Author
Listed:
- Frederick J. H. Whiting
(Institute of Cancer Research
Queen Mary University of London
Queen Mary University of London)
- Maximilian Mossner
(Institute of Cancer Research
Queen Mary University of London)
- Calum Gabbutt
(Institute of Cancer Research
Queen Mary University of London
Imperial College London)
- Christopher Kimberley
(Queen Mary University of London)
- Chris P. Barnes
(University College London)
- Ann-Marie Baker
(Institute of Cancer Research
Queen Mary University of London)
- Erika Yara-Romero
(Institute of Cancer Research)
- Andrea Sottoriva
(Institute of Cancer Research
Human Technopole)
- Richard A. Nichols
(Queen Mary University of London)
- Trevor A. Graham
(Institute of Cancer Research
Queen Mary University of London)
Abstract
Cancer treatment frequently fails due to the evolution of drug-resistant cell phenotypes driven by genetic or non-genetic changes. The origin, timing, and rate of spread of these adaptations are critical for understanding drug resistance mechanisms but remain challenging to observe directly. We present a mathematical framework to infer drug resistance dynamics from genetic lineage tracing and population size data without direct measurement of resistance phenotypes. Simulation experiments demonstrate that the framework accurately recovers ground-truth evolutionary dynamics. Experimental evolution to 5-Fu chemotherapy in colorectal cancer cell lines SW620 and HCT116 validates the framework. In SW620 cells, a stable pre-existing resistant subpopulation was inferred, whereas in HCT116 cells, resistance emerged through phenotypic switching into a slow-growing resistant state with stochastic progression to full resistance. Functional assays, including scRNA-seq and scDNA-seq, validate these distinct evolutionary routes. This framework facilitates rapid characterisation of resistance mechanisms across diverse experimental settings.
Suggested Citation
Frederick J. H. Whiting & Maximilian Mossner & Calum Gabbutt & Christopher Kimberley & Chris P. Barnes & Ann-Marie Baker & Erika Yara-Romero & Andrea Sottoriva & Richard A. Nichols & Trevor A. Graham, 2025.
"Quantitative measurement of phenotype dynamics during cancer drug resistance evolution using genetic barcoding,"
Nature Communications, Nature, vol. 16(1), pages 1-20, December.
Handle:
RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-59479-7
DOI: 10.1038/s41467-025-59479-7
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