Optimization in the expression of ASFV proteins for the development of subunit vaccines using poxviruses as delivery vectors

African swine fever virus (ASFV) causes a highly contagious hemorrhagic disease that affects domestic pig and Eurasian wild boar populations. To date, no safe and efficacious treatment or vaccine against ASF is available. Nevertheless, there are several reports of protection elicited by experimental vaccines based on live attenuated ASFV and some levels of protection and reduced viremia in other approaches such as DNA, adenovirus, baculovirus, and vaccinia-based vaccines. Current ASF subunit vaccine research focuses mainly on delivering protective antigens and antigen discovery within the ASFV genome. However, due to the complex nature of ASFV, expression vectors need to be optimized to improve their immunogenicity. Therefore, in the present study, we constructed several recombinant MVA vectors to evaluate the efficiency of different promoters and secretory signal sequences in the expression and immunogenicity of the p30 protein from ASFV. Overall, the natural poxvirus PrMVA13.5L promoter induced high levels of both p30 mRNA and specific anti-p30 antibodies in mice. In contrast, the synthetic PrS5E promoter and the S E/L promoter linked to a secretory signal showed lower mRNA levels and antibodies. These findings indicate that promoter selection may be as crucial as the antigen used to develop ASFV subunit vaccines using MVA as the delivery vector.

A Mycobacterium tuberculosis-specific subunit vaccine that provides synergistic immunity upon co-administration with Bacillus Calmette-Guérin

Given the encouraging clinical results of both candidate subunit vaccines and revaccination with Bacillus Calmette-Guérin (BCG) against tuberculosis (TB), there is support for combining BCG and subunit vaccination for increased efficacy. BCG and Mycobacterium tuberculosis (Mtb) share ~98% of their genome and current subunit vaccines are almost exclusively designed as BCG boosters. The goal of this study is to design a TB subunit vaccine composed of antigens not shared with BCG and explore the advantages of this design in a BCG + subunit co-administration vaccine strategy. Eight protective antigens are selected to create an Mtb-specific subunit vaccine, named H107. Whereas traditional vaccines containing BCG-shared antigens exhibit in vivo cross-reactivity to BCG, H107 shows no cross-reactivity and does not inhibit BCG colonization. Instead, co-administering H107 with BCG leads to increased adaptive responses against both H107 and BCG. Importantly, rather than expanding BCG-primed T cells, H107 broadens the overall vaccine repertoire with new T cell clones and introduces ‘adjuvant-imprinted’ qualities including Th17 responses and less-differentiated Th1 cells. Collectively, these features of H107 are associated with a substantial increase in long-term protection.

Synthesis of silymarin−selenium nanoparticle conjugate and examination of its biological activity in vitro

Silymarin (Sil) was conjugated to selenium nanoparticles (SeNPs) to increase Sil bioavailability. The conjugates were monodisperse; the average diameter of the native SeNPs was ~ 20-50 ± 1.5 nm, whereas that of the conjugates was 30-50 ± 0.5 nm. The use of SeNPs to increase the bioavailability of Syl was examined with the MH-22a, EPNT-5, HeLa, Hep-2, and SPEV-2 cell lines. The EPNT-5 (glioblastoma) cells were the most sensitive to the conjugates compared to the conjugate-free control. The conjugates increased the activity of cellular dehydrogenases and promoted the penetration of Sil into the intracellular space. Possibly, SeNPs play the main part in Sil penetration of cells and Sil penetration is not associated with phagocytosis. Thus, SeNPs are promising for use as a Sil carrier and as protective antigens.

Prospects for improving immunoprophylaxis of infectious diseases

This study described the perspective and significance of using complex vaccine systems in improving immunoprophylaxis of major infectious diseases of various etiologies and genesis. Immunobiological drugs traditionally used for this purpose, along with the advantages, have disadvantages, such as increased reactogenicity and development of post-vaccine reactions and complications in some cases. Such adverse effects are serious obstacles to immunoprophylaxis on a mass scale. This circumstance was the reason for the improvement of immunoprophylaxis, and the main focus was the creation of chemical, recombinant, and subunit vaccines. However, compared with traditional drugs, these vaccines have inferior effectiveness, even if they are practically reactogenic and do not lead to the development of post-vaccine reactions and complications. The main approaches to the development of effective and safe methods of immunoprophylaxis are considered based on the development of complex vaccine systems, and the components can be protective antigens, biologically active substances of the corresponding microorganisms, adjuvants applied or embedded in the corresponding biologically active, and safe biotechnological platforms. Among the latter, nanoparticles and microparticles of polylactoglycolic acid, liposomes, lipids, and copolymers are recognized as the most suitable for the construction of complex vaccine systems. This paper highlighted new trends in the development of these methods of immunoprophylaxis and their advantages in comparison with traditionally used immunobiological drugs. Moreover, prospects are characterized and examples of developed vaccine preparations are presented. The mechanisms of action of postvaccination immunity and factors that influence its formation are described.

Recent Progress in Shigella and Burkholderia Pseudomallei Vaccines

Significant advancement has been made in the development of vaccines against bacterial pathogens. However, several roadblocks have been found during the evaluation of vaccines against intracellular bacterial pathogens. Therefore, new lessons could be learned from different vaccines developed against unrelated intracellular pathogens. Bacillary dysentery and melioidosis are important causes of morbidity and mortality in developing nations, which are caused by the intracellular bacteria Shigella and Burkholderia pseudomallei, respectively. Although the mechanisms of bacterial infection, dissemination, and route of infection do not provide clues about the commonalities of the pathogenic infectious processes of these bacteria, a wide variety of vaccine platforms recently evaluated suggest that in addition to the stimulation of antibodies, identifying protective antigens and inducing T cell responses are some additional required elements to induce effective protection. In this review, we perform a comparative evaluation of recent candidate vaccines used to combat these two infectious agents, emphasizing the common strategies that can help investigators advance effective and protective vaccines to clinical trials.

Identification of Polyvalent Vaccine Candidates From Extracellular Secretory Proteins in Vibrio alginolyticus

Bacterial infections cause huge losses in aquaculture and a wide range of health issues in humans. A vaccine is the most economical, efficient, and environment-friendly agent for protecting hosts against bacterial infections. This study aimed to identify broad, cross-protective antigens from the extracellular secretory proteome of the marine bacterium Vibrio alginolyticus. Of the 69 predicted extracellular secretory proteins in its genome, 16 were randomly selected for gene cloning to construct DNA vaccines, which were used to immunize zebrafish (Danio rerio). The innate immune response genes were also investigated. Among the 16 DNA vaccines, 3 (AT730_21605, AT730_22220, and AT730_22910) were protective against V. alginolyticus infection with 47–66.7% increased survival compared to the control, while other vaccines had lower or no protective effects. Furthermore, AT730_22220, AT730_22910, and AT730_21605 also exhibited cross-immune protective effects against Pseudomonas fluorescens and/or Aeromonas hydrophila infection. Mechanisms for cross-protective ability was explored based on conserved epitopes, innate immune responses, and antibody neutralizing ability. These results indicate that AT730_21605, AT730_22220, and AT730_22910 are potential polyvalent vaccine candidates against bacterial infections. Additionally, our results suggest that the extracellular secretory proteome is an antigen pool that can be used for the identification of cross-protective immunogens.

Optimization in the Expression of ASFV Proteins for the Development of Subunit Vaccines Using Poxviruses As Delivery Vectors.

African swine fever virus (ASFV) causes a highly contagious hemorrhagic disease that affects domestic pig and Eurasian wild boar populations. To date, no safe and efficacious treatment or vaccine against ASF is available. Nevertheless, there are several reports of protection elicited by experimental vaccines based on live attenuated ASFV and some levels of protection and reduced viremia in other approaches such as DNA, adenovirus, baculovirus, and vaccinia-based vaccines. Current ASF subunit vaccine research focuses mainly on delivering protective antigens and antigen discovery within the ASFV genome. However, due to the complex nature of ASFV, expression vectors need to be optimized to improve their immunogenicity. Therefore, in the present study, we constructed several recombinant MVA vectors to evaluate the efficiency of different promoters and secretory signal sequences in the expression and immunogenicity of the p30 protein from ASFV. Overall, the natural poxvirus PrMVA13.5L promoter induced high levels of both p30 mRNA and specific anti-p30 antibodies in mice. In contrast, the synthetic PrS5E promoter and the S E/L promoter linked to a secretory signal showed lower mRNA levels and antibodies. These findings indicate that promoter selection may be as crucial as the antigen used to develop ASFV subunit vaccines using MVA as the delivery vector.

Acellular Pertussis Vaccine from Antigens of Freshly Isolated and Vaccine Strains of Bordetella pertussis with Different Genotypic Characteristics

Relevance. The development of effective and safe vaccines for pertussis prevention remains an urgent public health challenge.Aim. To study the protective activity and safety of acellular pertussis vaccine (AcPV) containing a complex of protective antigens from freshly isolated and vaccine strains of Bordetella pertussis.Materials and methods. Freshly isolated (No. 287, and No. 317) and vaccine (No. 305 and No. 475) B. pertussis strains with «non-vaccine» and «vaccine» allelic variants of the pertussis toxin (PT) subunit A gene, the PT promoter gene, the pertactin gene, the fimbria 2 gene, and the fimbria 3 gene strains were used for the production of AcPV.Results. All the studied variants of AcPV were harmless in the test of changes in the body weight of mice and sensitivity to histamine. The protective activity of AcPV3 (strains No. 287, No. 317 and No. 305) and AcPV1 (strains No. 287, No. 305 and No. 475) was higher than that of AcPV2 (strains No. 317, No. 305, and No. 475). IgG antibody titers to PT were also higher in mice immunized with AcPV1 and AcPV3.Conclusion. The higher protective activity of AcPV3 and AcPV1 may be associated with the genotype of strain No. 287, which has a ptxP3 PT promoter and is characterized by an increased level of PT production and high virulence. The most promising for further preclinical and clinical studies is AcPV3, which contains 2/3 of the antigens of the dominant «non-vaccine» genotype and 1/3 of the «vaccine» genotype, corresponding to the genes of PT, pertactin and fimbria to the currently circulating B. pertussis strains.