In Vitro Model of Suppression of the Alloantigen Response by Tolerogenic Dendritic Cells Transfected with Personalized DNA Constructs Encoding HLA Epitopes.

BACKGROUND: A search for efficient graft rejection modulation techniques for the promotion of durable engraftment remains to be a matter of close study all over the world. Despite the variety of immunosuppressive drugs, the schemes currently used show a lack of selectivity and have a number of side effects. Here we investigated an approach for the induction of antigen-specific tolerance in a human "stimulator-responder" model in vitro, using dendritic cells (DCs) transfected with designed DNA constructs encoding the stimulator's major histocompatibility complex (MHC) epitopes. METHODS: The object of the study is peripheral blood mononuclear cells (PBMCs) from 10 healthy donors. To induce antigen-specific tolerance, personalized DNA constructs were created for five responder-stimulator pairs, based on the sequences of donors' and recipients' MHCs. DNA sequencing was performed to select epitopes for incorporation into genetic constructs. A mixed lymphocyte culture assay was used (i) to assess the proliferative response in both directions for all possible stimulator-responder pairs (90 reactions) and (ii) to assess the tolerogenic properties of the generated transfected DCs (5 reactions). RESULTS: A significant increase in the amounts of FoxP3+ CD4+CD25+ cells and in IL-10 production was shown in culture of donor mononuclear cells after co-cultivation with the responder's dendritic cells transfected with donor-specific plasmids. The tolerogenic cultures generated using tolerogenic DCs transfected with MHC epitopes had a significantly greater ability to inhibit the proliferation of autologous MNCs in response to an allogeneic MHC stimulus. CONCLUSIONS: The produced DCs transfected with DNA constructs against HLA stimulating epitopes exhibited tolerogenic properties and may be used to develop antigen-specific tolerance. Thus, we proposed a perspective approach to the induction of antigen-specific tolerance, which should subsequently be studied for use in clinical practice.

Dendritic Cells Transfected with MHC Antigenic Determinants of CBA Mice Induce Antigen-Specific Tolerance in C57Bl/6 Mice.

BACKGROUND: Nonspecific immunosuppressive therapy for graft rejection and graft-versus-host disease (GVHD) is often accompanied by severe side effects such as opportunistic infections and cancers. Several approaches have been developed to suppress transplantation reactions using tolerogenic cells, including induction of FoxP3+ Tregs with antigen-loaded dendritic cells (DCs) and induction of CD4+IL-10+ cells with interleukin IL-10-producing DCs. Here, we assessed the effectiveness of both approaches in the suppression of graft rejection and GVHD. METHODS: IL-10-producing DCs were generated by the transfection of DCs with DNA constructs encoding mouse IL-10. Antigen-loaded DCs from C57BL/6 mice were generated by transfection with DNA constructs encoding antigenic determinants from the H2 locus of CBA mice which differ from the homologous antigenic determinants of C57BL/6 mice. RESULTS: We found that both IL-10-producing DCs and antigen-loaded immature DCs could suppress graft rejection and GVHD but through distinct nonspecific and antigen-specific mechanisms, respectively. Discussion. We provide data that the novel approach for DCs antigen loading using DNA constructs encoding distinct homologous determinants derived from major histocompatibility complex genes is effective in antigen-specific suppression of transplantation reactions. Such an approach eliminates the necessity of donor material use and may be useful in immunosuppressive therapy side effects prevention.

Genotyping of hepatitis B and C virus Russian isolates for reference serum panel construction.

Approximately 2% and 5% of the world human population is estimated to be infected with HCV and HBV, respectively. Reference panels of HCV and HBV serum samples with defined genotypes and serotypes is necessary for monitoring of the specificity and sensitivity of diagnostic test kits. The aim of this study was to determine genotypes/serotypes of HBV and HCV circulating in Russia in order to construct a panel of reference sera containing these HCV genotypes and HBV serotypes. A total of 343 HBsAg-positive and 207 anti-HCV positive serum samples were collected from patients with HBV and HCV infection from different cities between years 2002 and 2010 in St. Petersburg, Krasnodar, Nizhny Novgorod, Novosibirsk, Barnaul, Gorno-Altaisk, and Khabarovsk. HBV DNA was found in 76.4% of HBsAg positive samples by PCR for the S gene and HCV RNA was found in 71.5, 70.0, and 64.7% of anti-HCV positive samples in the 5'UTR, Core, and NS5B regions, respectively. The prevalence and proportion of HBV genotype/serotype associations were as follows: A/adw2, 2.1%; D/ayw2, 54.0%; D/ayw3, 43.1%; D/adw2, 0.7%. A new combination of genotype D and adw2 serotype was discovered. The distribution of HCV genotypes was the following: 43.6%, b; 3.8%, 2a; and 52.6%, 3a. Russian National reference panels of HBV and HCV lyophilized sera were developed to monitor specificity and sensitivity of approved kits and for the certification of newly developed assays.

Exclusion of HIV epitopes shared with human proteins is prerequisite for designing safer AIDS vaccines.

BACKGROUND: The safety of a potential AIDS vaccine is an issue that will become critical at later stages of product development and needs to be addressed before it is too late. OBJECTIVE: In order to design safer vaccine, the HIV antigens, to be deployed in it, should be free of regions that are either present in human proteins or exhibit pronounced structural similarity to proteins responsible for important physiological functions. STUDY DESIGN: The approach is based on the use of an original matrix predicting the antigenic similarity of amino acids. This mathematical approach developed by us was applied for identification of fragments with similarity to human proteins within potentially immunodominant regions of HIV proteins. A potential self-sensitization by viral quasispecies with variants of hypervariable V3 region, generated as a result of immune pressure on the immunodominant region of envelope, was considered in detail. RESULTS: Viral fragments occurring in normal human proteins as well as regions exhibiting high similarity to proteins responsible for physiological homeostasis were identified in every HIV protein at a frequency higher than expected. Most such regions contained either T-cell (CD8(+) CTL or CD4(+) Helper) or B-cell epitopes, or both of them simultaneously. The gained knowledge was applied in designing a synthetic immunogen containing multiple CTL epitopes. The synthesis of series of chimeric peptides representing hypervariable region of V3 loop of HIV envelope, to be used as a multi-epitope or mixotope vaccine candidate, has been achieved. Such a vaccine could theoretically pre-empt any escape mutant borrowing from antigenic diversity of hypervariable region of V3 loop of HIV envelope. CONCLUSIONS: The epitopes shared by HIV and its host are likely to be implicated in the immunopathogenesis of AIDS through induction of cross-reacting effectors of the immune system. The prospect that 'house-keeping' immune mechanism can be foiled by molecular mimicry of HIV with physiologically important human proteins should be taken into consideration in safer vaccine design.