Glycosylation of a novel member of the immunoglobulin gene superfamily expressed in rat carcinoma cell lines.

MAb E4 recognizes a 66-kDa glycoprotein, pE4, which is a member of the immunoglobulin gene superfamily. This protein is expressed at the cell surface in rat colon and mammary carcinomas, but only in trace amounts in normal adult rat tissues. Since expression of aberrant carbohydrate structures is often associated with malignant transformation, glycosylation of pE4 was analyzed. Reactivity of lectins with pE4 suggested the absence of N-acetylneuraminic acid, terminal galactose and O-linked glycan, and the presence of N-linked glycans. Tunicamycin treatment reduced the binding of MAb E4 to cancer cells suggesting that the E4 epitope is at least partially glycosylated. Digestions with neuraminidases, O-glycosidase and peptide-N-glycosidase F confirmed these results. Pronase treatment abolished the binding of MAb E4, indicating that E4 epitope involves not only a carbohydrate determinant but also a peptide moiety. Mild periodate oxidation abolished the binding of MAb E4, indicating that non-reducing terminus carbohydrates are part of the E4 epitope. Neutral sugar analysis revealed the absence of galactose and the presence of fucose. Since fucose is sensitive to periodate oxidation, this sugar could be the carbohydrate part of the determinant recognized by MAb E4. Reactivity of lectins specific for fucose indicated the presence of alpha(1-6)-fucose on pE4

Cloning of a rat gene encoding the histo-blood group A enzyme. Tissue expression of the gene and of the A and B antigens

The complete coding sequence of a BDIX rat gene homologous to the human ABO gene was determined. Identification of the exon-intron boundaries, obtained by comparison of the coding sequence with rat genomic sequences from data banks, revealed that the rat gene structure is identical to that of the human ABO gene. It localizes to rat chromosome 3 (q11-q12), a region homologous to human 9q34. Phylogenetic analysis of a set of sequences available for the various members of the same gene family confirmed that the rat sequence belongs to the ABO gene cluster. The cDNA was transfected in CHO cells already stably transfected with an alpha1,2fucosyltransferase in order to express H oligosaccharide acceptors. Analysis of the transfectants by flow cytometry indicated that A but not B epitopes were synthesized. Direct assay of the enzyme activity using 2' fucosyllactose as acceptor confirmed the strong UDP-GalNAc:Fucalpha1,2GalalphaGalNAc transferase (Atransferase) activity of the enzyme product and allowed detection of a small UDP-Gal:Fucalpha1,2GalalphaGal transferase (B transferase) activity. The presence of the mRNA and of the A and B antigens was searched in various BDIX rat tissues. There was a general good concordance between the presence of the mRNA and that of the A antigen. Tissue distributions of the A and B antigens in the homozygous BDIX rat strain were largely different, indicating that these antigens cannot be synthesized by alleles of the same gene in this rat inbred strain.Comparative StudyJournal ArticleResearch Support, Non-U.S. Gov'tinfo:eu-repo/semantics/publishe

Cloning of a rat gene encoding the histo-blood group B enzyme: rats have more than one Abo gene

A genomic DNA fragment corresponding to exon 7 of the human ABO gene was amplified from rats of several inbred and outbred strains. Five different sequences were obtained, four of them corresponding to A-type sequences and one to a B-type sequence based on the amino acids equivalent to residues at positions 266 and 268 of the human enzymes. In rats from inbred strains, a single A-type sequence and the unique B-type sequence were found, whereas some animals of outbred strains presented two or three A-type sequences along with the B-type sequence. The complete coding sequence of the B-type gene was obtained; identification of the exon-intron boundaries, determined by comparison with rat genomic sequences from data banks, revealed that the rat B-type gene structure is identical with that of the mouse Abo gene. Compared with the human ABO gene and the rat A gene, it lacks exon 4. Like the rat A gene (symbol: Abo), the rat B gene (symbol: Abo2) is located on chromosome 3q11-q12. It could be shown by transfection experiments that the B-type cDNA encodes an active B transferase. A transcript of the B gene was found ubiquitously, whereas the B antigen was only detected in a restricted set of tissues. These data indicate that rats have at least two distinct Abo genes, one monomorphic gene encoding a B-specific enzyme and one or more genes in some cases encoding an A-specific enzyme.Journal ArticleResearch Support, Non-U.S. Gov'tinfo:eu-repo/semantics/publishe

Investigate the sensitivity of the pearl oyster (Pinctada margaritifera) to environmental conditions in the context of black pearl farming

International audienc

Calcein staining of calcified structures in pearl oyster Pinctada margaritifera and the effect of food resource level on shell growth

International audienceMarine mollusc shell growth has been widely measured using fluorochrome marking. In order to test the efficiency and reliability of calcein staining on Pinctada margaritifera shells and pearls, the present study examined two administration methods, different concentrations and several immersion times. Immersion in a 150 mg L-1 calcein solution for 12 h to 24 h appeared to be the best method for marking P. margaritifera shells. For pearl marking, injection of a 200 mg L-1 calcein solution into the pearl pouch was the optimal method. Calcein marking was then used to measure the influence of food resource levels on the shell growth. Groups of 23-month-old P. margaritifera were fed at three trophic levels for two months. The two highest food levels tested (6000 cell mL(-1) and 15000 cell mL(-1)) induced uniform growth between the dorsal and ventral sides of shell, whereas the lowest food level (800 cell mL(-1)) induced greater growth on the dorsal side. Shell deposits from the ventral side were observed using a scanning electron microscope, revealing that the difference of the trophic level over two months had modified the thickness of the aragonite tablets formed. These results showed that the trophic level is a major factor conditioning P. margaritifera development. (C) 2011 Elsevier B.V. All rights reserved