Alginate Microsponges as a Scaffold for Delivery of a Therapeutic Peptide against Rheumatoid Arthritis.

The quest for biocompatible drug-delivery devices that could be able to open new administration routes is at the frontier of biomedical research. In this contribution, porous polysaccharide-based microsponges based on crosslinked alginate polymers were developed and characterized by optical spectroscopy and nanoscopic microscopy techniques. We show that macropores with a size distribution ranging from 50 to 120 nm enabled efficient loading and delivery of a therapeutic peptide (CIGB814), presently under a phase 3 clinical trial for the treatment of rheumatoid arthritis. Alginate microsponges showed 80% loading capacity and sustained peptide release over a few hours through a diffusional mechanism favored by partial erosion of the polymer scaffold. The edible and biocompatible nature of alginate polymers open promising perspectives for developing a new generation of polysaccharide-based carriers for the controlled delivery of peptide drugs, exploiting alternative routes with respect to intravenous administration.

Immunization with a DNA vaccine candidate in chronic hepatitis C patients is safe, well tolerated and does not impair immune response induction after anti-hepatitis B vaccination.

BACKGROUND: In the present study, we evaluated the safety of CIGB-230, a novel vaccine candidate based on the mixture of a plasmid for DNA immunization, expressing hepatitis C virus (HCV) structural antigens, with a recombinant HCV Core protein. METHODS: Fifteen HCV chronically-infected volunteers with detectable levels of HCV RNA genotype 1b, who were nonresponders to previous treatment with interferon plus ribavirin, were intramuscularly injected with CIGB-230 on weeks 0, 4, 8, 12, 16 and 20. Individuals were also immunized at weeks 28, 32 and 36 with a recombinant vaccine against hepatitis B. Adverse events were recorded and analyzed. Blood samples were taken every 4 weeks up to month 12 for hematological, biochemical, virological and immunological analysis. RESULTS: All patients completed the treatment with CIGB-230. Adverse events were only slight (83.6%) or moderate (16.4%). No significant differences in hematological and biochemical parameters, including serum aminotransferases, were detected between the baseline and post-treatment state. Induction of a CD4+ T lymphocyte response against a particular region in HCV E1, spanning amino acids 230-312 in HCV polyprotein, was detected in 42.8% of patients during treatment with CIGB-230. The ability of T cells to proliferate in response to mitogenic stimulation was not weakened. Most individuals (78.6%) were seroprotected after anti-hepatitis B vaccination and 42.8% were hyper-responders (antibody titers > 100 UI/ml). No anti-mitochondrial, anti-nuclear and anti-extractable nuclear antigen antibodies were generated during immunization with CIGB-230. CONCLUSIONS: Vaccination with CIGB-230 in HCV chronically-infected individuals was safe, well tolerated and did not impair the ability to respond to non-HCV antigens.

Immunization with a recombinant fowlpox virus expressing a hepatitis C virus core-E1 polyprotein variant, protects mice and African green monkeys (Chlorocebus aethiops sabaeus) against challenge with a surrogate vaccinia virus.

HCV (hepatitis C virus) is a worldwide health problem nowadays. No preventive vaccine is available against this pathogen, and therapeutic treatments currently in use have important drawbacks, including limited efficacy. In the present work a recombinant fowlpox virus, FPCoE1, expressing a truncated HCV core-E1 polyprotein, was generated. FPCoE1 virus generally failed to elicit a humoral immune response against HCV antigens in BALB/c mice. By contrast, mice inoculated with FPCoE1 elicited a positive interferon-gamma secretion response against HCV core in ex-vivo ELISPOT (enzyme-linked immunospot) assays. Remarkably, mice inoculated with FPCoE1 significantly controlled viraemia in a surrogate challenge model with vvRE, a recombinant vaccinia virus expressing HCV structural antigens. In fact, 40% of the mice had no detectable levels of vvRE in their ovaries. Administration of FPCoE1 in vervet monkeys [Chlorocebus (formerly Cercophitecus) aethiops sabaeus] induced lymphoproliferative response against HCV core and E1 proteins in 50% of immunized animals. Monkeys immunized with FPCoE1 had no detectable levels of vvRE in their blood, whereas monkeys inoculated with FP9, the negative control virus, had detectable levels of vvRE in blood up to 7 days after challenge. In conclusion, recombinant fowlpox virus FPCoE1 is able to induce an anti-HCV immune response in mice and monkeys. This ability could be rationally employed to develop effective strategies against HCV infection by using FPCoE1 in combination with other vaccine candidates or antiviral treatments.

In vitro assembly into virus-like particles is an intrinsic quality of Pichia pastoris derived HCV core protein.

Different variants of hepatitis C virus core protein (HCcAg) have proved to self-assemble in vitro into virus-like particles (VLPs). However, difficulties in obtaining purified mature HCcAg have limited these studies. In this study, a high degree of monomeric HCcAg purification was accomplished using chromatographic procedures under denaturing conditions. Size exclusion chromatography and sucrose density gradient centrifugation of renatured HCcAg (in the absence of structured RNA) under reducing conditions suggested that it assembled into empty capsids. The electron microscopy analysis of renatured HCcAg showed the presence of spherical VLPs with irregular shapes and an average diameter of 35nm. Data indicated that HCcAg monomers assembled in vitro into VLPs in the absence of structured RNA, suggesting that recombinant HCcAg used in this work contains all the information necessary for the assembly process. However, they also suggest that some cellular factors might be required for the proper in vitro assembly of capsids.

Immunization with a DNA vaccine encoding the hepatitis-C-virus structural antigens elicits a specific immune response against the capsid and envelope proteins in rabbits and Macaca irus (crab-eating macaque monkeys).

In the present study, we evaluated the capability of the plasmid pIDKE2, encoding the HCV (hepatitis C virus) structural proteins Core, E1 and E2, to induce immune response against HCV antigens after injection into rabbits and Macaca irus (crab-eating macaque). Animals were immunized intramuscularly with different amounts of plasmid on weeks 0, 3 and 8. Monkeys received a booster dose on week 46. All rabbits immunized with pIDKE2 generated a positive antibody response and, particularly in rabbits immunized with 2 mg, antibody titres reached values above 1:1500 and 1:400 against the core and the envelope proteins, respectively, 28 weeks after primary immunization. The antibody response in monkeys developed slowly, but antibody titres greater than 1:3500 against HCV structural antigens were detected at week 52. Moreover, anti-E2 antibodies recognized synthetic peptides covering the HVR-1 (hypervariable region-1) from different isolates corresponding to different genotypes. Additionally, a specific lymphoproliferative response against Core and E2 was detected in two out of three monkeys immunized with pIDKE2. The other monkey had a specific proliferative response to E1. Taking all these data together, immunization with pIDKE2 is able to elicit both humoral and cellular immunity against HCV structural antigens in animal models other than mice.

Enhancement of the immune response generated against hepatitis C virus envelope proteins after DNA vaccination with polyprotein-encoding plasmids.

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.