Evolution of cichlid vision via trans-regulatory divergence

Phenotypic evolution may occur through mutations that affect either the structure or expression of protein-coding genes. Although the evolution of color vision has historically been attributed to structural mutations within the opsin genes, recent research has shown that opsin regulatory mutations c...

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Bibliographic Details
Published in:BMC evolutionary biology 2012-12, Vol.12 (1), p.251-251, Article 251
Main Authors: O'Quin, Kelly E, Schulte, Jane E, Patel, Zil, Kahn, Nadia, Naseer, Zan, Wang, Helena, Conte, Matthew A, Carleton, Karen L
Format: Article
Language:English
Subjects:
Analysis
Animals
Biotechnology industry
Chromosome Mapping
Cichlidae
Cichlids - genetics
Cichlids - physiology
Color
Color vision
Color Vision - genetics
Crosses, Genetic
Deoxyribonucleic acid
Divergent evolution
DNA
DNA Mutational Analysis
Evolution & development
Evolution, Molecular
Gene Regulatory Networks
Genes
Genetic aspects
Genetic Linkage
Genetic regulation
Genetic research
Genomes
Genomics
Light
Mutation
Opsins - genetics
Physiological aspects
Polymorphism, Single Nucleotide
Quantitative genetics
Quantitative Trait Loci
Regulatory Sequences, Nucleic Acid
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Summary:Phenotypic evolution may occur through mutations that affect either the structure or expression of protein-coding genes. Although the evolution of color vision has historically been attributed to structural mutations within the opsin genes, recent research has shown that opsin regulatory mutations can also tune photoreceptor sensitivity and color vision. Visual sensitivity in African cichlid fishes varies as a result of the differential expression of seven opsin genes. We crossed cichlid species that express different opsin gene sets and scanned their genome for expression Quantitative Trait Loci (eQTL) responsible for these differences. Our results shed light on the role that different structural, cis-, and trans-regulatory mutations play in the evolution of color vision. We identified 11 eQTL that contribute to the divergent expression of five opsin genes. On three linkage groups, several eQTL formed regulatory "hotspots" associated with the expression of multiple opsins. Importantly, however, the majority of the eQTL we identified (8/11 or 73%) occur on linkage groups located trans to the opsin genes, suggesting that cichlid color vision has evolved primarily via trans-regulatory divergence. By modeling the impact of just two of these trans-regulatory eQTL, we show that opsin regulatory mutations can alter cichlid photoreceptor sensitivity and color vision at least as much as opsin structural mutations can. Combined with previous work, we demonstrate that the evolution of cichlid color vision results from the interplay of structural, cis-, and especially trans-regulatory loci. Although there are numerous examples of structural and cis-regulatory mutations that contribute to phenotypic evolution, our results suggest that trans-regulatory mutations could contribute to phenotypic divergence more commonly than previously expected, especially in systems like color vision, where compensatory changes in the expression of multiple genes are required in order to produce functional phenotypes.
ISSN:1471-2148
1471-2148
DOI:10.1186/1471-2148-12-251