Abstract
Despite extensive theory, little is known about the empirical accumulation and evolutionary timing of mutations that contribute to speciation. Here we combined QTL (Quantitative Trait Loci) analyses of reproductive isolation, with information on species evolutionary relationships, to reconstruct the order and timing of mutations contributing to reproductive isolation between three plant (Solanum) species. To evaluate whether reproductive isolation QTL that appear to coincide in more than one species pair are homologous, we used cross-specific tests of allelism and found evidence for both homologous and lineage-specific (non-homologous) alleles at these co-localized loci. These data, along with isolation QTL unique to single species pairs, indicate that >85% of isolation-causing mutations arose later in the history of divergence between species. Phylogenetically explicit analyses of these data support non-linear models of accumulation of hybrid incompatibility, although the specific best-fit model differs between seed (pairwise interactions) and pollen (multi-locus interactions) sterility traits. Our findings corroborate theory that predicts an acceleration (‘snowballing’) in the accumulation of isolation loci as lineages progressively diverge, and suggest different underlying genetic bases for pollen versus seed sterility. Pollen sterility in particular appears to be due to complex genetic interactions, and we show this is consistent with a snowball model where later arising mutations are more likely to be involved in pairwise or multi-locus interactions that specifically involve ancestral alleles, compared to earlier arising mutations.
Highlights
New species evolve via the accumulation of genetic changes that confer ecological differences and, in sexually reproducing organisms, reproductive isolating barriers
Tests of allelism can be used to assess whether isolation alleles detected between specific species are homologous with co-localized QTL detected in other crosses
In conjunction with data on loci that are unique to single species pairs, we infer the phylogenetic timing of mutations underlying all known reproductive isolation loci among three Solanum species
Summary
New species evolve via the accumulation of genetic changes that confer ecological differences and, in sexually reproducing organisms, reproductive isolating barriers Of these barriers, hybrid sterility and inviability are thought to be due to deleterious interactions between mutations, at two or more loci, that have arisen and fixed in diverging lineages The molecular loci and specific mutations responsible for the expression of hybrid problems have been identified (reviewed in [13,14]) Despite these emerging data, most studies have yet to reveal the precise origin and historical accumulation of hybrid sterility and inviability loci across a genome through time. These data are critical for understanding both the evolutionary dynamics of lineage divergence and the underlying genetics of speciation
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