A novel alpha1,2-fucosyltransferase (CE2FT-2) in Caenorhabditis elegans generates H-type 3 glycan structures

The 1,2-fucosyltransferase family (1,2FT) is the largest familyof glycosyltransferases in the genome of the free-living nematodeCaenorhabditis elegans, and early evidence suggests that eachmember may have a unique activity. Here we describe a C. elegansgene (designated CE2FT-2) encoding an 1,2FT that has the potentialto generate the sequence Fuc1-2Galβ1-3GalNAc-R, which isthe H-type 3 blood group structure. The CE2FT-2 cDNA encodesa putative transmembrane protein that shows 42% amino acid identityto a previously cloned C. elegans 1,2FT (termed CE2FT-1), buthas a very low identity (16–20%) to 1,2FT sequences inhumans, rabbits, and mice. A recombinant form of CE2FT-2 expressedin human 293T cells has a high 1,2FT activity toward Galβ1-3GalNAc-O-pNP,but unexpectedly, the enzyme is inactive toward the acceptorGalβ-O-phenyl. Thus, CE2FT-2 differs from all other 1,2FTspreviously described from animals that all utilize Galβ-O-phenyl.CE2FT-2 is expressed at all stages of worm development, butremarkably, promoter analysis of the CE2FT-2 gene using greenfluorescent protein reporter constructs indicates that the CE2FT-2is expressed exclusively in pharyngeal cells of the worm fromembryo to an adult stage. Because pharyngeal cells are knownto secrete their glycoconjugates to the nematode surface, theseresults may indicate that products of CE2FT-2 contribute tointeractions of the nematode with its environment or are usedas ligands for bacterial attachment. These findings, along withthose on other 1,2FTs in C. elegans, suggest that each 1,2FTin this organism may have a unique acceptor specificity, expressionpattern, and biological function.     

Engineering Chinese hamster ovary cells to maximize effector function of produced antibodies using FUT8 siRNA

We explored the possibility of converting established antibody-producing cells to cells producing high antibody-dependent cellular cytotoxicity (ADCC) antibodies. The conversion was made by constitutive expression of small interfering RNA (siRNA) against alpha1,6 fucosyltransferase (FUT8). We found two effective siRNAs, which reduce FUT8 mRNA expression to 20% when introduced into Chinese hamster ovary (CHO)/DG44 cells. Selection for Lens culinaris agglutinin (LCA)-resistant clones after introduction of the FUT8 siRNA expression plasmids yields clones producing highly defucosylated (approximately 60%) antibody with over 100-fold higher ADCC compared to antibody produced by the parental cells (approximately 10% defucosylated). Moreover, the selected clones remain stable, producing defucosylated antibody even in serum-free fed-batch culture. Our results demonstrate that constitutive FUT8 siRNA expression can control the oligosaccharide structure of recombinant antibody produced by CHO cells to yield antibodies with dramatically enhanced ADCC.     

Structure/function study of Lewis alpha3- and alpha3/4-fucosyltransferases: the alpha1,4 fucosylation requires an aromatic residue in the acceptor-binding domain

All vertebrate alpha3- and alpha3/4-FUTs possess the characteristic acceptor-binding motif VxxHH(W/R)(D/E). FUT6 and FUTb enzymes, harboring R in the acceptor-binding motif, transfer fucose in alpha1,3 linkage, whereas FUT3 and FUT5 enzymes with W at the candidate position can also transfer fucose in alpha1,4 linkage-FUT3 being more efficient than FUT5. To determine the involvement of the W/R residue in acceptor recognition, we produced 34 variants of human FUT3, FUT5, FUT6, and ox FUTb Lewis enzymes. Among the FUT3 variants where W(111) was replaced by the other amino acids, only enzymes with an aromatic residue at the candidate position kept about 50% of alpha1,4 activity and showed no changes in K(m) values for GDP-Fuc donor and H-type 1 acceptor substrates. All other substitutions produced enzymes with less than 20% of the alpha1,4 activity. Thus the ability of alpha3/4-FUTs to recognize type 1 substrates involves the aromatic character of W in the acceptor-binding domain. The alpha1,3 activity of FUT6 and FUTb significantly decreased when their R residue was substituted by basic or charged residues. Moreover, FUT3 and FUT5 variants with W-->R substitution had a better affinity for H-type 2 substrate and higher alpha1,3 activities. Therefore the optimal fucose addition in alpha1,3 linkage requires the R residue in the acceptor-binding motif of Lewis FUTs.     

LacZ expression in Fut2-LacZ reporter mice reveals estrogen-regulated endocervical glandular expression during estrous cycle, hormone replacement, and pregnancy

The secretor gene (FUT2) encodes an alpha(1,2)fucosyltransferase (E.C. 2.4.1.69) that elaborates alpha(1,2)fucose residues on mucosal epithelium and secreted mucins. Though uterine alpha(1,2)fucosylated glycans have been proposed to be involved in embryo adhesion, mice with a homozygous null mutation of Fut2 displayed normal fertility. To help develop alternative hypotheses for function, the cell type and regulation of Fut2 expression during the estrous cycle, hormone replacement, and pregnancy was examined in Fut2-LacZ reporter mice containing targeted replacement of Fut2 with bacterial lacZ. LacZ expression in the reproductive tract of Fut2-LacZ mice is most prominent in the glandular epithelium of the endocervix during estrus and pregnancy. Nuclear LacZ expression identifies cell-specific expression of Fut2 in mucus-secreting cells of the endocervix, uterine glands, foveolar pit and chief cells of the stomach, and goblet cells of the colon. In ovariectomized Fut2-LacZ mice, estradiol treatment stimulates X-gal staining in endocervix and uterus but does not affect expression in stomach and colon. Northern blot analysis in wild-type mice shows 15-fold elevations of Fut2 steady-state mRNA with estradiol treatment, whereas Fut1 varies little. Fut2 levels in the glandular stomach and distal colon remain constant, and uterine Fut2 levels vary eightfold during the estrous cycle. These data represent the first demonstration of a glycosyltransferase gene under tissue-specific hormonal regulation in a LacZ reporter mouse model. Endocervical expression of Fut2 in estrus and pregnancy may modify cervical mucus barrier properties from microbial infection analogous to the potential role of mucosal glycans in humans.     

Effect of the manganese ion on human α3/4 fucosyltransferase III activity

The effect of manganese and other divalent cations on the activity of a soluble recombinant form of human 3/4 fucosyltransferase III (SFT3) expressed in Spodoptera frugiperda (Sf9) insect cells was studied. SFT3 was active in the absence of divalent cations with an optimum pH of 4.5. In the absence of Mn²⁺ increasing the pH from 4.5 to 7.0 caused a decrease in the affinity of SFT3 for the acceptor Gal3GlcNAcO(CH₂)₃NHCO(CH₂)₅NH-biotin, as monitored by the 4-fold increase in the apparent K_M value (0.9 to 3.3 mM). At pH 7.0, the addition of Mn²⁺ activated the enzyme and caused an increase in the affinity of SFT3 for the acceptor, as monitored by the 5-fold decrease of the apparent K_M value (3.3 to 0.7 mM). In solution, a complex between GDP-Fuc donor and the divalent cation Mn²⁺ was observed by electrospray ionization mass spectrometry, in a 1:1 stoichiometry. These results indicated that Mn²⁺ bound the enzyme and increased its affinity for the acceptor; one possible functional role of manganese in catalysis could be as an electrophilic catalyst, co-ordinating the negative charges of the phosphate groups of the GDP-Fuc donor and promoting Fuc transfer. At low pH values such role would be played by the proton.     

The fucosyltransferase gene family: an amazing summary of the underlying mechanisms of gene evolution

The fucosyltransferase gene family encodes enzymes that transfer fucose in 1,2, 1,3/4 and 1,6 linkages on a large variety of glycans. The most ancient genes harbour a split coding sequence, and encode enzyme that transfer fucose at or near O- and N-peptidic sites (serine, threonine or chitobiose unit). Conversely, the more recent genes have a monoexonic coding sequence, and encode enzymes that transfer fucose at the glycan periphery. All basic mechanisms of gene evolution contribute to this amazing scenario: exon shuffling, transposition, point mutations, and duplication. As typical examples: (i) exon shuffling leads to the ancestral organization of the 1,6 fucosyltransferase gene; (ii) the ancestor of 1,2 fucosyltransferase genes is reshaped by retrotransposition at the same locus; (iii) duplication associated to point mutations leads to the most recent 1,3/4 fucosyltransferase genes.     

Fucosyltransferase substrate specificity and the order of fucosylation in invertebrates

Core alpha1,6-fucosylation is a conserved feature of animal N-linked oligosaccharides being present in both invertebrates and vertebrates. To prove that the enzymatic basis for this modification is also evolutionarily conserved, cDNAs encoding the catalytic regions of the predicted Caenorhabditis elegans and Drosophila melanogaster homologs of vertebrate alpha1,6-fucosyltransferases (E.C. 2.4.1.68) were engineered for expression in the yeast Pichia pastoris. Recombinant forms of both enzymes were found to display core fucosyltransferase activity as shown by a variety of methods. Unsubstituted nonreducing terminal GlcNAc residues appeared to be an obligatory feature of the substrate for the recombinant Caenorhabditis and Drosophila alpha1,6-fucosyltransferases, as well as for native Caenorhabditis and Schistosoma mansoni core alpha1,6-fucosyltransferases. On the other hand, these alpha1,6-fucosyltransferases could not act on N-glycopeptides already carrying core alpha1,3-fucose residues, whereas recombinant Drosophila and native Schistosoma core alpha1,3-fucosyltransferases were able to use core alpha1,6-fucosylated glycans as substrates. Lewis-type fucosylation was observed with native Schistosoma extracts and could take place after core alpha1,3-fucosylation, whereas prior Lewis-type fucosylation precluded the action of the Schistosoma core alpha1,3-fucosyltransferase. Overall, we conclude that the strict order of fucosylation events, previously determined for fucosyltransferases in crude extracts from insect cell lines (core alpha1,6 before core alpha1,3), also applies for recombinant Drosophila core alpha1,3- and alpha1,6-fucosyltransferases as well as for core fucosyltransferases in schistosomal egg extracts.     

Significance of each of three missense mutations, G484A, G667A, and G808A, present in an inactive allele of the human Lewis gene (FUT3) for α(1,3/1,4)fucosyltransferase inactivation

Recently, we found three novel missense mutations, G484A (Asp162Asn), G667A (Gly223Arg), and G808A (Val270Met), present in a Lewis-negative allele (le484,667,808) from an African (Xhosa) population. To define the relative contribution of each of the three mutations in the le484,667,808 allele for inactivation of the FUT3-encoded enzyme, we made chimeric FUT3 containing each of the three mutations. A transient expression study indicated that COS7 cells transfected with the FUT3 construct containing the G484A mutation expressed the Lewis antigen and had about 20% enzyme activity as compared with COS7 cells transfected with the wild type FUT3 allele, whereas COS7 cells transfected with the FUT3 construct containing either the G667A mutation or the G808A mutation did not express the Lewis antigen and showed no detectable (1,3/1,4)fucosyltransferase activity. These results suggest that the G667A and/or the G808A missense mutations of FUT3 alleles are responsible for the inactivation of the FUT3-encoded enzyme.     

Production via good manufacturing practice of exofucosylated human mesenchymal stromal cells for clinical applications

Background

The regenerative and immunomodulatory properties of human mesenchymal stromal cells (hMSCs) have raised great hope for their use in cell therapy. However, when intravenously infused, hMSCs fail to reach sites of tissue injury. Fucose addition in α(1,3)-linkage to terminal sialyllactosamines on CD44 creates the molecule known as hematopoietic cell E-/L-selectin ligand (HCELL), programming hMSC binding to E-selectin that is expressed on microvascular endothelial cells of bone marrow (BM), skin and at all sites of inflammation. Here we describe how this modification on BM-derived hMSCs (BM-hMSCs) can be adapted to good manufacturing practice (GMP) standards.

基于单细胞超高通量筛选的α-1,2-岩藻糖基转移酶定向进化

2’-岩藻糖基乳糖在婴幼儿配方奶粉、保健品和医药等产品开发方面极具应用价值。幽门螺杆菌(Helicobacter pylori NCTC11639)来源的α-1,2-岩藻糖基转移酶(FutC)是目前合成2’-岩藻糖基乳糖的重要生物催化剂,但是天然酶存在异源表达量低、催化活性差等缺陷。针对α-1,2-岩藻糖基转移酶定向进化过程中缺少高通量筛选方法的问题,发展了基于荧光激活细胞分选(fluorescence-activated cell sorting,FACS)的FutC超高通量筛选方法。对FutC进行了定向进化实验,通过对FutC的随机突变库进行了3轮筛选,从库容量为5.4×10⁵突变文库中成功筛选出活力提高2.6倍、2.7倍、3倍的3种突变体(K282E,K102E,R105C),证明了此筛选方法的有效性。本研究为α-1,2-岩藻糖基转移酶的分子活性改造奠定了良好基础。