Narjes Yousefi scite author profile

Supergenes are non-recombining genomic regions ensuring the co-inheritance of multiple, co-adapted genes. Despite the importance of supergenes in adaptation, little is known on how they originate. A classic example of supergene is the S locus controlling heterostyly, a floral heteromorphism occurring in 28 angiosperm families. In Primula, heterostyly is characterized by the co-occurrence of two complementary, self-incompatible floral morphs and is controlled by 5 genes clustered in the hemizygous, ca. 300-kbp S locus. Here we present the first chromosome-scale genome assembly of any heterostylous species, that of Primula veris (cowslip). By leveraging the high contiguity of the P. veris assembly and comparative genomic analyses, we demonstrated that the S-locus evolved via multiple, asynchronous gene duplications and independent gene translocations. Furthermore, we discovered a new whole-genome duplication in Ericales that is specific to the Primula lineage. We also propose a mechanism for the origin of S-locus hemizygosity via nonhomologous recombination involving the newly discovered two pairs of CFB genes flanking the S locus. Finally, we detected only weak signatures of degeneration in the S locus, as predicted for hemizygous supergenes. The present study provides a useful resource for future research addressing key questions on the evolution of supergenes in general and the S locus in particular: How do supergenes arise? What is the role of genome architecture in the evolution of complex adaptations? Is the molecular architecture of heterostyly supergenes across angiosperms similar to that of Primula?

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Sphagnum divinum(sp. nov.) andS. mediumLimpr. and their relationship toS. magellanicumBrid.

Hassel

Kyrkjeeide

Yousefi

et al. 2018

Journal of Bryology

108

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Spatial Genetic Structure of the Abundant and Widespread Peatmoss Sphagnum magellanicum Brid.

et al. 2016

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Spore-producing organisms have small dispersal units enabling them to become widespread across continents. However, barriers to gene flow and cryptic speciation may exist. The common, haploid peatmoss Sphagnum magellanicum occurs in both the Northern and Southern hemisphere, and is commonly used as a model in studies of peatland ecology and peatmoss physiology. Even though it will likely act as a rich source in functional genomics studies in years to come, surprisingly little is known about levels of genetic variability and structuring in this species. Here, we assess for the first time how genetic variation in S. magellanicum is spatially structured across its full distribution range (Northern Hemisphere and South America). The morphologically similar species S. alaskense was included for comparison. In total, 195 plants were genotyped at 15 microsatellite loci. Sequences from two plastid loci (trnG and trnL) were obtained from 30 samples. Our results show that S. alaskense and almost all plants of S. magellanicum in the northern Pacific area are diploids and share the same gene pool. Haploid plants occur in South America, Europe, eastern North America, western North America, and southern Asia, and five genetically differentiated groups with different distribution ranges were found. Our results indicate that S. magellanicum consists of several distinct genetic groups, seemingly with little or no gene flow among them. Noteworthy, the geographical separation of diploids and haploids is strikingly similar to patterns found within other haploid Sphagnum species spanning the Northern Hemisphere. Our results confirm a genetic division between the Beringian and the Atlantic that seems to be a general pattern in Sphagnum taxa. The pattern of strong genetic population structuring throughout the distribution range of morphologically similar plants need to be considered in future functional genomic studies of S. magellanicum.

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Divergent evolution and niche differentiation within the common peatmossSphagnum magellanicum

Yousefi

Hassel

Flatberg

et al. 2017

American J of Botany

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Genetic and morphological variation in the circumpolar distribution range ofSphagnum warnstorfii: indications of vicariant divergence in a common peatmoss

Yousefi

Mikulášková

Stenøien

et al. 2019

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Narjes Yousefi

Comparative Genomics Elucidates the Origin of a Supergene Controlling Floral Heteromorphism

Sphagnum divinum(sp. nov.) andS. mediumLimpr. and their relationship toS. magellanicumBrid.

Spatial Genetic Structure of the Abundant and Widespread Peatmoss Sphagnum magellanicum Brid.

Divergent evolution and niche differentiation within the common peatmossSphagnum magellanicum

Genetic and morphological variation in the circumpolar distribution range ofSphagnum warnstorfii: indications of vicariant divergence in a common peatmoss

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