Conservation Genomics of the Declining North American Bumblebee Reveals Inbreeding and Selection on Immune Genes

Overview

Journal Front Genet

Date 2018 Aug 28

PMID 30147708

Citations 22

Authors

Clement F Kent

Alivia Dey

Harshilkumar Patel

Nadejda Tsvetkov

Tanushree Tiwari

Victoria J MacPhail

Yann Gobeil

Brock A Harpur

James Gurtowski

Michael C Schatz

Sheila R Colla

Amro Zayed

Affiliations

Soon will be listed here.

Abstract

The yellow-banded bumblebee was common in North America but has recently declined and is now on the IUCN Red List of threatened species. The causes of s decline are not well understood. Our objectives were to create a partial genome and then use this to estimate population data of conservation interest, and to determine whether genes showing signs of recent selection suggest a specific cause of decline. First, we generated a draft partial genome (contig set) for , sequenced using Pacific Biosciences RS II at an average depth of 35×. Second, we sequenced the individual genomes of 22 bumblebee gynes from Ontario and Quebec using Illumina HiSeq 2500, each at an average depth of 20×, which were used to improve the PacBio genome calls and for population genetic analyses. The latter revealed that several samples had long runs of homozygosity, and individuals had high inbreeding coefficient F, consistent with low effective population size. Our data suggest that 's effective population size has decreased orders of magnitude from pre-Holocene levels. We carried out tests of selection to identify genes that may have played a role in ameliorating environmental stressors underlying s decline. Several immune-related genes have signatures of recent positive selection, which is consistent with the pathogen-spillover hypothesis for 's decline. The new contig set can help solve the mystery of bumblebee decline by enabling functional genomics research to directly assess the health of pollinators and identify the stressors causing declines.

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