Abstract
From conception to death, human cells accumulate somatic mutations in their genomes. These mutations can contribute to the development of cancer and non-malignant diseases and have also been associated with aging. Rapid technological developments in sequencing approaches in the last few years and their application to normal tissues have greatly advanced our knowledge about the accumulation of these mutations during healthy aging. Whole genome sequencing studies have revealed that there are significant differences in mutation burden and patterns across tissues, but also that the mutation rates within tissues are surprisingly constant during adult life. In contrast, recent lineage-tracing studies based on whole-genome sequencing have shown that the rate of mutation accumulation is strongly increased early in life before birth. These early mutations, which can be shared by many cells in the body, may have a large impact on development and the origin of somatic diseases. For example, cancer driver mutations can arise early in life, decades before the detection of the malignancy. Here, we review the recent insights in mutation accumulation and mutagenic processes in normal tissues. We compare mutagenesis early and later in life and discuss how mutation rates and patterns evolve during aging. Additionally, we outline the potential impact of these mutations on development, aging and disease.
Highlights
Every cell in the body contains a unique set of changes to the genome due to the accumulation of somatic mutations during life
It has become clear in recent years that the somatic mutation burden increases remarkably linearly with age in single cells in normal tissues (Blokzijl et al, 2016)
Differentiated granulocytes were found to have a slightly, not significantly, increased mutational load compared to hematopoietic stem cells (Abascal et al, 2021). Both naïve and memory T-lymphocytes showed an increased mutation rate of 22 and 25 SNVs per year compared to the 16 SNVs per year that this study found in hematopoietic stem cells
Summary
Princess Máxima Center for Pediatric Oncology and Oncode Institute, Utrecht, Netherlands. University of Nebraska Medical Center, United States. Specialty section: This article was submitted to Genetics, Genomics and Epigenomics of Aging, a section of the journal
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