The Genetic Basis of Adaptation following Plastic Changes in Coloration in a Novel Environment

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The Genetic Basis of Adaptation following Plastic Changes in Coloration in a Novel Environment. / Corl, Ammon; Bi, Ke; Luke, Claudia; Challa, Akshara Sree; Stern, Aaron James; Sinervo, Barry; Nielsen, Rasmus.

In: Current Biology, Vol. 28, No. 18, 2018, p. 2970-2977, e1-e7.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Corl, A, Bi, K, Luke, C, Challa, AS, Stern, AJ, Sinervo, B & Nielsen, R 2018, 'The Genetic Basis of Adaptation following Plastic Changes in Coloration in a Novel Environment', Current Biology, vol. 28, no. 18, pp. 2970-2977, e1-e7. https://doi.org/10.1016/j.cub.2018.06.075

APA

Corl, A., Bi, K., Luke, C., Challa, A. S., Stern, A. J., Sinervo, B., & Nielsen, R. (2018). The Genetic Basis of Adaptation following Plastic Changes in Coloration in a Novel Environment. Current Biology, 28(18), 2970-2977, e1-e7. https://doi.org/10.1016/j.cub.2018.06.075

Vancouver

Corl A, Bi K, Luke C, Challa AS, Stern AJ, Sinervo B et al. The Genetic Basis of Adaptation following Plastic Changes in Coloration in a Novel Environment. Current Biology. 2018;28(18):2970-2977, e1-e7. https://doi.org/10.1016/j.cub.2018.06.075

Author

Corl, Ammon ; Bi, Ke ; Luke, Claudia ; Challa, Akshara Sree ; Stern, Aaron James ; Sinervo, Barry ; Nielsen, Rasmus. / The Genetic Basis of Adaptation following Plastic Changes in Coloration in a Novel Environment. In: Current Biology. 2018 ; Vol. 28, No. 18. pp. 2970-2977, e1-e7.

Bibtex

@article{af386107876d4cdda6cac7fbef47b5f5,
title = "The Genetic Basis of Adaptation following Plastic Changes in Coloration in a Novel Environment",
abstract = "Phenotypic plasticity has been hypothesized to precede and facilitate adaptation to novel environments [1–8], but examples of plasticity preceding adaptation in wild populations are rare (but see [9, 10]). We studied a population of side-blotched lizards, Uta stansburiana, living on a lava flow that formed 22,500 years ago [11] to understand the origin of their novel melanic phenotype that makes them cryptic on the black lava. We found that lizards living on and off of the lava flow exhibited phenotypic plasticity in coloration but also appeared to have heritable differences in pigmentation. We sequenced the exomes of 104 individuals and identified two known regulators of melanin production, PREP and PRKAR1A, which had markedly increased levels of divergence between lizards living on and off the lava flow. The derived variants in PREP and PRKAR1A were only found in the lava population and were associated with increased pigmentation levels in an experimental cohort of hatchling lizards. Simulations suggest that the derived variants in the PREP and PRKAR1A genes arose recently and were under strong positive selection in the lava population. Overall, our results suggest that ancestral plasticity for coloration facilitated initial survival in the lava environment and was followed by genetic changes that modified the phenotype in the direction of the induced plastic response, possibly through de novo mutations. These observations provide a detailed example supporting the hypothesis that plasticity aids in the initial colonization of a novel habitat, with natural selection subsequently refining the phenotype with genetic adaptations to the new environment. Video Abstract: [Figure presented] Plasticity has been hypothesized to precede adaptation to new environments. Corl et al. show that melanic lizards from a lava flow have both ancestral plasticity in coloration and divergence in two genes that increase pigmentation. Plasticity aided in the initial colonization of the new habitat, where natural selection then refined the phenotype.",
keywords = "adaptation, Baldwin effect, crypsis, exon-capture, lizard, melanin, plasticity, PREP gene, PRKAR1A gene, Uta stansburiana",
author = "Ammon Corl and Ke Bi and Claudia Luke and Challa, {Akshara Sree} and Stern, {Aaron James} and Barry Sinervo and Rasmus Nielsen",
year = "2018",
doi = "10.1016/j.cub.2018.06.075",
language = "English",
volume = "28",
pages = "2970--2977, e1--e7",
journal = "Current Biology",
issn = "0960-9822",
publisher = "Cell Press",
number = "18",

}

RIS

TY - JOUR

T1 - The Genetic Basis of Adaptation following Plastic Changes in Coloration in a Novel Environment

AU - Corl, Ammon

AU - Bi, Ke

AU - Luke, Claudia

AU - Challa, Akshara Sree

AU - Stern, Aaron James

AU - Sinervo, Barry

AU - Nielsen, Rasmus

PY - 2018

Y1 - 2018

N2 - Phenotypic plasticity has been hypothesized to precede and facilitate adaptation to novel environments [1–8], but examples of plasticity preceding adaptation in wild populations are rare (but see [9, 10]). We studied a population of side-blotched lizards, Uta stansburiana, living on a lava flow that formed 22,500 years ago [11] to understand the origin of their novel melanic phenotype that makes them cryptic on the black lava. We found that lizards living on and off of the lava flow exhibited phenotypic plasticity in coloration but also appeared to have heritable differences in pigmentation. We sequenced the exomes of 104 individuals and identified two known regulators of melanin production, PREP and PRKAR1A, which had markedly increased levels of divergence between lizards living on and off the lava flow. The derived variants in PREP and PRKAR1A were only found in the lava population and were associated with increased pigmentation levels in an experimental cohort of hatchling lizards. Simulations suggest that the derived variants in the PREP and PRKAR1A genes arose recently and were under strong positive selection in the lava population. Overall, our results suggest that ancestral plasticity for coloration facilitated initial survival in the lava environment and was followed by genetic changes that modified the phenotype in the direction of the induced plastic response, possibly through de novo mutations. These observations provide a detailed example supporting the hypothesis that plasticity aids in the initial colonization of a novel habitat, with natural selection subsequently refining the phenotype with genetic adaptations to the new environment. Video Abstract: [Figure presented] Plasticity has been hypothesized to precede adaptation to new environments. Corl et al. show that melanic lizards from a lava flow have both ancestral plasticity in coloration and divergence in two genes that increase pigmentation. Plasticity aided in the initial colonization of the new habitat, where natural selection then refined the phenotype.

AB - Phenotypic plasticity has been hypothesized to precede and facilitate adaptation to novel environments [1–8], but examples of plasticity preceding adaptation in wild populations are rare (but see [9, 10]). We studied a population of side-blotched lizards, Uta stansburiana, living on a lava flow that formed 22,500 years ago [11] to understand the origin of their novel melanic phenotype that makes them cryptic on the black lava. We found that lizards living on and off of the lava flow exhibited phenotypic plasticity in coloration but also appeared to have heritable differences in pigmentation. We sequenced the exomes of 104 individuals and identified two known regulators of melanin production, PREP and PRKAR1A, which had markedly increased levels of divergence between lizards living on and off the lava flow. The derived variants in PREP and PRKAR1A were only found in the lava population and were associated with increased pigmentation levels in an experimental cohort of hatchling lizards. Simulations suggest that the derived variants in the PREP and PRKAR1A genes arose recently and were under strong positive selection in the lava population. Overall, our results suggest that ancestral plasticity for coloration facilitated initial survival in the lava environment and was followed by genetic changes that modified the phenotype in the direction of the induced plastic response, possibly through de novo mutations. These observations provide a detailed example supporting the hypothesis that plasticity aids in the initial colonization of a novel habitat, with natural selection subsequently refining the phenotype with genetic adaptations to the new environment. Video Abstract: [Figure presented] Plasticity has been hypothesized to precede adaptation to new environments. Corl et al. show that melanic lizards from a lava flow have both ancestral plasticity in coloration and divergence in two genes that increase pigmentation. Plasticity aided in the initial colonization of the new habitat, where natural selection then refined the phenotype.

KW - adaptation

KW - Baldwin effect

KW - crypsis

KW - exon-capture

KW - lizard

KW - melanin

KW - plasticity

KW - PREP gene

KW - PRKAR1A gene

KW - Uta stansburiana

U2 - 10.1016/j.cub.2018.06.075

DO - 10.1016/j.cub.2018.06.075

M3 - Journal article

C2 - 30197088

AN - SCOPUS:85053541858

VL - 28

SP - 2970-2977, e1-e7

JO - Current Biology

JF - Current Biology

SN - 0960-9822

IS - 18

ER -

ID: 222568039