Jong S. Leong

Salmo salar and Esox lucius full-length cDNA sequences reveal changes in evolutionary pressures on a post-tetraploidization genome

BackgroundSalmonids are one of the most intensely studied fish, in part due to their economic and environmental importance, and in part due to a recent whole genome duplication in the common ancestor of salmonids. This duplication greatly impacts species diversification, functional specialization, and adaptation. Extensive new genomic resources have recently become available for Atlantic salmon (Salmo salar), but documentation of allelic versus duplicate reference genes remains a major uncertainty in the complete characterization of its genome and its evolution.ResultsFrom existing expressed sequence tag (EST) resources and three new full-length cDNA libraries, 9,057 reference quality full-length gene insert clones were identified for Atlantic salmon. A further 1,365 reference full-length clones were annotated from 29,221 northern pike (Esox lucius) ESTs. Pairwise dN/dS comparisons within each of 408 sets of duplicated salmon genes using northern pike as a diploid out-group show asymmetric relaxation of selection on salmon duplicates.Conclusions9,057 full-length reference genes were characterized in S. salar and can be used to identify alleles and gene family members. Comparisons of duplicated genes show that while purifying selection is the predominant force acting on both duplicates, consistent with retention of functionality in both copies, some relaxation of pressure on gene duplicates can be identified. In addition, there is evidence that evolution has acted asymmetrically on paralogs, allowing one of the pair to diverge at a faster rate.

The Genome and Linkage Map of the Northern Pike (Esox lucius): Conserved Synteny Revealed between the Salmonid Sister Group and the Neoteleostei

The northern pike is the most frequently studied member of the Esociformes, the closest order to the diverse and economically important Salmoniformes. The ancestor of all salmonids purportedly experienced a whole-genome duplication (WGD) event, making salmonid species ideal for studying the early impacts of genome duplication while complicating their use in wider analyses of teleost evolution. Studies suggest that the Esociformes diverged from the salmonid lineage prior to the WGD, supporting the use of northern pike as a pre-duplication outgroup. Here we present the first genome assembly, reference transcriptome and linkage map for northern pike, and evaluate the suitability of this species to provide a representative pre-duplication genome for future studies of salmonid and teleost evolution. The northern pike genome sequence is composed of 94,267 contigs (N50 = 16,909 bp) contained in 5,688 scaffolds (N50 = 700,535 bp); the total scaffolded genome size is 878 million bases. Multiple lines of evidence suggest that over 96% of the protein-coding genome is present in the genome assembly. The reference transcriptome was constructed from 13 tissues and contains 38,696 transcripts, which are accompanied by normalized expression data in all tissues. Gene-prediction analysis produced a total of 19,601 northern pike-specific gene models. The first-generation linkage map identifies 25 linkage groups, in agreement with northern pikes diploid karyotype of 2N = 50, and facilitates the placement of 46% of assembled bases onto linkage groups. Analyses reveal a high degree of conserved synteny between northern pike and other model teleost genomes. While conservation of gene order is limited to smaller syntenic blocks, the wider conservation of genome organization implies the northern pike exhibits a suitable approximation of a non-duplicated Protacanthopterygiian genome. This dataset will facilitate future studies of esocid biology and empower ongoing examinations of the Atlantic salmon and rainbow trout genomes by facilitating their comparison with other major teleost groups.

Genomics of sablefish (Anoplopoma fimbria): expressed genes, mitochondrial phylogeny, linkage map and identification of a putative sex gene

BackgroundThe sablefish (order: Scorpaeniformes) is an economically important species in commercial fisheries of the North Pacific and an emerging species in aquaculture. Aside from a handful of sequences in NCBI and a few published microsatellite markers, little is known about the genetics of this species. The development of genetic tools, including polymorphic markers and a linkage map will allow for the successful development of future broodstock and mapping of phenotypes of interest. The significant sexual dimorphism between females and males makes a genetic test for early identification of sex desirable.ResultsA full mitochondrial genome is presented and the resulting phylogenetic analysis verifies the placement of the sablefish within the Scorpaeniformes. Nearly 35,000 assembled transcript sequences are used to identify genes and obtain polymorphic SNP and microsatellite markers. 360 transcribed polymorphic loci from two sablefish families produce a map of 24 linkage groups. The sex phenotype maps to sablefish LG14 of the male map. We show significant conserved synteny and conservation of gene-order between the threespine stickleback Gasterosteus aculeatus and sablefish. An additional 1843 polymorphic SNP markers are identified through next-generation sequencing techniques. Sex-specific markers and sequence insertions are identified immediately upstream of the gene gonadal-soma derived factor (gsdf), the master sex determinant locus in the medaka species Oryzias luzonensis.ConclusionsThe first genomic resources for sablefish provide a foundation for further studies. Over 35,000 transcripts are presented, and the genetic map represents, as far as we can determine, the first linkage map for a member of the Scorpaeniformes. The observed level of conserved synteny and comparative mapping will allow the use of the stickleback genome in future genetic studies on sablefish and other related fish, particularly as a guide to whole-genome assembly. The identification of sex-specific insertions immediately upstream of a known master sex determinant implicates gsdf as an excellent candidate for the master sex determinant for sablefish.

Transcriptional responses in a Drosophila defensive symbiosis

Inherited symbionts are ubiquitous in insects and can have important consequences for the fitness of their hosts. Many inherited symbionts defend their hosts against parasites or other natural enemies; however, the means by which most symbionts confer protection is virtually unknown. We examine the mechanisms of defence in a recently discovered case of symbiont‐mediated protection, where the bacterial symbiont Spiroplasma defends the fly Drosophila neotestacea from a virulent nematode parasite, Howardula aoronymphium. Using quantitative PCR of Spiroplasma infection intensities and whole transcriptome sequencing, we attempt to distinguish between the following modes of defence: symbiont–parasite competition, host immune priming and the production of toxic factors by Spiroplasma. Our findings do not support a model of exploitative competition between Howardula and Spiroplasma to mediate defence, nor do we find strong support for host immune priming during Spiroplasma infection. Interestingly, we recovered sequence for putative toxins encoded by Spiroplasma, including a novel putative ribosome‐inactivating protein, transcripts of which are up‐regulated in response to nematode exposure. Protection via the production of toxins may be a widely used and important mechanism in heritable defensive symbioses in insects.

Sex-specific expression, synthesis and localization of aromatase regulators in one-year-old Atlantic salmon ovaries and testes

Transcripts for dax1, foxl2, mis and sf1 are co-expressed in the somatic companion cells of teleost germ cells. These regulatory factors function, in part, to modulate the transcription of aromatase, particularly cyp19a, the terminal enzyme of estrogen biosynthesis. At least two separate aromatase loci exist in teleost fish that encode distinct isoforms. The activity of two forms, cyp19a and cyp19b1, is predominantly associated with the ovary and the brain, respectively. We isolated sequences that compose the proximal promoters of cyp19a, cyp19b1 and foxl2a, to identify potential transcription factor binding motifs to define sex-specific regulatory profiles for each gene. We also provide evidence for the translation and immunological localization of DAX-1, FOXL2 and MIS to the endoplasmic reticulum and accumulation within secretory vesicles of the salmon oocyte. We found no evidence for the expression of CYP19A or CYP19B1 in the oocyte at the one-year-old stage. However, synthesis of both aromatases was localized to testicular germ and soma cells at this early stage of development. Production of these regulatory factors in the germ cells may serve to modulate the transcription and activity of endogenous aromatase and/or contribute to the differentiation of the neighbouring companion cells through secretory signaling.

Multi-tissue transcriptome profiles for coho salmon (Oncorhynchus kisutch), a species undergoing rediploidization following whole-genome duplication.

Salmonids are an important family of fish both from economic and basic research perspectives, and have been subjected to extensive research at whole-animal and molecular levels. Most research to date has been conducted on Atlantic salmon (Salmo salar) and rainbow trout (Oncorhynchus mykiss), but more recently other salmonids have become a focus of study due to their interesting life histories and because of their potential for use in commercial aquaculture. However, molecular biology and genetic analyses for these emerging species are currently hampered due to the lack of extensive genomic resources. To overcome some of these limitations, we have constructed a 43,228 sequence transcriptome from 13 tissues from coho salmon, Oncorhynchus kisutch using de novo transcriptome assembly methods. The transcriptome profiling analysis has provided data distinguishing allelic variation from paralogues that arose during the recent whole-genome duplication event in this family, thus allowing simplified analysis of gene-specific expression. Additionally, 1599 novel coho sequences have been identified through comparison with transcriptomes from two other salmonids species (Atlantic salmon and rainbow trout), and with northern pike. The transcriptome presented here will be useful for genomic analysis of coho salmon and other closely related salmonid species.

Parallel epigenetic modifications induced by hatchery rearing in a Pacific Salmon

Significance Captive rearing is known to impact the fitness of individuals released in the wild, but the relative role of genetic vs. nongenetic underlying processes is still debated. We measured genome-wide methylation profiles to document epigenetic differences between Pacific salmon originating from a hatchery and their natural-born congeners in two geographically distant rivers. Our results provide evidence that the epigenetic modifications induced by hatchery rearing provide a potential explanatory mechanism for reduced fitness of hatchery-reared salmon once released in the wild. Wild stocks of Pacific salmonids have experienced sharp declines in abundance over the past century. Consequently, billions of fish are released each year for enhancing abundance and sustaining fisheries. However, the beneficial role of this widely used management practice is highly debated since fitness decrease of hatchery-origin fish in the wild has been documented. Artificial selection in hatcheries has often been invoked as the most likely explanation for reduced fitness, and most studies to date have focused on finding signatures of hatchery-induced selection at the DNA level. We tested an alternative hypothesis, that captive rearing induces epigenetic reprogramming, by comparing genome-wide patterns of methylation and variation at the DNA level in hatchery-reared coho salmon (Oncorhynchus kisutch) with those of their wild counterparts in two geographically distant rivers. We found a highly significant proportion of epigenetic variation explained by the rearing environment that was as high as the one explained by the river of origin. The differentially methylated regions show enrichment for biological functions that may affect the capacity of hatchery-born smolts to migrate successfully in the ocean. Shared epigenetic variation between hatchery-reared salmon provides evidence for parallel epigenetic modifications induced by hatchery rearing in the absence of genetic differentiation between hatchery and natural-origin fish for each river. This study highlights epigenetic modifications induced by captive rearing as a potential explanatory mechanism for reduced fitness in hatchery-reared salmon.

Microsatellite loci for genetic analysis of the arctic gadids Boreogadus saida and Arctogadus glacialis

We report sets of 19 and 16 microsatellite loci for the examination of the population genetics of Boreogadus saida and Arctogadus glacialis, respectively. Six of these loci were developed from a collection of 9,497 expressed sequences from B. saida while the remaining loci were found in the literature and optimized for use in B. saida and A. glacialis. The numbers of alleles observed for each locus ranged from 3 to 33 in B. saida and 1–22 in A. glacialis. Observed heterozygosities ranged from 0.02 to 0.93 in B. saida and 0.17–1.0 in A. glacialis. Species specific differences were observed for the loci providing new tools for the identification of these two morphologically similar arctic gadids. The loci presented here can be used to distinguish between the two species and fill fundamental biological knowledge gaps, thus promoting conservation of these important fishes.

Chinook salmon (Oncorhynchus tshawytscha) genome and transcriptome.

When unifying genomic resources among studies and comparing data between species, there is often no better resource than a genome sequence. Having a reference genome for the Chinook salmon (Oncorhynchus tshawytscha) will enable the extensive genomic resources available for Pacific salmon, Atlantic salmon, and rainbow trout to be leveraged when asking questions related to the Chinook salmon. The Chinook salmon’s wide distribution, long cultural impact, evolutionary history, substantial hatchery production, and recent wild-population decline make it an important research species. In this study, we sequenced and assembled the genome of a Chilliwack River Hatchery female Chinook salmon (gynogenetic and homozygous at all loci). With a reference genome sequence, new questions can be asked about the nature of this species, and its role in a rapidly changing world.

Subcellular localization and characterization of estrogenic pathway regulators and mediators in Atlantic salmon spermatozoal cells

Much progress has been made regarding our understanding of aromatase regulation, estrogen synthesis partitioning and communication between the germinal and somatic compartments of the differentiating gonad. We now know that most of the enzymatic and signaling apparatus required for steroidogenesis is endogenously expressed within germ cells. However, less is known about the expression and localization of steroidogenic components within mature spermatozoa. We have assembled a sperm library presenting 197,015 putative transcripts. Co-expression clustering analysis revealed that 6687 genes were present at higher levels in sperm in comparison to fifteen other salmon tissue libraries. The sperm transcriptome is highly complex containing the highest proportion of unannotated genes (45%) of the tissues analyzed. Our analysis of highly expressed genes in late-stage sperm revealed dedication to tasks involving chromatin remodeling, flagellogenesis and proteolysis. In addition, using various different embedding and microscopic techniques, we examined the morphology of salmon spermatozoa and characterized expression and localization of several estrogenic regulatory and signaling proteins by immunohistochemistry. We provide evidence for the endogenous synthesis and localization of aromatase (CYP19A and CYP19B1) and potential mediators of estrogen [i.e., ER-alpha and soluble adenylyl cyclase (sAC)] or phosphate (i.e., CREB and FOXL2A) signaling. Partitioning of select transcripts that encode AR-beta, FSH and the LH receptor, but not AR-alpha, LH or the FSH receptor, further points to localized specificity of function in the steroidogenic circuitry of the sperm cell. These results open new avenues of investigation to further our understanding of the intra- and intercellular regulatory processes that guide sperm development and biology.