A Model of Genome Size Evolution for Prokaryotes in Stable and Fluctuating Environments
Authored by Piotr Bentkowski, Oosterhout Cock Van, Thomas Mock
Date Published: 2015
DOI: 10.1093/gbe/evv148
Sponsors:
United Kingdom Natural Environment Research Council (NERC)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
Temporal variability in ecosystems significantly impacts species
diversity and ecosystem productivity and therefore the evolution of
organisms. Different levels of environmental perturbations such as
seasonal fluctuations, natural disasters, and global change have
different impacts on organisms and therefore their ability to
acclimatize and adapt. Thus, to understand how organisms evolve under
different perturbations is a key for predicting how environmental change
will impact species diversity and ecosystem productivity. Here, we
developed a computer simulation utilizing the individual-based model
approach to investigate genome size evolution of a haploid, clonal and
free-living prokaryotic population across different levels of
environmental perturbations. Our results show that a greater variability
of the environment resulted in genomes with a larger number of genes.
Environmental perturbations were more effectively buffered by
populations of individuals with relatively large genomes. Unpredictable
changes of the environment led to a series of population bottlenecks
followed by adaptive radiations. Our model shows that the evolution of
genome size is indirectly driven by the temporal variability of the
environment. This complements the effects of natural selection directly
acting on genome optimization. Furthermore, species that have evolved in
relatively stable environments may face the greatest risk of extinction
under global change as genome streamlining genetically constrains their
ability to acclimatize to the new environmental conditions, unless
mechanisms of genetic diversification such as horizontal gene transfer
will enrich their gene pool and therefore their potential to adapt.
Tags
ecology
Modularity
architecture
In-vivo
Biology
Persistence
Islands
Bacterial genomes
Prochlorococcus
Transients