Periodic Reporting for period 4 - HYPER-INSIGHT (Hypermutated tumors: insight into genome maintenance and cancer vulnerabilities provided by an extreme burden of somatic mutations)
Période du rapport: 2022-08-01 au 2024-01-31
Firstly, we were interested in using mutational patterns observed in tumors to be able to measure the DNA repair capacity and also DNA replication programs of tumor cells. This has implications for understanding how errors occur during DNA copying, and therefore also for occurrence of heritable diseases and cancer (that often result from such errors). We have identified germline variants in DNA repair and replication and chromatin modifying genes that influence somatic mutational processes (Vali-Pour et al 2022 Nature Comms). Furthermore, we characterized the redistribution of mutation risk across chromosomes in response to cell cycle gene alterations like RB1 and TP53 (Salvadores & Supek 2024 Nature Cancer)
Secondly, we were interested in learning more about evolutionary pressures on cancer genes. We addressed this by examining genetic interactions that affect selection on DNA mutations and copy number changes in cancers. This may reveal new mechanisms of carcinogenesis and/or potentially vulnerabilities (conditionally-essential genes) that are important for tumoral cells (Besedina & Supek 2024).
Thirdly, we are continuing our experimentation on various models of hypermutating cells examined on cancer cell lines, such as to be able to support a variety of predictions from computational cancer genomics with experimental data, adding further support to the multitude of evidence we will collect about hypermutating cells. Our discovery of HMCES gene as a synthetic lethal target in APOBEC3A-expressing lung cancer cells (Biayna et al. 2021 PLOS Biol), as well as a identifying particular pattern of clustered mutagenesis by APOBEC3A in cancer genomes (Mas-Ponte & Supek 2020 Nature Genet) are a prime example of how the integration of computational and experimental approaches can uncover novel cancer vulnerabilities. Further, our large scale analysis of cancer cell line genomes for mutational signatures identified widespread links to drug sensitivity, suggesting mutation patterns as a very promising marker for investigating patient stratification in the future (Levatic et al. 2022 Nature Comms).
In addition to these core lines of research, we have continued to develop novel methodologies and resources for the cancer genomics community, building on our successes with tools such as NMDetective (Lindeboom et al. 2019 Nature Genetics) and our framework for reclassifying cancer cell lines by tumor type and subtype (Salvadores et al 2020 Sci Adv). Finally, we devised methodologies for understanding toxicity of CRISPR/Cas9 damage to DNA, and how its toxicity can be avoided by design of CRISPR libraries (Alvarez et al 2022 Nature Comms).