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1. High thermal tolerance in high-elevation species and laboratory-reared colonies of tropical bumble bees

   Gonzalez, V.H.; Oyen, K.; Aguilar, M.L.; Herrea, A.; Martin, R.D.; and Ospina, R. (January 2022, Ecology and evolution)

   Bumble bees are key pollinators with some species reared in captivity at a commercial scale, but with significant evidence of population declines and with alarming predictions of substantial impacts under climate change scenarios. While studies on the thermal biology of temperate bumble bees are still limited, they are entirely absent from the tropics where the effects of climate change are expected to be greater. Herein, we test whether bees' thermal tolerance decreases with elevation and whether the stable optimal conditions used in laboratory-reared colonies reduces their thermal tolerance. We assessed changes in the lower (CTMin) and upper (CTMax) critical thermal limits of four species at two elevations (2600 and 3600 m) in the Colombian Andes, examined the effect of body size, and evaluated the thermal tolerance of wild-caught and laboratory-reared individuals of Bombus pauloensis. We also compiled information on bumble bees' thermal limits and assessed potential predictors for broadscale patterns of variation. We found that CTMin decreased with increasing elevation, while CTMax was similar between elevations. CTMax was slightly higher (0.84°C) in laboratory-reared than in wild-caught bees while CTMin was similar, and CTMin decreased with increasing body size while CTMax did not. Latitude is a good predictor for CTMin while annual mean temperature, maximum and minimum temperatures of the warmest and coldest months are good predictors for both CTMin and CTMax. The stronger response in CTMin with increasing elevation, and similar CTMax, supports Brett's heat-invariant hypothesis, which has been documented in other taxa. Andean bumble bees appear to be about as heat tolerant as those from temperate areas, suggesting that other aspects besides temperature (e.g., water balance) might be more determinant environmental factors for these species. Laboratory-reared colonies are adequate surrogates for addressing questions on thermal tolerance and global warming impacts. 

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2. Foraging behavior and the nest architecture of a high-Andean stingless bee (Hymenoptera: Apidae: Meliponini) revealed by X-ray computerized tomography

   https://doi.org/10.1007/s13592-024-01074-8  

   Jacome-García, Jesus_C; Gonzalez, Victor_H; Riaño-Jimenez, Diego_A; Herrera-Motta, Andres_F; Cure, Jose_R (May 2024, Apidologie)

   Abstract Stingless bees (Hymenoptera: Apidae: Meliponini) are key pollinators of both cultivated and wild plants in tropical and subtropical areas of the world. While most species are found in lowland to mid-elevations, a few have adapted to high elevations, and their biology remains poorly understood. We assess the foraging pattern ofParapartamona zonata(Smith) in the central Andes of Colombia (2583 m.a.s.l.) and apply computer tomography to visualize and characterize its internal nest architecture. Bees foraged for pollen and nesting materials (resin and/or mud) from sunrise (5:40 h) to sunset (17:45), even at ambient temperatures as low as 11 °C. Foraging varied significantly throughout the day and temperature and sky condition explained 47% of its variance. Differences in the nest architecture, when compared with previous records, suggest that nesting behavior might be variable. These results are discussed in the context of behavioral adaptations in this unique environmental niche. 

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3. Bees display limited acclimation capacity for heat tolerance

   https://doi.org/10.1242/bio.060179  

   Gonzalez, Victor H; Herbison, Natalie; Robles_Perez, Gabriela; Panganiban, Trisha; Haefner, Laura; Tscheulin, Thomas; Petanidou, Theodora; Hranitz, John (March 2024, Biology Open)

   Bees are essential pollinators and understanding their ability to cope with extreme temperature changes is crucial for predicting their resilience to climate change, but studies are limited. We measured the response of the critical thermal maximum (CTMax) to short-term acclimation in foragers of six bee species from the Greek island of Lesvos, which differ in body size, nesting habit, and level of sociality. We calculated the acclimation response ratio as a metric to assess acclimation capacity and tested whether bees’ acclimation capacity was influenced by body size and/or CTMax. We also assessed whether CTMax increases following acute heat exposure simulating a heat wave. Average estimate of CTMax varied among species and increased with body size but did not significantly shift in response to acclimation treatment except in the sweat bee Lasioglossum malachurum. Acclimation capacity averaged 9% among species and it was not significantly associated with body size or CTMax. Similarly, the average CTMax did not increase following acute heat exposure. These results indicate that bees might have limited capacity to enhance heat tolerance via acclimation or in response to prior heat exposure, rendering them physiologically sensitive to rapid temperature changes during extreme weather events. These findings reinforce the idea that insects, like other ectotherms, generally express weak plasticity in CTMax, underscoring the critical role of behavioral thermoregulation for avoidance of extreme temperatures. Conserving and restoring native vegetation can provide bees temporary thermal refuges during extreme weather events. 

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4. Variance in heat tolerance in bumble bees correlates with species geographic range and is associated with several environmental and biological factors

   https://doi.org/10.1002/ece3.10730  

   Feuerborn, Cody; Quinlan, Gabriela; Shippee, Rachael; Strausser, Tori L.; Terranova, Tatiana; Grozinger, Christina M.; Hines, Heather M. (November 2023, Ecology and Evolution)

   Globally, insects have been impacted by climate change, with bumble bees in particular showing range shifts and declining species diversity with global warming. This suggests heat tolerance is a likely factor limiting the distribution and success of these bees. Studies have shown high intraspecific variance in bumble bee thermal tolerance, suggesting biological and environmental factors may be impacting heat resilience. Understanding these factors is important for assessing vulnerability and finding environmental solutions to mitigate effects of climate change. In this study, we assess whether geographic range variation in bumble bees in the eastern United States is associated with heat tolerance and further dissect which other biological and environmental factors explain variation in heat sensitivity in these bees. We examine heat tolerance by caste, sex, and rearing condition (wild/lab) across six eastern US bumble bee species, and assess the role of age, reproductive status, body size, and interactive effects of humidity and temperature on thermal tolerance inBombus impatiens. We found marked differences in heat tolerance by species that correlate with each species' latitudinal range, habitat, and climatic niche, and we found significant variation in thermal sensitivity by caste and sex. Queens had considerably lower heat tolerance than workers and males, with greater tolerance when queens would first be leaving their natal nest, and lower tolerance after ovary activation. Wild bees tended to have higher heat tolerance than lab reared bees, and body size was associated with heat tolerance only in wild‐caught foragers. Humidity showed a strong interaction with heat effects, pointing to the need to regulate relative humidity in thermal assays and consider its role in nature. Altogether, we found most tested biological conditions impact thermal tolerance and highlight the stages of these bees that will be most sensitive to future climate change. 

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5. Spatial segregation and cross-kingdom interactions drive stingless bee hive microbiome assembly

   https://doi.org/10.1101/2025.03.07.642116  

   Caesar, Lílian; Barksdale, Carlin; Valiati, Victor Hugo; Newton, Irene (March 2025, bioRxiv)

   Abstract Studying host-associated microbiome assembly is key to understanding microbial and host evolution and health. While honey bee microbiomes have been central models for such investigations among pollinators, they overlook the diversity of eusocial dynamics and multi- kingdom interactions. Stingless bees, highly eusocial managed bees that rely on yeast for larval development, offer a valuable complementary system to study microbiome assembly, and within an eco-evolutionary framework. Using amplicon sequencing, metagenomics, and microbial experiments, we investigate the drivers of stingless bee microbiome assembly. We reveal a spatially structured, site-adapted microbiome, where high microbial influx hive components are segregated from the brood, which harbors a stable, multi-kingdom community. We show that the brood microbiome is not only physically protected but also actively maintained through highly selective bacterial-fungal interactions. Our findings uncover multi-layered mechanisms shaping an eusocial insect microbiome, from host biology to cross-kingdom interactions, while providing critical insights into microbiome maintenance of important pollinators. 

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