David Bröderbauer1, Anita Diaz, Anton Weber. 1. Department of Structural and Functional Botany, University of Vienna, Rennweg 14, 1030 Wien, Österreich. david.broederbauer@univie.ac.at
Abstract
PREMISE OF THE STUDY: Floral traps are among the most sophisticated devices that have evolved in angiosperms in the context of pollination, but the evolution of trap pollination has not yet been studied in a phylogenetic context. We aim to determine the evolutionary history of morphological traits that facilitate trap pollination and to elucidate the impact of pollinators on the evolution of inflorescence traps in the family Araceae. • METHODS: Inflorescence morphology was investigated to determine the presence of trapping devices and to classify functional types of traps. We inferred phylogenetic relationships in the family using maximum likelihood and Bayesian methods. Character evolution of trapping devices, trap types, and pollinator types was then assessed with maximum parsimony and Bayesian methods. We also tested for an association of trap pollination with specific pollinator types. • KEY RESULTS: Inflorescence traps have evolved independently at least 10 times within the Araceae. Trapping devices were found in 27 genera. On the basis of different combinations of trapping devices, six functional types of traps were identified. Trap pollination in Araceae is correlated with pollination by flies. • CONCLUSIONS: Trap pollination in the Araceae is more common than was previously thought. Preadaptations such as papillate cells or elongated sterile flowers facilitated the evolution of inflorescence traps. In some clades, imperfect traps served as a precursor for the evolution of more elaborate traps. Traps that evolved in association with fly pollination were most probably derived from mutualistic ancestors, offering a brood-site to their pollinators.
PREMISE OF THE STUDY: Floral traps are among the most sophisticated devices that have evolved in angiosperms in the context of pollination, but the evolution of trap pollination has not yet been studied in a phylogenetic context. We aim to determine the evolutionary history of morphological traits that facilitate trap pollination and to elucidate the impact of pollinators on the evolution of inflorescence traps in the family Araceae. • METHODS: Inflorescence morphology was investigated to determine the presence of trapping devices and to classify functional types of traps. We inferred phylogenetic relationships in the family using maximum likelihood and Bayesian methods. Character evolution of trapping devices, trap types, and pollinator types was then assessed with maximum parsimony and Bayesian methods. We also tested for an association of trap pollination with specific pollinator types. • KEY RESULTS: Inflorescence traps have evolved independently at least 10 times within the Araceae. Trapping devices were found in 27 genera. On the basis of different combinations of trapping devices, six functional types of traps were identified. Trap pollination in Araceae is correlated with pollination by flies. • CONCLUSIONS: Trap pollination in the Araceae is more common than was previously thought. Preadaptations such as papillate cells or elongated sterile flowers facilitated the evolution of inflorescence traps. In some clades, imperfect traps served as a precursor for the evolution of more elaborate traps. Traps that evolved in association with fly pollination were most probably derived from mutualistic ancestors, offering a brood-site to their pollinators.
Authors: Natalie Cusimano; Josef Bogner; Simon J Mayo; Peter C Boyce; Sin Y Wong; Michael Hesse; Wilbert L A Hetterscheid; Richard C Keating; Jim C French Journal: Am J Bot Date: 2011-03-30 Impact factor: 3.844
Authors: Danae Laina; Eva Gfrerer; Valerie Scheurecker; Roman Fuchs; Marielle Schleifer; Carina Zittra; Rüdiger Wagner; Marc Gibernau; Hans Peter Comes; Anja C Hörger; Stefan Dötterl Journal: Front Plant Sci Date: 2022-03-08 Impact factor: 5.753