Engineering of a polymeric bacterial protein as a scaffold for the multiple display of peptides.

Protein assemblies with a high degree of repetitiveness and organization are known to induce strong immune responses. For that reason they have been postulated for the design of subunit vaccines by means of protein engineering. The enzyme lumazine synthase from Brucella spp. (BLS) is highly immunogenic, presumably owing to its homodecameric arrangement and remarkable thermodynamic stability. Structural analysis has shown that it is possible to insert foreign peptides at the ten amino terminus of BLS without disrupting its general folding. These peptides would be displayed to the immune system in a highly symmetric three-dimensional array. In the present work, BLS has been used as a protein carrier of foreign peptides. We have established a modular system to produce chimeric proteins decorated with ten copies of a desired peptide as long as 27 residues and have shown that their folding and stability is similar to that of the wild-type protein. The knowledge about the mechanisms of dissociation and unfolding of BLS allowed the engineering of polyvalent chimeras displaying different predefined peptides on the same molecular scaffold. Moreover, the reassembly of mixtures of chimeras at different steps of the unfolding process was used to control the stoichiometry and spatial arrangement for the simultaneous display of different peptides on BLS. This strategy would be useful for vaccine development and other biomedical applications.

Nasal delivery of chitosan-DNA plasmid expressing epitopes of respiratory syncytial virus (RSV) induces protective CTL responses in BALB/c mice.

Respiratory syncytial virus (RSV), an important pathogen of the lower respiratory tract, is responsible for severe illness both in new born and young children and in elderly people. Due to complications associated with the use of the early developed vaccines, there is still a need for an effective vaccine against RSV. Most pathogens enter the body via mucosal surfaces and therefore vaccine delivery via routes such as the nasal, may well prove to be superior in inducing protective immune responses against respiratory viruses, since both local and systemic immunity can be induced by nasal immunisation. Previously we have shown that intradermal immunisation of a plasmid DNA encoding the CTL epitope from the M2 protein of RSV induced protective CTL responses. In the present study, the mucosal delivery of plasmid DNA formulated with chitosan has been investigated. Chitosan is a polysachharide consisting of copolymers of N-acetylglucosamine and glucosamine that is derived from chitin, a material found in the shells of crustacea. Intranasal immunisation with plasmid DNA formulated with chitosan induced peptide- and virus-specific CTL responses in BALB/c mice that were comparable to those induced via intradermal immunisation. Following RSV challenge of chitosan/DNA immunised mice, a significant reduction (P<0.001) in the virus load was observed in the lungs of immunised mice compared to that in the control group. These results indicate the potential of immunisation with chitosan-formulated epitope-based vaccines via the intranasal route.

Mimotopes of viral antigens and biologically important molecules as candidate vaccines and potential immunotherapeutics.

Antigen recognition by antibodies or ligand-receptor interactions involve small areas of the molecule named epitopes that are normally conformational in nature. The availability of combinatorial peptide libraries has provided a powerful tool for selecting novel sequences which mimic conformational epitopes (mimotopes) either structurally and/or immunologically. These mimotopes can be particularly useful in a number of situations, including: the development of vaccines against tumors, infectious diseases or allergic conditions; the design of molecules which can act as agonists or antagonists of various biologically-important molecules; and for the development of diagnostic assays. This article reviews the authors work on the application of combinatorial peptide libraries to identify mimotopes of protective B-cell epitopes from various pathogens, and the search for molecules able to block the biological activities of TNF-alpha, a cytokine which plays a key role in inflammation.

Nasal delivery of epitope based vaccines.

Essentially all of the currently available vaccines are based on the use of inactivated or live-attenuated pathogens. However, these vaccines have several shortcomings, such as difficulties of in vitro culturing, biohazard risks, as well as loss of efficacy due to the genetic variations seen in many viruses. These problems may potentially be solved by immunising with epitope-based vaccines consisting of rationally designed protective epitopes, appropriately presented and easy to deliver, which are capable of stimulating effective B-cell, T-cell and cytotoxic immune responses whilst avoiding potentially hazardous and undesirable effects. Furthermore, the use of a mixture of defined epitopes could lead to an effective broad range immune response which has the potential to overcome both strain specificity of the pathogen and the MHC restriction of the host. Epitope-based vaccines can be designed to involve the use of synthetic materials that can be available in unlimited quantities and posing no biohazard. Other approaches include the use of naked DNA or recombinant viruses or bacteria expressing the epitopes. An important objective in the development of such vaccines is that they should be effective when delivered via the mucosal route and effective in the presence of maternal antibodies. In this review, we present examples of the use of various epitope-based vaccine constructs, focussing particularly upon their intranasal delivery to the immune system.

Immune responses and protection induced by mucosal and systemic immunisation with recombinant measles nucleoprotein in a mouse model of measles virus-induced encephalitis.

In this study the immunogenicity of recombinant nucleoprotein (Np) administered intranasally or intraperitoneally, and its ability to support a systemic protective anti-virus antibody response was examined, in a mouse model of measles virus (MV)-induced encephalitis. Although both intranasal and intraperitoneal routes of immunisation resulted in priming Np- and MV-specific T-cell responses, the intraperitoneal route was shown to prime for a predominantly IgG2a serum anti-MV antibody response of high avidity, which confered complete protection following intracranial challenge with a neuroadapted strain of MV. On the other hand, intranasal priming resulted in a mixed IgG1, IgG2a serum anti-MV antibody response of low avidity, and only 43% of immunised mice survived following intracranial challenge with the neuroadapted strain of MV. These findings suggest that the route of immunisation in combination with an appropriate adjuvant could influence the induction of a quality antibody response with protective capacity.

The development of a mimotope-based synthetic peptide vaccine against respiratory syncytial virus.

Respiratory syncytial virus (RSV) is the most important cause of bronchiolitis and pneumonia in infants and young children worldwide and the development of a synthetic peptide epitope-based vaccine to induce virus-neutralising antibodies against RSV would seem to be a valid approach to the production of an effective vaccine against infection.A combinatorial solid-phase peptide library has been screened with a virus-neutralising, protective monoclonal antibody (MAb19) directed towards a conserved and conformationally-determined epitope of the Fusion (F) protein of the virus. Two of the sequences identified from the peptide library using MAb19 reacted specifically with the antibody and amino acid substitution experiments identified four sequences from one of the mimotopes which showed increased reactivity with MAb19. Immunisation of BALB/c mice with these mimotopes, presented as MAPs, resulted in the induction of anti-peptide antibodies that inhibited the binding of MAb19 to the virus and neutralised viral infection in vitro, with titres equivalent to those in sera from RSV-infected animals. Following RSV challenge of mimotope-immunised mice, a significant reduction in the titre of virus and a greatly reduced cell infiltration into the lungs of immunised mice compared to that in controls was observed. The induction of virus-specific cytotoxic T-lymphocyte responses as well as virus-specific antibodies are likely to be necessary in an effective vaccine. The incorporation of a peptide representing a CTL epitope from the M2 protein of the virus together with peptides inducing T-helper and anti-mimotope responses in a peptide cocktail vaccine resulted in a more effective clearance of the virus from immunised, challenged mice than peptide-induced humoral or cellular immunity alone.

Antipeptide antibody responses following intranasal immunization: effectiveness of mucosal adjuvants.

Toxicity is a major factor limiting the development and use of potent adjuvants for human mucosally delivered vaccines. Novel adjuvant formulations have recently become available, and in the present study two have been used for intranasal immunization with a synthetic peptide immunogen (MAP-M2). This peptide represents a multiple antigenic peptide containing multiple copies of a mimotope M2, a peptide mimic of a conformational epitope of the fusion protein of measles virus. MAP-M2 was administered intranasally to experimental animals together with synthetic oligodeoxynucleotides containing unmethylated CpG motifs with or without a mutant of wild-type enterotoxin of Escherichia coli (LTR72). The combination of the mutant toxin LTR72 and the CpG repeats, codelivered with a peptide immunogen, induced both local and systemic peptide- and pathogen-specific humoral and cellular immune responses comparable to those obtained after intranasal immunization with the wild-type toxin LT. In addition, this combination of adjuvants induced a predominantly immunoglobulin G2a antibody response. If both the LTR72 and CpG adjuvants are shown to be safe for use in humans, this particular combination would appear to have potential as an adjuvant for mucosally delivered vaccines in humans.

Protection against measles virus-induced encephalitis by anti-mimotope antibodies: the role of antibody affinity.

Synthetic peptides mimicking a conformational B-cell epitope (M2) of the measles virus fusion protein (MVF) were used for the immunization of BALB/c mice and the anti-peptide and anti-virus antibody titers induced were compared. Of the panel of tested peptides, a chimeric peptide consisting of two copies of a T-helper epitope (residues 288-302 of MVF) and one copy of the mimotope M2 (TTM2) and a multiple antigen peptide with eight copies of M2 (MAP-M2) induced the highest titers of anti-M2 and anti-MV antibodies. Furthermore, peptides TTM2 and MAP-M2 induced antibodies with highest affinity for the mimotope and highest avidity for measles virus. Immunization with the MAP-M2 construct induced high titers of high-affinity anti-M2 antibody despite the absence of a T-helper epitope, and lymphocyte proliferation data suggest that the addition of M2 to the MAP resulted in the generation of a structure capable of stimulating T-cell help. Sera with anti-M2 reactivity were pooled according to affinity values for binding to M2, and high- and low-affinity pools were tested for their ability to prevent MV-induced encephalitis in a mouse model. The high-affinity serum pool conferred protection in 100% of mice, whereas the lower affinity pool conferred protection to only 50% of animals. These results indicate the potential of mimotopes for use as synthetic peptide immunogens and highlight the importance of designing vaccines to induce antibodies of high affinity.

Sex-associated differences in the antibody-dependent cellular cytotoxicity antibody response to measles vaccines.

In some countries, excessive non-measles-related mortality has been observed among female recipients of high-titer measles vaccines. We determined if differences in the immune response to measles vaccines underlie the excessive female mortality by measuring the measles virus (MV)-specific antibody-dependent cellular cytotoxicity (ADCC) antibody response in 65 3-year-old Gambian children immunized with Edmonston-Zagreb medium-titer (EZ) or Schwarz standard vaccines during infancy. Among the 20 females and 22 males with undetectable anti-MV antibodies at the time of immunization, females had significantly lower ADCC than males (median cytotoxicities of 1/100 serum dilutions = 8.4 and 12%, respectively; P = 0.04). This sex-associated difference was present only among the six female and seven male recipients of EZ vaccine (median cytotoxicities = 5.1 and 19.0%, respectively; P = 0.02). There were no significant sex-associated differences in neutralizing antibody activity. Decreased ADCC antibody activity may contribute to the lower survival rate observed in females receiving high-titer measles vaccination.

CTL epitopes identified with a defective recombinant adenovirus expressing measles virus nucleoprotein and evaluation of their protective capacity in mice.

Cytotoxic T-lymphocyte (CTL) responses to measles virus (MV) play an important role in recovery from infection, with one of the major target proteins for CTL activity being the nucleoprotein (Np). In this report, a replication-deficient adenovirus-5 recombinant, expressing for MV Np (Rad68) was tested for in vivo priming of MV Np-specific CTL responses in BALB/c and CBA mice. In both strains of mice strong Np-specific CTL responses were induced and these responses were shown to be MHC class I restricted. Using overlapping 15mer peptides spanning residues 1-505 of MV Np a single epitope comprising residues 281-295 was identified in BALB/c mice whereas, in CBA mice two epitopes comprising residues 51-65 and 81-95, were identified. These epitopes were found to contain class I motifs for H-2L(d) and H-2K(k) MHC molecules, respectively. Immunization of BALB/c and CBA mice with the respective CTL epitopes resulted in the in vivo induction of peptide-and MV Np-specific CTL responses. In addition, the identified H-2K(k) restricted CTL epitopes conferred some protection against encephalitis induced following intracerebral challenge with a lethal dose of canine distemper virus (the Np of which shares 70% sequence homology with MV Np). These findings highlight the potential of using well-defined CTL epitopes to control virus infection.

Induction of cytotoxic T-cell responses following oral immunization with synthetic peptides encapsulated in PLG microparticles.

CTL responses play a critical role in clearing viral infections. We have investigated the potential of poly(lactide-co-glycolide) (PLG) microparticles as an oral delivery system for peptides representing CTL epitopes from measles virus nucleoprotein. Oral administration of CTL epitopes encapsulated in 50:50 PLG microparticles, resulted in vivo priming of splenic peptide-specific CTL responses. However, the observed CTL lysis was low and cofeeding of encapsulated peptide with cholera toxin as a mucosal adjuvant did not result in any significant enhancement of the observed CTL responses. The pronounced immunostimulatory effect of microparticles, combined with their excellent tissue compatibility and biodegradability makes them a valuable delivery system for synthetic peptide immunogens. However, further work is needed to improve their efficiency via the oral route.

Deconstructing the antigenic profile of a protective epitope from measles virus fusion protein using overlapping peptides.

Three different approaches of using overlapping peptides have been compared to analyse the fine specificity of the antibody response to a protective epitope from measles virus (MV) fusion protein, spanning residues 397-420. Anti-peptide antibodies raised in BALB/c, CBA and C57BL/6 mice were shown to react with the homologous peptide and the MV by ELISA. Results from indirect ELISA using 15mer peptides (overlapping by one residue) as solid phase antigens have shown that anti-peptide antibodies from CBA and C57BL/6 mice recognised the same B-cell epitope(s) located within the 398-414 region, whereas BALB/c mice predominantly recognised epitopes located within the 400-417 region. When the 15mer peptides were used as fluid phase antigens in an inhibition ELISA, peptide 405-419 was shown to be the most effective inhibitor in all three strains of mice. Analysis of serum samples by SPOTs ELISA has shown that the region 407-417 was predominantly recognised by BALB/c mice, whereas antibodies from C57BL/6 mice recognised the 408-420 region. No reactivity was observed with serum samples from CBA mice. Although the majority of the identified B-cell epitopes were shown to overlap by the three methods, the identified boundaries of these epitopes differed, suggesting that the size and the mode of peptide presentation affects their antigenicity.

Synergistic effect of immunization with a peptide cocktail inducing antibody, helper and cytotoxic T-cell responses on protection against respiratory syncytial virus.

Respiratory syncytial virus (RSV)-specific cytotoxic T lymphocytes (CTL) or neutralizing antibodies can protect against RSV infection when induced separately by immunization with synthetic peptides. In the work described here, RSV-specific neutralizing antibodies and CTLs were induced after immunization with a cocktail of peptides consisting of a B-cell mimotope (S1S-MAP), a T-helper epitope (SH:45-60) and a CTL epitope linked to a fusion (F) peptide (F/M2:81-95) that were comparable to those induced by the peptides alone. Following challenge, a 190-fold reduction in RSV titre was observed in the lungs of peptide cocktail-immunized mice. The combination of RSV-specific humoral and cellular immunity induced by the peptide cocktail was thus more effective at clearing RSV than peptide-induced humoral or cellular immunity alone.

A phage-displayed mimotope inhibits tumour necrosis factor-alpha-induced cytotoxicity more effectively than the free mimotope.

A phage-displayed peptide library was screened by direct interaction with human tumour necrosis factor-alpha (TNF-alpha) to identify novel antagonistic molecules of its biological activities. After several rounds of affinity selection, a phage displaying a mimotope sequence was shown to strongly inhibit, in a dose-dependent fashion, both mouse and human TNF-alpha-mediated cytotoxicity in L929 cells. The identified mimotope did not bear any sequence homology to the primary structures of the extracellular domains of either the 55 000 MW or the 75 000 MW TNF-alpha receptors, suggesting that it represents or mimics a conformational epitope involved with binding to TNF-alpha. The free 15-mer mimotope weakly inhibited TNF-alpha-induced cytotoxicity in vitro, and it did not bind to TNF-alpha as assessed by surface plasmon resonance, demonstrating the importance of mimotope presentation for its biological activities. In conclusion, this study highlights the potential of random combinatorial peptide libraries for the identification of novel inhibitors, which may serve as important tools in research that could lead to the development of TNF-alpha antagonists with therapeutic potential.

A peptidomimetic antagonist of TNF-alpha-mediated cytotoxicity identified from a phage-displayed random peptide library.

Phage-displayed peptide libraries represent a vast collection of peptide sequences that can be used to identify novel therapeutic molecules. In this report, a 15-mer phage-displayed peptide library was used to identify potential TNF-alpha antagonists. After direct interaction of recombinant human TNF-alpha with the library, four randomly selected phage clones were shown to inhibit in a dose-dependent fashion both mouse and human TNF-alpha-induced cytotoxicity in vitro. DNA sequencing of the positive clones revealed a common amino acid sequence that does not bear any structural similarity to the known primary structures of the extracellular domains of either 55-kDa or 75-kDa TNF receptors. This sequence was synthesized, and the peptidomimotope was shown i) to bind to the recombinant human TNF-alpha using surface plasmon resonance (biosensor) technology and ii) to inhibit both recombinant mouse and human TNF-alpha-induced cytotoxicity in vitro in a dose-dependent fashion. These findings highlight the potential of phage-displayed random peptide libraries for the identification of novel low molecular antagonistic molecules that can block the biologic activities of TNF-alpha.

Protective cytotoxic T lymphocyte responses against paramyxoviruses induced by epitope-based DNA vaccines: involvement of IFN-gamma.

Plasmid DNA vectors have been constructed with minigenes encoding a single cytotoxic T lymphocyte (CTL) epitope from either the M2 protein of respiratory syncytial virus (RSV) or from the nucleoprotein of measles virus (MV) with or without a signal sequence (also called secretory or leader sequence). Following intradermal immunization, plasmids in which the CTL epitopes were expressed in-frame with the signal sequence were more effective at inducing peptide- and virus-specific CTL responses than plasmids expressing CTL epitopes without the signal sequence. This immunization resulted in protection against MV-induced encephalitis and a significant reduction in viral load following RSV challenge. The reduction of viral load following RSV challenge was abrogated by prior injection with anti-IFN-gamma antibodies. These results highlight the ability of epitope-based DNA immunization to induce protective immune responses to well-defined epitopes and indicate the potential of this approach for the development of vaccines against infectious diseases.

Protection against measles virus-induced encephalitis by antibodies from mice immunized intranasally with a synthetic peptide immunogen.

Balb/c mice were immunized intranasally (i.n.) with a chimeric synthetic peptide containing two copies of a T- and one copy of a B-cell epitope (TTB) from measles virus (MV) fusion protein, plus cholera toxin B (CTB) adjuvant. The antibodies induced cross-reacted with, and neutralized MV and on passive transfer, protected mice against encephalitis induced by neuroadapated MV. Immunization with TTB alone induced antibodies which increased survival but not significantly compared to controls. Furthermore, i.n. immunization with TTB plus CTB induced TTB-specific IgA antibodies in saliva and nasal washes. Co-administration of CTB increased the affinity of antibodies to the B-cell epitope of TTB and caused a relative increase in the level of anti-peptide antibodies of the IgG2a subclass and the overall titre of IgG antibodies. These results indicate the potential of the i.n. route for immunization with synthetic peptide immunogens for induction of both local and systemic anti-peptide antibody responses.

A peptide mimic of a protective epitope of respiratory syncytial virus selected from a combinatorial library induces virus-neutralizing antibodies and reduces viral load in vivo.

Respiratory syncytial virus (RSV) is the most important cause of bronchiolitis and pneumonia in infants and young children worldwide. As yet, there is no effective vaccine against RSV infection, and previous attempts to develop a formalin-inactivated vaccine resulted in exacerbated disease in recipients subsequently exposed to the virus. In the work described here, a combinatorial solid-phase peptide library was screened with a protective monoclonal antibody (MAb 19) to identify peptide mimics (mimotopes) of a conserved and conformationally-determined epitope of RSV fusion (F) protein. Two sequences identified (S1 [HWYISKPQ] and S2 [HWYDAEVL]) reacted specifically with MAb 19 when they were presented as solid-phase peptides. Furthermore, after amino acid substitution analyses, three sequences derived from S1 (S1S [HWSISKPQ], S1K [KWYISKPQ], and S1P [HPYISKPQ]), presented as multiple antigen peptides (MAPs), also showed strong reactivity with MAb 19. The affinity constants of the binding of MAb 19, determined by surface plasmon resonance analyses, were 1.19 x 10(9) and 4.93 x 10(9) M(-1) for S1 and S1S, respectively. Immunization of BALB/c mice with these mimotopes, presented as MAPs, resulted in the induction of anti-peptide antibodies that inhibited the binding of MAb 19 to RSV and neutralized viral infection in vitro, with titers equivalent to those in sera from RSV-infected animals. Following RSV challenge of S1S mimotope-immunized mice, a 98.7% reduction in the titer of virus in the lungs was observed. Furthermore, there was a greatly reduced cell infiltration in the lungs of immunized mice compared to that in controls. These results indicate the potential of peptide mimotopes to protect against RSV infection without exacerbating pulmonary pathology.

Reduction of respiratory syncytial virus titer in the lungs of mice after intranasal immunization with a chimeric peptide consisting of a single CTL epitope linked to a fusion peptide.

In the work described here, the effect of intranasal immunization of BALB/c mice with synthetic chimeric peptides consisting of a cytotoxic T-cell epitope (amino acids 81-95) from the M2 protein of respiratory syncytial virus (RSV) and a fusion peptide (amino acids 113-131) from the F1 protein of measles virus on response to challenge with RSV has been assessed. Three intranasal immunizations with the chimeric peptides without adjuvant induce peptide- and RSV-specific cytotoxic T-cell responses (CTL) at 1 or 3 weeks after the third immunization. The CTL responses significantly declined at 6 weeks after immunization. Furthermore, viral load in the lungs following challenge with RSV was significantly reduced in mice immunized with the F/M2:81-95 chimeric peptide compared to control animals at 1 or 3 weeks after immunization and no reduction of RSV titers was detectable 6 weeks after immunization. The CTL activity induced by F/M2:81-95 was therefore short-lived (less than 6 weeks) but was significantly correlated with the reduction in viral load in the lungs.

Fine specificity of the antibody response to a synthetic peptide from the fusion protein and protection against measles virus-induced encephalitis in a mouse model.

A synthetic peptide representing residues 397-420 from the measles virus (MV) fusion (F) protein was tested for its structure, immunogenicity and protective capacity against intracerebral challenge with a neuroadapted strain of MV. Analysis of the peptide by mass spectrometry showed that it was linear, despite the presence of two cysteine residues in the sequence. Circular dichroism spectroscopy highlighted a weak preference for the peptide to adopt an alpha-helical conformation. The peptide was shown to be immunogenic in BALB/c and C57BL/6 mice after intraperitoneal immunization in Freund's adjuvant, and anti-peptide antibodies from both strains of mice reacted with the MV as a solid phase antigen on an ELISA plate. When the fine specificity of the anti-peptide antibody response was examined using overlapping 8-mer peptides, serum antibodies from BALB/c mice recognized the region between residues 407-417 whereas antibodies from C57BL/6 mice recognized the region 408-420 of the 397-420 peptide sequence. Although anti-397-420 antibodies had no demonstrable neutralizing activity, protection against challenge with a neuroadapted strain of MV was demonstrated following active immunization with peptide in C57BL/6 mice or after passive transfer of anti-peptide antibodies in BALB/c mice. These findings highlight the importance of the 397-420 region in the induction of protective antibodies in the MV encephalitis mouse model, and suggest that this epitope might be a good candidate for inclusion in a future MV synthetic peptide vaccine.