Communications Biology (Mar 2024)

Characterization of tumor evolution by functional clonality and phylogenetics in hepatocellular carcinoma

  • Zeynep Kacar,
  • Eric Slud,
  • Doron Levy,
  • Julián Candia,
  • Anuradha Budhu,
  • Marshonna Forgues,
  • Xiaolin Wu,
  • Arati Raziuddin,
  • Bao Tran,
  • Jyoti Shetty,
  • Yotsawat Pomyen,
  • Jittiporn Chaisaingmongkol,
  • Siritida Rabibhadana,
  • Benjarath Pupacdi,
  • Vajarabhongsa Bhudhisawasdi,
  • Nirush Lertprasertsuke,
  • Chirayu Auewarakul,
  • Suleeporn Sangrajrang,
  • Chulabhorn Mahidol,
  • Mathuros Ruchirawat,
  • Xin Wei Wang

DOI
https://doi.org/10.1038/s42003-024-06040-9
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 11

Abstract

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Abstract Hepatocellular carcinoma (HCC) is a molecularly heterogeneous solid malignancy, and its fitness may be shaped by how its tumor cells evolve. However, ability to monitor tumor cell evolution is hampered by the presence of numerous passenger mutations that do not provide any biological consequences. Here we develop a strategy to determine the tumor clonality of three independent HCC cohorts of 524 patients with diverse etiologies and race/ethnicity by utilizing somatic mutations in cancer driver genes. We identify two main types of tumor evolution, i.e., linear, and non-linear models where non-linear type could be further divided into classes, which we call shallow branching and deep branching. We find that linear evolving HCC is less aggressive than other types. GTF2IRD2B mutations are enriched in HCC with linear evolution, while TP53 mutations are the most frequent genetic alterations in HCC with non-linear models. Furthermore, we observe significant B cell enrichment in linear trees compared to non-linear trees suggesting the need for further research to uncover potential variations in immune cell types within genomically determined phylogeny types. These results hint at the possibility that tumor cells and their microenvironment may collectively influence the tumor evolution process.