Sangdeok Chung’s research while affiliated with National Fisheries Research and Development Institution and other places

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Publications (16)


of the final genome assembly results. (a) Contact map plot of the Patagonian toothfish genome. The Hi-C raw read pairs were aligned with the genome sequences; the x and y axes indicate their positions; the red dots indicate the position of the read pairs, and a high density of red dots denotes that they are located on the same chromosome. (b) Overview of the Patagonian toothfish genome. The features are arranged in chromosomes [a], gene density [b], DNA element density [c], LINE density [d], SINE density [e], GC contents [f], and GC skew [g] at 1-Mbp intervals across the 24 chromosomes. (c) Phylogenetic analysis with 17 species, including D. eleginoides. The number of expanded (red) and contracted (blue) gene families are indicated at each node and end, and the length of each node is indicated in million years old (MYA). Species of the Notothenioidei suborder, comprising Antarctic, sub-Antarctic, and non-Antarctic species, were binned into color zones. A divergence time of the Patagonian toothfish was indicated red dot and label.
(a) Genomic comparative between D.eleginoides and D. mawsoni. The regions of high similarity between the genomic segments in D.eleginoides and B are plotted as color-coded lines for each chromosome. D.eleginoides chromosomes are located at the top and D. mawsoni chromosomes at the bottom. (b) The region of AFGP genes family. Gene locations within the AFGP gene family region of two haplotypes of D. mawsoni and D.eleginoides were compared. Color-coded according to gene type, and the orientation of the arrow reflected the orientation of the gene. The position of each gene on the genome was shown on the same scale. Trypsinogen and AFGP gene regions were color-coded.
Summary of chromosome sequences of the final assembly.
Summary of functional annotations of the Patagonian toothfish genome.
Chromosome-level genome assembly and annotation of the Patagonian toothfish Dissostichus eleginoides
  • Article
  • Full-text available

November 2024

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13 Reads

Scientific Data

Seung Jae Lee

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[...]

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The Patagonian toothfish (Dissostichus eleginoides) belongs to the Actinopterygii class, and the suborder Notothenioidei, which lives in cold waters in the Southern Hemisphere. We performed assembly and annotation, and we integrated the Illumina short-read sequencing for polishinng, PacBio long-read sequencing for contig-level assembly, and Hi-C sequencing technology to obtain high-quality of chromosome-level genome assembly. The final assembly analysis resulted in a total of 495 scaffolds, a genome size of 844.7 Mbp and an N50 length of 36 Mbp. Among these data, we confirmed 24 scaffolds exceeded 10 Mbp and classified as chromosome-level. The completeness of BUSCO rate was over 97%. A total gene set of 32,224 was identified. Furthermore, we analyzed the presence of AFGP genes, classified into Antarctic and sub-Antarctic categories through phylogenetic analysis. This study provides a useful resource for the genomic analysis of Patagonian toothfish and genetic insights into the comparison with Antarctic fishes.

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Endemic Radiation of African Moonfish, Selene dorsalis (Gill 1863), in the Eastern Atlantic: Mitogenomic Characterization and Phylogenetic Implications of Carangids (Teleostei: Carangiformes)

September 2024

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197 Reads

Biomolecules

This study offers an in-depth analysis of the mitochondrial genome of Selene dorsalis (Gill 1863), a species native to the Eastern Atlantic Ocean. The circular mitochondrial DNA molecule measures 16,541 base pairs and comprises 13 protein-coding genes (PCGs), 22 transfer RNA (tRNA) genes, two ribosomal RNA genes, and a control region (CR). The nucleotide composition exhibits a notable adenine-thymine (AT) bias, accounting for 53.13%, which aligns with other species in the Carangidae family. Most PCGs initiate with the ATG codon, with the exception of Cytochrome C oxidase subunit I, which starts with GTG. Analysis of relative synonymous codon usage reveals that leucine and serine are the most prevalent amino acids in the mitochondrial genome of S. dorsalis and its congeners (S. vomer and S. setapinnis). All tRNAs display the typical cloverleaf structure, though tRNA Serine (S1) lacks a dihydrouracil arm. Pairwise comparisons of synonymous and nonsynonymous substitutions for all PCGs yielded values below ‘1’, indicating strong purifying selection. The CR spans 847 bp, representing 5.12% of the mitochondrial genome, and is characterized by high AT content (62.81%). It is situated between tRNA-Pro (TGG) and tRNA-Phe (GAA). The CR contains conserved sequence blocks, with CSB-1 being the longest at 22 bp and CSB-D the shortest at 18 bp. Phylogenetic analysis, using Bayesian and Maximum-likelihood trees constructed from concatenated PCGs across 72 species, successfully differentiates S. dorsalis from other carangids. This study also explores how ocean currents and gyres might influence lineage diversification and parapatric speciation of Selene species between the Atlantic and Pacific Oceans. These results highlight the importance of the mitochondrial genome in elucidating the structural organization and evolutionary dynamics of S. dorsalis and its relatives within marine ecosystems.


Integrative Taxonomy Clarifies the Historical Flaws in the Systematics and Distributions of Two Osteobrama Fishes (Cypriniformes: Cyprinidae) in India

February 2024

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137 Reads

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2 Citations

Fishes

The taxonomy and geographical distributions of Osteobrama species have historically posed challenges to ichthyologists, leading to uncertainties regarding their native ranges. While traditional taxonomy has proven valuable in classification, the utility of an integrated approach is restricted for this particular group due to limitations in combining information from biogeography, morphology, and genetic data. This study addresses the taxonomic puzzle arising from the recent identification of Osteobrama tikarpadaensis in the Mahanadi and Godavari Rivers, casting doubt on the actual distribution and systematics of both O. tikarpadaensis and Osteobrama vigorsii. The research reveals distinctions among specimens resembling O. vigorsii from the Krishna and Godavari riverine systems. Notably, specimens identified as O. vigorsii from the Indian Museum exhibit two pairs of barbels, while those from the Godavari River in this study are identified as O. tikarpadaensis. Inter-species genetic divergence and maximum likelihood phylogeny provide clear delineation between O. vigorsii and O. tikarpadaensis. The study suggests that O. vigorsii may be limited to the Krishna River system in southern India, while O. tikarpadaensis could potentially extend from the Mahanadi River in central India to the Godavari River in southern India. Proposed revision to morphological features for both species, accompanied by revised taxonomic keys, aim to facilitate accurate differentiation among Osteobrama congeners. The data generated by this research provide a resource for future systematic investigations into cyprinids in India and surrounding regions. Further, the genetic diversity information obtained from various riverine systems for Osteobrama species will be instrumental in guiding aquaculture practices and formulating effective conservation action plans.


Chromosome-level genome assembly of Pogonophryne albipinna. (a) Hi-C interaction heat map for P. albipinna. The blue boxes represent the chromosomes. (b) Collinear relationship between P. albipinna and Gasterosteus aculeatus. Connections within the circle represent alignments between the two assemblies.
Kimura distance-based copy divergence analysis of transposable elements in teleost genomes. The graphs depict genome coverage (Y-axis) for each type of TE in the Pogonophryne albipinna genome.
Gene ontology (GO) annotations of the predicted genes in the Pogonophryne albipinna genome. The horizontal axis indicates the number of genes in each class, while the vertical axis indicates the classes in the 2-level GO-annotation.
Gene family comparison. (a) Orthologous gene families between Pogonophryne albipinna and other fish species. (b) Venn diagram showing orthologous gene families among P. albipinna and five other Antarctic fish species.
Phylogenetic analysis of Pogonophryne albipinna within the teleost lineage and analysis of gene family gains and losses, including the number of gained gene families (+) and lost gene families (−). Each branch site number indicates divergence times between lineages.
Chromosome-level genome assembly and annotation of the Antarctica whitefin plunderfish Pogonophryne albipinna

December 2023

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111 Reads

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1 Citation

Scientific Data

The Antarctic whitefin plunderfish Pogonophryne albipinna belongs to the family Artedidraconidae, a key component of Antarctic benthic ecosystems within the order Perciformes and the suborder Notothenioidei. While genome research on P. albipinna using short-read sequencing is available, high-quality genome assembly and annotation employing long-read sequencing have yet to be performed. This study presents a chromosome-scale genome assembly and annotation for P. albipinna, utilizing a combination of Illumina short-read, PacBio long-read, and Hi-C sequencing technologies. The resulting genome assembly spans approximately 1.07 Gb, with a longest scaffold measuring 59.39 Mb and an N50 length of 41.76 Mb. Of the 1,111 Hi-C scaffolds, 23 exceeded 10 Mb and were thus classified as chromosome-level. BUSCO completeness was assessed at 95.6%. The assembled genome comprises 50.68% repeat sequences, and a total of 31,128 protein-coding genes were predicted. This study will enhance our understanding of the genomic characteristics of cryonotothenioids and facilitate comparative analyses of their adaptation and evolution in extreme environments.


Feeding ecology of Antarctic toothfish, Dissostichus mawsoni in the subarea 88.3 (Bellingshausen Sea and eastern Amundsen Sea) of the Southern Ocean

December 2023

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76 Reads

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1 Citation

Understanding feeding ecology is essential for ecosystem-based management. As dietary data can show differences depending on the spatiotemporal and ontogenetic aspects of the sample, the results should be derived based on various size classes and samples over a wide spatiotemporal range. Morphological analysis of the stomach contents of Dissostichus mawsoni, a piscivore, collected at depths of 603–2,113 m in subarea 88.3 during the Antarctic summer fishing seasons from 2016 to 2020 was used to assess the dietary composition according to the research block, fishing season, depth, and size. Here, we used 1,639 D. mawsoni specimens with a total length range of 44.5–189.0 cm. The dietary composition of D. mawsoni did not show significant differences by fishing season but differed with research block, depth, and size. Macrouridae dominated research blocks 88.3_1 and 88.3_3; Nototheniidae dominated research blocks 88.3_2 and 88.3_6; and Channichthyidae dominated research blocks 88.3_4 and 88.3_5. The proportion of Nototheniidae decreased as depth increased, whereas the consumption of Channichthyidae increased gradually with depth in research blocks 88.3_3 and 88.3_4. The proportion of Channichthyidae decreased as body size increased, whereas the consumption of Macrouridae increased gradually with body size in both blocks 88.3_3 and 88.3_4. During the study period, the dietary composition of D. mawsoni in both blocks 88.3_3 and 88.3_4 did not show significant temporal differences, suggesting that these data could be used as a baseline for identifying future environmental changes in the region. This study provides information on the relationships between various species and benthic fish fauna, which are essential for ecosystem-based management.


Mitogenomic Architecture and Phylogenetic Relationship of European Barracuda, Sphyraena sphyraena (Teleostei: Sphyraenidae) from the Atlantic Ocean

November 2023

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136 Reads

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4 Citations

Fishes

The collective understanding of global-scale evolutionary trends in barracuda mitogenomes is presently limited. This ongoing research delves into the maternal evolutionary path of Sphyraena species, with a specific focus on the complete mitogenome of Sphyraena sphyraena, sourced from the Atlantic Ocean through advanced next-generation sequencing. This mitogenome spans 16,841 base pairs and encompasses 37 genes, including 13 protein-coding genes (PCGs), 2 ribosomal RNA genes (rRNAs), 22 transfer RNA genes (tRNAs), and an AT-rich control region. Notably, the mitogenome of S. sphyraena exhibits a preference for AT-base pairs, constituting 55.06% of the composition, a trait consistent with a similar bias found in related species. Most protein-coding genes initiate with an ATG codon, with the exception of Cytochrome c oxidase I (COI), which begins with a GTG codon. Additionally, six PCGs terminate with a TAA codon, COI with AGA, while six others exhibit incomplete termination codons. In the S. sphyraena mitogenome, the majority of transfer RNAs exhibit typical cloverleaf secondary structures, except for tRNA-serine, which lacks a DHU stem. Comparative analysis of conserved blocks within the D-loop regions of six Sphyraenidae species reveals that the CSB-I block extends to 22 base pairs, surpassing other blocks and containing highly variable sites. Both maximum-likelihood and Bayesian phylogenetic analyses, using concatenated 13 mitochondrial PCGs, distinctly separate all Sphyraenidae species. The European Barracuda, S. sphyraena, demonstrates a sister relationship with the ‘Sphyraena barracuda’ group, including S. barracuda and S. jello. In conclusion, this study advances our understanding of the evolutionary relationship and genetic diversity within barracudas. Furthermore, it recommends comprehensive exploration of mitogenomes and broader genomic data for all existing Sphyraenidae fishes, providing invaluable insights into their systematics, genetic characterization, and maternal evolutionary history within marine environments.


Geographical differences in the diet of Dissostichus mawsoni revealed by metabarcoding

August 2022

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233 Reads

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4 Citations

The diet of the Antarctic toothfish (Dissostichus mawsoni) was analyzed using metabarcoding to determine whether spatiotemporal factors are related to its feeding ecology. A diet metabarcoding analysis was conducted for five years from 2016 to 2020 using 1,777 samples collected from two distantly located subareas, 88.3 and 58.4.1. Metabarcoding results revealed 105 prey haplotypes (29 families, 45 genera) in the stomach contents of D. mawsoni, which can serve as valuable genetic information for the accurate identification of piscine species inhabiting the Southern Ocean. Most of the stomach contents of D. mawsoni consisted of fish taxa, comprising 99.61% of read count, which is consistent with other studies indicating that D. mawsoni is piscivorous. The prey compositions were highly different between the two subareas (88.3 and 58.4.1) regardless of the year, indicating that the diet of D. mawsoni strongly reflects the fish assemblages in geographically different habitats. These results strongly suggest that the stomach contents are good ecological indicators for monitoring any changes in the marine ecosystem caused by either the fishery of D. mawsoni, the most voracious piscine predator in its habitat, or environmental changes. In addition, quantitative polymerase chain reaction results of the two most abundant Macrourus prey species of Antarctic toothfish, M. caml and M. whitsoni, showed that the distribution of these two species may be related to the dynamics of gyres, which flow along the Antarctic continent.


Standing stock of Antarctic krill (Euphausia superba Dana, 1850) (Euphausiacea) in the Southwest Atlantic sector of the Southern Ocean, 2018-19

October 2021

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393 Reads

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32 Citations

Journal of Crustacean Biology

Estimates of the distribution and density of Antarctic krill (Euphausia superba Dana, 1850) were derived from a large-scale survey conducted during the austral summer in the Southwest Atlantic sector of the Southern Ocean and across the Scotia Sea in 2018–19, the ‘2018–19 Area 48 Survey’. Survey vessels were provided by Norway, the Association of Responsible Krill harvesting companies and Aker BioMarine AS, the United Kingdom, Ukraine, Republic of Korea, and China. Survey design followed the transects of the Commission for the Conservation of Antarctic Marine Living Resources synoptic survey, carried out in 2000 and from regular national surveys performed in the South Atlantic sector by the U.S., China, Republic of Korea, Norway, and the U.K. The 2018–19 Area 48 Survey represents only the second large-scale survey performed in the area and this joint effort resulted in the largest ever total transect line (19,500 km) coverage carried out as one single exercise in the Southern Ocean. We delineated and integrated acoustic backscatter arising from krill swarms to produce distribution maps of krill areal biomass density and standing stock (biomass) estimates. Krill standing stock for the Area 48 was estimated to be 62.6 megatonnes (mean density of 30 g m–2 over 2 million km2) with a sampling coefficient variation of 13%. The highest mean krill densities were found in the South Orkney Islands stratum (93.2 g m–2) and the lowest in the South Georgia Island stratum (6.4 g m–2). The krill densities across the strata compared to those found during the previous survey indicate some regional differences in distribution and biomass. It is currently not possible to assign any such differences or lack of differences between the two survey datasets to longer term trends in the environment, krill stocks or fishing pressure.


Genetic Diversity and Population Structure of the Antarctic Toothfish, Dissostichus mawsoni, Using Mitochondrial and Microsatellite DNA Markers

August 2021

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390 Reads

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5 Citations

The Antarctic toothfish, Dissostichus mawsoni, serves as a valuable fishery resource around the Antarctic Continent since 1997, managed by the Commission for the Conservation of Antarctic Marine Living Resources (CCAMLR). Although delineating genetic or stock structure of populations is crucial for improving fishery management of this species, its number of genetic populations and genetic diversity levels remain ambiguous. In the present study, we assessed the population genetic and phylogeographic structure of the Antarctic toothfish across 20 geographic localities spanning from Subareas 88 (88.1, 88.2, and 88.3) to Subareas 58 (58.4 and 58.5) by using mitochondrial DNA (mtDNA) cytochrome oxidase I (COI) and 16S rRNA (16S) sequences and seven nuclear microsatellite loci. MtDNA revealed a low level of polymorphism (h = 0.571, π = 0.0006) with 40 haplotypes in 392 individuals, connected only by 1–5 mutational steps, which is indicative of shallow evolutionary history. Microsatellites showed a range of allelic richness (AR) from 6.328 (88.3 RB3) to 7.274 (88.3 RB6) within populations. Overall genetic diversity was generally higher in Subareas 58 than in Subareas 88, suggesting that effective population size (NE) is larger in Subareas 58. The results of population analyses using microsatellites suggest that the sampled populations are likely to comprise a well-admixed single gene pool (i.e., one genetic stock), perhaps due to high contemporary gene flow occurring during the prolonged larval phase of this fish. However, given weak, but significant microsatellite differentiation found in six population-pairs, the possibility of existence of multiple genetic populations could not be completely excluded. The mtDNA AMOVA suggests a genetic break between the Subareas 88 and 58 groups (FCT = 0.011, P = 0.004). Moreover, mtDNA genetic distances (FST) between populations were proportionally greater as geographic distances increase. The patterns of isolation by distance (IBD) shown only in mtDNA, but not in microsatellites might suggest that population differentiation or divergence processes underwent faster in mtDNA than microsatellites, due to its NE being only one-quarter of nuclear DNA. Temporal stability in the genetic structure of D. mawsoni is also indicated by the results of no genetic differentiation between juveniles and adults. The findings of this study will help to design effective stock management strategies for this valuable fishery resource. We suggest that a long-term genetic monitoring is needed to understand the population structure and dynamics of toothfish in response to ongoing climate changes.


Morphological dietary composition of Antarctic toothfish (Dissostichus mawsoni) along the East Antarctic continental slope

March 2021

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156 Reads

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7 Citations

Polar Biology

To predict how the fishing of Antarctic toothfish, Dissostichus mawsoni, would affect the ecosystem, it is necessary to understand the species’ ecological niche. Morphological analysis of the stomach contents of 960 D. mawsoni specimens collected at depths of 946–1600 m along the East Antarctic continental slope from December 2016 to March 2017 was used to assess dietary composition according to depth, sex, site, and size. Fishes were the most common prey item for D. mawsoni, comprising 97.8% based on the index of relative importance. Among the nine fish families consumed by D. mawsoni, Macrouridae was the dominant taxon. The size of D. mawsoni increased with depth. The dietary composition of D. mawsoni did not show significant differences by depth or sex, but did differ with site and size. D. mawsoni was the top predator in the ecosystem along the East Antarctic continental slope and can be considered an opportunistic feeder, feeding on abundant food in the environment. Therefore, additional studies of the diet of Antarctic toothfish are necessary to maintain the ecosystem structure and function in a changing environment, and the results of this study can be used as a monitoring baseline.


Citations (13)


... Laskar et al. [49] examined morphology, genetics, and ranges of Osteobrama vigorsii and O. tikarpadaensis. Their paper helped resolve a long-term quandary regarding unusual distributions of Osteobrama species in India that should improve fish conservation efforts. ...

Reference:

Vadas, R.L. Jr., and R.M. Hughes, eds. 2024. Monitoring and Conservation of Freshwater and Marine Fishes: Synopsis and Special Issue. Fishes [online] 9(12): 470 (https://www.mdpi.com/journal/fishes/special_issues/1N7J6D5S01).
Integrative Taxonomy Clarifies the Historical Flaws in the Systematics and Distributions of Two Osteobrama Fishes (Cypriniformes: Cyprinidae) in India

Fishes

... This raises the question of how such a small percentage would be able to sustain a population if this is the primary recruitment pathway or if further settlement regions exist further east. The Bellingshausen Shelf and Antarctic Peninsula are known Antarctic toothfish habitats 39 with small (< 50 cm) toothfish caught in these regions 40 and Antarctic toothfish genetics have shown a strong spatial connectivity 41 . ...

Feeding ecology of Antarctic toothfish, Dissostichus mawsoni in the subarea 88.3 (Bellingshausen Sea and eastern Amundsen Sea) of the Southern Ocean

... 22 for ab initio prediction, which was subsequently analyzed with RepeatMasker. Additionally, the Tandem Repeats Finder v4.09 (TRF) 23 program was applied to identify tandem repeats in the genome. In total, 111.47 Mb repeat sequences (24.25% of the assembled genome) were identified. ...

Chromosome-level genome assembly and annotation of the Antarctica whitefin plunderfish Pogonophryne albipinna

Scientific Data

... Despite the differences in gene intergenic, the mitochondrial genome of two Pomadasys species comprises 37 genes, with 28 genes located on the heavy strand and nine on the light strand, which is consistent with other teleost mitogenomes (Miya et al. 2005;Kundu et al. 2023a). Since mitochondrial genomes are generally conserved, gene arrangement is the key area of study in organismal systematics (Gong et al. 2020;Zhang et al. 2020). ...

Mitogenomic Architecture and Phylogenetic Relationship of European Barracuda, Sphyraena sphyraena (Teleostei: Sphyraenidae) from the Atlantic Ocean

Fishes

... Similarly, Queiroś et al. (2022) reported differences in diet composition by region via morphological and isotopic analyses of D. mawsoni collected from the Amundsen Sea and Dumont D'Urville Sea. Yoon et al. (2017) and Lee et al. (2022) used metabarcoding to compare the diets of D. mawsoni collected in subareas 88.3 and 58.4 and identified various prey species that could not be accurately classified morphologically post-digestion. However, these authors could not analyze specific dietary ecology based on factors such as water depth and size class. ...

Geographical differences in the diet of Dissostichus mawsoni revealed by metabarcoding

... However, the availability of krill on a large scale is also crucial during penguins' winter migrations, before and after the breeding season, when they tend to migrate long distances during winter from their breeding grounds, up to 1000 km for Adélie penguins from the South Orkney Islands 14 , and up to 4782 km for chinstrap penguins from Livingston Island 15 . Krafft et al. 16 estimated that the total krill biomass in subarea 48 was 62.9 megatonnes in 2018-2019 and that, compared with that found in the historical CCAMLR 2000 survey, the krill biomass in the South Shetland region was two times lower (2000 survey -6.615.000 t., 2018-19 survey -3.325.000 ...

Standing stock of Antarctic krill (Euphausia superba Dana, 1850) (Euphausiacea) in the Southwest Atlantic sector of the Southern Ocean, 2018-19

Journal of Crustacean Biology

... Stability in the genetic structure of populations throughout the age cohorts (juveniles and adults) has been related to a sufficiently large effective population size, which prevents genetic drift over generations, e.g., that detected with microsatellites and mtDNA in wild populations of the Antarctic toothfish, Dissostichus mawsoni [267]. Based on microsatellite detection, the following have been reported for some other species: the long-term stability of the genetic diversity of the declined population of the Japanese eel, Anguilla japonica, in the north of Taiwan from 1986 to 2007 [268], the temporal stability over the last 45 years of a pike, Esox lucius L., stocked population in Stege Nor, Denmark [269], the stability of Atlantic herring, C. harengus, in the Baltic Sea and Skagerrak waters over a 24-year period [28], in the Gulf of St. Lawrence in Canada over a 80-year period despite intensive fishing [270], and in wild Australian populations of barramundi, Lates calcarifer, over 25 years [271], the genetic composition of cod, G. morhua, in the Western Bank over a few years [272], and gilthead sea bream, Sparus aurata, in wild samples from the Aegean and Ionian Seas [273]. ...

Genetic Diversity and Population Structure of the Antarctic Toothfish, Dissostichus mawsoni, Using Mitochondrial and Microsatellite DNA Markers

... Among this group, Dissostichus mawsoni commonly known as Antarctic toothfish (hereafter TOA) is a species with a circumpolar distribution south of 60˚S latitude, inhabiting cold waters (with temperaturas below 0˚C) at depths up to 3000 meters along the shelf and continental slope [4][5][6]. Individuals can exceed 2 m in length and 100 kg in weight [7,8], lasting over 30 years, with a first sexual maturation between 12 and 16 years of age [5,9]. The TOA is by far the largest fish species, playing a key ecological role in the trophic web, both as a food source for marine mammals such as cetaceans [10] and seals [11], and as a top predator in deep-sea ecosystems, structuring the size and population dynamics of prey species through predation [8,12]. ...

Morphological dietary composition of Antarctic toothfish (Dissostichus mawsoni) along the East Antarctic continental slope

Polar Biology

... Finally, the SMRTbell library was sequenced using nine Sequel ™ SMRT ® Cell 1 M v2 and the Sequel Sequencing Kit 2.1. A 600-minute movie was captured for each SMRT cell using the Sequel System (Pacific Biosciences, Menlo Park, CA, USA) 10 . The Hi-C library was constructed according to the manufacturer protocol to generate pseudo-chromosomes. ...

Chromosomal assembly of the Antarctic toothfish (Dissostichus mawsoni) genome using third-generation DNA sequencing and Hi-C technology

动物学研究

... The predominant bacteria associated with Oxyphotobacteria, Bacteroidia, Alphaproteobacteria, Chloroplast, and Cytophagales, which were coexisting in source of nitrogen at different days, of these bacteria were most abundant ( Fig. 4a and b). Probably, because of its special metabolic pathway to algae, on the 16th day, under various nitrogen sources, it may occupy more than half of the community composition and has the ability to grow preferentially compared to other bacteria (Yang et al. 2019). Han et al. 2016, examined that certain bacterium has been reported to exert an effect on algae, indicating that the combination of microalgae and bacteria may be decisive for co-culture. ...

Assessment of the Dynamics of Microbial Community Associated with Tetraselmis suecica Culture under Different LED Lights Using Next-Generation Sequencing
  • Citing Article
  • December 2019

Journal of Microbiology and Biotechnology