Immunization of mice with recombinant S-adenosyl-L-homocysteine hydrolase protein confers protection against Brucella melitensis infection

Due to drawbacks of live attenuated vaccines, much attention has been focused on screening Brucella-protective antigens as subunit vaccine candidates. Here, an immunoproteomic assay was used to identify the immunogenic soluble proteins of Brucella melitensis 16M. In the present study, 27 unique immunogenic proteins were identified from the two-dimensional electrophoresis immunoblot profiles by liquid chromatography tandem MS (LC-MS/MS). From this set, the gene encoding one immunodominant protein of interest, S-adenosyl-l-homocysteine hydrolase (AdoHcyase), was expressed in Escherichia coli. The recombinant AdoHcyase induced a strong antibody response in BALB/c mice, and the polyclonal antibody could recognize a band of approximately 52 kDa in the immunoblots of soluble protein extracts from five Brucella strains. rAdoHcyase significantly stimulated the production of interferon-γ and interleukin-2, and induced a high level of protection against B. melitensis 16M challenge at 4 weeks postchallenge. Our results indicated that rAdoHcyase could be a useful candidate for the development of subunit vaccines against B. melitensis.     

A novel strategy for converting recombinant viral protein into high immunogenic antigen.

Interleukin 2 (IL-2) is a lymphokine promoting immune response and therefore has been investigated as an immunological adjuvant. In order to enhance the immunogenicity of recombinant viral protein, herpes simplex virus type 1 (HSV-1) glycoprotein D (gD), we genetically created a fusion protein consisting of gD and human IL-2. The fusion protein, without any other adjuvants, induced high antibody responses and cell-mediated immunity to HSV-1 in mice. Mice immunized with the fusion protein were protected against HSV-1 infection. The results indicate that IL-2-fusing can provide a means for converting a weak immunogenic protein into a high immunogenic antigen, and the strategy would be widely applicable to the other antigens for pathogens.     

Some serological properties ofActinobacillus pleuropneumoniae strains of serotypes 1 through 5

Rabbits were hyperimmunized with live, formalin-killed, and heat-treated antigen preparations of the reference strains of serotypes 1 through 5 ofActinobacillus pleuropneumoniae in order to study the antibody response to both soluble and particulate antigens. The antibody response was studied by means of precipitation, agglutination, coagglutination, indirect hemagglutination, and complement fixation tests.Serotyping ofA. pleuropneumoniae strains was done by ring precipitation (RP) and coagglutination (CoA) tests with unheated and heated cell-saline extract as antigens and rabbit hyperimmune sera produced against either live cultures or formalin-killed whole-cell suspensions. The results showed that live cultures provoked more cross-reactive antibodies in rabbits, thus making the antisera unsuitable for use in serotyping by the RP test when unheated wholecell saline extract was used as antigen. Rabbit hyperimmune serum produced against formalinkilled bacterial suspension gave serotype-specific reactions in the RP test. Boiled or autoclaved cell-saline extracts gave serotype-specific reactions in the RP test even when rabbit anti-livecell sera were used. Serotype-specific reactions were obtained in the CoA test in both rabbit anti-live or anti-formalin-killed cell sera with either unheated or heated bacterial cell suspensions as antigens.Live and formalin-killed whole-cell suspensions as well as their saline extracts provoked a high antibody response in rabbits. Heating the cell suspension at 100°C for 1 h caused a significant reduction in their immunogenic potency, whereas autoclaving (121°C) of the cell suspension for 1 h almost completely destroyed their serotype-specific immunogenic properties, since the antibody response was either absent or very poor and not type-specific. However, neither boiling nor autoclaving of the cell suspensions caused significant reduction in their ability to react with preformed antibodies. Phenol-water-extracted antigens gave the highest degree of serotype specificity in the complement fixation test.     

Immunity to Cholera: Relation of Fraction II of Type 2 Cholera Toxin to Vibriocidal Antibody

The nontoxic protein component in supernatant fluids of young cultures of the cholera vibrio in peptone dialysate broth contains an antigen identical in specificity to vibrio lipopolysaccharide. This material was heterogeneous after elution from diethylaminoethyl A50 Sephadex, and it contained at least five additional minor antigens. Identity was demonstrated by immunodiffusion methods, by the induction of specific vibriocidal antibody formation, and by specific interference in the vibriocidal reaction. The minor antigens appeared to be unrelated to the vibriocidal reaction. The major antigen was more highly immunogenic than lipopolysaccharide, giving higher and longer-persisting antibody titers in the rabbit, but lipopolysaccharide was the more effective interfering antigen per unit weight in the vibriocidal reaction. The nontoxicity and high immunogenic potency of the protein antigen suggest that it may be useful as an immunizing agent for the production of the antibacterial component of an effective immunity.     

Induction of immunity and specific unresponsiveness in vitro by cell-bound antigen: I. Symmetry in enhancement of both responses

Pulse treatment of lymphoid cells from rabbits with solubilized antigens from T2 phage results in the firm binding of small but highly active amounts of antigen. Binding of phage antigens to viable, nonviable, or disrupted cells enhances their ability to evoke antibody formation or specific unresponsiveness in the primary in vitro response of rabbit spleen cells. Transfer of sonicate containing the equivalent of 10₂ to 10₃ antigen-pulsed cells carrying 10^?8 to 10^?7 μg phage protein nitrogen into spleen cell cultures regularly evokes antibody formation, while introduction to such cultures of 10^?3 μg phage protein nitrogen in cell-bound form evokes unresponsiveness. These findings indicate a 10- to 100-fold amplification of tolerogenic and immunogenic activities of cell-bound over soluble T2 antigen.     

Conversion of a tolerogenic to an immunogenic signal by P388AD.2 cells, a lymphoid dendritic cell-like tumor line

The lymphoid dendritic cell-like tumor P388AD.2 is capable of converting a tolerogenic signal into an immunogenic one. In the present study, adherent P388AD.2 cells were pulsed with the tolerogen, fluoresceinated (FL) sheep gamma-globulin (SGG), washed, and incubated with normal spleen cells. After 24 hr, the spleen cells were harvested and challenged in secondary cultures with immunogenic doses of FL-thymic independent (TI) antigens. The plaque-forming cell response on day 3 of secondary culture was increased as much as 400% compared with control spleen cultures exposed to untreated P388AD.2 cells. The increased response was specific for the FL-hapten and occurred only when P388AD.2 cells were pulsed with FL-Ig or FL-F(ab')2 fragments, but not with FL-synthetic tolerogens or other FL-antigens. Furthermore, the augmentation required histocompatible T cells in the primary cultures. Additional experiments showed that if cultures were devoid of Lyt-1+ cells but not Lyt-2+ cells, no augmentation occurred. A variety of other macrophage-like tumor cells, some with known antigen presenting properties, were tested for the ability to present tolerogen in an immunogenic fashion. Only an I-A+ J774 clone was able to present tolerogen in an immunogenic fashion. However, we failed to find a correlation between the presence of surface Ia antigen and tolerogen-presenting ability. The results suggest that certain types of cells may play a role in immune regulation by abrogating the tolerogenicity of Ig tolerogens via their presentation in an immunogenic mode.     

Cholera Toxins: Immunogenicity of the Rabbit Ileal Loop Toxin and Related Antigens

A method of assay of immunogenic potency of the cholera gut toxin is described; it is based on the relation of dose of antigen to neutralizing antibody titer produced in the rabbit under defined conditions and allows quantification of immunogenicity as immunogenic units per milligram of protein. Evidence, based on immunogenicity and rabbit ileal loop toxicity, is presented which indicates that the positively charged fraction of liquid-culture supernatant fluid eluted in deionized water from diethylaminoethyl Sephadex, or in electrolyte from carboxymethyl Sephadex, is a complex made up of a nonantigenic toxic moiety, a nontoxic protein component which elicits the formation of toxin-neutralizing antibody, and an inactive fraction. The complex may also be dissociated in high-salt concentrations with apparent recombination of the toxic moiety with a nondialyzable constituent of peptone to give a negatively charged complex. The immunogenic component is found in nontoxic supernatant fluids of cultures grown at pH 6.5 or in media deficient in peptone. It is also present in the nontoxic fraction eluted from diethylaminoethyl Sephadex in electrolyte or in deionized water from carboxymethyl Sephadex. When separated from the positively charged toxic moiety, the net charge of the antigen is reduced as shown by immunoelectrophoresis. On primary fractionation, the antigen may be associated with a minor antigenic component of the negatively charged complex containing a major antigen eliciting vibriocidal antibody formation, but antisera to the toxin antigen preparations, either in this form or freed of antigenic contamination by recycling, do not contain vibriocidal antibody. It is suggested that this antigen be designated the T (toxin) antigen, and the antigen producing vibriocidal antibody the V antigen. These two antigens would appear to represent the major antigenic specificities associated with the antitoxic and antibacterial elements of the immune response to infection.     

Developing strategies to enhance and focus humoral immune responses using filamentous phage as a model antigen

Filamentous bacteriophage are commonly used as immunogenic carriers for peptides and proteins displayed on the phage surface. Previously, we showed that immunization with phage to which peptides had been chemically conjugated can elicit a focused anti-peptide antibody response compared with traditional carrier molecules bearing the same peptide, perhaps due to the low surface complexity of the phage. The regularity of its surface also gives the phage other advantages as a carrier, including immunological simplicity and thousands of well-defined sites for chemical conjugation. More recently, we showed that focusing of antibody responses against 'target' peptides was enhanced when the phage's molecular surface was simplified by removal of immunodominant B-cell epitopes present on the minor coat protein, pIII. The pIII-truncated variant elicits an antibody response that is largely restricted to the exposed N-terminus of the major coat protein, pVIII, and to phage-associated bacterial lipopolysaccharide, and a significant fraction of this response cross-reacts with a 12-residue peptide covering the surface-exposed region of pVIII. This allows one to track antibody responses against the phage (and any associated haptens) as they develop over time, and characterize them using a combination of serological, flow cytometric, cellular and immunogenetic assays. The filamentous phage thus provides an excellent model system for studying various aspects of the antibody response, all with the goal of targeting antibody production against weakly immunogenic peptides, proteins and carbohydrates.     

Detergent treatment of Dictyostelium discoideum cells allows examination of internal cell type-specific antigens by flow cytometry

Monoclonal antibodies are used extensively in flow cytometry to identify subpopulations of cells differing in surface antigens. Conventional studies on living cells do not allow analysis of internal antigens, because antibody molecules do not pass through an intact plasma membrane. It is important for developmental studies on Dictyostelium discoideum that not only surface but also internal antigens be analysed. Here techniques are reported that make possible such studies by permeabilising cells with mild detergent treatments using digitonin. Flow cytometer profiles of unfixed cells show that antigens recognised by two monoclonal antibodies, MUD102 and MUD3, are found inside subpopulations of cells in the D. discoideum slug. Double-labelling experiments were carried out to demonstrate that the antigens recognised by these antibodies are present inside prespore but not prestalk cells. The detergent treatment leads to loss of forward-angle light scatter, but 90 degrees light scatter of cells is not greatly affected. While fixed cells sometimes gave satisfactory results, internal labelling did not reliably demonstrate the two subpopulations observed with unfixed cells.     

Antigen-antibody interaction. Synthetic peptides define linear antigenic determinants recognized by monoclonal antibodies directed to the cytoplasmic carboxyl terminus of rhodopsin

The specificities of four monoclonal antibodies rho 1D4, 1C5, 3A6, and 3D6 prepared by immunization of rod outer segments containing rhodopsin have been defined using synthetic peptides. All of these antibodies interact within the 18 residues at the COOH terminus of rhodopsin and recognize linear antigenic determinants of 4-11 residues. Twenty-seven synthetic peptide analogs of varying lengths of native sequence or containing single amino acid substitutions at each position of the COOH-terminal 18 residues have provided some insight into the mechanism of antigen-antibody binding. Our results clearly demonstrate that antibodies can be highly specific at key positions as shown by the loss of binding on single amino acid substitutions in the binding site. In contrast single amino acid substitutions at other positions in the binding site only affect affinity for some antibodies. Ionic interactions can dominate immunogenic determinants. Immunogenic determinants are not restricted to highly charged hydrophilic regions on the surface of a protein and may be dominated by hydrophobic interactions. Although certain side chains can dominate the interaction of the antigen with antibody, our results are in agreement with the interpretation that the free energies of all the contact points are additive and a certain free energy must be present to achieve binding. Antibodies with different specificities directed to the same region of the protein antigen can be produced in an immune response. Peptide antigens representing regions of a protein antigen bind best to the anti-protein antibody when the sequence is shortened to contain only those residues binding to the specificity site in the antibody. Cross-reactivity between protein antigens can be explained by conservation of the critical residues in the combining site.     

FcRn overexpression in mice results in potent humoral response against weakly immunogenic antigen

The neonatal Fc receptor (FcRn) regulates IgG and albumin homeostasis, mediates maternal IgG transport, is active in phagocytosis and delivers antigen for presentation. We have previously shown that transgenic (tg) mice that have been created to overexpress bovine FcRn (bFcRn) demonstrate increased half-life of mouse IgG, significantly increased antigen-specific IgG in serum and augmented expansion of antigen-specific B cells and plasma cells after immunization. One of the interesting questions surrounding this enhanced immune response is whether these tg mice could effectively induce immune response to weakly immunogenic antigens. To address this question, we immunized these bFcRn tg mice with a conserved hemagglutinin subunit 2 (HA2)-based synthetic peptide that was recently found to be effectively targeted by neutralizing antibodies. Using an ELISA system, we found that, whereas wild-type mice showed a weak immune response and developed only a de minimis amount of antibody against the epitope, FcRn overexpressing animals mounted a robust reaction expressed in specific antibody titers on day 28 that continued to rise through day 50. Consistent with our previous data, the enhanced immune response resulting from the FcRn overexpression was also associated with a substantial increase in the number of spleen derived B cells, dendritic cells, granulocytes and plasma cells. Based on this evidence, we propose that tg mice that overexpress bFcRn offer major advantages in monoclonal antibody production because the tg mice would allow the generation of antibodies (hybridomas) to weakly immunogenic antigens that otherwise would be difficult or even impossible to make.Key words: neonatal Fc receptor (FcRn), transgenic mouse, immunogenicity, monoclonal antibody, influenza     

The 'co-delivery' approach to liposomal vaccines: application to the development of influenza-A and hepatitis-B vaccine candidates

DNA vaccination with mammalian-expressible plasmid DNA encoding protein antigens is known to be an effective means to elicit cell-mediated immunity, sometimes in the absence of a significant antibody response. This may be contrasted with protein vaccination, which gives rise to antibody responses with little evidence of cell-mediated immunity. This has led to considerable interest in DNA vaccination as a means to elicit cell-mediated immune responses against conserved viral antigens or intracellular cancer antigens, for the purpose of therapeutic vaccination. However, almost all current vaccines are used prophylactically and work by producing antibodies rather than cell mediated immune responses. In the present study we have therefore explored the combination of DNA and protein forms of an antigen using two exemplary prophylactic vaccine antigens, namely inactivated influenza virion and hepatitis-B surface antigen. We studied the effects of various combinations of DNA and protein on the antibody response. Co-administration of soluble forms of DNA and protein representations of the same antigen gave rise to the same level of antibody response as if protein were administered alone. In contrast, we found that when these antigens are entrapped in the same liposomal compartment, that there was a strong synergistic effect on the immune response, which was much greater than when either antigen was administered alone, or in various other modes of combination (e.g. co-administration as free entities, also pooled liposomal formulations where the two materials were contained in separate liposomal vehicles in the same suspension). The synergistic effect of liposomally co-entrapped DNA and protein exceeded, markedly, the well known adjuvant effects of plasmid DNA and liposomes. We have termed this new approach to vaccination 'co-delivery' and suggest that it may derive from the simultaneous presentation of antigen via MHC class-I (DNA) and MHC class-II (protein) pathways to CD8+ and CD4+ cells at the same antigen presenting cell--a mode of presentation that would commonly occur with live viral pathogens. We conclude that co-delivery is a very effective means to generate protective antibody responses against viral pathogens.     

Immunogenicity and epitope mapping of foreign sequences via genetically engineered filamentous phage

Repeat regions of the circumsporozoite protein gene of Plasmodium falciparum were cloned into the pIII gene of a filamentous phage. These genetically engineered filamentous phage display the recombinant proteins on their surface. We demonstrate that they are both antigenic and immunogenic in rabbits. The recombinant phage were shown to be useful as a source of antigen for this scarce malaria protein, for producing carrier-hapten conjugates for obtaining immunological reagents in rabbits, and for B epitope mapping. In addition, in mice the antibody response to the cloned antigens seems to be controlled by immune response genes. Therefore this system also has the potential for use in helper T cell epitope mapping using inbred mouse strains. This advantage will be of use in vaccine development.     

FcRn overexpression in mice results in potent humoral response against weakly immunogenic antigen

The neonatal Fc receptor (FcRn) regulates IgG and albumin homeostasis, mediates maternal IgG transport, is active in phagocytosis and delivers antigen for presentation. We have previously shown that transgenic (tg) mice that have been created to overexpress bovine FcRn (bFcRn) demonstrate increased half-life of mouse IgG, significantly increased antigen-specific IgG in serum and augmented expansion of antigen-specific B cells and plasma cells after immunization. One of the interesting questions surrounding this enhanced immune response is whether these tg mice could effectively induce immune response to weakly immunogenic antigens. To address this question, we immunized these bFcRn tg mice with a conserved hemagglutinin subunit 2 (HA2)-based synthetic peptide that was recently found to be effectively targeted by neutralizing antibodies. Using an ELISA system, we found that, whereas wild-type mice showed a weak immune response and developed only a de minimis amount of antibody against the epitope, FcRn over-expressing animals mounted a robust reaction expressed in specific antibody titers on day 28 that continued to rise through day 50. Consistent with our previous data, the enhanced immune response resulting from the FcRn overexpression was also associated with a substantial increase in the number of spleen derived B cells, dendritic cells, granulocytes and plasma cells. Based on this evidence, we propose that tg mice that overexpress bFcRn offer major advantages in monoclonal antibody production because the tg mice would allow the generation of antibodies (hybridomas) to weakly immunogenic antigens that otherwise would be difficult or even impossible to make.     

The ‘Co-Delivery’ Approach to Liposomal Vaccines: Application to the Development of influenza-A and hepatitis-B Vaccine Candidates

DNA vaccination with mammalian-expressible plasmid DNA encoding protein antigens is known to be an effective means to elicit cell-mediated immunity, sometimes in the absence of a significant antibody response. This may be contrasted with protein vaccination, which gives rise to antibody responses with little evidence of cell-mediated immunity. This has led to considerable interest in DNA vaccination as a means to elicit cell-mediated immune responses against conserved viral antigens or intracellular cancer antigens, for the purpose of therapeutic vaccination. However, almost all current vaccines are used prophylactically and work by producing antibodies rather than cell mediated immune responses. In the present study we have therefore explored the combination of DNA and protein forms of an antigen using two exemplary prophylactic vaccine antigens, namely inactivated influenza virion and hepatitis-B surface antigen. We studied the effects of various combinations of DNA and protein on the antibody response. Co-administration of soluble forms of DNA and protein representations of the same antigen gave rise to the same level of antibody response as if protein were administered alone. In contrast, we found that when these antigens are entrapped in the same liposomal compartment, that there was a strong synergistic effect on the immune response, which was much greater than when either antigen was administered alone, or in various other modes of combination (e.g. co-administration as free entities, also pooled liposomal formulations where the two materials were contained in separate liposomal vehicles in the same suspension). The synergistic effect of liposomally co-entrapped DNA and protein exceeded, markedly, the well known adjuvant effects of plasmid DNA and liposomes. We have termed this new approach to vaccination ‘co-delivery’ and suggest that it may derive from the simultaneous presentation of antigen via MHC class-I (DNA) and MHC class-II (protein) pathways to CD8+ and CD4+ cells at the same antigen presenting cell – a mode of presentation that would commonly occur with live viral pathogens. We conclude that co-delivery is a very effective means to generate protective antibody responses against viral pathogens.     

Electrophoretic and Western blot analyses of the lipopolysaccharide and glycocalyx of Flavobacterium psychrophilum

Flavobacterium psychrophilum is the aetiological agent of bacterial coldwater disease (CWD) and rainbow trout fry syndrome (RTFS) and it has emerged as one of the most significant bacterial pathogens in salmonid aquaculture worldwide. Previous studies have suggested that the O-polysaccharide (O-PS) component of the lipopolysaccharide (LPS) of F. psychrophilum is highly immunogenic and may be involved in eliciting a protective immune response in rainbow trout (Oncorhynchus mykiss Walbaum). In the present study, SDS-PAGE and Western blotting techniques were used to analyse the carbohydrate antigens of F. psychrophilum. Our analysis identified two distinct carbohydrate-banding patterns. One banding pattern corresponds with LPS, and we hypothesise that the other carbohydrate-banding pattern is that of the loosely associated glycocalyx of F. psychrophilum. Electron microscopy of F. psychrophilum cells immunogold labelled with a monoclonal antibody specific for this banding pattern supports this hypothesis as the outermost layer of the bacterium was heavily labelled. This is a significant finding because the immunogenic antigens that have been referred to as the O-PS of LPS, and implicated as potential vaccine candidate antigens, appear to be components of the glycocalyx of F. psychrophilum. This research suggests that the glycocalyx of F. psychrophilum may be an important antigen to consider for the development of a vaccine to control CWD and RTFS.     

Difference in antibody production to hererologus erythrocytes in conventional, specific-pathogen-free (SPF), germfree and antigen-free mice.

The expression of antibody-producing capacities against hamster erythrocytes (HRBC), known to be weakly immunogenic in mice, was compared among conventional, SPF, germfree and antigen-free mice. ICR strain germfree and antigen-free mice showed antibody production to HRBC comparable to that in conventional or specific-pathogen-free (SPF) mice. In the NC strain, some of the conventional mice produced low titers of antibody after a single injection of HRBC, but none of the germfree mice showed such a transient antibody production. In the ICR-KIG strain, which was selected from the colony-bred ICR strain, antibodies with high titers were produced after a single injection of HRBC under both conventional and germfree conditions. The onset of conversion from 2-mercaptoethanol (2-ME) sensitive to 2-ME resistant antibody after a single injection of HRBC was not delayed in the germfree mice when compared with the conventional or SPF mice. Antibody production to sheep erythrocytes (SRBC), known to be highly immunogenic in mice, was not influenced by exogeneous stimulation from microorganisms or diet. No differences in antibody production to SRBC were detected irrespective of the maintenance conditions of the mice. Stimulation with microorganisms or diet may not be required as essential elements for the maturation of antibody-producing capacities, but such a stimulation appears to modify the antibody response. The modifying effect was more prominent in the antibody response against weakly immunogenic antigens than against highly immunogenic ones.     

Protein Microarray Analysis of Antibody Responses to Plasmodium falciparum in Western Kenyan Highland Sites with Differing Transmission Levels

Malaria represents a major public health problem in Africa. In the East African highlands, the high-altitude areas were previously considered too cold to support vector population and parasite transmission, rendering the region particularly prone to epidemic malaria due to the lack of protective immunity of the population. Since the 1980’s, frequent malaria epidemics have been reported and these successive outbreaks may have generated some immunity against Plasmodium falciparum amongst the highland residents. Serological studies reveal indirect evidence of human exposure to the parasite, and can reliably assess prevalence of exposure and transmission intensity in an endemic area. However, the vast majority of serological studies of malaria have been, hereto, limited to a small number of the parasite’s antigens. We surveyed and compared the antibody response profiles of age-stratified sera from residents of two endemic areas in the western Kenyan highlands with differing malaria transmission intensities, during two distinct seasons, against 854 polypeptides of P. falciparum using high-throughput proteomic microarray technology. We identified 107 proteins as serum antibody targets, which were then characterized for their gene ontology biological process and cellular component of the parasite, and showed significant enrichment for categories related to immune evasion, pathogenesis and expression on the host’s cell and parasite’s surface. Additionally, we calculated age-fitted annual seroconversion rates for the immunogenic proteins, and contrasted the age-dependent antibody acquisition for those antigens between the two sampling sites. We observed highly immunogenic antigens that produce stable antibody responses from early age in both sites, as well as less immunogenic proteins that require repeated exposure for stable responses to develop and produce different seroconversion rates between sites. We propose that a combination of highly and less immunogenic proteins could be used in serological surveys to detect differences in malaria transmission levels, distinguishing sites of unstable and stable transmission.