| Literature DB >> 35102275 |
Chao Shi1,2, Shuo Wang3,4, Hao-Hong Cai1, Hong-Rui Zhang1, Xiao-Xuan Long1, Erik Tihelka5, Wei-Cai Song1, Qi Feng1, Ri-Xin Jiang1, Chen-Yang Cai6, Natasha Lombard7, Xiong Li8, Ji Yuan9, Jian-Ping Zhu10, Hui-Yu Yang1, Xiao-Fan Liu1, Qiao-Ping Xiang11, Zun-Tian Zhao10, Chun-Lin Long12, Harald Schneider13,14, Xian-Chun Zhang11, Hua Peng2, De-Zhu Li8, Yong Fan15, Michael S Engel16, Yong-Dong Wang6, Robert A Spicer17,18.
Abstract
The rapid Cretaceous diversification of flowering plants remains Darwin's 'abominable mystery' despite numerous fossil flowers discovered in recent years. Wildfires were frequent in the Cretaceous and many such early flower fossils are represented by charcoalified fragments, lacking complete delicate structures and surface textures, making their similarity to living forms difficult to discern. Furthermore, scarcity of information about the ecology of early angiosperms makes it difficult to test hypotheses about the drivers of their diversification, including the role of fire in shaping flowering plant evolution. We report the discovery of two exquisitely preserved fossil flower species, one identical to the inflorescences of the extant crown-eudicot genus Phylica and the other recovered as a sister group to Phylica, both preserved as inclusions together with burned plant remains in Cretaceous amber from northern Myanmar (~99 million years ago). These specialized flower species, named Phylica piloburmensis sp. nov. and Eophylica priscastellata gen. et sp. nov., exhibit traits identical to those of modern taxa in fire-prone ecosystems such as the fynbos of South Africa, and provide evidence of fire adaptation in angiosperms.Entities:
Mesh:
Substances:
Year: 2022 PMID: 35102275 DOI: 10.1038/s41477-021-01091-w
Source DB: PubMed Journal: Nat Plants ISSN: 2055-0278 Impact factor: 15.793