Madeline H. Carpenter scite author profile

Humans have domesticated hundreds of animal and plant species for thousands of years. Artwork, archeological finds, recorded accounts, and other primary sources can provide glimpses into the historic management practices used over the course of a given species’ domestication history. Pairing historic data with newly available genomic data can allow us to identify where and how species were moved out of their native ranges, how gene flow may have occurred between distantly related populations, and quantify how selection and drift each contributed to levels of genetic diversity. Intersecting these approaches has greatly improved our understanding of many managed species; however, there has yet to be a thorough review in a managed insect. Here, we review the archival and genetic history of honey bees introduced to the mainland United States to reconstruct a comprehensive importation history. We find that since 1622, at least nine honey bee subspecies were imported from four of the five honey bee lineages and distributed en masse across the country. Many imported genotypes have genetic evidence of persisting today and may segregate non-randomly across the country. However, honey bee population genetic comparisons on the nationwide scale are not yet feasible because of gaps in genetic and archival records. We conclude by suggesting future avenues of research in both fields.

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Improved Apis mellifera reference genome based on the alternative long-read-based assemblies

Каскинова

Yunusbayev

Altinbaev

et al. 2021

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Apis mellifera L., the western honey bee is a major crop pollinator that plays a key role in beekeeping and serves as an important model organism in social behavior studies. Recent efforts have improved on the quality of the honey bee reference genome and developed a chromosome-level assembly of sixteen chromosomes, two of which are gapless. However, the rest suffer from 51 gaps, 160 unplaced/unlocalized scaffolds, and the lack of 2 distal telomeres. The gaps are located at the hard-to-assemble extended highly repetitive chromosomal regions that may contain functional genomic elements. Here, we use de-novo re-assemblies from the most recent reference genome Amel_HAv_3.1 raw reads and other long-read-based assemblies (INRA_AMelMel_1.0, ASM1384120v1, and ASM1384124v1) of the honey bee genome to resolve 13 gaps, five unplaced/unlocalized scaffolds and, the lacking telomeres of the Amel_HAv_3.1. The total length of the resolved gaps is 848,747 bp. The accuracy of the corrected assembly was validated by mapping PacBio reads and performing gene annotation assessment. Comparative analysis suggests that the PacBio-reads-based assemblies of the honey bee genomes failed in the same highly repetitive extended regions of the chromosomes, especially on chromosome 10. To fully resolve these extended repetitive regions, further work using ultra-long Nanopore sequencing would be needed. Our updated assembly facilitates more accurate reference-guided scaffolding and marker/sequence mapping in honey bee genomics studies.

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ImprovedApis melliferareference genome based on the alternative long-read-based assemblies

Каскинова

Yunusbayev

Altinbaev

et al. 2021

Preprint

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