Litcius/Paper detail

The genetic basis of floral mechanical isolation between two hummingbird‐pollinated Neotropical understorey herbs

Kathleen M. Kay, Yann Surget‐Groba

2021Molecular Ecology12 citationsDOIOpen Access PDF

Abstract

Floral divergence can contribute to reproductive isolation among plant lineages, and thus provides an opportunity to study the genetics of speciation, including the number, effect size, mode of action and interactions of quantitative trait loci (QTL). Moreover, flowers represent suites of functionally interrelated traits, but it is unclear to what extent the phenotypic integration of the flower is underlain by a shared genetic architecture, which could facilitate or constrain correlated evolution of floral traits. Here, we examine the genetic architecture of floral morphological traits involved in an evolutionary switch from bill to forehead pollen placement between two species of hummingbird-pollinated Neotropical understorey herbs that are reproductively isolated by these floral differences. For the majority of traits, we find multiple QTL of relatively small effect spread throughout the genome. We also find substantial colocalization and alignment of effects of QTL underlying different floral traits that function together to promote outcrossing and reduce heterospecific pollen transfer. Our results are consistent with adaptive pleiotropy or linkage of many co-adapted genes, either of which could have facilitated a response to correlated selection and helped to stabilize divergent phenotypes in the face of low levels of hybridization. Moreover, our results indicate that floral mechanical isolation can be consistent with an infinitesimal model of adaptation.

Topics & Concepts

BiologyGenetic architectureReproductive isolationOutcrossingHummingbirdPleiotropyQuantitative trait locusEvolutionary biologySepalAdaptation (eye)GeneticsPollenPhenotypeBotanyGenePopulationStamenDemographyNeuroscienceSociologyPlant and animal studiesGenetic diversity and population structurePlant Reproductive Biology