Genetic diversity and thermal performance in invasive and native populations of African fig flies

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Genetic diversity and thermal performance in invasive and native populations of African fig flies. / Comeault, Aaron; Wang, Jeremy; Tittes, Silas et al.
Yn: Molecular Biology and Evolution, 28.02.2020.

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

HarvardHarvard

Comeault, A, Wang, J, Tittes, S, Isbell, K, Ingley, S, Hurlbert, A & Matute, D 2020, 'Genetic diversity and thermal performance in invasive and native populations of African fig flies', Molecular Biology and Evolution. <https://doi.org/10.1093/molbev/msaa050>

APA

Comeault, A., Wang, J., Tittes, S., Isbell, K., Ingley, S., Hurlbert, A., & Matute, D. (2020). Genetic diversity and thermal performance in invasive and native populations of African fig flies. Molecular Biology and Evolution. https://doi.org/10.1093/molbev/msaa050

CBE

Comeault A, Wang J, Tittes S, Isbell K, Ingley S, Hurlbert A, Matute D. 2020. Genetic diversity and thermal performance in invasive and native populations of African fig flies. Molecular Biology and Evolution.

MLA

VancouverVancouver

Comeault A, Wang J, Tittes S, Isbell K, Ingley S, Hurlbert A et al. Genetic diversity and thermal performance in invasive and native populations of African fig flies. Molecular Biology and Evolution. 2020 Chw 28.

Author

Comeault, Aaron ; Wang, Jeremy ; Tittes, Silas et al. / Genetic diversity and thermal performance in invasive and native populations of African fig flies. Yn: Molecular Biology and Evolution. 2020.

RIS

TY - JOUR

T1 - Genetic diversity and thermal performance in invasive and native populations of African fig flies

AU - Comeault, Aaron

AU - Wang, Jeremy

AU - Tittes, Silas

AU - Isbell, Kristin

AU - Ingley, Spencer

AU - Hurlbert, Allen

AU - Matute, Daniel

PY - 2020/2/28

Y1 - 2020/2/28

N2 - During biological invasions, invasive populations can suffer losses of genetic diversity that are predicted to negatively impact their fitness/performance. Despite examples of invasive populations harboring lower diversity than conspecific populations in their native range, few studies have linked this lower diversity to a decrease in fitness. Using genome sequences, we show that invasive populations of the African fig fly, Zaprionus indianus, have less genetic diversity than conspecific populations in their native range and that diversity is proportionally lower in regions of the genome experiencing low recombination rates. This result suggests that selection may have played a role in lowering diversity in the invasive populations. We next use interspecific comparisons to show that genetic diversity remains relatively high in invasive populations of Z. indianus when compared to other closely related species. By comparing genetic diversity in orthologous gene regions, we also show that the genome-wide landscape of genetic diversity differs between invasive and native populations of Z. indianus, indicating that invasion not only affects amounts of genetic diversity, but also how that diversity is distributed across the genome. Finally, we use parameter estimates from thermal performance curves measured for 13 species of Zaprionus to show that Z. indianus has the broadest thermal niche of measured species, and that performance does not differ between invasive and native populations. These results illustrate how aspects of genetic diversity in invasive species can be decoupled from measures of fitness, and that a broad thermal niche may have helped facilitate Z. indianus’s range expansion.

AB - During biological invasions, invasive populations can suffer losses of genetic diversity that are predicted to negatively impact their fitness/performance. Despite examples of invasive populations harboring lower diversity than conspecific populations in their native range, few studies have linked this lower diversity to a decrease in fitness. Using genome sequences, we show that invasive populations of the African fig fly, Zaprionus indianus, have less genetic diversity than conspecific populations in their native range and that diversity is proportionally lower in regions of the genome experiencing low recombination rates. This result suggests that selection may have played a role in lowering diversity in the invasive populations. We next use interspecific comparisons to show that genetic diversity remains relatively high in invasive populations of Z. indianus when compared to other closely related species. By comparing genetic diversity in orthologous gene regions, we also show that the genome-wide landscape of genetic diversity differs between invasive and native populations of Z. indianus, indicating that invasion not only affects amounts of genetic diversity, but also how that diversity is distributed across the genome. Finally, we use parameter estimates from thermal performance curves measured for 13 species of Zaprionus to show that Z. indianus has the broadest thermal niche of measured species, and that performance does not differ between invasive and native populations. These results illustrate how aspects of genetic diversity in invasive species can be decoupled from measures of fitness, and that a broad thermal niche may have helped facilitate Z. indianus’s range expansion.

UR - https://oup.silverchair-cdn.com/oup/backfile/Content_public/Journal/mbe/37/7/10.1093_molbev_msaa050/1/msaa050_supplementary_data.pdf?Expires=1616131335&Signature=YvQNUYrRSun6Lle6usQ6kKyNyLMTYee5SfOZibZI9UmXD3d2VbH1gJr84NSmLgt28N0Tt4BnYagJt2IandnsLAkMX3A9wsPiVCQe6b~9tfQJrxfI8iZRuuKZ--cQ9xyIWxg9OfeJqLM3ZMllQSn5A3Yt6f5PJSpfp9xq0mxq2XnWoWkzQ1Iny3gwXMBwLe0W2h-d1AuKZUfMqFf1-wU3z7-eueu~aVJsVf3yXr5sCTSu2qmbR9TaNeoh7V9uURtuYvP60eR1XYR6vhn~~sdAEJLR8Wo2ELoy7NGSWLGAKC1WGSPii44ya0UmzGv5KIaJDsPSpljFX57urikpHkQATw__&Key-Pair-Id=APKAIE5G5CRDK6RD3PGA

M3 - Article

JO - Molecular Biology and Evolution

JF - Molecular Biology and Evolution

SN - 0737-4038

ER -