Hepatitis B virus surface antigen (HBsAg) as carrier for synthetic peptides having an attached hydrophobic tail

Detection of hepatitis B virus PreS1 antigen using a time-resolved fluoroimmunoassay

The hepatitis B virus (HBV) PreS1 antigen is expressed at the distal most region of the envelope protein and contains the hepatocyte receptor-binding site. The presence of the HBV PreS1 antigen in serum and liver of HBsAg-positive patients is a new marker used for diagnosing HBV infection, and is indicative of viral replication. Our objective is to establish a method of time-resolved fluoroimmunoassay (TRFIA) with higher sensitivity and broader detection range for detecting serum HBV PreS1 antigen. Eu(3+) labeling of antibodies was performed with respective labeling kits, and Eu(3+) fluorescence intensity was measured with an auto DELFIA1235 TRFIA analyzer. The established method was evaluated for its performance. Serum specimens (574 in total) from Wuxi People's Hospital were analyzed for PreS1 antigen using the TRFIA and ELISA. The precision, specificity, and sensitivity of the TRFIA were clearly better than ELISA. The detection limit was 0.01 ng/mL. The average recovery rate for PreS1 antigens was 103.3%. There was significant correlation between the PreS1 antigen results obtained by TRFIA and ELISA in 374 serum samples with HBV >10(3) IU/mL (χ(2) = 25.04, p < 0.01) and 183 HbeAg-positive serum samples (χ(2) = 12.07, p < 0.01). Normal reference ranges were established at 0-0.32 ng/mL based on the values obtained from 100 healthy controls. TRFIA is a significantly effective method for clinical detection of serum HBV PreS1 antigens.

Virus-like particle vaccines and adjuvants: the HPV paradigm

Complex antigen structures currently represent the most-studied approach for prophylactic as well as therapeutic vaccines. Different types of complex vaccines, including virus-like particles and virosomes, have been developed depending on the nature of the viral pathogen they are trying to replicate (enveloped vs naked) or the modality to express antigenic epitopes (i.e., the binding of envelope protein on liposomic structures). The complex structure of these vaccines provides them with some adjuvanted properties, not uniformly present for all virus-like particle types. The further inclusion of specific adjuvants in vaccine preparations can modify the presentation modality of such particles to the immune system with a specific Th1 versus Th2 polarization efficacy. A paradigm of the relevance of these new adjuvants are the immunological results obtained with the inclusion of monophosphoryl lipid A adjuvant in the formulation of L1-based human papillomavirus-naked virus-like particles to reduce a Th1 cellular immunity impairment, peculiar for alum-derived adjuvants, along with the induction of highly enhanced humoral and memory B-cellular immunity.

Delivery of vaccine peptides by rapid conjugation to baculovirus particles

Baculoviruses deliver strong activation signals to dendritic cells and can promote potent immune responses. These properties can be harnessed to use baculovirus as an adjuvant and carrier particle for immunogenic peptides. In this study we use a chemical linker to couple peptides to the baculovirus Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV). Intranasal delivery of baculovirus coupled with immunogenic peptides to mice elicited antigen-specific IgG1 and IgG2a antibody. Furthermore, antigen-specific IgA was detected in the lung, and an IFN-gamma response was observed upon re-stimulation with antigen. We show that chemical coupling enables the rapid modification of AcMNPV, allowing multiple epitopes to be delivered simultaneously on a self-adjuvanting carrier particle.

Vaccination: a management tool in veterinary medicine

Conventional vaccines have been used for some 200 years, primarily to control infectious diseases. It is envisaged that such vaccines will continue to be used and new ones developed using conventional technology. However, in addition to conventional vaccines, novel approaches using biotechnology are already in use and many more are in various stages of development. These novel vaccines are not only being used to control infectious diseases, but also to improve productivity of livestock by modulating hormones, for gender selection, as well as in controlling ectoparasites. The recent developments in vaccination technology in all of these areas are described.

Single-chain lipopeptide vaccines for the induction of virus-specific cytotoxic T cell responses in randomly selected populations

Effective vaccine development is now taking advantage of the rapidly accumulating information concerning the molecular basis of a protective immune response. Analysts and medicinal chemists have joined forces with immunologists and taken up the clear challenge of identifying immunologically active structural elements and synthesizing them in pure, reproducible forms. Current literature reveals the growing interest for extremely reductionist approaches aiming at producing totally synthetic vaccines that would be fully defined at the molecular level and particularly safe. The sequential information contained in these formulations tends to be minimized to those epitopes which elicit neutralizing antibodies, or cell-mediated responses. In the following review, we describe some of our results in developing fully synthetic, clinically acceptable lipopeptide vaccines for inducing cytotoxic T lymphocytes (CTL) responses in randomly selected populations.

Purification and structural analysis of the hepatitis B virus preS1 expressed from Escherichia coli

The preS1 of hepatitis B virus (HBV) is located at the outermost part of the envelope protein and possesses several functionally important regions such as hepatocyte receptor-binding site and virus-neutralizing epitopes. As the first step to understand the structure-function relationship for the preS1 antigen, we have purified the preS1 and performed its structural characterization by circular dichroism (CD) spectroscopy. The preS1 was purified to near homogeneity from bacterially expressed glutathione S-transferase (GST)-preS1 fusion protein by two-step purification, affinity chromatography on glutathione-agarose column, and cation-exchange chromatography on Mono S column. The CD analysis showed that the purified preS1, which was largely unstructured in aqueous solution, acquired a significant (16%) alpha-helical structure when analyzed in 50% trifluoroethanol or 20 mM SDS. The results suggest that the preS1 assumes a mainly unstructured conformation and may form induced secondary structures upon binding to target proteins or under hydrophobic environment.

Purified dengue 2 virus envelope glycoprotein aggregates produced by baculovirus are immunogenic in mice

The full-length dengue 2 virus envelope glycoprotein (Egp) was expressed in insect cells by recombinant (r) baculovirus and found to form multimeric aggregates that were recovered in the void volume of gel filtration columns and by ultracentrifugation. An immunoblot confirmed that rEgp aggregrates disrupted with SDS sample buffer released a monomeric form that migrated with a molecular weight similar to native dengue 2 virus Egp on polyacrylamide gels. The rEgp aggregates reacted strongly with a panel of monoclonal antibodies specific for the native Egp and which identify critical structural and functional epitopes. The rEgp aggregates were purified by ultracentrifugation through 30% sucrose, and were shown to be the major protein band on a polyacrylamide gel and corresponding immunoblot. Purified rEgp aggregates in combination with aluminum hydroxide induced high titer neutralizing antibodies in adult mice. The generation of full-length dengue 2 rEgp aggregates in insect cells facilitated development of a simple, effective procedure for purification of the recombinant protein, and represents a good approach for producing highly immunogenic dengue 2 rEgp as a component of a subunit vaccine.

Core particles of hepatitis B virus as carrier for foreign epitopes

To be effective as vaccines, most monomeric proteins and peptides either require chemical coupling to high molecular weight carriers or application together with adjuvants. More recently, recombinant DNA techniques have been used to insert foreign epitopes into proteins with inherent multimerization capacity, such as particle-forming viral capsid or envelope proteins. The core protein of hepatitis B virus (HBcAg), because of its unique structural and immunological properties, has gained widespread interest as a potential antigen carrier. Foreign sequences of up to approximately 40 amino acid residues at the N terminus, 50 or 100 amino acids in the central immunodominant c/e 1 epitope region of HBcAg, and up to 100 or even more residues at the C terminus, did not interfere with particle formation. The humoral immunogenicity of inserted epitopes is determined by the immunogenicity of the peptide itself and its surface exposure, and is influenced by the route of application. The probably flexible and surface-exposed c/e1 region emerged as the most promising insertion site. When applied together with adjuvants approved for human and veterinary use, or even without adjuvants, such chimeric particles induced B and T cell immune responses against the inserted epitopes. In some cases neutralizing antibodies, cytotoxic T cells and protection against challenge with the intact pathogen were demonstrated. Major factors for the potentiated immune response against the foreign epitopes are the multimeric structure of chimeric HBcAg that results in a high epitope density per particle, and the provision of T cell help by the carrier moiety. Beyond its use as subunit vaccine, chimeric HBcAg produced in attenuated Salmonella strains may be applicable as live vaccine.

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

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

Recent advances in multiple antigen peptides

The goals for the development of multiple antigen peptides (MAP) are to provide a rational and unambiguous system to multimerize different types of synthetic peptide antigens and to attach immunomodulating molecules for targeting and delivery. These goals have been largely realized and new designs of MAPs now permit a broad range of immune responses including CTLs and mucosal IgAs. Furthermore, significant advances by the inventiveness of many laboratories have led to applications of MAPs for serodiagnostic and other biochemical uses including those for drug discovery. An important aspect to accomplish various goals of MAPs is chemistry. New methodologies using unprotected peptides as building blocks have been developed to accommodate new and sophisticated design of MAPs. This review is written based on the personal perspective of my laboratory and will focus on the recent progress in MAPs, together with the chemistry to achieve their synthesis.

Induction of systemic and mucosal immune responses following immunization with somatostatin-avidin complexes incorporated into ISCOMS

Synthetic, biotinylated somatostatin-14 (Somatotropin Release-Inhibiting Factor; SRIF) was conjugated to avidin, and the resulting complex incorporated into immune-stimulating complexes (ISCOMS). The ISCOMS were used to study the systemic and mucosal immune responses induced by parenteral and gastrointestinal vaccination. Mice were immunized by intraperitoneal (IP) and intragastric (IG) routes and subsequently by either IP or IG secondary immunizations (groups-IP/IP; IP/IG; IG/IG). Antigen specific IgG and IgA antibody secreting cells (ASC) from the spleen, mesenteric lymph nodes (MLN) and Peyer's patches (PP's) were studied by an enzyme-linked immunospot assay (ELISPOT). Specific proliferative responses of spleen cells to avidin and to SRIF were measured. Immunization IP/IP evoked the highest serum IgG levels to avidin and to SRIF as well as the highest numbers of splenic IgG isotype ASC. The greatest IgA response in MLN and PP's was induced by IP/IG immunization. Only marginal mucosal immunity and no splenic cell specific proliferative responses were found by IG/IG immunization. These results indicate that ISCOMS are an effective delivery system for protein-peptide antigens. The ISCOMS system described elicited systemic and mucosal antibody immune responses, and primed specific proliferative response when administered IP/IG. This offers another approach for the design and delivery of mucosally administered peptide vaccines.

Rotavirus particles function as immunological carriers for the delivery of peptides from infectious agents and endogenous proteins

A major problem in the development of useful animal subunit vaccines has been the generation of immune responses to weakly immunogenic molecules. For this purpose a new and effective delivery system has been devised. This system is based upon the inner capsid of bovine rotavirus. Under the appropriate conditions, the inner capsid protein, designated BP6, can be made to self-assemble in vitro and form spherical particles. These particles possess an inherent capacity to target to cells of the immune system. Exploitation of these properties has led to the development of technology to couple antigens to the VP6 particles such that the sphere acts as a novel immunological carrier. This is based on a "binding peptide" derived from another rotavirus peptide, VP4, as well as on more traditional techniques of chemical coupling. We have coupled peptides or proteins to this carrier via the binding peptide and have shown that every epitope tested to date gave excellent immune responses. Furthermore, using this carrier, immunity has been developed without the use of adjuvants. This has far-reaching implications for animal and human immunization.

Peptide component vaccine engineering: targeting the AIDS virus

Most of the successful vaccines developed to date induce protective immunity resembling that produced by natural infection. HIV infection does not induce protective immunity. Thus, previously successful approaches based on live- or killed-virus preparations may not yield an effective and safe AIDS vaccine and many feel that a more highly engineered vaccine will be required. Synthetic peptides represent extremely powerful tools for vaccine research and construct optimization. The theory and practice of vaccine engineering using synthetic peptide components is reviewed with special emphasis on progress towards development of a vaccine for AIDS.