12 research outputs found
Evolution of Competitive Ability: An Adaptation Speed vs. Accuracy Tradeoff Rooted in Gene Network Size
Ecologists have increasingly come to understand that evolutionary change on short
time-scales can alter ecological dynamics (and vice-versa), and this idea is
being incorporated into community ecology research programs. Previous research
has suggested that the size and topology of the gene network underlying a
quantitative trait should constrain or facilitate adaptation and thereby alter
population dynamics. Here, I consider a scenario in which two species with
different genetic architectures compete and evolve in fluctuating environments.
An important trade-off emerges between adaptive accuracy and adaptive speed,
driven by the size of the gene network underlying the ecologically-critical
trait and the rate of environmental change. Smaller, scale-free networks confer
a competitive advantage in rapidly-changing environments, but larger networks
permit increased adaptive accuracy when environmental change is sufficiently
slow to allow a species time to adapt. As the differences in network
characteristics increase, the time-to-resolution of competition decreases. These
results augment and refine previous conclusions about the ecological
implications of the genetic architecture of quantitative traits, emphasizing a
role of adaptive accuracy. Along with previous work, in particular that
considering the role of gene network connectivity, these results provide a set
of expectations for what we may observe as the field of ecological genomics
develops
Gene Networks and Metacommunities: Dispersal Differences Can Override Adaptive Advantage
Dispersal is an important mechanism contributing to both ecological and evolutionary dynamics. In metapopulation and metacommunity ecology, dispersal enables new patches to be colonized; in evolution, dispersal counter-acts local selection, leading to regional homogenization. Here, I consider a three-patch metacommunity in which two species, each with a limiting quantitative trait underlain by gene networks of 16 to 256 genes, compete with one another and disperse among patches. Incorporating dispersal among heterogeneous patches introduces a tradeoff not observed in single-patch simulations: if the difference between gene network size of the two species is greater than the difference in dispersal ability (e.g., if the ratio of network sizes is larger than the ratio of dispersal abilities), then genetic architecture drives community outcome. However, if the difference in dispersal abilities is greater than gene network differences, then any adaptive advantages afforded by genetic architecture are over-ridden by dispersal. Thus, in addition to the selective pressures imposed by competition that shape the genetic architecture of quantitative traits, dispersal among patches creates an escape that may further alter the effects of different genetic architectures. These results provide a theoretical expectation for what we may observe as the field of ecological genomics develops.This work was supported in part by a start-up grant from the University of Texas at Austin. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.Biological Sciences, School o