes in children and the role of epigenetics in pediatric tumors calls for tools accurately estimating methylation age in children. We aimed to evaluate seven methylation clocks in multiple tissues from healthy children to inform future studies on the optimal clock for pediatric cohorts, and analyzed the methylation age in brain tumors. We found that clocks trained on pediatric samples were the best in all tested tissues, highlighting the need for dedicated clocks. For blood samples, the Skin and blood clock had the best correlation with chronological age, while PedBE was the most accurate for saliva and buccal samples, and Horvath for brain tissue. Horvath methylation age was accelerated in pediatric brain tumors and the acceleration was subtype-specific for atypical teratoid rhabdoid tumor (ATRT), ependymoma, medulloblastoma and glioma. The subtypes with the highest acceleration corresponded to the worst prognostic categories in ATRT, ependymoma and glioma, whereas the relationship was reversed in medulloblastoma. This suggests that methylation age has potential as a prognostic biomarker in pediatric brain tumors and should be further explored.

Published

2020

15. Seven-CpG DNA Methylation Age Determined by Single Nucleotide Primer Extension and Illumina���s Infinium MethylationEPIC Array Provide Highly Comparable Results

Author

Vetter, V., Kalies, C., Sommerer, Y., Bertram, L., and Demuth, I.

Subjects

methylation age, aging, Berlin Aging Study II, single-nucleotide primer extension assay, biological age, Genetics, Molecular Medicine, BASE-II, Genetics (clinical), epigenetic clock, GendAge study, 600 Technik, Medizin, angewandte Wissenschaften::610 Medizin und Gesundheit::610 Medizin und Gesundheit, Original Research

Abstract

DNA methylation age (DNAm age, epigenetic clock) is a novel and promising biomarker of aging. It is calculated from the methylation fraction of specific cytosine phosphate guanine sites (CpG sites) of genomic DNA. Several groups have proposed epigenetic clock algorithms and these differ mostly regarding the number and location of the CpG sites considered and the method used to assess the methylation status. Most epigenetic clocks are based on a large number of CpGs, e.g. as measured by DNAm microarrays. We have recently evaluated an epigenetic clock based on the methylation fraction of seven CpGs that were determined by methylation-sensitive single nucleotide primer extension (MS-SNuPE). This method is more cost-effective when compared to array-based technologies as only a few CpGs need to be examined. However, there is only little data on the correspondence in epigenetic age estimation using the 7-CpG clock and other algorithms. To bridge this gap, in this study we measured the 7-CpG DNAm age using two methods, via MS-SNuPE and via the MethylationEPIC array, in a sample of 1,058 participants of the Berlin Aging Study II (BASE-II), assessed as part of the GendAge study. On average, participants were 75.6 years old (SD: 3.7, age range: 64.9���90.0, 52.6% female). Agreement between methods was assessed by Bland-Altman plots. DNAm age was highly correlated between methods (Pearson���s r = 0.9) and Bland-Altman plots showed a difference of 3.1 years. DNAm age by the 7-CpG formula was 71.2 years (SD: 6.9 years, SNuPE) and 68.1 years (SD: 6.4 years, EPIC array). The mean of difference in methylation fraction between methods for the seven individual CpG sites was between 0.7 and 13 percent. To allow direct conversion of DNAm age obtained from both methods we developed an adjustment formula with a randomly selected training set of 529 participants using linear regression. After conversion of the Illumina data in a second and independent validation set, the adjusted DNAm age was 71.44 years (SD: 6.1 years, n = 529). In summary, we found the results of DNAm clocks to be highly comparable. Furthermore, we developed an adjustment formula that allows for direct conversion of DNAm age estimates between methods and enables one singular clock to be used in studies that employ either the Illumina or the SNuPE method.

Published

2022

16. Estimage: a webserver hub for the computation of methylation age

Author

Pietro Di Lena, Christine Nardini, Claudia Sala, Di Lena, Pietro, Sala, Claudia, and Nardini, Christine

Subjects

Time Factors, methylation age, AcademicSubjects/SCI00010, Computational biology, Web Server, Biology, Epigenesis, Genetic, Correlation, 03 medical and health sciences, 0302 clinical medicine, Genetics, Epigenetics, 030304 developmental biology, Methyl-age, 0303 health sciences, Internet, Robustness (evolution), Gestational age, Methylation, DNA Methylation, Telomere, Biomarker (cell), 030220 oncology & carcinogenesis, DNA methylation, Web Server Issue, CpG Islands, Software

Abstract

Methylage is an epigenetic marker of biological age that exploits the correlation between the methylation state of specific CG dinucleotides (CpGs) and chronological age (in years), gestational age (in weeks), cellular age (in cell cycles or as telomere length, in kilobases). Using DNA methylation data, methylage is measurable via the so called epigenetic clocks. Importantly, alterations of the correlation between methylage and age (age acceleration or deceleration) have been stably associated with pathological states and occur long before clinical signs of diseases become overt, making epigenetic clocks a potentially disruptive tool in preventive, diagnostic and also in forensic applications. Nevertheless, methylage dependency from CpGs selection, mathematical modelling, tissue specificity and age range, still makes the potential of this biomarker limited. In order to enhance model comparisons, interchange, availability, robustness and standardization, we organized a selected set of clocks within a hub webservice, EstimAge (Estimate of methylation Age, http://estimage.iac.rm.cnr.it), which intuitively and informatively enables quick identification, computation and comparison of available clocks, with the support of standard statistics., Graphical Abstract Graphical AbstractEstimAge enables the computation of methylage via the largest selection of epigenetic clocks, offering multiple tabular and graphical outputs to be readily used for scientific reporting or further processing, including refined/alternative rounds of EstimAge selection.

Published

2021

17. Weight management intervention identifies association of decreased DNA methylation age with improved functional age measures in older adults with obesity

Author

Curtis L. Petersen, John A. Batsis, and Brock C. Christensen

Subjects

Epigenomics, Male, Aging, Physiology, Body Weight Maintenance, Healthy Aging, Grip strength, Methylation clock, Weight loss, Weight management, Weight Loss, Genetics, Medicine, Humans, Functional ability, Obesity, Association (psychology), Molecular Biology, Genetics (clinical), Aged, Hand Strength, business.industry, Research, Methylation, Anti-aging, DNA Methylation, Physical Functional Performance, medicine.disease, Walking Speed, DNA methylation, Methylation age, Linear Models, CpG Islands, Female, medicine.symptom, business, Developmental Biology

Abstract

Background Assessing functional ability is an important component of understanding healthy aging. Objective measures of functional ability include grip strength, gait speed, sit-to-stand time, and 6-min walk distance. Using samples from a weight loss clinical trial in older adults with obesity, we examined the association between changes in physical function and DNA-methylation-based biological age at baseline and 12 weeks in 16 individuals. Peripheral blood DNA methylation was measured (pre/post) with the Illumina HumanMethylationEPIC array and the Hannum, Horvath, and PhenoAge DNA methylation age clocks were used. Linear regression models adjusted for chronological age and sex tested the relationship between DNA methylation age and grip strength, gait speed, sit-to-stand, and 6-min walk. Results Participant mean weight loss was 4.6 kg, and DNA methylation age decreased 0.8, 1.1, and 0.5 years using the Hannum, Horvath, and PhenoAge DNA methylation clocks respectively. Mean grip strength increased 3.2 kg. Decreased Hannum methylation age was significantly associated with increased grip strength (β = −0.30, p = 0.04), and increased gait speed (β = 0.02, p = 0.05), in adjusted models. Similarly, decreased methylation age using the PhenoAge clock was associated with significantly increased gait speed (β = 0.02, p = 0.04). A decrease in Horvath DNA methylation age and increase in physical functional ability did not demonstrate a significant association. Conclusions The observed relationship between increased physical functional ability and decreased biological age using DNA methylation clocks demonstrate the potential utility of DNA methylation clocks to assess interventional approaches to improve health in older obese adults. Trial registration: National Institute on Aging (NIA), NCT03104192. Posted April 7, 2017, https://clinicaltrials.gov/ct2/show/NCT03104192

Published

2020

18. Epigenetic analysis of cardio-metabolic health in an African population

Author

Cronjé, H.T., Pieters, M., Nienaber-Rousseau, C., Elliott, H.R., 10797920 - Pieters, Marlien (Supervisor), and 12632449 - Nienaber-Rousseau, Cornelie (Supervisor)

Subjects

DNA methylation, urbanisation, inflammation, methylation age, PURE, epigenetic clocks, Cardiovascular disease, cardiovascular function, LMICs, EWAS

Abstract

PhD (Nutrition), North-West University, Potchefstroom Campus INTRODUCTION AND AIM: Eighty-five percent of the 41 million annual non-communicable disease (NCD) mortalities worldwide occur in low- and middle-income countries (LMICs). A large proportion of these deaths are caused by cardio-metabolic diseases (CMDs). The prevalence of CMDs continues to increase in part owing to the rapid urbanisation experienced by these countries. Evidence has shown that epigenetic mechanisms, such as DNA methylation (DNAm), associate with CMDs and CMD risk factors. These mechanisms potentially mediate the relationship between genetic/environmental exposure (such as the behaviour and lifestyle changes related to urbanisation) and disease. Valuable insights have so far come from investigations of DNAm in the context of CMD through epigenome-wide association analyses (EWASs), white blood cell count (WBC) ratios and DNAm clocks. Although these investigations could be of great benefit to CMD prevention and treatment in LMICs, thus far data have largely been collected in individuals from European descent, mostly living in urbanised, high-income countries. Data on populations from different ancestries, living in LMICs, including continental Africans, are scarce. Because there are known genetic and epigenetic differences between ancestral groups, the generalisability of the current epigenetic literature, mostly resulting from European cohorts, to understudied African populations is unknown. This thesis reports the first investigation into the relationship between DNAm and cardio-metabolic health in black South Africans. First, the urban-rural divide, as is experienced in developing countries such as South Africa, was described as an epidemiological approach to investigate the role of DNAm in the association between urbanisation and NCD risk, in the form of a review. This formed part of the literature required to understand and interpret the experimental data. Empirically, DNAm was investigated using EWASs and analysis of methylation-derived WBC ratios and DNAm clocks, in relation to a range of CMD-related phenotypes including chronological and biological age, alcohol consumption, smoking status, body composition, biochemical indicators of metabolic health and inflammation, as well as markers of cardiovascular function (CVF) and risk. METHODS: A sub-sample of 120 apparently healthy Batswana men, aged 45 to 88 years, who participated in the 2015 arm of the Prospective Urban and Rural Epidemiology study in the North West province of South Africa (PURE-SA-NW) were investigated. Genome-wide DNAm data were generated from whole-blood DNA using the Illumina® Infinium HumanMethylationEPIC bead chip (EPIC array). Multiple CMD-related EWASs were performed and compared to previously published EWASs conducted in different ethnicities, to evaluate the reproducibility of current literature and to contribute novel findings from the PURE-SA-NW cohort. Next, methylation-derived WBC ratios were investigated and compared to protein-based inflammatory markers in their associations with CVF markers and their literature-based portrayal of CVD risk. Lastly, DNAm ages were estimated using five widely used DNAm clocks. Age estimates from the Horvath, Hannum and skin and blood clocks were compared in terms of their accuracy of chronological age estimation and those from PhenoAge and GrimAge clocks were compared according to their ability to characterise biophysiological decline. RESULTS: Up to 86% of previously identified epigenome-wide associations overlapped with the findings from the PURE-SA-NW study, and a further 13% were directionally consistent. Only 1% of the replicated associations presented with effects opposite to findings in other ancestral groups and were largely explained by population-specific genomic variance. Nineteen novel CpG associations with alcohol consumption (11 EPIC probes and eight 450K probes also present on the EPIC array) and one with high-density lipoprotein (450K probe) were observed. The WBC ratio estimates of the PURE-SA-NW group were comparable to previously investigated ostensibly healthy ethnic groups. The CVD risk portrayed by these markers was also similar to that of conventionally used risk markers, including C-reactive protein. The methylation-derived WBC ratio indicators performed better than the protein-based inflammatory markers when disentangling variance in CVF. Optimal clarification of CVF variance was obtained when the methylation-derived and protein-based markers were used in tandem. The skin and blood clock had a stronger correlation with chronological age and less variation in age acceleration compared to the Horvath and Hannum clocks. All three of these clocks, however, tended to underestimate the chronological age of the cohort. This underestimation was increasingly pronounced with older chronological age. GrimAge provided superior characterisation of biophysiological decline compared to the PhenoAge estimate, partly because of its incorporation of smoking-related effects, which were not encapsulated by the PhenoAge estimate or any of its constituents. This was of particular importance in this study population, given that more than half of them were current smokers. CONCLUSION: This thesis demonstrates that the methylation associations observed in this black South African population are largely in agreement with the epigenetic data published on other ethnicities, with some differences related to genomic variance, highlighting the need for population-specific data. The enhanced coverage of the EPIC array proved useful in expanding the current epigenetic literature. Methylation-derived WBC ratio markers provided additional value to conventionally used inflammatory markers in the elucidation of the role of inflammation in CVF, even in population-based research without overt inflammatory diseases. The DNAm clocks require further optimisation for their use in older populations, as was observed in their systematic underestimation of biological age in the PURE-SA-NW data. The fact that the GrimAge incorporates, for the first time, lifestyle-related exposure, such as smoking, seemed to add to its accuracy in characterising biophysiological decline. Empirically, this thesis shows that investigations of diverse populations are valuable and can reveal new associations. The critical narrative literature review highlights the need for epidemiological studies of DNAm across urban-rural divides where suitable data sets exist. Future studies can replicate the data reported here and further investigate causal pathways and utility in disease prediction. Doctoral

Published

2020

19. CancerClock: A DNA Methylation Age Predictor to Identify and Characterize Aging Clock in Pan-Cancer

Author

Li Wang, Tongtong Zhu, Hanxiao Zhou, Xin Li, Shangwei Ning, Shipeng Shang, Dailin Sun, Hongjia Liu, Shuang Guo, Yanxia Wang, Hong Chen, Yue Gao, and Junwei Wang

Subjects

0301 basic medicine, Oncology, medicine.medical_specialty, Histology, methylation age, lcsh:Biotechnology, pan-cancer, Biomedical Engineering, Bioengineering, 02 engineering and technology, LASSO, Biology, survival, 03 medical and health sciences, Internal medicine, lcsh:TP248.13-248.65, Linear regression, medicine, Epigenetics, Original Research, chronological age, Pan cancer, Bioengineering and Biotechnology, Methylation, Chronological age, 021001 nanoscience & nanotechnology, Correlation value, 030104 developmental biology, DNA methylation, Cancer development, 0210 nano-technology, Biotechnology

Abstract

Many biological indicators related to chronological age have been proposed. Recent studies found that epigenetic clock or DNA methylation age is highly correlated with chronological age. In particular, a significant difference between DNA methylation age (m-age) and chronological age was observed in cancers. However, the prediction and characterization of m-age in pan-cancer remains an explored area. In this study, 1,631 age-related methylation sites in normal tissues were discovered and analyzed. A comprehensive computational model named CancerClock was constructed to predict the m-age for normal samples based on methylation levels of the extracted methylation sites. LASSO linear regression model was used to screen and train the CancerClock model in normal tissues. The accuracy of CancerClock has proved to be 81%, and the correlation value between chronological age and m-age was 0.939 (P < 0.01). Next, CancerClock was used to evaluate the difference between m-age and chronological age for 33 cancer types from TCGA. There were significant differences between predicted m-age and chronological age in large number of cancer samples. These cancer samples were defined as “age-related cancer samples” and they have some differential methylation sites. The differences between predicted m-age and chronological age may contribute to cancer development. Some of these differential methylation sites were associated with cancer survival. CancerClock provided assistance in estimating the m-age in normal and cancer samples. The changes between m-age and chronological age may improve the diagnosis and prognosis of cancers.

Published

2019

20. Accelerated DNA methylation age and medication use among African Americans.

Author

Kho M, Wang YZ, Chaar D, Zhao W, Ratliff SM, Mosley TH, Peyser PA, Kardia SLR, and Smith JA

Subjects

Adult, Anti-Inflammatory Agents, Non-Steroidal therapeutic use, Female, Humans, Male, Middle Aged, Multivariate Analysis, Sex Characteristics, Black or African American genetics, Aging genetics, DNA Methylation genetics, Pharmaceutical Preparations

Abstract

DNA methylation age acceleration, the discrepancy between epigenetic age and chronological age, is associated with mortality and chronic diseases, including diabetes, hypertension, and hyperlipidemia. In this study, we investigate whether medications commonly used to treat these diseases in 15 drug categories are associated with four epigenetic age acceleration measures: HorvathAge acceleration (HorvathAA), HannumAge acceleration (HannumAA), PhenoAge acceleration, and GrimAge acceleration (GrimAA) using cross-sectional (Phase 1, N=1,100) and longitudinal (Phases 1 and 2, N=266) data from African Americans in the Genetic Epidemiology Network of Arteriopathy (GENOA) study. In cross-sectional analyses, the use of calcium channel blockers was associated with 1.27 years lower HannumAA after adjusting for covariates including hypertension (p=0.001). Longitudinal analyses showed that, compared to those who never used antihypertensives, those who started to take antihypertensives after Phase 1 had a 0.97-year decrease in GrimAA (p=0.007). In addition, compared to those who never used NSAID analgesics, those who started to take them after Phase 1 had a 2.61-year increase in HorvathAA (p=0.0005). Our study demonstrates that three commonly used medications are associated with DNAm age acceleration in African Americans and sheds light on the potential epigenetic effects of pharmaceuticals on aging at the cellular level.

Published

2021

21. CancerClock: A DNA Methylation Age Predictor to Identify and Characterize Aging Clock in Pan-Cancer.

Author

Zhu T, Gao Y, Wang J, Li X, Shang S, Wang Y, Guo S, Zhou H, Liu H, Sun D, Chen H, Wang L, and Ning S

Abstract

Many biological indicators related to chronological age have been proposed. Recent studies found that epigenetic clock or DNA methylation age is highly correlated with chronological age. In particular, a significant difference between DNA methylation age (m-age) and chronological age was observed in cancers. However, the prediction and characterization of m-age in pan-cancer remains an explored area. In this study, 1,631 age-related methylation sites in normal tissues were discovered and analyzed. A comprehensive computational model named CancerClock was constructed to predict the m-age for normal samples based on methylation levels of the extracted methylation sites. LASSO linear regression model was used to screen and train the CancerClock model in normal tissues. The accuracy of CancerClock has proved to be 81%, and the correlation value between chronological age and m-age was 0.939 ( P < 0.01). Next, CancerClock was used to evaluate the difference between m-age and chronological age for 33 cancer types from TCGA. There were significant differences between predicted m-age and chronological age in large number of cancer samples. These cancer samples were defined as "age-related cancer samples" and they have some differential methylation sites. The differences between predicted m-age and chronological age may contribute to cancer development. Some of these differential methylation sites were associated with cancer survival. CancerClock provided assistance in estimating the m-age in normal and cancer samples. The changes between m-age and chronological age may improve the diagnosis and prognosis of cancers., (Copyright © 2019 Zhu, Gao, Wang, Li, Shang, Wang, Guo, Zhou, Liu, Sun, Chen, Wang and Ning.)

Published

2019