The two myostatin genes of Atlantic salmon (Salmo salar) are expressed in a variety of tissues.

Two myostatin isoforms were identified in Atlantic salmon (Salmo salar) by RT-PCR, and genomic sequences encoding this negative muscle growth factor were for the first time isolated from a nonmammalian species. Salmon myostatin isoform I is transcribed in white skeletal muscle as a 2346-nucleotide mRNA species that encodes a precursor protein of 373 amino acids. Salmon myostatin I shows 93% sequence identity with isoform II which was isolated from white muscle as a partial cDNA sequence of 1409 nucleotides. In contrast to the restricted gene expression of myostatin in mammals, salmon myostatin I and II mRNAs were identified by RT-PCR in multiple tissues, including white muscle, intestine, brain, gills, tongue and eye. In addition, isoform I mRNA was found in red skeletal muscle, heart, spleen, and ovarian tissue. Using polyclonal antibodies against both isoforms, a 55-kDa precursor protein was detected by Western blot analysis in the red and white skeletal muscle, heart, intestine, and brain. Immunoreactive peptides of 35-40 kDa were identified in the gills, tongue, spleen, and head kidney, while the 25-kDa mature myostatin was found in the eye and serum, and in vitro expressed in rabbit reticulocyte lysate. Salmon myostatin was immunohistochemically localized in the sarcoplasma of red and white muscle fibres, in intestinal epithelial cells, at the basis of the branchial primary lamellae, and in odontoblasts and ameloblasts of the tongue teeth. The results indicate that the role of fish myostatin may not be restricted to muscle growth regulation, but may have additional functions similar to the growth/differentiation factor-11 in mammals.     

Urokinase is required for the formation of mactinin,an alpha-actinin fragment that promotes monocyte/macrophage maturation

Myostatin is a recently discovered gene that inhibits muscle growth. In the present study, we characterized the myostatin locus and its expression in channel catfish (Ictalurus punctatus). The genomic DNA and cDNA encoding the channel catfish myostatin were cloned and sequenced. The myostatin gene has three exons encoding a protein of 389 amino acids. Comparison of the genomic sequences with those of the cDNA revealed that the myostatin cDNA was 1673 base pair (bp) long with a 5'-untranslated region (UTR) and 3'-UTR of 180 and 323 bp, respectively. The deduced amino acid sequences of the catfish myostatin is highly conserved with those of other organisms. The myostatin locus is highly polymorphic in channel catfish because of the presence of several microsatellites and single nucleotide polymorphic sites. The myostatin gene was expressed in various tissues and developmental stages at differential levels, suggesting complex regulation of this gene and perhaps roles for myostatin in addition to those originally suggested.     

Construction of Genetic Linkage Maps and Comparative Genome Analysis of Catfish Using Gene-Associated Markers

A genetic linkage map of the channel catfish genome (N = 29) was constructed using EST-based microsatellite and single nucleotide polymorphism (SNP) markers in an interspecific reference family. A total of 413 microsatellites and 125 SNP markers were polymorphic in the reference family. Linkage analysis using JoinMap 4.0 allowed mapping of 331 markers (259 microsatellites and 72 SNPs) to 29 linkage groups. Each linkage group contained 3–18 markers. The largest linkage group contained 18 markers and spanned 131.2 cM, while the smallest linkage group contained 14 markers and spanned only 7.9 cM. The linkage map covered a genetic distance of 1811 cM with an average marker interval of 6.0 cM. Sex-specific maps were also constructed; the recombination rate for females was 1.6 times higher than that for males. Putative conserved syntenies between catfish and zebrafish, medaka, and Tetraodon were established, but the overall levels of genome rearrangements were high among the teleost genomes. This study represents a first-generation linkage map constructed by using EST-derived microsatellites and SNPs, laying a framework for large-scale comparative genome analysis in catfish. The conserved syntenies identified here between the catfish and the three model fish species should facilitate structural genome analysis and evolutionary studies, but more importantly should facilitate functional inference of catfish genes. Given that determination of gene functions is difficult in nonmodel species such as catfish, functional genome analysis will have to rely heavily on the establishment of orthologies from model species.     

Molecular characterization of myostatin in black seabream, Acanthopagrus schlegelii.

Myostatin is a negative regulator of skeletal muscle growth and has a potential application in aquaculture. The black seabream myostatin gene was cloned and sequenced. It had three exons encoding a protein of 382 amino acids. A 90 bp 5'-untranslated region (UTR) and a 536 bp 3'-UTR were obtained by RACE. Four microsatellite sequences, a (CAG)9, a (TC)12, a (CA)16 repeat and an "imperfect" (CA)25 microsatellite, were found in the myostatin. Two introns were 329 and 742 bp in length, respectively. The deduced amino acid sequence of the myostatin had a putative amino terminal signal sequence, a TGF-beta propeptide domain, a RXXR proteolytic processing site, a TGF-beta domain, and 12 conserved cysteine residues. The myostatin gene was expressed in four of the examined ten tissues and organs. The expression of myostatin was the strongest in the skeletal muscle and brain, intermediate in the eye, and low in the heart.     

Divergent Toll-like receptors in catfish (Ictalurus punctatus): TLR5S, TLR20, TLR21

Toll-like receptors (TLR) mediate pathogen recognition in vertebrate species through detection of conserved microbial ligands. Families of TLR molecules have been described from the genomes of the teleost fish model species zebrafish and Takifugu, but much research remains to characterize the full length sequences and pathogen specificities of individual TLR members in fish. While the majority of these pathogen receptors are conserved among vertebrate species with clear orthologues present in fish for most mammalian TLRs, several interesting differences are present in the TLR repertoire of teleost fish when compared to that of mammals. A soluble form of TLR5 has been reported from salmonid fish and Takifugu rubripes which is not present in mammals, and a large group of TLRs (arbitrarily numbered 19-23) was identified from teleost genomes with no easily discernible orthologues in mammals. To better understand these teleost adaptations to the TLR family, we have isolated, sequenced, and characterized the full-length cDNA and gene sequences of TLR5S, TLR20, and TLR21 from catfish as well as studied their expression pattern in tissues. We also mapped these genes to bacterial artificial chromosome (BAC) clones for genome analysis. While TLR5S appeared to be common in teleost fish, and TLR21 is common to birds, amphibians and fish, TLR20 has only been identified in zebrafish and catfish. Phylogenetic analysis of catfish TLR20 indicated that it is closely related to murine TLR11 and TLR12, two divergent TLRs about which little is known. All three genes appear to exist in catfish as single copy genes.     

Phylogenetic analysis of the myostatin gene sub-family and the differential expression of a novel member in zebrafish

The myostatin (MSTN)-null phenotype in mammals is characterized by extreme gains in skeletal muscle mass or "double muscling" as the cytokine negatively regulates skeletal muscle growth. Recent attempts, however, to reproduce a comparable phenotype in zebrafish have failed. Several aspects of MSTN biology in the fishes differ significantly from those in mammals and at least two distinct paralogs have been identified in some species, which possibly suggests functional divergence between the different vertebrate classes or between fish paralogs. We therefore conducted a phylogenetic analysis of the entire MSTN gene sub-family. Maximum likelihood, Bayesian inference, and bootstrap analyses indicated a monophyletic distribution of all MSTN genes with two distinct fish clades: MSTN-1 and -2. These analyses further indicated that all Salmonid genes described are actually MSTN-1 orthologs and that additional MSTN-2 paralogs may be present in most, if not all, teleosts. An additional zebrafish homolog was identified by BLAST searches of the zebrafish Hierarchical Tets Generation System database and was subsequently cloned. Comparative sequence analysis of both genes (zebrafish MSTN (zfMSTN)-1 and -2) revealed many differences, primarily within the latency-associated peptide regions, but also within the bioactive domains. The 2-kb promoter region of zfMSTN-2 contained many putative cis regulatory elements that are active during myogenesis, but are lacking in the zfMSTN-1 promoter. In fact, zfMSTN-2 expression was limited to the early stages of somitogenesis, whereas zfMSTN-1 was expressed throughout embryogenesis. These data suggest that zfMSTN-2 may be more closely associated with skeletal muscle growth and development. They also resolve the previous ambiguity in classification of fish MSTN genes.     

Toll-like receptor 3 and TICAM genes in catfish: species-specific expression profiles following infection with Edwardsiella ictaluri

Toll-like receptors (TLRs) are a family of transmembrane proteins that recognize specific pathogen-associated molecular patterns and use conserved signaling pathways to activate proinflammatory cytokines and type-1 interferons to fight infection. TLR3 in mammals is best known for its recognition of dsRNA as ligand and its MyD88-independent signaling. TLR3, upon recognition of dsRNA, recruits and binds its adaptor protein TIR domain-containing adapter molecule (TICAM) 1. Here we report the genomic sequences and structures of TLR3 and a TICAM adaptor from channel catfish (Ictalurus punctatus). Whereas a partial TLR3 cDNA sequence has been reported from channel catfish, and complete TLR3 genes are known from other teleost fish species, a complete TICAM sequence has not been previously reported from a nonmammalian species. Analysis of catfish TLR3 and TICAM expression after infection with Edwardsiella ictaluri, the causative agent of enteric septicemia of catfish (ESC), suggested a conserved TLR3-TICAM receptor–adaptor relation in catfish. Comparison of TLR3 and TICAM expression profiles in channel catfish with those from the closely related blue catfish species (Ictalurus furcatus), which exhibits strong resistance to ESC, revealed a striking pattern of species-specific expression. A dramatic downregulation of TLR3 and TICAM gene expression was observed in blue catfish head kidney and spleen, which we speculate may be the result of maturation and migration of different cell types to and from the lymphoid tissues following infection.Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.Puttharat Baoprasertkul and Eric Peatman contributed equally to this work.     

Assignment of immune-related genes to the channel catfish, Ictalurus punctatus, genetic map

Eighteen new genes, adenosine A1 receptor (ADORA1), complement component 4-beta (C4b), complement component 8-beta (C8b), chemokine ligand 19 (CCL19), chemokine ligand 21 (CCL21), chemokine ligand 25 (CCL25), chemokine receptor 2 (CCR2), chemokine receptor 5 (CCR5), chemokine receptor 4 (CCR4), chemokine receptor 7 (CCR7), chemokine receptor 9 (CCR9), interleukin 1-beta (IL1B), integrin II-beta (ITGB2), novel immune type receptor 2 (NITR2), novel immune type receptor 4 (NITR4), natural killer cell lysin (NKLYSIN), nucleotide excision repair (RAD23B) and tumour necrosis factor-alpha (TNF), were assigned to the channel catfish (Ictalurus punctatus) genetic linkage map. Polymorphic microsatellite markers were developed for NITR2, NITR4 and RAD23B from short-tandem repeats in the available sequence. Polymorphic microsatellite markers were developed for the remaining 15 genes by short-tandem repeat-anchored primer sequencing of catfish bacterial artificial chromosomes. Two gene clusters (MYOG-NRAMP-ADORA1) and (CCR4-CCR2-CCR5) displayed conservation of synteny between catfish and mammals. Assignment of 18 new genes to the catfish linkage map will further advance integration of genetic and physical maps and comparative mapping between channel catfish and map rich species.     

Methylation status and chromatin structure of the myostatin gene promoter region in the sea perch Lateolabrax japonicus (Perciformes)

Myostatin is a negative regulator of the growth and development of skeletal muscle mass. In fish, myostatin is expressed in several organs in addition to skeletal muscle. To understand the mechanisms regulating myostatin gene expression in the sea perch, Lateolabrax japonicus, we examined the methylation status of the myostatin gene promoter region in several tissues (liver, eye, kidney, brain, and heart) isolated from adult specimens. The frequency of methylated cytosines was very low in all tissues, regardless of the level of myostatin expression, suggesting that DNA methylation is not involved in the tissue-specific regulation of myostatin expression. Southern blot analysis of genomic DNA obtained from micrococcal nuclease-treated nuclei showed that chromatin digestion occurs in tissues where the myostatin gene is actively transcribed and that the myostatin gene is protected from micrococcal nuclease in tissues where myostatin is not expressed. The chromatin structure in the myostatin gene region appears to regulate its expression without DNA methylation.     

Translational machinery of channel catfish: II. Complementary DNA and expression of the complete set of 47 60S ribosomal proteins

Ribosomal protein genes have become widely used as markers for phylogenetic studies and comparative genomics, but they have not been available in fish. We have cloned and sequenced a complete set of all 47 60S ribosomal protein cDNAs from channel catfish (Ictalurus punctatus), of which 43 included the complete protein encoding regions. Most ribosomal protein mRNAs in channel catfish are highly similar to their mammalian counterparts. However, L4, L14, and L29 are significantly shorter in channel catfish than in mammals due to deletions in the 3' end of the gene. Two distantly related L5 cDNAs, L5a and L5b, were found in channel catfish. L5a is more similar to L5 in other vertebrates, while L5b showed significant levels of divergence, suggesting independent evolution of the two L5-encoding genes. The 47 ribosomal protein genes are generally highly expressed and together account for 11-14% of overall gene expression, depending on the tissues. Expression levels were highly variable both within a single tissue among different ribosomal protein genes, and among tissues with regard to a single ribosomal protein gene. Strong tissue preference expression was also observed for some ribosomal proteins. This set of ribosomal protein gene sequences represents one of the most complete sets from any single organism and will aid in fish phylogenetic and comparative genomic studies.     

Myostatin maps to porcine chromosome 15 by linkage and physical analyses

Myostatin belongs to the transforming growth factor-β superfamily, and is expressed specifically in developing and mature skeletal muscle. Myostatin appears to act as a negative regulator of muscle development, since mice with targeted disruption of this gene display a large increase in muscle mass. In this study, the porcine myostatin gene was mapped to chromosome 15q2·3 by fluorescence in situ hybridization. Myostatin was also positioned within the chromosome 15 linkage group using both a polymorphism located in the second intron and an associated microsatellite. The development of highly polymorphic markers associated with myostatin will support population studies to identify alleles of this gene that affects muscle mass and/or fat deposition in swine.     

Molecular Cloning and Characterization of the Myostatin Gene in Croceine Croaker, Pseudosciaena crocea

Myostatin (MSTN) is a negative regulator of skeletal muscle mass and has a potential application in aquaculture. We reported the characterization of the myostatin gene and its expression in the croceine croaker, Pseudosciaena crocea. The myostatin gene had three exons encoding 376 amino acids. The cDNA was 1,906 bp long with a 5′-UTR and 3′-UTR of 108 bp and 667 bp, respectively. A microsatellite sequence, CA₃₀ and CA₂₆ separated by TA, existed in the 3′-UTR. Intron I and II were 343 bp and 758 bp in length, respectively. The deduced amino acid sequence was highly conserved, and had more than 90% identical to shi drum, gilthead seabream, striped sea-bass, white perch, and white bass proteins. The myostatin of croceine croaker had a putative amino terminal signal sequence (residues 1–22), a transforming growth factor-beta (TGF-β) propeptide domain (residues 41–256), a RXXR proteolytic processing site (RARR, residues 264–267, matching the RXXR consensus site), and a TGF-β domain (residues 282–376). There were 13 conserved cysteine residues in croceine croaker myostatin, nine of which are common to all TGF-β superfamily members. The most conserved region of vertebrate myostatins is the TGF-β domain, which was the mature bioactive domain of the myostatin protein. The myostatin gene was expressed not only in the skeletal muscle, but also in the other tissues.