J Kukowska-Latallo

We have used the human Lewis blood group fucosyltransferase cDNA and cross-hybridization procedures to isolate a human gene that encodes a distinct fucosyltransferase. Its DNA sequence predicts a type II transmembrane protein whose sequence is identical to 133 of 231 amino acids at corresponding positions within the catalytic domain of the Lewis fucosyltransferase. When expressed by transfection in cultured cell lines, this gene determines expression of a fucosyltransferase capable of efficiently utilizing N-acetyllactosamine to form the Lewis x determinant (Gal beta 1----4[Fuc alpha 1----3]GlcNAc). By contrast, biochemical and flow cytometry analyses suggest that the enzyme cannot efficiently utilize the type II acceptor NeuNAc alpha 2----3Gal beta 1----4GlcNAc, to form the sialyl Lewis x determinant. In Chinese hamster ovary cells, however, the enzyme can determine expression of the alpha 2----3-sialylated, alpha 1----3-fucosylated structure known as VIM-2, a putative oligosaccharide ligand for ELAM-1. Cell adhesion assays using VIM-2-positive, sialyl Lewis x-negative transfected Chinese hamster ovary cells indicate that surface expression of the VIM-2 determinant is not sufficient to confer ELAM-1-dependent adhesive properties upon the cells. These results demonstrate that substantial structural similarities can exist between mammalian glycosyltransferases with closely related enzymatic properties, thus facilitating isolation of their cognate genes by cross-hybridization methods. The results further suggest that cell surface expression of the VIM-2 determinant is not necessarily sufficient to mediate ELAM-1-dependent cell adhesion.

We have developed a genetic approach to isolate cloned cDNA sequences that determine expression of cell surface oligosaccharide structures and their cognate glycosyltransferases. A cDNA library was constructed in a mammalian expression vector by using mRNA from a murine cell line known to express a UDPgalactose:beta-D-galactosyl-1,4-N-acetyl-D-glucosaminide alpha-1,3-galactosyltransferase [(alpha 1-3)GT; EC 2.4.1.151]. This library was transfected into COS-1 cells, which lack expression of (alpha 1-3)GT. Transfected cells containing functional (alpha 1-3)GT cDNAs were detected and isolated with a lectin that recognizes the surface-expressed glycoconjugate product of the (alpha 1-3)GT enzyme. One cloned (alpha 1-3)GT cDNA was rescued from lectin-positive transfected cells. This cDNA contains a single long open reading frame that predicts a 394-amino-acid protein. No significant primary structure similarities were identified between this protein and other known sequences. However, the protein predicts a type II transmembrane topology similar to two other mammalian glycosyltransferases. This topology places the large COOH-terminal domain within the Golgi lumen; this domain was shown to be catalytically active when expressed in COS-1 cells as a portion of a secreted protein A fusion peptide. Biochemical analysis confirmed that this enzyme catalyzes a transglycosylation reaction between UDP-Gal and Gal(beta 1-4)GlcNAc to form Gal(alpha 1-3)Gal(beta 1-4)GlcNAc. This cloning approach may be generally applicable to the isolation of cDNAs encoding other mammalian glycosyltransferases.

Mouse L cell fibroblasts were transfected with cloned cDNA encoding rat liver fatty acid binding protein (L-FABP) also known as sterol carrier protein. Stable transfectant cell lines were selected and expression of L-FABP determined using Western blot analysis. The nontransfected controls and low expression cells did not differ significantly in any of the properties examined. All cell lines showed similar doubling times but cells expressing high levels of L-FABP attained 2-fold higher cell saturation density and differed significantly in their lipid metabolism as indicated by 1) higher cholesterol ester and phospholipid content, and 2) decreased sterol/phospholipid ratio. The observed changes in the lipid composition predicted a lower degree of membrane-lipid order (higher fluidity) in the plasma membranes of cells expressing high levels of L-FABP. Therefore, fluorescent molecule, 1,6-diphenyl-1,3,5-hexatriene, and multifrequency (1-250 MHz) phase and modulation fluorometry were used to probe the effect of L-FABP expression on membrane structure. Steady-state polarization and limiting anisotropy of diphenylhexatriene were significantly lower in the isolated plasma membrane vesicles from the high expression clones. The observed changes in L-cells as a result of de novo expression of L-FABP are consistent with the ability of this protein to bind sterols and fatty acids, stimulate sterol esterification, and stimulate phospholipid biosynthesis. This evidence is supportive of a physiologic role for L-FABP in modulating cellular lipid metabolism and membrane structure.

A full-length human c-myb cDNA clone has been isolated from a CCRF-CEM leukemia cell cDNA library. The plasmid vector contains simian virus 40-derived promotor, splice, and polyadenylation sequences as well as a transcription unit for a dihydrofolate reductase cDNA. We have introduced this construct into Friend erythroleukemia (F-MEL) cells and have isolated a number of clones which contain intact and transcriptionally active human c-myb sequences. F-MEL clones expressing the highest levels of the human c-myb mRNA differentiate poorly in response to dimethyl sulfoxide. Two clones which initially expressed low levels of human c-myb transcripts and which differentiated normally were subsequently inhibited in their ability to differentiate when grown in successively higher concentrations of methotrexate, due to amplification and enhanced expression of plasmid sequences. The inhibitory effect on F-MEL differentiation appeared to be independent of the early decline in c-myc transcripts which were normally regulated in all cases examined. Our results indicate that constitutive expression of a nontruncated human c-myb cDNA can exert profound effects on erythroid differentiation and argue for a causal role of c-myb in the F-MEL differentiation process.