Dietary Exposure to Individual Polybrominated Diphenyl Ether Congeners BDE-47 and BDE-99 Alters Innate Immunity and Disease Susceptibility in Juvenile Chinook Salmon.

Polybrominated diphenyl ethers (PBDEs), used as commercial flame-retardants, are bioaccumulating in threatened Pacific salmon. However, little is known of PBDE effects on critical physiological functions required for optimal health and survival. BDE-47 and BDE-99 are the predominant PBDE congeners found in Chinook salmon collected from the Pacific Northwest. In the present study, both innate immunity (phagocytosis and production of superoxide anion) and pathogen challenge were used to evaluate health and survival in groups of juvenile Chinook salmon exposed orally to either BDE-47 or BDE-99 at environmentally relevant concentrations. Head kidney macrophages from Chinook salmon exposed to BDE-99, but not those exposed to BDE-47, were found to have a reduced ability in vitro to engulf foreign particles. However, both congeners increased the in vitro production of superoxide anion in head kidney macrophages. Salmon exposed to either congener had reduced survival during challenge with the pathogenic marine bacteria Listonella anguillarum. The concentration response curves generated for these end points were nonmonotonic and demonstrated a requirement for using multiple environmentally relevant PBDE concentrations for effect studies. Consequently, predicting risk from toxicity reference values traditionally generated with monotonic concentration responses may underestimate PBDE effect on critical physiological functions required for optimal health and survival in salmon.

The TNFα converting enzyme (TACE) from ayu (Plecoglossus altivelis) exhibits TNFα shedding activity.

TNFα converting enzyme (TACE) is responsible for converting membrane-anchored TNFα to its soluble form in mammalian. However, the function and characteristics of TACE in teleosts is unclear. In this study, we report the cloning of a cDNA sequence of the PaTACE from ayu, Plecoglossus altivelis. PaTACE encodes an 865-aa polypeptide, which is closest to the TACE gene found in pufferfish (Takifugu rubripes). PaTACE mRNA was detected in all the tissues tested, although it was considerably higher in liver, spleen, and brain tissues following infection with Listonella anguillarum. The recombinant region including the PaTACE catalytic domain was used to produce anti-PaTACE IgG. Western blot results revealed two bands for PaTACE from monocytes/macrophages. PNGase F digestion confirmed that the high molecular mass of PaTACE was caused by glycosylation. TACE activity in cell homogenates from ayu monocytes/macrophages increased following L. anguillarum infection. Moreover, PaTACE neutralization led to downregulation of TNFα expression in the supernatant of ayu monocyte/macrophages. Anti-PaTACE IgG also decreased respiratory burst in monocytes/macrophages. In conclusion, we report for the first time the TNFα-converting activity of TACE from a teleost. More investigation is needed to illustrate PaTACE-shedding activity in other immune regulators.

Cloning and analysis of a ferritin subunit from turbot (Scophthalmus maximus).

Ferritin is an evolutionarily conserved protein that plays an important role in iron storage and detoxification. In this study, the gene encoding a ferritin H subunit homologue (SmFer1) was cloned from turbot (Scophthalmus maximus) and analyzed at the expression and functional levels. The open reading frame of SmFer1 is 534 bp and preceded by a 5'-untranslated region that contains a putative Iron Regulatory Element (IRE). The deduced amino acid sequence of SmFer1 shares extensive sequence identities with the H ferritins of a number of fish species and contains the ferroxidase center that is preserved in ferritin H subunits. Examination of tissue specific expression indicated that SmFer1 expression was most abundant in muscle, liver, and blood. Experimental infection with bacterial pathogens induced significant induction of SmFer1; however, the magnitudes of induction effected by Gram-negative pathogens were much higher than that induced by Gram-positive pathogen. Consistently, lipopolysaccharide (LPS) challenge drastically augmented SmFer1 expression. In addition to bacterial pathogens and LPS, poly(I:C) also induced a strong but transient induction of SmFer1 which differs in profile from those induced by bacterial pathogens. In vitro iron-chelating analysis showed that recombinant SmFer1 purified from Escherichia coli was able to bind ferrous iron in a concentration-dependent manner. To examine whether SmFer1, with its iron-chelating capacity, could have any effect on the infection of bacterial pathogens, purified recombinant SmFer1 was subjected to bacteriostatic analysis and proved to be able to inhibit the growth of the fish pathogen Listonella anguillarum which enhanced SmFer1 expression upon infection. Taken together, these results suggest that SmFer1 is likely to play a role in both iron storage and immune defense against microbial infections.

Arasin 1, a proline-arginine-rich antimicrobial peptide isolated from the spider crab, Hyas araneus.

Antimicrobial peptides (AMPs) are considered to play an important role as host-defense molecules in both vertebrates and invertebrates. This work was undertaken to characterize AMPs from hemocyte extracts of the small spider crab, Hyas araneus. A novel proline-arginine-rich AMP of 37 amino acids was isolated and characterized. The peptide, named arasin 1, has a chimeric structure with an N-terminal domain rich in proline and arginine and a C-terminal domain containing two disulfide linkages. The peptide precursor of 64 amino acids, deduced from a cDNA library, contained a hydrophobic pre-region of 25 amino acids, directly followed by the mature peptide. C-terminally, this precursor had two additional amino acids, which seem to be cleaved off post-translationally. Synthetic arasin 1 showed antibacterial activity. A putative isoform of arasin 1, named arasin 2, was found at the genetic level, and both transcripts were shown by real-time RT-PCR to be expressed mainly in hemocytes.