Nature Communications (Aug 2024)

DNA methylation and gene expression as determinants of genome-wide cell-free DNA fragmentation

  • Michaël Noë,
  • Dimitrios Mathios,
  • Akshaya V. Annapragada,
  • Shashikant Koul,
  • Zacharia H. Foda,
  • Jamie E. Medina,
  • Stephen Cristiano,
  • Christopher Cherry,
  • Daniel C. Bruhm,
  • Noushin Niknafs,
  • Vilmos Adleff,
  • Leonardo Ferreira,
  • Hari Easwaran,
  • Stephen Baylin,
  • Jillian Phallen,
  • Robert B. Scharpf,
  • Victor E. Velculescu

DOI
https://doi.org/10.1038/s41467-024-50850-8
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 11

Abstract

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Abstract Circulating cell-free DNA (cfDNA) is emerging as an avenue for cancer detection, but the characteristics of cfDNA fragmentation in the blood are poorly understood. We evaluate the effect of DNA methylation and gene expression on genome-wide cfDNA fragmentation through analysis of 969 individuals. cfDNA fragment ends more frequently contained CCs or CGs, and fragments ending with CGs or CCGs are enriched or depleted, respectively, at methylated CpG positions. Higher levels and larger sizes of cfDNA fragments are associated with CpG methylation and reduced gene expression. These effects are validated in mice with isogenic tumors with or without the mutant IDH1, and are associated with genome-wide changes in cfDNA fragmentation in patients with cancer. Tumor-related hypomethylation and increased gene expression are associated with decrease in cfDNA fragment size that may explain smaller cfDNA fragments in human cancers. These results provide a connection between epigenetic changes and cfDNA fragmentation with implications for disease detection.