First Evidence of the Effectiveness of a Field Application of RNAi Technology in Reducing Infestation of the Mite Varroa Destructor in the Western Honey Bee (Apis Mellifera)

Overview

Journal Parasit Vectors

Publisher Biomed Central

Date 2025 Jan 26

PMID 39865294

Authors

Francesca Bortolin

Emanuele Rigato

Sergio Perandin

Anna Granato

Laura Zulian

Caterina Millino

Beniamina Pacchioni

Franco Mutinelli

Giuseppe Fusco

Affiliations

Soon will be listed here.

Abstract

Background: The mite Varroa destructor is the most serious pest of the western honey bee (Apis mellifera) and a major factor in the global decline of colonies. Traditional control methods, such as chemical pesticides, although quick and temporarily effective, leave residues in hive products, harming bees and operators' health, while promoting pathogen resistance and spread. As a sustainable alternative, RNA interference (RNAi) technology has shown great potential for honey bee pest control in laboratory assays, but evidence of effectiveness in the field has been lacking.

Methods: We investigated the efficacy and feasibility of a RNAi treatment to improve bee health under natural beekeeping conditions by integrating a honey bee diet with a mixture of dsRNA targeting V. destructor acetyl-CoA carboxylase, Na/K ATPase and endochitinase genes.

Results: In treated hives, we observed that the average infestation rate of phoretic Varroa mite was reduced by 33% and 42% relative to control bees fed with sucrose and GFP-dsRNA, respectively. The dsRNA treatment did not affect bee survival, and the beekeepers involved in the project found the method manageable in the apiary and non-intrusive to production activities.

Conclusions: Our findings demonstrate the feasibility and effectiveness of RNAi technology in reducing Varroa mite infestations under natural rearing conditions. This study supports the potential of RNAi as a promising alternative to chemical pesticides, offering a targeted, efficient and sustainable solution for managing V. destructor in honey bee populations.

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