Your search keyword '"Dolezal AG"' showing total 3 results

1. Carryover insecticide exposure reduces bee reproduction across years.

Author

Dolezal AG

Subjects

Animals, Bees physiology, Neonicotinoids toxicity, Bees drug effects, Insecticides toxicity

Abstract

Competing Interests: The author declares no competing interest.

Published

2022

2. Honey bee virus causes context-dependent changes in host social behavior.

Author

Geffre AC, Gernat T, Harwood GP, Jones BM, Morselli Gysi D, Hamilton AR, Bonning BC, Toth AL, Robinson GE, and Dolezal AG

Subjects

Animals, Beekeeping methods, Bees genetics, Behavior, Animal, Colony Collapse epidemiology, DNA Viruses genetics, DNA Viruses metabolism, Dicistroviridae genetics, Dicistroviridae pathogenicity, Disease Transmission, Infectious veterinary, Mites genetics, Pollination, RNA, Double-Stranded, Social Behavior, Virulence, Bees virology, Dicistroviridae metabolism, Host-Pathogen Interactions physiology

Abstract

Anthropogenic changes create evolutionarily novel environments that present opportunities for emerging diseases, potentially changing the balance between host and pathogen. Honey bees provide essential pollination services, but intensification and globalization of honey bee management has coincided with increased pathogen pressure, primarily due to a parasitic mite/virus complex. Here, we investigated how honey bee individual and group phenotypes are altered by a virus of concern, Israeli acute paralysis virus (IAPV). Using automated and manual behavioral monitoring of IAPV-inoculated individuals, we find evidence for pathogen manipulation of worker behavior by IAPV, and reveal that this effect depends on social context; that is, within versus between colony interactions. Experimental inoculation reduced social contacts between honey bee colony members, suggesting an adaptive host social immune response to diminish transmission. Parallel analyses with double-stranded RNA (dsRNA)-immunostimulated bees revealed these behaviors are part of a generalized social immune defensive response. Conversely, inoculated bees presented to groups of bees from other colonies experienced reduced aggression compared with dsRNA-immunostimulated bees, facilitating entry into susceptible colonies. This reduction was associated with a shift in cuticular hydrocarbons, the chemical signatures used by bees to discriminate colony members from intruders. These responses were specific to IAPV infection, suggestive of pathogen manipulation of the host. Emerging bee pathogens may thus shape host phenotypes to increase transmission, a strategy especially well-suited to the unnaturally high colony densities of modern apiculture. These findings demonstrate how anthropogenic changes could affect arms races between human-managed hosts and their pathogens to potentially affect global food security., Competing Interests: The authors declare no competing interest.

Published

2020

3. Native habitat mitigates feast-famine conditions faced by honey bees in an agricultural landscape.

Author

Dolezal AG, St Clair AL, Zhang G, Toth AL, and O'Neal ME

Subjects

Animals, Biodiversity, Crops, Agricultural, Models, Biological, Seasons, Agriculture, Bees physiology, Ecosystem, Pollination physiology

Abstract

Intensive agriculture can contribute to pollinator decline, exemplified by alarmingly high annual losses of honey bee colonies in regions dominated by annual crops (e.g., midwestern United States). As more natural or seminatural landscapes are transformed into monocultures, there is growing concern over current and future impacts on pollinators. To forecast how landscape simplification can affect bees, we conducted a replicated, longitudinal assessment of honey bee colony growth and nutritional health in an intensively farmed region where much of the landscape is devoted to production of corn and soybeans. Surprisingly, colonies adjacent to soybean fields surrounded by more cultivated land grew more during midseason than those in areas of lower cultivation. Regardless of the landscape surrounding the colonies, all experienced a precipitous decline in colony weight beginning in August and ended the season with reduced fat stores in individual bees, both predictors of colony overwintering failure. Patterns of forage availability and colony nutritional state suggest that late-season declines were caused by food scarcity during a period of extremely limited forage. To test if habitat enhancements could ameliorate this response, we performed a separate experiment in which colonies provided access to native perennials (i.e., prairie) were rescued from both weight loss and reduced fat stores, suggesting the rapid decline observed in these agricultural landscapes is not inevitable. Overall, these results show that intensively farmed areas can provide a short-term feast that cannot sustain the long-term nutritional health of colonies; reintegration of biodiversity into such landscapes may provide relief from nutritional stress., Competing Interests: The authors declare no competing interest., (Copyright © 2019 the Author(s). Published by PNAS.)

Published

2019