Current progress in development of hepatitis C virus vaccines.

Despite major advances in the understanding and treatment of hepatitis C, a preventive vaccine remains elusive. The marked genetic diversity and multiple mechanisms of persistence of hepatitis C virus, combined with the relatively poor immune response of the infected host against the virus, are major barriers. The lack of robust and convenient model systems further hampers the effort to develop an effective vaccine. Advances in our understanding of virus-host interactions and protective immunity in hepatitis C virus infection provide an important roadmap to develop potent and broadly directed vaccine candidates targeting both humoral and cellular immune responses. Multiple approaches to generating and testing viral immunogens have met with variable success. Several candidates have advanced to clinical trials based on promising results in chimpanzees. The ultimate path to a successful preventive vaccine requires comprehensive evaluations of all aspects of protective immunity, innovative application of state-of-the-art vaccine technology and properly designed vaccine trials that can affirm definitive endpoints of efficacy.

Covalent albumin microparticles as an adjuvant for production of mucosal vaccines against hepatitis B.

Covalently modified albumin (BSA) microparticles were developed for potential use as an adjuvant in mucosal vaccines against hepatitis B. To synthesize consistent protein particles, a covalent approach was proposed to modify BSA. Our strategy was to bond maleic anhydride (MA) molecules to BSA structure by nucleophilic reaction for further radical cross-linking/polymerization reaction with N',N'-dimethylacrylamide (DMAAm). The presence of poly(N',N'-dimethylacrylamide) in the protein network enables the microparticles to show well-defined, homogeneous forms. Cytotoxicity tests showed that the cytotoxic concentration for 50% of VERO cells (CC50) was 216.25 ± 5.30 µg mL(-1) in 72 h of incubation. The obtained CC50 value is relatively low for an incubation time of 72 h, suggesting an acceptable biocompatibility. Assay of total protein showed that the encapsulation efficiency of the microparticles with hepatitis B surface antigen (HBsAg) was 77.7 ± 0.2%. For the reference sample, which was incubated without HBsAg, the quantity of protein was below the limit of detection.

Immunogenicity and cross-reactivity of a representative ancestral sequence in hepatitis C virus infection.

Vaccines designed to prevent or to treat hepatitis C viral infection must achieve maximum cross-reactivity against widely divergent circulating strains. Rational approaches for sequence selection to maximize immunogenicity and minimize genetic distance across circulating strains may enhance vaccine induction of optimal cytotoxic T cell responses. We assessed T cell recognition of potential hepatitis C virus (HCV) vaccine sequences generated using three rational approaches: combining epitopes with predicted tight binding to the MHC, consensus sequence (most common amino acid at each position), and representative ancestral sequence that had been derived using bayesian phylogenetic tools. No correlation was seen between peptide-MHC binding affinity and frequency of recognition, as measured by an IFN-γ T cell response in HLA-matched HCV-infected individuals. Peptides encoding representative, consensus, and natural variant sequences were then tested for the capacity to expand CD8 T cell populations and to elicit cross-reactive CD8 T cell responses. CD8(+) T cells expanded with representative sequence HCV generally more broadly and robustly recognized highly diverse circulating HCV strains than did T cells expanded with either consensus sequence or naturally occurring sequence variants. These data support the use of representative sequence in HCV vaccine design.

[Synthetic peptide vaccines].

This review considers the stages of the development of synthetic peptide vaccines against infectious agents, novel approaches and technologies employed in this process, including bioinformatics, genomics, proteomics, large-scale peptide synthesis, high-throughput screening methods, the use of transgenic animals for modelling human infections. An important role for the development and selection of efficient adjuvants for peptide immunogens is noted. Examples of synthetic peptide vaccine developments against three infectious diseases (malaria, hepatitis C, and foot-and-mouth disease) are given.

[Investigation of HCV multi-epitope gene vaccine loaded by CTS-Fe3O4].

OBJECTIVE: In order to develop a promising HCV gene vaccine candidate to induce effective immune response and explore the application of magnetic nanoparticles as gene delivery system. METHODS: The DNA fragment containing multi-epitope antigen gene of HCV with five conserved mimotopes was synthesized and cloned into plasmid pcDNA3.1 (+). The Fe3O4 modified with chitoson was prepared and the cytotoxicity of the magnetic material was detected in vitro. Analysis of recombinant plasmid in vitro expression, and its immunogenicity loaded by CTS-Fe3O4 in mice were evaluated in detail. RESULTS: The HCV multi-epitope gene vaccine pcDNA3.1 (+)-MA was successfully constructed and recognized by 81% HCV positive sera. There was no cytotoxicity of CTS-Fe3O4 when its concentration was equal or less than 1 mmol/L. Both the antibody production and T-cell activity were induced. CONCLUSION: It was believed that DNA encoding MA was an attractive approach for the therapeutic and prophylactic vaccines against HCV and the Fe3O4 modified with chitoson showed excellent target, safety and adjuvant effect as gene carrier.

[Studies on synthetic peptide. XX: the antigenicity and linear epitope map of synthetic peptide hepatitis C virus].

Hepatitis C virus (HCV), the major causative agent of post transfusion non-A, non-B hepatitis (NANB), had been cloned and expressed. According to the protein sequence of HCV-BK and its epitope profiles which combined the hydrophilicity, accessibility, flexibility, antigenicity, charge distribution and HPLC reserve coefficient of protein using the "Goldkey" computer program, we designed and synthesized the following peptides: P1(475-495), P3(449-468), P4(658-663), P5(645-663), P6(484-489), P7(475-489), P15(655-662), P16(230-237), P17(225-237), P18(1220-1240), P19(1694-1735), P24(1230-1240), P25(1482-1493), P26(384-389), P27(2355-2389). The results of ELISA showed that P6(60% positive results) and P19(63% positive results) testing with PT-HC of Gu An, Hebei province were the major antigens in NS1 and in NS4 region, respectively.

[Studies on polypeptides. IX. Synthesis and antigen specificity of pre-S region fragments of hepatitis B surface antigen].

Seven peptide fragments of HBsAg Pre-S region have been synthesized by liquid phase and solid phase methods. All peptide fragments were linked to protein carrier by carbodiimide and glutaraldehyde methods. The antigen specificity of the peptide--protein conjugates was assayed by anti-HBsAg polyclonal antibodies and anti--"a" monoclonal antibody. P1 and P5 were found to have higher antigen specificity.

Quality assessment of DNA vaccines: hepatitis-B vaccine.

Vaccines manufactured following "classical" methods contain inactivated or infectious but attenuated viruses or bacteria. In some instances, the inactivated agents are purified. In other cases, the vaccines contain protein subunits or practically pure polysaccharides. It is generally accepted that the final product cannot be completely characterised and that therefore extensive "in-process" controls are necessary to prove the consistent quality of such vaccines. Control tests are carried out on the substrate, the pooled bulk vaccine and on the final containers. Vaccines produced by recombinant DNA techniques consist of pure proteins. The production is carried out by the multiplication of the "working seed" under well-defined standardised conditions followed by clarification, extraction, purification, formulation. "In-process" controls are incorporated at each step and specifications for acceptance are formulated. The biological methods used for the classical vaccines are completed by physicochemical and immunological determinations of antigen content, identity and purity for the "new generation" products. The requirements for the manufacturers are based on the documents issued by the World Health Organisation and by the national control authorities. The marketing of vaccines is based on a lot by lot release procedure, whereby each lot is tested by the manufacturer and the national control authority before use. Hepatitis-B vaccine, derived from transformed yeast cells, is the first and sole vaccine which has obtained a world-wide license. The quality assessment of this vaccine has been achieved following the requirements for the new generation of biomolecules. It is an example for future vaccines.

Challenges and opportunities in biotechnology.

The biotechnology industry is thriving, and many predicted accomplishments have actually occurred during the last decade. Cloning and expression of genetic information is now simple and routine. Initial commercial products have been realized, but there is much yet to be accomplished in evaluating the clinical significance of many other gene products made available by biotechnology resources. During the next decade, human health care and the pharmaceutical industry should be affected substantially by first- and second-generation recombinant DNA products. Recombinant vaccines, blood coagulation factors, and known biological modulators produced by rDNA technologies should be widely used. Further opportunities will be realized with increasing discoveries of new bioactive molecules and identification of NANB hepatitis and AIDS infectious agents. Full exploitation of health care products will depend on innovative new delivery systems or the ability to reconstruct mammalian and plant genes, providing for in-situ delivery of the necessary gene products.