Occurrence and characteristics of natural hybridization in Begonia in China
Received date: 2017-02-20
Accepted date: 2017-06-28
Online published: 2017-07-10
Natural hybridization is a very common phenomenon in plants and has continuously been a hotspot in the scientific research of speciation and evolution. As one of the largest genera in plants, Begonia has a large number of species. However, very few cases have been reported on its natural hybrids. A systematic investigation of natural hybridization of Begonia can not only improve understanding of plant diversity and germplasm resources of this genus, but also be a step towards solving its taxonomical issues. Through a comprehensive field survey and experimental analysis of natural hybridization in Chinese begonias, we found nearly 50 populations of 31 natural hybrids occurred among 29 species, accounting for 15% of currently about 200 accepted species. Begonia hemsleyana and B. longifolia had the highest cross frequency and crossed with 8 and 7 other species, respectively. B. palmata contributed to 16 hybrid populations, the largest number in all individual species. The largest number of hybrids (31 hybrid populations from 20 parental species) occurred in Yunnan (mainly in the southern areas), followed by Taiwan and Guangxi. Hybridization between species was unidirectional in most cases, and the majority of hybrids were F1 individuals, which still rely on parents or hybridization zones and have not been established as a true species. Field observations showed that aphid flies, followed by members of the bee family (Apidae), were the most frequent visitors of begonia flowers, however, further studies are necessary to examine their behavior and the efficiency of pollination. The natural hybrids and their putative parents were identified using integrative methods of morphology, molecular research, and artificial crossing experiments. Genome size (C value) of hybrids was usually equal or close to the average of that of the two parents, with an error less than 10%, which could assist identification of hybrids and parents. In addition, we summarized the five conditions necessary for the occurrence of natural hybridization: overlapping or adjacent distributions, concurrent flowering (at least partially overlapping), efficient pollination media, cross compatibility, and suitable microhabitat and climate conditions for seed germination and seedling growth. Based on these, we also predicted future putative parents of about 40 new natural hybrids and possible hybridization sites. Thus far, although all the known natural begonia hybrids have not established as true species, it may be more appropriate to treat them as a special taxon of speciation and evolution, which should be thoroughly investigated and published referring to protocols for publishing a new taxon in the scientific research. Because the individuals of natural hybrids in Begonia are always sparsely distributed in small numbers, and hybrids are not harmful to its parents it increases plant diversity and the chances of obtaining a new ornamental cultivar by natural selection. Therefore, the priority of in situ conservation should be given to regions with natural hybrids and species-rich environments. Meanwhile, for the purpose of ex situ conservation, requiring sufficient planting distance between species should be considered in those species with overlapping flowering time to avoid possible natural hybridization due to high cross-compatibility, particularly in native begonias.
Tian Daike , Li Chun , Xiao Yan , Fu Naifeng , Tong Yi , Wu Ruijuan . Occurrence and characteristics of natural hybridization in Begonia in China[J]. Biodiversity Science, 2017 , 25(6) : 654 -674 . DOI: 10.17520/biods.2017050
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