We cloned a cDNA and the gene for Japanese flounder TNF. The TNF cDNA consisted of 1217 bp, which encoded 225 amino acid residues. The identities between Japanese flounder TNF and members of the mammalian TNF family were ∼20–30%. The positions of cysteine residues that are important for disulfide bonds were conserved with respect to those in mammalian TNF-α. The Japanese flounder TNF gene has a length of ∼2 kbp and consists of four exons and three introns. The positions of the exon-intron junction positions of Japanese flounder TNF gene are similar to those of human TNF-α. However, the length of the first intron of Japanese flounder is much shorter than that of the human TNF-α gene. There are simple CA or AT dinucleotide repeats in the 5′-upstream and 3′-downstream regions of the Japanese flounder TNF gene. Southern blot hybridization indicted that Japanese flounder TNF exists as a single copy. Expression of Japanese flounder TNF mRNA is greatly induced after stimulation of PBLs with LPS, Con A, or PMA. These results indicated that Japanese flounder TNF is more like mammalian TNF-α than mammalian lymphotoxin-α, with respect to its gene structure, length of amino acid sequence, number and position of cysteine residues, and regulation of gene expression.
We have isolated and identified all four TCR α, β, γ, and δ cDNAs and genomic clones from a Japanese flounder leukocyte cDNA library and bacterial artificial chromosomal genomic library. Numerous TCR transcripts were sequenced to examine the variability against antigenic peptide, and were shown hypervariability on their complementarity-determining region 3 (CDR3) loops. Among CDR3s, CDR3δ showed a long and broad length distribution, indicating greater similarity to that of Ig. From cDNA sequences and genomic gene analysis of each chain, we found that flounder TCR β, γ, and δ have two different C gene segments, while the TCR α C region exists as a single segment. The flounder Cγs and Cδs showed different lengths in the connecting peptide (CP) region between the different types of polypeptides. The Cδ1 gene consists of two exons, one that encodes an extracellular Ig-like domain (exon 1) and the other that encodes either a very short or possibly a lacking CP region, a transmembrane region, and a cytoplasmic tail (exon 2); these are located within TCR α gene locus. Southern blot analysis, using the bacterial artificial chromosomal genomic DNA clones, revealed that the Cδ2 gene segment, which has a long CP region and different genomic organization to the Cδ1 gene, exists on same gene locus as the TCR γ-chain. This suggests that the flounder possesses very unique genomic DNA organization and gene loci for TCR, Cα/Cδ1, and Cγ/Cδ2.
Background: Abalones are large marine snails in the family Haliotidae and the genus Haliotis belonging to the class Gastropoda of the phylum Mollusca. The family Haliotidae contains only one genus, Haliotis, and this single genus is known to contain several species of abalone. With 18 additional subspecies, the most comprehensive treatment of Haliotidae considers 56 species valid [1]. Abalone is an economically important fishery and aquaculture animal that is considered a highly prized seafood delicacy. The total global supply of abalone has increased 5-fold since the 1970s and farm production increased explosively from 50 mt to 103 464 mt in the past 40 years. Additionally, researchers have recently focused on abalone given their reported tumor suppression effect. However, despite the valuable features of this marine animal, no genomic information is available for the Haliotidae family and related research is still limited. To construct the H. discus hannai genome, a total of 580-G base pairs using Illumina and Pacbio platforms were generated with 322-fold coverage based on the 1.8-Gb estimated genome size of H. discus hannai using flow cytometry. The final genome assembly consisted of 1.86 Gb with 35 450 scaffolds (>2 kb). GC content level was 40.51%, and the N50 length of assembled scaffolds was 211 kb. We identified 29 449 genes using Evidence Modeler based on the gene information from ab initio prediction, protein homology with known genes, and transcriptome evidence of RNA-seq. Here we present the first Haliotidae genome, H. discus hannai, with sequencing data, assembly, and gene annotation information. This will be helpful for resolving the lack of genomic information in the Haliotidae family as well as providing more opportunities for understanding gastropod evolution.
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