From clonal interference to Poissonian interacting trajectories
Abstract
We consider a population whose size is fixed over the generations, and in which random beneficial mutations arrive at a rate of order per generation. In this so-called Gerrish--Lenski regime, typically a finite number of contending mutations are present together with one resident type. These mutations compete for fixation, a phenomenon addressed as clonal interference. We introduce and study a Poissonian system of interacting trajectories (PIT), and prove that it arises as a large population scaling limit of the logarithmic sizes of the contending clonal subpopulations in a continuous-time Moran model with strong selection. We show that the PIT exhibits an almost surely positive asymptotic rate of fitness increase (speed of adaptation), which turns out to be finite if and only if fitness increments have a finite expectation. We relate this speed to heuristic predictions from the literature. Furthermore, we derive a functional central limit theorem for the fitness of the resident population in the PIT.
Cite
@article{arxiv.2407.00793,
title = {From clonal interference to Poissonian interacting trajectories},
author = {Felix Hermann and Adrián Gonzalez Casanova and Renato Soares dos Santos and András Tóbiás and Anton Wakolbinger},
journal= {arXiv preprint arXiv:2407.00793},
year = {2025}
}
Comments
42 pages, 9 figures; changes in version 5: In the course of the third (minor) revision few texts were added, formulations changed, typos removed. The example in Figure 2 was reworked