Your search keyword '"Pollen toxicity"' showing total 3 results

1. Effects of developmental exposure to pesticides in wax and pollen on honey bee (Apis mellifera) queen reproductive phenotypes.

Author

Milone JP and Tarpy DR

Subjects

Animals, Bees growth & development, Fatty Acids chemistry, Fatty Acids toxicity, Female, Male, Oviposition drug effects, Pesticide Residues analysis, Pesticide Residues toxicity, Pesticides analysis, Phenotype, Pollen chemistry, Pollen toxicity, Reproduction drug effects, Social Behavior, Sperm Count, Waxes chemistry, Waxes toxicity, Bees drug effects, Bees physiology, Pesticides toxicity

Abstract

Stressful conditions during development can have sub-lethal consequences on organisms aside from mortality. Using previously reported in-hive residues from commercial colonies, we examined how multi-pesticide exposure can influence honey bee (Apis mellifera) queen health. We reared queens in beeswax cups with or without a pesticide treatment within colonies exposed to treated or untreated pollen supplement. Following rearing, queens were open-mated and then placed into standard hive equipment in an "artificial swarm" to measure subsequent colony growth. Our treated wax had a pesticide Hazard Quotient comparable to the average in beeswax from commercial colonies, and it had no measurable effects on queen phenotype. Conversely, colonies exposed to pesticide-treated pollen had a reduced capacity for viable queen production, and among surviving queens from these colonies we observed lower sperm viability. We found no difference in queen mating number across treatments. Moreover, we measured lower brood viability in colonies later established by queens reared in treated-pollen colonies. Interestingly, royal jelly from colonies exposed to treated pollen contained negligible pesticide residues, suggesting the indirect social consequences of colony-level pesticide exposure on queen quality. These findings highlight how conditions during developmental can impact queens long into adulthood, and that colony-level pesticide exposure may do so indirectly.

Published

2021

2. Pollens destroy respiratory epithelial cell anchors and drive alphaherpesvirus infection.

Author

Van Cleemput J, Poelaert KCK, Laval K, Impens F, Van den Broeck W, Gevaert K, and Nauwynck HJ

Subjects

Animals, Betula, Cells, Cultured, Corylus, Herpesviridae Infections metabolism, Herpesviridae Infections virology, Herpesvirus 1, Equid pathogenicity, Horses, Poaceae, Pollen enzymology, Respiratory Mucosa metabolism, Respiratory Mucosa pathology, Herpesviridae Infections etiology, Plant Proteins metabolism, Pollen toxicity, Respiratory Mucosa virology, Serine Proteases metabolism

Abstract

Pollens are well-known triggers of respiratory allergies and asthma. The pollen burden in today's ambient air is constantly increasing due to rising climate change and air pollution. How pollens interact with the respiratory mucosa remains largely unknown due to a lack of representative model systems. We here demonstrate how pollen proteases of Kentucky bluegrass, white birch and hazel selectively destroy integrity and anchorage of columnar respiratory epithelial cells, but not of basal cells, in both ex vivo respiratory mucosal explants and in vitro primary equine respiratory epithelial cells (EREC). In turn, this pollen protease-induced damage to respiratory epithelial cell anchorage resulted in increased infection by the host-specific and ancestral alphaherpesvirus equine herpesvirus type 1 (EHV1). Pollen proteases of all three plant species were characterized by zymography and those of white birch were fully identified for the first time as serine proteases of the subtilase family and meiotic prophase aminopeptidase 1 using mass spectrometry-based proteomics. Together, our findings demonstrate that pollen proteases selectively and irreversibly damage integrity and anchorage of columnar respiratory epithelial cells. In turn, alphaherpesviruses benefit from this partial loss-of-barrier function, resulting in increased infection of the respiratory epithelium.

Published

2019

3. Effects of Bt cabbage pollen on the honeybee Apis mellifera L.

Author

Yi D, Fang Z, and Yang L

Subjects

Acetylcholinesterase metabolism, Animals, Bacillus thuringiensis Toxins, Bacterial Proteins genetics, Bacterial Proteins metabolism, Bees growth & development, Body Weight drug effects, Brassica genetics, Endotoxins genetics, Endotoxins metabolism, Glutathione Transferase metabolism, Hemolysin Proteins genetics, Hemolysin Proteins metabolism, Insect Proteins metabolism, Intestinal Mucosa metabolism, Peptide Hydrolases metabolism, Plants, Genetically Modified metabolism, Pollen metabolism, Survival Analysis, Bacillus thuringiensis genetics, Bees drug effects, Brassica metabolism, Pollen toxicity

Abstract

Honeybees may be exposed to insecticidal proteins from transgenic plants via pollen during their foraging activity. Assessing effects of such exposures on honeybees is an essential part of the risk assessment process for transgenic Bacillus thuringiensis (Bt) cabbage. Feeding trials were conducted in a laboratory setting to test for possible effects of Cry1Ba3 cabbage pollen on Italian-derived honeybees Apis mellifera L. Newly emerged A. mellifera were fed transgenic pollen, activated Cry1Ba3 toxin, pure sugar syrup (60% w/v sucrose solution), and non-transgenic cabbage pollen, respectively. Then the effects on survival, pollen consumption, weight, detoxification enzyme activity and midgut enzyme activity of A. mellifera were monitored. The results showed that there were no significant differences in survival, pollen consumption, weight, detoxification enzyme activity among all treatments. No significant differences in the activities of total proteolytic enzyme, active alkaline trypsin-like enzyme and weak alkaline trypsin-like enzyme were observed among all treatments. These results indicate that the side-effects of the Cry1Ba3 cabbage pollen on A. mellifera L. are unlikely.

Published

2018