Organ-specific volatiles from Sonoran desert Krameria flowers as potential signals for oil-collecting bees

The evolution of flowers that offer oils as rewards and are pollinated by specialized bees represents a distinctive theme in plant-pollinator co-diversification. Some plants that offer acetylated glycerols as floral oils emit diacetin, a volatile by-product of oil metabolism, which is utilized by oi...

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Published in:Phytochemistry (Oxford) 2024-02, Vol.218, p.113937-113937, Article 113937
Main Authors: Balbuena, Maria Sol, Buchmann, Stephen L., Papaj, Daniel R., Raguso, Robert A.
Format: Article
Language:English
Subjects:
Animals
Apidae
Bees
Centris cockerelli
Flowers - chemistry
Gas Chromatography-Mass Spectrometry
Krameria bicolor
Krameria erecta
Krameriaceae
Norisoprenoids - analysis
Norisoprenoids - metabolism
Oil collecting bees
Oil flowers
Pollination
Signaling
Volatile organic compounds
β-ionone
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Summary:The evolution of flowers that offer oils as rewards and are pollinated by specialized bees represents a distinctive theme in plant-pollinator co-diversification. Some plants that offer acetylated glycerols as floral oils emit diacetin, a volatile by-product of oil metabolism, which is utilized by oil-collecting bees as an index signal for the presence of floral oil. However, floral oils in the genus Krameria (Krameriaceae) contain β-acetoxy-substituted fatty acids instead of acetylated glycerols, making them unlikely to emit diacetin as an oil-bee attractant. We analyzed floral headspace composition from K. bicolor and K. erecta, native to the Sonoran Desert of southwestern North America, in search of alternative candidates for volatile index signals. Using solid-phase microextraction, combined with gas chromatography-mass spectrometry, we identified 26 and 45 floral volatiles, respectively, from whole flowers and dissected flower parts of these two Krameria species. As expected, diacetin was not detected. Instead, β-ionone emerged as a strong candidate for an index signal, as it was uniquely present in dissected oil-producing floral tissues (elaiophores) of K. bicolor, as well as the larval cells and provisions from its oil-bee pollinator, Centris cockerelli. This finding suggests that the floral oil of K. bicolor is perfused with β-ionone in its tissue of origin and retains the distinctive raspberry-like scent of this volatile after being harvested by C. cockerelli bees. In contrast, the elaiophores of K. erecta, which are not thought to be pollinated by C. cockerelli, produced a blend of anise-related oxygenated aromatics not found in the elaiophores of K. bicolor. Our findings suggest that β-ionone has the potential to impact oil-foraging by C. cockerelli bees through several potential mechanisms, including larval imprinting on scented provisions or innate or learned preferences by foraging adults. [Display omitted] •Krameria oil flowers do not produce diacetin.•Krameria bicolor elaiophores emit β-ionone.•β -ionone could act as an index signal for the oil-collecting bee Centris cockerelli.
ISSN:0031-9422
1873-3700
DOI:10.1016/j.phytochem.2023.113937