Host-microbiome metabolism of a plant toxin in bees

While foraging for nectar and pollen, bees are exposed to a myriad of xenobiotics, including plant metabolites, which may exert a wide range of effects on their health. Although the bee genome encodes enzymes that help in the metabolism of xenobiotics, it has lower detoxification gene diversity than...

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Bibliographic Details
Published in:eLife 2022-12, Vol.11
Main Authors: Motta, Erick V S, Gage, Alejandra, Smith, Thomas E, Blake, Kristin J, Kwong, Waldan K, Riddington, Ian M, Moran, Nancy
Format: Article
Language:English
Subjects:
amygdalin
Amygdalin - metabolism
Animals
Apidae
Apis mellifera
Bacteria
Bees
Bifidobacterium
Biodegradation
Bombilactobacillus
By products
Detoxification
Ecology
Enzymes
Gastrointestinal Microbiome - physiology
Genomes
Gilliamella
Glucose
Glycoside hydrolase
Herbivores
Hindgut
Hydrogen cyanide
Intestinal microflora
Lysates
Metabolism
Metabolites
Microbiology and Infectious Disease
microbiome
Microbiomes
Microbiota
Midgut
Nectar
Nitriles
Pathogens
Plant nectar
Plants - metabolism
Strains (organisms)
Toxicity
Toxins
Toxins, Biological
Xenobiotics
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Summary:While foraging for nectar and pollen, bees are exposed to a myriad of xenobiotics, including plant metabolites, which may exert a wide range of effects on their health. Although the bee genome encodes enzymes that help in the metabolism of xenobiotics, it has lower detoxification gene diversity than the genomes of other insects. Therefore, bees may rely on other components that shape their physiology, such as the microbiota, to degrade potentially toxic molecules. In this study, we show that amygdalin, a cyanogenic glycoside found in honey bee-pollinated almond trees, can be metabolized by both bees and members of the gut microbiota. In microbiota-deprived bees, amygdalin is degraded into prunasin, leading to prunasin accumulation in the midgut and hindgut. In microbiota-colonized bees, on the other hand, amygdalin is degraded even further, and prunasin does not accumulate in the gut, suggesting that the microbiota contribute to the full degradation of amygdalin into hydrogen cyanide. In vitro experiments demonstrated that amygdalin degradation by bee gut bacteria is strain-specific and not characteristic of a particular genus or species. We found strains of , and that can degrade amygdalin. The degradation mechanism appears to vary since only some strains produce prunasin as an intermediate. Finally, we investigated the basis of degradation in wkB204, a strain that fully degrades amygdalin. We found overexpression and secretion of several carbohydrate-degrading enzymes, including one in glycoside hydrolase family 3 (GH3). We expressed this GH3 in and detected prunasin as a byproduct when cell lysates were cultured with amygdalin, supporting its contribution to amygdalin degradation. These findings demonstrate that both host and microbiota can act together to metabolize dietary plant metabolites.
ISSN:2050-084X
2050-084X
DOI:10.7554/eLife.82595