Nutrition Matters: Stress From Migratory Beekeeping May Be Eased by Access to Food
In the first large-scale and comprehensive study on the impacts of transporting honey bees to pollinate various crops, research from North Carolina State University shows that travel can adversely affect bee health and lifespan. Some of these negative impacts may be reduced by moving bee colonies into patches with readily available food or by providing supplemental nutrition when there are few flowers for honey bees to visit, the researchers say.
Honey bees (Apis mellifera) are among the country’s most important agricultural pollinators. They are frequently trucked around the United States – in short and long distances – to pollinate crops like apples, almonds and berries. But the impact of that travel remains unclear and ripe for study, says Hongmei Li-Byarlay, a National Research Council senior research associate in NC State’s Department of Entomology and Plant Pathology and co-first author of a paper describing the research, which aimed to be the first to directly measure stress in these types of colonies.
Combining the results of three different experiments, the research shows that traveling bees generally have shorter lives than stationary bees. Traveling bees also have greater oxidative stress levels – which ages them more quickly and may lessen their capacity to fight off disease and parasites.
“We found that migratory beekeeping influences the lifespan of bees, but how this impacts health and honey bee aging is more complicated and often more influenced by the environment these colonies are in,” said Michael Simone-Finstrom, an NC State postdoctoral researcher during this research and co-first author of the study who currently works at the USDA honey bee research lab in Baton Rouge, La.
In one experiment, bees from commercial colonies that had traveled to pollinate almonds in California and then in Maine were compared to bees from colonies that remained stationary in the NC State apiary. Traveling colony bees lived about one day less than the stationary bees.
“One day may seem trivial, but when a normal forager bee lifespan is only around 20 days, one day is significant,” Simone-Finstrom said.
In the second experiment, researchers compared lifespan and colony health of migratory bees that traveled relatively short distances in North Carolina – 35 to 60 miles in a handful of trips – to stationary bees; both types of colonies were controlled by the researchers.
“We saw the same lifespan differences as in the first experiment, plus we saw more oxidative stress in traveling bees when compared to stationary bees,” Li-Byarlay said.
However, this increase in stress levels was only apparent early in the season – May and June – when the stationary bees had plenty of access to food. As the flowers dried up in the North Carolina summer heat, stationary bees had to work harder to find food while the traveling bees were moved into fields of blooming plants and therefore did better.
In the third experiment, researchers compared oxidative stress levels of stationary bees with bees that were transported across North Carolina for three hours each day for six consecutive days – a more intensive bee travel regimen than the second experiment. The results shed light on how the bee-rearing environment – where bees were raised as larvae – can impact the oxidative stress levels when bees become adults. In this experiment, foraging bees raised in migratory bee colonies had higher oxidative stress levels than foraging bees raised in stationary hives.
Li-Byarlay says she’d like to look at longer-term effects of bee migration and the interaction with nutrition, as this study examined bees over the course of roughly four months in late spring and summer. As honey bee colonies nationwide currently experience higher annual mortality, understanding effects through overwintering and mitigation of these effects would be particularly insightful.
Other paper co-authors include Olav Rueppell at UNC-Greensboro, Mimi Strand at Army Research Lab, Ming Hua Huang and David Tarpy at NC State. The study is published online in Scientific Reports and was supported by the Army Research Laboratory and the National Research Council.
– kulikowski –
Note to editors: An abstract of the paper follows.
“Migratory management and environmental conditions affect lifespan and oxidative stress in honey bees”
Authors: Michael Simone-Finstrom, Hongmei Li-Byarlay, Ming Huang, David Tarpy, North Carolina State University; Micheline Strand, U.S. Army Research Office; Olav Rueppell, University of North Carolina-Greensboro
Published: Online Aug. 24, 2016, in Scientific Reports
DOI: 10.1038/srep32023
Abstract: Most pollination in large-scale agriculture is dependent on managed colonies of a single species, the honey bee Apis mellifera. More than 1 million hives are transported to California each year just to pollinate the almonds, and bees are trucked across the country for various cropping systems. Concerns have been raised about whether such “migratory management” causes bees undue stress; however to date there have been no longer-term studies rigorously addressing whether migratory management is detrimental to bee health. To address this issue, we conducted field experiments comparing bees from commercial and experimental migratory beekeeping operations to those from stationary colonies to quantify effects on lifespan, colony health and productivity, and levels of oxidative damage within individual bees. We detected a significant decrease in lifespan of migratory adult bees relative to stationary bees. We also found that migration affected oxidative stress levels in honey bees, but that food scarcity had an even larger impact; some detrimental effects of migration may be alleviated by a greater abundance of forage. In addition, rearing conditions affect levels of oxidative damage incurred as adults. This is the first comprehensive study on impacts of migratory management on the health and oxidative stress of honey bees.
This post was originally published in NC State News.