一株人抗人A—血型物质单克隆抗体特异性的研究

本文对一株人抗人A-血型物质单克隆抗体,用定量免疫沉淀法以及ELISA研究其与多种单糖、双糖及寡糖的反应性,从而确定了其结合部位的结构特异性。实验发现其结合部位互补于含有双分子岩藻糖残基的A-t糖:这一研究进一步强调了含有双分子岩藻糖残基的A血型抗原决定簇的重要性。     

A血型单克隆抗体的抗原结合部位结构多样性研究

应用杂交瘤技术,以Ａ型红细胞,Ａ１血型物质ＭＳＭ（Ａ１）和Ａ－ＲＢＣ＋ＭＳＭ（Ａ１）为免疫原,制备了一组抗人Ａ血型单克隆抗体：Ａ１２１８,Ｂ５７,ＤＥ９２３－Ｇ８,Ｄ２８６－Ｅ１２经Ｔａｋａｔｓｙ微量血细胞凝集试验证明：这组单抗仅能凝集Ａ１,Ａ２及ＡＢ型红细胞,不能凝集Ｂ,Ｏ型红细胞．采用ＥＬＩＳＡ定量抑制试验法,精确测定了它们抗原结合部位的结构,互补于Ａ活性寡糖。Ａ１２１８互补于具有双岩藻糖结构的Ａ活性五糖（Ａ－Ｐｅｎｔａ）;Ｂ５７,ＤＥ９２３－Ｇ８互补于具有单岩藻糖结构的Ａ活性六糖（Ａ－Ｈｅｘａ）;而Ｄ２８６－Ｅ１２则互补于具有单岩藻糖的Ａ活性四糖（Ａ－Ｔｅｔｒａ）．结果表明：血凝特异性相同的抗Ａ单抗,其抗原结合部位的结构可呈现多样性。即Ａ活性寡糖的糖基组成数目和含有岩藻糖数目均可不相同,各种抑制剂对不同单抗的抑制作用强弱也不相同。     

Y盒结合蛋白1单克隆抗体的研制、表位测定及其免疫学应用

建立稳定分泌抗人Y盒结合蛋白1单克隆抗体(anti-YB-1 mAb)的杂交瘤细胞株,鉴定其表位与免疫学应用。将重组YB-1蛋白免疫BALB/c小鼠,取脾细胞与Sp2/0骨髓瘤细胞融合。经ELISA法筛选鉴定、定株后采用腹水诱生法制备anti-YB-1 mAb;Protein G亲和层析法纯化mAb,ELISA法测定mAb效价、亚型及相对亲和力。采用抗原表位预测法鉴定anti-YB-1 mAb识别表位所在区域。Western blot和免疫组化鉴定mAb识别内源性YB-1的特异性。经筛选鉴定获得2株稳定分泌anti-YB-1 mAb的杂交瘤细胞(1-D9,3-E8);腹水抗体效价均≥1×10-6,亚型均为IgGl;1-D9和3-E8单抗识别表位分别位于(134-160aa)与(266-303aa)肽段。Western blot、免疫组化结果证实anti-YB-1 mAb能特异性识别内源性YB-1。该研究为YB-1免疫学定性、定量检测方法的建立、肿瘤靶向抗体治疗及进一步探讨YB-1的生物学功能奠定了基础。     

A血型单克隆抗体的抗原结合部位结构多样性研究

应用杂交瘤技术,以Ａ型红细胞,Ａ１血型物质ＭＳＭ（Ａ１）和Ａ－ＲＢＣ＋ＭＳＭ（Ａ１）为免疫原,制备了一组抗人Ａ血型单克隆抗体：Ａ１２１８,Ｂ５７,ＤＥ９２３－Ｇ８,Ｄ２８６－Ｅ１２经Ｔａｋａｔｓｙ微量血细胞凝集试验证明：这组单抗仅能凝集Ａ１,Ａ２及ＡＢ型红细胞,不能凝集Ｂ,Ｏ型红细胞。采用ＥＬＩＳＡ定量抑制试验法,精确测定了它们抗原结合部位的结构,互补于Ａ活性寡糖。Ａ１２１８互补于具有双岩藻糖结构     

鸡传染性贫血病毒VP3蛋白单克隆抗体的制备

以原核表达的鸡传染性贫血病毒(CIAV)VP3蛋白作为免疫原,免疫BALB/c小鼠,三次免疫后,取免疫小鼠脾细胞与SP2/0细胞融合,融合阳性细胞用间接ELISA方法检测,阳性细胞株经三代克隆纯化后,获得三株能稳定分泌抗CIAV VP3蛋白单克隆抗体的杂交瘤细胞株,分别命名为AG2、BC11、FG1。三株杂交瘤细胞株产生的细胞培养液上清和小鼠腹水的ELISA效价分别为2.5ⅹ102、1.5ⅹ102、1ⅹ102和2ⅹ106、1ⅹ106、2.5ⅹ105。与其它禽类病毒的交叉实验表明：这三株单抗具有良好的抗CIAV VP3蛋白特异性。该特异性单克隆抗体的研制成功为进一步研究VP3的生物学特性打下了基础。     

木菠萝凝集素结合部位糖的特异性

用定量免疫沉淀法和定量免疫沉淀抑制法研究了从木菠萝(Arthrocarpus integrifolia)种子提取的凝集素(jacalin)结合部位糖的特异性。Jacalin最强烈地沉淀含有DGalβ1→3DGalNAc结构的无活性抗冻糖蛋白,不同程度非特异地沉淀各种血型物质。研究发现凝集素结合部位对DGalβ→3DGalNAc有最高特异性。最强抑制剂是DGalβ1→3DGalNAcal→φNO_2,其抑制活性分别比DGalNAc和DGal高380倍和1000倍。对于各种甲基化或对硝基酚化的糖苷以及寡糖,除methylaDGalNAc_f外,仅α-构型表现出抑制活性,所有β-构型的糖苷均无抑制活性,jacalin结合部位对糖的结合是构型依赖性的。     

hGH单克隆抗体的筛选及双抗体夹心ELISA检测方法的建立

采用杂交瘤法制备单克隆抗体,并用辛酸-硫酸铵法纯化单抗,通过ELISA方法和Western blotting测定抗体的效价与特异性,并进行抗体类型、相对亲和力测定;应用纯化的单抗建立hGH双抗体夹心ELISA检测方法。筛选出两株可以稳定分泌抗hGH单抗的杂交瘤细胞株,分别命名为3E11、2G9,抗体类型均为IgG1,抗体滴度均可达10-10,特异性好,相对亲和力高,以筛选到的两株单抗建立的双抗夹心ELISA法线性范围为0.09～1.5625ng/mL,R2>0.9,灵敏度为0.09ng/mL。筛选出高效抗hGH的单抗,并建立了hGH双抗体夹心ELISA检测方法。     

抗鸡白细胞介素4单克隆抗体的制备及鉴定

为了制备鸡白细胞介素4(chIL-4)单克隆抗体,将成熟的chIL-4基因亚克隆至原核表达载体pET-28a和pGEX-6P-1上,然后在大肠杆菌中分别诱导重组蛋白His-chIL-4和GST-chIL-4的表达,并纯化。将纯化后的His-chIL-4作为免疫原免疫BALB/c小鼠,经4次免疫后,取小鼠脾细胞与骨髓瘤细胞(SP2/0)融合。将纯化后的GST-chIL-4作为筛选抗原,利用间接ELISA筛选阳性克隆。阳性细胞株经3次亚克隆后,获得3株稳定分泌抗chIL-4蛋白的杂交瘤细胞株,分别命名为1G11-3B、2E5-3D和1G11-5H。经ELISA检测,3株单克隆抗体的亚型均为IgG1,亲和力解离常数(Kd)分别为1.79×10~(–9)、1.61×10~(–9)和2.36×10~(–9)。经Western blotting及间接免疫荧光试验鉴定,3株单克隆抗体均能特异性识别原核和真核表达的chIL-4蛋白。Western blotting试验证明1G11-3B、2E5-3D和1G11-5H识别的抗原表位区域分别为chIL-4蛋白N端的第1–40、80–112和40–80位氨基酸。该单克隆抗体的制备为chIL-4的检测和生物学功能研究奠定了基础。     

兔支气管败血波氏杆菌单克隆抗体的制备及鉴定

目的建立能稳定分泌抗兔支气管败血波氏杆菌（Bb）的单克隆抗体杂交瘤细胞株,为今后进一步建立该菌的免疫检测技术奠定基础。方法以Bb分离株BLJ05的灭活菌液为免疫原,腹腔免疫BALB/c小鼠,采用常规杂交瘤技术制备Bb单克隆抗体（McAb）,用间接ELISA、Western-blot等方法对McAb特性进行鉴定。结果获得两株能稳定分泌抗Bb单克隆抗体的杂交瘤细胞株,分别命名为A7D5和D6B2,其小鼠腹水抗体效价分别为1∶409600和1∶102400;且不与兔大肠杆菌、多杀性巴氏杆菌、产气荚膜梭菌等兔的常见病原菌反应,特异性强。两株单抗亲和力实验表明A7D5亲和力略高于D6B2。ELISA相加试验表明它们针对相同的抗原表位。结论成功建立了两株能稳定分泌抗兔支气管败血波氏杆菌单克隆抗体的杂交瘤细胞株,效价高、特异性强,为今后建立该菌的免疫检测技术建立奠定了基础。     

NT-proBNP特异性单克隆抗体的制备及鉴定

旨在制备并鉴定抗人NT-pro BNP特异性单克隆抗体。采用重组NT-pro BNP蛋白免疫Balb/c小鼠,取血清效价高的脾细胞与SP2/0细胞融合,经HAT筛选和有限稀释法亚克隆,获得阳性杂交瘤细胞株,用动物体内诱生法制备腹水,用正辛酸-硫酸铵沉淀法将抗体纯化,并测定抗体的亚类、效价、特异性及相对亲和力。结果表明,获得4株能稳定分泌抗人NT-pro BNP单克隆抗体的阳性杂交瘤细胞株,分别命名为1G12、1B2、3D5和2D11。抗体Ig亚类,1G12和1B2为Ig G2a型,2D11为Ig G1型,3D5为Ig G2b型;1G12,1B2和3D5的抗体效价达到106,而2D11的效价仅达104。特异性好,1G12、1B2、3D5和2D11四株抗体的亲和常数依次为9.32×1011、1.07×1012、2.31×1012和6.33×1010。成功制备了特异性抗人NT-pro BNP单克隆抗体。     

The EPR spectrum of cytochrome b-563 in the cytocrhome bf complex from spinach: (1993) FEBS Letters 164, 71–74

Blood group H antigen with globo-series structure, reacting with the monoclonal antibody MBrl, was isolated and characterized from human blood group O erythrocytes. The structure was identified by methylation analysis, direct probe mass spectrometry, and ¹H-nuclear magnetic resonance spectroscopy as shown below: Fucαl → 2Galβl → 3GalNAcβl → 3Galαl → 4Galβl → 4Glcβl → 1Cer     

Structural characterization of glycolipids of rat small intestine having one to eight hexoses in a linear sequence

Eight different fractions containing glycolipids with 1 to 8 hexoses in a linear sequence were isolated from rat small intestine. The structure of the major components was established by mass spectrometry and proton nuclear magnetic resonance spectroscopy of the permethylated and permethylated-reduced (LiAlH₄) derivatives and by gas-liquid chromatography of degradation products of the native and permethylated or permethylated-reduced glycolipids. The major compounds were glucosylceramide, lactosylceramide, globotriaosylceramide, and a novel tetrahexosylceramide with the structure Gal α 1 → 3Galα1 → 4Galβ1 → 4Glcβ1 → 1Cer. In addition four minor compounds having five to eight hexoses were identified with the probable structures Galα1 → 3Galα1 → 3Galα1 → 4Galβ1 → 4Glcβ1 → 1Cer, Galα1 → 3Galα1 → 3Galα1 → 3Galα1 → 4Galβ1 → 4Glcβ1 → 1Cer, Gal1 → 3Gal1 → 3Gal1 → 3Gal1 → 3Gal1 → 4Gal1 → 4Glc1 → 1Cer, and Gal1 → 3Gal1 → 3Gal1 → 3Gal1 → 3Gal1 → 3Gal1 → 4Gal1 → 4Glc1 → 1Cer. In the pentahexosylceramide fraction a novel fucolipid was also present having the probable structure Fucα1 → 2Galα1 → 3Galα1 → 4Galβ1 → 4Galβ1 → 1Cer. The lipophilic part of the glycolipids was composed of trihydroxy 18:0 and dihydroxy 18:1 long-chain bases in combination with nonhydroxy and hydroxy 16:0–24:0 fatty acids. Glycolipid studies of isolated mucosal epithelial cells and the nonepithelial intestinal residue revealed a specific cell distribution of these hexosyl compounds. The two major components, glucosylceramide and globotriaosylceramide, were mainly located in the epithelial cells together with small amounts of lactosylceramide and tetrahexosylceramide. The epithelial cells practically lacked however the penta- to octahexosylceramides. The nonepithelial residue contained all hexosyl compounds. The fucolipid was exclusively present in the epithelial cells.     

Different asparagine-linked sugar chains on the two polypeptide chains of human chorionic gonadotropin

Human chorionic gonadotropin (hCG) purified from placenta, like urinary hCG, is shown to have the sialylated forms of three neutral oligosaccharides: Galβ1→4GlcNAcβ1→2Manα1→6(Galβ1→4GlcNAcβ1→2Manα1→3)Manβ1→4GlcNAcβ1→4(Fucα1→6)GlcNAc (N-1), Galβ1→4GlcNAcβ1→2Manα1→6(Galβ1→4GlcNAcβ1→2Manα1→3)Manβ1→4GlcNAcβ1→4GlcNAc (N-2) and Manα1→6(Galβ1→4GlcNAcβ1→2Manα1→3)Manβ1→4GlcNAcβ1→4GlcNAc (N-3). Gel permeation chromatographic analysis of oligosaccharides released from α- and β-subunits of placental hCG has revealed that the α-subunit has one each of sialylated N-2 and N-3, while the β-subunit has one each of sialylated N-1 and N-2.     

Structural studies of the carbohydrate moiety of human antithrombin III

Human antithrombin III contains four asparagine-linked sugar chains in one molecule. The sugar chains were quantitatively released as radioactive oligosaccharides from the polypeptide portion by hydrazinolysis followed by N-acetylation and NaB³H₄ reduction. All of the oligosaccharides, thus obtained, contain N-acetylneuraminic acid. A same neutral nonaitol was released from all acidic oligosaccharides by sialidase treatment. By combination of the sequential exoglycosidase digestion and methylation analysis, their structures were elucidated as NeuAcα2 → 6Galβ1 → 4GlcNAcβ1 → 2Manα1 → 6-(NeuAcα2 → 6Galβ1 → 4GlcNAcβ1 → 2Manα1 → 3)Manβ1 → 4GlcNAcβ1 → 4GlcNAc, Galβ1 → 4GlcNAcβ1 → 2Manα1 → 6(NeuAcα2 → 6Galβ1 → 4GlcNAcβ1 → 2Manαl → 3)Manβ1 → 4GlcNAcβ1 → 4GlcNAc, and NeuAcα2 → 6Galβ1 → 4GlcNAcβ1 → 2Manα1 → 6(Galβ1 → 4GlcNAcβ1 → 2Manα1 → 3)Manβ1 → 4GlcNAcβ1 → 4GlcNAc.     

The hapten structure of a developmentally regulated glycolipid antigen (SSEA-1) isolated from human erythrocytes and adenocarcinoma: a preliminary note

Glycolipid antigen reacting to the monoclonal antibody directed to the developmentally regulated antigen SSEA-1 was isolated from human erythrocytes and colonic adenocarcinoma. The antigens have the Le^x (Galβl→4[Fucα]→3]GlcNAcβl→R) or Le^y (Fucαl→2Galβl→4[Fucαl→3]GlcNAcβl→R) structure at the termini of the branched polylactosaminolipid. In addition, a novel polyfucosyl structure locating exclusively at the internal GlcNAc was detected in the tumor antigen. The antibody reacts with a simple monovalent Le^x glycolipid (Galβl→4[Fucαl→3]GlcNAcβl→3Galβl→4Glcβl→Cer) previously isolated from colonic carcinoma when presented at a high density on liposomes. The antibody therefore may react to the bivalent or multivalent Le^x or Le^y structure.     

Receptors for glucocorticoids in lung tissue

Gas chromatography-mass spectrometric identification of partially methylated aminosugars has been developed: (a) various kinds of O-methylated 2-deoxy-2-(N-methyl)-acetamidohexitols were prepared from partially O-(1-methoxy)-ethylated 2-deoxy-2-acetamidohexoses, and their gas chromatography-mass spectrometric patterns were determined; (b) permethylated glycolipids gave a satisfactory yield of 2-deoxy-2-N-methyl-amidohexoses by acetolysis with 0.5 n sulfuric acid in 95% acetic acid, followed by aqueous hydrolysis; (c) the resulting partially methylated aminosugars and neutral sugars were analyzed after borohydride reduction and acetylation according to the procedure of Lindberg and associates (Björndal, Lindberg and Svennson, 1967; Björndal, Hellerqvist, Lindberg and Svensson, 1970).This method was successfully applied to analysis of aminosugar linkages in blood group B-active ceramide pentasaccharide from rabbit erythrocytes and in Forssman antigen of equine spleen. The structure of blood group B-active glycolipid of rabbit erythrocyte was found to be Galα1 → 3Galβ1 → 4G1cNAcβ1 → 3Ga11 → 4Glc → Cer, and that of Forssman antigen to be GaNAcα1 → 3GalNAcβ1 → 3Galα1 → 4Ga11 → 4Glc → Cer.     

ABO blood group system

The ABO blood group system in humans has three different carbohydrate antigens named A, B, and O. The A antigen sequence is terminal trisaccharide N-acetylgalactosamine (GalNAc)α1-3[Fucα1-2]Galβ-, B is terminal trisaccharide Galα1-3[Fucα1-2]Galβ-, and O is terminal disaccharide Fucα1-2Galβ-. The single ABO gene locus has three alleles types A, B and O. The A and B genes code A and B glycosyltransferases respectively and O encodes an inactive enzyme. A large allelic diversity has been found for A and B transferases resulting in the genetic subgrouping of each ABO blood type. Genes for both transferases have been cloned and the 3D structure of enzymes with and without substrate has been revealed by NMR and X ray crystallography. The ABO blood group system plays a vital role in transfusion, organ and tissue transplantation, as well as in cellular or molecular therapies.