Activity of fucosyltransferases and altered glycosylation in cystic fibrosis airway epithelial cells.

Cystic fibrosis (CF) glycoconjugates have a glycosylation phenotype of increased fucosylation and/or decreased sialylation when compared with non-CF. A major increase in fucosyl residues linked alpha 1,3 to antennary GlcNAc was observed when surface membrane glycoproteins of CF airway epithelial cells were compared to those of non-CF airway cells. Importantly, the increase in the fucosyl residues was reversed with transfection of CF cells with wild type CFTR cDNA under conditions which brought about a functional correction of the Cl(-) channel defect in the CF cells. In contrast, examination of fucosyl residues in alpha 1,2 linkage by a specific alpha 1,2 fucosidase showed that cell surface glycoproteins of the non-CF cells had a higher percentage of fucose in alpha 1,2 linkage than the CF cells. Airway epithelial cells in primary culture had a similar reciprocal relationship of alpha 1,2- and alpha 1,3-fucosylation when CF and non-CF surface membrane glycoconjugates were compared. In striking contrast, the enzyme activity and the mRNA of alpha 1,2 fucosyltransferase did not reflect the difference in glycoconjugates observed between the CF and non-CF cells. We hypothesize that mutated CFTR may cause faulty compartmentalization in the Golgi so that the nascent glycoproteins encounter alpha 1,3FucT before either the sialyl- or alpha 1,2 fucosyltransferases. In subsequent compartments, little or no terminal glycosylation can take place since the sialyl- or alpha 1,2 fucosyltransferases are unable to utilize a substrate, which is fucosylated in alpha 1,3 position on antennary GlcNAc. This hypothesis, if proven correct, could account for the CF glycophenotype.

Terminal glycosylation of cystic fibrosis airway epithelial cells.

Cystic fibrosis (CF) has a characteristic glycosylation phenotype usually expressed as a decreased ratio of sialic acid to fucose. The glycosylation phenotype was found in CF/T1 airway epithelial cells (deltaF508/deltaF508). When these cells were transfected and were expressing high amounts of wtCFTR, as detected by Western blot analysis and in situ hybridization, the cell membrane glycoconjugates had an increased sialic acid content and decreased fucosyl residues in alpha1,3/4 linkage to antennary N-acetyl glucosamine (Fuc(alpha)1,3/4GlcNAc). After the expression of wtCFTR decreased, the amount of sialic acid and Fuc(alpha)1,3/4GlcNAc returned to levels shown by the parent CF cells. Sialic acid was measured by chemical analysis and Fuc(alpha)1,3/4GlcNAc was detected with a specific alpha1,3/4 fucosidase. CF and non-CF airway cells in primary culture also had a similar reciprocal relationship between fucosylation and sialylation. It is possible that the glycosylation phenotype is involved in the pathogenesis of CF lung disease by facilitating bacterial colonization and leukocyte recruitment.