Department of Mental Health, Johns Hopkins Bloomberg School of Public Health, Baltimore, Maryland, USA.
Wendy Klag Center for Autism and Developmental Disabilities, Johns Hopkins Bloomberg School of Public Health, Baltimore, Maryland, USA.
Autism Res. 2022 Dec;15(12):2359-2370. doi: 10.1002/aur.2822. Epub 2022 Oct 3.
Parental age is a known risk factor for autism spectrum disorder (ASD), however, studies to identify the biologic changes underpinning this association are limited. In recent years, "epigenetic clock" algorithms have been developed to estimate biologic age and to evaluate how the epigenetic aging impacts health and disease. In this study, we examined the relationship between parental epigenetic aging and their child's prospective risk of ASD and autism related quantitative traits in the Early Autism Risk Longitudinal Investigation study. Estimates of epigenetic age were computed using three robust clock algorithms and DNA methylation measures from the Infinium HumanMethylation450k platform for maternal blood and paternal blood specimens collected during pregnancy. Epigenetic age acceleration was defined as the residual of regressing chronological age on epigenetic age while accounting for cell type proportions. Multinomial logistic regression and linear regression models were completed adjusting for potential confounders for both maternal epigenetic age acceleration (n = 163) and paternal epigenetic age acceleration (n = 80). We found accelerated epigenetic aging in mothers estimated by Hannum's clock was significantly associated with lower cognitive ability and function in offspring at 12 months, as measured by Mullen Scales of Early Learning scores (β = -1.66, 95% CI: -3.28, -0.04 for a one-unit increase). We also observed a marginal association between accelerated maternal epigenetic aging by Horvath's clock and increased odds of ASD in offspring at 36 months of age (aOR = 1.12, 95% CI: 0.99, 1.26). By contrast, fathers accelerated aging was marginally associated with decreased ASD risk in their offspring (aOR = 0.83, 95% CI: 0.68, 1.01). Our findings suggest epigenetic aging could play a role in parental age risks on child brain development.
父母年龄是自闭症谱系障碍(ASD)的已知风险因素,但目前用于识别潜在生物学变化的研究还很有限。近年来,已经开发出“表观遗传时钟”算法来估计生物年龄,并评估表观遗传衰老对健康和疾病的影响。在这项研究中,我们检查了父母的表观遗传年龄与他们孩子未来患 ASD 的风险以及在早期自闭症风险纵向研究中自闭症相关定量特征之间的关系。使用三种稳健的时钟算法和基于 Infinium HumanMethylation450k 平台的母体血液和父体血液样本中的 DNA 甲基化测量值来计算表观遗传年龄。表观遗传年龄加速定义为将实际年龄回归到表观遗传年龄时的残差,同时考虑细胞类型比例。对于母体表观遗传年龄加速(n=163)和父体表观遗传年龄加速(n=80),我们完成了多分类逻辑回归和线性回归模型,以调整潜在混杂因素。我们发现,Hannum 时钟估计的母亲表观遗传衰老加速与 12 个月时子女的认知能力和功能显著相关,这可以通过 Mullen 早期学习量表评分来衡量(β=−1.66,95%CI:−3.28,−0.04,一个单位增加)。我们还观察到,Horvath 时钟的母亲表观遗传衰老加速与 36 个月时子女患 ASD 的几率增加存在边缘关联(aOR=1.12,95%CI:0.99,1.26)。相比之下,父亲的衰老加速与子女患 ASD 的风险降低呈边缘关联(aOR=0.83,95%CI:0.68,1.01)。我们的研究结果表明,表观遗传衰老可能在父母年龄对儿童大脑发育的风险中起作用。
