Identification of a candidate sex determination gene in Culaea inconstans suggests convergent recruitment of an Amh duplicate in two lineages of stickleback

Identification of a candidate sex determination gene in Culaea inconstans suggests convergent recruitment of an Amh duplicate in two lineages of stickleback

Sex chromosomes vary greatly in their age and levels of differentiation across the tree of life. This variation is largely due to the rates of sex chromosome turnover in different lineages; however, we still lack an explanation for why sex chromosomes are so conserved in some lineages (e.g. mammals,...

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Bibliographic Details
Published in:Journal of evolutionary biology Vol. 35; no. 12; pp. 1683 - 1695
Main Authors: Jeffries, Daniel L., Mee, Jonathan A., Peichel, Catherine L.
Format: Journal Article
Language:English
Published: Switzerland Blackwell Publishing Ltd 01-12-2022
John Wiley and Sons Inc
Subjects:
Amh
Amphibians
Animals
Chromosome 20
Chromosomes
Convergence
Culaea inconstans
Divergence
Evolution
Evolution, Molecular
Fishes - genetics
Gene sequencing
Genomes
Mammals - genetics
Recruitment
Reproduction (copying)
Sex
sex chromosome evolution
sex chromosome turnover
Sex chromosomes
Sex Chromosomes - genetics
Sex determination
Sex Determination Processes
Smegmamorpha - genetics
stickleback
teleosts
teleosts
stickleback
Amh
sex chromosome evolution
sex chromosome turnover
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Summary:Sex chromosomes vary greatly in their age and levels of differentiation across the tree of life. This variation is largely due to the rates of sex chromosome turnover in different lineages; however, we still lack an explanation for why sex chromosomes are so conserved in some lineages (e.g. mammals, birds) but so labile in others (e.g. teleosts, amphibians). To identify general mechanisms driving transitions in sex determination systems or forces which favour their conservation, we first require empirical data on sex chromosome systems from multiple lineages. Stickleback fishes are a valuable model lineage for the study of sex chromosome evolution due to variation in sex chromosome systems between closely‐related species. Here, we identify the sex chromosome and a strong candidate for the master sex determination gene in the brook stickleback, Culaea inconstans. Using whole‐genome sequencing of wild‐caught samples and a lab cross, we identify AmhY, a male specific duplication of the gene Amh, as the candidate master sex determination gene. AmhY resides on Chromosome 20 in C. inconstans and is likely a recent duplication, as both AmhY and the sex‐linked region of Chromosome 20 show little sequence divergence. Importantly, this duplicate AmhY represents the second independent duplication and recruitment of Amh as the sex determination gene in stickleback and the eighth example known across teleosts. We discuss this convergence in the context of sex chromosome turnovers and the role that the Amh/AmhrII pathway, which is crucial for sex determination, may play in the evolution of sex chromosomes in teleosts. Sex chromosomes vary greatly in their age and levels of differentiation across the tree of life, largely due to the rates of sex chromosome turnover in different lineages. Here, we identify a novel, and likely young, turnover in stickleback fishes. Using whole‐genome sequencing we identify AmhY, a male specific duplication of the autosomal gene Amh, as the candidate master sex determination gene in brook stickleback, Culaea inconstans. Importantly, this duplicate AmhY represents the second independent duplication and recruitment of Amh as the sex determination gene in stickleback and the eighth example known across teleosts. This convergence may offer important clues as to the mechanisms and forces shaping sex chromosome evolution in teleosts.
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ISSN:1010-061X
1420-9101
DOI:10.1111/jeb.14034