Location: Bee Research Laboratory
Project Number: 8042-21000-277-01-R
Project Type: Reimbursable Cooperative Agreement
Start Date: Feb 1, 2010
End Date: Jan 31, 2014
The parasitic mite Varroa destructor is the central pest of domesticated and free-living honey bees, causing direct impacts on bee health as well as indirect effects caused by vectoring viruses and other bee disease agents. Genomic information for this pest can be used to develop gene-based control strategies, determine weak points for conventional (chemical) controls, identify targets for biological control, and show how mites find honey bee hosts and reproduce in resistant and susceptible bee lineages. We will use emerging high-throughput sequencing techniques to sequence, assemble and annotate (describe key traits of) the genome of this mite. Sequencing will be completed in the first year of the project and released publically into genomic databases. Gene expression work aimed at discovering mite weaknesses will be completed in the second year and targets for mite control will be identified throughout the project. We will increase project impacts through a cost-effective partnership across existing sequencing and informatics centers and by choosing appropriate sequencing techniques for specific questions. We will leverage this project by engaging ca. 40 academic and governmental researchers in a volunteer consortium. The resulting insights will be used to improve honey bee health and crop pollination.
We will carry out genomic sequencing exceeding 60X coverage of the 565 million base-pair genome of Varroa destructor with an ‘optimal’ mix of straight and end-pair SOLEXA genomic sequencing reads, followed by genome assembly and pipeline annotation with resources provided by the US National Institutes of Health, NCBI. Specifically, we will carry out three SOLEXA flow cell runs with straight (72 bp) reads generated from Varroa genomic DNA templates and one SOLEXA endpair run (72 bp) generated from the same source material. Transcriptome surveys will be carried out using ROCHE Titanium pyrosequencing, focused on 1) nymphal development, 2) host finding (tarsal library), 3) immune responses (gut with and without virus infection), and 4) gut microbes. Single-nucleotide polymorphisms (SNPs) and protein polymorphism will be discovered using the ABI SOLiD platform on the mite transcriptome. These data will be aligned with homologous sequence data from the genome reads and from the 454 transcriptome reads to give an abundance of SNPs. Development and testing of a canonical gene set will be followed by integration and posting of emerging data via Beebase, NCBI, and other public databases.