Enzymatic basis for the accumulation of glycolipids with X and dimeric X determinants in human lung cancer cells (NCI-H69)

Many human carcinomas accumulate a large quantity of glycolipids having X (Gal beta 1----4[Fuc alpha 1----3] GlcNAc) as well as di- or trimeric X determinant (Gal beta 1----4 [Fuc alpha 1----3] GlcNAc beta 1----3Gal beta 1----4 [Fuc alpha 1----3]GlcNAc beta 1----3Gal) (e.g. Hakomori, S., Nudelman, E., Levery, S. B., and Kannagi, R. (1984) J. Biol. Chem. 259, 4672-4680). The enzymatic basis of this phenomenon has been investigated with human small cell lung carcinoma NCI-H69 cells, in which a series of these structures has been found to accumulate. An alpha 1----3 fucosyltransferase solubilized from the membrane fraction with Triton X-100 catalyzed not only the transfer of a fucosyl residue from GDP-fucose to the penultimate GlcNAc residue of lactoneotetraosylceramide (nLc4) and lactonorhexaosylceramide (nLc6), but also to the internal GlcNAc residue (III-GlcNAc) of y2 glycolipid (V3FucnLc6) and that of sialosyl2----6lactonorhexaosylceramide (VI6NeuAcnLc6). No transfer of fucose to the internal GlcNAc (III-GlcNAc) of lactonorhexaosylceramide occurred, unless the above substitutions (V3Fuc or VI6NeuAc) were present. Fucosylation at V-GlcNAc and III-GlcNAc of nLc6 could be catalyzed by the same enzyme, based on the following observations: (i) fucosylation at both III- and V-GlcNAc was competitively inhibited by V3FucnLc6 and III3V3Fuc2nLc6; (ii) the same conditions (pH, bivalent cation, detergent) were optimal for fucosylation at both III- and V-GlcNAc; (iii) the Km values of the enzyme for nLc4, nLc6, and V3FucnLc6 were approximately the same; and (iv) the activity of the enzyme catalyzing fucosylation at both III- and V-GlcNAc was adsorbed on GDP-hexanolamine-Sepharose and was not inhibited by N-ethylmaleimide. The enzyme preferentially transferred fucose to the penultimate VGlcNAc, followed by transfer to the internal III-GlcNAc of nLc6. Thus, the pathway for synthesis of dimeric X proceeds as follows: nLc6----V3FucnLc6----III3V3Fuc2nLc6. No mechanism was found to operate for chain elongation of the X hapten structure through addition of GlcNAc residues to the terminal Gal of the X hapten.     

The cloning and expression of a human alpha-1,3 fucosyltransferase capable of forming the E-selectin ligand.

The polymerase chain reaction was used to amplify a novel fucosyltransferase cDNA (FucT-VI) from A431 and from HL60 cells. The amplified cDNA has a high degree of sequence identity to FucT-V and to FucT-III, and a much lower level of similarity to FucT-IV. Transfection of the FucT-VI gene into mammalian cells confers alpha-1,3 fucosyltransferase activity to the cells, resulting in cell surface expression of Lewis x and sialyl-Lewis x carbohydrates. In contrast to FucT-IV activity, FucT-VI catalyzes the transfer of fucose from GDP-beta-fucose to alpha-2,3 sialylated substrates. The substrate specificity of the FucT-VI gene product suggests that FucT-VI may be an enzyme involved in the biosynthesis of the E-Selectin ligand, sialyl-Lewis x, in myeloid cells.     

Fucosyltransferases in Schistosoma mansoni development

Glycoconjugate-bound fucose, abundant in the parasite Schistosoma mansoni, has been found in the form of Fucalpha1,3GlcNAc, Fucalpha1,2Fuc, Fucalpha1,6GlcNAc, and perhaps Fucalpha1,4GlcNAc linkages. Here we quantify fucosyltransferase activities in three developmental stages of S. mansoni. Assays were performed using fluorophore-assisted carbohydrate electrophoresis with detection of radioactive fucose incorporation from GDP-[(14)C]-fucose into structurally defined acceptors. The total fucosyltransferase-specific activity in egg extracts was 50-fold higher than that in the other life stages tested (cercaria and adult worms). A fucosyltransferase was detected that transferred fucose to type-2 oligosaccharides (Galbeta1,4GlcNAc-R), both sialylated (with the sialic acid attached to the terminal Gal by alpha2,3 or 2,6 linkage) and nonsialylated. Another fucosyltransferase was identified that transferred fucose to lactose-based and type-2 fucosylated oligosaccharides, such as LNFIII (Galbeta1,4(Fucalpha1,3)GlcNAcbeta1,3Galbeta1,4Glc). A low level of fucosyltransferase that transfers fucose to no-sialylated type-1 oligosaccharides (Galbeta1,3GlcNAc-R) was also detected. These studies revealed multifucosylated products of the reactions. In addition, the effects of fucose-type iminosugars inhibitors were tested on schistosome fucosyltransferases. A new fucose-type 1-N-iminosugar was four- to sixfold more potent as an inhibitor of schistosome fucosyltransferases in vitro than was deoxyfuconojirimycin. In vivo, this novel 1-iminosugar blocked the expression of a fucosylated epitope (mAb 128C3/3 antigen) that is associated with the pathogenesis of schistosomiasis.     

The GDP-fucose:N-acetylglucosaminide 3-alpha-L-fucosyltransferases of LEC11 and LEC12 Chinese hamster ovary mutants exhibit novel specificities for glycolipid substrates

Previous studies have shown that the GDP-fucose:N-acetylglucosaminide 3-alpha-L-fucosyltransferase (alpha (1,3) fucosyltransferase (Fuc-T)) activities expressed by the Chinese hamster ovary cell mutants LEC11 (Fuc-TI) and LEC12 (Fuc-TII) are different enzymes and indicated that Fuc-TI might act on sialylated lactosamine sequences (Campbell, C., and Stanley, P. (1984) J. Biol. Chem. 259, 11208-11214). In this paper we show that CSLEX-1, a monoclonal antibody specific for NeuNac alpha (2,3)Gal beta (1,4)(Fuc alpha (1,3))GlcNAc beta 1 sequences, bound to LEC11 cells but not to LEC12 cells. Direct evidence that Fuc-TI could act on sialylated substrates was sought with a series of glycolipid acceptors. Optimal assay conditions in crude cell extracts were determined with nLc4, a glycolipid which accepted fucose with both Fuc-TI and Fuc-TII to generate the Lex antigenic determinant. The two enzymes differed in their detergent sensitivities, pH optima, Mn2+ requirements, and apparent Km values for nLc4. When sialylated glycolipids were examined as substrates, Fuc-TI added fucose to IV3NeuNAcnLc4 but not to IV6NeuNAcnLc4, whereas Fuc-TII was unable to utilize either glycolipid as a substrate. Further studies showed that Fuc-TI and Fuc-TII possess novel specificities for glycolipids containing two lactosamine sequences as potential fucose acceptors. Fuc-TI exhibited good activities with VI3NeuNAcnLc6 and VI6NeuNAcnLc6 whereas Fuc-TII had very low activity with both substrates. Glycosidase digestions of the labeled products showed that Fuc-TI added fucose primarily to the internal N-acetylglucosamine of both glycolipids. The same preference for the internal N-acetylglucosamine was shown by Fuc-TI when nLc6 was the acceptor. In contrast, Fuc-TII preferred to transfer fucose to the external acceptor site of nLc6, consistent with the low activities of Fuc-TII with sialylated nLc6 derivatives. Thus the two enzymes preferentially add fucose to different N-acetylglucosamines in the same substrate, nLc6. This indicates that the biosynthetic pathway for fucosylation of polylactosamine sequences in glycolipids and glycoproteins will vary depending upon the particular alpha (1,3)fucosyltransferase present.     

Biosynthesis of the sialyl-Lex determinant carried by type 2 chain glycosphingolipids (IV3NeuAcIII3FucnLc4, VI3NeuAcV3FucnLc6, and VI3NeuAcIII3V3Fuc2nLc6) in human lung carcinoma PC9 cells

The pathway for synthesis of three glycosphingolipids bearing a common sialyl-Lex determinant (NeuAc alpha 2----3Gal beta 1----4[Fuc alpha 1----3]GlcNac beta 1----R) from their type 2 lactoseries precursors has been studied using the 0.2% Triton X-100-soluble fraction from human lung carcinoma PC9 cells. Two enzymes were found to be required for their synthesis: (i) an alpha 1----3 fucosyltransferase, the properties of which have been characterized as being similar to the enzyme from human small cell lung carcinoma NCI-H69 cells (Holmes, E. H., Ostrander, G. K., and Hakomori, S. (1985) J. Biol. Chem. 260, 7619-7627); and (ii) an alpha 2----3 sialyltransferase that was efficiently solubilized by 0.2% Triton X-100 and required divalent metal ions and 0.3% Triton CF-54 for optimal activity at pH 5.9 in cacodylate buffer. Biosynthesis of the sialyl-Lex determinant was shown to proceed via sialylation of nLc6 and nLc4, followed by alpha 1----3 fucosylation at the penultimate GlcNAc residues, based on the following: (i) transfer of NeuAc by PC9 cell sialyltransferase was found only when the nonfucosylated acceptors nLc4 and nLc6 were added, and none of the glycolipids with Lex structure (III3FucnLc4; V3FucnLc6; III3V3Fuc2nLc6) were sialylated; and (ii) the PC9 cell fucosyltransferase was active with both neutral and ganglioside neolacto (type 2 chain) acceptors. Transfer of fucose to VI3NeuAcnLc6 yielded mono- and difucosyl derivatives, whereas only a monofucosyl derivative was obtained when VI6NeuAcnLc6 was the acceptor. This is most probably due to different conformations at the terminus of the two acceptor gangliosides. The fucosyltransferase was incapable of transferring fucose to sialyl 2----3 lactotetraosylceramide (IV3NeuAcLc4).     

Tumor-related expression of alpha1,2fucosylated antigens on colorectal carcinoma cells and its suppression by cell-mediated priming using sugar acceptors for alpha1,2fucosyltransferase

The accumulation of alpha1,2fucosylated antigens, such as Y (Fucalpha1,2Galbeta1,4 [Fucalpha1,3]GlcNAcbeta), Le(b) (Fucalpha1,2Galbeta1,3-[Fucalpha1,4]GlcNAcbeta), and H type 2 (Fucalpha1,2 Galbeta1,4GlcNAcbeta) occurs specifically within human colorectal tumor tissues and can be detected by an antifucosylated antigen antibody, such as the YB-2 antibody. In the present investigation, we found that the expression of these antigens bearing an alpha1,2-linked fucose correlated with the resistance of the tumor cells to anticancer treatments. Addition of an exogenous sugar acceptor for alpha1,2fucosyltransferase to the cell medium resulted in suppression of alpha1,2fucosylated antigen expression on the tumor cells and increased susceptibility to anticancer treatment. The increased susceptibility may be attributed to cancer cell-mediated priming by sugar acceptors for alpha1,2fucosyltransferase added to the medium.     

Overexpression of fucosyltransferase IV in A431 cell line increases cell proliferation

Fucosyltransferase IV is an essential enzyme that catalyzes the synthesis of fucosylated oligosaccharides by transferring GDP-fucose to the terminal N-acetylglucosamine with the alpha1,3-linkage. Lewis Y oligosaccharide has a terminal alpha1,3-linked fucose residue and elevation of Lewis Y level is seen in many epithelial cancers. The mechanism of Lewis Y elevation in neoplastic cells is still largely unknown. To study the impact of fucosyltransferase IV on Lewis Y expression and its role on neoplastic cell proliferation, a pEGFP-N1-FUT4 recombinant plasmid was developed and stably transfected into A431 cells. We found that fucosyltransferase IV overexpression promoted cell proliferation and increased the expression of proliferating cell nuclear antigen that correlated with Lewis Y augmentation. Cell cycle analysis demonstrated that fucosyltransferase IV overexpression facilitated cell cycle progression. In conclusion, fucosyltransferase IV overexpression augments Lewis Y expression to trigger neoplastic cell proliferation. These studies suggest that fucosyltransferase IV may serve as a potential therapeutic target for the treatment of Lewis Y-positive epithelial cancers.     

Pathophysiological contributions of fucosyltransferases in renal ischemia reperfusion injury

Ischemia reperfusion injury (IRI) is a major cause of delayed graft function. Recent studies have shown that selectins play an important role in IRI. Selectins bind to sialylated and fucosylated sLe(x) receptors, and two enzymes, fucosyltransferase IV (FucT-IV) and VII (FucT-VII), are important in the function of these receptors. We hypothesized that fucosyltransferase (FucT) enzymes were important pathophysiologic mediators of renal IRI. We therefore evaluated renal IRI in mice deficient in FucT-IV, FucT-VII, and both FucT-IV and FucT-VII and compared their renal function, tubular injury, selectin ligand expression, and neutrophil infiltration to those in wild-type control mice. Bilateral 30-min renal IRI was performed, and the results demonstrated that mice deficient in both FucT-IV/FucT-VII were significantly protected from renal IRI at 24 and 48 h compared with wild-type control mice. FucT-IV-deficient mice showed only modest protection from renal injury at 24 h. However, FucT-VII-deficient mice had similar injury as wild-type mice. Histological analysis of kidney tissue postischemia revealed that mice deficient in both FucT-IV and FucT-VII had significantly reduced tubular injury compared with wild-type mice. Selectin ligand expression increased postischemia in wild-type, but not FucT-IV/FucT-VII-deficient, mice. Neutrophil infiltration in postischemic kidneys of FucT-IV/FucT-VII-deficient mice was also attenuated. These data demonstrate that fucosyltransferases are important in the pathogenesis of renal IRI and are potential therapeutic targets.     

A highly conserved His-His motif present in alpha1-->3/4fucosyltransferases is required for optimal activity and functions in acceptor binding

Alpha1-->3/4fucosyltransferases (FucTs) from several species contain a highly conserved His-His motif adjacent to an enzyme region correlating with the ability to catalyze fucose transfer to type 1 chain acceptors. Site-directed mutagenesis has been employed to analyze structure-function relationships of this His-His motif in human FucT-IV. The results indicate that most changes of His(113) and His(114) and nearby residues of FucT-IV reduced the specific activity of the enzymes. Analysis of acceptor properties demonstrated close similarity of most mutants with wild-type FucT-IV, whereas an apparent preference for the H-type II acceptor was observed for the His(114) mutants. Kinetic studies demonstrated that mutants of His(114) had a substantially increased K(m) for acceptor compared to other enzymes tested. The dramatic increase in acceptor K(m) for the His(114) mutants, particularly for the nonfucosylated acceptor, suggests that this His-His motif is involved in acceptor binding and perhaps interacts with GlcNAc residues of type 2 acceptors. The presence of fucose in acceptor substrates may promote more efficient substrate binding and presumably partially overcomes the weaker interaction with GlcNAc caused by the mutation.     

Characterization of a cytosolic fucosylation pathway in Dictyostelium.

FP21 is a 21-kDa fucoprotein which fractionates with the cytosol after high-speed centrifugation of gently lysed Dictyostelium cells. Less than 0.7% of FP21 is associated with vesicles. In proliferating cells, 4 x 10(5) fucosyl moieties/cell are associated with FP21 as anionic, possibly O-linked oligosaccharides equal in size to 4.8 glucose units. FP21 is underfucosylated in a mutant strain (HL250) that depends on extracellular fucose for synthesis of GDP-fucose. To determine the cellular site of FP21 fucosylation, cytosolic and vesicular preparations from strain HL250 were compared for their ability to transfer fucose from GDP-fucose to FP21. Cytosolic preparations fucosylate endogenous FP21 in a time-, concentration-, and divalent cation-dependent fashion, with a Km for GDP-fucose of 1.4 microM. Activity in normal cell cytosol is dependent on exogenous mutant FP21, demonstrating that FP21 is normally fully fucosylated. Both mutant and normal cytosols are also able to alpha-fucosylate a type 1 glycolipid substrate (8-methoxycarbonyloctyl-Gal beta 1-3 beta GlcNAc), but not related substrates, with Km values for the type 1 glycolipid of 0.99 mM and for GDP-fucose of 1.6 microM. Competitive inhibition between FP21 and the type 1 glycolipid shows that the same enzyme fucosylates both substrates. Intact and permeabilized vesicle preparations from wild-type cells are unable to fucosylate FP21 or the type 1 glycolipid by a divalent cation-dependent mechanism, and thus are devoid of FP21-fucosyltransferase. Since control experiments showed that vesicle leakage is minimal during cytosol preparation, these results indicate that FP21 is synthesized and fucosylated in the cytosolic compartment, by an unusual soluble fucosyltransferase.     

An amino acid region at the N-terminus of rat hepatoma alpha1-->2 fucosyltransferase modulates enzyme activity and interaction with lipids: strong preference for glycosphingolipids containing terminal Galbeta1-->3GalNAc-structures

A GDP-fucose:GM1 alpha1-->2 fucosyltransferase (FucT) is induced during early stages of chemical hepatocarcinogenesis in parenchymal cells of Fischer 344 rats fed a diet supplemented with 0.03% N-2-acetylaminofluorene (AAF). This enzyme is undetectable in normal rat liver tissues but is highly expressed in many rat hepatoma cell lines, including rat hepatoma H35 cells. Enzymatic properties and acceptor specificity of native rat hepatoma H35 cell alpha1-->2FucT, expressed recombinant full-length H35 cell alpha1-->2FucT, and a truncated form missing the first 27 amino acid residues from the N-terminus, comprising the cytoplasmic and transmembrane domains of the enzyme, were studied. The results indicate that the recombinant full-length enzyme has a specific activity over 80-fold higher than the truncated enzyme. Both the native and recombinant full-length enzymes display significant activity in the absence of detergent or phospholipid and optimal activity in the presence of Triton CF-54 detergent. The truncated enzyme is optimally activated by CHAPSO, showing little activity in its absence. These findings are in agreement with previous studies demonstrating a requirement of a lipidic environment for optimal activity with this enzyme and suggest that the N-terminal transmembrane domain is important either in the maintenance of an active conformation or in allowing efficient interaction with acceptor glycolipids. Both the full-length and truncated enzymes transfer fucose not only to GM1 and asialo-GM1 (Gg4) but also to galactosyl globoside (Gb5) as well. Weak or undetectable transfer to lacto- and neolacto-series acceptors was observed, demonstrating a strong preference for terminal Galbeta1-->3GalNAc- structures. The structures of two reaction products generated by expressed recombinant full-length alpha1-->2FucT, which are known to be important tumor-associated antigens (fucosyl-GM1 and fucosyl-Gb5), were unambiguously confirmed by 1H-NMR spectral analysis.     

Acceptor requirements for GDP-fucose:xyloglucan 1,2-alpha-L-fucosyltransferase activity solubilized from pea epicotyl membranes.

GDP-fucose:xyloglucan (XG) fucosyltransferase from growing Pisum epicotyl tissue was solubilized in detergent and used to examine the capacity of intact XG from Tamarindus seeds, and its partial hydrolysis products, to act as fucose acceptors with GDP-[14C]fucose as donor. Native seed XG (Mr greater than 10(6) Da) was partially depolymerized by incubation with Trichoderma cellulase for various periods of time. Cellulase was inactivated and reaction mixtures were incubated with GDP-[14C]fucose plus solubilized pea fucosyltransferase and then fractionated on columns of Sepharose CL-6B or Bio-Gel P4. Specific activities (Bq/microgram carbohydrate) of fragments with Mr ranging from 10(6) to 10(4) Da were constant throughout the size ranges, indicating that all stretches of the XG chains were available for fucosylation. More complete cellulase hydrolysis yielded subunit oligosaccharides that chromatographed in a cluster of hepta-, octa-, and nonasaccharides, none of which acted as fucosyl acceptors when incubated with pea fucosyltransferase. However, a substantial amount (up to half of hydrolysate) of larger transient oligosaccharides was also formed with a size equivalent to three of the oligosaccharide subunits. Octasaccharide subunits in this trimer were readily fucosylated. This fucosyltransfer was inhibited by uncombined (free) subunit oligosaccharides, which implies that the latter could bind to the transferase and displace at least part of the trimer, even though they could not themselves be fucosylated. Reduction of the trimer oligosaccharide with NaB3H4, followed by further hydrolysis with cellulase, resulted in tritiated nonasaccharide and unlabeled octasaccharide in a concentration ratio of 1:2. The tamarind XG trimer which accepts fucose is therefore composed mainly of the subunit sequence: octa-octa-nonasaccharide (reducing). One of the terminal oligosaccharide subunits in this trimer, probably the nonasaccharide, appears to be required as a recognition (binding) site in fucosyltransferase in order for adjacent octasaccharide(s) to be fucosylated by the active (catalytic) enzyme site.     

Biosynthesis of fucose containing lacto-series glycolipids in human colonic adenocarcinoma Colo 205 cells

Biosynthesis of fucose containing lacto-series glycolipids has been studied in human colonic adenocarcinoma Colo 205 cells. Transfer of fucose in both alpha 1----3 linkage to type 2 chain acceptors and alpha 1----4 linkage to type 1 chain acceptors was demonstrated with a Triton X-100 solubilized membrane fraction. The enzyme was found to be highly active over a broad pH range between 6.0 and 7.5. Kinetics of the transfer reactions were studied and indicated that the enzyme had an apparent Km for GDPfucose of 53 and 49 microM with acceptors nLc4 and Lc4, respectively. The apparent Km values for acceptors Lc4, nLc4, and IV3NeuAcnLc4 were determined to be 42, 18, and 26 microM, respectively. Transfer of fucose to the type 1 chain acceptor Lc4 alone and in the presence of increasing concentrations of the type 2 chain acceptor IV3NeuAcnLc4 or Gb3 suggested that both type 1 and 2 acceptors were alternate acceptors for a single enzyme. This was further established by the finding that IV3NeuAcnLc4 behaved as a competitive inhibitor of fucose transfer with respect to Lc4. Conditions were defined for preparative scale in vitro synthesis of fucosylated products of nLc6 catalyzed by the Colo 205 cell enzyme. Yields of the monofucosyl derivative of 2.5 mg (46%) and 1 mg (17%) of the difucosyl derivative were obtained from 5 mg of original nLc6. The structures of these biosynthetic products were carefully studied by 1H NMR, +FAB-MS, and methylation analysis. These studies revealed extremely high purity products composed of III3FucnLc6 and III3V3Fuc2nLc6. The significance of the nature of these products and enzymatic properties is discussed.     

Surface Glycosyltransferase Activities During Development of Neuronal Cell Cultures

Neurons in culture obtained from dissociated cerebral hemispheres of 8-day-old chick embryos showed measurable activities of galactosyl-, fucosyl-, and sialyl-transferases at the external surface of their plasma membrane. Important changes in these activities were observed during cell proliferation and maturation, in particular the surface fucosyltransferase activity, and/or the amount of intracellular fucosylated acceptors increased during synaptogenesis, between 3 and 5 days in culture (d.i.c.). A sodium dodecyl sulfate radioelectrophoretic analysis of the fucosylated neuronal acceptors labelled with [14C]fucose showed, during synaptogenesis, the high labelling of two protein bands of 116 and 50 X 10(3) daltons. The fucosylation of glycoconjugates occurred preferentially, in neurons, upon glycoproteins whereas in glial cell cultures glycolipids were more fucosylated. The reasons for such a difference are not yet understood but the results suggest that the surface fucosyltransferase activity and fucosylated proteins in particular may play a role during the synaptogenesis of neurons in culture.     

A single amino acid in the hypervariable stem domain of vertebrate alpha1,3/1,4-fucosyltransferases determines the type 1/type 2 transfer. Characterization of acceptor substrate specificity of the lewis enzyme by site-directed mutagenesis

Alignment of 15 vertebrate alpha1,3-fucosyltransferases revealed one arginine conserved in all the enzymes employing exclusively type 2 acceptor substrates. At the equivalent position, a tryptophan was found in FUT3-encoded Lewis alpha1,3/1,4-fucosyltransferase (Fuc-TIII) and FUT5-encoded alpha1,3/1,4-fucosyltransferase, the only fucosyltransferases that can also transfer fucose in alpha1, 4-linkage. The single amino acid substitution Trp111 --> Arg in Fuc-TIII was sufficient to change the specificity of fucose transfer from H-type 1 to H-type 2 acceptors. The additional mutation of Asp112 --> Glu increased the type 2 activity of the double mutant Fuc-TIII enzyme, but the single substitution of the acidic residue Asp112 in Fuc-TIII by Glu decreased the activity of the enzyme and did not interfere with H-type 1/H-type 2 specificity. In contrast, substitution of Arg115 in bovine futb-encoded alpha1, 3-fucosyltransferase (Fuc-Tb) by Trp generated a protein unable to transfer fucose either on H-type 1 or H-type 2 acceptors. However, the double mutation Arg115 --> Trp/Glu116 --> Asp of Fuc-Tb slightly increased H-type 1 activity. The acidic residue adjacent to the candidate amino acid Trp/Arg seems to modulate the relative type 1/type 2 acceptor specificity, and its presence is necessary for enzyme activity since its substitution by the corresponding amide inactivated both Fuc-TIII and Fuc-Tb enzymes.     

Cloning and characterization of the alpha(1,3/4) fucosyltransferase of Helicobacter pylori

The gastric pathogen Helicobacter pylori can express the histo blood group antigens, which are on the surface of many human cells. Most H. pylori strains express the type II carbohydrates, Lewis X and Y, whereas a small population express the type I carbohydrates, Lewis A and B. The expression of Lewis A and Lewis X, as in the case of H. pylori strain UA948, requires the addition of fucose in alpha1,4 and alpha1,3 linkages to type I or type II carbohydrate backbones, respectively. This work describes the cloning and characterization of a single H. pylori fucosyltransferase (FucT) enzyme, which has the ability to transfer fucose to both of the aforementioned linkages in a manner similar to the human fucosyltransferase V (Fuc-TV). Two homologous copies of the fucT gene have been identified in each of the genomes sequenced. The characteristic adenosine and cytosine tracts in the amino terminus and repeated regions in the carboxyl terminus are present in the DNA encoding the two UA948fucT genes, but these genes also contain differences when compared with previously identified H. pylori fucTs. The UA948fucTa gene encodes an approximately 52-kDa protein containing 475 amino acids, whereas UA948fucTb does not encode a full-length FucT protein. In vitro, UA948FucTa appears to add fucose with a greater than 5-fold preference for type II chains but still retains significant activity using type I acceptors. The addition of the fucose to the type II carbohydrate acceptors, by UA948FucTa, does not appear to be affected by fucosylation at other sites on the carbohydrate acceptor, but the rate of fucose transfer is affected by terminal fucosylation of type I acceptors. Through mutational analysis we demonstrate that only FucTa is active in this H. pylori isolate and that inactivation of this enzyme eliminates expression of all Lewis antigens.     

Expression of human alpha-l-fucosyltransferase gene homologs in monkey kidney COS cells and modification of potential fucosyltransferase acceptor substrates by an endogenous glycosidase

Previous investigations on the monkey kidney COS cell line demonstrated the weak expression of fucosylated cell surface antigens and presence of endogenous fucosyltransferase activities in cell extracts. RT-PCR analyses have now revealed expression of five homologs of human fucosyltransferase genes, FUT1, FUT4, FUT5, FUT7, and FUT8, in COS cell mRNA. The enzyme in COS cell extracts acting on unsialylated Type 2 structures is closely similar in its properties to the alpha1,3- fucosyltransferase encoded by human FUT4 gene and does not resemble the product of the FUT5 gene. Although FUT1 is expressed in the COS cell mRNA, it has not been possible to demonstrate alpha1,2- fucosyltransferase activity in cell extracts but the presence of Le(y) and blood-group A antigenic determinants on the cell surface imply the formation of H-precursor structures at some stage. The most strongly expressed fucosyltransferase in the COS cells is the alpha1,6-enzyme transferring fucose to the innermost N -acetylglucosamine unit in N - glycan chains; this enzyme is similar in its properties to the product of the human FUT8 gene. The enzymes resembling the human FUT4 and FUT8 gene products both had pH optima of 7.0 and were resistant to 10 mM NEM. The incorporation of fucose into asialo-fetuin was optimal at 5.5 and was inhibited by 10 mM NEM. This result initially suggested the presence of a third fucosyltransferase expressed in the COS cells but we have now shown that triantennary N- glycans with terminal nonreducing galactose units, similar to those present in asialo-fetuin, are modified by a weak endogenous beta-galactosidase in the COS cell extracts and thereby rendered suitable substrates for the alpha1,6- fucosyltransferase.      

Oncofetal expression of Lex carbohydrate antigens in human colonic adenocarcinomas. Regulation through type 2 core chain synthesis rather than fucosylation

The mechanism of expression of a series of glycolipid antigens carrying the Lex determinant structure, Gal beta 1----4[Fuc alpha 1----3]GlcNAc beta 1----, and characterized by oncofetal expression in fetal colon and colonic adenocarcinomas has been studied in human fetal and adult proximal colon tissue. Results presented from TLC immunostain analysis of neutral glycolipids isolated from normal adult colonic mucosa have indicated the presence of only barely detectable quantities of both an Lex-active glycolipid that co-migrated with III3V3Fuc2nLc6 and its precursor nLc6. These structures were found in large quantities in glycolipid fractions from human adenocarcinoma tumors and human small cell lung carcinoma NCI-H69 cells. In contrast, type 1 chain-based Lea antigen structures were found in both normal mucosa and adenocarcinomas. Analysis of gangliosides of normal colonic mucosa by TLC immunostain indicated the presence of a series of type 2 chain-based gangliosides; however, sialyl-Lex was not detected. The ability of normal colonic mucosa to synthesize type 2 chain core structures was demonstrated by the presence of a beta 1----4 galactosyltransferase activity with Lc3 as an acceptor in an amount equivalent to 60-65% of the total galactosyltransferase activity. An alpha 1----3 fucosyltransferase was also found to be expressed in significant quantity in adult colonic mucosa. Kinetic studies indicated that this is most probably the alpha 1----3/4 fucosyltransferase suggested to be a product of the Lewis gene (Le). Thus, although normal adult colonic mucosa contained the enzymes to synthesize Lex and sialyl-Lex structures, these antigens were not found. Tissue immunofluorescence studies indicated that type 2 chain precursors and the alpha 1----3/4 fucosyltransferase were found in different cell populations in adult proximal colonic mucosa. However, both type 2 chain core structures and their fucosylated derivatives were found to be associated with epithelial cells of fetal colon. These results indicate that oncofetal expression of Lex antigens in fetal colonic epithelium and in adenocarcinomas but not in normal adult mucosa is due to the retrogenetic expression of type 2 chain precursors which are not found in normal adult colonic epithelial cells.     

Molecular cloning and characterization of an alpha1,3 fucosyltransferase, CEFT-1, from Caenorhabditis elegans

We report on the identification, molecular cloning, and characterization of an alpha1,3 fucosyltransferase (alpha1,3FT) expressed by the nematode, Caenorhabditis elegans . Although C. elegans glycoconjugates do not express the Lewis x antigen Galbeta1-- >4[Fucalpha1-->3]GlcNAcbeta-->R, detergent extracts of adult C.elegans contain an alpha1,3FT that can fucosylate both nonsialylated and sialylated acceptor glycans to generate the Lexand sialyl Lexantigens, as well as the lacdiNAc-containing acceptor GalNAcbeta1-->4GlcNAcbeta1-- >R to generate GalNAcbeta1-->4 [Fucalpha1-->3]GlcNAcbeta1-->R. A search of the C.elegans genome database revealed the existence of a gene with 20-23% overall identity to all five cloned human alpha1,3FTs. The putative cDNA for the C.elegans alpha1,3FT (CEFT-1) was amplified by PCR from a cDNA lambdaZAP library, cloned, and sequenced. COS7 cells transiently transfected with cDNA encoding CEFT-1 express the Lex, but not sLexantigen. The CEFT-1 in the transfected cell extracts can synthesize Lex, but not sialyl Lex, using exogenous acceptors. A second fucosyltransferase activity was detected in extracts of C. elegans that transfers Fuc in alpha1,2 linkage to Gal specifically on type-1 chains. The discovery of alpha-fucosyltransferases in C. elegans opens the possibility of using this well-characterized nematode as a model system for studying the role of fucosylated glycans in the development and survival of C.elegans and possibly other helminths.      

Acceptor specificity of the human leukocyte alpha3 fucosyltransferase: role of FucT-VII in the generation of selectin ligands

The alpha3 fucosyltransferase, FucT-VII, is one of the key glycosyltransferases involved in the biosynthesis of the sialyl Lewis X (sLex) antigen on human leukocytes. The sialyl Lewis X antigen (NeuAcalpha(2-3)Galbeta(1-4)[Fucalpha(1-3)]GlcNAc-R) is an essential component of the recruitment of leukocytes to sites of inflammation, mediating the primary interaction between circulating leukocytes and activated endothelium. In order to characterize the enzymatic properties of the leukocyte alpha3 fucosyltransferase FucT-VII, the enzyme has been expressed in Trichoplusia ni insect cells. The enzyme is capable of synthesizing both sLexand sialyl-dimeric-Lexstructures in vitro , from 3'-sialyl-lacNAc and VIM-2 structures, respectively, with only low levels of fucose transfer observed to neutral or 3'-sulfated acceptors. Studies using fucosylated NeuAcalpha(2-3)-(Galbeta(1- 4)GlcNAc)3-Me acceptors demonstrate that FucT-VII is able to synthesize both di-fucosylated and tri-fucosylated structures from mono- fucosylated precursors, but preferentially fucosylates the distal GlcNAc within a polylactosamine chain. Furthermore, the rate of fucosylation of the internal GlcNAc residues is reduced once fucose has been added to the distal GlcNAc. These results indicate that FucT-VII is capable of generating complex selectin ligands, in vitro , however the order of fucose addition to the lactosamine chain affects the rate of selectin ligand synthesis.