Anticarrier immunity suppresses the antibody response to polysaccharide antigens after intranasal immunization with the polysaccharide-protein conjugate.

We have conjugated cholera toxin (CT) B subunit (CTB) to dextran and studied the effect in mice of previous immunization with CT and CTB on the response to dextran after intranasal immunizations with conjugate. Preexisting immunity to CTB was found to inhibit both the lung mucosal response and serum antibody response to dextran, but this effect could be overcome by using a higher dose of conjugate and delaying the conjugate immunization until the CTB antibody titers had declined. The role of anti-CTB antibodies on the mucosal surface was probably to prevent uptake of the conjugate through a mechanism of immune exclusion. Passively transferred serum antibodies against CTB, on the other hand, suppressed both the serum response and the local antibody response against CTB but did not affect the response to dextran after intranasal immunization with conjugate.     

Intranasal administration of recombinant Neisseria gonorrhoeae transferrin binding proteins A and B conjugated to the cholera toxin B subunit induces systemic and vaginal antibodies in mice

The transferrin binding proteins (TbpA and TbpB) comprise the gonococcal transferrin receptor and are considered potential antigens for inclusion in a vaccine against Neisseria gonorrhoeae. Intranasal (IN) immunization has shown promise in development of immunity against sexually transmitted disease pathogens, in part due to the induction of antigen-specific genital tract immunoglobulin A (IgA) and IgG. Conjugation of antigens to the highly immunogenic cholera toxin B subunit (Ctb) enhances antibody responses in the serum and mucosal secretions following IN vaccination. In the current study, we characterized the anti-Tbp immune responses following immunization of mice IN with recombinant transferrin binding proteins (rTbpA and rTbpB) conjugated to rCtb. We found that both rTbpA-Ctb and rTbpB-Ctb conjugates administered IN induced antibody responses in the serum and genital tract. IN immunization resulted in both IgA and IgG in the genital tract; however, subcutaneous immunization mainly generated IgG. Surprisingly, rTbpA alone was immunogenic and induced serum and mucosal antibody responses similar to those elicited against the rTbpA-Ctb conjugate. Overall, rTbpB was much more immunogenic than rTbpA, generating serum IgG levels that were greater than those elicited against rTbpA. Bactericidal assays conducted with sera collected from mice immunized IN with TbpA and/or TbpB indicated that both antigens generated antibodies with bactericidal activity. Anti-TbpA antibodies were cross-bactericidal against heterologous gonococcal strains, whereas TbpB-specific antibodies were less cross-reactive. By contrast, antibodies elicited via subcutaneous immunization were not cross-bactericidal against heterologous strains, indicating that IN vaccination could be the preferred route for elicitation of biologically functional antibodies.     

Intranasal vaccination with the recombinant Listeria monocytogenes ΔactA prfA* mutant elicits robust systemic and pulmonary cellular responses and secretory mucosal IgA

We previously showed that recombinant (r) Listeria monocytogenes carrying ΔactA and a selected prfA* mutation (r-Listeria ΔactA prfA*) secreted >100-fold more immunogen in broth culture than wild-type r-Listeria or r-Listeria ΔactA and elicited much greater cellular and humoral immune responses than r-Listeria ΔactA after intravenous vaccination of mice. Here, we conducted comparative studies evaluating vaccine-elicited immune responses in systemic and mucosal sites after intranasal, intravenous, intraperitoneal, or subcutaneous immunization of mice with r-Listeria ΔactA prfA* vaccine candidates. Intranasal vaccination of mice with r-Listeria ΔactA prfA* vaccine candidates elicited a robust gamma interferon-positive (IFN-γ(+)) cellular response in systemic sites, although intravenous or intraperitoneal immunization was more efficient. Surprisingly, intranasal vaccination elicited an appreciable pulmonary IFN-γ(+) cellular response that was nonstatistically higher than the magnitude induced by the intravenous route but was significantly greater than that elicited by subcutaneous immunization. Furthermore, although intranasal r-Listeria ΔactA prfA* delivery induced poor systemic IgG responses, intranasal vaccination elicited appreciable secretory immunogen-specific IgA titers that were similar to or higher in mucosal fluid than those induced by subcutaneous and intravenous immunizations. Thus, intranasal vaccination with r-Listeria ΔactA prfA* appears to be a useful approach for eliciting robust systemic and pulmonary cellular responses and measurable secretory mucosal IgA titers.     

Systemic and mucosal immune responses in mice after mucosal immunization with group B streptococcus type III capsular polysaccharide-cholera toxin B subunit conjugate vaccine

Group B streptococci (GBS) colonize the female genital and rectal tracts and can cause invasive infection in susceptible newborns. An optimally effective GBS vaccine should induce mucosal and systemic immunity. In this study, we investigate the local and systemic immune responses to GBS type III capsular polysaccharide (CPS) after mucosal vaccination of mice via intranasal, peroral, rectal, and vaginal routes, with GBS type III CPS conjugated with recombinant cholera toxin B subunit (GBS III CPS-rCTB). Cholera toxin (CT) was added as an adjuvant. Immunoglobulin G (IgG) and IgA antibodies to the CPS were tested in serum, lungs, and intestinal, rectal, and vaginal extracts by enzyme-linked immunosorbent assay. The conjugated CPS administered by intranasal, peroral, rectal, and vaginal routes was much more effective at inducing both mucosal and systemic antibody responses to GBS III CPS than was unconjugated CPS. The CPS-specific immune responses in various organs were dependent on the route of immunization. Generally, the highest levels of IgA and IgG were generated in the regions or sites of the conjugate exposure. Thus, intranasal vaccination elicited the highest anti-CPS IgA and IgG antibody levels in the lungs, whereas peroral administration in the intestinal site and vaginal vaccination elicited the highest antibody levels in the vagina. Rectal vaccination was superior to the other routes in inducing high antibody levels in the rectum. The four routes of mucosal vaccination also induced distant antibody responses to CPS. Rectal vaccination induced high specific IgA levels in the vagina and intestine, and oral administration induced high specific IgA levels in the lungs and rectum. All four routes of vaccination with the conjugate elicited similarly high levels of anti-CPS IgG in serum. Intranasal vaccination with different doses of the conjugate (10, 30, and 80 microg of CPS) did not have a significant influence on the anti-CPS specific antibody responses. Intranasal immunization induced better antibody responses when one dose of the conjugate was divided and given on three consecutive days compared to administration of the full dose on one occasion. In conclusion, rectal and vaginal vaccination may be the best way of stimulating anti-CPS immune responses in the rectal and vaginal tracts, while high levels of anti-CPS antibodies in the lungs can be achieved after intranasal administration. The vaccination regimen thus might influence the mucosal immune response to CPS. This conjugate may serve as an effective mucosal vaccine for preventing mucosal colonization and invasive infection caused by GBS.     

Immune response of the female rat genital tract after oral and local immunization with keyhole limpet hemocyanin conjugated to the cholera toxin B subunit.

The immune response of the female rat genital tract was evaluated with Lewis rats given primary and secondary immunizations with keyhole limpet hemocyanin (KLH) alone or coupled to the cholera toxin (CT) B subunit (CTB) by the oral or intravaginal-uterine route or a combination of routes. CT (2 to 5 micrograms) was administered as an adjuvant with the KLH-CTB conjugate. While a significant mucosal immunoglobulin A (IgA) response was induced by KLH, there were no significant differences among the immunized groups in the levels of IgA antibodies in salivary gland, gut, vaginal, and uterine secretions, with the exception that rats immunized only orally with the KLH-CTB conjugate lacked a detectable vaginal response. Levels of IgA antibodies to CT, however, were significantly increased in genital tract secretions of rats immunized locally versus orally with the KLH-CTB conjugate. Antibody activity of the IgG isotype against both KLH and CT was significantly elevated in genital tract secretions of rats immunized with KLH-CTB by the oral or intravaginal-uterine route and given genital tract boosters, in comparison with the results for the other groups. IgM antibody titers were generally negligible in the different secretions. An enzyme-linked spot-forming assay revealed IgA and IgG antibody-secreting cells in salivary gland and uterine tissues. A highly significant correlation between the numbers of antibody-secreting cells and antibody titers existed for uterine IgG but not IgA responses to KLH among the different groups of rats. In conclusion, a vigorous local immune response was induced after immunization of the female rat reproductive tract alone or in combination with peroral challenge with the KLH-CTB conjugate.     

Role of local IgA antitoxin-producing cells for intestinal protection against cholera toxin challenge

We examined in mice, perorally immunized with cholera toxin (CT) or cholera B subunit (CTB), the association between protection against intestinal toxin challenge and frequency and function of gut mucosal IgA antitoxin-forming cells. The in vitro production of IgA antitoxin by isolated cells and the toxin-neutralizing ability of culture supernatants were determined. Repeated oral immunizations with CT gave rise to high numbers of IgA antitoxin 'spot-forming' cells (SFC) in the lamina propria as well as to protection against challenge with CT in ligated intestinal loops. In contrast, mice immunized with purified CTB, gave poor IgA antitoxin SFC responses in the lamina propria and little or no protection. When a small amount of CT was used to adjuvant the response to CTB, many IgA antitoxin SFC were found; however, protection in intestinal loops remained poor. This discrepancy was explained by the predominant localization of antitoxin SFC in the proximal small intestine following oral CTB/CT-adjuvant immunization, whereas relatively few SFC were found further down in the intestine where the loop-protection test was performed. Thus, when lamina propria plasma cells were isolated from challenged loops and cultured in vitro, they released only low titers of IgA antitoxin and CT-neutralizing antibodies in culture supernatants; this was in contrast to cells from optimally immunized mice which gave supernatants with high IgA antitoxin and toxin-neutralizing antibody titers. Increasing the dose of CT, added as adjuvant to the CTB, resulted in better protection and higher numbers of IgA antitoxin SFC in more distal parts of the intestine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Protective Immunity of Microsphere-Based Mucosal Vaccines against Lethal Intranasal Challenge with Streptococcus pneumoniae

Mucosal vaccination of capsular polysaccharide (PS) of Streptococcus pneumoniae and subsequent creation of the first line of immunological defense in mucosa were examined. Mucosal as well as systemic antibody responses to PS were evoked by peroral or intranasal immunization of BALB/c mice with PS-cholera toxin B subunit (CTB) conjugates entrapped in the alginate microspheres (AM). The bacterial colonization at the lung mucosa was most profoundly inhibited (<95%) by intranasal immunization with the naked conjugate (PS-CTB). The mice vaccinated orally with encapsulated conjugate [AM(PS-CTB)] showed significant reduction on the level of pneumococcal bacteremia (<99%). Eighty percent of the mice perorally immunized with AM (PS-CTB) were protected from lethal intranasal challenge with S. pneumoniae, whereas more than 60% of the mice in the other control groups died of infection. Our novel approach may prove to be important in the development of a mucosal vaccine that will provide protection of mucosal surfaces of host.     

Mucosal and systemic antibody responses after peroral or intranasal immunization: effects of conjugation to enterotoxin B subunits and/or of co-administration with free toxin as adjuvant

The mucosa-binding molecules cholera toxin (CT) from Vibrio cholerae and heat-labile enterotoxin (LT) from Escherichia coli have previously been used as mucosal adjuvants and carriers for many types of antigen. However, since these molecules are toxic and cannot be used in human vaccines, it is important to study whether their non-toxic mucosa-binding B subunits, CTB and LTB, can be used as alternative safe mucosal adjuvants and/or carrier molecules. We have as a model protein antigen used human gammaglobulin (HGG) for admixture with or chemical conjugation to recombinantly produced CTB and LTB, respectively, and measured antigen-specific local secretory IgA antibodies in saponin extracts from intestine and lung tissue by ELISA following intra-nasal (i.n.) or per-oral (p.o.) immunization. The results show that local antibody formation against HGG was increased after immunization with conjugated as compared to free HGG. However, while the conjugates alone gave rise to significant immune responses in the lung and also, to a lesser degree, in the intestine after i.n. immunization, co-administration of a small amount of free CT/LT as adjuvant was needed to induce a significant immune response in the intestine after p.o. immunization. We also found that following i.n. immunization, the addition of CTB to HGG, without coupling, increased the mucosal immune response to some extent, indicating that CTB by itself can work as an adjuvant by the i.n. route of immunization. A striking finding was that, as a carrier, CTB was superior to LTB when the conjugates were used by the oral but not by the i.n. route of immunization. In conclusion, conjugation of an antigen to mucosa-binding molecules such as CTB and/or LTB can dramatically increase their mucosal immunogenicity. This approach may thus be useful in the preparation of mucosal vaccines.     

Induction of mucosal immune responses by administration of liposome-antigen formulations and interleukin-12.

We examined the effect of interleukin-12 (IL-12) on the induction of mucosal immune responses following intranasal immunization with liposome-antigen formulations. We assessed the immune response to two recombinant glycoproteins (gD and gB) from bovine herpesvirus type 1 (BHV-1). Positively charged liposomes induced significantly higher gD-specific IgA titers than did immunization with antigen alone. This liposome formulation was selected to further assess the ability of IL-12 to influence mucosal immune responses. Intranasal immunization with IL-12 gD-liposome formulations did not alter the induction of mucosal immune responses. However, a significant increase in anti-gD antibody responses was induced in serum after intranasal immunization with IL-12 gD-liposome when compared with animals immunized with gD-liposomes. Mucosal antibody responses induced by a subcutaneous priming followed by an intranasal boost were significantly higher than those induced by two intranasal immunizations with the same IL-12 liposome-gD formulations. Furthermore, this immunization protocol resulted in the induction of high levels of interferon-gamma (IFN-gamma) in the lungs of subcutaneously primed mice. These findings indicate that the immunomodulatory effects of IL-12 influenced immune responses to a vaccine antigen when delivered intranasally and that these responses can be further enhanced by subcutaneous priming.     

Induction of mucosal immunity by intranasal application of a streptococcal surface protein antigen with the cholera toxin B subunit.

The level and distribution of isotype-specific antibodies in various secretions and of antibody-secreting cells in corresponding lymphoid organs and tissues were compared in mice immunized with Streptococcus mutans surface protein antigen I/II (AgI/II) conjugated to the cholera toxin B subunit (CTB), given intranasally (i.n.) or intragastrically (i.g.), with or without free cholera toxin (CT) as an adjuvant. Immunization i.n. induced stronger initial antibody responses to AgI/II in both serum and saliva than immunization i.g., but salivary immunoglobulin A (IgA)-specific antibody responses to immunization about 3 months later were not increased relative to total salivary IgA concentrations. Specific antibodies induced by i.n. immunization were as widely distributed in serum, saliva, tracheal wash, gut wash, and vaginal wash as those induced by i.g. immunization. Likewise, specific antibody-secreting cells were generated in the spleen, salivary glands, intestinal lamina propria, and mesenteric and cervical lymph nodes by either route of immunization. The strongest salivary IgA antibody response was induced by AgI/II-CTB conjugate given i.n., but the addition of CT did not further enhance it. However, free CTB could effectively replace CT as an adjuvant in i.n. immunization with unconjugated AgI/II. Booster i.n. immunization with AgI/II plus either free CT or CTB induced stronger recall serum antibody responses than conjugated AgI/II-CTB with or without CT as an adjuvant. Therefore, i.n. immunization with a protein antigen and free or coupled CTB is an effective means of generating IgA antibody responses expressed at several mucosal sites where protective immunity may be beneficial.     

Mucosal IgA responses in healthy adult volunteers following intranasal spray delivery of a live attenuated measles vaccine

Measles remains an important cause of morbidity and mortality among children in the developing world. The goal of this study was to examine measles virus-specific mucosal immune responses in healthy immune (n = 24; plaque reduction neutralization [PRN] titers of ≥200 mIU/ml) and nonimmune (n = 24) young adult volunteers who received the monovalent Moraten measles vaccine via intranasal (spray delivery) or subcutaneous immunization. Serum, oral fluid, and nasal wash samples were examined for measles virus-specific and total IgG and IgA on day 0 (prior to vaccination) and on days 14, 28, and 90 after vaccination. Nonimmune subjects vaccinated subcutaneously developed high levels of measles virus PRN, IgG, and IgA antibodies in serum, oral fluid, and nasal washes. Total IgG and secretory IgA (sIgA) titers were increased in nasal washes, and total IgG was increased in oral fluid specimens. There was a strong correlation between PRN and measles virus-specific IgG titers measured in serum, oral fluid, and nasal washes, whereas a weak correlation was found between PRN and measles virus-specific IgA titers. Notably, intranasal measles vaccination resulted in increased production of measles virus-specific sIgA in oral fluid and nasal washes in nonimmune individuals, without evidence of a systemic immune response. In contrast, no significant vaccine-induced responses were observed in immune subjects, regardless of the route of immunization. These results demonstrate that (i) intranasal measles immunization can elicit a mucosal response independent of the induction of serum antibodies and (ii) both mucosal and systemic antibody responses following nasal or subcutaneous immunization are blunted by preexisting measles immunity.     

Anti-bacterial and anti-toxic immunity induced by a killed whole-cell-cholera toxin B subunit cholera vaccine is essential for protection against lethal bacterial infection in mouse pulmonary cholera model

The lack of appropriate animal model for studying protective immunity has limited vaccine development against cholera. Here, we demonstrate a pulmonary cholera model conferred by intranasal administration of mice with live Vibrio cholerae. The bacterial components, but not cholera toxin, caused lethal and acute pneumonia by inducing massive inflammation. Intranasal immunization with Dukoral, comprising killed whole bacteria and recombinant cholera toxin B subunit (rCTB), developed both mucosal and systemic antibody responses with protection against the lethal challenge. Either rCTB-free Dukoral or rCTB alone partially protected the mice against the challenge. However, reconstitution of rCTB-free Dukoral with rCTB restored full protection. Parenteral immunization with Dukoral evoked strong systemic immunity without induction of mucosal immunity or protection from the challenge. These results suggest that both anti-bacterial and anti-toxic immunity are required for protection against V. cholerae–induced pneumonia, and this animal model is useful for pre-clinical evaluation of candidate cholera vaccines.     

LOS诱导的特异性抗体分泌细胞的ELISPOT法检测

目的 :动态测定卡他性莫拉氏菌 (Moraxellacatarrhalis,M .cat)脱毒脂寡糖 (dLOS)蛋白质结合疫苗诱导的抗体分泌细胞的应答状态。方法 :以M .catdLOS蛋白质结合疫苗滴鼻免疫BALB/c小鼠。应用酶联免疫斑点试验 (ELISPOT)检测免疫小鼠不同免疫诱导部位和免疫效应部位 ,包括 :鼻相关淋巴组织 (NALT)、脾脏、颈部淋巴结、鼻内容物、肺脏和派伊尔氏结的特异性抗体分泌细胞 ,并同时测定血清、鼻冲洗液、肺泡灌洗液、唾液及粪便提取液中特异性IgA、IgG和IgM的水平。结果 :M .catdLOS蛋白质结合疫苗免疫小鼠的NALT、脾脏、颈部淋巴结、鼻内容物、肺脏和派伊尔氏结中 ,均测出分泌LOS特异抗体的抗体分泌细胞 ,以鼻内容物中IgA分泌细胞的数目最多 ,其次是在NALT和肺脏中 ,这与特异性抗体测定的结果相一致。结论 :M .catdLOS蛋白质结合疫苗经滴鼻免疫 ,能刺激产生LOS特异的黏膜和全身抗体分泌细胞的应答。ELISPOT试验具有快速、灵敏、特异的优点 ,为动态分析单个抗体分泌细胞应答规律提供了新方法。     

Antibodies and Antibody-Secreting Cells in the Female Genital Tract after Vaginal or Intranasal Immunization with Cholera Toxin B Subunit or Conjugates

We studied the antibody response including antibody-secreting cells (ASC) in the female genital tract of mice after mucosal immunizations with the recombinant B subunit of cholera toxin (rCTB) perorally, intraperitoneally, vaginally, and intranasally (i.n.). The strongest genital antibody responses as measured with a novel perfusion-extraction method were induced after vaginal and i.n. immunizations, and these routes also gave rise to specific immunoglobulin A (IgA) and IgG ASC in the genital mucosa. Specific ASC in the iliac lymph nodes, which drain the female genital tract, were seen only after vaginal immunization. Progesterone treatment increased the ASC response in the genital tissue after all mucosal immunizations but most markedly after vaginal immunization. We also tested rCTB as a carrier for human gamma globulin (HGG) and the effect of adding cholera toxin (CT) as an adjuvant for the induction of systemic and genital antibody responses to HGG after vaginal and i.n. immunizations. Vaginal immunizations with HGG conjugated to rCTB resulted in high levels of genital anti-HGG antibodies whether or not CT was added, while after i.n. immunization the strongest antibody response was seen with the conjugate together with CT. In summary, vaginal and i.n. immunization give rise to a specific mucosal immune response including ASC in the genital tissue, and vaginal immunization also elicits ASC in the iliac lymph nodes. We have also shown that rCTB can act as an efficient carrier for a conjugated antigen for induction of a specific antibody response in the genital tract of mice after vaginal or i.n. immunization.     

Immunogenicity of a Salmonella typhimurium aroA aroD vaccine expressing a nontoxic domain of Clostridium difficile toxin A

The C-terminal repeat domain of Clostridium difficile toxin A harbors toxin-neutralizing epitopes and is considered to be a candidate component of a vaccine against C. difficile-associated disease (CDAD). Fourteen of the 38 C-terminal toxin A repeats (14CDTA) were cloned into pTECH-1 in frame with the immunogenic fragment C of tetanus toxin (TETC) to generate plasmid p56TETC. Expression of the TETC-14CDTA fusion protein was driven from the anaerobically inducible nirB promoter within attenuated Salmonella typhimurium BRD509 (aroA aroD). The TETC-14CDTA fusion protein was purified and shown to bind to known toxin A receptors found on the surface of rabbit erythrocytes. Intranasal (i.n.) and intragastric (i.g.) immunization with 10(7) and 10(10) CFU, respectively, of BRD509(p56TETC) generated significant (P < 0.05) anti-toxin A serum responses after a single dose. Antibody titers were elevated following a boosting dose with either live vaccine or a subcutaneous injection of 0.5 microgram of purified 14CDTA protein. Importantly, serum from mice immunized with BRD509(p56TETC) neutralized toxin A cytotoxicity. Both i.n. and i.g. immunizations also generated toxin A-specific immunoglobulin A on the pulmonary and intestinal mucosa, respectively. Intranasal vaccination induced consistently higher serum and mucosal anti-toxin A antibody responses. Significant anti-tetanus toxoid serum and mucosal antibodies were also generated by both immunization routes. The availability of live attenuated Salmonella typhi for human use may allow the development of a multivalent mucosal vaccine against CDAD, tetanus, and typhoid.     

Beta7-integrin-independent enhancement of mucosal and systemic anti-HIV antibody responses following combined mucosal and systemic gene delivery

Vaccination strategies that can block or limit heterosexual human immunodeficiency virus (HIV) transmissions to local and systemic tissues are the goal of much research effort. Herein, in a mouse model, we aimed to determine whether the enhancement of antibody responses through mucosal and systemic immunizations, previously observed with protein-based vaccines, applies to immunizations with DNA- or RNA-based vectors. Intranasal (i.n.) followed by intramuscular (i.m.) immunizations (i.n./i.m.) with polylactide-coglycolide (PLG)-DNA microparticles encoding HIV-gag (PLG-DNA-gag) significantly enhanced serum antibody responses, compared with i.m., i.n. or i.m. followed by i.n. (i.m./i.n.) immunizations. Moreover, while i.n./i.m., i.n. or i.m./i.n. immunizations with PLG-DNA-gag resulted in genital tract antibody responses, i.m. immunizations alone failed to do so. Importantly, beta7-deficient mice developed local and systemic antibody responses following i.n./i.m. immunization, or immunization via any other route, similar to those of wild-type mice. To compare the DNA with an RNA delivery system, immunizations were performed with VEE/SIN-gag replicon particles, composed of Venezuelan equine encephalitis virus (VEE) replicon RNA and Sindbis surface structure (SIN). i.n./i.m., compared with any other immunizations, i.n./i.m. immunization with VEE/SIN-gag resulted in enhanced genital tract but not serum antibody responses. These data show for the first time that mucosal followed by systemic immunizations with gene delivery systems enhance B-cell responses independent of the mucosal homing receptors alpha4beta7 and alphaEbeta7.     

rCTB和TT为蛋白载体的A群流脑多糖黏膜免疫初步研究

目的 对重组霍乱毒素B亚单位(rCTB)作为多糖蛋白结合疫苗候选载体的可行性进行分析,并对以破伤风类毒素(TT)与rCTB为蛋白载体的黏膜投递型疫茸的免疫效果进行初步探讨.方法 首先通过基因工程手段获得具有五聚体结构的rCTB.再将rCTB五聚体蛋白利用化学方法(ADH方法)与A群脑膜炎球菌多糖(GAMP)耦联,获得多糖蛋白结合物GAMP-rCTB,并将其与TT为蛋白载体的A群流脑多糖蛋白结合物(GAMP-TT)以滴鼻和注射途径免疫BALB/c小鼠,并对其进行免疫学评价.结果 以rCTB和TT为载体的A群流脑多糖蛋白结合物,通过黏膜投递途径均可在血清中产生相对较高的多糖特异性IgG抗体,在肺部盥洗液和小肠黏膜也产生了相应的特异性IgA抗体.结论 rCTB和TT均可作为黏膜投递型多糖结合疫苗的候选蛋白载体.以rCTB为载体的多糖蛋白结合物,黏膜途径可能在免疫功能方面优于注射途径.     

rCTB和TT为蛋白载体的A群流脑多糖黏膜免疫初步研究

目的 对重组霍乱毒素B亚单位(rCTB)作为多糖蛋白结合疫苗候选载体的可行性进行分析,并对以破伤风类毒素(TT)与rCTB为蛋白载体的黏膜投递型疫茸的免疫效果进行初步探讨.方法 首先通过基因工程手段获得具有五聚体结构的rCTB.再将rCTB五聚体蛋白利用化学方法(ADH方法)与A群脑膜炎球菌多糖(GAMP)耦联,获得多糖蛋白结合物GAMP-rCTB,并将其与TT为蛋白载体的A群流脑多糖蛋白结合物(GAMP-TT)以滴鼻和注射途径免疫BALB/c小鼠,并对其进行免疫学评价.结果 以rCTB和TT为载体的A群流脑多糖蛋白结合物,通过黏膜投递途径均可在血清中产生相对较高的多糖特异性IgG抗体,在肺部盥洗液和小肠黏膜也产生了相应的特异性IgA抗体.结论 rCTB和TT均可作为黏膜投递型多糖结合疫苗的候选蛋白载体.以rCTB为载体的多糖蛋白结合物,黏膜途径可能在免疫功能方面优于注射途径.     

rCTB和TT为蛋白载体的A群流脑多糖黏膜免疫初步研究

目的 对重组霍乱毒素B亚单位(rCTB)作为多糖蛋白结合疫苗候选载体的可行性进行分析,并对以破伤风类毒素(TT)与rCTB为蛋白载体的黏膜投递型疫茸的免疫效果进行初步探讨.方法 首先通过基因工程手段获得具有五聚体结构的rCTB.再将rCTB五聚体蛋白利用化学方法(ADH方法)与A群脑膜炎球菌多糖(GAMP)耦联,获得多糖蛋白结合物GAMP-rCTB,并将其与TT为蛋白载体的A群流脑多糖蛋白结合物(GAMP-TT)以滴鼻和注射途径免疫BALB/c小鼠,并对其进行免疫学评价.结果 以rCTB和TT为载体的A群流脑多糖蛋白结合物,通过黏膜投递途径均可在血清中产生相对较高的多糖特异性IgG抗体,在肺部盥洗液和小肠黏膜也产生了相应的特异性IgA抗体.结论 rCTB和TT均可作为黏膜投递型多糖结合疫苗的候选蛋白载体.以rCTB为载体的多糖蛋白结合物,黏膜途径可能在免疫功能方面优于注射途径.     

Mucosal and Systemic Immune Responses in Humans after Primary and Booster Immunizations with Orally Administered Invasive and Noninvasive Live Attenuated Bacteria

The mucosal and systemic immune responses after primary and booster immunizations with two attenuated live oral vaccine strains derived from a noninvasive (Vibrio cholerae) and an invasive (Salmonella typhi) enteric pathogen were comparatively evaluated. Vaccination with S. typhi Ty21a elicited antibody-secreting cell (ASC) responses specific for S. typhi O9, 12 lipopolysaccharide (LPS), as well as significant increases in levels of immunoglobulin G (IgG) and IgA antibodies to the same antigen in serum. A strong systemic CD4(+) T-helper type 1 cell-mediated immune (CMI) response was also induced. In contrast to results with Ty21a, no evidence of a CMI response was obtained after primary immunization with V. cholerae CVD 103-HgR in spite of the good immunogenicity of the vaccine. Volunteers who received a single dose of CVD 103-HgR primarily developed an IgM ASC response against whole vaccine cells and purified V. cholerae Inaba LPS, and seroconversion of serum vibriocidal antibodies occurred in four of five subjects. Serum IgG anti-cholera toxin antibody titers were of lower magnitude. For both live vaccines, the volunteers still presented significant local immunity 14 months after primary immunization, as revealed by the elevated baseline antibody titers at the time of the booster immunization and the lower ASC, serum IgG, and vibriocidal antibody responses after the booster immunization. These results suggest that local immunity may interfere with colonization of the gut by both vaccine strains at least up to 14 months after basis immunization. Interestingly, despite a low secondary ASC response, Ty21a was able to boost both humoral (anti-LPS systemic IgG and IgA) and CMI responses. Evidence of a CMI response was also observed for one of three volunteers given a cholera vaccine booster dose. The direct comparison of results with two attenuated live oral vaccine strains in human volunteers clearly showed that the capacity of the vaccine strain to colonize specific body compartments conditions the pattern of vaccine-induced immune responses.