Rationally designed strings of promiscuous CD4(+) T cell epitopes provide help to Haemophilus influenzae type b oligosaccharide: a model for new conjugate vaccines.

The age-related and T cell-independent immunological properties of most capsular polysaccharides limit their use as vaccines, especially in children under 2 years of age. To overcome these limitations, polysaccharide antigens have been successfully conjugated to a variety of carrier proteins, such as diphtheria toxoid or tetanus toxoid (TT) and the diphtheria mutant (CRM197) to produce very successful glycoconjugate vaccines. The increasing demand for new conjugate vaccines requires the availability of additional carriers providing high and long-lasting T helper cell immunity. Here we describe the design and construction of three recombinant carrier proteins (N6, N10, N19) constituted by strings of 6, 10 or 19 human CD4(+) T cell epitopes from various pathogen-derived antigens, including TT and proteins from Plasmodium falciparum, influenza virus and hepatitis B virus. Each of these epitopes is defined as universal in that it binds to many human MHC class II molecules. When conjugated to Haemophilus influenzae type b (Hib) oligosaccharide, these carriers elicit a potent anti-Hib antibody response in mice. In the case of the N19-Hib conjugate, this response is at least as good as that observed with CRM197-Hib, a conjugate vaccine currently used for mass immunization. We also show that some of the universal epitopes constituting the recombinant carriers are specifically recognized by two human in vitro systems, suggesting that T cell memory is provided by the selected epitopes. The data indicate that rationally designed recombinant polyepitope proteins represent excellent candidates for the development and clinical testing of new conjugate vaccines.

Cholera toxin induces maturation of human dendritic cells and licences them for Th2 priming.

Cholera toxin (CT) is a potent mucosal adjuvant that amplifies B and T cell responses to mucosally co-administered antigens, stimulating predominant Th2-type responses. However, little is known about the mechanism of adjuvanticity of CT and on the influence this toxin may have on Th2 cell development during the priming of an immune response. We analyzed the effect of CT on dendritic cells (DC), which are responsible for the priming of immune responses at the systemic as well as at the mucosal level. We found that CT induces phenotypic and functional maturation of blood monocyte-derived DC. Indeed, CT-treated DC up-regulate expression of HLA-DR molecules, B7. 1 and B7.2 co-stimulatory molecules, and are able to prime naive CD4(+)CD45RA(+) T cells in vitro, driving their polarization towards the Th2 phenotype. Furthermore, CT-matured DC express functional chemokine receptors CCR7 and CXCR4 which may render them responsive to migratory stimuli towards secondary lymphoid organs. Interestingly, the maturation program induced by CT is unique since CT does not induce but rather inhibits cytokine (IL-12p70 and TNF-alpha) and chemokine (RANTES, MIP-1alpha and MIP-1beta) secretion by lipopolysaccharide- or CD40 ligand-activated DC. Our results help to elucidate the mechanism of action of CT as an adjuvant and highlight a new stimulus of bacterial origin that promotes maturation of DC.

The comparison of the effect of LTR72 and MF59 adjuvants on mouse humoral response to intranasal immunisation with human papillomavirus type 6b (HPV-6b) virus-like particles.

Infections with genital human papillomaviruses (HPV) are likely to be neutralised more efficiently if a mucosal immune response can be elicited at the viral entry site. Local IgA antibodies are highly induced when antigens are co-administered with mucosal adjuvants, such as cholera toxin (CT) and Escherichia coli heat labile enterotoxin (LT) which, however, are not expected to have wide application because of their pronounced toxicity. We have immunised mice intranasally with HPV-6b virus-like particles (VLPs) and a genetically modified LT-derived molecule with only residual toxicity, LTR72, and compared the humoral responses with those obtained following systemic immunisation with VLPs and the MF59 adjuvant. Titration of anti-HPV antibodies in sera and vaginal secretions established that LTR72 was able to elicit higher serum and mucosal IgA titers, in addition to IgG serum levels, comparable to those obtained by parenteral immunisation. These results confirm the potential of toxin-derived adjuvants and extend their use in combination with HPV antigens.

Zonula occludens toxin is a powerful mucosal adjuvant for intranasally delivered antigens.

Zonula occludens toxin (Zot) is produced by toxigenic strains of Vibrio cholerae and has the ability to reversibly alter intestinal epithelial tight junctions, allowing the passage of macromolecules through the mucosal barrier. In the present study, we investigated whether Zot could be exploited to deliver soluble antigens through the nasal mucosa for the induction of antigen-specific systemic and mucosal immune responses. Intranasal immunization of mice with ovalbumin (Ova) and recombinant Zot, either fused to the maltose-binding protein (MBP-Zot) or with a hexahistidine tag (His-Zot), induced anti-Ova serum immunoglobulin G (IgG) titers that were approximately 40-fold higher than those induced by immunization with antigen alone. Interestingly, Zot also stimulated high anti-Ova IgA titers in serum, as well as in vaginal and intestinal secretions. A comparison with Escherichia coli heat-labile enterotoxin (LT) revealed that the adjuvant activity of Zot was only sevenfold lower than that of LT. Moreover, Zot and LT induced similar patterns of Ova-specific IgG subclasses. The subtypes IgG1, IgG2a, and IgG2b were all stimulated, with a predominance of IgG1 and IgG2b. In conclusion, our results highlight Zot as a novel potent mucosal adjuvant of microbial origin.

NMR studies on the structure/function correlations of T-cell-epitope analogs from pertussis toxin.

A synthetic tridecapeptide, corresponding to the 30-42 fragment of the S1 subunit of pertussis toxin, has been structurally characterised by using NMR spectroscopy. The molecule corresponds to a T-cell epitope of the bacterial toxin which has been extensively analysed with the alanine scanning approach to check the relevance of each residue for the biological activity of the peptide. Five of these Ala-substituted analogs have also been spectroscopically studied. In the experimental conditions used, different extents of helicity were found for the six peptides in a way which cannot be related to their capabilities of of binding to major histocompatibility complex (MHC) class II and inducing T-cell proliferation. Backbone flexibility around helical transient conformations seems to constitute the structural intermediate step between the structure of the corresponding sequence within the parental protein and in the MHC class II complex. A model of the latter complex, which accounts for the different biological activities of the analogs, is proposed.

Adjuvant effect of non-toxic mutants of E. coli heat-labile enterotoxin following intranasal, oral and intravaginal immunization.

Cholera toxin and Escherichia coli heat-labile enterotoxin (LT) are known to be very effective mucosal adjuvants, but their toxicity limits their use in humans. We genetically detoxified LT by substituting single residues in the active site of the enzymatic A subunit and obtained mutant molecules that retain mucosal adjuvant activity but are devoid of toxicity. These mutant LT molecules induce mucosal and systemic responses to antigens delivered intranasally, orally and intravaginally in mice. Furthermore, mucosal immunization with these molecules confers protection against systemic challenge with tetanus toxin (TT) and mucosal challenge with Helicobacter pylori.

Therapeutic intragastric vaccination against Helicobacter pylori in mice eradicates an otherwise chronic infection and confers protection against reinfection.

Chronic infection of the gastroduodenal mucosae by the gram-negative spiral bacterium Helicobacter pylori is responsible for chronic active gastritis, peptic ulcers, and gastric cancers such as adenocarcinoma and low-grade gastric B-cell lymphoma. The success of eradication by antibiotic therapy is being rapidly hampered by the increasing occurrence of antibiotic-resistant strains. An attractive alternative approach to combat this infection is represented by the therapeutic use of vaccines. In the present work, we have exploited the mouse model of persistent infection by mouse-adapted H. pylori strains that we have developed to assess the feasibility of the therapeutic use of vaccines against infection. We report that an otherwise chronic H. pylori infection in mice can be successfully eradicated by intragastric vaccination with H. pylori antigens such as recombinant VacA and CagA, which were administered together with a genetically detoxified mutant of the heat-labile enterotoxin of Escherichia coli (referred to as LTK63), in which the serine in position 63 was replaced by a lysine. Moreover, we show that therapeutic vaccination confers efficacious protection against reinfection. These results represent strong evidence of the feasibility of therapeutic use of VacA- or CagA-based vaccine formulations against H. pylori infection in an animal model and give substantial preclinical support to the application of this kind of approach in human clinical trials.

Acellular pertussis vaccines containing genetically detoxified pertussis toxin induce long-lasting humoral and cellular responses in adults.

New generation pertussis vaccines, containing only purified Bordetella pertussis antigens, have been proven safe, immunogenic and efficacious. They have, however, raised new questions regarding the mechanism of protection from whooping cough and the duration of the immune response following vaccination. In addition to the antibody (Ab) titer, the level of pertussis toxin (PT) neutralizing antibodies may be very important in protection and the role of cell-ediated immunity needs to be defined. We have previously reported the safety and immunogenicity results of two phase I trials in adult volunteers with two acellular pertussis vaccines containing genetically detoxified PT alone or in combination with filamentous hemagglutinin (FHA) and 69K protein. In this work, we present the results of a long term follow-up study of the immune response in the same vaccinees. We evaluated the Ab response, the PT neutralizing titer and the peripheral blood T cell response up to 4 years following vaccination. Our results show that in adults the level of antibodies to PT, FHA and 69K and the PT neutralizing titers slightly decline between 2.5 and 12 months after the last vaccine dose, but they remain high in the following 2-4 years, showing levels 10-100 times higher than pre-vaccination values. The T cell responses were more heterogeneous among vaccinees but they did not show any significant decline throughout the period monitored.

Induction of CD4+ T cell depletion in mice doubly transgenic for HIV gp120 and human CD4.

It has been suggested that loss of uninfected T cells in HIV infection occurs because of lymphocyte activation resulting in cell death by apoptosis. To address the question of whether cross-linking of CD4/HIV gp120 complexes by antibodies were sufficient to induce T cell depletion in vivo, we developed an animal model of continuous interaction between human CD4 (hCD4), gp120 and anti-gp120 antibodies in the absence of other viral factors. Double-transgenic mice have been generated in which T cells express on their membrane hCD4 and secrete HIV gp120. Although these mice have hCD4/gp120 complexes present on the surface of T cells, they do not show gross immunological abnormalities, and they are able to produce anti-gp120 antibodies following immunization with denaturated gp120. However, double-transgenic mice with antibodies to gp120, when immunized with tetanus toxoid, mount an IgG response that is significantly lower than that of double-transgenic mice without antibodies to gp120. Furthermore, the presence of anti-gp120 antibodies leads to CD4+ T cell depletion and immunodeficiency in the absence of HIV infection. Thus, the antibody response to gp120 can lead to CD4+ T cell attrition in vivo.

Induction of antigen-specific antibodies in vaginal secretions by using a nontoxic mutant of heat-labile enterotoxin as a mucosal adjuvant.

Immunization of the female reproductive tract is important for protection against sexually transmitted diseases and other pathogens of the reproductive tract. However, intravaginal immunization with soluble antigens generally does not induce high levels of secretory immunoglobulin A (IgA). We recently developed safe mucosal adjuvants by genetically detoxifying Escherichia coli heat-labile enterotoxin, a molecule with a strong mucosal adjuvant activity, and here we describe the use of the nontoxic mutant LTK63 to induce a response in the mouse vagina against ovalbumin (Ova). We compared intravaginal and intranasal routes of immunization for induction of systemic and vaginal responses against LTK63 and Ova. We found that LTK63 is a potent mucosal immunogen when given by either the intravaginal or intranasal route. It induces a strong systemic antibody response and IgG and long-lasting IgA in the vagina. The appearance of vaginal IgA is delayed in the intranasally immunized mice, but the levels of vaginal anti-LTK63 IgA after repeated immunizations are higher in the intranasally immunized mice than in the intravaginally immunized mice. LTK63 also acts as a mucosal adjuvant, inducing a serum response against Ova, when given by both the intravaginal and intranasal routes. However, vaginal IgA against Ova is stimulated more efficiently when LTK63 and antigen are given intranasally. In conclusion, our results demonstrate that LTK63 can be used as a mucosal adjuvant to induce antigen-specific antibodies in vaginal secretions and show that the intranasal route of immunization is the most effective for this purpose.

The reaction of bacterial toxins with formaldehyde and its use for antigen stabilization.

Since the discovery of diphtheria toxin inactivation in the early 1920s, formaldehyde has been used to inactivate bacterial toxins and viruses used as vaccine antigens. More recently, formaldehyde was used to inactivate pertussis toxin (PT), a component of the newly developed diphtheria-tetanus-acellular pertussis (DTaP) vaccine. This application however illustrated the complexity of the reaction. To eliminate the need for inactivation, the mutant PT-9K/129G was developed. This toxin analogue is irreversibly devoid of toxicity and is a more immunogenic antigen than chemically detoxified PT. Native antigens however proved less stable than detoxified antigens upon storage or heating. We investigated the use of low concentrations of formaldehyde as a stabilizing agent for PT-9K/129G. Under the conditions selected, its antigenic characteristics were retained. Enhanced immunogenicity compared to detoxified preparations was demonstrated in clinical trials in infants where DTaP vaccines containing formalin-stabilized PT-9K/129G were compared to other DTaP vaccines containing detoxified wild type PT. Additional studies with filamentous haemagglutinin (FHA), another component of acellular pertussis vaccines, showed how high formaldehyde concentrations could depress the presentation of epitopes to T-cells by limiting the antigen processing. In conclusion, mild formaldehyde treatment can be applied to stabilize vaccine antigens while retaining optimum antigenic activity.

Helicobacter pylori-specific CD4+ T-cell clones from peripheral blood and gastric biopsies.

Colonization of human gastric mucosa with cytotoxic strains of the bacterium Helicobacter pylori is associated with peptic ulcer and with chronic gastritis. Since little is known about the T-cell response to H. pylori, we investigated the CD4+ T-cell response both in peripheral blood mononuclear cells (PBMCs) and at the site of infection. First, we compared the bulk PBMC proliferative response to the bacterium in individuals with and without symptoms of gastroduodenal disease. We found that the PBMCs from virtually all individuals proliferate in response to heat-inactivated bacteria. Second, we cloned H. pylori-specific CD4+ T lymphocytes from the PBMCs of three patients and from both the gastric mucosa and PBMCs of a fourth patient. We have found that CD4+ T-cell clones specific for H. pylori from peripheral blood samples and gastric mucosae of infected patients are major histocompatibility complex class II restricted and discriminate between several cytotoxic and noncytotoxic bacterial strains. Moreover, they are polyclonal in terms of T-cell receptor usage and major histocompatibility complex restriction. Our results demonstrate that the T-cell response to the whole bacterium in PBMCs does not correlate with antibody response, infection, or disease. However, H. pylori-specific CD4+ T cells are detectable, at the clonal level, in both the periphery and gastric mucosa of infected patients. Localization of these cells at the site of disease suggests they are effectors of the immune response to the bacteria.

Acellular pertussis vaccine composed of genetically inactivated pertussis toxin.

Whooping cough, an acute respiratory disease affecting over sixty million infants, can be prevented by vaccination. The vaccine currently used, composed of killed bacterial cells, however, has been associated with many side effects. An improved vaccine against the disease should contain pertussis toxin (PT), a major virulent factor of Bordetella pertussis (B. pertussis). In order to be included in the vaccine, PT needs to be detoxified and the chemical methods used so far are not completely satisfactory, since they give a product with reduced immunogenicity and possible residual toxicity. To avoid this problem, we have used recombinant DNA technologies to clone the PT gene, express it in bacteria, map the B and T cell epitopes of the molecule and identify the amino acids that are important for the enzymatic activity and toxicity. Based on this information, the gene coding for PT was mutated to produce an inactive protein. This genetically modified PT was non toxic, highly immunogenic and able to protect mice from intracerebral challenge with virulent B. pertussis. The mutant was included as a main component of an acellular pertussis vaccine which has been shown in numerous clinical trials to be more safe and immunogenic than the old cellular vaccine.

Formaldehyde treatment of proteins can constrain presentation to T cells by limiting antigen processing.

Proteins to be used as vaccines are frequently treated with formaldehyde, although little is known about the effects of this treatment on protein antigenicity. To investigate the effect of formaldehyde treatment on antigen recognition by T cells, we compared the in vitro T-cell response to proteins that have been formaldehyde treated with the response to untreated proteins. We found that peripheral blood mononuclear cells from individuals vaccinated with three formaldehyde-treated proteins (pertussis toxin, filamentous hemagglutinin, pertactin) of Bordetella pertussis showed little or no response to the formaldehyde-treated proteins but proliferated very well in response to the corresponding untreated protein. These findings were further confirmed with CD4+ T-cell clones specific for defined epitopes of the bacterial proteins. We found that some epitopes are presented poorly or not at all when formaldehyde-treated proteins are used, whereas other epitopes are equally presented to T-cell clones when either formaldehyde-treated or untreated antigens are used. However, T-cell recognition could be restored by either antigen degradation before formaldehyde treatment or heat denaturation after such treatment. Parallel digestion with trypsin of both formaldehyde-treated and untreated proteins showed that fragments generated from the two forms of the same antigen were different in size. These results demonstrate that formaldehyde treatment can constrain antigen presentation to T cells and that this may be due to an altered proteolytic processing of formaldehyde-treated proteins.

Conformational study of a short Pertussis toxin T cell epitope incorporated in a multiple antigen peptide template by CD and two-dimensional NMR. Analysis of the structural effects on the activity of synthetic immunogens.

The immunogenic efficacy of multiple antigen peptides, MAPs, i.e. branched molecules in which multiple copies of a given immunogenic peptide are attached on a scaffold of lysine residues via both alpha and epsilon linkages, has been repeatedly demonstrated, but little is known about the structural arrangement of these peptide constructs. A conformational characterization was therefore performed for a known T cell epitope of the S1 subunit of Pertussis toxin, whose sequence is predicted to form alpha-helix. The peptide DNVLDHLTGR, its N-acetylated and C-amidated analogue and a tetrabranched MAP based on the N-acetylated peptide were prepared and studied by CD and two-dimensional 1H-NMR. No evidence of helical structure was obtained in water for the isolated peptides. In contrast, in triflouroethanol, the isolated epitopes fold into a helical structure spanning the segment Val3-Thr8 in the uncapped molecule and encompassing also the N-terminal region in the capped analogue. The mobile C-terminal region tends to adopt a distorted turn arrangement in both peptides due to the folding of Arg10 guanidinium over the backbone. No distortion of the helix structure was observed for the single-copy epitope in the four-branched MAP molecule in trifluoroethanol: each peptide chain is equivalent within the MAP and shows an even more regular helical pattern than the isolated end-blocked sequence. A slight difference was located at the junction with the lysine scaffold: the peptide bond to epsilon NH was found in a much more extended conformation than the corresponding link to alpha NH. These structural results correlate with in vitro T cell stimulatory activity of the three compounds examined and provide arguments supporting the previous suggestion that MAP tetramers are unlikely to elicit an immune response specific for the synthetic template assembly, a feature necessary to retain the advantage of the polymeric epitope presentation.

Recombinant acellular pertussis vaccine--from the laboratory to the clinic: improving the quality of the immune response.

Vaccination is the most effective way to prevent infectious diseases. Recombinant DNA technologies have provided powerful new tools to develop vaccines that were previously impossible or difficult to make, and to improve the vaccines that were already available but had been developed using old technology. In the case of whooping cough, an effective vaccine (composed of killed bacterial cells) is available, but its use is controversial because of the many side effects that have been associated with it. An improved vaccine against this disease should contain pertussis toxin, a molecule that needs to be detoxified in order to be included in the vaccine. Classical methods of detoxification, such as formaldehyde treatment have been used to inactivate this toxin. We have used recombinant DNA technologies to clone the pertussis toxin gene, express it in bacteria, map the B and T cell epitopes of the molecule, and to identify the amino acids that are important for enzymatic activity and toxicity. Finally, we have used this information to mutate the gene in the chromosome of Bordetella pertussis in order to obtain a strain that produces a molecule that is already non-toxic. This genetically inactivated pertussis toxin was tested extensively in animal models and clinical trials and was found to induce an immune response that is superior in quality and quantity to that induced by the vaccines produced by conventional technologies.

Mutations in the third, but not the first or second, hypervariable regions of DR(beta 1*0101) eliminate DR1-restricted recognition of a pertussis toxin peptide.

We have examined the role of 12 polymorphic residues of the beta-chain of the HLA-DR1 class II molecule in T cell recognition of an epitope of pertussis toxin. Murine L cell transfectants expressing wild-type or mutant DR1 molecules (containing single amino acid substitutions in DR(beta 1*0101)) were used as APC in proliferation assays involving nine DR1-restricted T cell clones specific for peptide 30-42 of pertussis toxin. Four different patterns of recognition of the mutants were found among the pertussis-specific clones. Residues in the third hypervariable region (HVR) of DR(beta 1*0101) are critically important for all the T cell clones; amino acid substitutions at positions 70 and 74 abrogated recognition by all of the T cell clones, and substitutions at positions 67 and 71 eliminated recognition by most of the clones. In contrast, most single amino acid substitutions in the first and second HVR, predicted to be located in the floor of the peptide binding groove, had little or no effect on the proliferative responses of these clones. However, the involvement of beta-chain first and second HVR residues was demonstrated by the inability of transfectants expressing wild-type DR(beta 1*0404) (DR4Dw14) or DR(beta 1*1402) (DR6Dw16) to present peptide to these clones. These beta-chains have completely different first and second HVR compared with DR(alpha,beta 1*0101) although the third HVR are identical. These results illustrate the functional importance of third HVR residues of DR(beta 1*0101) and allow definition of the molecular interactions of the DR1 molecule with the 30-42 peptide.

Interaction of the pertussis toxin peptide containing residues 30-42 with DR1 and the T-cell receptors of 12 human T-cell clones.

The interaction of the immunodominant pertussis toxin peptide containing residues 30-42 (p30-42) with soluble DR1 molecules and the T-cell receptor (TCR) of 12 DR1-restricted human T-cell clones has been analyzed. Peptide analogues of p30-42 containing single alanine substitutions were used in DR1-binding and T-cell proliferation assays to identify the major histocompatibility complex and TCR contact residues. Each T-cell clone was found to recognize p30-42 with a different fine specificity. However, a common core comprising amino acids 33-39 was found to be important for stimulation of all T-cell clones. Within this core two residues, Leu33 and Leu36, interact with the DR1 molecule, whereas Asp34, His35, Thr37, and Arg39 are important for TCR recognition in most of the clones. Computer modeling of the structure of p30-42 showed that an alpha-helical conformation is compatible with the experimental data. The analysis of TCR rearrangement revealed that the peptide was recognized by T-cell clones expressing different variable region alpha (V alpha) and variable region beta (V beta) chains, although a preferential use of V alpha 8-V beta 13 and V alpha 11-V beta 18 combinations was found in clones from the same donor. Understanding the details of the interaction of antigenic peptides with the major histocompatibility complex and TCR molecules should provide the theoretical basis to design T-cell epitopes and obtain more immunogenic vaccines.

Antigen analog-major histocompatibility complexes act as antagonists of the T cell receptor.

A novel mechanism for inhibition of T cell responses is described. Using the recognition of the influenza hemagglutinin (HA) 307-319 peptide in the context of DR1 class II major histocompatibility complex molecules, we have found that nonstimulatory analogs of the HA peptide preferentially inhibit HA-specific T cells in inhibition of antigen presentation assays. This antigen-specific effect could be generalized to another DR1-restricted peptide, Tetanus toxoid 830-843. Direct binding and cellular experiments indicated that the mechanism responsible was distinct from competition for binding to DR1 molecules. Likewise, negative signaling and induction of T cell tolerance could also be excluded as effector mechanisms. Thus, the most likely mechanism for this effect is engagement of antigen-specific T cell receptors by DR1-peptide analog complexes, which results in antigen-specific competitive blocking of T cell responses by virtue of their capacity to compete with DR1-antigen complexes for binding to the T cell receptor.