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dc.contributor.authorBinaghi, Martapt_BR
dc.contributor.authorEsfeld, Korinnapt_BR
dc.contributor.authorMandel, Theresept_BR
dc.contributor.authorFreitas, Loreta Brandão dept_BR
dc.contributor.authorRoesti , Mariuspt_BR
dc.contributor.authorKuhlemeier, Crispt_BR
dc.date.accessioned2023-11-30T03:24:25Zpt_BR
dc.date.issued2023pt_BR
dc.identifier.issn1741-7007pt_BR
dc.identifier.urihttp://hdl.handle.net/10183/267846pt_BR
dc.description.abstractBackground: Theory suggests that the genetic architecture of traits under divergent natural selection influences how easily reproductive barriers evolve and are maintained between species. Divergently selected traits with a simple genetic architecture (few loci with major phenotypic effects) should facilitate the establishment and maintenance of reproductive isolation between species that are still connected by some gene flow. While empirical support for this idea appears to be mixed, most studies test the influence of trait architectures on reproductive isolation only indirectly. Petunia plant species are, in part, reproductively isolated by their different pollinators. To investigate the genetic causes and consequences of this ecological isolation, we deciphered the genetic architecture of three floral pollination syndrome traits in naturally occurring hybrids between the widespread Petunia axillaris and the highly endemic and endangered P. exserta. Results Using population genetics, Bayesian linear mixed modelling and genome-wide association studies, we found that the three pollination syndrome traits vary in genetic architecture. Few genome regions explain a majority of the variation in flavonol content (defining UV floral colour) and strongly predict the trait value in hybrids irrespective of interspecific admixture in the rest of their genomes. In contrast, variation in pistil exsertion and anthocyanin content (defining visible floral colour) is controlled by many genome-wide loci. Opposite to flavonol content, the genome-wide proportion of admixture between the two species predicts trait values in their hybrids. Finally, the genome regions strongly associated with the traits do not show extreme divergence between individuals representing the two species, suggesting that divergent selection on these genome regions is relatively weak within their contact zones. Conclusions: Among the traits analysed, those with a more complex genetic architecture are best maintained in association with the species upon their secondary contact. We propose that this maintained genotype–phenotype association is a coincidental consequence of the complex genetic architectures of these traits: some of their many underlying small-effect loci are likely to be coincidentally linked with the actual barrier loci keeping these species partially isolated upon secondary contact. Hence, the genetic architecture of a trait seems to matter for the outcome of hybridization not only then when the trait itself is under selection.en
dc.format.mimetypeapplication/pdfpt_BR
dc.language.isoengpt_BR
dc.relation.ispartofBMC biology. London. Vol. 21 (Mar. 2023), e58, 13 p.pt_BR
dc.rightsOpen Accessen
dc.subjectAdaptive divergenceen
dc.subjectMorfologiapt_BR
dc.subjectBiotic selectionen
dc.subjectPetúniapt_BR
dc.subjectPollination syndromeen
dc.subjectIsolamento reprodutivopt_BR
dc.subjectSecondary contacten
dc.titleGenetic architecture of a pollinator shift and its fate in secondary hybrid zones of two Petunia speciespt_BR
dc.typeArtigo de periódicopt_BR
dc.identifier.nrb001170440pt_BR
dc.type.originEstrangeiropt_BR


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