The catfish liver-expressed antimicrobial peptide 2 (LEAP-2) gene is expressed in a wide range of tissues and developmentally regulated

Antimicrobial peptides (AMPs) are important components of the host's innate immune response against microbial invasion. The cysteine-rich AMPs such as defensin and hepcidin have been extensively studied, but the recently identified cysteine-rich liver-expressed antimicrobial peptide 2 (LEAP-2) has been characterized from only a few organisms. Here we cloned and sequenced the LEAP-2 cDNAs from both Channel catfish and Blue catfish. The LEAP-2 gene from Channel catfish was also sequenced and characterized. Channel catfish LEAP-2 gene consists of two introns and three exons that encode a peptide of 94 amino acids with a 28 amino acid signal peptide and a mature peptide of 41 amino acids. The amino acid sequences and gene organization were conserved between catfish and other organisms. The Channel catfish LEAP-2 gene is expressed in a wide range of tissues except brain and stomach. Its expression is developmentally regulated with no detection of mature mRNA in early stages of development. It appears that the catfish LEAP-2 gene is regulated at the level of splicing; it is constitutively transcribed, but remains unspliced until 6 days after hatching. The expression of LEAP-2 was induced in a tissue-specific manner. Its expression was upregulated in the spleen, but not in the liver and head kidney, after challenge with Edwardsiella ictaluri, the causative agent of enteric septicemia of catfish (ESC).     

The two channel catfish intelectin genes exhibit highly differential patterns of tissue expression and regulation after infection with Edwardsiella ictaluri

Intelectins (IntL) are Ca(2+)-dependent secretory glycoproteins that play a role in the innate immune response. The mammalian IntL is also known as lactoferrin receptor (LfR) that is involved in iron metabolism. The objective of this study was to characterize the intelectin genes in both channel catfish and blue catfish, to determine their genomic organization and copy numbers, to determine their patterns of tissue expression, and to establish if they are involved in defense responses of catfish after bacterial infection. Two types of IntL genes have been identified from catfish, and IntL2 was completely sequenced. The genomic structure and organization of IntL2 were similar to those of the mammalian species and of zebrafish and grass carp, but orthologies cannot be established with mammalian IntL genes. The IntL genes are highly conserved through evolution. Sequence analysis also indicated the presence of the fibrinogen-related domain in the catfish IntL genes, suggesting their structural conservations. Phylogenetic analysis suggested the presence of at least two prototypes of IntL genes in teleosts, but only one in mammals. The catfish IntL genes exhibited drastically different patterns of expression as compared to those of the mammalian species, or even with the grass carp gene. The catfish IntL1 gene is widely expressed in various tissues, whereas the channel catfish IntL2 gene was mainly expressed in the liver. While the catfish IntL1 is constitutively expressed, the catfish IntL2 was drastically induced by intraperitoneal injection of Edwardsiella ictaluri and/or iron dextran. Such induction was most dramatic when the fish were treated with both the bacteria and iron dextran. While IntL1 was expressed in all leukocyte cell lines, no expression of IntL2 was detected in any of the leukocyte cell lines, suggesting that the up-regulated channel catfish IntL2 expression after bacterial infection may be a consequence of the initial immune response, and/or a downstream immune response rather than a part of the primary immune responses.     

Identification,phylogeny and expression analysis of suppressors of cytokine signaling in channel catfish

The suppressors of cytokine signaling (SOCS) family genes play important roles in regulating a variety of signal transduction pathways that are involved in immunity, growth and development. Because of their importance, they have been extensively studied in mammalian species, but they have not been systematically studied among teleost fish species. In this study, a total of 12 SOCS genes were characterized to understand the molecular mechanisms of SOCS function in channel catfish. Phylogenetic analyses suggested that all SOCS were clustered into two main clusters. Further syntenic analysis confirmed the phylogenetic analyses and allowed the annotation of SOCS genes in channel catfish. This work, for the first time, determined the expression profiles of the 12 SOCS genes after bacterial infections with Flavobacterium columnare and Edwardsiella ictaluri in channel catfish. The SOCS1a and SOCS3a were significantly up-regulated at 4 h after F. columnare challenge in the gill, but were down-regulated at later stages of pathogenesis. Similarly, SOCS1a and CISH were significantly up-regulated at 3 h in intestine under E. ictaluri infection, but were down-regulated at later stages of pathogenesis at 24 h and 3 days after infection. These expression patterns may indicate that SOCS genes could be induced in acute immune responses after bacterial infections, but the massive cytokine expression, especially chemokine expression after the first day of infection may have had negative feedback leading to the overall down-regulation of the expression of SOCS genes. Moreover, the differential expression patterns of SOCS genes in the catfish gill and intestine after F. columnare and E. ictaluri infection demonstrated that the regulation of SOCS gene expression was both tissue-specific and time-dependent. Taken together, these results suggested that SOCS genes were involved in immune responses to bacterial invasions, and these results set the foundation for future studies of SOCS gene functions.     

l-Rhamnose-binding lectins (RBLs) in channel catfish, Ictalurus punctatus: Characterization and expression profiling in mucosal tissues

Rhamnose-binding lectins (RBLs) have recently emerged as important molecules in the context of innate immunity in teleost fishes. Previously, using RNA-seq technology, we observed marked up-regulation of a RBL in channel catfish (Ictalurus punctatus) gill following a challenge with the bacterial pathogen Flavobacterium columnare. Furthermore, the magnitude of RBL up-regulation positively correlated with disease susceptibility. Moving forward from these findings, we wished to more broadly understand RBL function, diversity, and expression kinetics in channel catfish. Therefore, in the present study we characterized the RBL gene family present in select channel catfish tissues and profiled family member expression after challenge with two different Gram-negative bacterial pathogens. Here, six RBLs were identified from channel catfish and were designated IpRBL1a, IpRBL1b, IpRBL1c, IpRBL3a, IpRBL3b, and IpRBL5a. These RBLs contained carbohydrate recognition domains (CRD) ranging from one to three domains and each CRD contained the conserved motifs of –YGR- and –DPC-. Despite a level of structural conservation, the catfish RBLs showed low full-length identity with RBLs from outside the order Siluriformes. IpRBL expression after bacterial infection varied depending on both pathogen and tissue type, suggesting that IpRBLs may exert disparate functions or exhibit distinct tissue-selective roles in the host immune response to bacterial pathogens.     

Porcine liver-expressed antimicrobial peptides, hepcidin and LEAP-2: cloning and induction by bacterial infection

Hepcidin is a liver-expressed iron-regulating hormone that also is an antimicrobial peptide. Here we report the full-length cDNA sequences of porcine hepcidin and liver-expressed antimicrobial peptide-2 (LEAP-2). Porcine hepcidin and LEAP-2 cDNA sequences contain 411 and 525 bp, and encode predicted peptides of 82 and 77 amino acid residues, respectively. Both porcine hepcidin and LEAP-2 are highly expressed in liver and LEAP-2 also is expressed in intestinal tissues and kidney. Pigs infected with Salmonella enterica serovar Typhimurium showed inducible but differential expression of hepcidin and LEAP-2 in bone marrow and intestinal tissues. Conversely, although highly expressed in liver, expression of hepcidin mRNA in liver was not influenced by Salmonella infection. These findings provide fundamental comparative data showing the relationship of porcine hepcidin and LEAP-2 to other mammalian orthologs and indicate that bacterial infections influence their expression.     

Expression of nitric oxide synthase (NOS) genes in channel catfish is highly regulated and time dependent after bacterial challenges

Nitric oxide is well known for its roles in immune responses. As such, its synthesizing enzymes have been extensively studied from various species including some teleost fish species. However, the NOS genes have not been characterized in channel catfish (Ictalurus punctatus). In this study, we identified and characterized three NOS genes including one NOS1 and two NOS2 genes in channel catfish. Comparing with the NOS genes from other fish species, the catfish NOS genes are highly conserved in their structural features. Phylogenetic and syntenic analyses allowed determination of NOS1 and NOS2 genes of channel catfish and their orthology relationships. Syntenic analysis, as well as the phylogenetic analysis, indicated that the two NOS2 genes of catfish were lineage-specific duplication. The NOS genes were broadly expressed in most tested tissues, with NOS1 being expressed at the highest levels in the brain, NOS2b1 highly expressed in the skin and gill, and NOS2b2 lowly expressed in most of the tested tissues. The most striking findings of this study was that the expression of the NOS genes are highly regulated after bacterial infection, with time-dependent expression patterns that parallel the migration of macrophages. After Edwardsiella ictaluri challenge, dramatically different responses among the three NOS genes were observed. NOS1 was only significantly in the skin early after infection, while NOS2b1 was rapidly upregulated in gill, but more up-regulated in trunk kidney with the progression of the disease, suggesting such differences in gene expression may be reflective of the migration of macrophages among various tissues of the infected fish. In contrast to NOS1 and NOS2b1, NOS2b2 was normally expressed at very low levels, but it is induced in the brain and liver while significantly down-regulated in most other tissues.     

Genomic organization, gene duplication, and expression analysis of interleukin-1beta in channel catfish (Ictalurus punctatus)

Interleukin-1beta (IL-1beta) is one of the pivotal early response pro-inflammatory cytokines that enables organisms to respond to infection and induces a cascade of reactions leading to inflammation. In spite of its importance and two decades of studies in the mammalian species, genes encoding IL-1beta were not identified from non-mammalian species until recently. Recent research, particularly with genomic approaches, has led to sequencing of IL-1beta from many species. Clinical studies also suggested IL-1beta as an immunoregulatory molecule potentially useful for enhancing vaccination. However, no IL-1beta genes have been identified from channel catfish, the primary aquaculture species from the United States. In this study, we identified two distinct cDNAs encoding catfish IL-1beta. Their encoding genes were identified, sequenced, and characterized. The catfish IL-1beta genes were assigned to bacterial artificial chromosome (BAC) clones. Genomic studies indicated that the IL-1beta genes were tandemly duplicated on the same chromosome. Phylogenetic analysis of various IL-1beta genes indicated the possibility of recent species-specific gene duplications in channel catfish, and perhaps also in swine and carp. Expression analysis indicated that both IL-1beta genes were expressed, but exhibited distinct expression profiles in various catfish tissues, and after bacterial infection with Edwardsiella ictaluri.     

Molecular responses of calreticulin genes to iron overload and bacterial challenge in channel catfish (Ictalurus punctatus)

Infection and inflammation are often accompanied by oxidative stress caused by the accumulation of reactive oxygen species which can be deleterious to the health of the host. Antioxidant defense mechanisms and components are crucial in limiting cellular and tissue-level damage and restoring homeostasis. In mammals, calreticulin is a 46-kDa multifunctional calcium binding protein of the endoplasmic reticulum that has many critical functions in the eukaryotic cell including regulation of intracellular calcium homoeostasis, lectin binding and chaperoning, and oxidative stress responses. In previous studies from our lab, the calreticulin gene was observed to be strongly upregulated in catfish during challenge with infectious Gram-negative bacteria. However, little is known about the function of this gene in teleost fish. The objective of this study, therefore, was to characterize the calreticulin gene from channel catfish, to determine its genomic organization, to profile its patterns of tissue expression, and to establish its potential for physiological antioxidant and immune responses in catfish after bacterial infection with Edwardsiella ictaluri and iron treatment. Our results indicate that there are at least three calreticulin related genes in the catfish genome. The three calreticulin genes are widely expressed in various tissues under homeostatic conditions and their expression showed significant upregulation following infection and/or iron level changes.     

Organization and expression analysis of the zebrafish hepcidin gene, an antimicrobial peptide gene conserved among vertebrates

Hepcidin is an antimicrobial peptide and iron-regulatory molecule that is conserved among vertebrates. Mutations or over-expression of the human hepcidin gene have been found in patients with hemochromatosis and refractory anemia. To further understand the function and regulation of hepcidin, animal models are needed. We sequenced cDNA, genes and upstream regions of zebrafish hepcidin and analyzed gene expression by kinetic PCR. Zebrafish hepcidin genes consist of two introns and three exons that encode a prepropeptide (91 amino acids). The amino acid sequences and gene organization were remarkably conserved between zebrafish and other species. Elevated gene expression was observed in abdominal organs, skin, and heart in fish that developed signs of infection following bacterial injection. Zebrafish may be a suitable model organism for further study of hepcidin gene regulation.     

Constitutive expression of three novel catfish CXC chemokines: homeostatic chemokines in teleost fish

Chemokines are best known for their vital role in leukocyte chemotaxis, as part of the larger inflammatory response. Expression analysis and functional characterization of chemokines in mammalian species have often overlooked the role of these proteins under homeostatic conditions. Recent investigations of chemokine diversity in teleost fish have also centered on the immune-related functions of chemotactic cytokines, such as CXCL8 and CXCL10. While a disease-based approach to chemokines is essential to the development of remediative therapies for both human and animal infections, it may be a poor measure of the overall complexity of chemokine functions. As part of a larger effort to assess the conservation of chemokine diversity in teleost fish, we report here the identification of three novel, constitutively expressed CXC chemokines from channel catfish (Ictalurus punctatus). Phylogenetic analyses indicated that two of the three CXC chemokines were orthologues for mammalian CXCL12 and CXCL14, respectively. Whereas a clear orthology could not yet be established for the third CXC chemokine, it shared highest amino acid identity with mammalian CXCL2. All three CXC chemokines show expression in a wide range of tissues, and early expression during development was observed for CXCL12. The expression of this new set of catfish CXC chemokines was not induced during challenge by infection of Edwardsiella ictaluri, the causative agent of the fish pathogen enteric septicemia of catfish. In contrast to the gene duplication of CXCL12 in carp and zebrafish, Southern blot analysis indicated that all three catfish CXC chemokines exist as single copy genes in the catfish genome suggesting that gene duplication of CXC chemokines in specific teleost fish was a recent evolutionary event.     

The CC and CXC chemokine receptors in channel catfish (Ictalurus punctatus) and their involvement in disease and hypoxia responses

Chemokines are vital regulators of cell mobilization for immune surveillance, inflammation, and development. Chemokines signal through binding to their receptors that are a superfamily of seven-transmembrane domain G-coupled receptors. Recently, a complete repertoire of both CC and CXC chemokines have been identified in channel catfish, but nothing is known about their receptors. In this study, a set of 29 CC chemokine receptor (CCR) genes and 8 CXC chemokine receptor (CXCR) genes were identified and annotated from the channel catfish genome. Extensive phylogenetic and comparative genomic analyses were conducted to annotate these genes, revealing fish-specific CC chemokine receptors, and lineage-specific tandem duplications of chemokine receptors in the teleost genomes. With 29 genes, the channel catfish genome harbors the largest numbers of CC chemokine receptors among all the genomes characterized. Analysis of gene expression after bacterial infections indicated that the chemokine receptors were regulated in a gene-specific manner. Most differentially expressed chemokine receptors were up-regulated after Edwardsiella ictaluri and Flavobacterium columnare infection. Among which, CXCR3 and CXCR4 were observed to participate in immune responses to both bacterial infections, indicating their potential roles in catfish immune activities. In addition, CXCR3.2 was significantly up-regulated in ESC-susceptible fish, and CXCR4b was mildly induced in ESC-resistant fish, further supporting the significant roles of CXCR3 and CXCR4 in catfish immune responses. CXCR4b and CCR9a were both up-regulated not only after bacterial infection, but also after hypoxia stress, providing the linkage between bacterial infection and low oxygen stresses. These results should be valuable for comparative immunological studies and provide insights into their roles in disease and stress responses.     

Identification,annotation and expression analysis of 29 Rho GTPase genes from channel catfish (Ictalurus punctatus) after bacterial infections

The Rho family GTPases are a group of small monomeric G proteins, which are molecular switches in signaling pathways. They have been known to regulate a diverse range of cellular processes including actin cytoskeleton rearrangement and microtubule dynamics. In particular, their participations in immune responses are also significant. However, little information of the Rho GTPases is available in teleost including channel catfish, an economically important species and one of the best teleost models forimmunological research. In this study, Rho GTPase genes were identified from channel catfish and well annotated by phylogenetic and syntenic analyses. Their expression profiles were determined in channel catfish healthy tissues and infected tissues. Altogether seven Rho GTPase genes were significantly regulated after bacterial infection, with six genes in the gill after Flavobacterium columnare challenge and two genes in the intestine in response to Edwardsiella ictaluri. All the differentially expressed genes were up-regulated soon after bacterial infection. Different expression patterns between the two experiments were observed, which may be attributed to tissue-specific regulation or pathogen-specific regulation. These results suggested that Rho GTPases play important roles in immune responses to bacterial pathogens, setting a foundation for future investigation on Rho GTPases.