Comparative genomic analysis reveals independent expansion of a lineage-specific gene family in vertebrates: the class II cytokine receptors and their ligands in mammals and fish

Fish virus-induced interferon exerts antiviral function through Stat1 pathway

Virus-induced interferons (IFNs) have been identified in various fish species and display antiviral activities similar to mammalian type I IFNs. However, apart from the mammalian IFN system, the IFN signaling pathway remains largely unknown. Using transient transfection and recombinant protein, we are reporting in this study that a crucian carp (Carassius auratus L.) IFN exhibits strong antiviral activity against grass carp hemorrhagic virus (GCHV) infection and also mediates Poly I:C-induced antiviral response, which correlates with its ability to induce a set of IFN-stimulated genes (ISGs). Strikingly, overexpression of wild-type Stat1 increases the effects of IFN on both the expression of ISGs and the inhibition of virus infection, whereas a dominant negative mutant of Stat1 (Stat1-Delta C), which lacks of the C-terminal transcriptional activation domain (TAD), inhibits the antiviral activity of IFN and reduces the expression of ISGs, demonstrating that fish IFN induces the expression of ISGs and host antiviral response through Stat1 pathway reminiscent that of mammalian IFNs. Significantly, unlike mammalian type I IFNs, recombinant fish IFN is able to upregulate IFN itself, which is enhanced by overexpression of Stat1 but impaired by knockdown of Stat1, indicating a positive feedback loop in regulation of IFN itself. These results provide strong evidence for the existence of an evolutionary conserved Stat1 pathway between fish and mammals, which is indispensable for fish virus-induced IFN antiviral response.

Zebrafish larvae are unable to mount a protective antiviral response against waterborne infection by spring viremia of carp virus

Interferons (IFNs) and their receptors exist in all classes of vertebrates, where they represent early elements in innate and adaptive immunity. Both types I and II IFNs have been discovered in fish and type I IFN has recently been classified into two groups based on their primary protein sequences and biological activities. Thus, although groups I and II zebrafish IFN show powerful antiviral activities, only group I (IFNphi1) is able to protect the fish against bacterial infection. In addition, group II IFNs (IFNphi2 and IFNphi3) induce a rapid and transient expression of antiviral genes, while group I IFN exerts a slow but more powerful induction of several antiviral and pro-inflammatory genes. To gain further insight into the IFN system of fish, we have developed a waterborne infection model of zebrafish larvae with the spring viremia of carp virus (SVCV). Larvae were challenged 3 days post-fertilization by immersion, which considerably reduces the manipulation of fish and represents a more natural route of infection. Using this infection model, we unexpectedly found an inability on the part of zebrafish larvae to mount a protecting antiviral response to waterborne SVCV. Nevertheless, zebrafish larvae showed a functional antiviral system since ectopic expression of the cDNA of both groups I and II IFN was able to protect them against SVCV via the induction of IFN-stimulated genes (ISGs). Interestingly, group II IFNs also induced group I IFN, suggesting crosstalk between these two kinds of antiviral IFN. These results further confirm the antiviral activities of type I IFN in the zebrafish and provide the first viral infection model for zebrafish larvae using a natural route of infection. This model, in combination with the powerful gene overexpression and morpholino-mediated knockdown techniques, will help to illuminate the IFN system of teleost fish.

Intron-containing type I and type III IFN coexist in amphibians: refuting the concept that a retroposition event gave rise to type I IFNs

Type I and III IFNs are structurally related cytokines with similar antiviral functions. They have different genomic organizations and bind to distinct receptor complexes. It has been vigorously debated whether the recently identified intron containing IFN genes in fish and amphibians belong to the type I or III IFN family or diverged from a common ancestral gene, that subsequently gave rise to both types. In this report, we have identified intron containing type III IFN genes that are tandemly linked in the Xenopus tropicalis genome and hence demonstrate for the first time that intron containing type I and III genes diverged relatively early in vertebrate evolution, and at least by the appearance of early tetrapods, a transition period when vertebrates migrated from an aquatic environment to land. Our data also suggest that the intronless type I IFN genes seen in reptiles, birds, and mammals have originated from a type I IFN transcript via a retroposition event that led to the disappearance of intron-containing type I IFN genes in modern vertebrates. In vivo and in vitro studies in this paper show that the Xenopus type III IFNs and their cognate receptor are ubiquitously expressed in tissues and primary splenocytes and can be upregulated by stimulation with synthetic double-stranded RNA, suggesting they are involved in antiviral defense in amphibians.

Cloning of a novel interleukin (IL)-20-like gene in rainbow trout Oncorhynchus mykiss gives an insight into the evolution of the IL-10 family

A novel IL-20-like (IL-20L) gene has been analyzed in rainbow trout. It has a six exon/five intron gene organisation and is translated into 181 amino acids (aa) with a signal peptide of 25aa and a mature peptide of 156aa. The trout IL-20L translation shares highest identities to other IL-20L molecules from fish and to IL-20 in mammals. Phylogenetic analysis showed that the fish IL-20L molecules form an independent clade but cluster with the group containing the IL-19, IL-20 and IL-24 molecules from higher vertebrates with a high bootstrap value (89%). The fish IL-20L genes are syntenically in the same location as mammalian IL-19/IL-20/IL-24. Gene organisation and multiple alignment also showed a close relationship of fish IL-20L genes to the mammalian IL-19/IL-20/IL-24 subfamily. These data suggest that the fish IL-20L molecules may have arisen from an ancestral gene that gave rise to IL-19, IL-20 and IL-24 in higher vertebrates. A high level of IL-20L expression in immune related tissues and in the brain, suggests an important role of the fish IL-20L molecule in both the fish immune system and nervous system. Although the exact cell types expressing IL-20L have yet to be defined, macrophages express IL-20L. Moreover, the IL-20L expression in the macrophage cell line RTS-11 was modulated by pro-inflammatory cytokines, signalling pathway activators, microbial mimics and the immuno-suppressor dexamethasone. These data suggest that trout IL-20L is an important player in the cytokine network. The increased expression of IL-20L was only detected at late stages (4-24h) of LPS stimulation in RTS-11 cells and in spleen 24-72h after infection with Yersinia ruckeri, and suggests that the increased expression of IL-20L by LPS and infection may be via the rapid increase of pro-inflammatory cytokines (e.g., IL-1beta) and other factors that is known to occur.

Identification of a putative invertebrate helical cytokine similar to the ciliary neurotrophic factor/leukemia inhibitory factor family by PSI-BLAST-based approach

Most of our knowledge of helical cytokine-like molecules in invertebrates relies on functional assays and similarities at the physicochemical level. It is hard to predict helical cytokines in invertebrates based on sequences from mammals and vertebrates, because of their long evolutionary divergence. In this article, we collected 12 kinds of fish cytokines and constructed their respective consensus sequences using hidden Markov models; then, the conserved domains region of each consensus sequence were further extracted by the SMART tool, and used as the query sequence for PSI-BLAST analysis in Drosophila melanogaster. After two filtering processes based on the properties of helical cytokines, we obtained one protein named CG14629, which shares 25% identities/46% positives to fish M17 cytokine in the half length of the N-terminus. Considering the homology between M17 and LIF/CNTF (leukemia inhibitory factor/ciliary neurotrophic factor), and the close relationship between Dome, the putative cytokine receptor in Drosophila cells, and LIFR/CNTFR (LIF receptor/CNTF receptor), the results suggest that CG14629 is a good candidate for the helical cytokine ortholog in D. melanogaster.

Atlantic salmon IPS-1 mediates induction of IFNa1 and activation of NF-kappaB and localizes to mitochondria

The striking difference in evolution of type I IFN genes of fish and mammals poses the question of whether these genes are induced through similar or different signalling pathways in the two vertebrate groups. Previous work has shown that expression of both Atlantic salmon (Salmo salar) IFNa1 and mammalian IFN-beta genes is dependent on IRF and NF-kappaB elements in their promoters. In mammals, IFN-beta transcription is induced through the RIG-I/MDA5 pathway where the adaptor protein IPS-1 plays a key role in the signal transduction. In this work we show that an Atlantic salmon homologue of IPS-1 (AsIPS-1) mediates activation of the salmon IFNa1 promoter and an NF-kappaB driven promoter. AsIPS-1 shares only 18% identity in amino acid sequence with human IPS-1, but possesses the CARD, proline-rich and transmembrane domains found in mammalian IPS-1. Overexpression of AsIPS-1 resulted in induction of an antiviral state in the cells apparently due to induction of IFN. Deletion of the CARD and transmembrane domains of AsIPS-1 abolished its ability to activate the IFNa1 promoter and the NF-kappaB driven promoter, and thus its ability to induce an antiviral state. AsIPS-1 is located to mitochondria similar to human IPS-1. Taken together, IPS-1 plays a key role in the induction of Atlantic salmon IFNa1, which appears to be the first and major IFN induced in host cells upon recognition of viral dsRNA.

The role of gamma interferon in innate immunity in the zebrafish embryo

The zebrafish genome contains ten genes that encode class II cytokine-like peptides, of which the two that are related most closely to mammalian interferon gamma (IFN-gamma) were named IFN-gamma1 and IFN-gamma2. Although the zebrafish has become a popular model system to study immune mechanisms, and although interferons are central regulators of immunity, which zebrafish cytokines correspond functionally to mammalian IFN-gamma has not been established. We used zebrafish embryos to assay the functions of IFN-gamma1 and IFN-gamma2, and have identified a subset of zebrafish homologs of the mammalian IFN-responsive genes as IFN-gamma targets in the zebrafish embryo: these genes are upregulated in response to raised levels of either IFN-gamma1 or IFN-gamma2. Infection studies using two different pathogens show that IFN-gamma signalling is required for resistance against bacterial infections in the young embryo and that the levels of IFN-gamma need to be regulated tightly: raising IFN-gamma levels sensitizes fish embryos against bacterial infection. Embryos injected with high doses of Escherichia coli are able to clear the bacteria within a day, and the gamma-interferons are necessary for this defence reaction. The protective response to Yersinia ruckeri, a natural fish pathogen that is lethal at low doses, also requires IFN-gamma. As in the induction of target genes, the two interferons act at least partly redundantly. Together with the previously demonstrated type III interferon response, these results show that the counterparts of the mammalian viral and bacterial interferon-dependent defence functions are in place in zebrafish embryos, and suggest that zebrafish IFN-gamma1 and IFN-gamma2 are functionally equivalent to mammalian IFN-gamma.

The search for the IFN-gamma receptor in fish: Functional and expression analysis of putative binding and signalling chains in rainbow trout Oncorhynchus mykiss

Interferons (IFNs), consisting of three major subfamilies, type I, type II (gamma) and type III (lambda) IFN, activate vertebrate antiviral defences once bound to their receptors. The three IFN subfamilies bind to different receptors, IFNAR1 and IFNAR2 for type I IFNs, IFNgammaR1 and IFNgammaR2 for type II IFN, and IL-28R1 and IL-10R2 for type III IFNs. In fish, although many types I and II IFN genes have been cloned, little is known about their receptors. In this report, two putative IFN-gamma receptor chains were identified and sequenced in rainbow trout (Oncorhynchus mykiss), and found to have many common characteristics with mammalian type II IFN receptor family members. The presented gene synteny analysis, phylogenetic tree analysis and ligand binding analysis all suggest that these molecules are the authentic IFNgammaRs in fish. They are widely expressed in tissues, with IFNgammaR1 typically more highly expressed than IFNgammaR2. Using the trout RTG-2 cell line it was possible to show that the individual chains could be differentially modulated, with rIFN-gamma and rIL-1beta down regulating IFNgammaR1 expression but up regulating IFNgammaR2 expression. Over-expression of the two receptor chains in RTG-2 cells revealed that the level of IFNgammaR2 transcript was crucial for responsiveness to rIFN-gamma, in terms of inducing gammaIP expression. Transfection experiments showed that the two putative receptors specifically bound to rIFN-gamma. These findings are discussed in the context of how the IFNgammaR may bind IFN-gamma in fish and the importance of the individual receptor chains to signal transduction.

The role of transposable elements in the regulation of IFN-lambda1 gene expression

IFNs lambda1, lambda2, and lambda3, or type III IFNs, are recently identified cytokines distantly related to type I IFNs. Despite an early evolutionary divergence, the 2 types of IFNs display similar antiviral activities, and both are produced primarily in dendritic cells. Although virus induction of the type I IFN-beta gene had served as a paradigm of gene regulation, relatively little is known about the regulation of IFN-lambda gene expression. Studies of virus induction of IFN-lambda1 identified an essential role of IFN regulatory factors (IRF) 3 and 7, which bind to a regulatory DNA sequence near the start site of transcription. Here, we report that the proximal promoter region of the IFN-lambda1 regulatory region is not sufficient for maximal gene induction in response to bacterial LPS, and we identify an essential cluster of homotypic NF-kappaB binding sites. Remarkably, these sites, which bind efficiently to NF-kappaB and function independently of the IRF3/7 binding sites, originate as transposable elements of the Alu and LTR families. We also show that depletion of the NF-kappaB RelA protein significantly reduces the level of the IFN-lambda1 gene expression. We conclude that IFN-lambda1 gene expression requires NF-kappaB, and we propose a model for IFN-lambda1 gene regulation, in which IRF and NF-kappaB activate gene expression independently via spatially separated promoter elements. These observations provide insights into the independent evolution of the IFN-lambda1 and IFN-beta promoters and directly implicate transposable elements in the regulation of the IFN-lambda1 gene by NF-kappaB.

Expression regulation and functional characterization of a novel interferon inducible gene Gig2 and its promoter

Grass carp hemorrhagic virus (GCHV)-induced gene 2 (Gig2) is a novel gene previously identified from UV-inactivated GCHV-treated Carassius auratus blastulae embryonic (CAB) cells, suggesting that it should play a pivotal role in the interferon (IFN) antiviral response. In this study, a polyclonal anti-Gig2 antiserum was generated and used to study the inductive expression pattern by Western blot analysis, showing no basal expression in normal CAB cells but a significant up-regulation upon UV-inactivated GCHV, polyinosinic:polycytidylic acid (Poly I:C) and recombinant IFN (rIFN). However, constitutive expression of Gig2 is observed in all tested tissues from grass carp (Ctenopharyngodon idellus), and Poly I:C injection increases the relative amount of Gig2 protein in skin, spleen, trunk kidney, gill, hindgut and thymus. Moreover, the genomic sequence covering the whole Gig2 ORF and the upstream promoter region were amplified by genomic walking. Significantly, the Gig2 promoter contains three IFN-stimulated response elements (ISREs), nine GAAA/TTTC motifs and five gamma-IFN activating sites (GAS), which are the characteristics of genes responsive to both type I IFN and type II IFN. Subsequently, the complete Gig2 promoter sequence was cloned into pGL3-Basic vector, and its activity was measured by luciferase assays in the transfected CAB cells. The Gig2 promoter-driven construct is highly induced in CAB cells after treatment with Poly I:C or rIFN, and the functional capability is dependent on IFN regulatory factor 7 (IRF7), because its activity can be stimulated by IRF7. Collectively, the data provide strong evidence that Gig2 is indeed a novel IFN inducible gene and its expression is likely dependent on IRF7 upon Poly I:C or IFN.

Identification of interleukin-22 in gadoids and examination of its expression level in vaccinated fish

This paper reports the cloning and sequencing of interleukin (IL)-22 in two gadoid fish, cod (Gadus morhua) and haddock (Melanogrammus aeglefinus). The complete transcript of this gene was 1002 and 1154 bp respectively, of which 492 bp was the open reading frame (ORF) in both genes. High amino acid identity (88.3%) was found between these genes but was less than 50% aa identity to other known genes. The gene organisation of haddock IL-22 consisted of five exons and four introns, as with other IL-10 family members. Expression studies showed that IL-22 is constitutively expressed in gill, with low level expression also observed in gut, gonad and head kidney. In a vaccination experiment, haddock were injected intraperitoneally with formalin-killed Vibrio anguillarum or with PBS, and 2 months later challenged by immersion in 10(7)cfu/ml V. anguillarum for 30 min. Head kidney and gill samples were collected prior to challenge and 24, 48 and 72 h post-challenge (hpc) for Real-time PCR analysis of IL-22 expression. No significant changes in IL-22 expression were observed in head kidney tissue but vaccinated fish showed a significantly increased expression of IL-22 24 hpc in gill and no mortalities were seen in these fish. In contrast, control fish, which started to succumb to the disease from 72 hpc, showed no significant increase in gill expression after challenge.

Mitochondrial antiviral signaling protein plays a major role in induction of the fish innate immune response against RNA and DNA viruses

Viral infection triggers host innate immune responses through cellular sensor molecules which activate multiple signaling cascades that induce the production of interferons (IFN) and other cytokines. The recent identification of mammalian cytoplasmic viral RNA sensors, such as retinoic acid-inducible gene I (RIG-I)-like receptors (RLRs) and their mitochondrial adaptor, the mitochondrial antiviral signaling protein (MAVS), also called IPS-1, VISA, and Cardif, highlights the significance of these molecules in the induction of IFN. Teleost fish also possess a strong IFN system, but nothing is known concerning the RLRs and their downstream adaptor. In this study, we cloned MAVS cDNAs from several fish species (including salmon and zebrafish) and showed that they were orthologs of mammalian MAVS. We demonstrated that overexpression of these mitochondrial proteins in fish cells led to a constitutive induction of IFN and IFN-stimulated genes (ISGs). MAVS-overexpressing cells were almost fully protected against RNA virus infection, with a strong inhibition of both DNA and RNA virus replication (1,000- and 10,000-fold decreases, respectively). Analyses of MAVS deletion mutants showed that both the N-terminal CARD-like and C-terminal transmembrane domains, but not the central proline-rich region, were indispensable for MAVS signaling function. In addition, we cloned the cDNAs encoding a RIG-I-like molecule from salmonid and cyprinid cell lines. Like the case with MAVS, overexpression of RIG-I CARDs in fish cells led to a strong induction of both IFN and ISGs, conferring on fish cells full protection against RNA virus infection. This report provides the first demonstration that teleost fish possess a functional RLR pathway in which MAVS may play a central role in the induction of the innate immune response.

New insights into the evolution of IFNs: zebrafish group II IFNs induce a rapid and transient expression of IFN-dependent genes and display powerful antiviral activities

The IFNs and their receptors have existed in early chordates for approximately 500 million years and represent the early elements in innate and adaptive immunity. Both types I and II IFNs have been discovered in fish, and type I has recently been classified into two groups based on their primary protein sequences. However, the biological activities of fish IFNs and their roles in infection are largely unknown. Using the zebrafish and manageable bacterial (Streptococcus iniae) and viral (spring viremia of carp virus) infection models, we are reporting in this study that zebrafish IFN (zfIFN) gamma failed to induce antiviral and proinflammatory genes when administered in vivo, which correlates with its inability to protect the fish against bacterial and viral infections. We also found that, although both group I (i.e., zfIFN1) and group II zfIFNs (i.e., zfIFN2 and zfIFN3) displayed strong in vivo antiviral activities, only group I zfIFN was able to protect the fish against bacterial infection, which may reflect the different patterns and kinetics of immune-related genes elicited by these two groups of IFNs. Thus, group II zfIFNs induced a rapid and transient expression of antiviral genes, whereas group I zfIFN exerted a slow but more powerful induction of several antiviral and proinflammatory genes. Collectively, our results suggest nonredundant, complementary roles of type I zfIFNs in viral infections and provide evidence for a pivotal role of the recently identified group II IFN of fish in the early stages of viral infections.

Characterization of the bovine type I IFN locus: rearrangements, expansions, and novel subfamilies

BACKGROUND

The Type I interferons (IFN) have major roles in the innate immune response to viruses, a function that is believed to have led to expansion in the number and complexity of their genes, although these genes have remained confined to single chromosomal region in all mammals so far examined. IFNB and IFNE define the limits of the locus, with all other Type I IFN genes except IFNK distributed between these boundaries, strongly suggesting that the locus has broadened as IFN genes duplicated and then evolved into a series of distinct families.

RESULTS

The Type I IFN locus in Bos taurus has undergone significant rearrangement and expansion compared to mouse and human, however, with the constituent genes separated into two sub-loci separated by >700 kb. The IFNW family is greatly expanded, comprising 24 potentially functional genes and at least 8 pseudogenes. The IFNB (n = 6), represented in human and mouse by one copy, are also present as multiple copies in Bos taurus. The IFNT, which encode a non-virally inducible, ruminant-specific IFN secreted by the pre-implantation conceptus, are represented by three genes and two pseudogenes. The latter have sequences intermediate between IFNT and IFNW. A new Type I IFN family (IFNX) of four members, one of which is a pseudogene, appears to have diverged from the IFNA lineage at least 83 million years ago, but is absent in all other sequenced genomes with the possible exception of the horse, a non-ruminant herbivore.

CONCLUSION

In summary, we have provided the first comprehensive annotation of the Type I IFN locus in Bos taurus, thereby providing an insight into the functional evolution of the Type I IFN in ruminants. The diversity and global spread of the ruminant species may have required an expansion of the Type I IFN locus and its constituent genes to provide broad anti-viral protection required for foraging and foregut fermentation.

An antiserum against Atlantic salmon IFNa1 detects IFN and neutralizes antiviral activity produced by poly I:C stimulated cells

Type I interferons (IFNs) play a crucial role in innate immune responses against virus infections in vertebrates. Two IFNs (IFNa1 and IFNa2) have previously been cloned from Atlantic salmon. In the present work a polyclonal antiserum, which was generated against salmon IFNa1 was used to study its production in cells by immunoblot detection and neutralization of antiviral activity. The antiserum was first confirmed to detect and neutralize the antiviral activity of recombinant salmon IFNa1 produced in HEK293 cells. The antiserum also detected IFNa1 and neutralized 95-98% of the antiviral activity in supernatants of poly I:C stimulated salmon TO cells. This suggests that IFNa1/IFNa2 are the major IFNs produced by poly I:C stimulated TO cells. The antiserum neutralized most of the IFN activity in poly I:C stimulated head kidney leucocytes from three of five individuals, but in stimulated leucocytes from the other two individuals only 75% of the antiviral activity was neutralized. This shows that although IFNa1/IFNa2 are major IFNs secreted by poly I:C stimulated leucocytes, these cells can also produce additional molecules with IFN-like activity.

Structural conservation of interferon gamma among vertebrates

Interferon gamma (IFN-gamma), being the hallmark of the T-cell T(H)1 response, has been extensively studied with respect to its expression and regulation of immune function. This gene has been extensively characterized in many mammalian species, making it one of the most widely cloned immunoregulatory genes. Recently, the gene has been identified in avian and piscine species and we have identified the gene in the frog genome. Based on these identified DNA sequences, we have constructed an evolutionary history of IFN-gamma that shows this molecule can be traced back more than 450 million years ago. Our analysis shows that type II interferon (IFN-gamma) function evolved before the tetrapod-fish split, a finding that contrasts earlier studies showing its origins in tetrapods. The IFN-gamma gene has undergone a further duplication event in teleosts after the tetrapod-fish split suggesting a specific-evolutionary adaptation in fish. The analyses of IFN-gamma, IL-22 and IL-26 genomic region in mammals, chicken, frog and fish reveal an evolutionary conservation of the loci and several regulatory elements controlling IFN-gamma gene transcription. Furthermore, across the vertebrata, the first intron of IFN-gamma gene contains a polymorphic microsatellite that has been closely correlated with disease susceptibility. Comparative-modeling of IFN-gamma structure revealed differences among the representative species but with an overall conservation of the fold, dimer interface and some interactions with the receptor. The structural and functional conservation of IFN-gamma suggests the presence of an innate, natural killer (NK) like response or even an adaptive T(H)1 immune response in lower vertebrates.

Identification of an Atlantic salmon IFN multigene cluster encoding three IFN subtypes with very different expression properties

A cluster of 11 interferon (IFN) genes were identified in the Atlantic salmon genome linked to the growth hormone 1 gene. The genes encode three different IFN subtypes; IFNa (two genes), IFNb (four genes) and IFNc (five genes), which show 22-32% amino acid sequence identity. Expression of the fish IFNs were studied in head kidney, leukocytes or TO cells after stimulation with the dsRNA poly I:C or the imidazoquinoline S-27609. In mammals, poly I:C induces IFN-beta through the RIG-I/MDA5 or the TLR3 pathway, both of which are dependent on NF-kB. In contrast, S-27609 induces mammalian IFN-alpha in plasmacytoid dendritic cells through the TLR7 pathway independent of NF-kappaB. The presence of an NF-kappaB site in their promoters and their strong up-regulation by poly I:C, suggest that salmon IFNa1/IFNa2 are induced through similar pathways as IFN-beta. In contrast, the apparent lack of NF-kappaB motif in the promoter and the strong upregulation by S-27609 in head kidney and leukocytes, suggest that IFNb genes are induced through a pathway similar to mammalian IFN-alpha. IFNc genes showed expression patterns different from both IFNa and IFNb. Taken together, salmon IFNa and IFNb are not orthologs of mammalian IFN-beta and IFN-alpha, respectively, but appear to utilize similar induction pathways.

Molecular cloning and expression analysis of three Mx isoforms of rock bream, Oplegnathus fasciatus

Complementary DNAs (cDNAs) corresponding to three isoforms of rock bream (Oplegnathus fasciatus) Mx (RbMx1, RbMx2 and RbMx3) were cloned using RACE reactions. Analysis of deduced amino acid sequences revealed that the tripartite GTP-binding domain, the dynamine family signature and the leucine zipper repeat were present in all three rock bream Mx isoforms. Cloning of genomic DNA sequence and Southern blot analysis showed that three rock bream Mx isoforms were encoded by different genomic loci, and they were not alternative splicing variants, although some alternative splicing variants were found in RbMx1 and RbMx2. When comparing amino acid sequence identity, RbMx1 shares about 60-70% identities with other fish Mx proteins, whereas both RbMx2 and RbMx3 share slightly high identity of 70-90%. As a result of expression analysis using RT-PCR, RbMx1 was constitutively expressed in the spleen and kidney of rock bream yearling, but RbMx2 and RbMx3 were rarely detected in both organs. When injected with synthetic double-stranded RNA polyinosinic:polycytidylic acid (poly I:C), expression of all rock bream Mx isoforms was up-regulated in spleen and head kidney. RbMx1 was continuously up-regulated throughout experimental period of 72 h but RbMx2 and RbMx3 were down-regulated to almost non-detectable level at 48 h post-injection.

The role of genomic data in the discovery, annotation and evolutionary interpretation of the interferon-lambda family

BACKGROUND

Type-I interferons, type-II interferons, and the IL-10 family are helical cytokines with similar three-dimensional folds. However, their homologous relationship is difficult to detect on the basis of sequence alone. We have previously described the discovery of the human type-III interferons (IFN lambda-1, -2, -3 or IL-29, IL-28A, IL-28B), which required a combination of manual and computational techniques applied to predicted protein sequences.

PRINCIPAL FINDINGS

Here we describe how the use of gene structure analysis and comparative genomics enabled a more extensive understanding of these genes early in the discovery process. More recently, additional mammalian genome sequences have shown that there are between one and potentially nine copies of interferon lambda genes in each genome, and that several species have single exon versions of the interferon lambda gene.

SIGNIFICANCE

The variable number of single exon type-I interferons in mammals, along with recently identified genes in zebrafish homologous to interferons allows a story of interferon evolution to be proposed. This model suggests that the gene duplications and single exon retrotransposons of mammalian type-III interferons are positively selected for within a genome. These characteristics are also shared with the fish interferons and could be responsible for the generation of the IL10 family and also the single exon type-I interferons.

Comparative study and expression analysis of the interferon gamma gene locus cytokines in Xenopus tropicalis

Using bioinformatics approach, the genome locus containing interleukin (IL)-22, IL-26, and interferon gamma (IFN-gamma) genes has been identified in the amphibian, Xenopus tropicalis. Like that in other vertebrates such as fish, birds, and mammals, the Xenopus IL-22, IL-26, and IFN-gamma are clustered in the same chromosome and the adjacent genes are conserved. The genomic structures of the Xenopus IL-22, IL-26, and IFN-gamma gene were identical to that of their mammalian counterparts. The Xenopus IL-22 and IL-26 genes contained five exons and four introns while the Xenopus IFN-gamma gene consisted of four exons and three introns. The Xenopus IL-22, IL-26, and IFN-gamma share 14.1-41.6%, 14.6-31.2%, and 23.7-36.5% identity to their counterparts in other species, respectively. Reverse-transcription polymerase chain reaction (PCR) and real-time quantitative PCR analyses revealed that the expression of IL-22, IL-26, and IFN-gamma genes was significantly upregulated after simulation with bacterial polyliposaccharide and/or synthetic double-stranded poly(I:C), suggesting these cytokines like those in other vertebrates play an important role in regulating immune response in Xenopus.

Local and systemic gene expression responses of Atlantic salmon (Salmo salar L.) to infection with the salmon louse (Lepeophtheirus salmonis)

Background

The salmon louse (SL) is an ectoparasitic caligid crustacean infecting salmonid fishes in the marine environment. SL represents one of the major challenges for farming of salmonids, and veterinary intervention is necessary to combat infection. This study addressed gene expression responses of Atlantic salmon infected with SL, which may account for its high susceptibility.

Results

The effects of SL infection on gene expression in Atlantic salmon were studied throughout the infection period from copepodids at 3 days post infection (dpi) to adult lice (33 dpi). Gene expression was analyzed at three developmental stages in damaged and intact skin, spleen, head kidney and liver, using real-time qPCR and a salmonid cDNA microarray (SFA2). Rapid detection of parasites was indicated by the up-regulation of immunoglobulins in the spleen and head kidney and IL-1 receptor type 1, CD4, beta-2-microglobulin, IL-12β, CD8α and arginase 1 in the intact skin of infected fish. Most immune responses decreased at 22 dpi, however, a second activation was observed at 33 dpi. The observed pattern of gene expression in damaged skin suggested the development of inflammation with signs of Th2-like responses. Involvement of T cells in responses to SL was witnessed with up-regulation of CD4, CD8α and programmed death ligand 1. Signs of hyporesponsive immune cells were seen. Cellular stress was prevalent in damaged skin as seen by highly significant up-regulation of heat shock proteins, other chaperones and mitochondrial proteins. Induction of the major components of extracellular matrix, TGF-β and IL-10 was observed only at the adult stage of SL. Taken together with up-regulation of matrix metalloproteinases (MMP), this classifies the wounds afflicted by SL as chronic. Overall, the gene expression changes suggest a combination of chronic stress, impaired healing and immunomodulation. Steady increase of MMP expression in all tissues except liver was a remarkable feature of SL infected fish.

Conclusion

SL infection in Atlantic salmon is associated with a rapid induction of mixed inflammatory responses, followed by a period of hyporesponsiveness and delayed healing of injuries. Persistent infection may lead to compromised host immunity and tissue self-destruction.

Expression of interferon and interferon-induced genes in salmonids in response to virus infection, interferon-inducing compounds and vaccination

Interferons (IFNs) involved in innate immunity against viruses have recently been cloned from Atlantic salmon and rainbow trout. Moreover, several IFN-stimulated genes (ISGs) have been cloned from salmonids although only Mx has been shown to possess antiviral properties. Much less in known about how viruses induce IFNs in salmonids, but synthetic ligands for some of the main mammalian viral sensors also induce IFNs and ISGs in salmonids. Analysis of the promoters of the salmon IFN-alpha1 and IFN-alpha2 genes shows that activation is dependent on both NFkappaB and IRFs similar to human IFN-beta. Furthermore, several IFN-stimulated genes (ISGs) have been cloned from salmonids although only Mx has been shown to possess antiviral properties. The synthetic compounds poly I:C, imidazoquinolines and CpG oligonucleotides induce IFNs and ISGs in salmonids, probably through the same pathways as in mammals. Salmonid viruses show potent ability to stimulate expression of IFN and ISGs in vivo. Differences between viruses in the ability to stimulate host gene expression are often more evident in cell culture, but more work is needed to pinpoint how salmonid viruses antagonize the IFN system of their host. Finally, existing data suggest that IFNs play a role in the early non-specific protection observed after vaccination of salmonids with rhabdoviral DNA vaccines and conventional polyvalent vaccines.

Conservation and divergence of gene families encoding components of innate immune response systems in zebrafish

Analysis of several fish genomes reveals components of the innate immune system and identifies orthologous relationships between gene families of fish and mammals.

Background

The zebrafish has become a widely used model to study disease resistance and immunity. Although the genes encoding many components of immune signaling pathways have been found in teleost fish, it is not clear whether all components are present or whether the complexity of the signaling mechanisms employed by mammals is similar in fish.

Results

We searched the genomes of the zebrafish Danio rerio and two pufferfish for genes encoding components of the Toll-like receptor and interferon signaling pathways, the NLR (NACHT-domain and leucine rich repeat containing) protein family, and related proteins. We find that most of the components known in mammals are also present in fish, with clearly recognizable orthologous relationships. The class II cytokines and their receptors have diverged extensively, obscuring orthologies, but the number of receptors is similar in all species analyzed. In the family of the NLR proteins, the canonical members are conserved. We also found a conserved NACHT-domain protein with WD40 repeats that had previously not been described in mammals. Additionally, we have identified in each of the three fish a large species-specific subgroup of NLR proteins that contain a novel amino-terminal domain that is not found in mammalian genomes.

Conclusion

The main innate immune signaling pathways are conserved in mammals and teleost fish. Whereas the components that act downstream of the receptors are highly conserved, with orthologous sets of genes in mammals and teleosts, components that are known or assumed to interact with pathogens are more divergent and have undergone lineage-specific expansions.

Culture conditions for maintaining the survival and mitotic activity of rainbow trout transplantable type A spermatogonia

Germ-cell transplantation is a powerful tool for studying gametogenesis in many species. We previously showed that spermatogonia transplanted into the peritoneal cavity of trout hatchlings were able to colonize recipient gonads, and produced fully functional sperm and eggs in synchrony with the germ cells of the recipient. An in vitro-culture system enabling spermatogonia to expand, when combined with transplantation, would be valuable in both basic and applied biology. To this end, we optimized culture conditions for type A spermatogonia in the present study using immature rainbow trout at 8-10 month of age. Spermatogonial survival and mitotic activity were improved during culture in Leibovitz's L-15 medium (pH 7.8) supplemented with 10% fetal bovine serum at 10 degrees C compared with culture under standard conditions for salmonids (Hank's MEM (pH 7.3) supplemented with 25 mM HEPES and 5% FBS, and culture at 20 degrees C). Elimination of testicular somatic cells promoted spermatogonial mitotic activity. In addition, insulin, trout embryonic extract, and basic fibroblast growth factor promoted the mitosis of purified spermatogonia in an additive manner. Mitotic activity increased nearly sevenfold over 19 days of culture compared with growth factor-free conditions and was maintained for >1 month. Furthermore, the cultured spermatogonia could colonize and proliferate in recipient gonads following transplantation. This study represents the first step towards establishing a cell line that can be transplanted for use in surrogate broodstock technology and cell-mediated gene-transfer systems.

Innate immunomodulation with recombinant interferon-alpha enhances resistance of rainbow trout (Oncorhynchus mykiss) to infectious hematopoietic necrosis virus

We examined the in vivo immunostimulatory effects of a recombinant Atlantic salmon (Salmo salar) interferon-alpha2 (rSasaIFN-alpha2). The mature rSasaIFN-alpha2, expressed and purified from Escherichia coli, was administered to rainbow trout (Oncorhynchus mykiss) via the oral, immersion, or intraperitoneal (IP) injection route. Injection of rSasaIFN-alpha2 at 0.1microg/g fish gave significantly greater protection than a phosphate buffered saline (PBS) injection against a lethal challenge of infectious hematopoietic necrosis virus (IHNV), with a relative percent survival of 39%. Relative percent survival (RPS) increased significantly to 92% when the fish were injected with rSasaIFN-alpha2 at 1microg/g fish. Antiviral protection was evident for up to 7 days post-injection of rSasaIFN-alpha2. Administration of rSasaIFN-alpha2 by the oral or immersion route was not protective, and the fish succumbed to virus infection. The level of systemic IFN-induced expression of the Mx1 gene was significantly greater (p<0.01) in the IFN-injected group than in the PBS-injected group, and this was correlated with the fish survival rates in the challenge study. We used relative quantitative real-time polymerase chain reactions to examine the systemic expression of several other IFN-induced genes (including genes for IFN1, IFN regulatory factors 1 and 2, MHC-I, STAT1, vig-1, and GBP) and found that their expression was significantly increased 1-day post-rSasaIFN-alpha2 injection. Expression of the IFN-gamma and interleukin-1beta genes was not significantly increased. Thus, a salmonid rIFN-alpha can modulate the innate immune response of rainbow trout and mediate early antiviral protection against IHNV.

Biological characterisation of a recombinant Atlantic salmon type I interferon synthesized in Escherichia coli

Type I (alpha/beta) interferons (IFNs) are a family of cytokines that stimulate the expression of numerous proteins that mediate an antiviral state in uninfected cells. Two Atlantic salmon (Salmo salar) IFN-alpha (SasaIFN-alpha1 & 2) genes have previously been cloned and both were found to contain a putative N-linked glycosylation site. Recombinant SasaIFN-alpha1 (rSasaIFN-alpha1) produced in eukaryotic systems has repeatedly been shown to confer antiviral properties. However, different IFN-alpha subtypes may exhibit differential antiviral activities and be subject to glycosylation. To evaluate the potential therapeutic impact of a rSasaIFN-alpha, the mature form of the SasaIFN-alpha2 protein was produced in a high-level Escherichia coli expression system. Expression of the rSasaIFN-alpha2 was detected by SDS-PAGE and Western blot, and its identity was confirmed by mass spectrometry. In the homologous Chinook salmon embryonic (CHSE-214) cell line, the rSasaIFN-alpha2 incited early expression of the IFN-induced Mx protein and exhibited high antiviral activity of about 2.8 x 10(6) U mg(-1) against infectious pancreatic necrosis virus (IPNV). Conversely, antiviral protection by rSasaIFN-alpha2 was not observed in a heterologous Japanese flounder embryo (HINAE) cell line. Hence, a biologically active form of rSasaIFN-alpha2 was successfully produced using a glycosylation-deficient prokaryotic system and purified to homogeneity, suggesting that glycosylation is not required for its antiviral activity.

Granulocyte colony-stimulating factor: molecular mechanisms of action during steady state and 'emergency' hematopoiesis

Neutrophils are phagocytes whose principal function is to maintain anti-bacterial immunity. Neutrophils ingest and kill invading bacteria, releasing cytotoxic, chemotactic and inflammatory mediators at sites of infection. This serves to control the immediate host immune response and attract other cells, such as macrophages and dendritic cells, which are important for establishing long-term adaptive immunity. Neutrophils thus contribute to both the initiation and the maintenance of inflammation at sites of infection. Aberrant neutrophil activity is deleterious; suppressed responses can cause extreme susceptibility to infection while overactivation can lead to excessive inflammation and tissue damage. This review will focus on neutrophil regulation by granulocyte colony-stimulating factor (G-CSF), the principal cytokine controlling neutrophil development and function. The review will emphasize the molecular aspects of G-CSF-driven granulopoiesis in steady state (healthy) conditions and during demand-driven or 'emergency' conditions elicited by infection or clinical administration of G-CSF. Understanding the molecular control of granulopoiesis will aid in the development of new approaches designed to treat disorders of neutrophil production and function.

Transmembrane protein 50b (C21orf4), a candidate for Down syndrome neurophenotypes, encodes an intracellular membrane protein expressed in the rodent brain

Transmembrane protein 50b, Tmem50b, previously referred to as C21orf4, encodes a predicted transmembrane protein and is one of few genes significantly over-expressed during cerebellar development in a Down syndrome mouse model, Ts1Cje. In order to assess potential mechanisms by which Tmem50b could contribute to Down syndrome-related phenotypes, we determined the expression patterns of Tmem50b mRNA, as well as Tmem50b protein distribution, expression and subcellular localization. In situ hybridization in mice at embryonic day 14.5 showed cortical plate and spinal cord mRNA expression. By postnatal day 7, strong mRNA expression was seen in the cerebellum, hippocampus and olfactory bulb, with diffuse cortical expression. Quantitative PCR of adult mouse tissue showed Tmem50b mRNA expression in the brain, heart and testis. A rabbit polyclonal antibody was generated against Tmem50b and rat and mouse tissue screening by Western blot, and immunohistochemistry showed that protein expression concurred with mRNA expression. Double immunofluorescence revealed that Tmem50b is highly expressed in rat and mouse glial fibrillary acidic protein-positive cells in vivo and in vitro, but less so in neuronal MAP2- or beta-tubulin II-positive cells in vitro. Tmem50b is invariably expressed in cultured mouse neural precursor cells. In adult mouse cerebellum sections, Tmem50b immunoreactivity was found in Purkinje and Golgi cell somata and in Bergmann glial processes. Electron microscopy confirmed that Tmem50b was present on endoplasmic reticulum (ER) and Golgi apparatus membranes. Results indicate that Tmem50b is a developmentally-regulated intracellular ER and Golgi apparatus membrane protein that may prove important for correct brain development through functions associated with precursor cells and glia.

Double-stranded RNA-activated protein kinase PKR of fishes and amphibians: varying the number of double-stranded RNA binding domains and lineage-specific duplications

Background

Double-stranded (ds) RNA, generated during viral infection, binds and activates the mammalian anti-viral protein kinase PKR, which phosphorylates the translation initiation factor eIF2α leading to the general inhibition of protein synthesis. Although PKR-like activity has been described in fish cells, the responsible enzymes eluded molecular characterization until the recent discovery of goldfish and zebrafish PKZ, which contain Z-DNA-binding domains instead of dsRNA-binding domains (dsRBDs). Fish and amphibian PKR genes have not been described so far.

Results

Here we report the cloning and identification of 13 PKR genes from 8 teleost fish and amphibian species, including zebrafish, demonstrating the coexistence of PKR and PKZ in this latter species. Analyses of their genomic organization revealed up to three tandemly arrayed PKR genes, which are arranged in head-to-tail orientation. At least five duplications occurred independently in fish and amphibian lineages. Phylogenetic analyses reveal that the kinase domains of fish PKR genes are more closely related to those of fish PKZ than to the PKR kinase domains of other vertebrate species. The duplication leading to fish PKR and PKZ genes occurred early during teleost fish evolution after the divergence of the tetrapod lineage. While two dsRBDs are found in mammalian and amphibian PKR, one, two or three dsRBDs are present in fish PKR. In zebrafish, both PKR and PKZ were strongly upregulated after immunostimulation with some tissue-specific expression differences. Using genetic and biochemical assays we demonstrate that both zebrafish PKR and PKZ can phosphorylate eIF2α in yeast.

Conclusion

Considering the important role for PKR in host defense against viruses, the independent duplication and fixation of PKR genes in different lineages probably provided selective advantages by leading to the recognition of an extended spectrum of viral nucleic acid structures, including both dsRNA and Z-DNA/RNA, and perhaps by altering sensitivity to viral PKR inhibitors. Further implications of our findings for the evolution of the PKR family and for studying PKR/PKZ interactions with viral gene products and their roles in viral infections are discussed.

Poly I:C induces Mx transcription and promotes an antiviral state against sole aquabirnavirus in the flatfish Senegalese sole (Solea senegalensis Kaup)

Mx is an interferon-induced protein that protects against viral infections. In this study the absolute number of Mx transcripts after poly I:C injection (a synthetic dsRNA) or sole aquabirnavirus (solevirus) inoculation in Senegalese sole (Solea senegalensis Kaup) has been quantified. Mx expression profiles differed clearly in both experimental conditions; the induction response was faster and more intense after poly I:C injection than after solevirus inoculation. Moreover, pre-injection of soles with poly I:C prior to solevirus infection eliminated the induction of Mx expression associated with this virus. To evaluate the possible interference of poly I:C treatments on solevirus replication, the mRNA levels of the virus capsid protein (VP2) were determined by RT-PCR. VP2 transcripts were hardly detected in poly I:C pre-injected animals from 12 to 72 h after solevirus inoculation. All these data suggest that poly I:C is able to induce an antiviral state that interferes with solevirus replication, and support the suitability of Mx expression analysis as a marker to study the defensive response against solevirus.

The innate immune response of finfish--a review of current knowledge

The decline in the fisheries of traditional marine species has been an incentive for the diversification of today's aquaculture sector into the intensive rearing of many finfish species. The increasing interest in commercial farming of different finfish species is expected to result in similar environmental and husbandry-related problems as have been experienced in the development of the salmonid farming industry. An understanding of the biology of the fish species being cultured, in particular the immune response is important for improved husbandry and health management of the species. The innate immune system of fish has generated increasing interest in recent years and is now thought to be of key importance in primary defence and in driving adaptive immunity. This review focuses on key components (cellular and humoral) of the innate immune responses of different fish species of commercial importance.

Identification of a second group of type I IFNs in fish sheds light on IFN evolution in vertebrates

In this report, three type I IFN genes were identified in rainbow trout (rt) Oncorhynchus mykiss and are classified into two groups based on their primary protein sequences: group I containing two cysteine residues; and group II containing four cysteines residues. The group I rtIFNs were induced in fibroblasts (RTG-2 cells), macrophages (RTS-11 cells), and head kidney leukocytes when stimulated with polyinosinic:polycytidylic acid, whereas group II IFN was up-regulated in head kidney leukocytes but not in RTG-2 and RTS-11 cells. Recombinant group I rtIFNs were potent at inducing Mx expression and eliciting antiviral responses, whereas recombinant group II rtIFN was poor in these activities. That two subgroups of type I IFN exist in trout prompted a survey of the genomes of several fish species, including zebrafish, medaka, threespine stickleback and fugu, the amphibian Xenopus tropicalis, the monotreme platypus and the marsupial opossum, to gain further insight into possible IFN evolution. Analysis of the sequences confirmed that the new IFN subgroup found in trout (group II IFN) exists in other fish species but was not universally present in fish. The IFN genes in amphibians were shown for the first time to contain introns and to conserve the four cysteine structure found in all type I IFNs except IFN-betaepsilon and fish group I IFN. The data overall support the concept that different vertebrate groups have independently expanded their IFN types, with deletion of different pairs of cysteines apparent in fish group I IFN and IFN-betaepsilon of mammals.

Historical developments in the research of interferon receptors

Interferons (IFNs) were discovered 50 years ago independently by Isaacs and Lindemann and by Nagata and Kojima. When it was later realized that IFNs are active at very low concentrations, research began to determine how their powerful effects were generated from such a small initial signal. It has since been established that interferons, as well as all other cytokines, employ cell surface receptors to translate their presence in the serum to a potent cellular response to a viral infection. These receptor complexes are composed of multiple distinct glycosylated transmembrane polypeptides, a number of protein tyrosine kinases, and interact transiently with a large variety of other proteins including transcription factors, phosphatases, signaling repressors, and adaptor proteins coupling the receptor to alternative signaling pathways. Three major receptor complexes exist that are exclusive to each of three major classes of interferon. Even though the effects of each major class of interferon vary physiologically, each receptor complex interacts with its ligand in similar ways and activates similar signaling cascades. In this mini-review, we take a historical perspective at the major events in the characterization of interferon receptors, discussing interesting results that still need to be explained.

IL-28 and IL-29: newcomers to the interferon family

IL-28 and IL-29 were recently described as members of a new cytokine family that shares with type I interferon (IFN) the same Jak/Stat signalling pathway driving expression of a common set of genes. Accordingly, they have been named IFN lambda. IFNs lambda exhibit several common features with type I IFNs: antiviral activity, antiproliferative activity and in vivo antitumour activity. Importantly, however, IFNs lambda bind to a distinct membrane receptor, composed of IFNLR1 and IL10R2. This specific receptor usage suggests that this cytokine family does not merely replicate the type I IFN system and justifies its designation as type III IFN by the nomenclature committee of the International Society of Interferon and Cytokine Research.

Identification of the Zebrafish IFN Receptor: Implications for the Origin of the Vertebrate IFN System

The recent description of virus-induced fish IFNs has raised questions about the evolution of this complex antiviral system. Identification of the receptor of the zebrafish virus-induced IFN (zIFN) was sought to help resolve these questions. We set up an experimental system to study the zIFN system in the course of a viral infection of zebrafish embryos. In this setting, zIFN was induced by viral infection, and we identified zIFN-dependent induced transcripts. Embryos quickly died from the infection, but zIFN overexpression increased their survival. We took advantage of this experimental system to perform in vivo loss and gain of function analysis of candidate receptors of the class II helical receptor family and identified zCRFB1 and zCRFB5 as the two subunits of the zebrafish IFN receptor. Based on the organization of the zIFN gene and the protein structure of the identified receptor components, the virus-induced fish IFNs appear as orthologs of mammalian IFN-lambda, specifying type III IFN as the ancestral antiviral system of vertebrates.

Cloning, characterization and expression analysis of pufferfish interleukin-4 cDNA: The first evidence of Th2-type cytokine in fish

Interleukin-4 (IL-4) is one of the key cytokines in Th2 mediated immune responses, which has been shown to regulate the responses of many immune cytokines, such as interferon-gamma (IFN-gamma), interleukin-1 (IL-1) and TNF-alpha. Much work on IL-4 has been done in human and several mammal species while little in fish. In this study, we have cloned and characterized the full-length cDNA of IL-4 in Tetraodon. The Tetraodon IL-4 cDNA is 834bp in length and contains a short 5'UTR of 39bp, a 3'UTR of 375bp and an open reading frame of 420bp translating into a protein of 139aa with a predicted molecular mass of 16.131kDa. The Tetraodon IL-4-encoding gene with the same organization as the mammalians and birds consists of four exons and three introns. The encoded protein shows 11-16% identities to other homologues. RT-PCR was optimized to estimate the expression level of IL-4 in Tetraodon. The results showed that IL-4 is constitutively expressed in all selected tissues, including head kidney, spleen, liver, brain, gill, muscle and heart, although low levels were observed in head kidney, spleen, and liver. The ubiquitous expression of IL-4 is consistent with a postulated role in immune cytokines regulation. Stimulating the fish with a mixed stimulant that contained 2 microg ConA, 2 microg PHA, and 2 microg PMA, significantly up-regulated the expression of IL-4 in most tissues examined, which potentially indicated that IL-4 was involved in the immune inflammatory responses triggered by mitogens. This is the first report of cloning and characterization of IL-4 cDNA and gene in fish.

Inhibition of nervous necrosis virus propagation by fish Mx proteins

Mx proteins are interferon induced, antiviral proteins, expressed in response to treatment with double stranded RNA or virus infection. Here we report the cloning, sequencing, and antiviral property of three forms of Mx genes, MxI, MxII, and MxIII from grouper (Epinephelus coioides). Multiple comparison of grouper Mx amino acid sequences revealed the conservation of Mx putative GTP-binding domain, dynamin family signature, and leucine zipper motif. We have established a new cell line, grouper brain 3 (GB3), and prepared stable clones expressing Flag-epitope tagged grouper MxI, MxII, and MxIII. Immunostaining shows that all the three grouper Mx proteins are localized in the cytoplasm. To examine the antiviral activity of grouper Mx proteins, these stable clones were infected by a nodavirus, yellow grouper nervous necrosis virus (YGNNV), and the results showed that all the three Mx isoforms have the efficiency of reducing the titre of virus from 10- to 100-fold. Moreover, through immunocytochemistry we demonstrated that Mx protein can inhibit the YGNNV propagation in GB3 cells. Taken together, this study demonstrates that grouper Mx proteins have efficient inhibitory activity against nodavirus, the most endangered virus of fish, and this information would be helpful to design effective DNA vaccines that can confer an early non-specific antiviral protection.

Identification, cloning and characterization of interleukin-17 and its family from zebrafish

Cytokines are one of the major signaling molecules involved in immunity. Many of these cytokines have been isolated in vertebrates and found to play a significant role in host defense mechanism. Interleukin-17 (IL-17) family of genes are known to have pro-inflammatory actions and associated with specific disease conditions, these genes are conserved across vertebrate evolution. In this study, computational screening for the zebrafish (Danio rerio) genome resulted in identification of five contigs harboring IL-17 genes. Zebrafish cDNA encoding five IL-17 genes exhibited percentage identities of 19.3%-61.9% with that of human homologs. The molecules show conservation of cysteines, important for disulphide bonds for IL-17 molecules. The structural composition of these genes shows two introns and three exons except for IL-17D gene that has only one intron and two exons. Phylogenetic analysis using maximum parsimony algorithm showed that zebrafish IL-17 genes clustered well with other IL-17 homologs further proving the structural similarity with IL-17 genes from other organisms. Expression analysis by RT-PCR revealed expression of IL-17 genes in normal and stimulated tissues of kidney, spleen, gills and intestine. The expression of IL-17 in un-stimulated tissues indicates that these genes may play important roles in normal conditions as well.

Functional characterisation of the Japanese flounder, Paralichthys olivaceus, Mx promoter

The Japanese flounder, Paralichthys olivaceus, genome appears to encode a single Mx gene based on Southern blotting and previous cDNA studies. The 5' flanking region of the Japanese flounder Mx gene was cloned and analysed for its regulatory regions. A TATA box (-24 to -30), two interferon-stimulated response elements (ISREs) (-69 to -80 and -508 to -521) and two Sp1 sites (-563 to -572 and -994 to -1003) were identified relative to the transcription start site. The effects of various stimuli, as well as the effects of various promoter mutations, were investigated in a transient expression system using Japanese flounder (hirame) natural embryo (HINAE) cells and luciferase reporter gene constructs. Although not sensitive to LPS, ConA or PMA, reporter gene expression increased more than 10-fold after stimulation by polyinosinic:polycytidilic acid (poly I:C), an established inducer of interferon. Deletion mutational analyses revealed the ISRE closest to the transcription start site to be crucial for promoter activity. The distal ISRE, despite its relatively distant location, contributed to induce maximal promoter activity, but when alone was not sufficient by itself to elicit any significant promoter activity. An electrophoretic mobility shift assay confirmed the binding of transcription factors to both ISREs. Induction of luciferase by poly I:C was inhibited by 2-Aminopurine, a protein kinase (PKR) inhibitor, in a dose-dependent (1-10 mM) manner, suggesting that PKR may be required as a signal transducer for type I IFN signaling in fish. This Mx reporter assay may be useful for quantifying the responses and elucidating the regulation pathways of IFN type I.

Identification of novel rainbow trout (Onchorynchus mykiss) chemokines, CXCd1 and CXCd2: mRNA expression after Yersinia ruckeri vaccination and challenge

Chemokines play important roles in controlling leukocyte trafficking under normal and inflammatory conditions. Sixteen CXC chemokines have been identified in the human and mouse genomes, while considerably fewer teleost fish CXC chemokines have been reported. Here, we describe a novel clade of trout (Onchorynchus mykiss) CXC chemokines, designated Onmy CXCd, and we identify a novel gene, CXCd1, and a putative duplicate, CXCd2. The trout CXCd proteins contain 112 amino acids and the CXCd1 gene is comprised of four exons and three introns. Constitutive CXCd mRNA expression was detected in skin, gill, visceral fat, and posterior kidney tissues, while low transcript levels were present in the anterior kidney and spleen. Spleen CXCd transcript abundance increased 1 day after bath vaccination (fourfold) and subsided to basal levels by 7 days postvaccination. Challenge with viable Yersinia ruckeri induced expression of trout CXCd RNA up to ninefold in the spleen. The number of viable Y. ruckeri were significantly correlated with CXCd gene transcript abundance (P = 0.0051, Spearman correlation 0.497, n = 30 fish), and fish with the highest bacterial loads had the highest CXCd expression. In contrast, pro-inflammatory cytokine IL-1-beta2 mRNA levels were elevated in fish infected with low numbers of Y. ruckeri, while diminishing in heavily infected fish. CXCd mRNA expression was not increased in rainbow trout infected with infectious hematopoietic necrosis virus, suggesting that up-regulation may be pathogen-specific. Taken together, these results indicate that CXCd transcript elevation follows the pro-inflammatory cytokine response to Y. ruckeri and may be a relevant immunological marker of exposure.

An unexpected discovery of two interferon gamma-like genes along with interleukin (IL)-22 and -26 from teleost: IL-22 and -26 genes have been described for the first time outside mammals

By comparative genomics based on chromosome synteny between human and fish, IL-22, IL-26 and two IFN-gamma-like genes have been isolated in fish. Interleukin-22 and -26 have been identified for the first time outside of mammals and their organization and synteny demonstrates that this cluster of cytokines is well conserved during evolution. The cloned zebrafish IL-22 and -26 homologs are 161 and 169-aa long, respectively. Both the genes harbor a well-conserved IL-10-family signature in their respective C-terminus. The coding regions of these genes are spread in five exons and at the same position as in human homologs. Furthermore, surprisingly two IFN-gamma-like genes are present in tandem, 7.0 kb apart from each other, along this locus. IFN-gamma1 and 2 genes are composed of 170- and 185-aa and share a low amino acid identity of 17.0%. The genomic structures of the isolated fish IFN-gamma genes were similar to its mammalian homologs, sharing a four exon and three phase 0 introns. The presence two IFN-gamma genes in both zebra and pufferfishes demonstrate that the duplication of IFN-gamma might have occurred prior to the teleostean split. The structural homology is further validated by phylogenetic analysis showing that the isolated cytokine genes are homologous to mammalian counterparts. Expression analysis of IL-22, IL-26 and two IFN-gamma genes suggests an active role of these genes in immune responses in fish.