English

Sequential mutations in exponentially growing populations

Populations and Evolution 2023-07-07 v3 Probability

Abstract

Stochastic models of sequential mutation acquisition are widely used to quantify cancer and bacterial evolution. Across manifold scenarios, recurrent research questions are: how many cells are there with nn alterations, and how long will it take for these cells to appear. For exponentially growing populations, these questions have been tackled only in special cases so far. Here, within a multitype branching process framework, we consider a general mutational path where mutations may be advantageous, neutral or deleterious. In the biologically relevant limiting regimes of large times and small mutation rates, we derive probability distributions for the number, and arrival time, of cells with n mutations. Surprisingly, the two quantities respectively follow Mittag-Leffler and logistic distributions regardless of nn or the mutations' selective effects. Our results provide a rapid method to assess how altering the fundamental division, death, and mutation rates impacts the arrival time, and number, of mutant cells. We highlight consequences for mutation rate inference in fluctuation assays.

Keywords

Cite

@article{arxiv.2208.02088,
  title  = {Sequential mutations in exponentially growing populations},
  author = {Michael D. Nicholson and David Cheek and Tibor Antal},
  journal= {arXiv preprint arXiv:2208.02088},
  year   = {2023}
}
R2 v1 2026-06-25T01:26:56.130Z