Segregation of infectious pancreatic necrosis resistance QTL in the early life cycle of Atlantic Salmon (Salmo salar)

In a previous study, three significant quantitative trait loci (QTL) associated with resistance to Infectious Pancreatic Necrosis (IPN) disease were identified by analysing challenge data from one sub-population of Landcatch Atlantic salmon (Salmo salar) smolt. While these QTL were shown to affect the resistance in seawater, their effect in freshwater was unknown. This study investigates the effect of these QTL on IPN resistance in salmon fry in freshwater. Twenty families with intermediate levels of IPN mortality were analysed from a freshwater challenge trial undertaken on a different sup-population of LNS salmon to that studied previously. Only the QTL from linkage group 21 (LG21) appeared to have a significant and large effect on resistance in freshwater; the same QTL was found to have the largest effect in seawater in the previous study. Variance component analysis showed a high heritability for the QTL: 0.45 ± 0.07 on the liability scale and 0.25 ± 0.05 on the observed scale. In a family where both parents were segregating for the QTL, there was a 0% vs. 100% mortality in homozygous offspring for resistant and susceptible QTL alleles. The finding that the same QTL has major effect in both freshwater and seawater has important practical implications, as this will allow the improvement of resistance in both phases through marker assisted selection by targeting this QTL. Moreover, the segregation of the LG21 QTL in a different sub-population gives further evidence of its association with IPN-resistance.     

Mammalian sulfoconjugate metabolism

Sulfoconjugates occur ubiquitously as sulfopolysaccharides, sulfolipids and sulfoproteins. A variety of sulfotransferases catalyze the sulfation process with 3’-phosphoadenosine 5’-phosphosulfate as the sulfate donor. Sulfatases that catalyze the desulfation of different sulfoconjugates are known to be deficient in a number of genetic storage disorders.     

Photoaffinity labeling of T4 bacteriophage 32 protein

With a view toward the determination of nucleic acid binding domains and sites on nucleic acid helix-destabilizing (single strand-specific) proteins (HDPs), we have studied the interactions of the copolymer polynucleotide photoaffinity label, poly(adenylic, 8-azidoadenylic acid), (poly(A,8-N3A] with the T4 bacteriophage HDP, 32 protein. Poly(A,8-N3A) quenched the intrinsic tryptophan fluorescence of 32 protein in a manner similar to that observed with other polynucleotides, and the effect could be reversed by addition of sufficient NaCl. The binding affinity and site size of this noncovalent interaction of poly(A,8-N3A) with 32 protein are similar to the values obtained for poly(A) and this protein. When [3H]poly(A,8-N3A)/32 protein mixtures were irradiated at 254 nm, fluorescence quenching was not reversed by NaCl, suggesting that the label was covalently bound to the protein. Mixtures of photolabel and protein subjected to short periods of irradiation (generally 1 min, 2000 erg mm-2) formed high molecular weight complexes, which when electrophoresed on sodium dodecyl sulfate (SDS)-polyacrylamide gels were radioactive and stained with Coomassie Blue R. Under the same conditions, [3H]poly(A) failed to label 32 protein. The radioactivity of [3H]poly(A,8-N3A)-labeled complexes subjected to micrococcal nuclease after irradiation was seen to migrate just behind the free 32 protein monomer on SDS-polyacrylamide gels, indicating that portions of the photolabel not in direct contact with protein were accessible to this enzyme. By several criteria, we conclude that 32 protein was photolabeled specifically at its single-stranded nucleic acid binding site. Single-stranded nucleic acids with affinities for protein greater than that of poly(A,8-N3A) effectively inhibited photolabeling. The [NaCl] dependence of photolabeling monitored on SDS gels paralleled the NaCl reversal of (noncovalent) poly(A,8-N3A)-32 protein binding. Photolabeling reached a plateau after 1-2 min. The formation of high molecular weight complexes with increasing [poly(A,8-N3A)] paralleled the disappearance of free protein on SDS gels, and reached a saturation level of about 75% labeling. Several chromatographic procedures appear to be useful for the separation of the photolabeled complexes from free protein and photolabel. Limited trypsin hydrolysis of photolabeled 32 protein indicated that all the label was within the central ("III") portion of the protein. This approach should have general applicability to the identification of nucleic acid binding sites on helix-destabilizing proteins.