吸入免疫研究进展

吸入能有效地诱导粘膜局部免疫和系统免疫应答,比其它途径更方便,更安全,成为当今免疫学研究的重点方向之一。本介绍了吸入免疫的基本情况、提高其效果的措施,以及吸入免疫的优缺点等应用方面的研究进展。     

粘膜免疫系统与粘膜免疫应答的诱导

粘膜免疫系统是机体抵抗病原体入健的第一道免疫屏蔽,同机体的系统免疫相比,粘膜免疫系统的淋巴细胞总数远远超过存在于骨髓,胸,腺,脾脏以及淋巴结中的淋巴细胞数量,粘膜表面分泌性免疫球蛋白A（sIgA)的量显高于循环IgG的总量,而且粘膜分泌物中的抗体以IgA抗体为主,由于粘膜免疫系统的区域性分布,诱导系统免疫的免疫途径和免疫佐剂不能诱导粘膜免疫应答,经消化道,呼吸道和生殖道免疫可有效地诱导粘膜免疫应答,霍乱毒素是良好的粘膜免疫,佐剂,能有效地诱导粘膜免疫应答,粘膜免疫的上述特点可能是某些疫苗经系统免疫后,尽管能诱导血液中产生高滴度的IgG抗体,但不能预防疾病的原因。     

粘膜接种疫苗研究进展

与注射疫苗相比,粘膜接种疫苗具有使用方便,免疫效果好,不仅诱导局部免疫应答,也诱导全身性应答等优点,故日益引起重视,近年已相继开发了多种粘膜疫苗及用于粘膜免疫接种的佐剂和载体,后者包括非活性颗粒载体及具有复制活性的减毒活疫苗株,它们可保护疫苗不被降解,增强人体的免疫应答水平。本文介绍了这方面的研究进展。     

重组BCG口服免疫诱导的细胞和体液免疫应答

重组ＢＣＧ口服免疫诱导的细胞和体液免疫应答最近研究证明,外源基因能在牛分枝杆菌ＢＣＧ中表达,用这些重组分枝杆菌免疫小鼠可诱导抗外来蛋白的细胞和抗体免疫应答。近年来的许多研究也证实了肠道和呼吸道粘膜淋巴系统在防御感染方面的贡献,因此,迫切需要能够刺激粘...     

整合素α4β7研究进展

α4β7是一种整合素分子 ,主要介导淋巴细胞向粘膜部位的迁移和归巢 ,同时参与一些炎症反应 ,并对肠相关淋巴组织 (GAL T)的发育、粘膜部位的免疫应答等有重要作用     

α4β7研究进展

α４β７是一种整合素分子，主要介导淋巴细胞向粘膜部位的迁移和归巢，同时参与一些炎症反应，并对肠相关淋巴组织（ＧＡＬＴ）的发育，粘膜部位的免疫应答等有重要作用。     

HEVAg-PLGA纳米颗粒疫苗小鼠体内免疫学研究

研究重组戊型肝炎抗原(HEVAg)-乳酸/乙醇酸共聚物(PLGA)纳米颗粒抗原能否在动物体内诱导产生免疫应答。制备HEVAg-PLGA纳米颗粒抗原后,通过皮下、滴鼻、口服途径接种Balb/c小鼠,每隔4周加强免疫两次,HEVAg与铝盐佐剂(铝佐剂疫苗Al_2O_3-Ag)为对照组,一定时间内检测抗体及细胞因子的应答水平。结果HEVAg-PLGA纳米颗粒抗原在小鼠体内诱导产生有效的体液免疫、细胞免疫。滴鼻、口服途径黏膜系统中诱导产生较高滴度的IgA抗体,ELISPOT结果显示鼻腔、唾液腺中IgA ASCs数量显著增加;皮下途径诱导产生较高滴度的IgG抗体;常规铝佐剂疫苗相比于HEVAg-PLGA纳米颗粒抗原诱导较强的IgG抗体水平,未诱导产生黏膜免疫应答;HEVAg-PLGA纳米颗粒抗原诱导产生较强细胞免疫应答,皮下接种途径IFN-γ、IL-4生成细胞数量显著高于其它免疫组。与铝佐剂疫苗相比,HEVAg-PLGA纳米颗粒抗原能有效诱导产生系统免疫及黏膜免疫应答,显示HEVAg-PLGA有潜力成为备选HEV黏膜疫苗抗原,同时展示PLGA颗粒作为黏膜系统抗原递送载体及黏膜佐剂的优越性。     

植物生物反应器生产绿色疫苗研究进展

植物生物反应器为人类提供了更为安全的疫苗生产体系。研究显示植物源性的绿色疫苗确实能诱导动物和人产生粘膜和全身性免疫应答。与传统疫苗相比,可食疫苗更简单、安全、稳定、经济和卫生。本文综述了绿色疫苗基因工程的研究及进展,并对潜在的问题及对策略进行了探讨。     

植物生物反应器生产绿色疫苗研究进展

植物生物反应器为人类提供了更为安全的疫苗生产体系。研究显示植物源性的绿色疫苗确实能诱导动物和人产生粘膜和全身性免疫应答。与传统疫苗相比 ,可食疫苗更简单、安全、稳定、经济和卫生。本文综述了绿色疫苗基因工程的研究及进展 ,并对潜在的问题及应对策略进行了探讨。     

靶向鼻腔树突细胞的F1t3配体作佐剂激发抗致死性肺炎球菌性肺炎保护

作者以往的研究证明以肺炎球菌表面蛋白A（PspA）为基础的疫苗含有编码Flt3配体（FL）基因的DNA质粒（pFL）,这种DNA质粒可作为一种鼻腔佐剂,该疫苗能够预防肺炎链球菌在鼻腔的定植。在本项研究中,作者进一步研究了这种鼻腔投递疫苗在小鼠模型中诱导抗肺炎链球菌肺部感染的PspA特异性抗体应答的有效性及安全性,C57BL／6小鼠鼻腔免疫重组PspA／Rxl（rPspA）加pFL,免疫3次,间隔1周。     

Immunogenic properties of modified antigen E. III. Effect of repeated injections of modified antigen on immunocompetent cells specific for native antigen.

It has been shown that ragweed antigen E loses its major antigenic determinants after denaturation in 8 M urea, but urea-denatured (UD) antigen and an alpha-polypeptide chain isolated from the denatured molecules are capable of priming mouse T cells specific for native antigen. Weekly injections of 10mug UD antigen or alpha-chain into antigen E-primed animals depressed the ongoing IgE antibody response, whereas injections of the same dose of antigen E failed to depress the antibody response. It was found by adoptive transfer experiments that helper activity of antigen E-primed splenic T cells was depressed by the treatment of the donors with either modified antigen or native antigen E. The same treatment of antigen E-primed animals depressed the DNA synthetic response of their splenic T cells to antigen E. The treatment of antigen E-primed animals with UD antigen resulted in a decrease of antigen E-specific IgE-B cells and IgG-B cells in their spleen, whereas the treatment with native antigen expanded the B cell populations. In view of the results obtained in the mouse, cellular basis for the immunologic effects of hyposensitization treatment is discussed.     

Endocytosis and recycling of specific antigen by human B cell lines.

Human B cell lines expressing membrane immunoglobulin specific for tetanus toxoid/toxin were used to study the receptor-mediated endocytosis of antigen. Monovalent antigen, initially bound to cell surface immunoglobulin at 0 degree C, was rapidly endocytosed upon warming the cells to 37 degrees C. The kinetics of endocytosis of antigen were independent of the number of occupied binding sites and indicated a half-life for antigen on the cell surface of 8.5 min. Endocytosis of antigen apparently ceased after approximately 15 min at 37 degrees C, although some 40-50% remained on the cell surface at this time. We show, using biotinylated antigen and an avidin detection assay, that this is due to recycling of antigen to the cell surface. By labelling the antigen on the cell surface with Fabs against different epitopes we show that antigen continues to be endocytosed for at least 1 h after the initial rapid phase of endocytosis, again indicating that there must be recycling of immunoglobulin/antigen complexes. As a consequence of the stable interaction between antigen and membrane immunoglobulin, the capacity of the cells to accumulate antigen was limited when the synthesis of membrane immunoglobulin was blocked; under these conditions only 2-3 times as much antigen was endocytosed and degraded when antigen was supplied continuously over a 4-h period at 37 degrees C as could be bound to the cells at 0 degree C. These results reveal a rapid and efficient pathway for the endocytosis and recycling of monovalent antigen in B cells.     

Transformation of type polysaccharide antigen synthesis and hemolysin synthesis in streptococci

Transformation of the ability to synthesize type polysaccharide antigen and beta-hemolysin has been obtained in group F streptococci. Colonies possessing cells transformed to antigen synthesis were detected on the agar surface with fluorescein-labeled anti-type serum. This selection method, in contrast to those with antibiotics, allowed both transformed and nontransformed cells to grow, resulting in sectored colonies. These colonies could be subcultured to further establish the synthesis of antigen. Group F, group A, and group-like z deoxyribonucleic acid (DNA) labeled with type II antigen and hemolysin, and streptomycin resistance transferred each marker to a group F strain lacking a type antigen. DNA from group F and z3 strains labeled with type III antigen, and streptomycin resistance transferred both markers to group F and z3 strains lacking type antigen. A second F strain without type antigen was not transformed with any of these markers. A group H strain was transformed to streptomycin resistance only by the same types of DNA. Transformation to type II antigen synthesis always resulted in the formation of beta-hemolysin. All strains isolated from natural sources contained both markers. A mutant, obtained by nitrosoguanidine treatment of an FII(sr) strain, did not synthesize either the hemolysin or the antigen. This mutant still possessed the group antigen and streptomycin resistance. A close linkage of type II antigen and beta-hemolysin is indicated. The fluorescent-antibody staining of cells containing both group and type antigens showed a more intense ultraviolet adsorption for type than group antigen. A surface location (microcapsular) for the type antigen appeared likely. These results are of interest for studies on antigen biosynthesis, genetics, and classification of the streptococci.     

The actin cytoskeleton coordinates the signal transduction and antigen processing functions of the B cell antigen receptor

The B cell antigen receptor （BCR） is the sensor on the B cell surface that surveys foreign molecules （antigen） in our bodies and activates B cells to generate antibody responses upon encountering cognate antigen. The binding of antigen to the BCR induces signaling cascades in the cytoplasm, which provides the first signal for B cell activation. Subsequently, BCRs internalize and target bound antigen to endosomes, where antigen is processed into T cell recognizable forms. T helper cells generate the second activation signal upon binding to antigen presented by B cells. The optimal activation of B cells requires both signals, thereby depending on the coordination of BCR signaling and antigen transport functions. Antigen binding to the BCR also induces rapid remodeling of the cortical actin network of B cells. While being initiated and controlled by BCR signaling, recent studies reveal that this actin remodeling is critical for both the signaling and antigen processing functions of the BCR, indicating a role for actin in coordinating these two pathways. Here we will review previous and recent studies on actin reorganization during BCR activation and BCR- mediated antigen processing, and discuss how actin remodeling translates BCR signaling into rapid antigen uptake and processing while providing positive and negative feedback to BCR signaling.     

B cells extract and present immobilized antigen: implications for affinity discrimination

Binding of antigen to B-cell antigen receptor (BCR) leads to antigen internalization and presentation to T cells, a critical process in the initiation of the humoral immune response. However, antigen internalization has been demonstrated for soluble antigen, in vivo antigen is often encountered in insoluble form or tethered to a cell surface. Here, we show that not only can B cells internalize and present large particulate antigen (requiring a signalling-competent BCR to drive antigen uptake), but they can also extract antigen that is tethered tightly to a non-internalizable surface. The form in which the antigen is displayed affects the B cell's ability to discriminate antigen-BCR affinity. Thus, arraying an antigen on a particle or surface allows efficient presentation of low affinity antigens. However, the presentation efficiency of antigen arrayed on an internalizable particle plateaus at low affinity values. In contrast, extraction and presentation of antigen from a non-internalizable surface depends on antigen-BCR affinity over a wide affinity range. The results have implications for understanding both the initiation and affinity maturation of the immune response.     

A deterministic model for the processing and presentation of bacteria-derived antigenic peptides

The amount and the dynamics of antigen supply to the cellular antigen processing and presentation machinery differ largely among diverse microbial antigens and various types of antigen presenting cells. The precise influence, however, of antigen supply on the antigen presentation pattern of cells is not known. Here, we provide a basic deterministic mathematical model of antigen processing and presentation of microbial antigens. The model predicts that different types of antigen presenting cells e.g. cells presenting or cross-presenting exogenous antigens, cells infected with replicating microbes, or cells in which microbial antigen synthesis is blocked after a certain period of time have inherently different antigen presentation patterns which are defined by the kinetics of antigen supply. The reevaluation of existing experimental data [Sijts, A.J., Pamer, E.G., 1997. Enhanced intracellular dissociation of major histocompatibility complex class I-associated peptides: a mechanism for optimizing the spectrum of cell surface-presented cytotoxic T lymphocyte epitopes. J. Exp. Med. 185, 1403-1411] describing the processing and presentation of two antigenic peptides derived from the p60 proteins of the facultatively intracellular bacterium Listeria monocytogenes shows that p60 proteins accumulating intracellularly during bacterial infection of cells play no measurable role as substrate for the cytosolic antigen presentation pathway.     

Purification, characterization, and quantitation of the antigen employed in the immunodiffusion test for diagnosis of equine infectious anemia.

Equine infectious anemia (EIA) antigen extracted from the spleen of horses infected with EIA virus was purified by pH treatment, (NH4)2SO4 fractionation and affinity chromatography. The homogeneity of the antigen was indicated by sedimentation rate and sedimentation equilibrium experiments. A S20,w of 0.51 was determined and a molecular weight of 7600 was calculated from sedimentation equilibrium analysis. The amino acid composition of the pure antigen indicated the antigen is an acidic protein. Employing radical immunodiffusion (RID) and pure antigen a method for quantitating antigen content of antigen containing preparations was developed.     

Excretory-secretory antigen is better than crude antigen for the serodiagnosis of clonorchiasis by ELISA

Although stool examination is the standard diagnostic method of clonorchiasis, serodiagnosis by ELISA using crude antigen is now widely used because of its convenience. However, ELISA diagnosis still suffers from cross-reactions, and therefore there is a need to improve the present conventional ELISA. The present study was undertaken to evaluate the diagnostic value of ELISA using excretory-secretory antigen (ESA) instead of crude antigen (CA) of Clonorchis sinensis. The diagnostic sensitivity of ELISA using excretory-secretory antigen was 92.5%, which was higher than that of ELISA using crude Clonorchis sinensis antigen (88.2%). In addition, the specificity of excretory-secretory antigen was found 93.1% while that of crude antigen was 87.8%. In summary, Clonorchis sinensis ESA was found to be a better serodiagnostic antigen than CA for ELISA.     

Peptide map analysis of normal plasma and platelet factor VIII antigen

Factor VIII antigen from platelet intracellular granules was immunoprecipitated using a monospecific rabbit antibody to normal plasma factor VIII antigen. The factor VIII antigen in the immunoprecipitate was isolated on sodium dodecyl sulfate polyacrylamide gels, radiolabeled with ¹²⁵I, trypsinized, and subjected to peptide mapping using two dimensional high voltage electrophoresis and thin layer chromatography. The platelet protein was compared to purified plasma factor VIII antigen. The two dimensional tryptic ¹²⁵I peptide map of platelet granule factor VIII antigen was similar but not identical to the plasma factor VIII antigen peptide map. The platelet and plasma proteins shared approximately 34 radioactive peptide spots. Seven plasma factor VIII antigen peptides were not detected in platelet factor VIII antigen. The reason for the structural differences of plasma and platelet granule factor VIII antigen are unknown. The possibility is raised that proteolysis has altered the platelet protein in vitro. It is also possible that factor VIII antigen synthesized by megakaryocytes differs from the plasma protein.     

Cytolysin A-mediated protein exportation efficiency and its role in enhancing the fitness of live recombinant Salmonella Typhi vaccine strain

The genetic fusion of cytolysin A (clyA) to heterologous antigen expressed in live Salmonella vector demonstrated efficient translocation into periplasmic space and extracellular medium. Accumulating evidence has shown that clyA-mediated antigen delivery improved growth fitness and enhanced immunogenicity of live vector vaccine, but the factors influencing this protein exportation has not been investigated. In this study, Toxoplasma gondii antigen fused at C-terminal of clyA protein was expressed in live S. Typhi vector via both plasmid and chromosomal-based expressions. The bivalent strains showed comparable growth rates as monovalent strains, but in varies antigen exportation efficiency. ClyA-fusion antigen with positive charges was translocated to the extracellular spaces, whereas those with negative charges were retained in the cytoplasm. Furthermore, excessive cellular resources expenditure on antigen expression, especially antigen with larger size, could limit the clyA-fusion antigen exportation, resulting in undesirable metabolic burden that eventually affects the growth fitness. Altogether, the present work indicates potential linkage of factors mainly on antigen properties and expression platforms that may affect clyA-mediated antigen delivery to enhance the growth fitness of live vector strain.