Abstract
Hybridization between tetraploids and their related diploids is generally unsuccessful in Centaurea, hence natural formation of triploid hybrids is rare. In contrast, the diploid Centaurea aspera and the allotetraploid C. seridis coexist in several contact zones where a high frequency of triploid hybrids is found. We analyzed the floral biology of the three taxa to identify reproductive isolation mechanisms that allow their coexistence. Flowering phenology was recorded, and controlled pollinations within and between the three taxa were performed in the field. Ploidy level and germination of progeny were also assessed. There was a 50% flowering overlap which indicated a phenological shift. Diploids were strictly allogamous and did not display mentor effects, while tetraploids were found to be highly autogamous. This breakdown of self-incompatibility by polyploids is first described in Centaurea. The asymmetrical formation of the hybrid was also found: all the triploid intact cypselae came from the diploid mothers pollinated by the pollen of tetraploids. Pollen and eggs from triploids were totally sterile, acting as a strong triploid block. These prezygotic isolation mechanisms ensured higher assortative mating in tetraploids than in diploids, improving their persistence in the contact zones. However these mechanisms can also be the cause of the low genetic diversity and high genetic structure observed in C. seridis.
Highlights
Nowadays there is no doubt about the central role of polyploidization in the evolution of flowering plants [1]
The flowering phenology of C. aspera, C. seridis, and C. × subdecurrens was assessed during a 2-year field observation period (2004 and 2005) at the polyploid complex of El Saler (Valencia)
Centaurea aspera is a species with broad populations from inland to the coast, while C. seridis has a smaller distribution area, located exclusively on the coast and largely overlapped by C. aspera
Summary
Nowadays there is no doubt about the central role of polyploidization in the evolution of flowering plants [1]. (Asteraceae) is a recently evolved genus that presents a high diversification and speciation rate due to the existence of cycles of polyploidy and descending dysploidy, as well as hybridization events [3, 4]. These evolutionary dynamics have led to the existence of several contact zones where diploid and both auto- and allo-polyploid individuals coexist [5,6,7,8,9,10]. Post-zygotic mechanisms act through a lack of germination, a low viability, or a high degree of sterility of the rarely formed triploid hybrids [9, 10]
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