Abstract
Distyly, a special polymorph, has evolved in many groups of angiosperms and has attracted attention since Darwin’s time. Development studies on distylous taxa have helped us to understand the evolutionary process of this polymorph, but most of these studies focus on species with narrowly tubular corolla. Here, we studied the floral development of Polygonum jucundum, a distylous species with broadly open flowers, at multiple spatial scales. Results showed that the difference in stigma height between flowers of the two morphs was caused by differences in style growth throughout the entire floral development process. The observed difference in anther heights between the two morphs was because the filaments grew faster in short-styled (SS) than in long-styled (LS) flowers in the later stages of floral development. In addition, the longer styles in LS flowers than in SS flowers was because of faster cell division in the early stages of floral development. However, SS flowers had longer filaments than LS flowers primarily because of greater cell elongation. These results indicate that floral development in P. jucundum differs from that of distylous taxa with floral tubes shown in previous studies. Further, we conclude that the presence of distyly in species with open flowers is a result of convergent evolution.
Highlights
Is a unique polymorph of the reproductive structure in plants, a phenomenon that has no parallel in the animal kingdom [1,2]
We investigate the floral development of Polygonum jucundum at multiple spatial scales in order to answer the following questions: (1) how does floral-organ development differ between LS and SS flowers in P. jucundum; (2) how do histological processes influence this macroscopic difference; and (3) what is the probable evolution pattern of the dimorph in this distylous species
Stigma and anther heights were assessed to determine the difference in the developmental process among the reproductive organs in a flower
Summary
Is a unique polymorph of the reproductive structure in plants, a phenomenon that has no parallel in the animal kingdom [1,2]. Heterostylous species could be divided into distylous and tristylous taxa. The tristylous taxa consist of three morphs, in which the stigma-height of each morph differs from the other two [1,3,4,5]. The polymorphic structure in heterostylous species is designed to improve the accuracy of pollen transfer between different morphs, ensuring the outbreeding of these species [5,6]. In 28 families with heterostyly, the distylous morph is more prevalent and has recently attracted great attention from botanists [2,4,7,8,9,10,11,12]
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