{"title":"Pan-Tissue Aging Clock Genes That Have Intimate Connections with the Immune System and Age-Related Disease.","authors":"Adiv A Johnson, Maxim N Shokhirev","doi":"10.1089/rej.2021.0012","DOIUrl":null,"url":null,"abstract":"<p><p>In our recent transcriptomic meta-analysis, we used random forest machine learning to accurately predict age in human blood, bone, brain, heart, and retina tissues given gene inputs. Although each tissue-specific model utilized a unique number of genes for age prediction, we found that the following six genes were prioritized in all five tissues: <i>CHI3L2</i>, <i>CIDEC</i>, <i>FCGR3A</i>, <i>RPS4Y1</i>, <i>SLC11A1</i>, and <i>VTCN1</i>. Since being selected for age prediction in multiple tissues is unique, we decided to explore these pan-tissue clock genes in greater detail. In the present study, we began by performing over-representation and network topology-based enrichment analyses in the Gene Ontology Biological Process database. These analyses revealed that the immunological terms \"response to protozoan,\" \"immune response,\" and \"positive regulation of immune system process\" were significantly enriched by these clock inputs. Expression analyses in mouse and human tissues identified that these inputs are frequently upregulated or downregulated with age. A detailed literature search showed that all six genes had noteworthy connections to age-related disease. For example, mice deficient in <i>Cidec</i> are protected against various metabolic defects, while suppressing VTCN1 inhibits age-related cancers in mouse models. Using a large multitissue transcriptomic dataset, we additionally generate a novel, minimalistic aging clock that can predict human age using just these six genes as inputs. Taken all together, these six genes are connected to diverse aspects of aging.</p>","PeriodicalId":20979,"journal":{"name":"Rejuvenation research","volume":"24 5","pages":"377-389"},"PeriodicalIF":2.2000,"publicationDate":"2021-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Rejuvenation research","FirstCategoryId":"3","ListUrlMain":"https://doi.org/10.1089/rej.2021.0012","RegionNum":4,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"GERIATRICS & GERONTOLOGY","Score":null,"Total":0}
引用次数: 2
Abstract
In our recent transcriptomic meta-analysis, we used random forest machine learning to accurately predict age in human blood, bone, brain, heart, and retina tissues given gene inputs. Although each tissue-specific model utilized a unique number of genes for age prediction, we found that the following six genes were prioritized in all five tissues: CHI3L2, CIDEC, FCGR3A, RPS4Y1, SLC11A1, and VTCN1. Since being selected for age prediction in multiple tissues is unique, we decided to explore these pan-tissue clock genes in greater detail. In the present study, we began by performing over-representation and network topology-based enrichment analyses in the Gene Ontology Biological Process database. These analyses revealed that the immunological terms "response to protozoan," "immune response," and "positive regulation of immune system process" were significantly enriched by these clock inputs. Expression analyses in mouse and human tissues identified that these inputs are frequently upregulated or downregulated with age. A detailed literature search showed that all six genes had noteworthy connections to age-related disease. For example, mice deficient in Cidec are protected against various metabolic defects, while suppressing VTCN1 inhibits age-related cancers in mouse models. Using a large multitissue transcriptomic dataset, we additionally generate a novel, minimalistic aging clock that can predict human age using just these six genes as inputs. Taken all together, these six genes are connected to diverse aspects of aging.
期刊介绍:
Rejuvenation Research publishes cutting-edge, peer-reviewed research on rejuvenation therapies in the laboratory and the clinic. The Journal focuses on key explorations and advances that may ultimately contribute to slowing or reversing the aging process, and covers topics such as cardiovascular aging, DNA damage and repair, cloning, and cell immortalization and senescence.
Rejuvenation Research coverage includes:
Cell immortalization and senescence
Pluripotent stem cells
DNA damage/repair
Gene targeting, gene therapy, and genomics
Growth factors and nutrient supply/sensing
Immunosenescence
Comparative biology of aging
Tissue engineering
Late-life pathologies (cardiovascular, neurodegenerative and others)
Public policy and social context.