A field realistic model to assess the effects of pesticides residues and adulterants on honey bee gene expression

PLoS One. 2024 Jun 26;19(6):e0302183. doi: 10.1371/journal.pone.0302183. eCollection 2024.

Abstract

While studies on the sublethal effects of chemical residues in beeswax on adult honey bees are increasing, the study protocols assessing the impacts on honey bee brood in realistic conditions still need to be investigated. Moreover, little is known about the residue's effect on gene expression in honey bee brood. This study reports the effects of chlorpyriphos-ethyl, acrinathrin and stearin worker pupae exposure through contaminated or adulterated beeswax on the gene expression of some key health indicators, using a novel in vivo realistic model. Larvae were reared in acrinathrin (12.5, 25, 10 and 100 ppb) and chlorpyriphos-ethyl (5, 10, 500 and 5000 ppb) contaminated or stearin adulterated beeswax (3, 4, 5, 6 and 9%) in newly formed colonies to reduce the influence of external factors. On day 11, mortality rates were assessed. Honey bee pupae were extracted from the comb after 19 days of rearing and were analysed for the gene expression profile of four genes involved in the immune response to pathogens and environmental stress factors (Imd, dorsal, domeless and defensin), and two genes involved in detoxifications mechanisms (CYP6AS14 and CYP9Q3). We found no linear relation between the increase in the pesticide concentrations and the brood mortality rates, unlike stearin where an increase in stearin percentage led to an exponential increase in brood mortality. The immune system of pupae raised in acrinathrin contaminated wax was triggered and the expression of CYP6AS14 was significantly upregulated (exposure to 12.5 and 25 ppb). Almost all expression levels of the tested immune and detoxification genes were down-regulated when pupae were exposed to chlorpyrifos-contaminated wax. The exposure to stearin triggered the immune system and detoxification system of the pupae. The identification of substance-specific response factors might ultimately serve to identify molecules that are safer for bees and the ecosystem's health.

MeSH terms

  • Animals
  • Bees / drug effects
  • Bees / genetics
  • Gene Expression Regulation / drug effects
  • Insect Proteins / genetics
  • Insect Proteins / metabolism
  • Larva / drug effects
  • Larva / genetics
  • Pesticide Residues* / analysis
  • Pesticide Residues* / toxicity
  • Pupa / drug effects
  • Pupa / genetics
  • Waxes*

Substances

  • Waxes
  • beeswax
  • Pesticide Residues
  • Insect Proteins

Grants and funding

Operational General Direction in Agriculture, Natural Resources and Environment (DGARNE) (Grant Quali Wax D32-0443) and the University of Liège (crédit facultaire). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.