The molecular identification of factor H and factor I molecules in rainbow trout provides insights into complement C3 regulation.

The complement system in vertebrates plays a crucial role in the elimination of pathogens. To regulate complement on self-tissue and to prevent spontaneous activation and systemic depletion, complement is controlled by both fluid-phase and membrane-bound inhibitors. One such inhibitor, complement factor I (CFI) regulates complement by proteolytic cleavage of components C3b and C4b in the presence of specific cofactors. Complement factor H (CFH), the main cofactor for CFI, regulates the alternative pathway of complement activation by acting in the breakdown of C3b to iC3b. To gain further insight into the origin of C3 regulation in bony fish we have cloned and characterized the CFI and CFH1 cDNAs in the rainbow trout (Oncorhynchus mykiss). In this study we report the primary sequence, the tissue expression profile, the polypeptide domain architecture and the phylogenetic analysis of trout CFI and CFH1 genes. The deduced amino acid sequences of trout CFI and CFH1 polypeptides exhibit 42% and 32% identity with human orthologs, respectively. RNA expression analysis showed that CFI is expressed differentially in trout tissues, while liver is the main source of CFH1 expression. Our data indicate that factor H and I genes have emerged during evolution as early as the divergence of teleost fish.

CR3 complement receptor: cloning and characterization in rainbow trout.

The beta 2 integrin CR3 is a leukocyte adhesion heterodimeric glycoprotein which functions both as receptor for iC3b and in several cell-cell and cell-substrate adhesion interactions. In order to elucidate the molecular evolution of the CR3 receptor, here we report the cloning and characterization of its beta2 (CD18) and aM (CD11b) subunits in rainbow trout (Oncorhynchus mykiss). The predicted polypeptide sequences of trout CD18 and CD11b-like exhibit 50, 49, or 61% and 25, 25, or 30% identity with human, mouse, and zebrafish orthologs, respectively. The 'domain' architecture of trout CD18 and CD11b-like subunits retains several characteristics of the mammalian ortholog proteins, such as cysteine-rich regions, N-linked glycosylation sites and several proposed domains and signal sequences (von Willebrand factor type A, Integrin alpha, Integrin B tail, EGF, and Transmembrane domain). The tissue expression profiles of trout CR3 subunits diverge from those of mammalian counterparts, showing the kidney as the main source of the trout CD18 and CD11b-like mRNA transcripts. This is the first report of cloning and characterization of the CR3 receptor in low vertebrates.

Cloning and characterization of the trout perforin.

The pore-forming protein, perforin is one of the effectors of cell-mediated killing. A perforin cDNA clone was isolated from rainbow trout (Oncorhynchus mykiss) after screening of a spleen cDNA library. The full-length cDNA is 2070 bp in size, encoding for a polypeptide of 589 amino acids. The predicted amino acid sequence of the trout perforin is 64, 58 and 40% identical to those of Japanese flounder, zebrafish and human perforins, respectively. Although its membrane attack complex/perforin (MACPF) domain is conserved, trout perforin shows low homology to human and trout terminal complement components (C6, C7, C8 and C9), ranging from 19 to 26% identity. Expression analysis reveals that the trout perforin gene is expressed in the blood, brain, heart, kidney, intestine and spleen. Phylogenetic analysis of proteins which belong to the MACPF superfamily clusters the trout perforin in the same group with other known perforins.

Cloning and characterization of two clusterin isoforms in rainbow trout.

Clusterin is a broadly distributed glycoprotein constitutively expressed by various tissues and cell types and has been shown to be associated with several physiological and pathological functions. In order to study the molecular evolution of clusterin, here we report the cloning and characterization of two clusterin genes in rainbow trout (Oncorhynchus mykiss). The deduced amino acid sequences of clusterin-1 and a partial clusterin-2 clone are 89% identical to each other, showing 45, 42 and 38% identity with chicken, frog and human orthologs, respectively. Most of the putative N-glycosylation sites, as well as all 10 cysteine residues which are involved in disulfide bond formation in the mature trout clusterin-1 protein, are fully conserved when aligned with its orthologs from various species. Although trout clusterin genes exhibit the same exon-intron organization, in line with that of human clusterin, they show a totally different mRNA expression profile among various trout tissues. Phylogenetic analysis indicates an early segregation of the clusterin ancestral gene within the taxon of fish leading to the formation of a separate subgroup.

Molecular studies of the immunological effects of the sevoflurane preconditioning in the liver and lung in a rat model of liver ischemia/reperfusion injury.

Sevoflurane has been shown to improve ischemia/reperfusion injury (IRI) through several mechanisms, including amelioration of inflammatory response. However, there haven't been any studies considering the potential role of the complement system in sevoflurane-mediated amelioration of ischemia/reperfusion injury. Our purpose was to investigate the molecular mechanisms involved in sevoflurane preconditioning in liver and lung injury induced by liver ischemia-reperfusion (LIR), giving emphasis to the immunological mechanisms. In order to do that, fifty male Wistar rats were randomly allocated in five groups (n=10 each): Animals in group LIR received ketamine and xylazine and were then subjected to ischemia of the right and median hepatic lobe for 45 min and reperfusion for 6h. Group SEVO/LIR received sevoflurane and then LIR was induced, as in group LIR. Animals in group SHAM/LIR were anesthetized with ketamine and xylazine and then laparotomy followed. Group SHAM/SEVO received sevoflurane for 30 min and then laparotomy followed. Finally, in group VEN, animals only received ketamine and xylazine. Our results showed that sevoflurane preconditioning significantly improved liver-biochemical tests (decreased Alanine transaminase (ALT), Alkaline phosphatase (ALP), Aspartate transaminase (AST) and Alkaline phosphatase (ALP) levels) and limited inflammatory cell infiltration in BALF. Additionally, compared with the LIR group, the reduction in plasma C3 was significantly reduced in the SEVO/LIR group. No significant differences were observed in histological examination in the liver and lung. Immunostaining of the liver for Intracellular Adhesion Molecule 1 (ICAM1) however, showed a decrease in ICAM1 levels in the SEVO/LIR group. In the lung, sevoflurane seemed to exert no effect in ICAM1 levels. Caspase 3 (CASP3) levels in the liver and the lung also appeared unaffected by sevoflurane preconditioning. In the SEVO/LIR group, ICAM1 mRNA expression was significantly reduced in the liver. No statistical significantly differences were observed in Complement component 3 (C3), Complement component 5 (C5) and Clusterin (CLU) mRNA levels in the liver or the lung tissue. Summarizing, sevoflurane preconditioning seems to ameliorate LIR-induced injury in the rats, mediated by mechanisms that include ICAM1 and complement C3 down regulation.

Molecular cloning and expression of Aven gene in chicken.

Aven was originally identified as a protein that regulates apoptosis by binding to apoptotic regulators, Bcl-xL and Apaf-1. Recently was found that Aven protein is a potent activator of ATM, critical for its DNA damage-induced activation. An Aven cDNA clone was isolated from chicken (Gallus gallus) after screening of a cerebellum cDNA library. The full-length cDNA is 1,430 nt in size, encoding for a polypeptide of 352 amino acid residues. The predicted amino acid sequence of the chicken Aven is 69, 46, 45 and 37% identical to those of zebra finch, human, xenopus and zebrafish orthologs, respectively. Expression analysis reveals that the chicken Aven gene is expressed in the adult brain, heart, intestine, kidney, lung, stomach and spleen, as well as in the whole embryos of 4- and 6-days old. Phylogenetic analysis of the Aven ortholog proteins from various organisms clusters the chicken Aven in the same group with other bird Avens.

Cloning of the sixth complement component and, spatial and temporal expression profile of MAC structural and regulatory genes in chicken.

Humoral cytotoxicity results from the assembly of terminal components of complement, called membrane attack complex (MAC), which lead to the formation of pores on pathogen membranes. The complement components involved in MAC formation are C5b, C6, C7, C8alpha, C8beta, C8gamma and C9. Among them, C6 protein interacts with C5b through a metastable binding site to form a soluble C5b-6 dimer in the vicinity of the activating cell. Formation of the MAC is controlled by complement regulatory molecules, such as CD59, vitronectin and clusterin. Here, we report the molecular characterization of the C6 complement component, as well as the spatial and temporal expression profile of MAC structural (C6, C7, C8alpha, C8beta, C8gamma) and regulatory (CD59, vitronectin and clusterin) genes in chicken (Gallus gallus). The deduced polypeptide sequence of chicken C6 consists of 935 amino acid residues and exhibits 81%, 58%, 56% and 44% identity with zebra finch, human, frog and trout orthologs, respectively. The 'domain' architecture of chicken C6 resembles that of mammalian counterparts and the cysteine backbone is also conserved. MAC structural and regulatory genes are expressed in a wide range of adult chicken tissues, with the liver being the major source of their produced transcripts. The developmental expression profile of chicken MAC structural genes shows that their transcripts initially appear in the 12th embryonic day in the liver, exhibiting a pick in the 17th, while no expression was detected in the early whole embryo (day 4 and 6), as well as in the 2-day old neonate chicken liver. On the other hand, MAC regulatory genes are expressed in all the developmental stages investigated.