Single and interactive effects of Varroa destructor, Nosema spp., and imidacloprid on honey bee colonies (Apis mellifera)

Dooremalen, Coby van; Cornelissen, B.; Poleij-Hok-Ahin, Chula; Blacquière, T.

doi:10.1002/ecs2.2378

Cited by 34 publications

(41 citation statements)

References 62 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The observed increase in the amount of brood in response to a stressor has previously been described for Varroa destructor infested colonies [14], where larger colonies in the autumn were more likely to die the following year. A bee colony is an adaptable unit that uses brood rearing as one of the mechanisms to respond to external and internal stimuli, through both positive and negative feedback loops [60].…”

Section: Table 2 Posterior Distributions For the Main Parameters On Osupporting

confidence: 76%

See 1 more Smart Citation

American foulbrood in a honeybee colony: spore-symptom relationship and feedbacks between disease and colony development

2020

View full text Add to dashboard Cite

Background: The most severe bacterial disease of honeybees is American foulbrood (AFB). The epidemiology of AFB is driven by the extreme spore resilience, the difficulty of bees to remove these spores, and the considerable incidence of undetected spore-producing colonies. The honeybee collective defence mechanisms and their feedback on colony development, which involves a division of labour at multiple levels of colony organization, are difficult to model. To better predict disease outbreaks we need to understand the feedback between colony development and disease progression within the colony. We therefore developed Bayesian models with data from forty AFB-diseased colonies monitored over an entire foraging season to (i) investigate the relationship between spore production and symptoms, (ii) disentangle the feedback loops between AFB epidemiology and natural colony development, and (iii) discuss whether larger insect societies promote or limit within-colony disease transmission. Results: Rather than identifying a fixed spore count threshold for clinical symptoms, we estimated the probabilities around the relationship between spore counts and symptoms, taking into account modulators such as brood amount/number of bees and time post infection. We identified a decrease over time in the bees-to-brood ratio related to disease development, which should ultimately induce colony collapse. Lastly, two contrasting theories predict that larger colonies could promote either higher (classical epidemiological SIR-model) or lower (increasing spatial nest segregation and more effective pathogen removal) disease prevalence. Conclusions: AFB followed the predictions of the SIR-model, partly because disease prevalence and brood removal are decoupled, with worker bees acting more as disease vectors, infecting new brood, than as agents of social immunity, by removing infected brood. We therefore established a direct link between disease prevalence and social group size for a eusocial insect. We furthermore provide a probabilistic description of the relationship between AFB spore counts and symptoms, and how disease development and colony strength over a season modulate this relationship. These results help to better understand disease development within honeybee colonies, provide important estimates for further epidemiological modelling, and gained important insights into the optimal sampling strategy for practical beekeeping and honeybee research.

show abstract

Section: Table 2 Posterior Distributions For the Main Parameters On Osupporting

confidence: 76%

“…At the same time, beekeepers worldwide are experiencing increased winter and seasonal colony losses [4][5][6][7]. Such losses stem from a combination of parasites and diseases, poor nutrition, inadequate beekeeping management practices and pesticide exposure; both individually and synergistically [8][9][10][11][12][13][14][15][16].…”

mentioning

confidence: 99%

American foulbrood in a honeybee colony: spore-symptom relationship and feedbacks between disease and colony development

2020

View full text Add to dashboard Cite

show abstract

“…Amongst the many factors potentially impacting honey bee health and thus pollination services, invasive parasitic species, e.g. introduced by global trade in honey bees and related products such as wax and honey (Chanpanitkitchote et al, ; Krongdang, Evans, Chen, Mookhploy, & Chantawannakul, ; Neumann, Pettis, & Schäfer, ; Ouessou Idrissou, Huang, Yañez, & Neumann, ; Schäfer et al, ), can play a key role (Neumann et al, ; Potts, Biemeijer, et al, ; Rosenkranz, Aumeier, & Ziegelmann, ; van Dooremalen, Cornelissen, Poleij‐Hok‐Ahin, & Blacquière, ). However, knowledge of the potential effects of climate change on such species is currently lacking (Le Conte & Navajas, ).…”

Section: Introductionmentioning

confidence: 99%

Global warming promotes biological invasion of a honey bee pest

Cornelissen

Neumann

Schweiger

2019

Global Change Biology

Self Cite

View full text Add to dashboard Cite

Climate change and biological invasions are two major global environmental challenges. Both may interact, e.g. via altered impact and distribution of invasive alien species. Even though invasive species play a key role for compromising the health of honey bees, the impact of climate change on the severity of such species is still unknown. The small hive beetle (SHB, Aethina tumida, Murray) is a parasite of honey bee colonies. It is endemic to sub‐Saharan Africa and has established populations on all continents except Antarctica. Since SHBs pupate in soil, pupation performance is governed foremost by two abiotic factors, soil temperature and moisture, which will be affected by climate change. Here, we investigated SHB invasion risk globally under current and future climate scenarios. We modelled survival and development time during pupation (=pupal performance) in response to soil temperature and soil moisture using published and novel experimental data. Presence data on SHB distribution were used for model validation. We then linked the model with global soil data in order to classify areas (resolution: 10 arcmin; i.e. 18.6 km at the equator) as unsuitable, marginal and suitable for SHB pupation performance. Under the current climate, the results show that many areas globally yet uninvaded are actually suitable, suggesting considerable SHB invasion risk. Future scenarios of global warming project a vehement increase in climatic suitability for SHB and corresponding potential for invasion, especially in the temperate regions of the Northern hemisphere, thereby creating demand for enhanced and adapted mitigation and management. Our analysis shows, for the first time, effects of global warming on a honey bee pest and will help areas at risk to prepare adequately. In conclusion, this is a clear case for global warming promoting biological invasion of a pest species with severe potential to harm important pollinator species globally.

show abstract

“…Even though Varroa-infestation rates were moderate (1-2%), the likelihood of these infested colonies to survive winter would have already been compromised [22]. Based on these infestation rates and an assumed doubling of mites between August and September, the likelihood of colony collapse during the following winter would have been 25-60%.…”

Section: Causes and Consequences Of The Varroa-induced Reduction In Fmentioning

confidence: 99%

Varroa destructor infestation impairs the improvement of landing performance in foraging honeybees

et al. 2020

Self Cite

View full text Add to dashboard Cite

The parasitic mite Varroa destructor is an important contributor to the high losses of western honeybees. Forager bees from Varroa -infested colonies show reduced homing and flight capacity; it is not known whether flight manoeuvrability and related learning capability are also affected. Here, we test how honeybees from Varroa -infested and control colonies fly in an environment that is unfamiliar at the beginning of each experimental day. Using stereoscopic high-speed videography, we analysed 555 landing manoeuvres recorded during 12 days of approximately 5 h in length. From this, we quantified landing success as percentage of successful landings, and assessed how this changed over time. We found that the forager workforce of Varroa -infested colonies did not improve their landing success over time, while for control bees landing success improved with approximately 10% each hour. Analysis of the landing trajectories showed that control bees improved landing success by increasing the ratio between in-flight aerodynamic braking and braking at impact on the landing platform; bees from Varroa -infested colonies did not increase this ratio over time. The Varroa -induced detriment to this landing skill-learning capability might limit forager bees from Varroa -infested colonies to adapt to new or challenging conditions; this might consequently contribute to Varroa -induced mortality of honeybee colonies.

show abstract

Single and interactive effects of Varroa destructor, Nosema spp., and imidacloprid on honey bee colonies (Apis mellifera)

Cited by 34 publications

References 62 publications

American foulbrood in a honeybee colony: spore-symptom relationship and feedbacks between disease and colony development

American foulbrood in a honeybee colony: spore-symptom relationship and feedbacks between disease and colony development

Global warming promotes biological invasion of a honey bee pest

Varroa destructor infestation impairs the improvement of landing performance in foraging honeybees

Contact Info

Product

Resources

About