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.     

Anti-viral effects of interferon administration on sevenband grouper, Epinephelus septemfasciatus

Interferon (IFN) plays crucial roles in innate immune responses against viral infections. In the present study, we report cloning and characterization of the IFN gene from the sevenband grouper (Epinephelus septemfasciatus), and the anti-viral effects of its recombinant IFN protein in vivo. The isolated cDNA from sevenband grouper IFN encoded a protein consisting of 178 amino acids, and its first 22 amino acids represented a putative signal peptide. We named the identified sevenband grouper IFN gene as SgIFNa1 based on the result from phylogenetic analysis that categorized the deduced protein sequence into fish IFNa family. The expression of SgIFNa1 mRNA in the head kidney cells was induced by synthetic Poly(I:C), which is known as an inducer of IFN. It has also been confirmed that injection of recombinant SgIFNa1 protein (rSgIFNa1) upregulates expression of the Mx gene, which is known as an IFN-responsive gene, in head kidney cells. Moreover, we observed that preliminarily injection of rSgIFNa1 provided significant protection against a lethal challenge of nervous necrosis virus (NNV), which is a serious disease of sevenband grouper. These results demonstrate that SgIFNa1 has anti-viral activity and the administration of rSgIFNa1 to sevenband grouper is effective in preventing severe symptom development after NNV infection.     

Cloning and expression analysis of Mx cDNA from Senegalese sole (Solea senegalensis)

Senegalese sole (Solea senegalensis) is a promising fish species of growing interest in European aquaculture. In fish farming, viral infections are a constant threat therefore, understanding fish defence mechanisms is a main priority to avoid economic losses. Mx proteins are involved in the innate antiviral response of fish. They are induced by type I interferons (alpha and beta) and are essential to investigate viral defence mechanisms in fish, due to the difficulty in tracking interferon activity in these species. In this study a full-length Senegalese sole Mx cDNA has been RT-PCR cloned, resulting in 2322bp coding for 623 amino acids. The sequence accounts for the main characteristics of Mx proteins but lacking nuclear localisation signal (NLS), which suggests cytoplasmic localisation. The alignments of Senegalese sole Mx sequence showed the highest identity with the flatfish species, 80.1% identity with flounder and 78.9% with halibut. The spatial and temporal expression pattern has been analysed in control and challenged fish by RT-PCR. In control fish a constitutive level of sole Mx expression has been obtained and a clear induction was observed after treatment with Poly[I:C], which supports a putative role for the Mx in Senegalese sole viral defence. These findings contribute to increasing the knowledge of the role of interferon pathway in fish innate immunity and to develop new tools to fight virus infections in the culture of this species.     

Induction of Mx protein by interferon and double-stranded RNA in salmonid cells

Mx protein is one of several antiviral proteins that are induced by the type I interferons (IFN), IFNalpha and beta, in mammals. In this work induction of a 76 kDa Mx protein by double-stranded RNA (dsRNA) or type I IFN-like activity in Atlantic salmon macrophages, Atlantic salmon fibroblast cells (AS cells) and in Chinook salmon embryo cells (CHSE-214) is reported. Type I IFN-like activity was produced by the stimulation of Atlantic salmon macrophages with the synthetic dsRNA polyinosinic polycytidylic acid (poly I:C). A correlation appeared to exist between Mx protein expression and protection against infectious pancreatic necrosis virus (IPNV) induced by IFN in CHSE-214 cells. Several observations in the present work suggest that, as in mammals, the induction of Mx protein by dsRNA in fish cells primarily occurs via induction of type I IFN. First, type I IFN-like activity but not poly I:C, induced Mx protein expression in CHSE-214 cells. These cells apparently lack the ability to produce IFN in response to poly I:C. Second, the putative IFN induced maximal Mx protein expression 48 h earlier than poly I:C in AS cells. Third, the peak expression of Mx protein in macrophages induced by poly I:C occurred after 48 h whereas peak in IFN-like activity was observed by 24 h after addition of poly I:C. The present work supports the notion of using Mx protein as a molecular marker for the production of putative type I IFN in fish.     

鲫Nub1基因的克隆及特征分析

Nub1(NEDD8 Ultimate Buster-1)是近年来发现的一种干扰素诱导表达基因,过量表达该基因能抑制细胞生长。研究通过RACE-PCR方法从产生干扰素的鲫囊胚培养细胞(Carassius auratus blastulae embryonic cells,CAB)中克隆出鲫Nub1基因。鲫Nub1全长cDNA为2298bp,编码一个由589个氨基酸残基组成的蛋白。推导的鲫NUB1蛋白具有哺乳类同源蛋白保守的结构域,包括N端的UBL结构域和C端两个UBA结构域,与已知的哺乳类包括人和小鼠、鸟类和两栖类的同源蛋白具有41%-45%的相似性。诱导表达分析显示PolyI:C和LPS均能诱导CAB细胞Nub1mRNA的上调,表明Nub1基因在鱼类的抗病免疫反应中发挥某种重要作用。       

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.     

斑马鱼一个IFIT 家族基因的鉴定及启动子分析

IFIT 家族由一类受干扰素诱导表达并具有TPR 结构域的蛋白组成, 但是在鱼类关于IFIT 基因的研究还很少。研究利用哺乳类IFIT 家族基因IFI56 的序列搜索斑马鱼基因组数据库鉴定出一个未知基因, 该基因具有哺乳类IFIT 家族保守的基因组结构, 编码蛋白具有保守的TPR 结构域, 暂命名为IFIT-A。RT-PCR 分析表明, Poly I:C 能够诱导IFIT-A 基因转录水平上调。与哺乳类IFIT 家族基因相似, 斑马鱼IFIT-A 启动子存在ISG 基因特有的典型ISRE 结构域。荧光素酶活性实验揭示Poly I:C 和重组IFN 蛋白能激活斑马鱼IFIT-A 启动子活性。此外, 过量表达IFN 调控因子IRF3 和IRF7 能诱导斑马鱼IFIT-A 启动子活性。实验结果证明IFIT-A基因是斑马鱼IFIT 家族成员, IRF3 和IRF7 在其诱导表中具有重要调控作用。       

干扰素诱导的鱼类Mx蛋白

Mx蛋白是干扰素诱导表达的蛋白家族中的成员,当机体和细胞受病毒感染或诱生剂处理时产生。Mx蛋白和其它干扰素诱导蛋白一起构成宿主细胞的抗病毒状态,以达到抗病毒的目的。研究表明,Mx蛋白具有抗病毒活性,还可能与其它基本生命活动如发育或分化,蛋白质分送和生长有关。在鱼类也发现多种Mx蛋白,具有Mx蛋白家族的共有特征;在肽链末端有一个三联ATP／GTP结合区和发动蛋白家族的结构特征序列;在蛋白C端存在使Mx蛋白形成三聚体的Leu拉链结构以及定位信号。但是迄今没有发现鱼类Mx蛋白的抗病毒活性。文章最后对目前鱼类病毒病的防治及利用抗病毒基因进行鱼类基因工程抗病毒育种进行了探讨。     

First report of invertebrate Mx: cloning, characterization and expression analysis of Mx cDNA in disk abalone (Haliotis discus discus)

Myxovirus resistance (Mx) protein is one of the most studied antiviral proteins. It is induced by the type I interferon system (IFN alpha/beta) in various vertebrates, but its expression has not been identified or characterized in mollusks or other multi-cellular invertebrates to date. In this study, we isolated the Mx gene from a disk abalone (Haliotis discus discus) normalized cDNA library. Mx cDNA was sequenced, cloned and compared to other known Mx proteins. The full-length 1664 bp of abalone Mx cDNA contained a 1533-bp open reading frame that codes for 511 amino acids. Within the coding sequence of abalone Mx, characteristic features were found, such as a tripartite guanosine-5'-triphosphate (GTP)-binding motif and a dynamin family signature. In addition, leucine residues in the C-terminal region displayed a special leucine domain at L(468), L(475), L(489) and L(510), suggesting that abalone Mx may have a similar oligomerization function as other leucine zipper motifs. Abalone Mx protein exhibited 44% amino acid similarity with channel catfish Mx1, rainbow trout Mx2 and Atlantic halibut Mx. Abalones were injected intramuscularly with the known IFN inducer poly I:C and RT-PCR was performed for Mx mRNA analysis. The results showed enhanced Mx expression in abalone gill and digestive tissues 24h as well as 48 h after injection of poly I:C. Mx mRNA was expressed in gill, digestive gland, mantle and foot tissues in healthy abalone, suggesting that the basal level of Mx expressed is tissue-specific. There is no known Mx protein closely related to abalone Mx according to phylogenetic analysis. Abalone Mx may have diverged from a common gene ancestor of fish and mammalian Mx proteins, since abalone Mx showed high similarity in terms of conserved tripartite GTP-binding, dynamin family signature motifs and poly I:C enhancement of Mx mRNA expression.     

Monosaccharide uptake in common carp (Cyprinus carpio) EPC cells is mediated by a facilitative glucose carrier

In most animal cells, transport of monosaccharides across the plasma membrane is mediated by glucose transporters (GLUT). Mammals express at least five distinct transporters (GLUTs 1--5), which are well characterised both functionally and genetically. In contrast, the glucose transport system of fish remains poorly studied. Here we report studies of hexose uptake in carp EPC cells and cloning of a glucose transporter cDNA from these cells. Transport of radio-labelled methylglucose (3-OMG) followed Michaelis--Menten kinetics with a K(m) value (8.5 mM) similar to that of mammalian cells. The inhibition of transport by cytochalasin B and phloretin, but not by phloridzin or cyanide, strongly suggested the existence of a facilitative carrier. D-Glucose, 2-deoxyglucose, 3-OMG, D-mannose and D-xylose were competitive inhibitors of 3-OMG uptake, while L-glucose, mannitol, D-fructose, D-ribose and sucrose did not compete with 3-OMG. We cloned a carp glucose transporter (CyiGLUT1), using RT-PCR and RACE strategies. CyiGLUT1 was different from known carp and zebrafish EST sequences. The complete cDNA (3060 bp) contained one open reading frame encoding a predicted protein of 478 amino acids. The deduced amino acid sequence shared 78% identity with mammalian and avian GLUT1 proteins. Key amino acids involved in substrate selection and catalysis of mammalian GLUTs were conserved in the carp transporter.     

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.