Abstract
Understanding how pollinator behavior may influence pollen transmission across floral types is a major challenge, as pollinator decision depends on a complex range of environmental cues and prior experience. Here we report an experiment using the plant Antirrhinum majus and the bumblebee Bombus terrestris to investigate how prior learning experience may affect pollinator preferences between floral types when these are presented together. We trained naive bumblebees to forage freely on flowering individuals of either A. majus pseudomajus (magenta flowers) or A. majus striatum (yellow flowers) in a flight cage. We then used a Y-maze device to expose trained bumblebees to a dual choice between the floral types. We tested the influence of training on their choice, depending on the type of plant signals available (visual signals, olfactory signals, or both). Bumblebees had no innate preference for either subspecies. Bumblebees trained on the yellow-flowered subspecies later preferred the yellow type, even when only visual or only olfactory signals were available, and their preference was not reinforced when both signal types were available. In contrast, bumblebees trained on the magenta-flowered subspecies showed no further preference between floral types and took slightly more time to make their choice. Since pollinator constancy has been observed in wild populations of A. majus with mixed floral types, we suggest that such constancy likely relies on short-term memory rather than acquired preference through long-term memory induced by prior learning.
Highlights
A large proportion of plants are insect-pollinated, and pollinator behavior may impact plant evolutionary dynamics
Of the 152 Volatile organic compounds (VOCs) measured in floral scent samples, three were found to occur significantly more in A. m. striatum than in A. m. pseudomajus: hexanal (Chi2 = 4.32, df = 1, P = 0.038); heptanal (Chi2 = 4.08, df = 1, P = 0.043), and one unidentified fatty acid derivative (Chi2 = 4.08, df = 1, P = 0.043)
The PLS-DA based on VOC absolute emission rates successfully discriminated the floral scent profiles of plants of the two subspecies, with 11 VOCs explaining much of the variance among plants (Fig 4)
Summary
A large proportion of plants are insect-pollinated, and pollinator behavior may impact plant evolutionary dynamics. Since pollinators mediate pollen flow, they may strongly affect overall plant gene flow [1]. An abundant literature has focused on pollination syndromes, i.e. the PLOS ONE | DOI:10.1371/journal.pone.0130225. Prior Learning Combined to Floral Signals Affect Pollinator Choice.
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