Characterisation of an inhibitory monoclonal antibody-defined epitope on a malaria vaccine candidate antigen.

A monoclonal antibody that recognizes a recently characterised 45-kDa merozoite surface antigen of the human malaria parasite Plasmodium falciparum inhibits the growth of the asexual blood stages of the parasite in vitro. The corresponding epitope has been determined by testing the reactivity of the antibody with sequentially overlapping octapeptides. A synthetic peptide containing the epitope elicits antibodies that react with the native antigen. Epitope mapping in this manner is useful in the design of synthetic vaccines against malaria.     

Oral immunization with a recombinant malaria protein induces conformational antibodies and protects mice against lethal malaria

The increasing death toll from malaria, due to the decreasing effectiveness of current prophylactic and therapeutic regimens, has sparked a search for alternative methods of control, such as vaccines. Although several single proteins have shown some promise as subunit vaccines against sexual blood stages in experimental systems, it is clear that multicomponent vaccines are required. Many logistic difficulties make such an approach prohibitively expensive. In an effort to try to overcome some of these issues, we examined the possibility of oral immunization as a route for inducing host protective immunity. We report here that oral feeding of a malaria protein induced serum antibody levels similar to those induced by intraperitoneal immunization with Freund's adjuvant. Further, responses to conformational epitopes were induced. In the rodent challenge system, significant levels of protection to lethal challenge with malaria were induced in mice. The protective efficacy was highly correlated with antibody levels, which depended on the antigen dosage and required cholera toxin subunit B as an oral adjuvant. These findings offer new approaches to the development of a malaria vaccine and provide justification for the investigation of transgenic plants as a means of vaccine delivery.     

The RTS,S vaccine candidate for malaria

Malaria continues to be a worldwide leading cause of morbidity and mortality, and the development of an effective malaria vaccine remains a research imperative. Of the multiple approaches that have been pursued, the RTS,S/AS01 vaccine candidate represents the most developed and clinically validated malaria vaccine formulation. Throughout its development, increasingly more effective adjuvants have been key in improving the potency of the vaccine. RTS,S-based vaccine formulations have been demonstrated to be safe, well tolerated, immunogenic, and to confer partial efficacy in both malaria-naive and -experienced adults as well as children. Further research to optimize and improve vaccine efficacy is ongoing.     

HLA polymorphism and T cell recognition of a conserved region of p190, a malaria vaccine candidate.

We have examined T cell recognition of a recombinant polypeptide (190L), corresponding to a 175-amino-acid-long conserved region of the major surface antigen (p190) of Plasmodium falciparum merozoites. We show that 190L contains a variety of T cell epitopes, and can be recognized in association with many different MHC class II molecules, including HLA-DR, DP, and DQ antigens. Most of the epitope-containing peptides are able to bind to more than one DR, and a single DR molecule can bind to different peptides. These findings, together with the fact that humans are generally heterozygous at the DR, DQ, and DP beta chain loci, suggest that MHC restriction should not be a major constraint in the development of malaria subunit vaccines.     

重组杆状病毒表达的EIAV Env蛋白与含有env基因重组痘苗病毒的联合免疫

目的：构建新型的马传染性贫血病毒(EIAV)的候选疫苗：方法：利用BAC—To—BAC杆状病毒表达系统，将中国马传贫驴白细胞弱毒疫苗(EIAV DLV)及其亲本株(EIAV LN)env基因导入到杆状病毒基因组中。转染昆虫细胞后，得到的重组病毒用SDS—PAGE和Western blot检测表达产物。以本实验室构建的含有EIAV env基因的重组痘苗病毒，单独或与重组杆状病毒表达的EIAV Env蛋白联合免疫小鼠。结果：构建的重组杆状病毒能正确表达全长Env蛋白。与单独免疫组相比，联合免疫组免疫应答显著增强，其中中和抗体的滴度提高5～9倍。结论：含有EIAV env基因的重组痘苗病毒与Env蛋白抗原联合免疫，能够诱导高滴度的中和抗体。     

A recombinant minigene vaccine containing a nonameric cytotoxic-T-lymphocyte epitope confers limited protection against Listeria monocytogenes infection.

We have previously shown that vaccines expressing virus-derived cytotoxic-T-lymphocyte (CTL) epitopes as short minigenes can confer effective protection against virus challenges, and here we extend these studies to the bacterium Listeria monocytogenes. Host defense against this important human pathogen appears largely T cell mediated, and a nonamer CTL epitope from the listeriolysin O (LLO) protein has been identified in BALB/c mice. We have synthesized this nonamer as a minigene, expressed it in a recombinant vaccinia virus (VV-list), and used this to immunize mice. Memory CTLs cultured from VV-list-immunized mice specifically lyse target cells pulsed with a nonamer peptide identified at LLO amino acid residues 91 to 99. Four weeks postimmunization, mice were challenged with L. monocytogenes. By day 6 following challenge with a sublethal dose of L. monocytogenes, mice immunized with VV-list showed a approximately 2,000- to 6,000-fold reduction in bacteria CFU in the spleen and liver. At this time point, with control mice, bacterial were readily detectable by Gram stain of the liver but were undetectable in the VV-list-immunized animals. Additionally, when a normally lethal dose of bacteria was given, death was delayed in VV-list-immunized animals. This study has demonstrated that a single immunization with a recombinant vaccinia virus bearing only nine amino acids from a bacterial pathogen can induce specific CTLs able to confer partial protection against bacterial challenge.     

Characterization of a reduced peptide bond analogue of a promiscuous CD4 T cell epitope derived from the Plasmodium falciparum malaria vaccine candidate merozoite surface protein 1

Use of synthetic peptides as vaccine components is hampered by their susceptibility to enzymatic degradation and rapid clearance from biological fluids. Introduction of non-natural structural modifications can render peptides more resistant to enzymatic degradation, encouraging attempts to profile such non-natural ligands as components of synthetic sub-unit vaccines. We have compared the antigenic and immunogenic properties of a series of non-natural peptide analogues derived from a promiscuous T cell epitope of the major Plasmodium falciparum malaria vaccine candidate merozoite surface protein 1 (MSP-1). A series of HLA class II restricted MSP-1(38-58)-specific TCC established from three volunteers were characterized for their minimal epitope and fine specificity. T cell stimulatory activities of a series of pseudo-peptide analogues with single reduced peptide bond Psi-[CH2-NH] modifications were compared with those of single d-amino acid replacement analogues. Compared to reduced peptide bond analogues the single d-amino acid replacement analogues turned out to be less suitable for stimulation of TCC. In particular, the reduced peptide analogue carrying a Psi-[CH2-NH] backbone modification between positions V52 and L53 of MSP-1(38-58) demonstrated properties that would make it a more suitable vaccine component than the unmodified parent peptide. First, the pseudo-peptide stimulated a number of TCC restricted by a range of HLA class II alleles. Second, trypsin treatment in combination with T cell stimulation assays provided evidence for increased resistance to proteolytic digestion. Third, the parasite-binding anti-MSP-1 mAb 7.27 recognized best this particular pseudo-peptide in competition ELISA experiments and its immunogenicity in out-bred Aotus monkeys was superior to that of the parent peptide eliciting antibodies cross-reactive with native MSP-1.     

Cytotoxic T-lymphocyte epitopes for HLA-B53 and other HLA types in the malaria vaccine candidate liver-stage antigen 3

The development of an effective preerythrocytic vaccine against Plasmodium falciparum malaria is likely to require inclusion of components from several preerythrocytic antigens. The association of HLA-B53 with resistance to severe malaria in West Africa provided evidence that HLA class I-restricted CD8(+) T-cell responses play a role in protective immunity in African children, supporting data from rodent models of malaria. Previously, a single epitope from liver-stage-specific antigen 1 (LSA-1) has been shown to be recognized by HLA-B53-specific cytotoxic T lymphocytes (CTL), but HLA-B53 epitopes were not found in four other antigens. In this study we measured CTL responses to peptides from the recently sequenced antigen liver-stage antigen 3 (LSA-3) and identified in it a new epitope restricted by HLA-B53. Several CTL epitopes restricted by other class I types were also identified within LSA-3 in studies in The Gambia and Tanzania. CTL were also identified to an additional P. falciparum antigen, exported protein 1 (Exp-1), the homologue of which is a protective antigen in a rodent model of malaria. These findings emphasize the diversity of P. falciparum antigens recognized by CD8(+) T cells in humans and support the inclusion of components from several antigens in new CTL-inducing vaccines against malaria.     

Nasal immunization with a malaria transmission-blocking vaccine candidate, Pfs25, induces complete protective immunity in mice against field isolates of Plasmodium falciparum

Malaria transmission-blocking vaccines based on antigens expressed in sexual stages of the parasites are considered one promising strategy for malaria control. To investigate the feasibility of developing noninvasive mucosal transmission-blocking vaccines against Plasmodium falciparum, intranasal immunization experiments with Pichia pastoris-expressed recombinant Pfs25 proteins were conducted. Mice intranasally immunized with the Pfs25 proteins in the presence of a potent mucosal adjuvant cholera toxin induced robust systemic as well as mucosal antibodies. All mouse immunoglobulin G (IgG) subclasses except IgG3 were found in serum at comparable levels, suggesting that the immunization induced mixed Th1 and Th2 responses. Consistent with the expression patterns of the Pfs25 proteins in the parasites, the induced immune sera specifically recognized ookinetes but not gametocytes. In addition, the immune sera recognized Pfs25 proteins with the native conformation but not the denatured forms, indicating that mucosal immunization induced biologically active antibodies capable of recognizing conformational epitopes of native Pfs25 proteins. Feeding Anopheles dirus mosquitoes with a mixture of the mouse immune sera and gametocytemic blood derived from patients infected with P. falciparum resulted in complete interference with oocyst development in mosquito midguts. The observed transmission-blocking activities were strongly correlated with specific serum antibody titers. Our results demonstrated for the first time that a P. falciparum transmission-blocking vaccine candidate is effective against field-isolated parasites and may justify the investigation of noninvasive mucosal vaccination regimens for control of malaria, a prototypical mucosa-unrelated mosquito-borne parasitic disease.     

Active immunization of homosexual men using a recombinant hepatitis B vaccine

Twenty homosexual men [13 anti-human immunodeficiency virus (HIV)-positive, seven anti-HIV negative] without HBsAg, anti-HBs, and anti-HBc were vaccinated with three 20 micrograms doses of a recombinant hepatitis B vaccine. All anti-HIV-positive homosexuals were nonresponders independent of the initial number of CD4-positive cells. Among seven anti-HIV-negative individuals, five responded. After three doses of the vaccine, CD4-positive cells fell in anti-HIV positive individuals by 22.4%. A similar fall in CD4-positive cells of an average 24.9% was noted in 17 matching, but nonvaccinated, anti-HIV-positive homosexuals. The study indicates that the efficacy of vaccination in anti-HIV-positive individuals is questionable. There is, however, no evidence that vaccination against hepatitis B might be harmful to anti-HIV-positive subjects.     

Human and murine T-cell responses to allelic forms of a malaria circumsporozoite protein epitope support a polyvalent vaccine strategy.

Mouse models and a recent vaccine trial have indicated the importance of T-cell immunity to the circumsporozoite protein (CSP) of malaria sporozoites. One of the major impediments for the development of a CSP-based vaccine is that human T-cell epitopes, identified on the CSP, span regions of significant point mutational polymorphism. Studies with human and mouse T-cell clones have indicated that this polymorphism affects T-cell cross-reactivity to Th2R and Th3R, the two most polymorphic and immunodominant epitopes. We extend this observation with polyclonal human T-cell lines, from 11 donors, raised to known variants of Th2R. These lines showed limited but variable cross-reactivity with the heterologous peptides. T cells from B10.A4(R) (I-Ak) mice immunized with each of 18 natural variants of Th2R indicated a similar, limited, cross-reactivity. I-Ak competition assays showed that a number of peptides were unable to bind because of a single polymorphic residue. In both the human and mouse assays, analysis of the sequences of immunogenic cross-reactive and non-cross-reactive peptides suggested that the individual polymorphic residues affect the three-dimensional conformation of the peptide within the major histocompatibility complex (MHC) groove in an, as yet, unpredictable way. These observations argue that design of an epitope able to generate broad cross-reactivity is, to date, not possible. However, despite the limited cross-reactivity of the individual human T-cell lines, most of the donors had T-cell repertoires capable of recognizing all or nearly all of the variants tested, which supports a strategy using a multivalent vaccine.     

A candidate vaccine against influenza virus intensively improved the immunogenicity of a neutralizing epitope

BACKGROUND: The hemagglutinin (HA) of influenza viruses is one of the major targets of the humoral response. The role of serum antibody to HA in the protection against infection has been demonstrated by long-standing observation. In previous studies, we suggested that an epitope vaccine might be a new strategy against the virus. METHODS: HA sequences of 491 H3 subtype strains from the influenza sequence database were compared and analyzed. To acquire information on the immunogenicity of the F3 epitope, F3-epitope-specific antibody levels in 81 patient sera infected with influenza virus were tested by ELISA. Based on the theory of the epitope vaccine, we designed an epitope peptide F3 (C-KAYSNCYPYDVPDY-G-KAYSNCYPYDVPDY), which contains the repeated F3 epitope KAYSNCYPYDVPDY (aa92-105) on HA (H3N2). The specificity and the titer of the antibodies induced by the epitope vaccine were determined by ELISA. The neutralizing activities of these anti-F3 antibodies were shown by inhibiting influenza virus infection of MDCK cells. RESULTS AND CONCLUSION: Comparison of HA sequences of 491 H3 subtype strains indicates that this epitope is highly conservative. Analysis of the sera from influenza virus-infected patients revealed a very low level of F3 epitope-specific antibodies, suggesting the poor immunogenicity of the F3 epitope on influenza virus. The epitope vaccine based on the F3 epitope induced high levels of F3 epitope-specific antibodies recognizing the epitope peptide F3 (antibody titer in antisera up to 1:25,600). Besides, the antisera could also recognize the natural HA in Western blotting. Interestingly, these antisera induced by the epitope vaccine could inhibit infection of MDCK cells by influenza virus (strain A/Wuhan/359/95) in the neutralization assay. These results suggest that the epitope vaccine can intensively increase the immunogenicity of neutralizing epitopes and may provide a new way to develop an effective vaccine against influenza virus.     

posttranslational modification of recombinant Plasmodium falciparum apical membrane antigen 1: impact on functional immune responses to a malaria vaccine candidate

Recombinant apical membrane antigen 1 (AMA1) is a leading vaccine candidate for Plasmodium falciparum malaria, as antibodies against recombinant P. falciparum AMA1 (PfAMA1) interrupt merozoite invasion into erythrocytes. In order to investigate the role of posttranslational modification in modulating the functional immune response to recombinant AMA1, two separate alleles of PfAMA1 (FVO and 3D7), in which native N-glycosylation sites have been mutated, were produced using Escherichia coli and a Pichia pastoris expression system. Recombinant Pichia pastoris AMA1-FVO (PpAMA1-FVO) and PpAMA1-3D7 are O-linked glycosylated, and 45% of PpAMA1-3D7 is nicked, though all four recombinant molecules react with conformation-specific monoclonal antibodies. To address the immunological effect of O-linked glycosylation, we compared the immunogenicity of E. coli AMA1-FVO (EcAMA1-FVO) and PpAMA1-FVO antigens, since both molecules are intact. The effect of antigen nicking was then investigated by comparing the immunogenicity of EcAMA1-3D7 and PpAMA1-3D7. Our data demonstrate that there is no significant difference in the rabbit antibody titer elicited towards EcAMA1-FVO and PpAMA1-FVO or to EcAMA1-3D7 and PpAMA1-3D7. Furthermore, we have demonstrated that recombinant AMA1 (FVO or 3D7), whether expressed and refolded from E. coli or produced from the Pichia expression system, is equivalent and mimics the functionality of the native protein in in vitro growth inhibition assay experiments. We conclude that in the case of recombinant AMA1, the E. coli- and P. pastoris-derived antigens are immunologically and functionally equivalent and are unaffected by the posttranslational modification resulting from expression in these two systems.     

Enteral immunization with attenuated recombinant Listeria monocytogenes as a live vaccine vector: organ-dependent dynamics of CD4 T lymphocytes reactive to a Leishmania major tracer epitope

Listeria monocytogenes is considered as a potential live bacterial vector, particularly for the induction of CD8 T cells. The CD4 T-cell immune response triggered after enteral immunization of mice has not yet been thoroughly characterized. The dynamics of gamma interferon (IFN-gamma)- and interleukin-4 (IL-4)-secreting CD4 T cells were analyzed after priming through intragastric delivery of an attenuated delta actA recombinant L. monocytogenes strain expressing the Leishmania major LACK protein; a peptide of this protein, LACK(158-173) peptide (pLACK), is a well-characterized CD4 T-cell target in BALB/c mice. Five compartments were monitored: Peyer's patches, mesenteric lymph nodes (MLN), spleen, liver, and blood. A single intragastric inoculation of delta actA-LACK-LM in BALB/c mice led to colonization of the MLN and spleen at a significant level for at least 3 days. Efficient priming of IFN-gamma-secreting pLACK-reactive CD4 T cells was observed in all tested compartments. Interestingly, IL-4-secreting pLACK-reactive CD4 T cells were detectable at day 6 or 7 only in blood and liver. The absence of translocation of viable bacteria through the intestinal epithelium after further delta actA-LACK-LM inoculations was concomitant with the absence of an increase in the level of IFN-gamma secreted by the MLN, blood, and splenic pLACK-reactive Th1 T cells, although the levels remained significantly above the basal level. No change in this population size was detected in the spleen. However, an increase in the number of intragastric inoculations had a clinical beneficial effect in L. major-infected BALB/c mice. L. monocytogenes thus presents the potential of an efficient vector for induction of CD4 T cells when administered by the enteral route.     

狂犬病毒CTN株糖蛋白重组鸡痘病毒与核酸疫苗的联合免疫

目的 构建狂犬病毒糖蛋白重组鸡痘病毒，研究联合运用重组病毒与同一抗原核酸疫苗对小鼠的免疫效果，为狂犬病疫苗的研究提供基础。方法 以中国鸡痘病毒疫苗株282E4为基础构建的表达载体pUTA-2的ATI-P7．5复合启动子下游，插入狂犬病毒CTN-18l株糖蛋白基因，构建了重组转移载体pUTA-RgC。以脂质体转染法将pUTA-RgC转染至已感染鸡痘病毒282E4株(FPV)2～3h的鸡胚成纤维(CEF)细胞中。待细胞出现明显病变后收获病毒，用BrdU进行连续3次加压筛选，挑取蚀斑毒株、纯化、扩增，间接免疫荧光鉴定。用重组鸡痘病毒vUTA-RgC单独及与核酸疫苗联合免疫小鼠，在细胞及体液免疫，攻毒保护水平评价所构建的重组病毒及联合免疫效果。结果 间接免疫荧光结果表明已成功构建重组鸡痘病毒，免疫后能诱导机体产生细胞与体液免疫，并能抵抗标准攻毒株的攻击，联合免疫效果较为理想。结论 获得一株能够表达狂犬病毒糖蛋白的vUTA．RgC，并证明有一定的免疫原性，与核酸疫苗联合应用能够克服各自的缺点。     

含EBV-LMP2基因重组腺病毒疫苗的构建及其诱导CTL应答的初步探讨

目的　构建包含EBV LMP2基因的重组腺病毒疫苗并探讨它在体内外的免疫性质。方法　采用pAdeasy 1系统构建包含EBV LMP2基因的重组腺病毒疫苗 ,并用IFA、PCR和TCID50 等方法对其特异性进行鉴定。通过重组腺病毒感染人树突状细胞 (DC) ,在体外活化自体T细胞 ;以及通过重组腺病毒感染小鼠淋巴细胞 ,皮下免疫同种小鼠 ,体内活化CTL评价其免疫效果。结果　通过PCR以及间接免疫荧光试验分别证实了病毒目的基因LMP2的存在以及蛋白在 2 93细胞中的表达。采用TCID50 方法 ,测定第 6代的病毒滴度为 2× 10 8。体内外的免疫实验结果显示通过这两种方式均可以有效地引发针对EBV LMP2的CTL反应。结论　包含EBV LMP2基因的重组腺病毒疫苗可以在体内外有效地引发CTL应答 ,这些资料为下一步临床应用含LMP2的重组腺病毒作为疫苗治疗和预防EBV相关肿瘤奠定了基础。     

Chimeric Dr fimbriae with a herpes simplex virus type 1 epitope as a model for a recombinant vaccine

The potential of the major structural protein DraE of Escherichia coli Dr fimbriae has been used to display an 11-amino-acid peptide of glycoprotein D derived from herpes simplex virus (HSV) type 1. The heterologous sequence mimicking an epitope from glycoprotein D was inserted in one copy into the draE gene in place of a predicted 11-amino-acid sequence in the N-terminal region of surface-exposed domain 2 within the conserved disulfide loop (from Cys21 to Cys53). The inserted epitope was displayed on the surface of the chimeric DraE protein as evidenced by immunofluorescence and was recognized by monoclonal antibodies to the target HSV glycoprotein D antigen. Conversely, immunization of rabbits with purified chimeric Dr-HSV fimbriae resulted in a serum that specifically recognized the 11-amino-acid epitope of HSV glycoprotein D, indicating the utility of the strategy employed.     

Major population differences in T cell response to a malaria sporozoite vaccine candidate.

Using a complete series of overlapping peptides, we have identified the T cell epitopes of a malaria vaccine candidate, the circumsporozoite (CS) protein, that are recognized by sporozoite-exposed residents of a non-endemic country. This protein and subunits from it are being considered as malaria sporozoite vaccine candidates, as CS-specific antibodies and cytotoxic T lymphocytes have been shown to have a role in protection. The rationale for developing an antibody-based vaccine is that in Plasmodium falciparum the immunodominant B cell epitope of the protein, (Asn-Ala-Asn-Pro)n [(NANP)n], is invariant. However, the ideal vaccine must contain CS protein-derived T cell antigenic epitopes to allow natural boosting of the antibody response following sporozoite exposure. Here, we show that major differences occur between the CS-specific T cell responses of non-endemic Caucasians and an endemic African population. HLA differences between the populations are, in part, responsible. Subunit malaria vaccines for one population may be ineffective in a different population.     

The future of plague vaccines: hopes raised by a surrogate, live-attenuated recombinant vaccine candidate

Yersinia pestis (YP) is the Gram-negative etiological agent of plague against which no commercial vaccine exists to prophylactically prevent a potential outbreak due to natural or bio-warfare/terrorism-mediated causes. The US FDA only recently approved levofloxacin to combat this deadly pathogen. In the article under review, an attenuated, recombinant Salmonella typhimurium ΔphoPQ mutant strain producing YP antigens F1, LcrV and F1-V (fusion protein) from either low-copy pBR or high-copy pUC vectors (maintained by plasmid addiction rather than antibiotic selection pressure) were evaluated for their ability to induce a humoral immune response in both mice and rabbits. This study highlights the need for developing a well-tolerated YP vaccine that, through the oral route, can be readily administered and elicit both mucosal and systemic anti-plague humoral immunity.     

Antibody to a recombinant merozoite protein epitope identifies horses infected with Babesia equi.

Horses infected with Babesia equi were previously identified by the presence of antibodies reactive with a merozoite surface protein epitope (D. P. Knowles, Jr., L. E. Perryman, L. S. Kappmeyer, and S. G. Hennager. J. Clin. Microbiol. 29:2056-2058, 1991). The antibodies were detected in a competitive inhibition enzyme-linked immunosorbent assay (CI ELISA) by using monoclonal antibody 36/133.97, which defines a protein epitope on the merozoite surface. The gene encoding this B. equi merozoite epitope was cloned and expressed in Escherichia coli. The recombinant merozoite protein, designated equi merozoite antigen 1 (EMA-1), was evaluated in the CI ELISA. Recombinant EMA-1 bound antibody from the sera of B. equi-infected horses from 18 countries. The antibody response to EMA-1 was then measured in horses experimentally infected with B. equi via transmission by the tick vector Boophilus microplus or by intravenous inoculation. Anti-EMA-1 antibody was detected 7 weeks post-tick exposure and remained, without reexposure to B. equi, for the 33 weeks of the evaluation period. The data indicate that recombinant EMA-1 can be used in the CI ELISA to detect horses infected with B. equi.