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Genome-wide patterns of differentiation within and among U.S. commercial honey bee stocks
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Genome-wide patterns of differentiation within and among U.S. commercial honey bee stocks
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Journal Article
Genome-wide patterns of differentiation within and among U.S. commercial honey bee stocks
2020
Overview
Background
The population genetics of U.S. honey bee stocks remain poorly characterized despite the agricultural importance of
Apis mellifera
as the major crop pollinator. Commercial and research-based breeding programs have made significant improvements of favorable genetic traits (e.g. production and disease resistance). The variety of bees produced by artificial selection provides an opportunity to characterize the genetic diversity and regions of the genome undergoing selection in commonly managed stocks.
Results
Pooled sequencing of eight honey bee stocks found strong genetic similarity among six of the stocks. Two stocks, Pol-line and Hilo, showed significant differentiation likely due to their intense and largely closed breeding for resistance to the parasitic
Varroa
mite. Few variants were identified as being specific to any one stock, indicating potential admixture among the sequenced stocks. Juxtaposing the underlying genetic variation of stocks selected for disease- and parasite-resistance behavior, we identified genes and candidate regions putatively associated with resistance regulated by hygienic behavior.
Conclusion
This study provides important insights into the distinct genetic characteristics and population diversity of honey bee stocks used in the United States, and provides further evidence of high levels of admixture in commercially managed honey bee stocks. Furthermore, breeding efforts to enhance parasite resistance in honey bees may have created unique genetic profiles. Genomic regions of interest have been highlighted for potential future work related to developing genetic markers for selection of disease and parasite resistance traits. Due to the vast genomic similarities found among stocks in general, our findings suggest that additional data regarding gene expression, epigenetic and regulatory information are needed to more fully determine how stock phenotypic diversity is regulated.
Publisher
BioMed Central,BioMed Central Ltd,Springer Nature B.V,BMC
Subject
/ Animal Genetics and Genomics
/ Animals
/ Bees
/ Biomedical and Life Sciences
/ FST
/ Genetics
/ Genomes
/ Genomics
/ High-Throughput Nucleotide Sequencing
/ Honey
/ Hygiene
/ Microbial Genetics and Genomics
/ Multicellular invertebrate genomics
/ Pool-seq
/ Principal components analysis
