Abstract
The ecologically and economic important honey bee (Apis mellifera) is a key non-target arthropod species in environmental risk assessment (ERA) of genetically modified (GM) crops. Honey bee larvae are directly exposed to transgenic products by the consumption of GM pollen. But most ERA studies only consider responses of adult bees, although Bt-proteins primarily affect the larval phases of target organisms. We adopted an in vitro larvae rearing system, to assess lethal and sublethal effects of Bt-pollen consumption in a standardized eco-toxicological bioassay. The effects of pollen from two Bt-maize cultivars, one expressing a single and the other a total of three Bt-proteins, on the survival and prepupae weight of honey bee larvae were analyzed. The control treatments included pollen from three non-transgenic maize varieties and of Heliconia rostrata. Three days old larvae were fed the realistic exposure dose of 2 mg pollen within the semi-artificial diet. The larvae were monitored over 120 h, until the prepupal stage, where larvae terminate feeding and growing. Neither single nor stacked Bt-maize pollen showed an adverse effect on larval survival and the prepupal weight. In contrast, feeding of H. rostrata pollen caused significant toxic effects. The results of this study indicate that pollen of the tested Bt-varieties does not harm the development of in vitro reared A. mellifera larvae. To sustain the ecosystem service of pollination, Bt-impact on A. mellifera should always be a crucial part of regulatory biosafety assessments. We suggest that our approach of feeding GM pollen on in vitro reared honey bee larvae is well suited of becoming a standard bioassay in regulatory risk assessments schemes of GM crops.
Highlights
Pollinators provide key ecosystem services by maintaining both the biodiversity of wild plants and agricultural productivity [1,2] at an estimated value of US $217 billion yearly [3]
Crops expressing insecticidal proteins derived from the bacterium Bacillus thuringiensis (Bt) (Bt-proteins) are among the most widely cultivated genetically modified (GM) crops worldwide [6]
In order to minimize the environmental risks of cultivating GM crops and their discussed contribution of being an underlying factor of the globally observed bee losses, robust and highly standardized risk assessment methods for honey bees are imperative
Summary
Pollinators provide key ecosystem services by maintaining both the biodiversity of wild plants and agricultural productivity [1,2] at an estimated value of US $217 billion yearly [3]. The most important pollinator species worldwide is the honey bee Apis mellifera [4], with populations present in all countries growing genetically modified (GM) crops [5,6]. Honey bees are a key non-target test species for assessing the potential adverse impacts of GM crops on pollinators [7,8]. A recent metaanalysis showed no adverse effects of Bt-crops on A. mellifera [7]. One future trend in plant biotechnology is the stacking of multiple resistance traits. Regulatory authorities are in need of up to date test-standards, to guide robust first-Tier laboratory experiments to assess the risks of new GM plants to non-target organisms [9]
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