Kallai Attila, Ungvari Zoltan, Fekete Mónika, Maier Andrea B, Mikala Gabor, Andrikovics Hajnalka, Lehoczki Andrea
Healthy Aging Program, Institute of Preventive Medicine and Public Health, Semmelweis University, Budapest, Hungary.
Doctoral College, Health Sciences Program, Semmelweis University, Budapest, Hungary.
Geroscience. 2025 Feb;47(1):703-720. doi: 10.1007/s11357-024-01374-y. Epub 2024 Oct 15.
Aging is a multifaceted process characterized by a gradual decline in physiological function and increased susceptibility to a range of chronic diseases. Among the molecular and cellular mechanisms driving aging, genomic instability is a fundamental hallmark, contributing to increased mutation load and genetic heterogeneity within cellular populations. This review explores the role of genomic instability and genetic heterogeneity in aging in the hematopoietic system, with a particular focus on clonal hematopoiesis of indeterminate potential (CHIP), monoclonal gammopathy of undetermined significance (MGUS), and monoclonal B-cell lymphocytosis (MBL) as biomarkers. CHIP involves the clonal expansion of hematopoietic stem cells with somatic mutations. In contrast, MGUS is characterized by the presence of clonal plasma cells producing monoclonal immunoglobulins, while MBL is characterized by clonal proliferation of B cells. These conditions are prevalent in the aging population and serve as measurable indicators of underlying genomic instability. Studying these entities offers valuable insights into the mechanisms by which somatic mutations accumulate and drive clonal evolution in the hematopoietic system, providing a deeper understanding of how aging impacts cellular and tissue homeostasis. In summary, the hematopoietic system serves as a powerful model for investigating the interplay between genomic instability and aging. Incorporating age-related hematological conditions into aging research, alongside other biomarkers such as epigenetic clocks, can enhance the precision and predictive power of biological age assessments. These biomarkers provide a comprehensive view of the aging process, facilitating the early detection of age-related diseases and hopefully enabling personalized healthcare strategies.
衰老 是一个多方面的过程,其特征是生理功能逐渐下降,以及对一系列慢性疾病的易感性增加。在驱动衰老的分子和细胞机制中,基因组不稳定是一个基本特征,导致细胞群体中突变负荷增加和遗传异质性增加。本综述探讨了基因组不稳定和遗传异质性在造血系统衰老中的作用,特别关注具有不确定潜能的克隆性造血(CHIP)、意义未明的单克隆丙种球蛋白病(MGUS)和单克隆B淋巴细胞增多症(MBL)作为生物标志物的情况。CHIP涉及具有体细胞突变的造血干细胞的克隆性扩增。相比之下,MGUS的特征是存在产生单克隆免疫球蛋白的克隆性浆细胞,而MBL的特征是B细胞的克隆性增殖。这些情况在老年人群中很普遍,是潜在基因组不稳定的可测量指标。研究这些实体为体细胞突变如何在造血系统中积累并驱动克隆进化的机制提供了有价值的见解,从而更深入地了解衰老如何影响细胞和组织的稳态。总之,造血系统是研究基因组不稳定与衰老之间相互作用的有力模型。将与年龄相关的血液学状况纳入衰老研究,与表观遗传时钟等其他生物标志物一起,可以提高生物年龄评估的准确性和预测能力。这些生物标志物提供了衰老过程的全面视图,有助于早期发现与年龄相关的疾病,并有望实现个性化医疗策略。