Selection strategies for randomly partitioned genetic replicators

TL;DR

This paper analyzes how random partitioning of replicators into compartments affects natural selection, showing that multiple occupancy can be beneficial and that the negative effects are often minimal or reversible.

Contribution

It derives mathematical models for selection in randomly partitioned replicator systems, highlighting conditions where multiple occupancy enhances selection efficiency.

Findings

Multiple occupancy has a limited negative impact on selection.

Higher mean occupancy improves phenotypic diversity exploration.

In some cases, multiple occupancy effects can be nullified.

Abstract

The amplification cycle of many replicators (natural or artificial) involves the usage of a host compartment, inside of which the replicator express phenotypic compounds necessary to carry out its genetic replication. For example, viruses infect cells, where they express their own proteins and replicate. In this process, the host cell boundary limits the diffusion of the viral protein products, thereby ensuring that phenotypic compounds, such as proteins, promote the replication of the genes that encoded them. This role of maintaining spatial co-localization, also called genotype-phenotype linkage, is a critical function of compartments in natural selection. In most cases however, individual replicating elements do not distribute systematically among the hosts, but are randomly partitioned. Depending on the replicator-to-host ratio, more than one variant may thus occupy some compartments, blurring the genotype-phenotype linkage and affecting the effectiveness of natural selection. We derive selection equations for a variety of such random multiple occupancy situations, in particular considering the effect of replicator population polymorphism and internal replication dynamics. We conclude that the deleterious effect of random multiple occupancy on selection is relatively benign, and may even completely vanish is some specific cases. In addition, given that higher mean occupancy allows larger populations to be channeled through the selection process, and thus provide a better exploration of phenotypic diversity, we show that it may represent a valid strategy in both natural and technological cases.