Functionally enriched epigenetic clocks reveal tissue-specific discordant aging patterns in individuals with cancer.

IF 5.4 Q1 MEDICINE, RESEARCH & EXPERIMENTAL Communications medicine Pub Date : 2025-04-02 DOI:10.1038/s43856-025-00739-4

Chiara M S Herzog, Elisa Redl, James Barrett, Sepideh Aminzadeh-Gohari, Daniela D Weber, Julia Tevini, Roland Lang, Barbara Kofler, Martin Widschwendter

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Abstract

Background: Aging is a key risk factor for many diseases, including cancer, and a better understanding of its underlying molecular mechanisms may help to prevent, delay, or treat age-related pathologies. Epigenetic alterations such as DNA methylation (DNAme) changes are a hallmark of aging and form the basis of so-called epigenetic clocks, yet their functional relevance and directionality in different organs during disease development is often unclear.

Methods: Here, we link cell-specific age-related DNAme changes with three key hallmarks of aging and cancer (senescence, promoter methylation in genes associated with stem cell fate, and dysregulated proliferation) to comprehensively dissect their association with current and future cancer development, carcinogen exposure or preventive measures, and mortality using data in different organs from over 12,510 human and 105 mouse samples, benchmarking against existing epigenetic clocks.

Results: Our findings offer insights into the association of functionally enriched groups of age-related DNAme changes with cancer, identify sites perturbed earliest during carcinogenesis, as well as those distinct between cancer and reprogramming that could inform strategies to prevent teratoma formation upon in vivo reprogramming. Surprisingly, both mouse and human data reveal accelerated aging in breast cancer tissue but decelerated epigenetic aging in some non-cancer surrogate samples from breast cancer patients, in particular cervical samples.

Conclusions: This work provides evidence for discordant systemic tissue aging in breast cancer.

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功能丰富的表观遗传时钟揭示了癌症个体中组织特异性不一致的衰老模式。

背景：衰老是包括癌症在内的许多疾病的关键风险因素，更好地了解其潜在的分子机制可能有助于预防、延缓或治疗与年龄有关的病症。DNA甲基化（DNAme）变化等表观遗传学改变是衰老的标志，也是所谓表观遗传时钟的基础，但它们在疾病发展过程中与不同器官的功能相关性和方向性往往并不清楚。方法：在此，我们将细胞特异性的年龄相关DNAme变化与衰老和癌症的三个关键标志（衰老、与干细胞命运相关的基因启动子甲基化和增殖失调）联系起来，利用超过12510份人类样本和105份小鼠样本中不同器官的数据，以现有的表观遗传时钟为基准，全面剖析了它们与当前和未来癌症发展、致癌物暴露或预防措施以及死亡率的关系：结果：我们的研究结果有助于深入了解与年龄相关的DNAme变化的功能富集组与癌症的关联，确定致癌过程中最早受到干扰的位点，以及癌症与重编程之间的不同位点，从而为防止体内重编程后畸胎瘤形成的策略提供信息。令人惊讶的是，小鼠和人类的数据都显示乳腺癌组织加速衰老，但乳腺癌患者的一些非癌症替代样本，特别是宫颈样本的表观遗传衰老却在减速：这项研究为乳腺癌不和谐的全身组织衰老提供了证据。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Communications medicine

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