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Grooming Behavior and Gene Expression of the Indiana ``Mite-Biter

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Grooming Behavior and Gene Expression of the Indiana ``Mite-Biter Grooming behavior and gene expression of the Indiana “mite-biter” honey bee stock Nuria Morfin, Krispn Given, Mathew Evans, Ernesto Guzman-Novoa, GregJ. Hunt To cite this version: Nuria Morfin, Krispn Given, Mathew Evans, Ernesto Guzman-Novoa, Greg J. Hunt. Grooming be- havior and gene expression of the Indiana “mite-biter” honey bee stock. Apidologie, 2020, 51 (2), pp.267-275. 10.1007/s13592-019-00710-y. hal-03084266 HAL Id: hal-03084266 https://hal.archives-ouvertes.fr/hal-03084266 Submitted on 21 Dec 2020 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Apidologie (2020) 51:267–275 Original Article * The Author(s), 2019 DOI: 10.1007/s13592-019-00710-y Grooming behavior and gene expression of the Indiana “mite-biter” honey bee stock 1 2 3 1 Nuria MORFIN , Krispn GIVEN , Mathew EVA NS , Ernesto GUZMAN-NOVOA , 2 Greg J. HUNT 1School of Environmental Sciences, University of Guelph, 50 Stone Road East, Guelph, Ontario N1G 2W1, Canada 2Department of Entomology, Purdue University, 901 W State St, West Lafayette, IN 47907, USA 3Woodland Honey, Van Buren, IN, USA Received 28 March 2019 – Revised 9 August 2019 – Accepted 24 October 2019 Abstract – This study was conducted to evaluate the Indiana “mite-biter” honey bee stock, which has been selected for increased mutilation of Varroa destructor mites (“mite biting” behavior). A comparison between colonies of the selected stock and colonies of unselected Italian bees showed that the proportion of mutilated mites, the severity of mutilations, and winter colony survival were higher in Indiana mite-biter colonies. Additionally, the number of fallen mites and the rate of mite population growth were lower in the colonies of the selected genotype than in those of the unselected genotype. The expression of a gene associated with grooming behavior, AmNrx-1 (neurexin ), was significantly higher in the selected stock. Moreover, AmNrx-1 expression was positively correlated with the proportion of mutilated mites but not with mite population growth. AmNrx-1 may have the potential to be used for marker-assisted selection. This study provides evidence that selection for mite-biting behavior reduces V. destructor infestations, increases colony survival and increases the expression of a grooming behavior– associated gene. Varroa destructor / grooming behavior / chewed mites / gene expression 1. INTRODUCTION et al. 2014; Reyes-Quintana et al. 2019). Two bee behavioral traits that restrain V. destructor Studies conducted in Europe and North Amer- population growth in colonies are grooming be- ica have demonstrated that the single most impor- havior (Rinderer et al. 2010; Arechavaleta- tant factor associated with honey bee colony mor- Velasco and Guzmán-Novoa 2001), the removal tality is the mite Varroa destructor (Guzman- of mites from the bees’ bodies, and the Varroa Novoa et al. 2010; Le Conte et al. 2010). Rela- sensitive hygiene (VSH) trait, which involves the tively low mite infestation levels can cause severe ability of bees to detect and remove infested brood damages in bees of different genotypes (De Jong where V. destructor reproduces (Ibrahim and 1997; Bowen-Walker and Gunn 2001; Büchler Spivak 2006; Harbo and Harris 2009). Stocks selected for increased VSH by researchers from the United States Department of Agriculture Electronic supplementary material The online version of (USDA) have been made available to North this article (https://doi.org/10.1007/s13592-019-00710-y) contains supplementary material, which is available to American queen breeders (Danka et al. 2011). authorized users. Grooming behavior, however, is difficult to measure because there are no practical assays to Corresponding author: N. Morfin, test colonies and thus, honey bee stocks selected [email protected] Manuscript editor: Klaus Hartfelder for this trait are not generally available to queen 268 N. Morfin et al. producers. Nevertheless, individual grooming as- biter stock by comparing it with an Italian com- says have demonstrated that vigorous grooming is mercial genotype for V. destructor mutilations, important for successful removal of mites from mite population growth, and winter survival. We bees (Guzman-Novoa et al. 2012), although in- also correlated mite population growth and the tense grooming could decrease by V. destructor proportion of mutilated mites with the expression parasitism (Morfin et al. 2019). Individual assays of AmNrx-1 in bees, to assess the value of this were also used in backcrossed bees that were gene as a potential marker of V. destructor genotyped at over 1000 single nucleotide poly- resistance. morphisms (SNPs) to identify quantitative trait loci (QTL) associated with this behavior 2. MATERIALS AND METHODS (Arechavaleta-Velasco et al. 2012). The most sig- nificant QTL region in chromosome 5 contained 2.1. Colonies AmNrx-1 , a gene that encodes for neurexin-1, a presynaptic protein involved in synapse differen- An apiary with 36 colonies was established in tiation and function (Tabuchi and Südhof 2002). West Lafayette, IN, USA. Half of the colonies Individual bees that were vigorous groomers ex- were headed by sister queens from the stock se- hibited higher expression of AmNrx-1 compared lected for increased mutilation of V. d est ru ct or to bees that groomed lightly or not at all mites, or Indiana mite-biter, and half were headed (Hamiduzzaman et al. 2017). In other species, this by sister queens from unselected Italian bees. The gene has been associated with neural disorders Indiana mite-biter queens were reared from the such as autism in humans (Kim et al. 2008)and selected stock established in 1997 at Purdue Uni- auto-grooming in mice (Etherton et al. 2009). versity, which initially included a queen from One study reported that the proportion of dam- VSH stock and two Russian queens, but the ma- aged mites (presumably chewed by worker bees) jority of the initial population was from local that fall onto sampling sheets is a good indicator Indiana queen breeders and feral colonies collect- of grooming behavior (Andino and Hunt 2011). ed in Indiana and Ohio. The Italian queens used in This colony trait, referred to as “mite biting,” has this study came from a commercial California been used in a breeding program to select for breeder that did not attempt to select for grooming increased V. destructor resistance (Hunt et al. behavior. The experimental colonies were created 2016). The program is currently carried out by by dividing the bee population and brood of col- Purdue University’s researchers in collaboration onies into two equal parts. The divisions of the with beekeepers from USA Midwest states. In a colonies were made on early June 2017. The previous study, the selected stock was compared resulting colonies contained three frames of brood to commercial Carniolan stocks by beekeepers in and a frame of honey and pollen, plus the adhering the Midwest region. “Mite-biter” colonies had bees to provide a starting population of about about one-third of the mite levels and higher an- 15,000 bees. Since the divided colonies were to nual survival rate than Carniolan commercial bees remain in the same apiary, emerging brood and (Hunt et al. 2016). Additionally, other honey bee combs with nurse bees were preferentially placed stocks selected for low mite population growth in the colony that was to be at a new hive location have shown significantly lower numbers of fallen within the apiary and the colonies were turned mites and higher percentages of injured mites around to face the perimeter of the apiary. These compared to unselected stocks (Guzman-Novoa measures were taken to minimize drifting and to et al. 2012). obtain equal colony populations since most older The aim of this study was to assess the efficacy field bees attempt to return to the original location. of selecting for increased mutilation of A test queen of each type was introduced into each V. destructor mites as a tool to breed half of each divided colony. The allocation of the V. destructor resistant bees and the possible in- queen types to the experimental colonies was volvement of AmNrx-1 in mite biting behavior. done at random. The population of the colonies We expanded the evaluation of the Indiana mite- (number of frames with brood and adult bees) was Evaluation of the “mite-biter” stock 269 evaluated as per Delaplane et al. (2013) and was 2.3. RNA extraction, cDNA synthesis, and similar between the colonies included in the ex- relative gene expression (qRT-PCR) periment. All the colonies received the same man- agement throughout the course of the experiment Total RNA was extracted from a pool of 30 and were not treated for V. d est ru ct or control. honey bee heads per colony, from the 33 colonies (15 Italian and 18 Indiana mite-biter colonies) 2.2. V. destructor infestation levels, biting using TRIzol® reagent (Invitrogen, Carslbad, behavior, and winter survival CA, USA) as per manufacturer’s protocol. cDNA for qRT-PCR reactions was prepared using V. de st ru ct or infestation levels and the propor- 2000 ng of RNA for each sample (RevertAid™ tion of damaged (“chewed”) mites were deter- H Minus First Strand cDNA Synthesis Kit; mined twice in each colony in July and October Fermentas, Burlington ON, Canada). The qRT- 2017. The initial evaluation of the colonies began PCR was performed with a BioRad CFX96™ 24 days after the introduction of queens to the thermocycler (Bio-Rad Laboratories, experimental colonies.
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