Abstract

BackgroundUp to now, diploid and triploid cultivars were reported for the ornamental crop Hydrangea macrophylla. Especially, the origin of triploids and their crossing behaviors are unknown, but the underlying mechanisms are highly relevant for breeding polyploids.ResultsBy screening a cultivar collection, we identified diploid, triploid, tetraploid and even aneuploid H. macrophylla varieties. The pollen viability of triploids and tetraploids was comparable to that of diploids. Systematic crosses with these cultivars resulted in viable diploid, triploid, tetraploid and aneuploid offspring. Interestingly, crosses between diploids produced diploid and 0 or 1–94% triploid offspring, depending on the cultivars used as pollen parent. This finding suggests that specific diploids form unreduced pollen, either at low or high frequencies. In contrast, crosses of triploids with diploids or tetraploids produced many viable aneuploids, whose 2C DNA contents ranged between the parental 2C values. As expected, crosses between diploid and tetraploid individuals generated triploid offspring. Putative tetraploid plants were obtained at low frequencies in crosses between diploids and in interploid crosses of triploids with either diploid or tetraploid plants. The analysis of offspring populations indicated the production of 1n = 2x gametes for tetraploid plants, whereas triploids produced obviously reduced, aneuploid gametes with chromosome numbers ranging between haploid and diploid level. While euploid offspring grew normally, aneuploid plants showed mostly an abnormal development and a huge phenotypic variation within offspring populations, most likely due to the variation in chromosome numbers. Subsequent crosses with putative diploid, triploid and aneuploid offspring plants from interploid crosses resulted in viable offspring and germination rates ranging from 21 to 100%.ConclusionsThe existence of diploids that form unreduced pollen and of tetraploids allows the targeted breeding of polyploid H. macrophylla. Different ploidy levels can be addressed by combining the appropriate crossing partners. In contrast to artificial polyploidization, cross-based polyploidization is easy, cheap and results in genetically variable offspring that allows the direct selection of more robust and stress tolerant polyploid varieties. Furthermore, the generation of polyploid H. macrophylla plants will favor interspecific breeding programs within the genus Hydrangea.

Highlights

  • Up to now, diploid and triploid cultivars were reported for the ornamental crop Hydrangea macrophylla

  • We aimed to reveal i) to which extent crosses between cultivars of different ploidy levels are successful, ii) whether offspring from interploid crosses is viable and suitable for selection and further crossings, iii) which cross combinations allow the targeted generation of polyploids, iv) which ploidy is existent in gametes produced by diploid, triploid and tetraploid crossing partners

  • Somatic doubling of diploid and triploid H. macrophylla cultivars was previously achieved through Trifluralin-mediated polyploidization, and tetraploid and hexaploid H. macrophylla plants were generated [7]

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Summary

Introduction

Diploid and triploid cultivars were reported for the ornamental crop Hydrangea macrophylla. Polyploid organisms contain more than two complete sets of chromosomes per cell nucleus This often results in an increased fitness, higher yield, improved product quality and better tolerance to abiotic and biotic stresses in comparison with diploid relatives. The production of polyploid plants is an important strategy of crop breeding, especially in ornamental crops. Is an economically important ornamental crop, which belongs to the upmarket segment. This perennial, deciduous species produces attractive foliage and large, colorful inflorescences. Important traits in breeding of H. macrophylla are brightly colored flowers arranged in impressive inflorescences, attractive foliage, remontant flowering as well as compact growth.

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