The role of genome and gene regulatory network canalization in the evolution of multi-trait polymorphisms and sympatric speciation
Authored by Paulien Hogeweg, Tusscher Kirsten H W J ten
Date Published: 2009
DOI: 10.1186/1471-2148-9-159
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Platforms:
R
Model Documentation:
Other Narrative
Mathematical description
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Abstract
Background: Sexual reproduction has classically been considered as a
barrier to the buildup of discrete phenotypic differentiation. This
notion has been confirmed by models of sympatric speciation in which a
fixed genetic architecture and a linear genotype phenotype mapping were
assumed. In this paper we study the influence of a flexible genetic
architecture and non-linear genotype phenotype map on differentiation
under sexual reproduction.
We use an individual based model in which organisms have a genome
containing genes and transcription factor binding sites. Mutations
involve single genes or binding sites or stretches of genome. The genome
codes for a regulatory network that determines the gene expression
pattern and hence the phenotype of the organism, resulting in a
non-linear genotype phenotype map. The organisms compete in a
multi-niche environment, imposing selection for phenotypic
differentiation.
Results: We find as a generic outcome the evolution of discrete clusters
of organisms adapted to different niches, despite random mating.
Organisms from different clusters are distinct on the genotypic, the
network and the phenotypic level. However, the genome and network
differences are constrained to a subset of the genome locations, a
process we call genotypic canalization. We demonstrate how this
canalization leads to an increased robustness to recombination and
increasing hybrid fitness. Finally, in case of assortative mating, we
explain how this canalization increases the effectiveness of
assortativeness.
Conclusion: We conclude that in case of a flexible genetic architecture
and a non-linear genotype phenotype mapping, sexual reproduction does
not constrain phenotypic differentiation, but instead constrains the
genotypic differences underlying it. We hypothesize that, as genotypic
canalization enables differentiation despite random mating and increases
the effectiveness of assortative mating, sympatric speciation is more
likely than is commonly suggested.
Tags
sexual selection
Yeast
neutral evolution
Mathematical-models
Ecological speciation
Cichlid fish
Dependent disruptive selection
Heliconius butterflies
Bacterial speciation
Adaptive evolution