Colonization of Honey Bee Digestive Tracts by Environmental Yeast Is Naturally Occurring, Temperature Dependent, and Impacts the Microbiome of Newly Emerged Bees

Overview

Journal Microbiol Spectr

Specialty Microbiology

Date 2023 Feb 15

PMID 36790179

Authors

Helen V Kogan

Annabelle B Elikan

Kimberly F Glaser

Jenna M Bergmann

Laure M Raymond

Sofia R Prado-Irwin

Jonathan W Snow

Affiliations

Soon will be listed here.

Abstract

Honey bees are critical pollinators in both agricultural and ecological settings. Recent declines in honey bee colonies in the United States have put increased strain on agricultural pollination. Although there are many environmental stressors implicated in honey bee disease, there has been intensifying focus on the role of microbial attacks on honey bee health. Despite the long-standing appreciation for the association of fungi of various groups with honey bees and their broader environment, the effects of these interactions on honey bee health are incompletely understood. Here, we report the discovery of colonization of the honey bee digestive tract by the environmental yeast Lachancea thermotolerans. Experimental colonization of honey bee digestive tracts by L. thermotolerans revealed that this yeast species maintains high levels in the honey bee midgut only at temperatures below the typical colony temperature. In newly eclosed bees, colonization alters the microbiome, suggesting that environmental yeasts can impact its composition. Future studies should be undertaken to better understand the role of and other environmental yeasts in honey bee health. Although many fungal species are found in association with honey bees and their broader environment, the effects of these interactions on honey bee health are largely unknown. Here, we report the discovery that a yeast commonly found in the environment can be found at high levels in honey bee digestive tracts. Experimentally feeding this yeast to honey bees showed that the yeast's ability to maintain high levels in the digestive tract is influenced by temperature and can lead to alterations of the microbiome in young bees. These studies provide a foundation for future studies to better understand the role of environmental yeasts in honey bee health.

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