Dietary Phytochemicals, Honey Bee Longevity and Pathogen Tolerance.

Elisa Bernklau,Louis Bjostad,Alison Hogeboom,Ashley Carlisle,Arathi H S

doi:10.3390/insects10010014

Abstract

Continued loss of natural habitats with native prairies and wildflower patches is eliminating diverse sources of pollen, nectar and phytochemicals therein for foraging bees. The longstanding plant-pollinator mutualism reiterates the role of phytochemicals in sustaining plant-pollinator relationship and promoting honey bee health. We studied the effects of four phytochemicals—caffeine, gallic acid, kaempferol and p-coumaric acid, on survival and pathogen tolerance in the European honey bee, Apis mellifera (L.). We recorded longevity of worker bees that were provided ad libitum access to sugar solution supplemented with different concentrations of phytochemicals. We artificially infected worker bees with the protozoan parasite, Nosema ceranae. Infected bees were provided access to the same concentrations of the phytochemicals in the sugar solution, and their longevity and spore load at mortality were determined. Bees supplemented with dietary phytochemicals survived longer and lower concentrations were generally more beneficial. Dietary phytochemicals enabled bees to combat infection as seen by reduced spore-load at mortality. Many of the phytochemicals are plant defense compounds that pollinators have evolved to tolerate and derive benefits from. Our findings support the chemical bases of co-evolutionary interactions and reiterate the importance of diversity in floral nutrition sources to sustain healthy honey bee populations by strengthening the natural mutualistic relationships.

Highlights

Recent fluctuations seen in honey bee populations have been attributed to habitat degradation, chemical intensive agriculture, pests and pathogens [1]
Our goal in the current study is to reveal different classes of phytochemicals that are beneficial to honey bees
Worker bees supplemented with dietary phytochemicals survived longer than control bees (Figure 1A) across 2016 and 2017 with no significant effect of years

Summary

Introduction

Recent fluctuations seen in honey bee populations have been attributed to habitat degradation, chemical intensive agriculture, pests and pathogens [1]. Even as the demand for pollination services continues to grow, the ecological impacts of modern agriculture, including the elimination of remnants of native prairies and wildflower patches, are leading to a distinct drop in the diversity of the pollen/nectar diet of bees, compromising their health and physiological abilities [2,3]. The relationships between flowering plants and their pollinators have an extensive co-evolutionary history. Embedded within this long-standing plant-pollinator mutualism, is the nutritional benefit for pollinators in return for the pollination services [9]. Honey bees are among the Insects 2019, 10, 14; doi:10.3390/insects10010014 www.mdpi.com/journal/insects

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