T and B cell responses to chimeric proteins containing heterologous T helper epitopes inserted at different positions

Immunological Analysis of Nodavirus Capsid Displaying the Domain III of Japanese Encephalitis Virus Envelope Protein

Japanese encephalitis virus (JEV) is the pathogen that causes Japanese encephalitis (JE) in humans and horses. Lethality of the virus was reported to be between 20–30%, of which, 30–50% of the JE survivors develop neurological and psychiatric sequelae. Attributed to the low effectiveness of current therapeutic approaches against JEV, vaccination remains the only effective approach to prevent the viral infection. Currently, live-attenuated and chimeric-live vaccines are widely used worldwide but these vaccines pose a risk of virulence restoration. Therefore, continuing development of JE vaccines with higher safety profiles and better protective efficacies is urgently needed. In this study, the Macrobrachium rosenbergii nodavirus (MrNV) capsid protein (CP) fused with the domain III of JEV envelope protein (JEV-DIII) was produced in Escherichia coli. The fusion protein (MrNV-CP^JEV-DIII) assembled into virus-like particles (VLPs) with a diameter of approximately 18 nm. The BALB/c mice injected with the VLPs alone or in the presence of alum successfully elicited the production of anti-JEV-DIII antibody, with titers significantly higher than that in mice immunized with IMOJEV, a commercially available vaccine. Immunophenotyping showed that the MrNV-CP^JEV-DIII supplemented with alum triggered proliferation of cytotoxic T-lymphocytes, macrophages, and natural killer (NK) cells. Additionally, cytokine profiles of the immunized mice revealed activities of cytotoxic T-lymphocytes, macrophages, and NK cells, indicating the activation of adaptive cellular and innate immune responses mediated by MrNV-CP^JEV-DIII VLPs. Induction of innate, humoral, and cellular immune responses by the MrNV-CP^JEV-DIII VLPs suggest that the chimeric protein is a promising JEV vaccine candidate.

Antibody responses to chimeric peptides derived from parasite antigens in mice and other animal species

Peptide vaccines constitute an interesting alternative to classical vaccines due to the possibility of selecting specific epitopes, easy of production and safety. However, an inadequate design may render these peptides poorly immunogenic or lead to undesirable outcomes (e.g., formation of B neoepitopes). As an approach to vaccine development, we evaluated the antibody response to chimeras composed of two or three known B epitopes from Trichinella and Fasciola, and several linkers (GSGSG, GPGPG and KK) in species as different as mice, sheep and turbot. All these species could mount an effective immune response to the short chimeric peptides. Nevertheless, this response depended on several factors including a favorable orientation of B-cell epitopes, adequateness of linkers and/or probability of formation of T neoepitopes. We also observed that, at least in mice, the inclusion of a decoy epitope may have favorable consequences on the antibody response to other epitopes in the chimera.

Design and Evaluation of a Multi-Epitope Peptide of Human Metapneumovirus

OBJECTIVES

No licensed vaccines or therapeutic agents for human metapneumovirus (hMPV) infection exist to date. We aimed to construct a multi-epitope peptide (MEP) of hMPV to show promising results for epitope-based vaccine development.

METHODS

Six independent algorithms were screened to predict B-cell epitopes of hMPV, and three algorithms were used to predict cytotoxic T lymphocyte and T helper (Th) lymphocyte epitopes. Predicted epitopes were assembled in series with the spacers GPGPG and KK introduced, termed MEP. Recombinant mep genes were inserted into pET32a(+) plasmid and expressed in Escherichia coli strain BL21 (DE3). BALB/c mice were immunized with MEP with different adjuvants. Antibody titer, lymphocyte proliferation, cytotoxic T lymphocyte (CTL) activity and splenocyte cytokines were detected 2 weeks later after the last immunization. Microneutralization assay was used to detect neutralizing antibodies.

RESULTS

Six B-cell epitopes, four CTL epitopes and two Th epitopes were screened to construct the mep gene. Expressed MEP induced >104 antibodies in BALB/c mice, and produced anti-MEP antibody reacting with hMPV strains specifically as detected in indirect fluorescent assay (the titer was 160). The lymphocyte proliferation index, CTL activity and splenocyte cytokines of the MEP immunization groups were higher than in the control group (p < 0.05). Both IgG1 and IgG2a antibodies could be detected in the different groups, and balanced Th1/Th2 cytokines were secreted by splenocytes in these groups. The mean neutralizing titers of the MEP+CpG ODN, MEP+Alum and MEP+Alum+ CpG ODN groups were 87 (95% CI 50-126), 93 (95% CI 67-121) and 96 (95% CI 69-147), respectively.

CONCLUSION

MEP of hMPV elicited both strong humoral immunity and cell-mediated immunity in mice. The anti-MEP serum could neutralize hMPV infection in vitro. Joint use of CpG ODN and aluminum hydroxide adjuvants obtained the best immune effects. This study may contribute to hMPV epitope-based vaccine development.

Carrier protein influences immunodominance of a known epitope: implication in peptide vaccine design

We investigated how the processing of a given antigen by antigen presenting cells (APC) is dictated by the conformation of the antigen and how this governs the immunodominance hierarchy. To address the question, a known immunodominant sequence of bacteriophage lambda repressor N-terminal sequence 12-26 [λR(12-26)] was engineered at the N and C termini of a heterologous leishmanial protein, Kinetoplastid membrane protein-11 (KMP-11); the resulting proteins were defined as N-KMP-11 and C-KMP-11 respectively. The presence of λR(12-26) in N-KMP-11 and C-KMP-11 was established by western blot analysis with antibody to λR(12-26) peptide. N-KMP-11 but not C-KMP-11 could stimulate the anti λR(12-26) T-cell clonal population very efficiently in the presence of APCs. Priming of BALB/c mice with N-KMP-11 or C-KMP-11 generated similar levels of anti-KMP-11 IgG, but anti-λR(12-26) specific IgG was observed only upon priming with N-KMP-11. Interestingly, uptake of both N-KMP-11 and C-KMP-11 by APCs was similar but catabolism of N-KMP-11 but not C-KMP-11 was biphasic and fast at the initial time point. Kratky plots of small angle X-ray scattering showed that while N-KMP-11 adopts flexible Gaussian type of topology, C-KMP-11 prefers Globular nature. To show that KMP-11 is not unique as a carrier protein, an epitope (SPITBTNLBTMBK) of Plasmodium yoelii (PY) apical membrane protein 1[AMA-1 (136-148)], is placed at the C and N terminals of a dominant T-cell epitope of ovalbumin protein OVA(323-339) and the resulting peptides are defined as PY-OVA and OVA-PY respectively. Interestingly, only OVA-PY could stimulate anti-OVA T-cells and produce IgG response upon priming of BALB/c mice with it. Thus for rational design of peptide vaccine it is important to place the dominant epitope appropriately in the context of the carrier protein.

Recombinant vaccine displaying the loop-neutralizing determinant from protective antigen completely protects rabbits from experimental inhalation anthrax

We previously showed that a multiple antigenic peptide (MAP) vaccine displaying amino acids (aa) 304 to 319 from the 2β2-2β3 loop of protective antigen was capable of protecting rabbits from an aerosolized spore challenge with Bacillus anthracis Ames strain. Antibodies to this sequence, referred to as the loop-neutralizing determinant (LND), are highly potent at neutralizing lethal toxin yet are virtually absent in rabbit and human protective antigen (PA) antiserum. While the MAP vaccine was protective against anthrax, it contains a single heterologous helper T cell epitope which may be suboptimal for stimulating an outbred human population. We therefore engineered a recombinant vaccine (Rec-LND) containing two tandemly repeated copies of the LND fused to maltose binding protein, with enhanced immunogenicity resulting from the p38/P4 helper T cell epitope from Schistosoma mansoni. Rec-LND was found to be highly immunogenic in four major histocompatibility complex (MHC)-diverse strains of mice. All (7/7) rabbits immunized with Rec-LND developed high-titer antibody, 6 out of 7 developed neutralizing antibody, and all rabbits were protected from an aerosolized spore challenge of 193 50% lethal doses (LD(50)) of the B. anthracis Ames strain. Survivor serum from Rec-LND-immunized rabbits revealed significantly increased neutralization titers and specific activity compared to prechallenge levels yet lacked PA or lethal factor (LF) antigenemia. Control rabbits immunized with PA, which were also completely protected, appeared sterilely immune, exhibiting significant declines in neutralization titer and specific activity compared to prechallenge levels. We conclude that Rec-LND may represent a prototype anthrax vaccine for use alone or potentially combined with PA-containing vaccines.

Multiple linear epitopes (B-cell, CTL and Th) of JEV expressed in recombinant MVA as multiple epitope vaccine induces a protective immune response

Epitope-based vaccination might play an important role in the protective immunity against Japanese encephalitis virus (JEV) infection. The purpose of the study is to evaluate the immune characteristics of recombinant MVA carrying multi-epitope gene of JEV (rMVA-mep). The synthetic gene containing critical epitopes (B-cell, CTL and Th) of JEV was cloned into the eukaryotic expression vector pGEM-K1L, and the rMVA-mep was prepared. BALB/c mice were immunized with different dosages of purified rMVA-mep and the immune responses were determined in the form of protective response against JEV, antibodies titers (IgG1 and IgG2a), spleen cell lymphocyte proliferation, and the levels of interferon-γ and interleukin-4 cytokines. The results showed that live rMVA-mep elicited strongly immune responses in dose-dependent manner, and the highest level of immune responses was observed from the groups immunized with 10⁷ TCID₅₀ rMVA-mep among the experimental three concentrations. There were almost no difference of cytokines and neutralizing antibody titers among 10⁷ TCID₅₀ rMVA-mep, recombinant ED3 and inactivated JEV vaccine. It was noteworthy that rMVA-mep vaccination potentiates the Th1 and Th2-type immune responses in dose-dependent manner, and was sufficient to protect the mice survival against lethal JEV challenge. These findings demonstrated that rMVA-mep can produce adequate humoral and cellular immune responses, and protection in mice, which suggested that rMVA-mep might be an attractive candidate vaccine for preventing JEV infection.

Design and evaluation of a multi-epitope peptide against Japanese encephalitis virus infection in BALB/c mice

Epitope-based vaccination is a promising means to achieve protective immunity and to avoid immunopathology in Japanese encephalitis virus (JEV) infection. Several B-cell and T-cell epitopes have been mapped to the E protein of JEV, and they are responsible for the elicitation of the neutralizing antibodies and CTLs that impart protective immunity to the host. In the present study, we optimized a proposed multi-epitope peptide (MEP) using an epitope-based vaccine strategy, which combined six B-cell epitopes (amino acid residues 75-92, 149-163, 258-285, 356-362, 373-399 and 397-403) and two T-cell epitopes (amino acid residues 60-68 and 436-445) from the E protein of JEV. This recombinant protein was expressed in Escherichia coli, named rMEP, and its protective efficacy against JEV infection was assessed in BALB/c mice. The results showed that rMEP was highly immunogenic and could elicit high titer neutralizing antibodies and cell-mediated immune responses. It provided complete protection against lethal challenge with JEV in mice. Our findings indicate that the multi-epitope vaccine rMEP may be an attractive candidate vaccine for the prevention of JEV infection.

Novel vaccines for the treatment of chronic HBV infection based on mycobacterial heat shock protein 70

Immunogenic peptide-based vaccines can raise significant cellular immune responses. Although cytotoxic T lymphocytes (CTL) peptide epitopes are generally poor immunogens, heat shock protein 70 from Mycobacterium tuberculosis (TBhsp70) can overcome this problem since it is a potent adjuvant that links innate and adaptive immune responses. Our goal is to use TBhsp70 as an adjuvant for development of therapeutic vaccines for chronic Hepatitis B virus infection (HBV). To this end, we genetically fused the HBV core 18-27 peptide (HBcAg((18-27))) as a CTL epitope to the C-terminus of TBhsp70 and expressed the resulting protein in methylotropic yeast Pichia pastoris GS115. At the same time, the TBhsp70-HBcAg((18-27)) peptide complex was reconstituted in vitro. We investigated whether TBhsp70-peptide complex and TBhsp70-peptide fusion protein could generate antigen specific CTL responses in vitro. Dendritic cells (DC) from HLA-A2(+) chronic HBV infection and healthy control pulsed with two vaccines were studied phenotypically by FACS analyses and functionally by cytokine release, and HBV-specific CTL response. Our results demonstrate that two vaccines can activate DC of chronic HBV infection and healthy control by upregulation CD40 and CD86, high production of IL-12p70 and TNF-alpha. Furthermore, autologous T cells with DC stimulated by two vaccines can produce IFN-gamma and generate HBV-specific CTL response. However, capacity for CTL response and cytokines production from HBV infections remained inferior to that of healthy controls. Thus, the strategy of utilizing TBhsp70 may provide a novel design for the development of prophylactic and therapeutic vaccines.

'Troy-bodies': antibodies as vector proteins for T cell epitopes

A major objective in vaccine development is the design of reagents that give a strong, specific T cell response. Targeting of antigens to antigen presenting cells (APC) results in enhanced antigen presentation and T cell activation. In this paper, we describe a novel targeting reagent denoted 'Troy-bodies', namely recombinant antibodies with APC-specificity and with T cell epitopes integrated in their C regions. We have made such antibodies with V regions specific for either IgD or MHC class II, and five different T cell epitopes have been tested. All epitopes could be introduced into loops of C domains without disrupting immunoglobulin (Ig) folding. Four have been tested in T cell activation studies, and all could be released and presented by APC. Furthermore, whether IgD- or MHC-specific, the molecules tested enhanced T cell stimulation compared to non-specific control antibodies in vitro as well as in vivo. Using this technology, specific reagents can be designed that target selected antigenic peptides to an APC of choice. Troy-bodies may therefore be useful for manipulation of immune responses, and in particular for vaccination purposes.

Impact of epitope permutations in the antibody response of mice to a multi-epitope polypeptide of the V3 loop of human immunodeficiency virus type 1

Our group have produced in Escherichia coli and evaluated the immunogenicity of different multi-epitope polypeptides (MEPs) bearing one copy of V3 loop sequential B cell epitopes from several isolates of human immunodeficiency virus type 1 (HIV-1) gp120. One of these MEPs called TAB9 comprises the 15 central amino acids of the V3 loop from isolates LR150, JY1, RF, MN, BRVA and IIIB in this order. Antibodies against all V3 regions were elicited after immunization of rabbits, macaques and humans with TAB9. In contrast, mice immunized with this protein only developed antibodies against epitopes JY1, LR150 and MN in that order (JY1>LR150>MN>>>RF, BRVA, IIIB) resembling an immunodominant gradient from the N-terminus to the C-terminal portion of this construction. To assess what role the location of the V3 epitopes in TAB9 could play, we constructed the protein TAB16, by altering the position of V3 epitopes in TAB9 primary structure and compared the pattern of antibodies elicited by both MEPs in H-2(d) Balb/c mice. The MEP TAB16 elicited antibody titers comparable to that of the sera from mice immunized with TAB9. There were no statistical differences in antibody titers between both groups (P>0.05). JY1, LR150 and MN V3 epitopes were again immunodominant in mice immunized with TAB16 fusion protein. The highest antibody titers detected in both groups among V3 epitopes corresponded to JY1, now located at the C-terminus of the permuted chimera. Antibodies against V3 epitopes RF, BRVA and IIIB were again not detected. Additionally, the MN V3 epitope showed to be significantly more immunogenic in its new orientation in TAB16, possibly as a result of a higher degree of accessibility in the surface of the protein. The results of the present investigation strongly suggest that the sequential order or the intramolecular position of V3 epitopes inside the primary structure of TAB9 and TAB16 MEPs does not interfere with the global immunogenicity or with the hierarchy of immunodominance of these regions.

"Troy-bodies": recombinant antibodies that target T cell epitopes to antigen presenting cells

Targeting of antigens to antigen presenting cells (APC) results in enhanced antigen presentation and T cell activation. In this paper, we describe a novel targeting reagent denoted "Troy-bodies", namely recombinant antibodies with APC-specific V regions and C regions with integrated T cell epitopes. We have made such antibodies with V regions specific for either IgD or MHC class II, and four different T cell epitopes have been tested. All four epitopes could be introduced into loops of C domains without disrupting Ig folding, and they could be released and presented by APC. Furthermore, whether IgD- or MHC-specific, the molecules enhanced T cell stimulation compared to non-specific control antibodies in vitro as well as in vivo. Using this technology, specific reagents can be designed that target selected antigenic peptides to an APC of choice. Troy-bodies may therefore be useful for manipulation of immune responses, and in particular for vaccination purposes.

The principle of delivery of T cell epitopes to antigen-presenting cells applied to peptides from influenza virus, ovalbumin, and hen egg lysozyme: implications for peptide vaccination

Targeting of antigens to antigen-presenting cells (APCs) increases CD4(+) T cell activation, and this observation can be exploited in the development of new vaccines. We have chosen an antigen-targeting approach in which we make recombinant antibodies (Abs) with T cell epitopes in their constant region and APC-specific variable regions. Three commonly used model epitopes, amino acids 110-120 of hemagglutinin, 323-339 of ovalbumin, and 46-61 of hen egg lysozyme, were introduced as loops in the C(H)1 domain of human IgG3. For all three epitopes, we show that the recombinant molecules are secreted from transfected cells. The epitopes are presented to specific T cells, and targeting to IgD on B cells in vitro enhances the presentation efficiency by 10(4) to 10(5) compared with the free peptide. After i.v. injection, the epitopes targeted to IgD are presented by splenic APCs to activate specific T cells, whereas little or no activation could be detected without targeting, even after the amount of antigen injected was increased 100-fold or more. Because a wide variety of T cell epitopes, in terms of both length and secondary structure, can be tolerated in loops in constant domains of Abs, the Ab constant region seems to have the intrinsic stability that is needed for this fusion molecule strategy. It might thus be possible to load the Ab with several different epitopes in loops in different domains and thereby make a targeted multisubunit vaccine.

Recombinant antibodies as carrier proteins for sub-unit vaccines: influence of mode of fusion on protein production and T-cell activation

A major objective in development of vaccines is the design of sub-unit vaccines with the ability to induce strong T-cell responses. For this purpose, T-cell epitopes have been genetically inserted into various carrier proteins. Ig molecules may be especially useful as vehicles for delivery of CD4(+) T-cell epitopes to antigen presenting cells (APC). We have previously replaced loop structures between beta-strands in the C(H)1 domain of human IgG3 with a defined 11 amino acids long, MHC class II-restricted T-cell epitope. In this report we have added the same T-cell epitope into loops in the C(H)1 domain of mouse IgG2b. The following major points can be made: (1) Loops can accommodate an elongation of at least 11 amino acids without disruption of the overall Ig structure and secretion. (2) The recombinant Ig molecules are processed by spleen APC and the epitopes that are released are presented to T-cells. (3) Site of integration influences efficiency of processing and presentation. (4) Elongation of two neighbouring loops reduces Ig secretion. Taken together, our present results indicate that IgG C(H)1 domains may be engineered to carry T-cell epitopes in loop structures between beta-strands, but not all loops may be equally suitable for this purpose.

Induction of P815 tumor immunity by recombinant Semliki Forest virus expressing the P1A gene

The methylcholantrene-induced P815 mastocytoma tumor is derived from DBA/2 mice and expresses a weak tumor rejection antigen, P815A. The P1A gene, which encodes for the P815A antigen, is silent in most normal tissues with the exception of testis and placenta. These characteristics make P815 an interesting mouse model for the human MAGE-type tumor antigens. Recombinant Semliki Forest virus particles (rSFV) were constructed that expressed variants of the P815 antigen. Such particles, when used for vaccination, express the antigen only transiently since the viral vector is incapable of productive replication. Nevertheless, mice vaccinated with rSFV generated strong CTL responses and were protected against P815 tumor challenge.

Conformational and linear B-cell epitopes of Asp f 2, a major allergen of Aspergillus fumigatus, bind differently to immunoglobulin E antibody in the sera of allergic bronchopulmonary aspergillosis patients

Asp f 2 is a major Aspergillus fumigatus allergen involved in allergic bronchopulmonary aspergillosis. Knowledge of the B-cell epitopes may contribute to the understanding of immunoregulation and immunodiagnosis. To elucidate the immunoglobulin E (IgE) binding epitopes in the linear sequence of Asp f 2, we synthesized decamer peptides spanning the whole molecule of Asp f 2 on derivatized cellulose membranes and evaluated IgE binding in ABPA patient and control sera. Peptides three to five amino acids long were synthesized based on amino acid sequences within the IgE binding regions and evaluated for the specificity of epitope antibody interactions. Nine IgE binding regions were recognized in this protein of 268 amino acid residues. Of the nine epitopes, seven (ATQRRQI, RKYFG, HWR, YTTRR, DHFAD, ALEAYA, and THEGGQ) are present in the hydrophilic regions of Asp f 2. Immunologic evaluation of the three recombinant fragments, Asp f 2A encompassing the N-terminal epitope region, Asp f 2B without N- and C-terminal regions of the protein, and Asp f 2C representing C-terminal epitopes, revealed that either the N- or C-terminal region of the protein is essential for the correct folding and conformation for IgE antibody binding.

Increasing Immunogenicity of Antigens Fused to Ig-Binding Proteins by Cell Surface Targeting

Fusion of antigenic proteins to Ig-binding proteins such as protein A from Staphylococcus aureus and its derived ZZ fragment is known to increase immunogenicity of the fused Ag in vivo. To shed light on the origin of this effect, we used snake toxins as Ags and observed that 1) fusion of toxins to ZZ enhanced their presentation to a toxin-specific T cell hybridoma (T1B2), using A20 B lymphoma cells, splenocytes, or peritoneal exudate cells as APCs; 2) this enhancement further increased when the number of fused Ig-binding domains varied from two with ZZ to five with protein A; and 3) the phenomenon vanished when the fusion protein was preincubated with an excess of free ZZ or when P388D1 monocytes cells were used as APCs. Therefore, ZZ-fused toxins are likely to be targeted to surface Igs of APCs by their ZZ moiety. Furthermore, ZZ-α and toxin α stimulated similar profiles of toxin-specific T cells in BALB/c mice, suggesting a comparable processing and presentation in vivo for both toxin forms. To improve the targeting efficiency, ZZ-α was noncovalently complexed to various Igs directed to different cell surface components of APCs. The resulting complexes were up to 103-fold more potent than the free toxin at stimulating T1B2. Also, they elicited both a T cell and an Ab response in BALB/c mice, without the need of any adjuvant. This simple approach may find practical applications by increasing the immunogenicity of recombinant proteins without the use of adjuvant.

Characterization of immune responses to experimental polyvalent subunit vaccines assembled in iscoms

Immune responses to experimental polyvalent subunit vaccines assembled in a particulate adjuvant/delivery system, iscoms, are described. The fusion protein ZZ-M5 comprises structures of staphylococcal protein A (ZZ) and the Plasmodium falciparum malaria antigen Pf155/RESA (M5). MHC congenic mice were immunized with ZZ-M5 conjugated to iscoms containing human influenza virus antigen (flu ag, M5-flu-isc) or to iscom matrix (iscom particles without flu ag, M5-isc). Comparison of antibody and T-cell responses to M5-isc and M5-flu-isc demonstrated that the flu ag in M5-flu-isc exhibits carrier-related helper functions and that the assembly of immunogens in M5-flu-isc did not result in any apparent antigenic competition. In addition, assembly of ZZ-M5 and flu ag in iscoms induced an alteration of the IgG subclass profile of the antibody response to M5. The results suggest that assembly of immunogens in iscoms may be a useful approach to the design of subunit vaccines but that both quantitative and qualitative aspects of the immunogenic properties of such constructs should be scrutinized.

Towards a recombinant vaccine against diphtheria toxin

Two recombinant fragments of diphtheria toxin (DT) were fused to an engineered tandem repeat of the immunoglobulin (Ig) binding domain of protein A, called ZZ. These fragments are (i) the receptor binding domain (DTR), which comprises amino acids 382 to 535 of DT, and (ii) a linear peptide (DT(168-220)) which comprises residues 168 to 220 of the loop between fragment A and fragment B of DT. The fusion proteins were produced in Escherichia coli and purified by affinity chromatography. In vitro experiments showed that the DTR domain is responsible for the capacity of ZZ-DTR to bind to Vero cells and is capable of inhibiting the cytotoxicity of DT for these cells. These findings suggest that DTR binds to the cell surface receptors of DT and hence adopts a conformation that is similar to that of the receptor binding domain of DT. We compared the capacities of ZZ-DTR, ZZ-DT(168-220), and a chemically detoxified form of DT currently used for vaccination to elicit antibodies in rabbits. The toxoid was more immunogenic than ZZ-DT(168-220), which in turn was more immunogenic than ZZ-DTR. However, ZZ-DT(168-220) antiserum was poorly efficient at neutralizing DT cytotoxicity on Vero cells, whereas ZZ-DTR antiserum was only 15-fold less potent than anti-DT antisera.

Tandem repeats of T helper epitopes enhance immunogenicity of fusion proteins by promoting processing and presentation

Empirical findings have shown that recombinant chimeric proteins may be made more immunogenic if T helper epitopes are incorporated as tandem repeats. In the present study we investigated the mechanisms responsible for the enhanced immunogenicity of fusion proteins composed of the heat-stable enterotoxin of enterotoxigenic E. coli (STa) linked to multiple copies of the ovalbumin323-339 T helper epitope (ova) and a connecting dimer of an Ig-binding region of Staphylococcus aureus protein A (ZZ), which were previously shown to stimulate strong anti-STa titres in mice. We used B cell and macrophage cell lines as APC and IL-2 production by ova-specific T cells as our read-out system. Fusion proteins containing four repeated T helper epitopes were found to be the most immunogenic and resulted in 50-fold higher IL-2 production than constructs with a single T helper epitope. Under limiting APC conditions the construct with four epitopes was the best inducer of IL-2, indicating that this construct was most effectively processed by the APC. Analysis of IL-2R alpha expression by flow cytometry confirmed that four copies gave the highest frequency of activated T cells in culture, indicating a direct correlation between ability to activate T cells and IL-2 production in culture. Also in vivo, the fusion protein with four epitopes exhibited the strongest T cell priming effect. Moreover, both in vitro and in vivo, the ZZ construct was found to serve as an efficient means for targeting of the fusion proteins to B cells, thereby allowing access to the Ig receptor uptake pathway for Ag. The present study provides direct evidence that fusion proteins can be constructed to optimize processing in the individual APC and enhance activation of clonal T cells.

Predominance of H-2d- and H-2k-restricted T-cell epitopes in the highly repetitive Plasmodium falciparum antigen Pf332

Genetic restriction of immune responses to malaria antigens is an important issue for a better comprehension of malaria immunity as well as for development of subunit vaccines. To experimentally define the major histocompatibility complex restriction of immune responses to the highly repetitive Plasmodium falciparum high-molecular-weight antigen Pf332, H-2-congenic mice were immunized with EB200, a recombinant fragment of Pf332 consisting of degenerate repeat motifs. Strong B- and T-cell responses were elicited in H-2d and H-2k mice whereas responses in H-2b, H-2q and H-2s mice were of lower magnitude. The T-cell specificity elicited by EB200 was defined by in vitro proliferative responses to a panel of overlapping peptides spanning EB200. Dominant epitopes were identified for H-2d and H-2k mice, respectively, and an additional epitope was recognized by all five mouse strains. Selected EB200-derived peptides were further investigated for their ability to elicit T-cell help when injected as multiple antigen peptides. Defined H-2d- and H-2k-restricted T-cell epitopes generated high antibody levels in the respective mouse strains, as did several peptides lacking defined epitopes indicating the presence of additional H-2d- and H-2k-restricted, cryptic or subdominant T-cell epitopes in EB200. The biased H-2 restriction pattern of T-cell epitopes in Pf332 and, as previously reported, in structurally related repeats in the malaria antigens Pf11.1 and Pf155/RESA may be explained by a shared motif for H-2d and H-2k class II-restricted T-cell epitopes, as revealed by alignment of these sequences.

Antigenicity of HIV-derived T helper determinants in the context of carrier recombinant proteins: effect on T helper cell repertoire selection

T helper (Th) epitopes can be included in a recombinant protein with B and CTL epitopes to create more effective immunogens. To determine whether the antigenicity of HIV Th epitopes is preserved in this altered molecular context, human Th clones specific for peptides of HIV gp120 and reverse transcriptase p66 were challenged with recombinant proteins carrying the antigenic epitopes in different sites. We found that a given epitope was recognized by a specific T cell clone only when it was inserted in a particular position of the carrier. However, the permissive position was not the same for all epitopes. Enzymatic excision from a nonpermissive context or insertion of a polyserine spacer between the epitope and the carrier restored antigenicity. Nevertheless, antigenicity was not abolished in a synthetic peptide encompassing the epitope and the neighboring residues from the nonpermissive location. These data suggest that, in this case, the primary sequence of the chimeric protein flanking the HIV peptide is not responsible for loss of antigenicity. Furthermore, constructs carrying the epitope in a given position were recognized by peptide-specific Th clones raised from some individuals, but not from others. We show that this is due neither to individual modes of processing nor to the use of distinct major histocompatibility complex MHC class II restriction elements, but rather that it is related to the fine specificity of the clones. To study the effect of epitope context on selection of T cell repertoire in a naive individual, T cell lines were generated in vitro by stimulation with different peptide constructs. This resulted in the induction of diverse clonotypes defined by the pattern of recognition of different constructs, by T cell receptor V beta gene usage and by fine epitope mapping.

A versatile system for the production of recombinant chimeric peptides

Production of chimeric and multimeric peptides is of interest for the analysis of topographic relationships between T and B cell stimulatory epitopes. Recombinant DNA technology has certain advantages over conventional chemical peptide synthesis for the production of peptide constructs of large size (more than 40 amino acid residues). We describe a methodology which is versatile and independent of the expression vector used because it only relies on the incorporation of appropriate restriction enzyme sites in oligonucleotides. The method was verified using two 20mer sequences from the 38 kDa antigen of M. tuberculosis. Peptide 201-220, containing an antibody binding linear epitope, has been made immunogenic in vivo when combined with T cell stimulatory peptide 350-369 in a chimeric peptide. The results demonstrate that a distinct orientation of the constituent peptides was essential for achieving optimal immunogenicity.

Fusion proteins with heterologous T helper epitopes. Recombinant E. coli heat-stable enterotoxin proteins

Fusion proteins containing specific B cell and T cell epitopes were used to examine how the intramolecular arrangement of T and B cell epitopes within a chimeric protein influences antigen-specific B cell antibody responses as well as specific T cell activation. Chimeric proteins, containing single or multiple copies of the Th epitope ovalbumin 323-339 (ova) linked at different positions to STa, the heat-stable enterotoxin of E. coli, were compared with respect to their ability to induce STa-specific antibody production and to induce ova-specific T cell activation. Chimeric proteins induced ova-dependent antibody production against STa at the amino terminal end, irrespective of the positioning of ova. Multiple tandem copies of ova in any position led to increased levels of antibody production against this epitope. In contrast, T cell help for antibody production against a second B cell epitope at the carboxy terminus of the fusion proteins was more effective after insertion of multiple copies of ova in a distal than in an adjacent position. A fusion protein, containing four copies of ova effectively elicited T cell help for antibody production against both examined B cell determinants, showing that activated Th cells recognizing a single epitope could simultaneously provide help for distinct sets of B cells specific for widely separated epitopes within a protein. T cell recognition of ova in all chimeric peptides, independently of its position, following the same pattern of genetic restriction (i.e. immunodominant in H-2d and nonimmunogenic in H-2k) as in the native ovalbumin molecule.(ABSTRACT TRUNCATED AT 250 WORDS)

Immunogenicity of viral B- and T-cell epitopes expressed in recombinant bacterial proteins

Foreign polypeptides can be expressed as genetic inserts in several permissive sites of MalE and LamB, two Escherichia coli envelope proteins. Several viral B and T-cell epitopes have been inserted in these proteins and we analyzed the role of the molecular environment on the immunogenicity of the foreign epitopes. These studies demonstrated that the antigenicity and immunogenicity of B-cell epitopes depend on their site of insertion in the carrier protein. Using bacteria expressing B-cell epitopes either at the cell surface or in the periplasm, it was also shown that the cellular location of a foreign B-cell epitope expressed by recombinant bacteria determines its T-cell dependent or independent characteristics. Analysis of in vivo immunogenicity of purified LamB or MalE hybrid proteins expressing two different T-cell epitopes established that the immunogenicity of recombinant T-cell epitopes may be strongly affected by both the insertion site and inserted adjacent residues. The in vitro analysis of specific T-cell hybridoma response to hybrid MalE proteins also showed that the molecular context of a T-cell determinant alters the diversity of its T-cell recognition.

Immunodominance of a recombinant T-cell epitope depends on its molecular environment

In the present study, we have investigated the influence of the molecular environment of a T-cell epitope on its immunogenicity. We genetically inserted into different sites of two bacterial recipient proteins, LamB or MalE, an immunodominant T-cell epitope: the 120-132 T-cell epitope from the PreS2 region of HBV. The T-cell epitope was introduced, either alone (PreS:T) or with an adjacent B-cell epitope (PreS:TB). After purification, the hybrid proteins were injected into mice and we studied the immunogenicity of recombinant T-cell epitopes by analyzing the in vitro proliferative responses of LN cells from these mice to the inserted peptides. The immunization of mice with recombinant MalE protein containing the PreS:T or PreS:TB peptides at two different sites induced strong peptide-specific proliferative responses, indicating that the insertion sites did not affect the immunodominance of the inserted T-cell epitope. A strong T-cell proliferative response was also obtained after immunization of mice with hybrid LamB protein containing the PreS:TB epitope at position 153. In contrast, the recombinant proteins which contained only the PreS:T epitope at positions 153 or 374 failed to stimulate T-cell responses. Therefore, this study demonstrates that the immunogenicity of recombinant T-cell epitopes may be strongly affected both by the insertion site and by inserted adjacent residues.

Induction of T cell responses by chimeric bacterial proteins expressing several copies of a viral T cell epitope

A viral T cell epitope was genetically inserted within the periplasmic MalE protein of Escherichia coli in two different permissive insertion sites and resulting hybrid proteins were used to study the in vitro and in vivo immunogenicity of the foreign T cell epitope. Purified hybrid MalE proteins containing the T cell epitope 120-132 (PreS:T) from PreS2 region of hepatitis B virus HBsAg inserted alone or with its adjacent B cell epitope (132-145) were able to induce strong peptide-specific T cell responses in mice. In vitro stimulation of primed lymph node cells or specific T cell hybridomas by the hybrid proteins required processing of the inserted T cell epitope and was inhibited by antigen-presenting cells fixation. The inserted T cell epitope was presented in vitro, in association with appropriate major histocompatibility complex molecules, as efficiently as free synthetic peptide. The in vitro immunogenicity of MalE hybrid proteins was increased by inserting four tandemly repeated copies of PreS:T, either at site 133 or 303. These results were confirmed in vivo by comparing the proliferative responses of lymph node cells from DBA/1 mice primed with MalE hybrid proteins containing one or four copies of PreS:T. Thus, the use of MalE hybrid proteins expressing multiple copies of a given foreign T cell epitope allows the induction of peptide-specific T cell response with a lower dose of priming antigen.

Influence of the T-helper epitope on the titre and affinity of antibodies to B-cell epitopes after co-immunization

We have assessed the influence of different T-helper cell epitopes on the level and affinity of antibody to B-cell epitopes induced following co-immunization with free peptides mimicking epitopes from measles and respiratory syncytial virus envelope proteins. The responses obtained following co-immunization have been compared to those obtained following immunization with chimeric synthetic peptide immunogens in which the epitopes were covalently coupled. The results show that covalent linkage of the B- and T-cell epitopes is not necessary for the generation of T-cell dependent antibody responses to non-immunogenic B-cell epitopes. In addition the induction of memory B-cells required adjuvant but subsequent stimulation of these memory cells did not. The responses obtained were non-MHC restricted since co-immunization resulted in the production of antibody responses to B-cell epitopes in a panel of five inbred mouse strains but there were differences in the ability of different T-cell epitopes to provide help for antibody production to the same B-cell epitope. The affinity of antibodies to the B-cell epitopes induced following immunization with chimeric T:B peptides was higher than that obtained following co-immunization. These results indicate the value of co-immunization for the induction of antibody responses to B-cell epitopes across MHC differences and suggest that this strategy may be of value in the development of synthetic peptide vaccines. However, modifications of the approach need to be developed to ensure the production of antibody of the highest possible affinity.

Engineered bacterial receptors in immunology

Gram-positive surface receptors, such as staphylococcal protein A ans streptococcal protein G, have been genetically engineered for many applications in the field of immunology, including detection antigens, affinity purification of fusion proteins and display of heterologous epitopes on the surface of bacterial cells.