Rapid adaptive radiation of Darwin's finches depends on ancestral genetic modules

Carl Johan Rubin; Erik D. Enbody; Mariya P. Dobreva; Arhat Abzhanov; Brian W. Davis; Sangeet Lamichhaney; Mats Pettersson; Ashley T. Sendell-Price; C. Grace Sprehn; Carlos A. Valle; Karla Vasco; Ola Wallerman; B. Rosemary Grant; Peter R. Grant; Leif Andersson

doi:10.1126/sciadv.abm5982

Rapid adaptive radiation of Darwin's finches depends on ancestral genetic modules

Carl Johan Rubin
, Erik D. Enbody
, Mariya P. Dobreva
, Arhat Abzhanov
, Brian W. Davis
, Sangeet Lamichhaney
, Mats Pettersson
, Ashley T. Sendell-Price
, C. Grace Sprehn
, Carlos A. Valle
, Karla Vasco
, Ola Wallerman
, B. Rosemary Grant
, Peter R. Grant
, Leif Andersson^*

^*Corresponding author for this work

Uppsala University
Havforskningsinstituttet
Imperial College London
Texas A&M University
Kent State University
University of Oxford
Princeton University
Swedish University of Agricultural Sciences

Research output: Contribution to journal › Article › peer-review

43 Scopus citations

Abstract

Recent adaptive radiations are models for investigating mechanisms contributing to the evolution of biodiversity. An unresolved question is the relative importance of new mutations, ancestral variants, and introgressive hybridization for phenotypic evolution and speciation. Here, we address this issue using Darwin's finches and investigate the genomic architecture underlying their phenotypic diversity. Admixture mapping for beak and body size in the small, medium, and large ground finches revealed 28 loci showing strong genetic differentiation. These loci represent ancestral haplotype blocks with origins predating speciation events during the Darwin's finch radiation. Genes expressed in the developing beak are overrepresented in these genomic regions. Ancestral haplotypes constitute genetic modules for selection and act as key determinants of the unusual phenotypic diversity of Darwin's finches. Such ancestral haplotype blocks can be critical for how species adapt to environmental variability and change.

Original language	English
Article number	abm5982
Journal	Science Advances
Volume	8
Issue number	27
DOIs	https://doi.org/10.1126/sciadv.abm5982
State	Published - Jul 2022

Access to Document

10.1126/sciadv.abm5982

Cite this

Rubin, C. J., Enbody, E. D., Dobreva, M. P., Abzhanov, A., Davis, B. W., Lamichhaney, S., Pettersson, M., Sendell-Price, A. T., Sprehn, C. G., Valle, C. A., Vasco, K., Wallerman, O., Grant, B. R., Grant, P. R., & Andersson, L. (2022). Rapid adaptive radiation of Darwin's finches depends on ancestral genetic modules. Science Advances, 8(27), Article abm5982. https://doi.org/10.1126/sciadv.abm5982

@article{c1a06d428bac418a968586e944c60e7f,

title = "Rapid adaptive radiation of Darwin's finches depends on ancestral genetic modules",

abstract = "Recent adaptive radiations are models for investigating mechanisms contributing to the evolution of biodiversity. An unresolved question is the relative importance of new mutations, ancestral variants, and introgressive hybridization for phenotypic evolution and speciation. Here, we address this issue using Darwin's finches and investigate the genomic architecture underlying their phenotypic diversity. Admixture mapping for beak and body size in the small, medium, and large ground finches revealed 28 loci showing strong genetic differentiation. These loci represent ancestral haplotype blocks with origins predating speciation events during the Darwin's finch radiation. Genes expressed in the developing beak are overrepresented in these genomic regions. Ancestral haplotypes constitute genetic modules for selection and act as key determinants of the unusual phenotypic diversity of Darwin's finches. Such ancestral haplotype blocks can be critical for how species adapt to environmental variability and change.",

author = "Rubin, \{Carl Johan\} and Enbody, \{Erik D.\} and Dobreva, \{Mariya P.\} and Arhat Abzhanov and Davis, \{Brian W.\} and Sangeet Lamichhaney and Mats Pettersson and Sendell-Price, \{Ashley T.\} and Sprehn, \{C. Grace\} and Valle, \{Carlos A.\} and Karla Vasco and Ola Wallerman and Grant, \{B. Rosemary\} and Grant, \{Peter R.\} and Leif Andersson",

note = "Publisher Copyright: {\textcopyright} 2022 The Authors.",

year = "2022",

month = jul,

doi = "10.1126/sciadv.abm5982",

language = "Ingl{\'e}s",

volume = "8",

journal = "Science Advances",

issn = "2375-2548",

publisher = "American Association for the Advancement of Science",

number = "27",

}

TY - JOUR

T1 - Rapid adaptive radiation of Darwin's finches depends on ancestral genetic modules

AU - Rubin, Carl Johan

AU - Enbody, Erik D.

AU - Dobreva, Mariya P.

AU - Abzhanov, Arhat

AU - Davis, Brian W.

AU - Lamichhaney, Sangeet

AU - Pettersson, Mats

AU - Sendell-Price, Ashley T.

AU - Sprehn, C. Grace

AU - Valle, Carlos A.

AU - Vasco, Karla

AU - Wallerman, Ola

AU - Grant, B. Rosemary

AU - Grant, Peter R.

AU - Andersson, Leif

PY - 2022/7

Y1 - 2022/7

N2 - Recent adaptive radiations are models for investigating mechanisms contributing to the evolution of biodiversity. An unresolved question is the relative importance of new mutations, ancestral variants, and introgressive hybridization for phenotypic evolution and speciation. Here, we address this issue using Darwin's finches and investigate the genomic architecture underlying their phenotypic diversity. Admixture mapping for beak and body size in the small, medium, and large ground finches revealed 28 loci showing strong genetic differentiation. These loci represent ancestral haplotype blocks with origins predating speciation events during the Darwin's finch radiation. Genes expressed in the developing beak are overrepresented in these genomic regions. Ancestral haplotypes constitute genetic modules for selection and act as key determinants of the unusual phenotypic diversity of Darwin's finches. Such ancestral haplotype blocks can be critical for how species adapt to environmental variability and change.

AB - Recent adaptive radiations are models for investigating mechanisms contributing to the evolution of biodiversity. An unresolved question is the relative importance of new mutations, ancestral variants, and introgressive hybridization for phenotypic evolution and speciation. Here, we address this issue using Darwin's finches and investigate the genomic architecture underlying their phenotypic diversity. Admixture mapping for beak and body size in the small, medium, and large ground finches revealed 28 loci showing strong genetic differentiation. These loci represent ancestral haplotype blocks with origins predating speciation events during the Darwin's finch radiation. Genes expressed in the developing beak are overrepresented in these genomic regions. Ancestral haplotypes constitute genetic modules for selection and act as key determinants of the unusual phenotypic diversity of Darwin's finches. Such ancestral haplotype blocks can be critical for how species adapt to environmental variability and change.

UR - https://www.scopus.com/pages/publications/85133885535

U2 - 10.1126/sciadv.abm5982

DO - 10.1126/sciadv.abm5982

M3 - Artículo

C2 - 35857449

AN - SCOPUS:85133885535

SN - 2375-2548

VL - 8

JO - Science Advances

JF - Science Advances

IS - 27

M1 - abm5982

ER -

Rapid adaptive radiation of Darwin's finches depends on ancestral genetic modules

Abstract

Access to Document

Other files and links

Fingerprint

Cite this