Sergei I. Bazhan

Rational design based synthetic polyepitope DNA vaccine for eliciting HIV-specific CD8+ T cell responses

Advances in defining HIV-1 CD8+ T cell epitopes and understanding endogenous MHC class I antigen processing enable the rational design of polyepitope vaccines for eliciting broadly targeted CD8+ T cell responses to HIV-1. Here we describe the construction and comparison of experimental DNA vaccines consisting of ten selected HLA-A2 epitopes from the major HIV-1 antigens Env, Gag, Pol, Nef, and Vpr. The immunogenicity of designed gene constructs was assessed after double DNA prime, single vaccinia virus boost immunization of HLA-A2 transgenic mice. We compared a number of parameters including different strategies for fusing ubiquitin to the polyepitope and including spacer sequences between epitopes to optimize proteasome liberation and TAP transport. It was demonstrated that the vaccine construct that induced in vitro the largest number of [peptide-MHC class I] complexes was also the most immunogenic in the animal experiments. This most immunogenic vaccine construct contained the N-terminal ubiquitin for targeting the polyepitope to the proteasome and included both proteasome liberation and TAP transport optimized spacer sequences that flanked the epitopes within the polyepitope construct. The immunogenicity of determinants was strictly related to their affinities for HLA-A2. Our finding supports the concept of rational vaccine design based on detailed knowledge of antigen processing.

Novel approaches in polyepitope T-cell vaccine development against HIV-1

RV144 clinical trial was modestly effective in preventing HIV infection. New alternative approaches are needed to design improved HIV-1 vaccines and their delivery strategies. One of these approaches is construction of synthetic polyepitope HIV-1 immunogen using protective T- and B-cell epitopes that can induce broadly neutralizing antibodies and responses of cytotoxic (CD8+ CTL) and helpers (CD4+ Th) T-lymphocytes. This approach seems to be promising for designing of new generation of vaccines against HIV-1, enables in theory to cope with HIV-1 antigenic variability, focuses immune responses on protective determinants and enables to exclude from the vaccine compound that can induce autoantibodies or antibodies enhancing HIV-1 infectivity. Herein, the authors will focus on construction and rational design of polyepitope T-cell HIV-1 immunogens and their delivery, including: advantages and disadvantages of existing T-cell epitope prediction methods; features of organization of polyepitope immunogens, which can generate high-level CD8+ and CD4+ T-lymphocyte responses; the strategies to optimize efficient processing, presentation and immunogenicity of polyepitope constructs; original software to design polyepitope immunogens; and delivery vectors as well as mucosal strategies of vaccination. This new knowledge may bring us a one step closer to developing an effective T-cell vaccine against HIV-1, other chronic viral infections and cancer.

Mathematical model of the Tat-Rev regulation of HIV-1 replication in an activated cell predicts the existence of oscillatory dynamics in the synthesis of viral components

BackgroundThe life cycle of human immunodeficiency virus type-1 (HIV-1) makes possible the realization of regulatory strategies that can lead to complex dynamical behavior of the system. We analyze the strategy which is based on two feedback mechanisms, one mediating a positive regulation of the virus replication by Tat protein via the antitermination of the genomic RNAs transcription on TAR (transactivation responsive) element of the proviral DNA and the second mechanism providing a negative regulation of the splicing of the full-length (9 kb) RNAs and incompletely spliced (4 kb) RNAs via their transport from the nucleus to the cytoplasm. Although the existence of these two regulatory feedback loops has been considered in other mathematical models, none of them examined the conditions for the emergence of complex oscillatory patterns in the intracellular dynamics of viral components.ResultsWe developed a mechanistic mathematical model for the Tat-Rev mediated regulation of HIV-1 replication, which considers the activation of proviral DNA transcription, the Tat-specific antitermination of transcription on TAR-element, resulting in the synthesis of the full-length 9 kb RNA, the splicing of the 9 kb RNA down to the 4 kb RNA and the 4 kb RNA to 2 kb RNA, the transport of 2 kb mRNAs from the nucleus to the cytoplasm by the intracellular mechanisms, the multiple binding of the Rev protein to RRE (Rev Response Element) sites on 9 kb and 4 kb RNA resulting in their export to the cytoplasm and the synthesis of Tat and Rev proteins in the cytoplasm followed by their transport into the nucleus. The degradation of all viral proteins and RNAs both in the cytoplasm and the nucleus is described. The model parameters values were derived from the published literature data. The model was used to examine the dynamics of the synthesis of the viral proteins Tat and Rev, the mRNAs under the intracellular conditions specific for activated HIV-1 infected macrophages. In addition, we analyzed alternative hypotheses for the re-cycling of the Rev proteins both in the cytoplasm and the nuclear pore complex.ConclusionsThe quantitative mathematical model of the Tat-Rev regulation of HIV-1 replication predicts the existence of oscillatory dynamics which depends on the efficacy of the Tat and TAR interaction as well as on the Rev-mediated transport processes. The biological relevance of the oscillatory regimes for the HIV-1 life cycle is discussed.

PolyCTLDesigner: a computational tool for constructing polyepitope T-cell antigens

BackgroundConstruction of artificial polyepitope antigens is one of the most promising strategies for developing more efficient and safer vaccines evoking T-cell immune responses. Epitope rearrangements and utilization of certain spacer sequences have been proven to greatly influence the immunogenicity of polyepitope constructs. However, despite numerous efforts towards constructing and evaluating artificial polyepitope immunogens as well as despite numerous computational methods elaborated to date for predicting T-cell epitopes, peptides binding to TAP and for antigen processing prediction, only a few computational tools were currently developed for rational design of polyepitope antigens.FindingsHere we present a PolyCTLDesigner program that is intended for constructing polyepitope immunogens. Given a set of either known or predicted T-cell epitopes the program selects N-terminal flanking sequences for each epitope to optimize its binding to TAP (if necessary) and joins resulting oligopeptides into a polyepitope in a way providing efficient liberation of potential epitopes by proteasomal and/or immunoproteasomal processing. And it also tries to minimize the number of non-target junctional epitopes resulting from artificial juxtaposition of target epitopes within the polyepitope. For constructing polyepitopes, PolyCTLDesigner utilizes known amino acid patterns of TAP-binding and proteasomal/immunoproteasomal cleavage specificity together with genetic algorithm and graph theory approaches. The program was implemented using Python programming language and it can be used either interactively or through scripting, which allows users familiar with Python to create custom pipelines.ConclusionsThe developed software realizes a rational approach to designing poly-CTL-epitope antigens and can be used to develop new candidate polyepitope vaccines. The current version of PolyCTLDesigner is integrated with our TEpredict program for predicting T-cell epitopes, and thus it can be used not only for constructing the polyepitope antigens based on preselected sets of T-cell epitopes, but also for predicting cytotoxic and helper T-cell epitopes within selected protein antigens. PolyCTLDesigner is freely available from the project’s web site: http://tepredict.sourceforge.net/PolyCTLDesigner.html.

Design and Evaluation of Optimized Artificial HIV-1 Poly-T Cell-Epitope Immunogens

A successful HIV vaccine in addition to induction of antibody responses should elicit effective T cell responses. Here we described possible strategies for rational design of T-cell vaccine capable to induce high levels of both CD4+ and CD8+ T- cell responses. We developed artificial HIV-1 polyepitope T-cell immunogens based on the conserved natural CD8+ and CD4+ T cell epitopes from different HIV-1 strains and restricted by the most frequent major human leukocyte antigen (HLA) alleles. Designed immunogens contain optimized core polyepitope sequence and additional “signal” sequences which increase epitope processing and presentation to CD8+ and CD4+ T-lymphocytes: N-terminal ubiquitin, N-terminal signal peptide and C-terminal tyrosine motif of LAMP-1 protein. As a result we engineered three T cell immunogens – TCI-N, TCI-N2, and TCI-N3, with different combinations of signal sequences. All designed immunogens were able to elicit HIV-specific CD4+ and CD8+ T cell responses following immunization. Attachment of either ubiquitin or ER-signal/LAMP-1 sequences increased both CD4+ and CD8+ mediated HIV-specific T cell responses in comparison with polyepitope immunogen without any additional signal sequences. Moreover, TCI-N3 polyepitope immunogen with ubiquitin generated highest magnitude of HIV-specific CD4+ and CD8+ T cell responses in our study. Obtained data suggests that attachment of signal sequences targeting polyepitope immunogens to either MHC class I or MHC class II presentation pathways may improve immunogenicity of T-cell vaccines. These results support the strategy of the rational T cell immunogen design and contribute to the development of effective HIV-1 vaccine.

Attenuated Salmonella enteritidis E23 as a vehicle for the rectal delivery of DNA vaccine coding for HIV-1 polyepitope CTL immunogen

This study is focusing on elucidation of the capacity of attenuated Salmonella enteritidis E23 (cya, crp) to serve as a vehicle for the rectal delivery of the DNA vaccine. Earlier for creation HIV‐1 candidate DNA vaccine we have designed the polyepitope protein TCI (T‐cell immunogen), which comprises over 80 CTL epitopes from subtype A, B and C HIV‐1 proteins. The gene coding for TCI protein was used to construct the eukaryotic expression plasmid pcDNA‐TCI. The attenuated S. enteritidis E23 was transformed by electroporation with recombinant plasmid pcDNA‐TCI and the expression of the TCI gene was determined in vitro and in vivo. BALB/c mice were rectally immunized with S. enteritidis E23/pcDNA‐TCI (108 cfu) twice at 4 week interval. Bacteria were not pathogenic for mice and spontaneously eliminated from mice spleen and liver to 60 days post the immunization. Detectable antibodies were generated in 2 weeks after immunization and their level increased after second immunization. The results of INF‐γ ELISpot show that mice immunized with S. enteritidis E23/pcDNA‐TCI elicited HIV‐specific cellular immune response. This study demonstrates that attenuated S. enteritidis E23 is an effective live vector for rectal delivery of the DNA vaccine pcDNA‐TCI to generate humoral and T‐cellular responses against HIV‐1.

P19-04. A synergistic effect of a combined bivalent DNA-protein anti-HIV-1 vaccine containing multiple T- and B-cell epitopes of HIV-1 proteins

Immunogenic properties of the combined vaccine CombiHIVvac, comprising polyepitope HIV-1 immunogens, one being the artificial polyepitope protein TBI, containing the T- and B-cell epitopes from Env and Gag proteins, and the DNA vaccine construct pcDNA-TCI coding for the artificial protein TCI, carrying over 80 T-cell epitopes (both CD4+ CTL and CD8+ Th) from Env, Gag, Pol, and Nef proteins, are studied in this work. The data reported demonstrate clearly that a combination of two B- and T-cell immunogens (TBI and TCI) in one construct results in a synergistic increase in the antibody response to both TBI protein and the proteins from HIV-1 lysate. The level of antibodies induced by immunization with the constructs containing either immunogen alone (TBI protein or the plasmid pcDNA-TCI) was significantly lower as compared to that induced by the combined vaccine. The analysis performed suggests that the presence of CD4+ T-helper epitopes, which can be presented by MHC class II, in the protein TCI may be the main reason underlying the increased synthesis of antibodies to TBI protein due to a CD4-mediated stimulation of B-cell proliferation and differentiation.

On the Potential for Multiscale Oscillatory Behavior in HIV

This chapter summarizes several theoretical studies on the potential for oscillatory behavior of HIV infection at molecular and cellular levels. It discusses the biological relevance of oscillatory systems in the HIV life cycle and touches upon broader perspectives for further theoretical and experimental exploration of system dynamics. The potential interference of HIV oscillatory dynamics at different scales and levels as well as interaction and coevolution with the complex host immune system is also discussed.

Visualization of CombiHIVvac Vaccine Particles Using Electron Microscopy

Acandidate vaccine CombiHIVvac is developed; presently the clinical phase I trial has been completed successfully. CombiHIVvac combines the conserved polyepitope immunogens approaches in a novel self-adjuvanted microparticle concept. The artificial TBI (T cell and B cell immunogen) polypeptide used in the vaccine comprises epitopes from Env and Gag. The polypeptide is conjugated to dextran and mixed with DNA, which leads to formation of microparticles presenting TBI on the surface and containing the DNA inside. The DNA (pcDNA-TCI) enclosed in the microparticles codes for the TCI (T cell immunogen) polypeptide, which contains CD8 and CD4 epitopes from Env, Gag, Pol, and Nef conserved among HIV subtypes A, B, and C. The proposed technique enables the vaccine components to combine into particles on the principle of self-assembly (Fig. 1A). The conjugate molecule consists of 1 dextran molecule, 1 protein TBI molecule, and 10–15 spermidine molecules. Positively charged spermidine provides binding of the conjugate dextran/protein TBI with negatively charged DNAvaccine promoting formation of particles on the self-assembly principle. According to our estimation, the plasmid pcDNA-TCI (6,583 bp) is able to present about 100–110 dextran (60 kDa) molecules on its surfaces. For vaccine assembly, pcDNA-TCI was added to conjugate in the proportion of 1 DNA molecule:120 conjugate molecules. To prove that CombiHIVvac has actually the form of particles, we used gel filtration chromatography and atomic force microscopy. During sepharose CL-2B gel filtration, the vaccine was eluted in the volume, corresponding to 12–14 MDa size material. Experimental visualization of a theoretically predicted formation of artificial microparticles was performed with transmission electron microscopy with negative staining (1%

Results of phase I clinical trials of a combined vaccine against HIV-1 based on synthetic polyepitope immunogens

The CombiHIVvac candidate vaccine against HIV-1/AIDS containing two synthetic polyepitope immunogens such as TBI and TCI to stimulate the humoral and cellular response is described. The recombinant TBI protein is constructed as a polypeptide with predetermined tertiary structure and contains epitopes of Env and Gag proteins of HIV-1. TCI contains CD8+ CTL and CD4+ Th epitopes of the major viral proteins such as Env, Gag, Pol and Nef which are highly conserved among subtypes A, B and C of HIV-1. A gene encoding the polyepitope TCI immunogen is inserted into a pcDNA-3.1 plasmid vector. The CombiHIVvac vaccine was designed as virus-like particles containing the pcDNA-TCI plasmid in their cores (DNA vaccine) and the TBI protein conjugated with polyglucin on their surfaces. Immunogenicity and safety of CombiHIVvac has been shown in preclinical studies in several animal species. Phase I clinical trials of the vaccine have been completed and the results obtained in human volunteers confirmed that the CombiHIVvac candidate vaccine was safe and did not cause side effects, at the same time, inducing the HIV-specific humoral and cellular immune response. The phase II clinical trials have been approved by the Ministry of Health and Social Development of the Russian Federation.