Viral Quasispecies Evolution as a Branching Random Walk on the Hypercube

Abstract

We study a continuous-time nearest-neighbor branching random walk on the d-dimensional b-ary hypercube \0,1,…,b-1\d as a model for viral quasispecies evolution under mutation and replication. Motivated by mutagenic antiviral treatments and evolutionary-safety questions, we analyze the first passage time to a fixed target genotype at Hamming distance m, corresponding to the first appearance of a prescribed collection of mutations. We derive sharp asymptotics for these first passage times, uniformly for m d/L as d∞ (where L>0 is a large constant), and identify a phase transition in first-passage scaling at =e, where denotes the effective growth parameter. In the slow-branching regime ∈(1,e) relevant to mutagenic treatment scenarios, the first passage time is asymptotically affine in the genome length d and the target distance m. In particular, when replication is fixed and mutation exceeds branching, increasing the mutation rate can delay the first appearance of a prescribed genotype by order d, providing a quantitative perspective on evolutionary safety.

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