Single-mitosis dissection of acute and chronic DNA mutagenesis and repair.
Paul Adrian GinnoHelena BorgersChristina ErnstAnja SchneiderMikaela BehmSarah J AitkenMartin S TaylorDuncan T OdomPublished in: Nature genetics (2024)
How chronic mutational processes and punctuated bursts of DNA damage drive evolution of the cancer genome is poorly understood. Here, we demonstrate a strategy to disentangle and quantify distinct mechanisms underlying genome evolution in single cells, during single mitoses and at single-strand resolution. To distinguish between chronic (reactive oxygen species (ROS)) and acute (ultraviolet light (UV)) mutagenesis, we microfluidically separate pairs of sister cells from the first mitosis following burst UV damage. Strikingly, UV mutations manifest as sister-specific events, revealing mirror-image mutation phasing genome-wide. In contrast, ROS mutagenesis in transcribed regions is reduced strand agnostically. Successive rounds of genome replication over persisting UV damage drives multiallelic variation at CC dinucleotides. Finally, we show that mutation phasing can be resolved to single strands across the entire genome of liver tumors from F1 mice. This strategy can be broadly used to distinguish the contributions of overlapping cancer relevant mutational processes.
Keyphrases
- genome wide
- dna damage
- reactive oxygen species
- crispr cas
- oxidative stress
- liver failure
- papillary thyroid
- dna methylation
- drug induced
- type diabetes
- cell death
- magnetic resonance
- young adults
- computed tomography
- squamous cell carcinoma
- metabolic syndrome
- cell proliferation
- single molecule
- lymph node metastasis
- adipose tissue
- signaling pathway
- dna repair
- high fat diet induced
- hepatitis b virus
- circulating tumor
- endoplasmic reticulum stress
- cell free
- wild type