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1. Antibiotics in hives and their effects on honey bee physiology and behavioral development

   https://doi.org/10.1242/bio.053884  

   Ortiz-Alvarado, Yarira ; Clark, David R. ; Vega-Melendez, Carlos J. ; Flores-Cruz, Zomary ; Domingez-Bello, Maria G. ; Giray, Tugrul ( November 2020 , Biology Open)

   null (Ed.)

   Recurrent honey bee losses make it critical to understand the impact of human interventions, such as antibiotics use in apiculture. Antibiotics are used to prevent or treat bacterial infections in colonies. However, little is known about their effects on honey bee development. We studied the effect of two commercial beekeeping antibiotics on the bee physiology and behavior throughout development. Our results show that antibiotic treatments have an effect on amount of lipids and rate of behavioral development. Lipid amount in treated bees was higher than those not treated. Also, the timing of antibiotic treatment had distinct effects for the age of onset of behaviors starting with cleaning, then nursing and lastly foraging. Bees treated during larva-pupa stages demonstrated an accelerated behavioral development and loss of lipids, while bees treated from larva to adulthood had a delay in behavioral development and loss of lipids. The effects were shared across the two antibiotics tested, TerramycinR (oxytetracycline) and TylanR (tylosin tartrate). These results on effects of antibiotic treatments suggest a role of microbiota in the interaction between the fat body and brain that is important for honey bee behavioral development. 

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2. Medicinal value of sunflower pollen against bee pathogens

   https://doi.org/10.1038/s41598-018-32681-y  

   Giacomini, Jonathan J. ; Leslie, Jessica ; Tarpy, David R. ; Palmer-Young, Evan C. ; Irwin, Rebecca E. ; Adler, Lynn S. ( September 2018 , Scientific Reports)

   Global declines in pollinators, including bees, can have major consequences for ecosystem services. Bees are dominant pollinators, making it imperative to mitigate declines. Pathogens are strongly implicated in the decline of native and honey bees. Diet affects bee immune responses, suggesting the potential for floral resources to provide natural resistance to pathogens. We discovered that sunflower (Helianthus annuus) pollen dramatically and consistently reduced a protozoan pathogen (Crithidia bombi) infection in bumble bees (Bombus impatiens) and also reduced a microsporidian pathogen (Nosema ceranae) of the European honey bee (Apis mellifera), indicating the potential for broad anti-parasitic effects. In a field survey, bumble bees from farms with more sunflower area had lowerCrithidiainfection rates. Given consistent effects of sunflower in reducing pathogens, planting sunflower in agroecosystems and native habitat may provide a simple solution to reduce disease and improve the health of economically and ecologically important pollinators.

    

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3. Ecological Drivers and Consequences of Bumble Bee Body Size Variation

   https://doi.org/10.1093/ee/nvac093  

   Fitzgerald, Jacquelyn L. ; Ogilvie, Jane E. ; CaraDonna, Paul J. ; Poland, ed., Therese ( November 2022 , Environmental Entomology)

   Body size is arguably one of the most important traits influencing the physiology and ecology of animals. Shifts in animal body size have been observed in response to climate change, including in bumble bees (Bombus spp. [Hymenoptera: Apidae]). Bumble bee size shifts have occurred concurrently with the precipitous population declines of several species, which appear to be related, in part, to their size. Body size variation is central to the ecology of bumble bees, from their social organization to the pollination services they provide to plants. If bumble bee size is shifted or constrained, there may be consequences for the pollination services they provide and for our ability to predict their responses to global change. Yet, there are still many aspects of the breadth and role of bumble bee body size variation that require more study. To this end, we review the current evidence of the ecological drivers of size variation in bumble bees and the consequences of that variation on bumble bee fitness, foraging, and species interactions. In total we review: (1) the proximate determinants and physiological consequences of size variation in bumble bees; (2) the environmental drivers and ecological consequences of size variation; and (3) synthesize our understanding of size variation in predicting how bumble bees will respond to future changes in climate and land use. As global change intensifies, a better understanding of the factors influencing the size distributions of bumble bees, and the consequences of those distributions, will allow us to better predict future responses of these pollinators.

    

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4. Contrasting effects of land cover on nesting habitat use and reproductive output for bumble bees

   https://doi.org/10.1002/ecs2.3642  

   Pugesek, Genevieve ; Crone, Elizabeth E. ( July 2021 , Ecosphere)

   Understanding habitat quality is central to understanding the distributions of species on the landscape, as well as to conserving and restoring at‐risk species. Although it is well known that many species require different resources throughout their life cycles, pollinator conservation efforts focus almost exclusively on forage resources. In this study, we evaluate nesting habitat for bumble bees by locating nests directly on the landscape. We compared colony density and colony reproductive output forBombus impatiens, the common eastern bumble bee, across three different land cover types (hay fields, meadows, and forests). We also assessed nesting habitat associations for allBombusnests located during surveys to tease apart species‐specific patterns of habitat use. We found thatB. impatiensnested under the ground in two natural land cover types, forests, and meadows, but found noB. impatiensnests in hay fields. ThoughB. impatiensnested at similar densities in both meadows and forests, colonies in forests had much higher reproductive output. In contrast,B. griseocollistended to nest on the surface of the ground and was almost always found in meadows.B. perplexiswas the only species to nest in all three habitat types, including hay fields. For some bumble bee species in this system, meadows, the habitat type with abundant forage resources, may be sufficient to maintain them throughout their life cycles. However,B. impatiensmight benefit from heterogeneous landscapes with forests and meadows. Results forB. impatiensemphasize the longstanding notion that habitat use is not always positively correlated with habitat quality (as measured by reproductive output). Our results also show that habitat selection by bumble bees at one spatial scale may be influenced by resources at other scales. Finally, we demonstrate the feasibility of direct nest searches for understanding bumble bee distribution and ecology.

    

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5. Parallel mechanisms of visual memory formation across distinct regions of the honey bee brain

   https://doi.org/10.1242/jeb.242292  

   Avalos, Arián ; Traniello, Ian M. ; Pérez Claudio, Eddie ; Giray, Tugrul ( October 2021 , Journal of Experimental Biology)

   ABSTRACT Visual learning is vital to the behavioral ecology of the Western honey bee (Apis mellifera). Honey bee workers forage for floral resources, a behavior that requires the learning and long-term memory of visual landmarks, but how these memories are mapped to the brain remains poorly understood. To address this gap in our understanding, we collected bees that successfully learned visual associations in a conditioned aversion paradigm and compared gene expression correlates of memory formation in the mushroom bodies, a higher-order sensory integration center classically thought to contribute to learning, as well as the optic lobes, the primary visual neuropil responsible for sensory transduction of visual information. We quantified expression of CREB and CaMKII, two classical genetic markers of learning, and fen-1, a gene specifically associated with punishment learning in vertebrates. As expected, we found substantial involvement of the mushroom bodies for all three markers but additionally report the involvement of the optic lobes across a similar time course. Our findings imply the molecular involvement of a sensory neuropil during visual associative learning parallel to a higher-order brain region, furthering our understanding of how a tiny brain processes environmental signals. 

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