免疫不育疫苗的研究进展

免疫不育疫苗主要以哺乳动物的精子或卵子蛋白以及在受精和胚胎早期发育过程中发挥重要作用的激素为靶抗原。以激素为抗原的不育疫苗产生的不育效果多为不可逆的,且对机体损伤较大。以精子表面抗原制备的疫苗能够诱导产生精子抗体和不育效果,目前已成为避孕研究的一个热点。哺乳动物卵透明带（zona pellucida,ZP）是覆盖于卵母细胞及着床前受精卵外的一层基质,其在调节精卵特异性结合、诱导获能精子发生顶体反应和阻止多精受精等方面发挥着重要作用。ZP相对分子质量较小且免疫原性强,是免疫不育疫苗理想的靶抗原,抗ZP抗体可阻断精卵结合,故可被用作人类避孕和免疫不育控制有害动物种群数量的靶抗原,但人用ZP疫苗免疫机体后造成的卵巢功能损伤和免疫抑制等问题尚有待明确。     

人及哺乳动物受精与糖蛋白的关系

越来越多的研究表明精卵识别与精子质膜及卵透明带中所含糖蛋白有直接关系。在精卵识别中存在着精子受体和卵透明带（zona pellucida,ZP）配体相互作用的糖类识别机制及精子质膜与卵子质膜的糖蛋白识别。本文主要从结构功能上对与受精相关的精卵表面糖蛋白作一介绍。卵子表面受精相关的糖蛋白主要是ZP1、ZP2、ZP3。与卵子表面糖蛋白相比,精子表面参与精卵识别的糖蛋白种类较多,在SP56、SP95、PH－20、FA－1、甘露糖结合蛋白、顶体素、fertilin蛋白等。     

哺乳动物受精过程中精子和透明带的初级及次级结合

在哺乳动物的受精过程中,获能的精子穿过卵丘细胞层到达卵子透明带后,精子头部便结合在透明带的表面上.精子和透明带的结合可以分为初级结合和次级结合两个阶段,初级结合是指二者在顶体反应之前的结合,次级结合是指二者在顶体反应之后的结合.精子和透明带的结合是精子顶体反应和精子入卵的先决条件,是哺乳动物受精过程中非常重要的环节,涉及到精子以及透明带的多种蛋白质分子之间的相互作用.这方面的研究工作主要是以小鼠为实验对象进行的,在其他哺乳动物中也有很多报道.本文将主要以小鼠为例,概述哺乳动物受精过程中精子和透明带结合的分子机制,并兼述在二者的结合过程中透明带糖蛋白ZP3对精子顶体反应的诱导作用.     

银鲫ZP3的表达特征和卵壳ZP3蛋白的分离

克隆得到银鲫(Carassius auratus gibelio)ZP3基因全长cDNA,在体外表达出银鲫的ZP3融合蛋白,并制备出多抗血清;通过免疫印迹和RT-PCR分析,研究了银鲫ZP3在卵子发生过程中的表达特征和在早期发育胚胎中的状态变化。研究结果表明,银鲫ZP3的转录发生在卵黄发生以前,而ZP3蛋白的翻译起始于卵黄形成阶段,且随着卵母细胞进一步成熟,其含量不断增加。ZP3蛋白的存在状态在受精后和早期胚胎发育过程中发生了明显变化。在受精后5—30min期间,抽提液中原始的ZP3蛋白带迅速消失,取而代之的是分子量大约为90KD以及更高分子量的蛋白带;而在受精后80min和8—16胞期的胚胎抽提液中,二聚体和多聚体复合体蛋白带也相继消失。这种状态变化意味着ZP3蛋白在卵子受精后有可能与自身或其他蛋白共价结合转变成了二聚体和多聚体。接着,用获得的ZP3抗体作为检测指标,通过卵壳蛋白的凝胶分离,从卵壳中分离纯化出银鲫ZP3蛋白。     

卵母细胞透明带异常及其对助孕结局影响的研究进展

人类透明带(zona pellucida,ZP)是在卵泡发生过程中由卵母细胞和颗粒细胞共同分泌的由ZP1-ZP4四种糖蛋白分子组成的高度有序结构,它与卵母细胞的成熟、受精、胚胎发育及妊娠结局等预后紧密关联。许多生殖中心实验室发现有些患者的卵出现全部或部分的透明带异常,而且不同实验室发现的透明带异常类型各异。研究发现这些透明带异常与卵母细胞受精、胚胎发育及临床结局有一定的相关性。本文综述了关于透明带异常及其对卵母细胞受精、胚胎发育潜能和临床结局的影响的研究进展。     

哺乳动物精子中的ZP3结合蛋白研究进展

哺乳动物卵透明带糖蛋白ZP3(zona pellucida3)是介导精卵初级结合、诱发精子发生顶体反应的关键分子。目前已在精子中发现多种ZP3结合蛋白。95kD酪氨酸激酶受体可能通过其酪氨酸激酶活性介导ZP3诱发的顶体反应。β—1,4—半乳糖基转移酶与ZP3的糖基结合后,通过激活下游信号分子诱发顶体反应。精子蛋白sp56可能介导了顶体反应期间顶体基质与ZP之间的相互作用。透明带粘附素(zonadhesin)也是在顶体反应发生之后才与ZP发生相互作用。这些精子蛋白介导的下游信号事件将是下一步研究的热点。     

小鼠卵ZP3蛋白的可溶性表达、纯化及免疫活性鉴定

哺乳动物卵透明带3(Zona pellucida 3,ZP3)在诱导获能精子发生顶体反应中发挥着重要作用,其在大肠杆菌中主要以包涵体形式表达。本研究在大肠杆菌中诱导表达可溶性的mZP3融合蛋白,并鉴定该蛋白的免疫活性。将小鼠卵透明带3克隆至pMAL-p2x质粒,转化至大肠杆菌BL21表达菌中。用不同温度、不同IPTG浓度、不同诱导时间及不同浓度的添加剂诱导目的蛋白表达,以筛选出mZP3融合蛋白可溶性表达的最佳条件。大量表达纯化后以Western blotting和ELISA检测蛋白的免疫活性。酶切鉴定及DNA测序表明mZP3已克隆入pMAL-p2x质粒。经优化诱导表达条件,筛选出mZP3融合蛋白可溶性表达的最佳条件为:当A600为0.6时添加0.02 mol/L葡萄糖,以0.6 mmol/L IPTG于25oC条件下诱导表达4 h。ELISA及Western blotting检测结果表明诱导表达的蛋白具有免疫活性。在大肠杆菌中表达并纯化获得可溶性mZP3蛋白,为mZP3免疫不育疫苗研制及其免疫效果检测提供了可溶性抗原。     

重组人卵透明带ZP3蛋白在毕赤酵母中的表达

利用P.pastoris表达人卵透明带ZP3蛋白。设计特定引物从全长hZP3 cDNA上扩增含跨膜区序列的人卵透明带ZP3基因片段,并在N末端接上串联组氨酸编码序列的重组基因序列;扩增片段插入表达载体pPIC9K中;线性化后的重组质粒转入P.pastoris中,用高浓度G418筛选高拷贝菌株,然后甲醇诱导目的蛋白表达。用SDS-PAGE和Western blot分析表达产物。结果发现P.pastoris表达的人ZP3蛋白可以分泌到培养液中,并且可溶性好。纯化前后的重组人ZP3蛋白均能与兔抗猪ZP3蛋白抗体发生交叉反应,证实表达的目的蛋白具有反应原性。     

猪卵透明带ZP3α真核表达载体的构建及体外瞬时表达

目的：构建猪卵透明带zP3α真核表达栽体,为探讨卵透明带DNA疫苗避孕疫苗奠定基础。方法：采用PCR法获得了去除N端信号肽序列和C端跨膜区序列的猪卵透明带ZP3α的cDNA序列片段,以专门用于发展DNA疫苗的质粒pVAX1为载体构建了真核细胞表达质粒pvAX1-pZP3α。通过脂质体转染将之导入HeLa细胞进行体外瞬时表达,然后采用RT—PGR和间接免疫荧光技术(IIF)检测pZP3α在mRNA水平的转录和蛋白质水平上的表达。结果：真核细胞表达质粒pVAX1-pZP3α构建成功,用RT-PCR和IIF技术检测到了pZP3α在HeLa胞中的转录与表达。结论：真核表达载体pVAX1—pzP3aα的成功构建和表达为研制开发有效的人用卵透明带DNA避孕疫苗奠定了基础。     

PolyI:C协同IL-15作为小鼠卵透明带3基因疫苗佐剂黏膜免疫效果的观察

目的:以Toll样受体拮抗物Poly I:C协同细胞因子IL-15作为免疫佐剂,通过滴鼻方式免疫ICR小鼠,对卵透明带3(murine zona pellucida,m ZP3)基因疫苗的免疫增强效果进行观察。方法:将Poly I:C和IL-15单独或协同与用壳聚糖(chitosan,Chi)包裹的m ZP3基因疫苗滴鼻免疫ICR小鼠,ELISA法检测小鼠血清中特异性抗m ZP3抗体和生殖道黏液、肺洗液中s Ig A的水平,MTT法检测淋巴细胞增殖,小鼠的平均窝仔数和生育率检测抗生育情况,组织学观察小鼠的卵巢病理切片。结果:Poly I:C协同IL-15共同免疫组能够显著提高免疫后小鼠抗m ZP3抗体的水平,促进淋巴细胞的增殖,平均窝仔数和生育率显著降低,小鼠的卵巢发育异常。结论:Poly I:C协同IL-15能够增强m ZP3基因疫苗的免疫效果,并在一定程度上降低小鼠生育率。     

Recombinant mouse sperm ZP3-binding protein (ZP3R/sp56) forms a high order oligomer that binds eggs and inhibits mouse fertilization in vitro

Many candidates have been proposed as zona pellucida-binding proteins. Without precluding a role for any of those candidates, we focused on mouse sperm protein ZP3R/sp56, which is localized in the acrosomal matrix. The objective of this study was to analyze the role of ZP3R/sp56 in mouse fertilization. We expressed recombinant ZP3R/sp56 as a secreted protein in HEK293 cells and purified it from serum-free, conditioned medium. In the presence of reducing agents, the recombinant ZP3R/sp56 exhibited a molecular weight similar to that observed for the native ZP3R/sp56. Reminiscent of the native protein, recombinant ZP3R/sp56 formed a high molecular weight, disulfide cross-linked oligomer consisting of six or more monomers under non-reducing conditions. Recombinant ZP3R/sp56 bound to the zona pellucida of unfertilized eggs but not to 2-cell embryos, indicating that the changes that take place in the zona pellucida at fertilization affected the interaction of this protein with the zona pellucida. The extent of in vitro fertilization was reduced in a dose-dependent manner when unfertilized eggs were preincubated with recombinant ZP3R/sp56 (74% drop at the maximum concentrations assayed). Eggs incubated with the recombinant protein showed an absence of or very few sperm in the perivitelline space, suggesting that the reduction in the fertilization rate is caused by the inhibition of sperm binding and/or penetration through the zona pellucida. These results indicate that sperm ZP3R/sp56 is important for sperm-zona interactions during fertilization and support the concept that the acrosomal matrix plays an essential role in mediating the binding of sperm to the zona pellucida.     

Sperm binding to the zona pellucida is not sufficient to induce acrosome exocytosis

At fertilization, spermatozoa bind to the zona pellucida (ZP1, ZP2, ZP3) surrounding ovulated mouse eggs, undergo acrosome exocytosis and penetrate the zona matrix before gamete fusion. Following fertilization, ZP2 is proteolytically cleaved and sperm no longer bind to embryos. We assessed Acr3-EGFP sperm binding to wild-type and huZP2 rescue eggs in which human ZP2 replaces mouse ZP2 but remains uncleaved after fertilization. The observed de novo binding of Acr3-EGFP sperm to embryos derived from huZP2 rescue mice supports a ;zona scaffold' model of sperm-egg recognition in which intact ZP2 dictates a three-dimensional structure supportive of sperm binding, independent of fertilization and cortical granule exocytosis. Surprisingly, the acrosomes of the bound sperm remain intact for at least 24 hours in the presence of uncleaved human ZP2 regardless of whether sperm are added before or after fertilization. The persistence of intact acrosomes indicates that sperm binding to the zona pellucida is not sufficient to induce acrosome exocytosis. A filter penetration assay suggests an alternative mechanism in which penetration into the zona matrix initiates a mechanosensory signal transduction necessary to trigger the acrosome reaction.     

Identification of human sperm peptide sequence involved in egg binding for immunocontraception

Development of a vaccine based on sperm antigens represents a promising approach to contraception. The sperm-zona pellucida (ZP) interaction constitutes the most important event in the fertilization process, and the molecular sequences involved at this site may provide the most attractive candidates for immunocontraception. In the present study, using the phase peptide display technique, a novel dodecamer sequence, designated as YLP(12), was identified that is involved in sperm-ZP recognition/binding. The synthetic 12-mer peptide based on this sequence and its monovalent Fab' antibodies specifically and significantly (P < 0.05) inhibited human sperm-ZP binding. In Western blot and immunoprecipitation procedures, the YLP(12) peptide recognized the ZP3 component of solubilized human ZP proteins. In the Western blot procedure involving 10 different human tissue extracts, the anti-YLP(12) Fab' antibodies recognized a protein band of approximately 72 +/- 2 kDa only in the testis lane. The peptide sequence was localized on the acrosomal region of the human sperm cell. These findings indicate that the novel testis-specific 12-mer YLP(12) that is present in the acrosomal region and is involved in human sperm-ZP interaction may find applications in contraceptive vaccine development, as well as in diagnosis and treatment of male infertility mediated through sperm dysfunction.     

Profile of a mammalian sperm receptor

Complementary molecules on the surface of eggs and sperm are responsible for species-specific interactions between gametes during fertilization in both plants and animals. In this essay, several aspects of current research on the mouse egg receptor for sperm, a zona pellucida glycoprotein called ZP3, are addressed. These include the structure, synthesis, and functions of the sperm receptor during oogenesis and fertilization in mice. Several conclusions are drawn from available information. These include (I) ZP3 is a member of a unique class of glycoproteins found exclusively in the extracellular coat (zona pellucida) of mammalian eggs. (II) ZP3 gene expression is an example of oocyte-specific and, therefore, sex-specific gene expression during mammalian development. (III) ZP3 is a structural glycoprotein involved in assembly of the egg extracellular coat during mammalian oogenesis. (IV) ZP3 is a sperm receptor involved in carbohydrate-mediated gamete recognition and adhesion during mammalian fertilization. (V) ZP3 is an inducer of sperm exocytosis (acrosome reaction) during mammalian fertilization. (VI) ZP3 participates in the secondary block to polyspermy following fertilization in mammals. (VII) The extracellular coat of other mammalian eggs contains a glycoprotein that is functionally analogous to mouse ZP3. The unique nature, highly restricted expression, and multiple roles of ZP3 during mammalian development make this glycoprotein a particularly attractive subject for investigation at both the cellular and molecular levels.     

Enhanced contraceptive response by co-immunization of DNA and protein vaccines encoding the mouse zona pellucida 3 with minimal oophoritis in mouse ovary

Zona pellucida 3 (ZP3) acts as the primary sperm receptor, induces autoantibody that can prevent oocyte fertilization and has been proposed as a vaccine candidate for contraception in humans. Due to the elicited autoreactive T cell inflammation that causes ovarian destruction, ZP3-based vaccine with removed T epitopes from the ZP3 is considered as a preferred approach. We present here a new strategy to eliminate the T cell inflammation while retaining a high level of antibody by co-immunization of mZP3 DNA and protein vaccines, which resulted in a higher reduction rate of fertility in this group. Histological analysis showed that there were normal follicular developments of infertile mice in the co-immunized group; while other vaccine groups of the most infertile mice lacked mature follicles. There was a significant correlation between normal follicular development and the inhibition of T cell response in co-immunized mice. At the same time, co-immunization reduced the production of inflammatory cytokine, IFN-gamma, and increased the productions of IL-10 and FoxP3 in CD4 T cells, suggesting the anti-inflammation may be via a T regulatory function. The results indicate that co-immunization of mZP3 DNA- and protein-based vaccines can reduce fertility without interfering with the normal follicular development and present a novel strategy to develop a contraceptive vaccine in humans.     

Phosphoinositide-dependent pathways in mouse sperm are regulated by egg ZP3 and drive the acrosome reaction

Sperm of many animals must complete an exocytotic event, the acrosome reaction, in order to fuse with eggs. In mammals, acrosome reactions are triggered during sperm contact with the egg extracellular matrix, or zona pellucida, by the matrix glycoprotein ZP3. Here, we show that ZP3 stimulates production of phosphatidylinositol-(3,4,5)-triphosphate in sperm membranes. Phosphatidylinositol-3-kinase antagonists that prevent acrosome reactions and fertilization in vitro, while generation of this phosphoinositide in the absence of ZP3 triggered acrosome reactions. Downstream effectors of phosphatidylinositol-(3,4,5)-triphosphate in sperm include the protein kinases, Akt and PKCzeta. These studies outline a signal transduction pathway that plays an essential role in the early events of mammalian fertilization.     

Recombinant mouse ZP3 inhibits sperm binding and induces the acrosome reaction.

Mammalian fertilization involves interactions of sperm surface receptors with ligands of the zona pellucida, an extracellular matrix surrounding the ovulated egg. In mouse, the zona is composed of three glycoproteins. One of them, ZP3, participates in primary sperm binding and in the subsequent triggering of the sperm's acrosome reaction. Considerable evidence suggests that carbohydrate determinants of ZP3 are responsible for binding to sperm and may be important for acrosomal exocytosis. A full-length cDNA encoding mouse ZP3 was assembled and cloned into expression vectors that contained either a cytomegalovirus (CMV) or a vaccinia (P11) promoter. Mouse L-929 cells were stably transformed with the pZP3-CMV constructs, and green monkey CV-1 cells were infected with a recombinant vaccinia virus containing ZP3. rZP3 was affinity purified from culture media and detected on Western blots as a single 60- to 70-kDa band, which differed in molecular weight from native ZP3 (mean, 83 kDa). Nevertheless, rZP3 is biologically active. rZP3 decreases sperm-zona binding with a potency equivalent to that of native zona pellucida and, like native ZP3, rZP3 triggers acrosomal exocytosis in capacitated mouse sperm. Thus, rZP3 isolated from both rodent and primate cells appears to contain those carbohydrate and protein structures necessary for ZP3's dual role in fertilization.     

Distinct membrane fractions from mouse sperm bind different zona pellucida glycoproteins.

Interactions between sperm and zona pellucida (ZP) during mammalian fertilization are not well characterized at the molecular level. To identify sperm proteins that recognize ligand ZP3, we used sonicated sperm membrane fractions as competitors in a quantitative binding assay. Sonicated membranes were density fractionated into 4 fractions. Bands 1-3 contained membrane vesicles, and band 4 contained axonemal and midpiece fragments. In competitive binding assays, bands 1, 2, and 3 but not band 4 were able to compete with live, capacitated, intact sperm for soluble 125I-ZP binding. Affinity-purified ZP fractions consisting of a ZP3-enriched fraction (125I-ZP3) and a fraction enriched for ligands ZP1 and ZP2 and depleted of ZP3 (125I-ZP1/2) were obtained by antibody affinity purification of ZP3. In competitive binding assays, bands 2 and 3 competed for 125I-ZP3 binding, but band 1 did not interact with enriched 125I-ZP3. None of the membrane fractions competed for 125I-ZP1/2 binding. These results demonstrate that band 2 and band 3 contain sperm components that interact with ZP3 alone and that components in band 1 interact with ZP3 in conjunction with either ZP1 or ZP2. These data indicate that there must be at least 2 unique sperm plasma membrane components that mediate intact sperm interactions with ZP glycoproteins in mouse. Bands 2 and 3 are likely to contain a primary ZP-binding protein because they interacted directly with ZP3, whereas band 1 may contain sperm proteins involved in later interactions with the ZP, perhaps transitional interactions to maintain sperm contact with the ZP during acrosomal exocytosis.     

A synthetic decapeptide from a conserved ZP3 protein domain induces the G protein-regulated acrosome reaction in bovine spermatozoa

In some animal species, the zona pellucida protein 3 (ZP3) plays a central role during fertilization, functioning as a specific receptor for sperm and as an inducer of the acrosome reaction. On the other hand, the zona pellucida protein 2 (ZP2) acts as a secondary receptor, binding to acrosome-reacted sperm. The objective of these studies was to identify ZP2 and ZP3 domains that may be of importance for the induction of the acrosome reaction. For this purpose, we synthesized a number of ZP2 and ZP3 peptides that were either conserved among species or that were species-specific according to their respective primary structures. We identified a defined, conserved ZP3 decapeptide (ZP3-6 peptide) that bound to the surface of the acrosomal region and induced the acrosome reaction in a concentration-dependent manner in capacitated bovine sperm; this effect was significant in the nanomolar range. Pertussis toxin inhibited the ZP3-6 peptide-induced acrosome reaction but had no effect on the progesterone-induced exocytotic event. Our data are in accordance with previous studies showing that progesterone induces acrosomal exocytosis via a different pathway than ZP3 and strengthen the hypothesis that the effect of ZP3-6 peptide upon acrosomal exocytosis is G protein regulated. Despite the commonly accepted idea that glycosylation of ZP proteins is required for successful sperm-oocyte interaction, we found that acrosomal exocytosis can be induced by a synthetic ZP3 peptide that is not glycosylated. The results presented in this study may be useful for the investigation of the molecular mechanisms of sperm-egg interaction in bovine and other species.     

Polypeptide backbone derived from carboxyl terminal of mouse ZP3 inhibits sperm-zona binding

For mammalian organism, fertilization begins with species-specific recognition between sperm and egg, a process depending upon egg zona pellucida glycoproteins and putative sperm interacting protein(s). In mouse, zona pellucida glycoprotein ZP3 is believed to be the primary receptor for sperm and inducer of sperm acrosomal reaction, and its function has been attributed to the specific O-linked oligosaccharides attached to polypeptide backbone. While lots of reports have focused on the role of ZP3's oligosaccharides in fertilization, there are few concerning its polypeptide backbone. To investigate whether mZP3 polypeptide backbone is involved in sperm-egg recognition, three partially overlapping cDNA fragments, together covering entire mouse ZP3, were cloned, expressed and purified under denaturing condition. Although all three refolded proteins possess native conformation, only one derived from the carboxyl terminal showed inhibitory effect to the sperm-zona binding during in vitro fertilization. This phenomenon could not be explained by enhanced acrosomal exocytosis rate, in that the acrosomal reaction assay demonstrated its inability to induce the acrosomal reaction. Our results suggest that the carboxyl terminal of mZP3 polypeptide backbone interacts with sperm and such interaction plays a significant role in sperm-zona binding, ultimately successful fertilization.