Stochastic Multistability of Clonallike States in the Eigen Model: a Fidelity Catastrophe

TL;DR

This paper reveals a stochastic fidelity catastrophe in the Eigen model, showing noise-induced multistability and regime switching between clonal states, especially when the number of variants exceeds population size.

Contribution

It introduces the concept of a fidelity catastrophe caused by stochastic fluctuations, expanding understanding of error thresholds in evolutionary models.

Findings

Fidelity catastrophe occurs due to state-dependent fluctuations.

System exhibits noise-induced multistability with regime switching.

Large number of variants leads to a narrow transition zone between regimes.

Abstract

The Eigen model is a prototypical toy model of evolution that is synonymous with the so-called error catastrophe: when mutation rates are sufficiently high, the genetic variant with the largest replication rate does not occupy the largest fraction of the total population because it acts as a source for the other variants. Here we show that, in the stochastic version of the Eigen model, there is also a fidelity catastrophe. This arises due to the state-dependence of fluctuations and occurs when rates of mutation fall beneath a certain threshold, which we calculate. The result is a type of noise-induced multistability whereupon the system stochastically switches between short-lived regimes of effectively clonal behavior by different genetic variants. Most notably, when the number of possible variants -- typically $\sim4^L$, with $L\gg 1$ the length of the genome -- is significantly larger than the population size, there is only a vanishingly small interval of mutation rates for which the Eigen model is neither in the fidelity- nor error-catastrophe regimes, seemingly subverting traditional expectations for evolutionary systems.