Tian Mi, Andrew G. Soerens, Shanta Alli, Tae Gun Kang, Anoop Babu Vasandan, Zhaoming Wang, Vaiva Vezys, Shunsuke Kimura, Ilaria Iacobucci, Stephen B. Baylin, Peter A. Jones, Christopher Hiner, April Mueller, Harris Goldstein, Charles G. Mullighan, Caitlin C. Zebley, David Masopust, Ben Youngblood
{"title":"Conserved epigenetic hallmarks of T cell aging during immunity and malignancy","authors":"Tian Mi, Andrew G. Soerens, Shanta Alli, Tae Gun Kang, Anoop Babu Vasandan, Zhaoming Wang, Vaiva Vezys, Shunsuke Kimura, Ilaria Iacobucci, Stephen B. Baylin, Peter A. Jones, Christopher Hiner, April Mueller, Harris Goldstein, Charles G. Mullighan, Caitlin C. Zebley, David Masopust, Ben Youngblood","doi":"10.1038/s43587-024-00649-5","DOIUrl":null,"url":null,"abstract":"Chronological aging correlates with epigenetic modifications at specific loci, calibrated to species lifespan. Such ‘epigenetic clocks’ appear conserved among mammals, but whether they are cell autonomous and restricted by maximal organismal lifespan remains unknown. We used a multilifetime murine model of repeat vaccination and memory T cell transplantation to test whether epigenetic aging tracks with cellular replication and if such clocks continue ‘counting’ beyond species lifespan. Here we found that memory T cell epigenetic clocks tick independently of host age and continue through four lifetimes. Instead of recording chronological time, T cells recorded proliferative experience through modification of cell cycle regulatory genes. Applying this epigenetic profile across a range of human T cell contexts, we found that naive T cells appeared ‘young’ regardless of organism age, while in pediatric patients, T cell acute lymphoblastic leukemia appeared to have epigenetically aged for up to 200 years. Thus, T cell epigenetic clocks measure replicative history and can continue to accumulate well-beyond organismal lifespan. Using an iterative boost and transplantation model to generate multilifetime T cells, Mi et al. show that cellular epigenetic age can be uncoupled from organism age. While naive T cells appear epigenetically young, memory T cells and T-ALL leukemia can exhibit epigenetic ages exceeding the organismal lifespan.","PeriodicalId":94150,"journal":{"name":"Nature aging","volume":"4 8","pages":"1053-1063"},"PeriodicalIF":17.0000,"publicationDate":"2024-06-12","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.nature.com/articles/s43587-024-00649-5.pdf","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Nature aging","FirstCategoryId":"1085","ListUrlMain":"https://www.nature.com/articles/s43587-024-00649-5","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"CELL BIOLOGY","Score":null,"Total":0}
引用次数: 0
Abstract
Chronological aging correlates with epigenetic modifications at specific loci, calibrated to species lifespan. Such ‘epigenetic clocks’ appear conserved among mammals, but whether they are cell autonomous and restricted by maximal organismal lifespan remains unknown. We used a multilifetime murine model of repeat vaccination and memory T cell transplantation to test whether epigenetic aging tracks with cellular replication and if such clocks continue ‘counting’ beyond species lifespan. Here we found that memory T cell epigenetic clocks tick independently of host age and continue through four lifetimes. Instead of recording chronological time, T cells recorded proliferative experience through modification of cell cycle regulatory genes. Applying this epigenetic profile across a range of human T cell contexts, we found that naive T cells appeared ‘young’ regardless of organism age, while in pediatric patients, T cell acute lymphoblastic leukemia appeared to have epigenetically aged for up to 200 years. Thus, T cell epigenetic clocks measure replicative history and can continue to accumulate well-beyond organismal lifespan. Using an iterative boost and transplantation model to generate multilifetime T cells, Mi et al. show that cellular epigenetic age can be uncoupled from organism age. While naive T cells appear epigenetically young, memory T cells and T-ALL leukemia can exhibit epigenetic ages exceeding the organismal lifespan.
时间衰老与特定位点的表观遗传修饰相关,并与物种寿命校准。这种 "表观遗传时钟 "在哺乳动物中似乎是保守的,但它们是否独立于细胞并受限于生物体的最大寿命仍是未知数。我们利用重复接种疫苗和记忆性 T 细胞移植的多寿命小鼠模型来检验表观遗传学衰老是否与细胞复制同步,以及这种时钟是否在物种寿命之后继续 "计数"。在这里,我们发现记忆 T 细胞表观遗传时钟的滴答声不受宿主年龄的影响,并可持续四次寿命。T细胞不记录时间,而是通过细胞周期调控基因的改变来记录增殖经历。将这种表观遗传学特征应用于一系列人类 T 细胞时,我们发现,无论机体年龄如何,天真 T 细胞都显得 "年轻",而在儿科患者中,T 细胞急性淋巴细胞白血病的表观遗传学年龄似乎长达 200 年。因此,T细胞表观遗传时钟可测量复制历史,并可在生物体寿命之外继续积累。