The interferon system of teleost fish

Interferons (IFNs) are secreted proteins, which induce vertebrate cells into an antiviral state. In mammals, three families of IFNs (type I IFN, type II IFN and IFN-lambda) can be distinguished on the basis of gene structure, protein structure and functional properties. Type I IFNs, which include IFN-alpha and IFN-beta, are encoded by intron lacking genes and have a major role in the first line of defense against viruses. The human IFN-lambdas have similar biological properties as type I IFNs, but are encoded by intron containing genes. Type II IFN is identical to IFN-gamma, which is produced by T helper 1 cells in response to mitogens and antigens and has a key role in adaptive cell mediated immunity. IFNs, which show structural and functional properties similar to mammalian type I IFNs, have recently been cloned from Atlantic salmon, channel catfish, pufferfish, and zebrafish. Teleost fish appear to have at least two type I IFN genes. Phylogenetic sequence analysis shows that the fish type I IFNs form a group separated from the avian type I IFNs and the mammalian IFN-alpha, -beta and -lambda groups. Interestingly, the fish IFNs possess the same exon/intron structure as the IFN-lambdas, but show most sequence similarity to IFN-alpha. Recently, IFN-gamma genes have also been cloned from several fish species and shown to have the same exon/intron structure as mammalian IFN-gamma genes. The antiviral effect of mammalian type I IFN is exerted through binding to the IFN-alpha/beta-receptor, which triggers signal transduction through the JAK-STAT signal transduction pathway resulting in expression of Mx and other antiviral proteins. Putative IFN receptor genes have been identified in pufferfish. Several interferon regulatory factors and members of the JAK-STAT pathway have also been identified in various fish species. Moreover, Mx and several other interferon stimulated genes have been cloned and studied in fish. Furthermore, antiviral activity of Mx protein from Atlantic salmon and Japanese flounder has recently been demonstrated.     

Molecular characterisation and expression analysis of interferon gamma in Atlantic cod (Gadus morhua)

Interferon gamma (IFN-γ) has important roles in both innate and adaptive immune responses. In this study, the cDNA and genomic sequences of Atlantic cod IFN-γ were cloned and found to encode a putative protein containing 194 amino acids with a 24 amino acid signal peptide sequence. The gene is composed of four exons and three introns similar to IFN-γ genes of other vertebrates. The cod IFN-γ showed only 14–29% amino acid identity with other fish IFN-γ and 9–17% identity with IFN-γ from higher vertebrates. However, cod IFN-γ possesses the typical IFN-γ motifs in the C-terminal end of the protein and displays an alpha-helix structure similar to mammalian IFN-γ. The promoter region contains a putative ISRE element indicating up-regulation by type I IFNs and dsRNA. Real time RT-PCR analysis confirmed that IFN-γ gene expression was up-regulated in organs of cod injected with the dsRNA polyinosinic:polycytidylic acid (poly I:C), which is a strong inducer of type I IFNs. Injection of cod with formalin-killed Vibrio anguillarum also increased IFN-γ expression in head kidney, but to a much lesser extent than poly I:C. The gene expression results thus indicate a role for IFN-γ in innate immune response against both virus and bacteria in Atlantic cod.     

Crystal structure of Zebrafish interferons I and II reveals conservation of type I interferon structure in vertebrates

Interferons (IFNs) play a major role in orchestrating the innate immune response toward viruses in vertebrates, and their defining characteristic is their ability to induce an antiviral state in responsive cells. Interferons have been reported in a multitude of species, from bony fish to mammals. However, our current knowledge about the molecular function of fish IFNs as well as their evolutionary relationship to tetrapod IFNs is limited. Here we establish the three-dimensional (3D) structure of zebrafish IFN?1 and IFN?2 by crystallography. These high-resolution structures offer the first structural insight into fish cytokines. Tetrapods possess two types of IFNs that play an immediate antiviral role: type I IFNs (e.g., alpha interferon [IFN-α] and beta interferon [IFN-β]) and type III IFNs (lambda interferon [IFN-λ]), and each type is characterized by its specific receptor usage. Similarly, two groups of antiviral IFNs with distinct receptors exist in fish, including zebrafish. IFN?1 and IFN?2 represent group I and group II IFNs, respectively. Nevertheless, both structures reported here reveal a characteristic type I IFN architecture with a straight F helix, as opposed to the remaining class II cytokines, including IFN-λ, where helix F contains a characteristic bend. Phylogenetic trees derived from structure-guided multiple alignments confirmed that both groups of fish IFNs are evolutionarily closer to type I than to type III tetrapod IFNs. Thus, these fish IFNs belong to the type I IFN family. Our results also imply that a dual antiviral IFN system has arisen twice during vertebrate evolution.     

Ⅲ型干扰素——新型抗病毒细胞因子

干扰素（IFN）是抗病毒感染的第一道防线,Ⅰ型和Ⅱ型干扰素不仅可抑制病毒,而且还能参与天然免疫反应和获得性免疫反应。最近干扰素家族增添一位新成员：Ⅲ型干扰素,即IFN-λ,因其具有类似干扰素的抗病毒活性且能诱导干扰素相关基因的表达而命名。IFN-λ受体与Ⅰ型干扰素的受体不同,但具有与Ⅰ型干扰素类似的诱导表达方式和信号转导通路,并能激活一系列相似的干扰素刺激基因。就IFN-λ家族及其受体、基因表达和信号转导机制、抗病毒作用等进行综述。     

Nucleotide sequence of channel catfish heavy chain cDNA and genomic blot analyses. Implications for the phylogeny of Ig heavy chains

Our prior analyses defined the cDNA sequence on part of the CH2 domain, the complete CH3 and CH4 domains, and the 3'-untranslated region of a catfish H chain. To complete the catfish H chain mRNA sequence, a primer-extended H chain cDNA library was constructed. Analysis of this library has resulted in the definition of full-length clones encoding a 61-bp 5' untranslated region, a 51-bp leader sequence, the V region and the complete CH1 and CH2 domains. The high similarity defined with other vertebrate V regions readily allowed the catfish sequence to be divided into FR and CDR regions. Sequence comparisons with mammalian VH and JH genes strongly suggest that the catfish V region is the product of multiple genes. Using a catfish VH cDNA probe, at least 25 different genomic VH members were defined. Because this probe does not hybridize with other full-length H chain cDNA clones, additional VH families will likely be defined in catfish. Phylogenetic sequence comparisons of the catfish C region domains indicated that the CH1 and CH4 were the most highly conserved. In addition several important features were defined in genomic Southern blot analyses of catfish DNA. Gene titration experiments established that the catfish CH gene is represented by a single genomic copy. This finding provides clear evidence that the genomic organization of H chain genes in catfish must be different from that defined in sharks and suggests that the phylogeny of single copy CH genes may have been established at the level of the bony fishes. It is also likely that there is an additional CH gene in catfish. This gene is also represented by a single genomic copy, and based upon its relative signal intensity when compared with the known CH gene it appears to share higher similarity with the known CH1 domain than it does with the CH2 domain.     

The GRIMs: a new interface between cell death regulation and interferon/retinoid induced growth suppression

Cytokines and vitamins play a central role in controlling neoplastic cell growth. The interferon (IFN) family of cytokines regulates antiviral, anti-tumor, antimicrobial, differentiation, and immune responses in mammals. Significant advances have been made with respect to IFN-induced signal transduction pathways and antiviral responses. However, the IFN-induced anti-tumor actions are poorly defined. Although IFNs themselves inhibit tumor growth, combination of IFNs with retinoids (a class of Vitamin A related compounds) strongly potentiates the IFN-regulated anti-tumor action in a number of cell types. To define the molecular mechanisms involved in IFN/retinoid (RA)-induced apoptosis we have employed a genetic approach and identified several critical genes. In this review, I provide the current picture of IFN- RA- and IFN/RA-regulated growth suppressive pathways. In particular, I focus on a novel set of genes, the genes-associated with retinoid-interferon induced mortality (GRIM). GRIMs may be novel types of tumor suppressors, useful as biological response markers and potentially novel targets for drug development.     

Reversible inhibition of murine cytomegalovirus replication by gamma interferon (IFN-γ) in primary macrophages involves a primed type I IFN-signaling subnetwork for full establishment of an immediate-early antiviral state

Activated macrophages play a central role in controlling inflammatory responses to infection and are tightly regulated to rapidly mount responses to infectious challenge. Type I interferon (alpha/beta interferon [IFN-α/β]) and type II interferon (IFN-γ) play a crucial role in activating macrophages and subsequently restricting viral infections. Both types of IFNs signal through related but distinct signaling pathways, inducing a vast number of interferon-stimulated genes that are overlapping but distinguishable. The exact mechanism by which IFNs, particularly IFN-γ, inhibit DNA viruses such as cytomegalovirus (CMV) is still not fully understood. Here, we investigate the antiviral state developed in macrophages upon reversible inhibition of murine CMV by IFN-γ. On the basis of molecular profiling of the reversible inhibition, we identify a significant contribution of a restricted type I IFN subnetwork linked with IFN-γ activation. Genetic knockout of the type I-signaling pathway, in the context of IFN-γ stimulation, revealed an essential requirement for a primed type I-signaling process in developing a full refractory state in macrophages. A minimal transient induction of IFN-β upon macrophage activation with IFN-γ is also detectable. In dose and kinetic viral replication inhibition experiments with IFN-γ, the establishment of an antiviral effect is demonstrated to occur within the first hours of infection. We show that the inhibitory mechanisms at these very early times involve a blockade of the viral major immediate-early promoter activity. Altogether our results show that a primed type I IFN subnetwork contributes to an immediate-early antiviral state induced by type II IFN activation of macrophages, with a potential further amplification loop contributed by transient induction of IFN-β.     

Amino acid differences in interferon-tau (IFN-τ) of Bos taurus Coreanae and Holstein

Interferons (IFNs) are commonly grouped into type I and type II IFN. Type I IFNs are known as antiviral IFNs including IFN-α, IFN-β, and IFN-ω whereas type II IFN is referred to immune IFN and IFN-γ is only member of the type II IFN. Type I IFNs are induced by virus invading however type II IFN is produced by mitogenic or antigenic stimuli. IFN-τ was first identified in ruminant ungulates as a pregnancy recognition hormone, trophoblastin. IFN-τ constitutes a new class of type I IFN, which possesses the common features of type I IFN, such as the ability to prevent viral infection and to limit cell proliferation. In addition, IFN-τ is unique in that it is induced by pregnancy unlike other type I IFNs. We cloned Bos taurus (B. T.) Coreanae IFN-τ from peripheral blood mononuclear cells. The amino acid sequence of B. T. Coreanae IFN-τ shares only 90.3% identity with that of Holstein dairy cow. Recombinant B. T. Coreanae and Holstein IFN-τ proteins were expressed in Escherichia coli and the antiviral activity of IFN-τ proteins were examined. Both recombinant proteins were active and protected human WISH and bovine MDBK cells from the cytopathic effect of vesicular stomatitis virus. The recombinant IFN-τ protein of B. T. Coreanae and Holstein properly induced the expression of antiviral genes including 2',5'-oligoadenylate synthetase (OAS) and Mx GTPase 1 (Mx-1).     

Molecular cloning and characterization of an interferon induced human cDNA with sequence homology to a mammalian peptide chain release factor.

Here we report the molecular cloning of several related human cDNAs from which a full-length sequence can be determined. The cDNAs encode a 2.8 kb mRNA that is strongly induced by interferon (IFN) gamma and the expression of which is not cell-restricted but observed in fibroblasts, macrophages and epithelial cells. The deduced amino acid sequence predicts a protein of 471 amino acids with high sequence similarity to a previously identified rabbit peptide chain release factor. Functional studies to demonstrate release factor activity showed that the protein encoded by this cDNA inhibited the readthrough activity of a yeast UGA suppressor tRNA in an in vitro translation system. The identification of this novel cDNA implies that translational control by IFN induced proteins may not be restricted to the initial steps of protein synthesis but may also act by regulation of peptide chain termination.     

Herpesviruses and the Type Ⅲ Interferon System

Type Ⅲ interferons (IFNs) represent the most recently discovered group of IFNs.Together with type Ⅰ IFNs (e.g.IFN-α/β),type Ⅲ IFNs (IFN-λ) are produced as part of the innate immune response to virus infection,and elicit an anti-viral state by inducing expression of interferon stimulated genes (ISGs).It was initially thought that type Ⅰ IFNs and type Ⅲ IFNs perform largely redundant functions.However,it has become evident that type Ⅲ IFNs particularly play a major role in antiviral protection of mucosal epithelial barriers,thereby serving an important role in the first-line defense against virus infection and invasion at contact areas with the outside world,versus the generally more broad,potent and systemic antiviral effects of type Ⅰ IFNs.Herpesviruseses are large DNA viruses,which enter their host via mucosal surfaces and establish lifelong,latent infections.Despite the importance of mucosal epithelial cells in the pathogenesis of herpesviruses,our current knowledge on the interaction of herpesviruses with type Ⅲ IFN is limited and largely restricted to studies on the alphaherpesvirus herpes simplex virus (HSV).This review summarizes the current understanding about the role of IFN-λ in the immune response against herpesvirus infections.     

Cloning and sequence analysis of channel catfish heavy chain cDNA indicate phylogenetic diversity within the IgM immunoglobulin family

Catfish cDNA libraries were constructed using the poly(A+) RNA obtained from in vitro stimulated catfish leukocytes. Antigenic analysis with different antisera to catfish Ig resulted in the definition of cDNA clones encoding the catfish H chain. Sequence analysis confirmed that the catfish H chain was definitively identified, based on its similarities with chicken and mouse mu chains. Two clones were each shown to encode part of the CH2 domain, the complete CH3 and CH4 domains, the C-terminus, and a 184-bp 3' untranslated region before the poly(A+) tail. The conservation of domain size and structure is clearly evident. The two cysteines forming the intradomain disulfide bridge, as well as the tryptophans located within each domain, are absolutely conserved. There are four carbohydrate acceptor sites in the catfish H chain, only one of which is phylogenetically conserved. Of the six sequenced H chain clones, one was found to differ in a single base in the CH3, which results in the loss of a carbohydrate acceptor site. Whether this difference indicates isotypic variation between closely related genes or somatic mutation is unresolved. Amino acid sequence comparisons indicate that there is a approximately 24% similarity when the catfish H chain is aligned with mouse mu chains. This is considerably less than the approximately 40% amino acid conservation found between the chicken and mouse mu chain. The amino acid sequence of the catfish H chain is most conserved in the C-terminus (approximately 30%) and the CH4 (approximately 26%); there is less conservation in the CH3 (approximately 20%) when comparisons are made with mouse mu chain. The CH3 domain of the catfish H chain also has different hydropathy properties, when compared with the CH3 domain of the higher vertebrate mu chains. Finally, the sequence of the catfish H chain indicates an unusual arrangement of the cysteines that likely participate in intersubunit and inter-H chain disulfide linkages. The disulfide linkage of these cysteines during Ig polymerization may account for the unusual covalent architecture associated with the catfish tetramer.     

Poly I:C inhibits the expression of channel catfish virus immediate-early gene ORF 1 at early times after infection

Channel catfish virus (CCV) is a herpesvirus that infects channel catfish fry and fingerlings. Previous research has demonstrated that Type I interferons inhibit the expression of immediate-early (IE) genes of some mammalian herpesviruses. However, CCV is distantly related to the mammalian herpesviruses and Type I interferons from higher vertebrates exhibit only 20% similarity to fish interferons. In this work we demonstrate that treatment of channel catfish ovary (CCO) cells, a fibroblast-like cell line, with poly I:C, a known inducer of Type I interferons, results in inhibition of expression of the CCV IE gene ORF 1. Thus, although the genes involved have diverged, the mechanism appears to be conserved. If this paradigm holds true for other CCV IE-Type I interferon interactions, it could have important implications for the impact of CCV on the host immune system.     

A rat beta-interferon-induced mRNA: sequence characterization.

Polymerase chain reaction amplification of a cDNA derived from rat aortic smooth muscle cells, using sequences from conserved regions of the intramembrane domains of adrenergic receptors as primers, yielded the clone, rat8. This clone possesses a high degree of sequence similarity to a series of human interferon (IFN)-inducible genes. The rat8 sequence is 70% similar to that derived from the human alpha-IFN-induced gene, 9-27; there is 66% similarity between the deduced amino acid sequences encoded by the rat and the human genes. The rat homologue hybridizes with many bands in Southern analysis of rat DNA, suggesting that it is a member of a large multigene family.