Immunological characterization of a rotavirus-neutralizing epitope fused to the cholera toxin B subunit

Structure-guided design and immunological characterization of immunogens presenting the HIV-1 gp120 V3 loop on a CTB scaffold

V3 loop is a major neutralizing determinant of the HIV-1 gp120. Using 3D structures of cholera toxin B subunit (CTB), complete V3 in the gp120 context, and V3 bound to a monoclonal antibody (mAb), we designed two V3-scaffold immunogen constructs (V3-CTB). The full-length V3-CTB presenting the complete V3 in a structural context mimicking gp120 was recognized by the large majority of our panel of 24 mAbs. The short V3-CTB presenting a V3 fragment in the conformation observed in the complex with the 447-52D Fab, exhibited high-affinity binding to this mAb. The immunogens were evaluated in rabbits using DNA-prime/protein-boost protocol. Boosting with the full-length V3-CTB induced high anti-V3 titers in sera that potently neutralize multiple HIV virus strains. The short V3-CTB was ineffective. The results suggest that very narrow antigenic profile of an immunogen is associated with poor Ab response. An immunogen with broader antigenic activity elicits robust Ab response.

Rabies glycoprotein fused with B subunit of cholera toxin expressed in tobacco plants folds into biologically active pentameric protein

The pentameric B subunit of cholera toxin (CtxB) is an efficient mucosal adjuvant for vaccines. We report the expression of a chimeric protein comprising the synthetic cholera toxin B subunit fused at its C-terminal with rabies surface glycoprotein (G protein) in tobacco plants. The approximately 80.3 kDa fusion polypeptide expressed at 0.4% of the total soluble protein in leaves of the selected transgenic lines. The fusion protein formed a approximately 403 kDa pentameric protein which was functionally active in binding to GM1 receptor. The plant-made protein had a higher affinity for GM1 receptor than the native bacterial CtxB. The pentameric fusion protein was recognized by the anti-cholera toxin as well as anti-rabies antibodies. Its immuno-protective ability against rabies remains to be examined.

A Sabin 1 poliovirus-based vaccine vector transfects Vero cells with high efficiency

Over the past 40 years, live oral poliovirus (PV) vaccines have contributed to the eradication of wild PV in most countries. These live vaccine strains have a high safety record and can stimulate both cellular and humoral immune responses. As both of these factors are critical characteristics of a good vaccine, we aimed to modify the oral PV vaccines to create a powerful vaccine vector for extraneous antigen expression. In this study, we amplified three separate fragments from the Sabin 1 virus genome by RT-PCR and cloned them into the pGEM-TEasy vector. A cassette containing engineered protease cleavage sites and a polylinker was introduced into one of these fragments (f1) in front of the translation start site. This construction facilitated the insertion of foreign genes into the vector and the subsequent release of their co-translated antigens after digestion by endogenous protease. We also placed a ribozyme (Rz) sequence between the T7 promoter and viral genomic DNA so that in vitro transcription and Rz cleavage recreated the authentic 5′ end of the PV genome RNA. Poly(A)₄₀ tails were added to the 3′ end of the genome to stabilize the transcribed RNA. The three PV genome fragments and their derivatives were cloned into various types of vectors that were transfected into Vero cells. Virus rescue experiments demonstrated that both the Rz and poly(A)₄₀ elements were required for high transfection efficiency of the vector-derived RNAs.

Expression systems and developments in plant-made vaccines

Delivery of vaccines to mucosal surfaces can elicit humoral and cell-mediated responses of the mucosal and systemic immune systems, evoke less pain and discomfort than parenteral delivery, and eliminate needle-associated risks. Transgenic plants are an ideal means by which to produce oral vaccines, as the rigid walls of the plant cell protect antigenic proteins from the acidic environment of the stomach, enabling intact antigen to reach the gut associated lymphoid tissue. In the past few years, new techniques (such as chloroplast transformation and food processing) have improved antigen concentration in transgenic plants. In addition, adjuvants and targeting proteins have increased the immunogenicity of mucosally administered plant-made vaccines. These studies have moved plant-made vaccines closer to the development phase.

New approaches to improve a peptide vaccine against porcine Taenia solium cysticercosis

Cysticercosis caused by Taenia solium frequently affects human health and rustic porciculture. Cysticerci may localize in the central nervous system of humans causing neurocysticercosis, a major health problem in undeveloped countries. Prevalence and intensity of this disease in pigs and humans are related to social factors (poor personal hygiene, low sanitary conditions, rustic rearing of pigs, open fecalism) and possibly to biological factors such as immunity, genetic background, and gender. The indispensable role of pigs as an obligatory intermediate host in the life cycle offers the possibility of interfering with transmission through vaccination of pigs. An effective vaccine based on three synthetic peptides against pig cysticercosis has been successfully developed and proved effective in experimental and field conditions. The well-defined peptides that constitute the cysticercosis vaccine offer the possibility to explore alternative forms of antigen production and delivery systems that may improve the cost/benefit of this and other vaccines. Encouraging results were obtained in attempts to produce large amounts of these peptides and increased its immunogenicity by expression in recombinant filamentous phage (M13), in transgenic plants (carrots and papaya), and associated to bacterial immunogenic carrier proteins.

Protection of gerbils from amebic liver abscess by vaccination with a 25-mer peptide derived from the cysteine-rich region of Entamoeba histolytica galactose-specific adherence lectin

The protozoan parasite Entamoeba histolytica causes extensive morbidity and mortality through intestinal infection and amebic liver abscess. Here we show that immunization of gerbils with a single keyhole limpet hemocyanin-coupled 25-mer peptide derived from the 170-kDa subunit of the E. histolytica galactose-binding adhesin is sufficient to confer substantial protection against experimentally induced amebic liver abscesses. Vaccination provided total protection in 5 of 15 immunized gerbils, and abscesses were significantly smaller (P < 0.01) in the remaining vaccinated animals. The degree of protection correlated with the titer of antibodies to the peptide, and results of passive transfer experiments performed with SCID mice were consistent with a role for antibodies in protection. In addition, parenteral or oral vaccination of gerbils with 13-amino-acid subfragments of the peptide N-terminally fused to the B subunit of cholera toxin also significantly inhibited liver abscess formation (P < 0.05). These data indicate that small peptides derived from the galactose-binding adhesin administered by the parenteral or oral route can provide protection against amebic liver abscess and should be considered as components of a subunit vaccine against invasive amoebiasis.

A cloning vector for efficient generation of cholera toxin B gene fusions for epitope screening

Gene fusion proteins with epitopes attached to the amino end of cholera toxin B subunit (CTB) are useful to raise immunological responses. We describe a cloning vector, designated pCTBtet, carrying a tetracycline resistance gene (TetR) between the leader peptide and mature CTB. Removal of TetR to insert oligonucleotides encoding fusion epitopes allowed for screening of tetracycline-sensitive clones. Restoration of the correct CTB reading phase was subsequently used to choose gene fusion candidate colonies. The use of pCTBtet permitted the rapid construction of 8 fusion proteins carrying 9-24 aa from Salmonella typhi OmpC and 6 hybrids with 7-31 aa from Escherichia coli colonization factor CFAI.

Fusions to the cholera toxin B subunit: influence on pentamerization and GM1 binding

The cholera toxin B (CTB) subunit has been used extensively in vaccine research as a carrier for peptide immunogens due to its immunopotentiating properties, where coupling has been obtained either by genetic fusion or chemical conjugation. For genetically fused immunogens both N- and C-terminal fusions have been used. Only shorter extensions have previously been evaluated and in some reports these fusions have impaired the biological functions of CTB, such as the ability to form pentamers and to adhere to its cell receptor, the GM1 ganglioside. Here we report the first systematic study where the same fusion partner has been used for either C-terminal, N-terminal or dual fusions to CTB. The serum albumin binding region (BB, approximately 25 kDa) from streptococcal protein G, which is known to fold independently of N- or C-terminal fusions, was selected as fusion partner. The three fusion proteins CTB-BB, BB-CTB and BB-CTB-BB were expressed in Escherichia coli, where they were efficiently secreted to the periplasmic space, and could be purified by affinity chromatography on human serum albumin (HSA) columns. The CTB fusion proteins were compared for their ability to form pentamers, by gel electrophoresis and size-exclusion chromatography, and it was concluded that all three fusion proteins were able to pentamerize. Interestingly, the C-terminal fusion to CTB showed most efficient pentamerization, while the dual fusion was much less efficient. Purified pentamer fractions from all three fusions where found to react to a monoclonal antibody described to react only to pentameric forms of CTB. In addition, the purified pentamer fractions were analyzed in an enzyme-linked immunosorbent assay (ELISA) for their ability to bind GM1, and it was found that the C-terminal fusion (CTB-BB) showed significant GM1-binding, but that also the N-terminal and dual CTB fusion proteins bound GM1, although less efficiently. The implications of the results for the design and use of CTB fusion proteins as subunit vaccines are discussed.

Progress towards development of a vaccine for amebiasis

The application of molecular biologic techniques over the past decade has seen a tremendous growth in our knowledge of the biology of Entamoeba histolytica, the causative agent of amebic dysentery and amebic liver abscess. This approach has also led to the identification and structural characterization of three amebic antigens, the serine-rich Entamoeba histolytica protein (SREHP), the 170-kDa subunit of the Gal/GalNAc binding lectin, and the 29-kDa cysteine-rich protein, which all show promise as recombinant antigen-based vaccines to prevent amebiasis. In recent studies, an immunogenic dodecapeptide derived from the SREHP molecule has been genetically fused to the B subunit of cholera toxin, to create a recombinant protein capable of inducing both antiamebic and anti-cholera toxin antibodies when administered by the oral route. Continued progress in this area will bring us closer to the goal of a cost-effective oral combination "enteric pathogen" vaccine, capable of inducing protective mucosal immune responses to several clinically important enteric diseases, including amebiasis.

Surface display of the cholera toxin B subunit on Staphylococcus xylosus and Staphylococcus carnosus

The heterologous surface expression of the cholera toxin B subunit (CTB) from Vibro cholerae in two staphylococcal species, Staphylococcus xylosus and Staphylococcus carnosus, has been investigated. The gene encoding native CTB (103 amino acids) was introduced into gene constructs encoding chimeric receptors designed to be translocated and anchored on the outer cell surface of the staphylococci. Since functionality of CTB is correlated with its ability to form pentamers and the capacity of the pentameric CTB to bind the GM1 ganglioside, both the surface accessibility and the functionality of the surface-displayed CTB receptors were evaluated. It could be concluded that the chimeric receptors were targeted to the cell wall of the staphylococci, since they could be released by lysostaphin treatment and, after subsequent affinity purification, identified as full-length products by immunoblotting. Surface accessibility of the chimeric receptors was demonstrated by a colorimetric assay and by immunofluorescence staining with a CTB-reactive rabbit antiserum. Pentamerization was investigated by using a monoclonal antibody described to be specific for pentameric CTB, and the functionality of the receptors was tested in a binding assay with digoxigenin-labelled GM1. It was concluded that functional CTB was present on both types of staphylococci, and for S. carnosus, the reactivity to the pentamer-specific monoclonal antibody and in the GM1 binding assay was indeed significant. The implications of the results for the design of live bacterial vaccine delivery systems intended for administration by the mucosal route are discussed.

Progress towards an amebiasis vaccine

Amebiasis (infection by Entamoeba histolytica) remains a major health problem in much of the developing world. Morbidity and mortality from amebic dysentery and amebic liver abscess have persisted despite the availability of effective anti-amebic therapy, suggesting a need for alternative measures of disease control. Through the application of recombinant DNA technology, several E. histolytica antigens have now been expressed in prokaryotic systems and tested in animal models as vaccines to prevent invasive amebiasis. In this review, Sam Stanley Jr discusses why a vaccine for amebiasis may be feasible, and describes the recent development of several promising recombinant E. histolytica antigen-based parenteral and oral vaccine candidates.

Design of synthetic peptides for oral vaccination

The rational design of effective oral vaccines based on synthetic peptides is a very ambitious undertaking, and involves the solution of huge problems related to protection of the antigens against degradation in the alimentary tract, efficient uptake of the antigens by the relevant cells, and efficient induction of long lasting systemic immunity, local immunity, or both. This paper summarises the steps, necessary to develop such synthetic oral vaccines. These steps involve: (1) the definition of B-cell epitopes; (2) the definition of T-cell epitopes; (3) definition of the carrier or backbone molecule; (4) definition of an immunomodulating element; (5) definition of an adjuvant element; and (6) definition of a targeting element. Good progress is being made with respect to the first three steps, the other steps still provide major challenges, notably the definition of targeting elements. Nevertheless, the first synthetic oral vaccines may become reality in the near future, depending on the speed by which new technology in the area of molecular recognition will develop, i.e. the appropriate chemistry, organic chemistry, molecular modelling, resolution of the molecular interaction of key molecules in microbiology and immunology.

The Salmonella ompC gene: structure and use as a carrier for heterologous sequences

The Salmonella typhi (St) ompC gene codes for a major outer membrane protein (OMP) that is highly expressed in both low and high osmolarity. By hybridization studies with the entire gene or with segments thereof, ompC was found to be highly conserved within 11 different Salmonella serotypes, with the exception of S. arizonae. The study included several St isolates from Mexico and Indonesia. Variation was only detected in two (e and f) of the seven regions previously found to vary between St and E. coli ompC. Chimeric OmpC proteins, carrying a rotavirus VP4 capsid protein epitope, are well recognized by a specific monoclonal antibody (mAb) against this epitope, either in OMP preparations (by enzyme-linked immunosorbent assay; ELISA) or intact cells (by ELISA and immunogold-labelling), indicating that regions c and f are oriented towards the cell surface and are probably exposed. As has been shown before for other regulated OMP, this experimental approach could be useful for the presentation of heterologous epitopes in order to gain knowledge about porin topology, for testing the effect of altered porin surface epitopes on bacterial physiology, or else, in the development of multivalent vaccines.

Oral immunization with the dodecapeptide repeat of the serine-rich Entamoeba histolytica protein (SREHP) fused to the cholera toxin B subunit induces a mucosal and systemic anti-SREHP antibody response

The intestinal protozoan parasite Entamoeba histolytica causes amebic dysentery, a major cause of morbidity worldwide. The induction of a mucosal antibody response capable of blocking amebic adhesion to intestinal cells could represent an approach to preventing E. histolytica infection and disease. Here we describe the expression of a chimeric protein containing an immunogenic dodecapeptide derived from the serine-rich E. histolytica protein (SREHP), fused to the cholera toxin B subunit (CtxB). The CtxB-SREHP-12 chimeric protein was purified from Escherichia coli lysates and retained the critical GM1 ganglioside-binding activity of the CtxB moiety. Mice fed the CtxB-SREHP-12 fusion protein along with a subclinical dose of cholera toxin developed mucosal immunoglobulin A and immunoglobulin G and systemic antibody responses that recognized recombinant and native SREHP. Our study confirms the feasibility of inducing mucosal immune responses to immunogenic peptides by their genetic fusion to the CtxB subunit and identifies the CtxB-SREHP-12 chimeric protein as a candidate oral vaccine to prevent E. histolytica infection.