The power and promise of <scp>RNA</scp>‐seq in ecology and evolution

Todd, Erica V.; Black, Michael A.; Gemmell, Neil J.

doi:10.1111/mec.13526

Cited by 196 publications

(185 citation statements)

References 67 publications

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“…Indeed, of the studies included here, nearly half did not include true biological replicates (at best, samples were pooled within groups to create a single library for RNA-seq), consistent with the dearth of replication observed in ecological and evolutionary studies in general (Todd et al 2016). St.…”

Section: Experimental Protocols and Sampling Designmentioning

confidence: 77%

“…The application of RNA-seq to study non-model systems is still in its infancy, and care must be taken not to overlook its limitations in the rush to adopt the technology (Costa et al 2013;Todd et al 2016). In this section, we describe some of the experimental, analytical, and conceptual challenges raised specifically by the body of work described herein and highlight some avenues of future exploratory and confirmatory analyses.…”

Section: Challenges and Directions For Future Researchmentioning

confidence: 99%

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Transcriptomic responses to environmental change in fishes: Insights from RNA sequencing

Oomen

Hutchings

2017

FACETS

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The need to better understand how plasticity and evolution affect organismal responses to environmental variability is paramount in the face of global climate change. The potential for using RNA sequencing (RNA-seq) to study complex responses by non-model organisms to the environment is evident in a rapidly growing body of literature. This is particularly true of fishes for which research has been motivated by their ecological importance, socioeconomic value, and increased use as model species for medical and genetic research. Here, we review studies that have used RNA-seq to study transcriptomic responses to continuous abiotic variables to which fishes have likely evolved a response and that are predicted to be affected by climate change (e.g., salinity, temperature, dissolved oxygen concentration, and pH). Field and laboratory experiments demonstrate the potential for individuals to respond plastically to short-and long-term environmental stress and reveal molecular mechanisms underlying developmental and transgenerational plasticity, as well as adaptation to different environmental regimes. We discuss experimental, analytical, and conceptual issues that have arisen from this work and suggest avenues for future study.

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Section: Experimental Protocols and Sampling Designmentioning

confidence: 77%

Section: Challenges and Directions For Future Researchmentioning

confidence: 99%

Transcriptomic responses to environmental change in fishes: Insights from RNA sequencing

Oomen

Hutchings

2017

FACETS

View full text Add to dashboard Cite

show abstract

“…In contrast, SNPs typically have lower power per locus relative to microsatellites, but hundreds to thousands of SNP loci can now be rapidly and reliably quantified across large numbers of individuals (Campbell et al, 2015;Ali et al, 2016;Andrews et al, 2016). Additionally, SNPs in coding regions can be used to understand genotype and phenotype linkages and identify loci under selection if adequate genomic and budget resources are available (Hoban et al, 2016;Todd et al, 2016).…”

Section: Expansion Of Molecular Markersmentioning

confidence: 99%

Advances in the Application of Genetics in Marine Turtle Biology and Conservation

et al. 2017

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Marine turtles migrate across long distances, exhibit complex life histories, and occupy habitats that are difficult to observe. These factors present substantial challenges to understanding fundamental aspects of their biology or assessing human impacts, many of which are important for the effective conservation of these threatened and endangered species. The early development and application of genetic tools made important contributions to understanding marine turtle population and evolutionary biology, such as providing evidence of regional natal homing by breeding adults, establishing connectivity between rookeries and foraging habitats, and determining phylogeography and broad scale stock structure for most marine turtle species. Recent innovations in molecular technologies, statistical methods, and creative application of genetic tools have significantly built upon this knowledge to address key questions in marine turtle biology and conservation management. Here, we evaluate the latest major advances and potential of marine turtle genetic applications, including improved resolution and large-scale syntheses of population structure, connectivity and phylogeography, estimation of key demographic rates such as age to maturity and operational or breeding sex ratios, insight into reproductive strategies and behavior, and assessment of differential human impacts among populations. We then discuss remaining challenges and emerging capabilities, such as rapid, multiplexed genotyping, and investigation of the genomic underpinnings of adaptive variation afforded by high-throughput sequencing technologies.

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“…Despite huge efort, de novo sequencing of an entire genome is not an easy task, even now, and this also makes 'RNA sequencing (hereafter, RNA-Seq)-based transcriptomic analysis' appealing for non-model organisms that are generally described as having no or limited genomic resources and transcriptomic datasets as well as molecular tools [3][4][5][6]. In the ield of '-omics' disciplines, RNA-Seq is among high-throughput experimental methods and widely used for identifying all functional elements in the genome.…”

Section: Introductionmentioning

confidence: 99%

Transcriptome Analysis for Non-Model Organism: Current Status and Best-Practices

Eldem¹,

Zararsız²,

Taşçi³

et al. 2017

Applications of RNA-Seq and Omics Strategies - From Microorganisms to Human Health

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Since transcriptome analysis provides genome-wide sequence and gene expression information, transcript reconstruction using RNA-Seq sequence reads has become popular during recent years. For non-model organism, as distinct from the reference genome-based mapping, sequence reads are processed via de novo transcriptome assembly approaches to produce large numbers of contigs corresponding to coding or non-coding, but expressed, part of genome. In spite of immense potential of RNA-Seq-based methods, particularly in recovering full-length transcripts and spliced isoforms from short-reads, the accurate results can be only obtained by the procedures to be taken in a step-by-step manner. In this chapter, we aim to provide an overview of the state-of-the-art methods including (i) quality check and pre-processing of raw reads, (ii) the pros and cons of de novo transcriptome assemblers, (iii) generating non-redundant transcript data, (iv) current quality assessment tools for de novo transcriptome assemblies, (v) approaches for transcript abundance and diferential expression estimations and inally (vi) further mining of transcriptomic data for particular biological questions. Our intention is to provide an overview and practical guidance for choosing the appropriate approaches to best meet the needs of researchers in this area and also outline the strategies to improve on-going projects.

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

Cited by 196 publications

References 67 publications

Transcriptomic responses to environmental change in fishes: Insights from RNA sequencing

Transcriptomic responses to environmental change in fishes: Insights from RNA sequencing

Advances in the Application of Genetics in Marine Turtle Biology and Conservation

Transcriptome Analysis for Non-Model Organism: Current Status and Best-Practices

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