Selection and hybridization shaped the rapid spread of African honey bee ancestry in the Americas

Selection and hybridization shaped the rapid spread of African honey bee ancestry in the Americas

Recent biological invasions offer 'natural' laboratories to understand the genetics and ecology of adaptation, hybridization, and range limits. One of the most impressive and well-documented biological invasions of the 20th century began in 1957 when Apis mellifera scutellata honey bees sw...

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Veröffentlicht in:PLoS genetics 2020-10, Vol.16 (10), p.e1009038-e1009038
Hauptverfasser: Calfee, Erin, Agra, Marcelo Nicolás, Palacio, María Alejandra, Ramírez, Santiago R, Coop, Graham
Format: Artikel
Sprache:eng
Schlagworte:
Africa, Eastern
Americas
Animal behavior
Animals
Apis mellifera
Argentina
Beekeeping
Bees
Bees - genetics
Biology and Life Sciences
Brazil
California
Climate effects
Clines
Distribution
Earth Sciences
Ecology
Evolution
Funding
Genetic aspects
Genetic diversity
Genetic research
Genome, Insect - genetics
Genomes
Honey
Honeybee
Hybrid zones
Hybridization
Hybridization, Genetic - genetics
Invasions
Mitochondrial DNA
Nucleic Acid Hybridization
People and Places
Physiological aspects
Physiology
Polygenic inheritance
Polymorphism, Single Nucleotide - genetics
Population
Population biology
Recombination
Reproductive fitness
Selection, Genetic - genetics
Whole Genome Sequencing
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container_issue 10
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creator Calfee, Erin
Agra, Marcelo Nicolás
Palacio, María Alejandra
Ramírez, Santiago R
Coop, Graham
description Recent biological invasions offer 'natural' laboratories to understand the genetics and ecology of adaptation, hybridization, and range limits. One of the most impressive and well-documented biological invasions of the 20th century began in 1957 when Apis mellifera scutellata honey bees swarmed out of managed experimental colonies in Brazil. This newly-imported subspecies, native to southern and eastern Africa, both hybridized with and out-competed previously-introduced European honey bee subspecies. Populations of scutellata-European hybrid honey bees rapidly expanded and spread across much of the Americas in less than 50 years. We use broad geographic sampling and whole genome sequencing of over 300 bees to map the distribution of scutellata ancestry where the northern and southern invasions have presently stalled, forming replicated hybrid zones with European bee populations in California and Argentina. California is much farther from Brazil, yet these hybrid zones occur at very similar latitudes, consistent with the invasion having reached a climate barrier. At these range limits, we observe genome-wide clines for scutellata ancestry, and parallel clines for wing length that span hundreds of kilometers, supporting a smooth transition from climates favoring scutellata-European hybrid bees to climates where they cannot survive winter. We find no large effect loci maintaining exceptionally steep ancestry transitions. Instead, we find most individual loci have concordant ancestry clines across South America, with a build-up of somewhat steeper clines in regions of the genome with low recombination rates, consistent with many loci of small effect contributing to climate-associated fitness trade-offs. Additionally, we find no substantial reductions in genetic diversity associated with rapid expansions nor complete dropout of scutellata ancestry at any individual loci on either continent, which suggests that the competitive fitness advantage of scutellata ancestry at lower latitudes has a polygenic basis and that scutellata-European hybrid bees maintained large population sizes during their invasion. To test for parallel selection across continents, we develop a null model that accounts for drift in ancestry frequencies during the rapid expansion. We identify several peaks within a larger genomic region where selection has pushed scutellata ancestry to high frequency hundreds of kilometers past the present cline centers in both North and South America and tha
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At these range limits, we observe genome-wide clines for scutellata ancestry, and parallel clines for wing length that span hundreds of kilometers, supporting a smooth transition from climates favoring scutellata-European hybrid bees to climates where they cannot survive winter. We find no large effect loci maintaining exceptionally steep ancestry transitions. Instead, we find most individual loci have concordant ancestry clines across South America, with a build-up of somewhat steeper clines in regions of the genome with low recombination rates, consistent with many loci of small effect contributing to climate-associated fitness trade-offs. 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One of the most impressive and well-documented biological invasions of the 20th century began in 1957 when Apis mellifera scutellata honey bees swarmed out of managed experimental colonies in Brazil. This newly-imported subspecies, native to southern and eastern Africa, both hybridized with and out-competed previously-introduced European honey bee subspecies. Populations of scutellata-European hybrid honey bees rapidly expanded and spread across much of the Americas in less than 50 years. We use broad geographic sampling and whole genome sequencing of over 300 bees to map the distribution of scutellata ancestry where the northern and southern invasions have presently stalled, forming replicated hybrid zones with European bee populations in California and Argentina. California is much farther from Brazil, yet these hybrid zones occur at very similar latitudes, consistent with the invasion having reached a climate barrier. At these range limits, we observe genome-wide clines for scutellata ancestry, and parallel clines for wing length that span hundreds of kilometers, supporting a smooth transition from climates favoring scutellata-European hybrid bees to climates where they cannot survive winter. We find no large effect loci maintaining exceptionally steep ancestry transitions. Instead, we find most individual loci have concordant ancestry clines across South America, with a build-up of somewhat steeper clines in regions of the genome with low recombination rates, consistent with many loci of small effect contributing to climate-associated fitness trade-offs. Additionally, we find no substantial reductions in genetic diversity associated with rapid expansions nor complete dropout of scutellata ancestry at any individual loci on either continent, which suggests that the competitive fitness advantage of scutellata ancestry at lower latitudes has a polygenic basis and that scutellata-European hybrid bees maintained large population sizes during their invasion. To test for parallel selection across continents, we develop a null model that accounts for drift in ancestry frequencies during the rapid expansion. We identify several peaks within a larger genomic region where selection has pushed scutellata ancestry to high frequency hundreds of kilometers past the present cline centers in both North and South America and that may underlie high-fitness traits driving the invasion.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>33075065</pmid><doi>10.1371/journal.pgen.1009038</doi><orcidid>https://orcid.org/0000-0001-8431-0302</orcidid><orcidid>https://orcid.org/0000-0002-9732-3070</orcidid><orcidid>https://orcid.org/0000-0003-1306-1315</orcidid><orcidid>https://orcid.org/0000-0003-2145-1866</orcidid><oa>free_for_read</oa></addata></record>
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subjects Africa, Eastern
Americas
Animal behavior
Animals
Apis mellifera
Argentina
Beekeeping
Bees
Bees - genetics
Biology and Life Sciences
Brazil
California
Climate effects
Clines
Distribution
Earth Sciences
Ecology
Evolution
Funding
Genetic aspects
Genetic diversity
Genetic research
Genome, Insect - genetics
Genomes
Honey
Honeybee
Hybrid zones
Hybridization
Hybridization, Genetic - genetics
Invasions
Mitochondrial DNA
Nucleic Acid Hybridization
People and Places
Physiological aspects
Physiology
Polygenic inheritance
Polymorphism, Single Nucleotide - genetics
Population
Population biology
Recombination
Reproductive fitness
Selection, Genetic - genetics
Whole Genome Sequencing
title Selection and hybridization shaped the rapid spread of African honey bee ancestry in the Americas
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