卵巢激素对小鼠围着床期子宫内膜Le^y寡糖表达的调控

研究表明Le^y寡糖介导了胚胎与子宫内膜之间的识别与粘附,在胚胎植入中起重要作用。其α1,2、α1,3岩藻糖基的合成分别与α1,2岩藻糖基转移酶（FUT1）、α1,3岩藻糖基转移酶（FUT4）的催化作用密切相关,应用Western印迹、免疫组化和半定量RT-PCR方法,观察小鼠妊娠早期、去卵巢后雌孕激素处理的子宫内膜Le^y寡糖抗原以及其合成相关的FUT1、FUT4基因的表达,分析卵巢激素对Le^y寡糖表达的调控,结果显示：妊娠早期,FUT1、FUT4基因的转录水平随孕激素水平上程式而呈下降的趋势,这与Le^y寡糖抗原表达一致。进一步观察发现,去卵巢后经孕激素处理,FUT1、FUT4基因及Le^y寡糖抗原表达均较对照组降低,雌激素处理组表达则明显升高;雌孕激素联合作用介于雌激素组和孕激素组之间,结果表明,孕激素能下调FUT1、FUT4基因的表达。雌激素对其有上调作用,两种激素之间表现为相互拮抗,提示雌孕激素可能通过FUT1、FUT4基因转录水平调控Le^y寡糖抗原在小鼠子宫内膜上皮的表达。     

RNA干扰敲减FucT VII表达抑制人结肠癌细胞HT-29和HUVECs的粘附能力

 探讨利用RNA干扰（RNAi）技术抑制岩藻糖基转移酶Ⅶ（FucT Ⅶ）表达对人结肠癌细胞HT-29与人脐静脉内皮细胞（HUVEC）粘附能力的影响及其机制.本课题构建3对针对FucT Ⅶ基因的RNAi表达载体,并将其转染入人结肠癌细胞HT-29,Western 印迹检测FucT Ⅶ及其下游产物sLeX蛋白的变化;实时PCR 检测FucT Ⅶ mRNA表达的变化;玫瑰红染色法检测RNAi 对HT-29与HUVECs细胞粘附能力的影响.结果显示,3对FucT Ⅶ siRNA表达载体均可有效抑制HT-29细胞FucT Ⅶ mRNA和蛋白表达,以pSilencer 2.0 FucT Ⅶ 2最为有效;与空白细胞组比较,转染pSilencer 2.0-FucT Ⅶ的HT-29细胞表面sLeX表达水平明显下降,以pSilencer 2.0-FucT Ⅶ 2最为显著;RNA干扰FucT Ⅶ表达后HT 29细胞和HUVEC之间的粘附能力明显受到抑制.研究表明,RNAi靶向沉默HT-29细胞中FucT Ⅶ基因表达可显著降低其下游产物sLeX的合成,进而抑制HT-29细胞与HUVECs的粘附能力.     

Murine monoclonal antibody recognizing human α(1,3/1,4)fucosyltransferase

We prepared a mouse monoclonal antibody, FTA1-16, that specifically recognizes human (1,3/1,4)fucosyltransferase without crossreactivity to any other members of the (1,3)fucosyltransferase family. The specificity was confirmed by both immunofluorescense staining of native antigens in the Golgi apparatus and Western blotting analysis, using stable transformant cells transfected with each gene of the (1,3)fucosyltransferase family. Western blotting analysis on a series of human tumour cell lines from various tissues revealed that some epithelial cancer cell lines from digestive organs expressed an amount of (1,3/1,4)fucosyltransferase in good correlation with expression of sialyl Lewis a antigen. Immunohistochemical staining by FTA1-16 on colon cancer tissues revealed enhanced expression of the enzyme in cancer cells in comparison to normal cells. Finally, the antigenic epitope recognized by FTA1-16 was determined using truncated recombinant peptides which were expressed inE. coli. A minimal length determined was a fragment, amino acid positions 132–153, of the (1,3/1,4)fucosyltransferase.     

Molecular basis for erythrocyte Le(a+b+) and salivary ABH partial-secretor phenotypes: expression of a FUT2 secretor allele with an A→T mutation at nucleotide 385 correlates with reducedα(1,2) fucosyltransferase activity

TheSe ^wA385T mutation of the FUT2 gene was found to correlate with both the erthrocyte Le(a+b+) and/or salivary ABH partial-secretor phenotypes of Polynesians. Constructs with FUT1 and FUT2 wild type genes, and the FUT2Se ^wA385T,se ^G428A andse ^C571T mutated alleles, were cloned into pcDNAI, and expressed in COS-7 cells. COS-7 cells transfected with theSe ^wA385T allele had weak, but detectable, (1,2)fucosyltransferase activity, with an acceptor substrate pattern similar to the wild type FUT2 gene. Comparative kinetic studies from cell extracts with mutatedSe ^wA385T and wild type FUT2 alleles gave similarK _m values, but less enzyme activity was present in cells transfected withSe ^wA385T (V _max 230 pmol h^–1 mg^–1), as compared to those transfected with FUT2 (V _max 1030 pmol h^–1 mg^–1), suggesting that the mutated enzyme is more unstable. These results confirm that the molecular basis for the erythrocyte Le(a+b+) and the associated ABH salivary partial-secretor phenotype, is an amino acid change of Ile 129Phe in the secretor (1,2)fucosyltransferase.Abbreviations (1,3/1,4)fucosyltransferase GDP-L-fucose:-D-N-acetylglucosaminide 3/4--L-fucosyltransferase - (1,2)fucosyltransferase GDP-L-fucose: -D-galactoside-2--L-fucosyltransferase - bp base pairs - FUT1 H gene; FUT2,Se gene - FUT3 Lewis gene or Fuc-TIll gene - FUT4 Fuc-TIV gene - FUT5 Fuc-TV gene - FUT6 Fuc-TVI gene - MAb monoclonal antibody - PCR polymerase chain reaction - RFLP restriction fragment length polymorphism - se ^G428A FUT2 nonsecretor GA mutation at nucleotide 428 - se ^C571T FUT2 nonsecretor CT mutation at nucleotide 571 - Se ^wA385T FUT2 secretor weak AT mutation at nucleotide 385 - SSP sequence specific primer     

Fucosylated umbilical cord blood hematopoietic stem cell expansion on selectin-coated scaffolds

Despite the advantages of transplantation of umbilical cord blood's (UCB's) hematopoietic stem cells (uHSCs) for hematologic malignancy treatment, there are two major challenges in using them: (a) Insufficient amount of uHSCs in a UCB unit; (b) a defect in uHSCs homing to bone marrow (BM) due to loose binding of their surface glycan ligands to BM's endothelium selectin receptors. To overcome these limitations, after poly l -lactic acid (PLLA) scaffold establishment and incubation of uHSCs with fucosyltransferase-VI and GDP-fucose, ex vivo expansion of these cells on selectin-coated scaffold was done. The characteristics of the cultured fucosylated and nonfucosylated cells on a two-dimensional culture system, PLLA, and a selectin-coated scaffold were evaluated by flow cytometry, 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay, colony-forming unit (CFU) assay, and CXCR4 expression at the messenger RNA and protein levels. According to the findings of this study, optimized attachment to the scaffold in scanning electron microscopy micrograph, maximum count of CFU, and the highest 570 nm absorption were observed in fucosylated cells expanded on selectin-coated scaffolds. Furthermore, real-time polymerase chain reaction showed the highest expression of the CXCR4 gene, and immunocytochemistry data confirmed that the CXCR4 protein was functional in this group compared with the other groups. Considered together, the results showed that selectin-coated scaffold could be a supportive structure for fucosylated uHSC expansion and homing by nanotopography. Fucosylated cells placed on the selectin-coated scaffold serve as a basal surface for cell–cell interaction and more homing potential of uHSCs. Accordingly, this procedure can also be considered as a promising technique for the hematological disorder treatment and tissue engineering applications.     

Specificity of DC-SIGN for mannose- and fucose-containing glycans

The dendritic cell specific C-type lectin dendritic cell specific ICAM-3 grabbing non-integrin (DC-SIGN) binds to "self" glycan ligands found on human cells and to "foreign" glycans of bacterial or parasitic pathogens. Here, we investigated the binding properties of DC-SIGN to a large array of potential ligands in a glycan array format. Our data indicate that DC-SIGN binds with K(d)<2muM to a neoglycoconjugate in which Galbeta1-4(Fucalpha1-3)GlcNAc (Le(x)) trisaccharides are expressed multivalently. A lower selective binding was observed to oligomannose-type N-glycans, diantennary N-glycans expressing Le(x) and GalNAcbeta1-4(Fucalpha1-3)GlcNAc (LacdiNAc-fucose), whereas no binding was observed to N-glycans expressing core-fucose linked either alpha1-6 or alpha1-3 to the Asn-linked GlcNAc of N-glycans. These results demonstrate that DC-SIGN is selective in its recognition of specific types of fucosylated glycans and subsets of oligomannose- and complex-type N-glycans.     

CEACAM1, an adhesion molecule of human granulocytes, is fucosylated by fucosyltransferase IX and interacts with DC-SIGN of dendritic cells via Lewis x residues

The CEA-related cell adhesion molecule 1, CEACAM1, is a glycoprotein expressed on the surface of human granulocytes and lymphocytes, endothelia, and many epithelia. CEACAM1 is involved in the regulation of important biological processes, such as tumor growth, angiogenesis, and modulation of the immune response. CEACAM1, a member of the immunoglobulin superfamily carries several Lewis x (Lex) structures as we recently demonstrated by mass spectrometry of native CEACAM1 from human granulocytes. Since Lex residues of pathogens bind to the C-type lectin dendritic cell-specific ICAM-3 grabbing nonintegrin (DC-SIGN) expressed on human DCs, we hypothesized that Lex glycans of CEACAM1 are recognized by DC-SIGN. Here, we demonstrate that CEACAM1, the major carrier of Lex residues in human granulocytes, is specifically recognized by DC-SIGN via Lex residues mediating the internalization of CEACAM1 into immature DCs. Expression studies with CEACAM1 in combination with different fucosyltransferases (FUTs) revealed that FUTIX plays a key role in the synthesis of Lex groups of CEACAM1. As Lex groups on CEACAM1 are selectively attached and specifically interact with DC-SIGN, our findings suggest that CEACAM1 participates in immune regulation in physiological conditions and in pathological conditions, such as inflammation, autoimmune disease, and cancer.