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3. Effects of imidacloprid on stretching and production of wax in domestic bees Apis mellifera intermissa in North Africa (Algeria).

Author

Toudert-Djouber, F, Piou, V., Amrane, R., and Treilhou, M.

Abstract

Imidacloprid is a well-known systemic insecticide which has a deleterious impact on honeybees. Beekeepers in the Tizi-Ouzou wilaya (Algeria) where the imidacloprid insecticide is used, report unusual losses and deaths of bee colonies. Even at sublethal doses, insecticid can impact the most crucial tasks of a bee colony such as comb building. This study was conducted in order to investigate the effect of an imidacloprid based insecticide (Confidor®Supra) on the production of wax by the honeybee Apis mellifera intermissa. After the imidacloprid LD50 was determined in controlled conditions, three sublethal doses were tested. The mortality, the syrup consumption and the weight of the wax generated were recorded. The imidacloprid insecticide LD50 at 48 hours was evaluated at 3.5 ng.per bee on 4 days old spring worker bees. We found that the three sublethal doses (0.175 mg L-1, 0.087 mg L-1 and 0.035 mg L-1) had an impact on the syrup consumption and the wax production by adult bees. Bees exposed to sublethal doses of insecticide consumed less syrup and produced less wax that the control bees. A dose response was observed regarding the production of wax. The reduction of wax production by bees caused by an exposure to an imidacloprid based insecticide ads up to the many other effects of imidacloprid described in the literature.  This kind of impact could have harmful consequences for bee colonies as wax production is the basis of nest building. The physiological causes of the reduction of wax production remain to be investigated. [ABSTRACT FROM AUTHOR]

Published
2022
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4. Varroa destructor relies on physical cues to feed in artificial conditions

Author

Piou Vincent, Vilarem Caroline, Blanchard Solène, Armengaud Catherine, Heeb Philipp, and Vétillard Angélique

Subjects
artificial conditions, olfaction, physical cues, shape, pulse, varroa destructor, Infectious and parasitic diseases, RC109-216
Abstract

Olfaction is a major sense in Varroa destructor. In natural conditions, it is known that this honey bee parasite relies on kairomones to detect its host or to reproduce. Yet, in artificial conditions, the parasite is able to feed and survive for a few days even though most honey bee pheromones are lacking. Other key cues are thus probably involved in V. destructor perception of its close environment. Here, we used several artificial feeding designs to explore the feeding behaviour of the parasite when it is deprived of olfactory cues. We found that V. destructor is still able to feed only guided by physical cues. The detection of the food source seems to be shape-related as a 3D membrane triggers arrestment and exploration more than a 2D membrane. The tactile sense of V. destructor could thus be essential to detect a feeding site, although further studies are needed to assess the importance of this sense combined with olfaction in natural conditions.

Published
2023
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5. The proteomic content of Varroa destructor gut varies according to the developmental stage of its host.

Author

Piou V, Arafah K, Bocquet M, Bulet P, and Vétillard A

Subjects
Animals, Bees parasitology, Bees metabolism, Proteome metabolism, Proteome analysis, Larva metabolism, Gastrointestinal Tract parasitology, Gastrointestinal Tract metabolism, Varroidae, Host-Parasite Interactions physiology, Proteomics methods
Abstract

The nutritional physiology of parasites is often overlooked although it is at the basis of host-parasite interactions. In the case of Varroa destructor, one of the major pests of the Western honey bee Apis mellifera, the nature of molecules and tissues ingested by the parasite is still not completely understood. Here, the V. destructor feeding biology was explored through artificial feeding, dissection of the mite's gut and proteomic analyses. More specifically, the proteome of guts extracted from starved mites and honey bee-fed mites was compared to highlight both the parasite proteins likely involved in food processing and the honey bee proteins actually ingested by the mite. We could identify 25 V. destructor candidate proteins likely involved in the parasite digestion. As the host developmental stages infested by the mite are diverse, we also focused on the identity and on the origin of honey bee proteins ingested by the mite when it feeds on larvae, pupae or adults. We highlighted profiles of consumed honey bee proteins and their variations throughout the V. destructor life cycle. These variations matched the ones observed in the honey bee hemolymph, showing that this tissue is an important part of the mite's diet. Based on the variations of abundance of the most consumed honey bee proteins and on their functions, the potential implication of these key candidate nutrients in V. destructor reproduction is also discussed., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Piou et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published
2024
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6. Lactic acid treatment on infested honey bees works through a local way of action against Varroa destructor.

Author

Vilarem C, Blanchard S, Julien F, Vétillard A, and Piou V

Subjects
Animals, Bees parasitology, Bees drug effects, Acaricides pharmacology, Varroidae drug effects, Lactic Acid metabolism, Lactic Acid pharmacology
Abstract

Lactic acid is an alternative treatment to hard chemicals against Varroa destructor, the parasitic mite of the Western honey bee Apis mellifera. This soft acaricide is used only for small apiaries due to its laborious administration. However, the mode of action of this honey bee medication remains unknown. Previous studies showed that a direct contact between the arolia of V. destructor and lactic acid altered their morphology and led to an impairment of grip. Yet, there is no evidence for the way of action of lactic acid in a realistic in-hive scenario, i.e. after an indirect exposure of the mite through honey bees. We investigated the nature of lactic acid activity in the hive treatment context. The local and/or systemic way of action of this honey bee treatment against V. destructor was studied through a behavioural and toxicological approach at the individual level. On one hand, we confirmed the altered morphology for the arolia of mites and studied the evolution of the process over time. On the other hand, we found that haemolymph contaminated with lactic acid did not kill the feeding parasitic mite. These findings support a local mode of action. In order to unravel the sequence of events leading to the local contact between the acid and the mite on bees, we also documented the olfactory valence of lactic acid for A. mellifera and V. destructor. This work provides a new comprehension of lactic acid activity against the parasitic mite through honey bee exposure and gives new opportunities for control strategies against V. destructor., (© 2024. The Author(s).)

Published
2024
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7. Honey Bee Larval Hemolymph as a Source of Key Nutrients and Proteins Offers a Promising Medium for Varroa destructor Artificial Rearing.

Author

Piou V, Vilarem C, Blanchard S, Strub JM, Bertile F, Bocquet M, Arafah K, Bulet P, and Vétillard A

Subjects
Animals, Bees parasitology, Bees metabolism, Female, Nutrients metabolism, Proteomics methods, Varroidae, Larva metabolism, Hemolymph metabolism
Abstract

Varroa destructor , a major ectoparasite of the Western honey bee Apis mellifera , is a widespread pest that damages colonies in the Northern Hemisphere. Throughout their lifecycle, V. destructor females feed on almost every developmental stage of their host, from the last larval instar to the adult. The parasite is thought to feed on hemolymph and fat body, although its exact diet and nutritional requirements are poorly known. Using artificial Parafilm™ dummies, we explored the nutrition of V. destructor females and assessed their survival when fed on hemolymph from bee larvae, pupae, or adults. We compared the results with mites fed on synthetic solutions or filtered larval hemolymph. The results showed that the parasites could survive for several days or weeks on different diets. Bee larval hemolymph yielded the highest survival rates, and filtered larval plasma was sufficient to maintain the mites for 14 days or more. This cell-free solution therefore theoretically contains all the necessary nutrients for mite survival. Because some bee proteins are known to be hijacked without being digested by the parasite, we decided to run a proteomic analysis of larval honey bee plasma to highlight the most common proteins in our samples. A list of 54 proteins was compiled, including several energy metabolism proteins such as Vitellogenin, Hexamerin, or Transferrins. These molecules represent key nutrient candidates that could be crucial for V. destructor survival.

Published
2023
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8. Transmission of deformed wing virus between Varroa destructor foundresses, mite offspring and infested honey bees.

Author

Piou V, Schurr F, Dubois E, and Vétillard A

Subjects
Animals, Bees, Viral Load, Mite Infestations veterinary, RNA Viruses, Varroidae
Abstract

Background: Varroa destructor is the major ectoparasite of the western honey bee (Apis mellifera). Through both its parasitic life-cycle and its role as a vector of viral pathogens, it can cause major damage to honey bee colonies. The deformed wing virus (DWV) is the most common virus transmitted by this ectoparasite, and the mite is correlated to increased viral prevalence and viral loads in infested colonies. DWV variants A and B (DWV-A and DWV-B, respectively) are the two major DWV variants, and they differ both in their virulence and transmission dynamics., Methods: We studied the transmission of DWV between bees, parasitic mites and their offspring by quantifying DWV loads in bees and mites collected in in vitro and in situ environments. In vitro, we artificially transmitted DWV-A to mites and quantified both DWV-A and DWV-B in mites and bees. In situ, we measured the natural presence of DWV-B in bees, mites and mites' offspring., Results: Bee and mite viral loads were correlated, and mites carrying both variants were associated with higher mortality of the infected host. Mite infestation increased the DWV-B loads and decreased the DWV-A loads in our laboratory conditions. In situ, viral quantification in the mite offspring showed that, after an initially non-infected egg stage, the DWV-B loads were more closely correlated with the foundress (mother) mites than with the bee hosts., Conclusions: The association between mites and DWV-B was highlighted in this study. The parasitic history of a mite directly impacts its DWV infection potential during the rest of its life-cycle (in terms of variant and viral loads). Regarding the mite's progeny, we hypothesize that the route of contamination is likely through the feeding site rather than by vertical transmission, although further studies are needed to confirm this hypothesis., (© 2022. The Author(s).)

Published
2022
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9. Standard Methods for Dissection of Varroa destructor Females.

Author

Piou V, Vilarem C, Rein C, Sprau L, and Vétillard A

Abstract

Varroa destructor (Anderson and Trueman) is known as a major pest of Apis mellifera L, especially in the Northern Hemisphere where its effects can be deleterious. As an obligate parasite, this mite relies entirely on its host to reproduce and complete its cycle. Studies focusing on isolated organs are needed to better comprehend this organism. To conduct such targeted molecular or physiological studies, the dissection of V. destructor mites is crucial as it allows the extraction of specific organs. Here, we propose a technical article showing detailed steps of females V. destructor dissection, illustrated with pictures and videos. These illustrated guidelines will represent a helpful tool to go further in V. destructor research.

Published
2021
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10. Varroa destructor from the Laboratory to the Field: Control, Biocontrol and IPM Perspectives-A Review.

Author

Vilarem C, Piou V, Vogelweith F, and Vétillard A

Abstract

Varroa destructor is a real challenger for beekeepers and scientists: fragile out of the hive, tenacious inside a bee colony. From all the research done on the topic, we have learned that a better understanding of this organism in its relationship with the bee but also for itself is necessary. Its biology relies mostly on semiochemicals for reproduction, nutrition, or orientation. Many treatments have been developed over the years based on hard or soft acaricides or even on biocontrol techniques. To date, no real sustainable solution exists to reduce the pressure of the mite without creating resistances or harming honeybees. Consequently, the development of alternative disruptive tools against the parasitic life cycle remains open. It requires the combination of both laboratory and field results through a holistic approach based on health biomarkers. Here, we advocate for a more integrative vision of V. destructor research, where in vitro and field studies are more systematically compared and compiled. Therefore, after a brief state-of-the-art about the mite's life cycle, we discuss what has been done and what can be done from the laboratory to the field against V. destructor through an integrative approach.

Published
2021
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11. The nature of the arena surface affects the outcome of host-finding behavior bioassays in Varroa destructor (Anderson & Trueman).

Author

Piou V, Urrutia V, Laffont C, Hemptinne JL, and Vétillard A

Subjects
Animals, Bees growth & development, Female, Gelatin, Host-Parasite Interactions, Larva growth & development, Larva parasitology, Pupa growth & development, Pupa parasitology, Bees parasitology, Host-Seeking Behavior physiology, Varroidae physiology
Abstract

Varroa destructor, an acarian parasite of the Western honey bee Apis mellifera L., is a serious threat to colonies and beekeeping worldwide. The parasite lifecycle occurs in close synchrony with its host development. The females have to discriminate between different developmental stages of the host and trigger an appropriate behavioral response. Many studies have focused on these behavioral aspects, whether it is the choice of a precise host stage or the reproduction of female mites. Behavioral tests often require laboratory settings that are very different from the mite's environment. Our first experiment was designed to study the impact of the surface of test arena on the mite behavior. We found that plastic from Petri dishes commonly used as test arenas disturbs the female mites and can cause death. We searched for a substrate that does not harm mites and found that gelatin-coated plastic Petri dishes responded to these expectations. We then investigated the host choice behavior of phoretic mites confronted with larval stages of the bee on gelatin-coated arenas to watch if the well-documented orientation towards 5th instar larva was observable in our conditions. Pupal stages were included in the host choice experiments, initially to act as neutral stimuli. As white-eyed pupae were revealed attractive to the mite, several pupal stages were then included in a series of host choice bioassays. These additional experiments tend to show that the positive response to the white-eyed pupa stage depends on cues only delivered by living pupae. Further investigation on the nature and impact of these cues are needed as they could shed light on key signals involved in the parasite lifecycle.

Published
2019
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12. Effect of pollen extract supplementation on the varroatosis tolerance of honey bee (Apis mellifera) larvae reared in vitro.

Author

Piou V, Tabart J, Hemptinne JL, and Vétillard A

Subjects
Animal Feed analysis, Animals, Bees growth & development, Diet, Dietary Supplements analysis, Larva growth & development, Larva parasitology, Longevity, Plant Extracts administration & dosage, Pupa growth & development, Pupa parasitology, Bees parasitology, Host-Parasite Interactions, Pollen physiology, Varroidae physiology
Abstract

As the main source of lipids and proteins in honey bees, pollen is a major nutrient provider involved in development and health and has been studied for tolerance stimulation against pathogens and parasites. In the case of Varroa destructor Anderson & Trueman (Acari, Mesostigmata: Varroidae) parasitization, the lack of a complete laboratory system to rear both the bee larva and the acarian parasite limited the studies concerning larval nutrition effects on the bee tolerance and resistance against varroatosis. Due to the development of this complete rearing protocol, we managed to feed young honey bee larvae with pollen supplemented solutions and to study the effect on their later development under parasitism conditions. In our experimental conditions, pollen influences neither the deformity rate, nor the survival of bees both parasitized and unparasitized. However, pollen extract supplementation seems to significantly impact the weight of the spinning bee larvae without having an effect on the physiological weight loss during pupation, so the differences found at the larval stage remain the same as at emergence. Varroa has a deleterious effect on bee pupae and led to a steady increase of the physiological weight loss experienced during metamorphosis. Interestingly, this ponderal loss associated with Varroa parasitization seems to be reduced in the polyfloral pollen supplementation condition. Altogether, this work is to our knowledge the first to study in laboratory conditions the impact of larval nutrition on the tolerance to parasitism. A diverse pollen diet may be beneficial to the bees' tolerance against V. destructor parasitism.

Published
2018
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13. Impact of the Phoretic Phase on Reproduction and Damage Caused by Varroa destructor (Anderson and Trueman) to Its Host, the European Honey Bee (Apis mellifera L.).

Author

Piou V, Tabart J, Urrutia V, Hemptinne JL, and Vétillard A

Subjects
Animals, Bees genetics, Bees virology, Female, Gene Expression Regulation, Larva growth & development, Male, Picornaviridae physiology, Reproduction, Survival Analysis, Varroidae virology, Vitellogenins genetics, Bees parasitology, Bees physiology, Host-Parasite Interactions, Varroidae physiology
Abstract

Varroa destructor is a parasitic mite of the honeybee that causes thousands of colony losses worldwide. The parasite cycle is composed of a phoretic and a reproductive phase. During the former, mites stay on adult bees, mostly on nurses, to feed on hemolymph. During the latter, the parasites enter brood cells and reproduce. We investigated if the type of bees on which Varroa stays during the phoretic phase and if the duration of this stay influenced the reproductive success of the parasite and the damage caused to bees. For that purpose, we used an in vitro rearing method developed in our laboratory to assess egg laying rate and the presence and number of fully molted daughters. The expression level of two Varroa vitellogenin genes (VdVg1 and VdVg2), known to vary throughout reproduction, was also quantified. Results showed that the status of the bees or time spent during the phoretic phase impacts neither reproduction parameters nor the Varroa vitellogenin genes levels of expression. However, we correlated these parameters to the gene expression and demonstrated that daughters expressed the vitellogenin genes at lower levels than their mother. Regarding the damage to bees, the data indicated that a longer stay on adult bees during the phoretic phase resulted in more frequent physical deformity in newborn bees. We showed that those mites carry more viral loads of the Deformed Wing Virus and hence trigger more frequently overt infections. This study provides new perspectives towards a better understanding of the Varroa-honeybee interactions.

Published
2016
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