带3蛋白C端和血型糖蛋白A相互作用及其抗原相关性的研究

采用高效液相色谱法分离鉴定了红细胞膜蛋白质跨膜域的亲水性肽链,结果显示血型糖蛋白A(GPA)Lys101～Asp130与带3蛋白有相关性.为进行深入研究,采用RT-PCR方法从K562细胞中扩增了410 bp的GPA基因,分别克隆到酵母双杂交BD端表达质粒和杆状病毒转移载体上.同时,以含有带3蛋白全长基因的质粒为模板扩增了348 bp的带3蛋白C端基因,将其克隆到酵母双杂交AD端表达质粒.经酵母双杂交营养缺陷培养选择和β半乳糖苷酶检测证实GPA与带3蛋白之间存在相互作用.GPA表达产物分别经抗带3蛋白和抗GPA抗体进行蛋白质印迹分析,表明二者具有免疫交叉反应.上述结果表明带3蛋白与GPA在结构与功能上存在着密切联系.     

血型糖蛋白C是恶性疟原虫配体PfEBP-2(baebl)的红细胞膜受体

恶性疟原虫(Plasmodium falciparum,Pf)红细胞结合蛋白-2(Pferythrocyte binding protein-2,PfEBP-2)是Duffy结合样红细胞结合蛋白(Duffy-binding-like erythrocyte-binding protein,DBL-EBP)家族的一个成员,长期以来Pf入侵人红细胞时该配体所需的受体迄未被确认。2003年Lobo等采用酶处理的红细胞与缺失不同膜表面蛋白的罕见变种红细胞,显示PfEBP-2不与缺失血型糖蛋白C(GPC)的红细胞结合,并且它与缺失外显子2或外显子3的GPC变种进行的结合亦互有差异,因此证明GPC是PfEBP-2(或称baebl,EBA-140)的红细胞膜受体。他们进一步检出GPC分子上的结合域局限在其外显子2的第14￣22位氨基酸残基范围。PfEBP-2与受体的相互作用需要唾液酸,而不涉及血型糖蛋白A(glycophorin A,GPA)或血型糖蛋白B(GPB),它代表了Pf入侵红细胞的一条新途径。Mayer等继续探索了BAEBL(VSTK)变种与GPC结合的特异性,揭示在该Pf配体变种的第II区,围绕Thr-121的两个Arg残基对保证BAEBL(VSTK)同唾液酸结合的特异反应十分关键。并认为,BAEBL的单个点突变将有助Pf识别各种红细胞表面糖蛋白或糖脂分子上的寡糖,从而显著拓宽了其入侵的范围。     

红细胞4．1蛋白与血型糖蛋白C／D结合位点研究进展

红细胞膜骨架与脂双层间存在着相互作用,其中带4.1蛋白与血型糖蛋白C/D间的相互作用对维持正常红细胞的形态和机械稳定性起着重要作用,研究表明,带4.1蛋白在血型糖蛋白C、D上的结合位点分别位于血型糖蛋白C的第82～98位氨基酸残基和血型糖蛋白D的第61～77位氨基酸残基．     

一种鉴定MNSs红细胞血型单克隆抗体类型的方法的建立

为鉴定MNSs血型单克隆细胞株6D7C9分泌的抗体类型,通过克隆、亚克隆、细胞转染等分子生物学技术建立了血型糖蛋白GPA、GPB的异源表达系统,并将其作为抗原,通过ELISA、Western 印迹法确定6D7C9分泌的McAb.结果显示,RT－PCR技术成功克隆获得了GPA、GPB血型糖蛋白编码基因,通过分别构建其重组逆转录病毒表达载体pEGZ/GPA及pEGZ/GPB,转染包装细胞293T,再感染L929细胞,经zeocin筛选2周后,RT PCR及流式细胞仪分析证实,L929/GPA和L929/GPB转基因细胞中分别有GPA、GPB目的基因的转录和蛋白表达.用稳定高表达GPA、GPB的转基因细胞通过ELISA和Western 印迹法证实单克隆细胞株6D7C9分泌的是抗GPA/GPB McAb.本研究成功地建立了血型糖蛋白GPA、GPB的异源表达系统,为MNSs血型McAb的检测及GPA、GPB蛋白的功能学研究奠定了基础.     

红细胞膜带4.2蛋白的结构与功能

带4.2蛋白是一种重要的红细胞膜蛋白,与红细胞的形态、可变形性及携氧功能有至关重要的联系。它通过与带3蛋白(阴离子通道蛋白)、锚蛋白结合,稳定的连接在细胞膜的内表面,连接着膜骨架网架结构与细胞膜,是膜骨架与脂质双分子层连接的重要纽带。带4.2蛋白的缺失会引起球形或椭圆形红细胞增多症及不同程度的溶血性贫血,严重的情况需要摘除脾脏来进行治疗。近年来研究认为,带4.2蛋白在维持细胞膜骨架的完整性和稳定性方面扮演了重要角色。现对带4.2蛋白结构及功能的研究状况进行综述。     

人红细胞膜上的A,B和H血型抗原物质

血型物质是在红细胞膜上存在的表现血型特异的抗原物质。在人的红细胞膜上具有 A,B,H 和 Lewis 血型特异的抗原物质,如糖蛋白,糖脂和游离的低聚糖。血型特异的糖蛋白是唾液以及胃液等分泌液的组分。具有血型活性的低聚糖可在乳汁和尿中找到。活性的糖脂是红细胞膜和血清的组分。     

人红细胞膜带3蛋白的提纯与鉴定

提出了一种分离纯化人红细胞膜带3蛋白的不含血型糖蛋白制剂的改良方法:先后用0.89％NaCl、20mM pH8.0磷酸钠和0.05％TritonX-100处理膜除去膜骨骼蛋白类和血型糖蛋白,再用自行设计的凝胶制备电泳装置进一步纯化。冰冻干燥的制剂是均质的,得率为18.5±2.85％,它的分子量、氨基酸组成和紫外吸收光谱与文献报道基本相同。     

人红细胞膜上可能存在4．1－血型糖蛋白C与p55蛋白的相互作用

人红细胞膜上可能存在４．１－血型糖蛋白Ｃ与ｐ５５蛋白的相互作用卢义钦，刘俊凡（湖南医科大学生化教研室，长沙４１００７８）关键词人红细胞膜，蛋白ｐ５５，相互作用人红细胞膜的一些膜蛋白，通过彼此间的相互作用可形成错综复杂的膜下网络，呈现一定的双向或立体结...     

蛋白4.1基因家族的研究进展

近几年,先后发现了三种与红细胞中的4.1蛋白同源性很高的蛋白质,这四种蛋白质都具有三个功能性结构域,即膜结合结构域,血影蛋白-肌动蛋白结合结构域和羧基端结构域.而且除了已知的在细胞膜物理和生理特性维持方面的重要作用外,4.1蛋白还与有丝分裂以及神经突触的形成有关.     

逆转录法筛选mRNA靶点设计核酶对GPA的表达干预实验研究

采用自行设计5’固定3’随机的文库对基因mRNA进行杂交用于逆转录反应以筛选mRNA的寡核苷酸结合靶点。对人I型跨膜糖蛋白-血型糖蛋白A （glycophorin A,GPA）的mRNA筛选了4个反义寡核苷酸可结合靶点,分别设计反义核酸（Antisense）,分别加入mRNA中用RNase H验证各靶点的核酸结合和切割效率,最终确定2个高效结合和切割靶点。再设计Ribozyme,构建表达核酶（Ribozyme）质粒,利用慢病毒（Lentivirus）包装技术,感染人源红系白血病细胞株K562细胞,在细胞水平验证其下调GPA基因表达的效果,对转染细胞mRNA进行反转录和Real Time PCR分析mRNA表达水平,并在蛋白水平进行了Western Blot分析。结果表明文库结合逆转录方法筛选靶点设计的Ribozyme具有高效率下调膜受体表达的作用,GPA为I型跨膜糖蛋白,该实验为筛选mRNA靶点提供参考方法,并对膜受体表达干预有参考价值。     

Evolution of glycophorin A in the hominoid primates studied with monoclonal antibodies, and description of a sialoglycoprotein analogous to human glycophorin B in chimpanzee

Comparison of human and primate erythrocyte membrane sialoglycoproteins showed that common chimpanzee, dwarf chimpanzee, gorilla, orangutan, and gibbon have major periodic acid Schiff-positive proteins resembling human glycophorin A (GPA) monomer and dimer in electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gels. Immunoperoxidase staining of Western blots with monoclonal antibodies to human GPA showed that these primate bands express some GPA antigenic determinants. A new sialoglycoprotein analogous to human glycophorin B (GPB) was detected in common chimpanzee. Although human MN blood group phenotype results from an amino acid polymorphism of GPA, Western blots showed that in chimpanzee sialoglycoprotein (GPAch) always expresses the M blood group, whereas chimpanzee sialoglycoprotein (GPBch) expresses either the N blood group or a null phenotype. This result explains the detection of M and MN, but not of N, blood group phenotypes in chimpanzee. GPBch has higher apparent m.w. than human GPB, is present in the erythrocyte membrane in greater quantity than human GPB, and contains trypsin cleavage site(s) and the 10F7 determinant (both found on human GPA but not GPB). Expression of human GPA antigenic determinants was consistent with the phylogeny of the hominoid primates; common and dwarf chimpanzee expressed most of the determinants tested, gorilla and orangutan an intermediate number, and gibbon and siamang the least. Of the GPA antigenic determinants examined, the MN blood group determinants were most consistently expressed during evolution of the hominoid primates. The results suggested that variability in expression of GPA antigenic determinants between species was due to both differences in amino acid sequence and glycosylation.     

New procedures for glycophorin A purification with high yield and high purity

Glycophorin A (GPA) is the major glycoprotein of the human erythrocyte membrane. It is known to form, in SDS gels as well as in a membrane environment, homodimers, and also heterodimers with the homologous molecule Glycophorin B (GPB). It is shown in this report that the propensity of GPA to dimerize with GPB precludes satisfactory preparation with high yield of pure GPA using classical techniques including SEC and RPLC. It was demonstrated using multiple angle light scattering that GPA is eluted from RPLC columns as dimers. A convenient procedure was devised which allowed us to get pure GPA with high yield. This procedure consists of selectively blocking GPA–GPB heterodimer formation by selective modification of Cysteine 50 of GPB before RPLC.     

A novel gene member of the human glycophorin A and B gene family. Molecular cloning and expression

A new gene closely related to the glycophorin A (GPA) and glycophorin B (GPB) genes has been identified in the normal human genome as well as in that of persons with known alterations of GPA and/or GPB expression. This gene, called glycophorin E (GPE), is transcribed into a 0.6-kb message which encodes a 78-amino-acid protein with a putative leader peptide of 19 residues. The first 26 amino acids of the mature protein are identical to those of M-type glycophorin A (GPA), but the C-terminal domain (residues 27-59) differs significantly from those of glycophorins A and B (GPA and GPB). The GPE gene consists of four exons distributed over 30 kb of DNA, and its nucleotide sequence is homologous to those of the GPA and GPB genes in the 5' region, up to exon 3. Because of branch and splice site mutations, the GPE gene contains a large intron sequence partially used as exons in GPA and GPB genes. Compared to its counterpart in the GPB gene, exon 3 of the GPE gene contains several point mutations, an insertion of 24 bp, and a stop codon which shortens the reading frame. Downstream from exon 3, the GPE and the GPB sequences are virtually identical and include the same Alu repeats. Thus, it is likely that the GPE and GPB genes have evolved by a similar mechanism. From the analysis of the GPA, GPB and GPE genes in glycophorin variants [En(a-), S-s-U- and Mk], it is proposed that the three genes are organized in tandem on chromosome 4. Deletion events within this region may remove one or two structural gene(s) and may generate new hybrid structures in which the promoter region of one gene is positioned upstream from the body of another gene of the same family. This model of gene organization provides a basis with which to explain the diversity of the glycophorin gene family.     

Biochemical roles of the oligosaccharide chains in thyrostimulin, a heterodimeric hormone of glycoprotein hormone subunits alpha 2 (GPA2) and beta 5 (GPB5)

Thyrostimulin is a heterodimeric hormone composed of GPA2 and GPB5, and shares the thyroid-stimulating hormone receptor (TSHR). Thyrostimulin has three N-linked oligosaccharide chains, two in GPA2 and one in GPB5. The roles of these N-linked oligosaccharides in secretion, heterodimer formation and signal transduction were analyzed. Recombinant GPA2s lacking either of the two oligosaccharides were obtained from conditioned medium, whereas dual site-disrupted GPA2 and the GPB5 mutant were not expressed in either the conditioned medium or cell lysate. The binding between GPA2 and GPB5 was weaker than that between TSH subunits GPA1 and TSH beta. Neither of the oligosaccharides in GPA2 had significant effects on heterodimerization. Disruption of either of the oligosaccharides in GPA2 significantly decreased receptor activation, suggesting their critical role in receptor activation.     

The G-protein beta subunit GPB1 is required for mating and haploid fruiting in Cryptococcus neoformans

Cryptococcus neoformans is an opportunistic fungal pathogen with a defined sexual cycle. The gene encoding a heterotrimeric G-protein beta subunit, GPB1, was cloned and disrupted. gpb1 mutant strains are sterile, indicating a role for this gene in mating. GPB1 plays an active role in mediating responses to pheromones in early mating steps (conjugation tube formation and cell fusion) and signals via a mitogen-activated protein (MAP) kinase cascade in both MATalpha and MATa cells. The functions of GPB1 are distinct from those of the Galpha protein GPA1, which functions in a nutrient-sensing cyclic AMP (cAMP) pathway required for mating, virulence factor induction, and virulence. gpb1 mutant strains are also defective in monokaryotic fruiting in response to nitrogen starvation. We show that MATa cells stimulate monokaryotic fruiting of MATalpha cells, possibly in response to mating pheromone, which may serve to disperse cells and spores to locate mating partners. In summary, the Gbeta subunit GPB1 and the Galpha subunit GPA1 function in distinct signaling pathways: one (GPB1) senses pheromones and regulates mating and haploid fruiting via a MAP kinase cascade, and the other (GPA1) senses nutrients and regulates mating, virulence factors, and pathogenicity via a cAMP cascade.     

Molecular analysis of glycophorin A and B gene structure and expression in homozygous Miltenberger class V (Mi. V) human erythrocytes

In the Miltenberger class V (Mi. V) condition, red cells lack glycophorin A (GPA) and glycophorin B (GPB) but carry instead an unusual glycoprotein thought to be a hybrid molecule produced by the unequal crossing-over between the closely linked genes encoding for GPA and GPB. By Western blot analysis with rabbit anti-GPA antibodies specific for discrete domains of GPA, it was found that the Mi. V glycoprotein (donor F. M.) contains approximately 60 amino acid residues of GPA at its N-terminus. As a preliminary approach to the molecular analysis of this variant the restriction maps of the GPA and GPB genes were established by Southern blot analysis of genomic DNA and from genomic clones isolated from a human leukocyte library constructed in lambda EMBL4. The GPA and GPB genes cover about 30 kb of DNA and are organized into seven exons (A-1-A-7) and five exons (B-1-B-5), respectively. In addition to the normal genes, a third gene (named inv), closely resembling the GPA and GPB genes, was also identified. In the homozygous Mi. V individual the normal GPA and GPB genes were absent, but an unusual form of gene structure was detected by Southern blot analysis. The Mi. V glycoprotein gene was composed of exon B-1 of the GPB gene followed by exons A-2 and A-3 of the GPA gene and the exons B-3, B-4 and B-5 of the GPB gene. Exon B-1 can be distinguished from exon A-1 of GPA since it is located within a different restriction fragment, but both encode the same amino acid sequence (N-terminal region of the signal peptides). Using the polymerase chain reaction, the junction between exon A-3 and exon B-3 was confirmed by amplification of the DNA region where the putative crossing-over has occurred and it was deduced that the Mi. V glycoprotein is a hybrid molecule composed of amino acid residues 1-58 from GPA fused to amino acid residues 27-72 of GPB. In addition, the finding that part of the signal peptide and the 5'-untranslated region are derived from GPB suggests that the genetic background of the Mi. V variant is rather complex and may involve a cascade of recombination or gene conversion events.     

Studies on human red-cell membrane glycophorin A and glycophorin B genes in glycophorin-deficient individuals.

1. Genomic DNA derived from individuals who lack glycophorin A (GPA), glycophorin B (GPB) or both of these proteins was subjected to Southern-blot analysis using GPA and GPB cDNA probes. 2. Bands on the Southern blots were assigned to the GPA gene, GPB gene or to a putative pseudogene. 3. Genomic DNA derived from an individual of the Mk phenotype was shown to have deletions in the GPA and GPB genes. The simplest model for the results obtained is that a single deletion spans the GPA and GPB genes in the individual studied.