Hepatitis C virus (HCV) is a worldwide health problem. No vaccine is available against this pathogen and therapeutic treatments currently in use are of limited efficacy. In the present study, the immunogenicity of the therapeutic vaccine candidate CIGB-230, based on the mixture of pIDKE2, a plasmid expressing HCV structural antigens, with a recombinant HCV core protein, Co.120, was evaluated. CIGB-230 was administered by intramuscular injection on weeks 0, 4, 8, 12, 16 and 20 to 15 HCV-chronically infected individuals, non-responders to previous treatment with interferon (IFN) plus ribavirin. Interestingly, following the final immunization, neutralizing antibody responses against heterologous viral pseudoparticles were modified in eight individuals, including six de novo responders. In addition, 73% of vaccinees exhibited specific T cell proliferative response and T cell IFN-gamma secretory response 24 weeks after primary immunization with CIGB-230. Furthermore, 33.3% of individuals developed de novo cellular immune response against HCV core and the number of patients (46.7% at the end of treatment) with cellular immune response against more than one HCV structural antigen increased during vaccination (P = 0.046). In addition, despite persistent detection of HCV RNA, more than 40% percent of vaccinated individuals improved or stabilized liver histology, particularly reducing fibrosis, which correlated with cellular immune response against more than one HCV antigen (P = 0.0053). In conclusion, CIGB-230 is a promising candidate for effective therapeutic interventions based on its ability for enhancing the immune response in HCV chronically infected individuals.
Hepatitis C virus (HCV) infection is a major worldwide problem. Chronic hepatitis C is recognized as one of the major causes of cirrhosis, hepatocellular carcinoma, and liver failure. Although new, directly acting antiviral therapies are suggested to overcome the low efficacy and adverse effects observed for the current standard of treatment, an effective vaccine would be the only way to certainly eradicate HCV infection. Recently, polyhydroxybutyrate beads produced by engineered Escherichia coli showed efficacy as a vaccine delivery system. Here, an endotoxin-free E. coli strain ( Hepatitis C virus (HCV) is an etiologic agent of chronic hepatitis C (1). Chronic HCV infection affects more than 170 million people worldwide and is responsible for approximately 350,000 deaths each year (2). Viral exposure results in acute disease in a small proportion of cases, while the majority (80%) progress to chronic infection, causing liver inflammation that slowly progresses to cirrhosis, liver failure, hepatocellular carcinoma, and death (3).Despite a substantial decline in HCV transmission due to improved prevention strategies and the introduction of new and powerful targeted therapies, hepatitis C remains a huge health problem, justifying further endeavors to develop new vaccines. Indeed, the pool of asymptomatic chronic HCV carriers who represent an infectious reservoir will remain substantial for many years. Less than 30% of patients with chronic hepatitis C are aware of the infection, and only about 10% of patients are currently treated (4, 5). Therefore, even if new antivirals could cure 90% of patients, there would still be a considerable percentage of patients who would be excluded (6). Hence, development of a vaccine to prevent infection or to at least prevent progression to chronicity represents a significant unmet medical need and is of high priority.Since 1% of infected patients show an immune response clearing the infection and the rate of spontaneous resolution is higher in the case of reinfected patients, this demonstrates that the induction of protective immunity which prevents development of chronic disease is a feasible goal for the development of a preventive vaccine against HCV (7,8).The role of HCV-specific T cell responses in the outcome of primary HCV infection has been widely studied, although a single correlate of protection has not been determined. However, it is known that this type of immune response is a determinant in the clearance of the virus. Comparative studies in humans and chimpanzees have shown that widespread and long-lasting CD8 ϩ and CD4 ϩ T cell responses against multiple HCV regions are linked to spontaneous viral clearance (9, 10).However, there is also strong evidence that rapid induction of high-titer cross-neutralizing antibodies targeting HCV envelope proteins correlates with viral clearance and protects against reinfection (11, 12). Therefore, an optimal HCV vaccine probably needs to elicit broad cross-reactive cellular immune responses together with cross-neutralizing antibo...
Plasmids expressing variants of the hepatitis C virus (HCV) core, E1 and E2 proteins individually or as polyproteins were administered to BALB/c mice. All plasmids induced a detectable and specific antibody response. Antibody titres against core, E1 and E2 proteins, 19 weeks after primary immunization, ranged from 1:50 to 1:4500 depending on the inoculated plasmid and the HCV antigen evaluated. Constructs expressing HCV envelope proteins as polyprotein variants including the core amino acid region induced statistically stronger antibody responses than plasmids encoding individual E1 and E2 proteins. Particularly, the pIDKE2 plasmid, expressing the first 650 amino acids in the viral polyprotein, induced a potent and multispecific antibody and lymphoproliferative response against HCV core, E1 and E2 proteins. Anti-E2 antibodies generated by pIDKE2 immunization were cross-reactive to hypervariable region-1 peptides from different genotypes. Immunization with the pIDKE2 also generated a positive cellular immune response against the core antigen, determined by interferon-gamma enzyme-linked immunospot (ELISPOT) assay, and induced detectable levels of interferon-gamma but not interleukin-4 in vaccinated mice. The detection of both antibody and cytotoxic T-lymphocyte responses, potentially targeted to circulating or cell-infecting virions respectively, in mice vaccinated with the pIDKE2 plasmid is very attractive for the effective eradication of HCV infection.
Hepatitis C virus (HCV) causes chronic infection in approximately two thirds of cases, leading to chronic hepatitis, liver cirrhosis and hepatocellular carcinoma in a substantial proportion of the 170 million HCV-infected individuals worldwide. As there is neither prophylactic nor therapeutic vaccines for this virus, the research in this area is of special importance. Several vaccine candidates have been evaluated in pre-clinic, but only a few have reached the clinical evaluation. DNA immunization is one of the most evaluated approaches to obtain an effective vaccine against HCV infection. In the last few years a group of technical refinements in DNA vaccines has allowed to increase their immunogenicity. Two DNA vaccine candidates against HCV have already reached clinical evaluation, and are well tolerated and immunogenic in HCV-chronically infected individuals. The main results, opportunities and challenges of DNA immunization against HCV are discussed further in the present commentary. DNA vaccination is already a valuable tool for research HCV. Further improvements in formulation and delivery devices might be sufficient for becoming a real alternative in HCV vaccine.
In the present work, immunogenicity of recombinant in vitro assembled hepatitis C virus core particles, HCcAg.120-VLPs, either alone or in combination with different adjuvants was evaluated in BALB/c mice. HCcAg.120-VLPs induced high titers of anti-HCcAg.120 antibodies and virus-specific cellular immune responses. Particularly, HCcAg.120-VLPs induced specific delayed type hypersensitivity, and generated a predominant T helper 1 cytokine profile in immunized mice. In addition, HCcAg.120-VLPs prime splenocytes proliferate in vitro against different HCcAg.120-specific peptides, depending on either the immunization route or the adjuvant used. Remarkably, immunization with HCcAg.120-VLPs/Montanide ISA888 formulation resulted in a significant control of vaccinia virus titer in mice after challenge with a recombinant vaccinia virus expressing HCV core protein, vvCore. Animals immunized with this formulation had a marked increase in the number of IFN-γ producing spleen cells, after stimulation with P815 cells infected with vvCore. These results suggest the use of recombinant HCV core particles as components of therapeutic or preventive vaccine candidates against HCV.
Hepatitis C virus (HCV) infects approximately 3% of global population. This pathogen is one of the main causes of chronic viral hepatitis, cirrhosis, and liver cancer, as well as the principal reason for liver transplant in Western countries. Therapy against HCV infection is effective in only half of treated patients. There is no vaccine available against HCV. Some vaccine candidates have reached the clinical trials but several factors, including the incomplete definition of immunological correlates of protection and treatment-related clearance have slowed down vaccine development. Precisely, the present review discusses the state of the art in the establishment of parameters related with immunity against HCV. Validity and limitations of the information accumulated from chimpanzees and other animal models, analysis of studies in humans infected with HCV, and relevance of aspects like type, strength, duration, and specificity of immune response related to successful outcome are evaluated in detail. Moreover, the immune responses induced in some clinical trials with vaccine candidates resemble the theoretical immunological correlates, raising questions about the validity of those correlates. When all facts are taken together, complete definition of immunological correlates for protection or treatment-related clearance is an urgent priority. A limited or wrong criterion with respect to this relevant matter might cause incorrect vaccine design and selection of immunization strategies or erroneous clinical evaluation.
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