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

Epigenetic clocks are mathematical models that predict the biological age of an individual using DNA methylation data and have emerged in the last few years as the most accurate biomarkers of the aging process. However, little is known about the molecular mechanisms that control the rate of such clocks. Here, we have examined the human epigenetic clock in patients with a variety of developmental disorders, harboring mutations in proteins of the epigenetic machinery. Using the Horvath epigenetic clock, we perform an unbiased screen for epigenetic age acceleration in the blood of these patients. We demonstrate that loss-of-function mutations in the H3K36 histone methyltransferase NSD1, which cause Sotos syndrome, substantially accelerate epigenetic aging. Furthermore, we show that the normal aging process and Sotos syndrome share methylation changes and the genomic context in which they occur. Finally, we found that the Horvath clock CpG sites are characterized by a higher Shannon methylation entropy when compared with the rest of the genome, which is dramatically decreased in Sotos syndrome patients. These results suggest that the H3K36 methylation machinery is a key component of the epigenetic maintenance system in humans, which controls the rate of epigenetic aging, and this role seems to be conserved in model organisms. Our observations provide novel insights into the mechanisms behind the epigenetic aging clock and we expect will shed light on the different processes that erode the human epigenetic landscape during aging.

[1]  R. Weksberg,et al.  Discovery of cross-reactive probes and polymorphic CpGs in the Illumina Infinium HumanMethylation450 microarray , 2013, Epigenetics.

[2]  Raymond K. Auerbach,et al.  An Integrated Encyclopedia of DNA Elements in the Human Genome , 2012, Nature.

[3]  D. Zheng,et al.  An H3K36 methylation-engaging Tudor motif of polycomb-like proteins mediates PRC2 complex targeting. , 2013, Molecular cell.

[4]  P. Laird,et al.  Low-level processing of Illumina Infinium DNA Methylation BeadArrays , 2013, Nucleic acids research.

[5]  Mark Gerstein,et al.  GENCODE reference annotation for the human and mouse genomes , 2018, Nucleic Acids Res..

[6]  Manuel Serrano,et al.  The Hallmarks of Aging , 2013, Cell.

[7]  James A. Cuff,et al.  A Bivalent Chromatin Structure Marks Key Developmental Genes in Embryonic Stem Cells , 2006, Cell.

[8]  E. Kanavakis,et al.  A clinical study of Sotos syndrome patients with review of the literature. , 2009, Pediatric neurology.

[9]  D. Baralle,et al.  Growth disrupting mutations in epigenetic regulatory molecules are associated with abnormalities of epigenetic aging , 2018, bioRxiv.

[10]  Felix Krueger,et al.  Multi-tissue DNA methylation age predictor in mouse , 2017, bioRxiv.

[11]  Steve Horvath,et al.  Accelerated epigenetic aging in Down syndrome , 2015, Aging cell.

[12]  Ian J. Deary,et al.  DNA methylation levels at individual age-associated CpG sites can be indicative for life expectancy , 2016, Aging.

[13]  H. Bjornsson The Mendelian disorders of the epigenetic machinery , 2015, Genome research.

[14]  M. Levine,et al.  An epigenetic clock analysis of race/ethnicity, sex, and coronary heart disease , 2016, Genome Biology.

[15]  M. Levine,et al.  DNA methylation-based measures of biological age: meta-analysis predicting time to death , 2016, Aging.

[16]  Alex P. Reiner,et al.  Epigenetic clock for skin and blood cells applied to Hutchinson Gilford Progeria Syndrome and ex vivo studies , 2018, Aging.

[17]  Darren J. Fitzpatrick,et al.  The H3K36me2 Methyltransferase Nsd1 Demarcates PRC2-Mediated H3K27me2 and H3K27me3 Domains in Embryonic Stem Cells. , 2018, Molecular cell.

[18]  R. Touraine,et al.  Mutations in SETD2 cause a novel overgrowth condition , 2014, Journal of Medical Genetics.

[19]  Terence P. Speed,et al.  Removing unwanted variation in a differential methylation analysis of Illumina HumanMethylation450 array data , 2015, bioRxiv.

[20]  J. Mill,et al.  Properties of the epigenetic clock and age acceleration , 2018, bioRxiv.

[21]  Lukas Burger,et al.  Genomic profiling of DNA methyltransferases reveals a role for DNMT3B in genic methylation , 2015, Nature.

[22]  M. Levine,et al.  Genetic variants near MLST8 and DHX57 affect the epigenetic age of the cerebellum , 2016, Nature Communications.

[23]  Thomas Lengauer,et al.  CpG Island Mapping by Epigenome Prediction , 2007, PLoS Comput. Biol..

[24]  Steve Horvath,et al.  Obesity accelerates epigenetic aging of human liver , 2014, Proceedings of the National Academy of Sciences.

[25]  T. Spector,et al.  Predicting genome-wide DNA methylation using methylation marks, genomic position, and DNA regulatory elements , 2013, Genome Biology.

[26]  S. Horvath,et al.  DNA methylation age of blood predicts all-cause mortality in later life , 2015, Genome Biology.

[27]  J. Kere,et al.  Differential DNA Methylation in Purified Human Blood Cells: Implications for Cell Lineage and Studies on Disease Susceptibility , 2012, PloS one.

[28]  A. Brunet,et al.  Epigenetic regulation of ageing: linking environmental inputs to genomic stability , 2015, Nature Reviews Molecular Cell Biology.

[29]  Brent S. Pedersen,et al.  Pybedtools: a flexible Python library for manipulating genomic datasets and annotations , 2011, Bioinform..

[30]  F. Cunningham,et al.  The Ensembl Variant Effect Predictor , 2016, Genome Biology.

[31]  Anuj Srivastava,et al.  A multi-tissue full lifespan epigenetic clock for mice , 2018, Aging.

[32]  Shijie C. Zheng,et al.  Correlation of an epigenetic mitotic clock with cancer risk , 2016, Genome Biology.

[33]  S. Horvath,et al.  Tracking the Epigenetic Clock Across the Human Life Course: A Meta-analysis of Longitudinal Cohort Data , 2018, The journals of gerontology. Series A, Biological sciences and medical sciences.

[34]  Siu Sylvia Lee,et al.  Two SET domain containing genes link epigenetic changes and aging in Caenorhabditis elegans , 2012, Aging cell.

[35]  C. Skinner,et al.  Clinical Validation of Fragile X Syndrome Screening by DNA Methylation Array. , 2016, The Journal of molecular diagnostics : JMD.

[36]  S. Berger,et al.  Epigenetic Mechanisms of Longevity and Aging , 2016, Cell.

[37]  Howard Y. Chang,et al.  Aging, Rejuvenation, and Epigenetic Reprogramming: Resetting the Aging Clock , 2012, Cell.

[38]  S. Dimitrov,et al.  Histone H3 trimethylation at lysine 36 is associated with constitutive and facultative heterochromatin. , 2011, Genome research.

[39]  Peter D. Adams,et al.  Epigenetic aging signatures in mice livers are slowed by dwarfism, calorie restriction and rapamycin treatment , 2017, Genome Biology.

[40]  Andres Metspalu,et al.  Age-related profiling of DNA methylation in CD8+ T cells reveals changes in immune response and transcriptional regulator genes , 2015, Scientific Reports.

[41]  R. Wolf,et al.  Additional file 9: of Multi-tissue DNA methylation age predictor in mouse , 2017 .

[42]  S. Horvath,et al.  Huntington's disease accelerates epigenetic aging of human brain and disrupts DNA methylation levels , 2016, Aging.

[43]  Shijie C. Zheng,et al.  Cell and tissue type independent age-associated DNA methylation changes are not rare but common , 2018, bioRxiv.

[44]  Martin A. M. Reijns,et al.  Gain of function DNMT3A mutations cause microcephalic dwarfism and hypermethylation of Polycomb-regulated regions , 2018, Nature Genetics.

[45]  P. Stadler,et al.  Changes of bivalent chromatin coincide with increased expression of developmental genes in cancer , 2016, Scientific Reports.

[46]  D. Schübeler Function and information content of DNA methylation , 2015, Nature.

[47]  M. Levine,et al.  GWAS of epigenetic aging rates in blood reveals a critical role for TERT , 2018, Nature Communications.

[48]  Giulia Basile,et al.  Intragenic DNA methylation prevents spurious transcription initiation , 2017, Nature.

[49]  S. Warren,et al.  Genome-wide analysis validates aberrant methylation in fragile X syndrome is specific to the FMR1 locus , 2013, BMC Medical Genetics.

[50]  S. Horvath,et al.  An epigenetic aging clock for dogs and wolves , 2017, Aging.

[51]  Morris A. Swertz,et al.  Age-related accrual of methylomic variability is linked to fundamental ageing mechanisms , 2016, Genome Biology.

[52]  Jing Zhao,et al.  Peripheral blood methylation profiling of female Crohn’s disease patients , 2016, Clinical Epigenetics.

[53]  Sang-Goo Lee,et al.  Using DNA Methylation Profiling to Evaluate Biological Age and Longevity Interventions. , 2017, Cell metabolism.

[54]  Steve Horvath,et al.  DNA methylation-based biomarkers and the epigenetic clock theory of ageing , 2018, Nature Reviews Genetics.

[55]  Owen T McCann,et al.  Human aging-associated DNA hypermethylation occurs preferentially at bivalent chromatin domains. , 2010, Genome research.

[56]  James C. Cummings,et al.  Profiling of m6A RNA modifications identified an age‐associated regulation of AGO2 mRNA stability , 2018, Aging cell.

[57]  W. Wagner,et al.  Epigenetic-aging-signature to determine age in different tissues , 2011, Aging.

[58]  Alexander T. Adams,et al.  H3K36 Methylation Regulates Nutrient Stress Response in Saccharomyces cerevisiae by Enforcing Transcriptional Fidelity. , 2017, Cell reports.

[59]  Wei Li,et al.  Large conserved domains of low DNA methylation maintained by Dnmt3a , 2013, Nature Genetics.

[60]  Margarita V. Meer,et al.  A whole lifespan mouse multi-tissue DNA methylation clock , 2018, eLife.

[61]  T. Ideker,et al.  Genome-wide methylation profiles reveal quantitative views of human aging rates. , 2013, Molecular cell.

[62]  C. Relton,et al.  Age-related DNA methylation changes are tissue-specific with ELOVL2 promoter methylation as exception , 2018, Epigenetics & Chromatin.

[63]  S. Horvath,et al.  Synchrony and asynchrony between an epigenetic clock and developmental timing , 2019, Scientific Reports.

[64]  Gang Xiao,et al.  Histone H3 trimethylation at lysine 36 guides m6A RNA modification co-transcriptionally , 2019, Nature.

[65]  Y. Fukushima,et al.  Haploinsufficiency of NSD1 causes Sotos syndrome , 2002, Nature Genetics.

[66]  S. Horvath,et al.  Accelerated epigenetic aging in Werner syndrome , 2017, Aging.

[67]  Michael Q. Zhang,et al.  Epigenomic Analysis of Multilineage Differentiation of Human Embryonic Stem Cells , 2013, Cell.

[68]  Shijie C. Zheng,et al.  Cell-type deconvolution in epigenome-wide association studies: a review and recommendations. , 2017, Epigenomics.

[69]  Hanxin Lin,et al.  Genomic DNA Methylation Signatures Enable Concurrent Diagnosis and Clinical Genetic Variant Classification in Neurodevelopmental Syndromes. , 2018, American journal of human genetics.

[70]  S. Horvath,et al.  HIV-1 Infection Accelerates Age According to the Epigenetic Clock , 2015, The Journal of infectious diseases.

[71]  Andreas Heger,et al.  Epigenetic conservation at gene regulatory elements revealed by non-methylated DNA profiling in seven vertebrates , 2013, eLife.

[72]  L. Christiansen,et al.  Epigenetic signature of birth weight discordance in adult twins , 2014, BMC Genomics.

[73]  Devin C. Koestler,et al.  DNA methylation arrays as surrogate measures of cell mixture distribution , 2012, BMC Bioinformatics.

[74]  S. Horvath DNA methylation age of human tissues and cell types , 2013, Genome Biology.

[75]  A L Turinsky,et al.  NSD1 mutations generate a genome-wide DNA methylation signature , 2015, Nature Communications.

[76]  J. Tyler,et al.  Epigenetics and aging , 2016, Science Advances.

[77]  Hui Shen,et al.  DNA methylation loss in late-replicating domains is linked to mitotic cell division , 2018, Nature Genetics.

[78]  Francesco Marabita,et al.  A beta-mixture quantile normalization method for correcting probe design bias in Illumina Infinium 450 k DNA methylation data , 2012, Bioinform..

[79]  Y. Zhang,et al.  Genome-wide analyses reveal a role of Polycomb in promoting hypomethylation of DNA methylation valleys , 2018, Genome Biology.

[80]  P. Stanier,et al.  Genome-wide methylation analysis in Silver–Russell syndrome patients , 2015, Human Genetics.

[81]  Devin C. Koestler,et al.  Improving cell mixture deconvolution by identifying optimal DNA methylation libraries (IDOL) , 2016, BMC Bioinformatics.

[82]  António J. M. Ribeiro,et al.  cuRRBS: simple and robust evaluation of enzyme combinations for reduced representation approaches , 2017, Nucleic acids research.

[83]  Data production leads,et al.  An integrated encyclopedia of DNA elements in the human genome , 2012 .

[84]  C. Skinner,et al.  The defining DNA methylation signature of Kabuki syndrome enables functional assessment of genetic variants of unknown clinical significance , 2017, Epigenetics.

[85]  M. Bulyk,et al.  Polycomb-like proteins link the PRC2 complex to CpG islands , 2017, Nature.

[86]  Johann A. Gagnon-Bartsch,et al.  Using control genes to correct for unwanted variation in microarray data. , 2012, Biostatistics.

[87]  Albert Jeltsch,et al.  The Dnmt3a PWWP Domain Reads Histone 3 Lysine 36 Trimethylation and Guides DNA Methylation* , 2010, The Journal of Biological Chemistry.

[88]  Wolfgang Wagner,et al.  Age-dependent DNA methylation of genes that are suppressed in stem cells is a hallmark of cancer. , 2010, Genome research.

[89]  E. Wagner,et al.  Understanding the language of Lys36 methylation at histone H3 , 2012, Nature Reviews Molecular Cell Biology.

[90]  K. Hansen,et al.  Functional normalization of 450k methylation array data improves replication in large cancer studies , 2014, Genome Biology.

[91]  Haiyuan Yu,et al.  Trimethylation of Lys36 on H3 restricts gene expression change during aging and impacts life span , 2015, Genes & development.

[92]  R. Marioni,et al.  Partial reprogramming induces a steady decline in epigenetic age before loss of somatic identity , 2018, bioRxiv.

[93]  K. Ge,et al.  Histone H3 lysine 4 methyltransferase KMT2D. , 2017, Gene.

[94]  A. Polanowski,et al.  Epigenetic estimation of age in humpback whales , 2014, Molecular ecology resources.

[95]  B. Kennedy,et al.  H3K36 methylation promotes longevity by enhancing transcriptional fidelity , 2015, Genes & development.

[96]  S. Horvath,et al.  Epigenetic age analysis of children who seem to evade aging , 2015, Aging.

[97]  Andrei L. Turinsky,et al.  CHARGE and Kabuki Syndromes: Gene-Specific DNA Methylation Signatures Identify Epigenetic Mechanisms Linking These Clinically Overlapping Conditions , 2017, American journal of human genetics.

[98]  John J. Cole,et al.  Diverse interventions that extend mouse lifespan suppress shared age-associated epigenetic changes at critical gene regulatory regions , 2017, Genome Biology.

[99]  D. Matallanas,et al.  Dnmt3a and Dnmt3b Associate with Enhancers to Regulate Human Epidermal Stem Cell Homeostasis. , 2016, Cell stem cell.

[100]  Trey Ideker,et al.  DNA Methylation Clocks in Aging: Categories, Causes, and Consequences. , 2018, Molecular cell.

[101]  E. Li,et al.  The PWWP Domain of Dnmt3a and Dnmt3b Is Required for Directing DNA Methylation to the Major Satellite Repeats at Pericentric Heterochromatin , 2004, Molecular and Cellular Biology.

[102]  Rafael A. Irizarry,et al.  Minfi: a flexible and comprehensive Bioconductor package for the analysis of Infinium DNA methylation microarrays , 2014, Bioinform..

[103]  D. Valle,et al.  Patients with a Kabuki syndrome phenotype demonstrate DNA methylation abnormalities , 2017, European Journal of Human Genetics.