Your search keyword '"Kristine L, Haftorn"' showing total 8 results

1. Stability selection enhances feature selection and enables accurate prediction of gestational age using only five DNA methylation sites

Author

Kristine L. Haftorn, Julia Romanowska, Yunsung Lee, Christian M. Page, Per M. Magnus, Siri E. Håberg, Jon Bohlin, Astanand Jugessur, and William R. P. Denault

Subjects

DNA methylation, Epigenetics, Gestational age, Illumina MethylationEPIC BeadChip, Epigenetic clock, Stability selection, Medicine, Genetics, QH426-470

Abstract

Abstract Background DNA methylation (DNAm) is robustly associated with chronological age in children and adults, and gestational age (GA) in newborns. This property has enabled the development of several epigenetic clocks that can accurately predict chronological age and GA. However, the lack of overlap in predictive CpGs across different epigenetic clocks remains elusive. Our main aim was therefore to identify and characterize CpGs that are stably predictive of GA. Results We applied a statistical approach called ‘stability selection’ to DNAm data from 2138 newborns in the Norwegian Mother, Father, and Child Cohort study. Stability selection combines subsampling with variable selection to restrict the number of false discoveries in the set of selected variables. Twenty-four CpGs were identified as being stably predictive of GA. Intriguingly, only up to 10% of the CpGs in previous GA clocks were found to be stably selected. Based on these results, we used generalized additive model regression to develop a new GA clock consisting of only five CpGs, which showed a similar predictive performance as previous GA clocks (R 2 = 0.674, median absolute deviation = 4.4 days). These CpGs were in or near genes and regulatory regions involved in immune responses, metabolism, and developmental processes. Furthermore, accounting for nonlinear associations improved prediction performance in preterm newborns. Conclusion We present a methodological framework for feature selection that is broadly applicable to any trait that can be predicted from DNAm data. We demonstrate its utility by identifying CpGs that are highly predictive of GA and present a new and highly performant GA clock based on only five CpGs that is more amenable to a clinical setting.

Published

2023

2. The X-factor in ART: does the use of assisted reproductive technologies influence DNA methylation on the X chromosome?

Author

Julia Romanowska, Haakon E. Nustad, Christian M. Page, William R. P. Denault, Yunsung Lee, Maria C. Magnus, Kristine L. Haftorn, Miriam Gjerdevik, Boris Novakovic, Richard Saffery, Håkon K. Gjessing, Robert Lyle, Per Magnus, Siri E. Håberg, and Astanand Jugessur

Subjects

Epigenetics, Assisted reproductive technology (ART), The Norwegian Mother, Father and Child Cohort Study (MoBa), DNA methylation, Epigenome-wide association study, Medicine, Genetics, QH426-470

Abstract

Abstract Background Assisted reproductive technologies (ART) may perturb DNA methylation (DNAm) in early embryonic development. Although a handful of epigenome-wide association studies of ART have been published, none have investigated CpGs on the X chromosome. To bridge this knowledge gap, we leveraged one of the largest collections of mother–father–newborn trios of ART and non-ART (natural) conceptions to date to investigate sex-specific DNAm differences on the X chromosome. The discovery cohort consisted of 982 ART and 963 non-ART trios from the Norwegian Mother, Father, and Child Cohort Study (MoBa). To verify our results from the MoBa cohort, we used an external cohort of 149 ART and 58 non-ART neonates from the Australian ‘Clinical review of the Health of adults conceived following Assisted Reproductive Technologies’ (CHART) study. The Illumina EPIC array was used to measure DNAm in both datasets. In the MoBa cohort, we performed a set of X-chromosome-wide association studies (‘XWASs’ hereafter) to search for sex-specific DNAm differences between ART and non-ART newborns. We tested several models to investigate the influence of various confounders, including parental DNAm. We also searched for differentially methylated regions (DMRs) and regions of co-methylation flanking the most significant CpGs. Additionally, we ran an analogous model to our main model on the external CHART dataset. Results In the MoBa cohort, we found more differentially methylated CpGs and DMRs in girls than boys. Most of the associations persisted after controlling for parental DNAm and other confounders. Many of the significant CpGs and DMRs were in gene-promoter regions, and several of the genes linked to these CpGs are expressed in tissues relevant for both ART and sex (testis, placenta, and fallopian tube). We found no support for parental DNAm-dependent features as an explanation for the observed associations in the newborns. The most significant CpG in the boys-only analysis was in UBE2DNL, which is expressed in testes but with unknown function. The most significant CpGs in the girls-only analysis were in EIF2S3 and AMOT. These three loci also displayed differential DNAm in the CHART cohort. Conclusions Genes that co-localized with the significant CpGs and DMRs associated with ART are implicated in several key biological processes (e.g., neurodevelopment) and disorders (e.g., intellectual disability and autism). These connections are particularly compelling in light of previous findings indicating that neurodevelopmental outcomes differ in ART-conceived children compared to those naturally conceived.

Published

2023

3. Nucleated red blood cells explain most of the association between DNA methylation and gestational age

Author

Kristine L. Haftorn, William R. P. Denault, Yunsung Lee, Christian M. Page, Julia Romanowska, Robert Lyle, Øyvind E. Næss, Dana Kristjansson, Per M. Magnus, Siri E. Håberg, Jon Bohlin, and Astanand Jugessur

Subjects

Biology (General), QH301-705.5

Abstract

CpG sites associated with gestational age are predominantly found in nucleated red blood cells, which point to an epigenetic signature of erythropoiesis as being partly responsible for this association.

Published

2023

4. DNA methylation in newborns conceived by assisted reproductive technology

Author

Siri E. Håberg, Christian M. Page, Yunsung Lee, Haakon E. Nustad, Maria C. Magnus, Kristine L. Haftorn, Ellen Ø. Carlsen, William R. P. Denault, Jon Bohlin, Astanand Jugessur, Per Magnus, Håkon K. Gjessing, and Robert Lyle

Subjects

Science

Abstract

Timing of assisted reproduction technology (ART) procedures coincides with extensive epigenetic remodeling early after conception. Here the authors identify 176 DNA methylation differences in cord blood of newborns conceived with ART. including genes related to growth, neurodevelopment, and cancer.

Published

2022

5. Blood-based epigenetic estimators of chronological age in human adults using DNA methylation data from the Illumina MethylationEPIC array

Author

Yunsung Lee, Kristine L. Haftorn, William R. P. Denault, Haakon E. Nustad, Christian M. Page, Robert Lyle, Sindre Lee-Ødegård, Gunn-Helen Moen, Rashmi B. Prasad, Leif C. Groop, Line Sletner, Christine Sommer, Maria C. Magnus, Håkon K. Gjessing, Jennifer R. Harris, Per Magnus, Siri E. Håberg, Astanand Jugessur, and Jon Bohlin

Subjects

DNA methylation, Epigenetic age, Chronological age, Illumina MethylationEPIC BeadChip, MoBa, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Epigenetic clocks have been recognized for their precise prediction of chronological age, age-related diseases, and all-cause mortality. Existing epigenetic clocks are based on CpGs from the Illumina HumanMethylation450 BeadChip (450 K) which has now been replaced by the latest platform, Illumina MethylationEPIC BeadChip (EPIC). Thus, it remains unclear to what extent EPIC contributes to increased precision and accuracy in the prediction of chronological age. Results We developed three blood-based epigenetic clocks for human adults using EPIC-based DNA methylation (DNAm) data from the Norwegian Mother, Father and Child Cohort Study (MoBa) and the Gene Expression Omnibus (GEO) public repository: 1) an Adult Blood-based EPIC Clock (ABEC) trained on DNAm data from MoBa (n = 1592, age-span: 19 to 59 years), 2) an extended ABEC (eABEC) trained on DNAm data from MoBa and GEO (n = 2227, age-span: 18 to 88 years), and 3) a common ABEC (cABEC) trained on the same training set as eABEC but restricted to CpGs common to 450 K and EPIC. Our clocks showed high precision (Pearson correlation between chronological and epigenetic age (r) > 0.94) in independent cohorts, including GSE111165 (n = 15), GSE115278 (n = 108), GSE132203 (n = 795), and the Epigenetics in Pregnancy (EPIPREG) study of the STORK Groruddalen Cohort (n = 470). This high precision is unlikely due to the use of EPIC, but rather due to the large sample size of the training set. Conclusions Our ABECs predicted adults’ chronological age precisely in independent cohorts. As EPIC is now the dominant platform for measuring DNAm, these clocks will be useful in further predictions of chronological age, age-related diseases, and mortality.

Published

2020

6. The X-factor in ART: does the use of Assisted Reproductive Technologies influence DNA methylation on the X chromosome?

Author

Julia Romanowska, Haakon E. Nustad, Christian M. Page, William R.P. Denault, Jon Bohlin, Yunsung Lee, Maria C. Magnus, Kristine L. Haftorn, Miriam Gjerdevik, Boris Novakovic, Richard Saffery, Håkon K. Gjessing, Robert Lyle, Per Magnus, Siri E. Håberg, and Astanand Jugessur

Abstract

BackgroundAssisted reproductive technologies (ART) may perturb DNA methylation (DNAm) in early embryonic development. Although a handful of epigenome-wide association studies of ART have been published, none have investigated CpGs on the X chromosome. To bridge this knowledge gap, we leveraged one of the largest collections of mother-father-newborn trios of ART and non-ART (natural) conceptions to date to investigate DNAm differences on the X chromosome.Materials and MethodsThe discovery cohort consisted of 982 ART and 963 non-ART trios from the Norwegian Mother, Father, and Child Cohort Study (MoBa). The replication cohort consisted of 149 ART and 58 non-ART neonates from the Australian “Clinical review of the Health of adults conceived following Assisted Reproductive Technologies” (CHART) study. The Illumina EPIC array was used to measure DNA methylation (DNAm) in both datasets. In the MoBa cohort, we performed a set of X-chromosome-wide association studies (“XWASs” hereafter) to search for sex-specific DNAm differences between ART and non-ART newborns. We tested several models to investigate the influence of various confounders, including parental DNAm. We also searched for differentially methylated regions (DMRs) and regions of co-methylation flanking the most significant CpGs. For replication purposes, we ran an analogous model to our main model on the CHART dataset.Results and conclusionsIn the MoBa cohort, we found more differentially methylated CpGs and DMRs in girls than boys. Most of the associations persisted even after controlling for parental DNAm and other confounders. Many of the significant CpGs and DMRs were in gene-promoter regions, and several of the genes linked to these CpGs are expressed in tissues relevant for both ART and sex (testis, placenta, and fallopian tube). We found no support for parental infertility as an explanation for the observed associations in the newborns. The most significant CpG in the boys-only analysis was inUBE2DNL, which is expressed in testes but with unknown function. The most significant CpGs in the girls-only analysis were inEIF2S3andAMOT. These three loci also displayed differential DNAm in the CHART cohort. Overall, genes that co-localized with the significant CpGs and DMRs are implicated in several key biological processes (e.g., neurodevelopment) and disorders (e.g., intellectual disability and autism. These connections are particularly compelling in light of previous findings indicating that neurodevelopmental outcomes differ in ART-conceived children compared to naturally-conceived.

Published

2022

7. Longitudinal associations of DNA methylation and sleep in children: a meta-analysis

Author

Sara Sammallahti, M. Elisabeth Koopman-Verhoeff, Anne-Claire Binter, Rosa H. Mulder, Alba Cabré-Riera, Tuomas Kvist, Anni L. K. Malmberg, Giancarlo Pesce, Sabine Plancoulaine, Jonathan A. Heiss, Sheryl L. Rifas-Shiman, Stefan W. Röder, Anne P. Starling, Rory Wilson, Kathrin Guerlich, Kristine L. Haftorn, Christian M. Page, Annemarie I. Luik, Henning Tiemeier, Janine F. Felix, Katri Raikkonen, Jari Lahti, Caroline L. Relton, Gemma C. Sharp, Melanie Waldenberger, Veit Grote, Barbara Heude, Isabella Annesi-Maesano, Marie-France Hivert, Ana C. Zenclussen, Gunda Herberth, Dana Dabelea, Regina Grazuleviciene, Marina Vafeiadi, Siri E. Håberg, Stephanie J. London, Mònica Guxens, Rebecca C. Richmond, Charlotte A. M. Cecil, Child and Adolescent Psychiatry / Psychology, Pediatrics, Epidemiology, Erasmus MC other, HUS Gynecology and Obstetrics, Department of Obstetrics and Gynecology, Department of Psychology and Logopedics, Developmental Psychology Research Group, and University of Helsinki

Subjects

Epigenomics, Sleep Wake Disorders, BLOOD, DISORDERS, 515 Psychology, Methylation, Epigenesis, Genetic, Sleep Wake Disorders/genetics, Epigenome, Actigraphy, Child, Longitudinal Studies, Meta-analysis, Sleep, Genetics, Humans, EXPOSURE, Molecular Biology, Genetics (clinical), RISK, Longitudinal studies, WIDE, DNA Methylation, PREGNANCY, DISCOVERY, Sleep/genetics, Developmental Biology

Abstract

BackgroundSleep is important for healthy functioning in children. Numerous genetic and environmental factors, from conception onwards, may influence this phenotype. Epigenetic mechanisms such as DNA methylation have been proposed to underlie variation in sleep or may be an early-life marker of sleep disturbances. We examined if DNA methylation at birth or in school age is associated with parent-reported and actigraphy-estimated sleep outcomes in children.MethodsWe meta-analysed epigenome-wide association study results. DNA methylation was measured from cord blood at birth in 11 cohorts and from peripheral blood in children (4–13 years) in 8 cohorts. Outcomes included parent-reported sleep duration, sleep initiation and fragmentation problems, and actigraphy-estimated sleep duration, sleep onset latency and wake-after-sleep-onset duration.ResultsWe found no associations between DNA methylation at birth and parent-reported sleep duration (n = 3658), initiation problems (n = 2504), or fragmentation (n = 1681) (pvalues above cut-off 4.0 × 10–8). Lower methylation atcg24815001andcg02753354at birth was associated with longer actigraphy-estimated sleep duration (p = 3.31 × 10–8,n = 577) and sleep onset latency (p = 8.8 × 10–9,n = 580), respectively. DNA methylation in childhood was not cross-sectionally associated with any sleep outcomes (n = 716–2539).ConclusionDNA methylation, at birth or in childhood, was not associated with parent-reported sleep. Associations observed with objectively measured sleep outcomes could be studied further if additional data sets become available.

Published

2022

8. DNA methylation in newborns conceived by assisted reproductive technology

Author

Siri E, Håberg, Christian M, Page, Yunsung, Lee, Haakon E, Nustad, Maria C, Magnus, Kristine L, Haftorn, Ellen Ø, Carlsen, William R P, Denault, Jon, Bohlin, Astanand, Jugessur, Per, Magnus, Håkon K, Gjessing, and Robert, Lyle

Subjects

Reproductive Techniques, Assisted, Fertilization, Infertility, Infant, Newborn, Humans, Fertilization in Vitro, DNA Methylation

Abstract

Assisted reproductive technology (ART) may affect fetal development through epigenetic mechanisms as the timing of ART procedures coincides with the extensive epigenetic remodeling occurring between fertilization and embryo implantation. However, it is unknown to what extent ART procedures alter the fetal epigenome. Underlying parental characteristics and subfertility may also play a role. Here we identify differences in cord blood DNA methylation, measured using the Illumina EPIC platform, between 962 ART conceived and 983 naturally conceived singleton newborns. We show that ART conceived newborns display widespread differences in DNA methylation, and overall less methylation across the genome. There were 607 genome-wide differentially methylated CpGs. We find differences in 176 known genes, including genes related to growth, neurodevelopment, and other health outcomes that have been associated with ART. Both fresh and frozen embryo transfer show DNA methylation differences. Associations persist after controlling for parents' DNA methylation, and are not explained by parental subfertility.

Published

2021