Population genomics of invasive rodents on islands: Genetic consequences of colonization and prospects for localized synthetic gene drive

Population genomics of invasive rodents on islands: Genetic consequences of colonization and prospects for localized synthetic gene drive

Abstract Introduced rodent populations pose significant threats worldwide, with particularly severe impacts on islands. Advancements in genome editing have motivated interest in synthetic gene drives that could potentially provide efficient and localized suppression of invasive rodent populations. A...

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Main Authors: Kevin P. Oh, Aaron B. Shiels, Laura Shiels, Dimitri V. Blondel, Karl J. Campbell, J. Royden Saah, Alun L. Lloyd, Paul Q. Thomas, Fred Gould, Zaid Abdo, John R. Godwin, Antoinette J. Piaggio
Format: Article
Language:English
Published: Wiley 2021-05-01
Series:Evolutionary Applications
Subjects:
Cas9
CRISPR
genetic biocontrol
genome editing
Mus musculus
synthetic biology
Online Access:https://doi.org/10.1111/eva.13210
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spelling doaj-e2d27117772b41ca9e05ded3ae4e11732021-05-17T12:54:01ZengWileyEvolutionary Applications1752-45712021-05-011451421143510.1111/eva.13210Population genomics of invasive rodents on islands: Genetic consequences of colonization and prospects for localized synthetic gene driveKevin P. Oh0Aaron B. Shiels1Laura Shiels2Dimitri V. Blondel3Karl J. Campbell4J. Royden Saah5Alun L. Lloyd6Paul Q. Thomas7Fred Gould8Zaid Abdo9John R. Godwin10Antoinette J. Piaggio11National Wildlife Research Center USDA APHIS Wildlife Services Fort Collins Colorado USANational Wildlife Research Center USDA APHIS Wildlife Services Fort Collins Colorado USANational Wildlife Research Center USDA APHIS Wildlife Services Fort Collins Colorado USADepartment of Biological Sciences North Carolina State University Raleigh North Carolina USAIsland Conservation Puerto Ayora EcuadorIsland Conservation Puerto Ayora EcuadorGenetic Engineering and Society Center North Carolina State University Raleigh North Carolina USAThe Robinson Research Institute and School of Medicine The University of Adelaide Adelaide South Australia AustraliaGenetic Engineering and Society Center North Carolina State University Raleigh North Carolina USADepartment of Microbiology, Immunology and Pathology Colorado State University Fort Collins Colorado USADepartment of Biological Sciences North Carolina State University Raleigh North Carolina USANational Wildlife Research Center USDA APHIS Wildlife Services Fort Collins Colorado USAAbstract Introduced rodent populations pose significant threats worldwide, with particularly severe impacts on islands. Advancements in genome editing have motivated interest in synthetic gene drives that could potentially provide efficient and localized suppression of invasive rodent populations. Application of such technologies will require rigorous population genomic surveys to evaluate population connectivity, taxonomic identification, and to inform design of gene drive localization mechanisms. One proposed approach leverages the predicted shifts in genetic variation that accompany island colonization, wherein founder effects, genetic drift, and island‐specific selection are expected to result in locally fixed alleles (LFA) that are variable in neighboring nontarget populations. Engineering of guide RNAs that target LFA may thus yield gene drives that spread within invasive island populations, but would have limited impacts on nontarget populations in the event of an escape. Here we used pooled whole‐genome sequencing of invasive mouse (Mus musculus) populations on four islands along with paired putative source populations to test genetic predictions of island colonization and characterize locally fixed Cas9 genomic targets. Patterns of variation across the genome reflected marked reductions in allelic diversity in island populations and moderate to high degrees of differentiation from nearby source populations despite relatively recent colonization. Locally fixed Cas9 sites in female fertility genes were observed in all island populations, including a small number with multiplexing potential. In practice, rigorous sampling of presumptive LFA will be essential to fully assess risk of resistance alleles. These results should serve to guide development of improved, spatially limited gene drive design in future applications.https://doi.org/10.1111/eva.13210Cas9CRISPRgenetic biocontrolgenome editingMus musculussynthetic biology
collection DOAJ
language English
format Article
sources DOAJ
author Kevin P. Oh
Aaron B. Shiels
Laura Shiels
Dimitri V. Blondel
Karl J. Campbell
J. Royden Saah
Alun L. Lloyd
Paul Q. Thomas
Fred Gould
Zaid Abdo
John R. Godwin
Antoinette J. Piaggio
spellingShingle Kevin P. Oh
Aaron B. Shiels
Laura Shiels
Dimitri V. Blondel
Karl J. Campbell
J. Royden Saah
Alun L. Lloyd
Paul Q. Thomas
Fred Gould
Zaid Abdo
John R. Godwin
Antoinette J. Piaggio
Population genomics of invasive rodents on islands: Genetic consequences of colonization and prospects for localized synthetic gene drive
Evolutionary Applications
Cas9
CRISPR
genetic biocontrol
genome editing
Mus musculus
synthetic biology
author_facet Kevin P. Oh
Aaron B. Shiels
Laura Shiels
Dimitri V. Blondel
Karl J. Campbell
J. Royden Saah
Alun L. Lloyd
Paul Q. Thomas
Fred Gould
Zaid Abdo
John R. Godwin
Antoinette J. Piaggio
author_sort Kevin P. Oh
title Population genomics of invasive rodents on islands: Genetic consequences of colonization and prospects for localized synthetic gene drive
title_short Population genomics of invasive rodents on islands: Genetic consequences of colonization and prospects for localized synthetic gene drive
title_full Population genomics of invasive rodents on islands: Genetic consequences of colonization and prospects for localized synthetic gene drive
title_fullStr Population genomics of invasive rodents on islands: Genetic consequences of colonization and prospects for localized synthetic gene drive
title_full_unstemmed Population genomics of invasive rodents on islands: Genetic consequences of colonization and prospects for localized synthetic gene drive
title_sort population genomics of invasive rodents on islands: genetic consequences of colonization and prospects for localized synthetic gene drive
publisher Wiley
series Evolutionary Applications
issn 1752-4571
publishDate 2021-05-01
description Abstract Introduced rodent populations pose significant threats worldwide, with particularly severe impacts on islands. Advancements in genome editing have motivated interest in synthetic gene drives that could potentially provide efficient and localized suppression of invasive rodent populations. Application of such technologies will require rigorous population genomic surveys to evaluate population connectivity, taxonomic identification, and to inform design of gene drive localization mechanisms. One proposed approach leverages the predicted shifts in genetic variation that accompany island colonization, wherein founder effects, genetic drift, and island‐specific selection are expected to result in locally fixed alleles (LFA) that are variable in neighboring nontarget populations. Engineering of guide RNAs that target LFA may thus yield gene drives that spread within invasive island populations, but would have limited impacts on nontarget populations in the event of an escape. Here we used pooled whole‐genome sequencing of invasive mouse (Mus musculus) populations on four islands along with paired putative source populations to test genetic predictions of island colonization and characterize locally fixed Cas9 genomic targets. Patterns of variation across the genome reflected marked reductions in allelic diversity in island populations and moderate to high degrees of differentiation from nearby source populations despite relatively recent colonization. Locally fixed Cas9 sites in female fertility genes were observed in all island populations, including a small number with multiplexing potential. In practice, rigorous sampling of presumptive LFA will be essential to fully assess risk of resistance alleles. These results should serve to guide development of improved, spatially limited gene drive design in future applications.
topic Cas9
CRISPR
genetic biocontrol
genome editing
Mus musculus
synthetic biology
url https://doi.org/10.1111/eva.13210
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