Large-scale transcriptome sequencing reveals novel expression patterns for key sex-related genes in a sex-changing fish

Liu, Hui; Lamm, Melissa S.; Rutherford, Kim; Black, Michael A.; Godwin, John; Gemmell, Neil J.

doi:10.1186/s13293-015-0044-8

Cited by 92 publications

(137 citation statements)

References 191 publications

(217 reference statements)

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“…Although there were also some studies focusing on sex-biased genes in gonad or brain in zebrafish and other fishes (Small et al 2009; Wong et al 2014; Liu et al 2015), few of them have investigated the evolutionary dynamics of sex-biased genes and their driving forces. Our results in zebrafish are consistent with this from other model organisms.…”

Section: Discussionmentioning

confidence: 99%

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Both Male-Biased and Female-Biased Genes Evolve Faster in Fish Genomes

Yang

Zhang

2016

Genome Biol Evol

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Males and females often display extensive phenotypic differences, and many of these sexual dimorphisms are thought to result from differences between males and females in expression of genes present in both sexes. Sex-biased genes have been shown to exhibit accelerated rates of evolution in a wide array of species, however the cause of this remains enigmatic. In this study, we investigate the extent and evolutionary dynamics of sex-biased gene expression in zebrafish. Our results indicate that both male-biased genes and female-biased genes exhibit accelerated evolution at the protein level. In order to differentiate between adaptive and nonadaptive causes, we tested for codon usage bias and signatures of different selective regimes in our sequence data. Our results show that both male- and female-biased genes show signatures consistent with adaptive evolution. In order to test the generality of our findings across fish, we also analyzed publicly available data on sticklebacks, and found results consistent with our findings in zebrafish.

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Section: Discussionmentioning

confidence: 99%

“…Although there have been several studies of sex-biased genes expression in zebrafish and other fish species (Small et al 2009; Wong et al 2014; Liu et al 2015), few of them detailed the evolutionary dynamics of sex-biased genes. Hence, a comprehensive analysis of the expression and evolution of sex-biased genes in fishes is needed.…”

Section: Introductionmentioning

confidence: 99%

Both Male-Biased and Female-Biased Genes Evolve Faster in Fish Genomes

Yang

Zhang

2016

Genome Biol Evol

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“…However, a much broader distribution of effect sizes describes the much more varied expression landscape between male and female gonad, compared to the shallow expression landscape of the brain, where very few genes show sex-specific expression differences. In bluehead wrasse gonad, tens of thousands of transcripts show significant sex-biased expression, while fewer than 10 transcripts are significantly differentially expressed between male and female forebrain (Liu et al 2015). Where expression landscapes are shallow and most meaningful expression differences are subtle, DE tests will have lower power and study designs will require more biological replicates.…”

Section: Complexities Of Rna-seq Power Analysismentioning

confidence: 99%

“…Unfortunately, often only a small proportion of DE contigs can be matched to known proteins [e.g. <20% in the bluehead wrasse (Liu et al 2015), 31% in Acropora coral (Meyer et al 2011)]. There will be many (e.g.…”

Section: Choice Of Mapping Reference Mattersmentioning

confidence: 99%

The power and promise of RNA‐seq in ecology and evolution

2016

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Reference is regularly made to the power of new genomic sequencing approaches. Using powerful technology, however, is not the same as having the necessary power to address a research question with statistical robustness. In the rush to adopt new and improved genomic research methods, limitations of technology and experimental design may be initially neglected. Here, we review these issues with regard to RNA sequencing (RNA-seq). RNA-seq adds large-scale transcriptomics to the toolkit of ecological and evolutionary biologists, enabling differential gene expression (DE) studies in nonmodel species without the need for prior genomic resources. High biological variance is typical of field-based gene expression studies and means that larger sample sizes are often needed to achieve the same degree of statistical power as clinical studies based on data from cell lines or inbred animal models. Sequencing costs have plummeted, yet RNA-seq studies still underutilize biological replication. Finite research budgets force a trade-off between sequencing effort and replication in RNAseq experimental design. However, clear guidelines for negotiating this trade-off, while taking into account study-specific factors affecting power, are currently lacking. Study designs that prioritize sequencing depth over replication fail to capitalize on the power of RNA-seq technology for DE inference. Significant recent research effort has gone into developing statistical frameworks and software tools for power analysis and sample size calculation in the context of RNA-seq DE analysis. We synthesize progress in this area and derive an accessible rule-of-thumb guide for designing powerful RNA-seq experiments relevant in eco-evolutionary and clinical settings alike.

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“…More surprisingly, no sex‐bias was observed in gonadal expression of foxl2 in protogynous three‐spot wrasses; indeed, foxl2 expression actually increased during aromatase inhibitor‐induced sex change (Kobayashi et al, ). In bluehead wrasses, foxl2 expression was much higher in ovaries than testes (Liu et al, ). The delayed pattern of expression of foxl2 during mid‐transition does not provide a strong case for Foxl2 initiating the sex change (Liu, ); elevated foxl2 expression may instead reflect a feedback response to E2 depletion (Liu et al, ; Guiguen et al, ) or may be stimulated by other factors, such as long non‐coding RNAs or microRNAs (Piferrer, ; Rosario et al, ; Boulanger et al, ).…”

Section: Regulatory Mechanisms Of Protogynous Sex Changementioning

confidence: 99%

Sexual plasticity: A fishy tale

Liu

Todd

Lokman

et al. 2016

Molecular Reproduction Devel

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121

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SUMMARYTeleost fish exhibit remarkably diverse and plastic patterns of sexual development. One of the most fascinating modes of plasticity is functional sex change, which is widespread in marine fish including species of commercial importance; however, the regulatory mechanisms remain elusive. In this review, we explore such sexual plasticity in fish, using the bluehead wrasse (Thalassoma bifasciatum) as the primary model. Synthesizing current knowledge, we propose that cortisol and key neurochemicals modulate gonadotropin releasing hormone and luteinizing hormone signaling to promote socially controlled sex change in protogynous fish. Future largescale genomic analyses and systematic comparisons among species, combined with manipulation studies, will likely uncover the common and unique pathways governing this astonishing transformation. Revealing the molecular and neuroendocrine mechanisms underlying sex change in fish will greatly enhance our understanding of vertebrate sex determination and differentiation as well as phenotypic plasticity in response to environmental influences.

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Large-scale transcriptome sequencing reveals novel expression patterns for key sex-related genes in a sex-changing fish

Cited by 92 publications

References 191 publications

Both Male-Biased and Female-Biased Genes Evolve Faster in Fish Genomes

Both Male-Biased and Female-Biased Genes Evolve Faster in Fish Genomes

The power and promise of RNA‐seq in ecology and evolution

Sexual plasticity: A fishy tale

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