Immunoglobulin immobilized liposomal constructs for transmucosal vaccination through nasal route

The aim of the present investigation was to evaluate the prospective of surface-engineered vesicular carriers for mucosal immunization via the nasal route. IgG antibody was immobilized on the surface of hepatitis B surface antigen (HBsAg) antigen–loaded liposomes. The developed formulations were characterized on the basis of physicochemical parameters, such as morphology, particle size, polydispersity index, entrapment efficiency, and zeta potential. Liposomal formulations were then evaluated for in-process antigen stability and storage stability. In vivo studies were conducted to visualize targeting potential, localization pattern, and immunogenicity. In addition, immune response was compared with alum-HBsAg vaccine injected intramuscularly. The serum anti-HBsAg titer, obtained from the postnasal administration of IgG-coupled liposomes, was significantly higher than plain liposomes. Moreover, IgG-coupled liposomes generated both humoral (i.e., systemic and mucosal) and cellular immune responses upon nasal administration, while the alum-adsorbed antigen displayed neither cellular (cytokine level) nor mucosal (IgA) response. The formulation also displayed enhanced transmucosal transport, improved in vitro stability, and effective immunoadjuvant property. To conclude, IgG antibody-coupled liposomes may serve as novel carriers to augment the secretory immune response of antigen encapsulated in the liposomes, apparently by escalating liposome uptake via M cells, thereby rationalizing their use as a carrier adjuvant for nasal subunit vaccines.     

M cell–targeting strategy enhances systemic and mucosal immune responses induced by oral administration of nuclease-producing L. lactis

Efficient delivery of antigens to the gut-associated lymphoid tissue (GALT) is the most critical step for the induction of mucosal immunity by oral vaccines. As M cells are the main portal for luminal antigens into the GALT, the M cell-targeting of antigens affords a promising strategy toward the development of effective oral vaccines. Lactococcus lactis is a fascinating recombinant host for oral vaccines, as they survive and produce antigens in the gut and have a particularly safe profile for human use. In this study, we developed and evaluated an M cell–targeting oral immunization system using recombinant L. lactis strains. For the purpose, we generated an L. lactis strain that secretes a model antigen fused with the OmpH β1α1 domain of Yersinia enterocolitica, which has been shown to bind to a complement C5a receptor on the M cell surface. As the model antigen, Staphylococcus aureus nuclease was used for fusion, resulting in L. lactis–expressing Nuc-OmpH (LL/Nuc-OmpH). Ex vivo intestinal loop assays showed that the amount of Nuc-OmpH taken up into Peyer’s patches was more than that of the unfused nuclease (Nuc). In addition, oral administration of the recombinant L. lactis strains to mice demonstrated that LL/Nuc-OmpH-induced nuclease-specific fecal IgA and serum IgG titers were significantly higher than those induced by LL/Nuc. These results indicate that OmpH works as an M cell–targeting molecule when fused with antigens secreted from L. lactis and that the M cell–targeting strategy affords a promising platform for L. lactis–based mucosal immunization.

     

Lactococcus lactis: high-level expression of tetanus toxin fragment C and protection against lethal challenge

To determine if the food-grade bacterium Lactococcus lactis holds promise as a vaccine antigen delivery vector we have investigated whether this bacterium can be made to produce high levels of a heterologous protein antigen. A regulated expression system has been developed which may be generally suitable for the expression of foreign antigens (and other proteins) In L. lactis. The system utilizes the fast-acting T7 RNA polymerase to transcribe target genes, and provides the first example of the successful use of this polymerase in a Gram-positive bacterium. When the performance of the expression system was characterized using tetanus toxin fragment C (TTFC) up to 22% of soluble cell protein was routinely obtained as TTFC. Mice immunized subcutaneously with L. lactis expressing TTFC were protected from lethal challenge with tetanus toxin. These results show for the first time that L. lactis is able to express substantial quantities of a heterologous protein antigen and that this organism can present this antigen to the Immune system in an immunogenic form.     

NSOM‐ and AFM‐based nanotechnology elucidates nano‐structural and atomic‐force features of a Y. pestis V immunogen‐containing particle vaccine capable of eliciting robust response

It is postulated that unique nanoscale proteomic features of immunogen on vaccine particles may determine immunogen‐packing density, stability, specificity, and pH‐sensitivity on the vaccine particle surface and thus impact the vaccine‐elicited immune responses. To test this presumption, we employed near‐filed scanning optical microscopy (NSOM)‐ and atomic force microscopy (AFM)‐based nanotechnology to study nano‐structural and single‐molecule force bases of Yersinia pestis (Y. pestis) V immunogen fused with protein anchor (V‐PA) loaded on gram positive enhancer matrix (GEM) vaccine particles. Surprisingly, the single‐molecule sensitive NSOM revealed that ～90% of V‐PA immunogen molecules were packed as high‐density nanoclusters on GEM particle. AFM‐based single‐molecule force analyses indicated a highly stable and specific binding between V‐PA and GEM at the physiological pH. In contrast, this specific binding was mostly abrogated at the acidic pH equivalent to the biochemical pH in phagolysosomes of antigen‐presenting‐cells in which immunogen protein is processed for antigen presentation. Intranasal mucosal vaccination of mice with such immunogen loaded on vaccine particles elicited robust antigen‐specific immune response. This study indicated that high‐density, high‐stability, specific, and immunological pH‐responsive loading of immunogen nanoclusters on vaccine particles could readily be presented to the immune system for induction of strong antigen‐specific immune responses.     

Plant‐derived recombinant immune complexes as self‐adjuvanting TB immunogens for mucosal boosting of BCG

Progress with protein‐based tuberculosis (TB) vaccines has been limited by poor availability of adjuvants suitable for human application. Here, we developed and tested a novel approach to molecular engineering of adjuvanticity that circumvents the need for exogenous adjuvants. Thus, we generated and expressed in transgenic tobacco plants the recombinant immune complexes (RICs) incorporating the early secreted Ag85B and the latency‐associated Acr antigen of Mycobacterium tuberculosis, genetically fused as a single polypeptide to the heavy chain of a monoclonal antibody to Acr. The RICs were formed by virtue of the antibody binding to Acr from adjacent molecules, thus allowing self‐polymerization of the complexes. TB‐RICs were purified from the plant extracts and shown to be biologically active by demonstrating that they could bind to C1q component of the complement and also to the surface of antigen‐presenting cells. Mice immunized with BCG and then boosted with two intranasal immunizations with TB‐RICs developed antigen‐specific serum IgG antibody responses with mean end‐point titres of 1 : 8100 (Acr) and 1 : 24 300 (Ag85B) and their splenocytes responded to in vitro stimulation by producing interferon gamma. 25% of CD4+ proliferating cells simultaneously produced IFN‐γ, IL‐2 and TNF‐α, a phenotype that has been linked with protective immune responses in TB. Importantly, mucosal boosting of BCG‐immunized mice with TB‐RICs led to a reduced M. tuberculosis infection in their lungs from log₁₀ mean = 5.69 ± 0.1 to 5.04 ± 0.2, which was statistically significant. We therefore propose that the plant‐expressed TB‐RICs represent a novel molecular platform for developing self‐adjuvanting mucosal vaccines.     

Mucosal immunity and vaccination.

The gut mucosal immune system is a critical component of the body's defense against pathogenic organisms, especially those responsible for enteric infections associated with diarrhoeal disease. Attempts to vaccinate against infections of mucosal tissues have been less successful than vaccination against systemic infections, to a large extent reflecting a still incomplete knowledge about the most efficient means for inducing protective local immune responses at these sites. Secretory IgA (SIgA) is the predominating immunoglobulin along mucosal surfaces, and SIgA antibodies generated in gastrointestinal, respiratory or genito-urinary mucosal tissues can confer protection against infections affecting or originating in these sites. An efficacious intestinal SIgA immunity-inducing oral vaccine against cholera has been developed recently, and development of oral vaccines against other enteric infections such as those caused by enterotoxigenic Escherichia coli, Shigella and rotaviruses is in progress as well. Based on the concept of a common mucosal immune system through which activated lymphocytes from the gut can disseminate immunity to other mucosal and glandular tissues, there is currently also much interest in the possibility of developing oral vaccines against infections in the respiratory and urogenital tracts. However, the large and repeated antigen doses often required to achieve a protective immune response still makes this vaccination approach impractical for many purified antigens. There is, therefore, a great need to develop strategies for enhancing delivery of antigen to the mucosal immune system as well as to identify mucosa-active immunostimulating agents (adjuvants). These and other aspects of mucosal immunity in relation to immunization and vaccine development are discussed in this short review article.     

Development of mucosal immunity in the first year of life and relationship to sudden infant death syndrome

The common mucosal immune system (CMIS) is an interconnecting network of immune structures that provides effective immunity to mucosal surfaces. The structures of the mucosal immune system are fully developed in utero by 28 weeks gestation, but in the absence of intrauterine infection, activation does not occur until after birth. Mucosal immune responses occur rapidly in the first weeks of life in response to extensive antigenic exposure. Maturation of the mucosal immune system and establishment of protective immunity varies between individuals but is usually fully developed in the first year of life, irrespective of gestational age at birth. In addition to exposure to pathogenic and commensal bacteria, the major modifier of the developmental patterns in the neonatal period is infant feeding practices. A period of heightened immune responses occurs during the maturation process, particularly between 1 and 6 months, which coincides with the age range during which most cases of sudden infant death syndrome (SIDS) occur. A hyper-immune mucosal response has been a common finding in infants whose death is classified as SIDS, particularly if in association with a prior upper respiratory infection. Inappropriate mucosal immune responses to an otherwise innocuous common antigen and the resulting inflammatory processes have been proposed as factors contributing to SIDS.     

Mucosal immunity and vaccination

Abstract The gut mucosal immune system is a critical component of the body's defense against pathogenic organisms, especially those responsible for enteric infections associated with diarrhoeal disease. Attempts to vaccinate against infections of mucosal tissues have been less successful than vaccination against systematic infections, to a large extent reflecting a still incomplete knowledge about the most efficient means for inducing protective local immune responses at these sites. Secretory IgA (SIgA) is the predominating immunoglobulin along mucosal surfaces, and SIgA antibodies generated in gastrointestinal, respiratory or genito-urinary mucosal tissues can confer protection against infections affecting or originating in these sites. An efficacious intestinal SIgA immunity-inducing oral vaccine against cholera has been developed recently, and development of oral vaccines against other enteric infections such as those caused by enterotoxigenic Escherichia coli, Shigella and rotaviruses is in progress as well. Based on the concept of a common mucosal immune system through which activated lymphocytes from the gut can disseminate immunity to other mucosal and glandular tissues, there is currently also much interest in the possibility of developing oral vaccines against infections in the respiratory and urogenital tracts. However, the large and repeated antigen doses often required to achieve a protective immune response still makes this vaccination approach impractical for many purified antigens. There is, therefore, a great need to develop strategies for enhancing delivery of antigen to the mucosal immune system as well as to identify mucosa-active immunostimulating agents (adjuvants). These and other aspects of mucosal immunity in relation to immunization and vaccine development are discussed in this short review article.     

枯草芽孢杆菌表面展示技术用于黏膜疫苗的研究进展

枯草杆菌全名枯草芽孢杆菌(Bacillus subtilis),因其优秀的益生特性及芽孢良好的抗逆性而备受研究者青睐,由于芽孢的特殊结构及独特的生理特性,是酶和免疫原等外源蛋白的理想锚定点。采用枯草杆菌进行芽孢表面展示被认为是表达高活性和高稳定性的外源蛋白的方法之一。本文主要对枯草杆菌芽孢表面展示抗原蛋白以生产黏膜疫苗的策略和应用前景进行综述。     

流感新型黏膜疫苗的研究

目的评价PorA、PorB和Class4对流感裂解疫苗的免疫增强作用,从中挑选出最有效的流感黏膜佐剂,为发展流感黏膜疫苗提供理论基础。方法流感三价裂解抗原按比例与PorA、PorB和Class4非共价结合,滴鼻免疫Balb／c小鼠3次,采取间接ELISA检测血清特异性IgG抗体及抗体亚型,检测鼻咽、肺、小肠和阴道冲洗液中IgA效价,采用血凝抑制试验检测血清中HAI效价。结果PorB重组蛋白佐剂组较无佐剂的流感裂解抗原组在提高小鼠早期免疫应答的同时诱导较强的系统免疫应答和黏膜免疫应答;PorA组也有黏膜佐剂的功能,但和无佐剂的流感裂解抗原组相比,差异无统计学意义。结论在蛋白体的三分子中,以PorB为佐剂的流感黏膜疫苗不仅提高了抗原的系统免疫应答,而且诱导了较强的小鼠呼吸道、生殖道的局部黏膜免疫应答,为流感黏膜疫苗的研制奠定了理论基础。     

Mucosal immunization with surface-displayed severe acute respiratory syndrome coronavirus spike protein on Lactobacillus casei induces neutralizing antibodies in mice

Induction of mucosal immunity may be important for preventing SARS-CoV infections. For safe and effective delivery of viral antigens to the mucosal immune system, we have developed a novel surface antigen display system for lactic acid bacteria using the poly-gamma-glutamic acid synthetase A protein (PgsA) of Bacillus subtilis as an anchoring matrix. Recombinant fusion proteins comprised of PgsA and the Spike (S) protein segments SA (residues 2 to 114) and SB (residues 264 to 596) were stably expressed in Lactobacillus casei. Surface localization of the fusion protein was verified by cellular fractionation analyses, immunofluorescence microscopy, and flow cytometry. Oral and nasal inoculations of recombinant L. casei into mice resulted in high levels of serum immunoglobulin G (IgG) and mucosal IgA, as demonstrated by enzyme-linked immunosorbent assays using S protein peptides. More importantly, these antibodies exhibited potent neutralizing activities against severe acute respiratory syndrome (SARS) pseudoviruses. Orally immunized mice mounted a greater neutralizing-antibody response than those immunized intranasally. Three new neutralizing epitopes were identified on the S protein using a peptide neutralization interference assay (residues 291 to 308, 520 to 529, and 564 to 581). These results indicate that mucosal immunization with recombinant L. casei expressing SARS-associated coronavirus S protein on its surface provides an effective means for eliciting protective immune response against the virus.     

Research

Gram-positive bacterium Streptococcus gordonii, a human oral commensal, was engineered to display a single-chain Fv (scFv) antibody fragment at the cell surface. The previously developed host-vector system allowed expression of the Guy’s 13 scFv as a fusion with the streptococcal surface protein M6. Surface expression of the 515-amino acid M6/scFv fusion protein was confirmed by Western blot analysis on cellular fractions and flow cytometric analysis. Guy’s 13 scFv was derived from the Guy’s 13 monoclonal antibody, which was raised against streptococcal antigen I/II (SA I/II), the major adhesin of the caries-producing bacterium Streptococcus mutans. Surface plasmon resonance was used to test binding of scFv-expressing S. gordonii to SA I/II. Whole cells of recombinant S. gordonii were found to specifically bind to immobilised SA I/II and binding was inhibited by fluid-phase SA I/II in a dose-dependent manner. Production of a functional scFv in S. gordonii is the first step towards the development of genetically engineered commensal bacteria that, by colonizing mucosal surfaces, may provide the host with sustained delivery of recombinant antibodies.     

Mucosal immunization using recombinant plant-based oral vaccines

The induction of mucosal immunity is very important in conferring protection against pathogens that typically invade via mucosal surfaces. Delivery of a vaccine to a mucosal surface optimizes the induction of mucosal immunity. The apparent linked nature of the mucosal immune system allows delivery to any mucosal surface to potentially induce immunity at others. Oral administration is a very straightforward and inexpensive approach to deliver a vaccine to the mucosal lining of the gut. However, vaccines administered by this route are subject to proteolysis in the gastrointestinal tract. Thus, dose levels for protein subunit vaccines are likely to be very high and the antigen may need to be protected from proteolysis for oral delivery to be efficacious. Expression of candidate vaccine antigens in edible recombinant plant material offers an inexpensive means to deliver large doses of vaccines in encapsulated forms. Certain plant tissues can also stably store antigens for extensive periods of time at ambient temperatures, obviating the need for a cold-chain during vaccine storage and distribution, and so further limiting costs. Antigens can be expressed from transgenes stably incorporated into a host plant's nuclear or plastid genome, or from engineered plant viruses infected into plant tissues. Molecular approaches can serve to boost expression levels and target the expressed protein for appropriate post-translational modification. There is a wide range of options for processing plant tissues to allow for oral delivery of a palatable product. Alternatively, the expressed antigen can be enriched or purified prior to formulation in a tablet or capsule for oral delivery. Fusions to carrier molecules can stabilize the expressed antigen, aid in antigen enrichment or purification strategies, and facilitate delivery to effector sites in the gastrointestinal tract. Many antigens have been expressed in plants. In a few cases, vaccine candidates have entered into early phase clinical trials, and in the case of farmed animal vaccines into relevant animal trials.     

乙肝表面抗原a表位粘膜疫苗的构建及免疫原性检测

利用DNA重组技术 ,构建霍乱毒素B亚单位与乙肝病毒表面抗原a表位的融合基因 ,并在大肠杆菌表达体系pET 30a BL2 1 (DE3)中获得以包涵体形式的高效表达。免疫印迹表明表达产物具有免疫学活性 ,包涵体复性后 ,表达产物能够象CTB那样形成五体 ,以腹腔注射、灌胃、鼻饲形式免疫小鼠均能产生抗HBsAg抗体     

靶向M细胞的抗原递送¾¾增强黏膜免疫应答的关键策略

黏膜是阻止病原入侵的第一道防线,黏膜免疫系统在抵抗感染方面起着至关重要的作用。通过黏膜途径接种疫苗可以同时诱导黏膜和全身免疫反应,因此,理论上针对黏膜的免疫策略是最合理和有效的。但黏膜免疫系统的复杂性和屏障作用造成抗原诱导的免疫应答水平低下,制约了黏膜疫苗的发展。M细胞(Microfoldcells)是黏膜免疫系统所独有的,其具有捕获腔内抗原和启动抗原特异性免疫应答的功能。M细胞摄取抗原的多少直接关系到黏膜疫苗的免疫效力,而利用M细胞配体可将抗原靶向递呈给M细胞,从而实现高效的黏膜免疫应答。靶向M细胞的抗原递送策略及其应用可以提高黏膜免疫应答水平,促进黏膜疫苗的研制。尽管如此,要成功研制安全高效的黏膜疫苗,今后依然有漫长的路要走,这可能有赖于进一步探究M细胞的特性和功能及黏膜免疫机制。     

Evaluation of a Liposome-Supplemented Intranasal Influenza Subunit Vaccine in a Murine Model System: Induction of Systemic and Local Mucosal Immunity

Abstract

This study reports on the mucosal immunoadjuvant activity of liposomes in an experimental influenza subunit vaccine administered intranasally (i.n.) to mice. Antibody responses induced by the i.n. liposomal vaccine were compared to those induced by an influenza infection or by subcutaneous (s.c.) injection of subunit antigen alone, the conventional route of human flu vaccination. Negatively charged liposomes, but not positively charged or zwitter-ionic liposomes, coadministered i.n. with influenza subunit antigen, significantly stimulated systemic IgG levels and local antibody responses in pulmonary secretions, relative to the responses upon i.n. administration of subunit antigen alone. I.n. immunization with liposome-supplemented subunit antigen as well as s.c. immunization with subunit antigen alone or infection induced high levels of IgG antibodies in serum and pulmonary secretions, with a preferential induction of IgGl upon immunization and IgG2a upon infection. Both i.n. immunization with liposome-supplemented antigen and infection, but not s.c. immunization with subunit antigen alone, induced local secretion of S-IgA. At the same time, both IgA-and IgG-secreting cells appeared in (he lungs and lung-associated lymph nodes, suggestive of local antibody production. In conclusion, the liposomal adjuvant system, combined with a mucosal administration protocol, provides a promising strategy for induction of both systemic and local antibody responses against influenza virus.     

The outer membrane porin from Yersinia enterocolitica in yersiniosis diagnostics

The diagnostic test system based on a species-specific antigen, pore-forming protein from the outer membrane of Yersinia enterocolitica, for yersiniosis verification by the method of ELISA has been developed and approved. The proposed ELISA test system is characterized by high sensitivity (95%) and specificity (89%) and provides a differential diagnostics of yersiniosis from other acute enteric infections with similar clinical manifestations. In comparison with the commercial diagnostics based on indirect hemagglutination reaction, which is conventionally used in clinical practice, the porin-based ELISA provides the high level (90–95%) of yersiniosis identification at early (1st week) and late (2nd–4th week) stages of infection process. It has been found that the ELISA test system reveals antibodies to the Y. enterocolitica porin in patient’s serum irrespective of the serological variant of causative agent.     

Unpolarized release of vaccinia virus and HIV antigen by colchicine treatment enhances intranasal HIV antigen expression and mucosal humoral responses

The induction of a strong mucosal immune response is essential to building successful HIV vaccines. Highly attenuated recombinant HIV vaccinia virus can be administered mucosally, but even high doses of immunization have been found unable to induce strong mucosal antibody responses. In order to solve this problem, we studied the interactions of recombinant HIV vaccinia virus Tiantan strain (rVTT-gagpol) in mucosal epithelial cells (specifically Caco-2 cell layers) and in BALB/c mice. We evaluated the impact of this virus on HIV antigen delivery and specific immune responses. The results demonstrated that rVTT-gagpol was able to infect Caco-2 cell layers and both the nasal and lung epithelia in BALB/c mice. The progeny viruses and expressed p24 were released mainly from apical surfaces. In BALB/c mice, the infection was limited to the respiratory system and was not observed in the blood. This showed that polarized distribution limited antigen delivery into the whole body and thus limited immune response. To see if this could be improved upon, we stimulated unpolarized budding of the virus and HIV antigens by treating both Caco-2 cells and BALB/c mice with colchicine. We found that, in BALB/c mice, the degree of infection and antigen expression in the epithelia went up. As a result, specific immune responses increased correspondingly. Together, these data suggest that polarized budding limits antigen delivery and immune responses, but unpolarized distribution can increase antigen expression and delivery and thus enhance specific immune responses. This conclusion can be used to optimize mucosal HIV vaccine strategies.     

Salmonella landau as a live vaccine against Escherichia coli O157:H7 investigated in a mouse model of intestinal colonization.

The present study was performed to assess the potential of a humoral mucosal immune response directed against the O157 antigen of Escherichia coli O157:H7 to prevent intestinal colonization by the pathogen. To this end, mice were gavaged with inocula of Salmonella landau, a Salmonella strain that naturally expresses the O157 antigen. Salmonella landau was avirulent for mice. Despite this, mice exposed to S. landau developed high titres of serum and coproantibodies against the O157 antigen. These mice, compared with controls, demonstrated some ability to resist transient intestinal colonization by an oral inoculum of an isolate of E. coli O157:H7. These findings suggest that a local immune response directed against the O157 antigen might increase host resistance to this pathogen.     

Heterologous expression of Brucella abortus GroEL heat-shock protein in Lactococcus lactis

Background  

Brucella abortus is a facultative intracellular pathogen that mainly infects cattle and humans. Current vaccines rely on live attenuated strains of B. abortus, which can revert to their pathogenic status and thus are not totally safe for use in humans. Therefore, the development of mucosal live vaccines using the food-grade lactic acid bacterium, Lactococcus lactis, as an antigen delivery vector, is an attractive alternative and a safer vaccination strategy against B. abortus. Here, we report the construction of L. lactis strains genetically modified to produce B. abortus GroEL heat-shock protein, a candidate antigen, in two cellular locations, intracellular or secreted.