Genomic analyses elucidate <i>S</i>‐locus evolution in response to intra‐specific losses of distyly in <i>Primula vulgaris</i>

Mora‐Carrera, E.; Stubbs, R. L.; Potente, G.; Yousefi, N.; Keller, B.; de Vos, J. M.; Szövényi, P.; Conti, E.

doi:10.1002/ece3.10940

Cited by 2 publications

(1 citation statement)

References 94 publications

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“…The most recent common ancestor of the tribe Limonieae was most likely sexual, SI, and pollen-stigma dimorphic 31 . Consequently, SI can be weakened or lost via mutations and/or recombination in the genomic regions controlling the floral dimorphism 39 , 40 , likely resulting in A/cob and B/pap plants with a weakened/disabled SI system or B/cob and A/pap plants with compatible pollen-stigma combinations, respectively. However, the genes controlling the pollen-stigma dimorphism and mutations responsible for its loss remain unknown.…”

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confidence: 99%

Island plants with newly discovered reproductive traits have higher capacity for uniparental reproduction, supporting Baker’s law

Keller,

Alther,

Jiménez

et al. 2024

Sci Rep

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Uniparental reproduction is advantageous when lack of mates limits outcrossing opportunities in plants. Baker’s law predicts an enrichment of uniparental reproduction in habitats colonized via long-distance dispersal, such as volcanic islands. To test it, we analyzed reproductive traits at multiple hierarchical levels and compared seed-set after selfing and crossing experiments in both island and mainland populations of Limonium lobatum, a widespread species that Baker assumed to be self-incompatible because it had been described as pollen-stigma dimorphic, i.e., characterized by floral morphs differing in pollen-surface morphology and stigma-papillae shape that are typically self-incompatible. We discovered new types and combinations of pollen and stigma traits hitherto unknown in the literature on pollen-stigma dimorphism and a lack of correspondence between such combinations and pollen compatibility. Contrary to previous reports, we conclude that Limonium lobatum comprises both self-compatible and self-incompatible plants characterized by both known and previously undescribed combinations of reproductive traits. Most importantly, plants with novel combinations are overrepresented on islands, selfed seed-set is higher in islands than the mainland, and insular plants with novel pollen-stigma trait-combinations disproportionally contribute to uniparental reproduction on islands. Our results thus support Baker’s law, connecting research on reproductive and island biology.

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Section: Introductionmentioning

confidence: 99%

Island plants with newly discovered reproductive traits have higher capacity for uniparental reproduction, supporting Baker’s law

Keller,

Alther,

Jiménez

et al. 2024

Sci Rep

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The Primula edelbergii S‐locus is an example of a jumping supergene

Potente,

Yousefi,

Keller

et al. 2024

Molecular Ecology Resources

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Research on supergenes, non‐recombining genomic regions housing tightly linked genes that control complex phenotypes, has recently gained prominence in genomics. Heterostyly, a floral heteromorphism promoting outcrossing in several angiosperm families, is controlled by the S‐locus supergene. The S‐locus has been studied primarily in closely related Primula species and, more recently, in other groups that independently evolved heterostyly. However, it remains unknown whether genetic architecture and composition of the S‐locus are maintained among species that share a common origin of heterostyly and subsequently diverged across larger time scales. To address this research gap, we present a chromosome‐scale genome assembly of Primula edelbergii, a species that shares the same origin of heterostyly with Primula veris (whose S‐locus has been characterized) but diverged from it 18 million years ago. Comparative genomic analyses between these two species allowed us to show, for the first time, that the S‐locus can ‘jump’ (i.e. translocate) between chromosomes maintaining its function in controlling heterostyly. Additionally, we found that four S‐locus genes were conserved but reshuffled within the supergene, seemingly without affecting their expression, thus we could not detect changes explaining the lack of self‐incompatibility in P. edelbergii. Furthermore, we confirmed that the S‐locus is not undergoing genetic degeneration. Finally, we investigated P. edelbergii evolutionary history within Ericales in terms of whole genome duplications and transposable element accumulation. In summary, our work provides a valuable resource for comparative analyses aimed at investigating the genetics of heterostyly and the pivotal role of supergenes in shaping the evolution of complex phenotypes.

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Genomic analyses elucidate S‐locus evolution in response to intra‐specific losses of distyly in Primula vulgaris

Cited by 2 publications

References 94 publications

Island plants with newly discovered reproductive traits have higher capacity for uniparental reproduction, supporting Baker’s law

Island plants with newly discovered reproductive traits have higher capacity for uniparental reproduction, supporting Baker’s law

The Primula edelbergii S‐locus is an example of a jumping supergene

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