Abstract
The concept of fitness is often reduced to a single component, such as the replication rate in a given habitat. For species with multi-step life cycles, this can be an unjustified oversimplification, as every step of the life cycle can contribute to the overall reproductive success in a specific way. In particular, this applies to microbes that spend part of their life cycles associated to a host. In this case, there is a selection pressure not only on the replication rates, but also on the phenotypic traits associated to migrating from the external environment to the host and vice-versa (i.e., the migration rates). Here, we investigate a simple model of a microbial lineage living, replicating, migrating and competing in and between two compartments: a host and an environment. We perform a sensitivity analysis on the overall growth rate to determine the selection gradient experienced by the microbial lineage. We focus on the direction of selection at each point of the phenotypic space, defining an optimal way for the microbial lineage to increase its fitness. We show that microbes can adapt to the two-compartment life cycle through either changes in replication or migration rates, depending on the initial values of the traits, the initial distribution across the two compartments, the intensity of competition, and the time scales involved in the life cycle versus the time scale of adaptation (which determines the adequate probing time to measure fitness). Overall, our model provides a conceptual framework to study the selection on microbes experiencing a host-associated life cycle.
Highlights
Fitness is a central concept in evolutionary biology, of particular importance for the theory of natural selection
We propose a framework to assess the selection gradient acting upon the lifehistory traits of microbes undergoing a biphasic life cycle, in which they alternate between phases of host association and free-living environmental phases
Out in the wild, microbial lineages are often subject to multi-step life cycles, where they alternate between at least two habitats
Summary
Fitness is a central concept in evolutionary biology, of particular importance for the theory of natural selection. Fitness is often quantified under controlled laboratory conditions, using different proxies such as a net replication rate measured over a limited period of time, or a proportion of habitats successfully colonized. None of these fitness components alone provides a holistic view of what fitness encompasses in natural conditions. Fitness of an individual lineage is a multivariate function of all the life-history traits characterizing its life cycle, and in particular, its reproduction rates within the habitats and, importantly, transmission across habitats
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