Immunotherapeutic approaches to curtail COVID-19.

COVID-19, the disease induced by the recently emerged severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), has imposed an unpredictable burden on the world. Drug repurposing has been employed to rapidly find a cure; but despite great efforts, no drug or vaccine is presently available for treating or prevention of COVID-19. Apart from antivirals, immunotherapeutic strategies are suggested considering the role of the immune response as the host defense against the virus, and the fact that SARS-CoV-2 suppresses interferon induction as an immune evasion strategy. Active immunization through vaccines, interferon administration, passive immunotherapy by convalescent plasma or synthesized monoclonal and polyclonal antibodies, as well as immunomodulatory drugs, are different immunotherapeutic approaches that will be mentioned in this review. The focus would be on passive immunotherapeutic interventions. Interferons might be helpful in some stages. Vaccine development has been followed with unprecedented speed. Some of these vaccines have been advanced to human clinical trials. Convalescent plasma therapy is already practiced in many countries to help save the lives of severely ill patients. Different antibodies that target various steps of SARS-CoV-2 pathogenesis or the associated immune responses are also proposed. For treating the cytokine storm induced at a late stage of the disease in some patients, immune modulation through JAK inhibitors, corticosteroids, and some other cognate classes are evaluated. Given the changing pattern of cytokine induction and immune responses throughout the COVID-19 disease course, different adapted approaches are needed to help patients. Gaining more knowledge about the detailed pathogenesis of SARS-CoV-2, its interplay with the immune system, and viral-mediated responses are crucial to identify efficient preventive and therapeutic approaches. A systemic approach seems essential in this regard.

Production and Preliminary In Vivo Evaluations of a Novel in silico-designed L2-based Potential HPV Vaccine.

BACKGROUND: L2-based Human Papillomavirus (HPV) prophylactic vaccines, containing epitopes from HPV minor capsid proteins, are under investigation as second-generation HPV vaccines. No such vaccine has passed clinical trials yet, mainly due to the low immunogenicity of peptide vaccines; so efforts are being continued. A candidate vaccine composed of two HPV16 L2 epitopes, flagellin and a Toll-Like Receptor (TLR) 4 agonist (RS09) as adjuvants, and two universal T-helper epitopes was designed in silico in our previous researches. METHODS: The designed vaccine construct was expressed in E. coli BL21 (DE3) and purified through metal affinity chromatography. Following mice vaccination, blood samples underwent ELISA and flow cytometry analyses for the detection of IgG and seven Th1 and Th2 cytokines. RESULTS: Following immunization, Th1 (IFN-γ, IL-2) and Th2 (IL-4, IL-5, IL-10) type cytokines, as well as IgG, were induced significantly compared with the PBS group. Significant increases in IFN-γ, IL-2, and IL-5 levels were observed in the vaccinated group versus Freund's adjuvant group. CONCLUSION: The obtained cytokine induction profile implied both cellular and humoral responses, with a more Th-1 favored trend. However, an analysis of specific antibodies against L2 is required to confirm humoral responses. No significant elevation in inflammatory cytokines, (IL-6 and TNF-α), suggested a lack of unwanted inflammatory side effects despite using a combination of two TLR agonists. The designed construct might be capable of inducing adaptive and innate immunity; nevertheless, comprehensive immune tests were not conducted at this stage and will be a matter of future work.

A novel HPV prophylactic peptide vaccine, designed by immunoinformatics and structural vaccinology approaches.

Human papillomavirus (HPV)-caused cervical cancer is the fourth common female cancer globally. Despite availability of three effective vaccines in market, development of HPV prophylactic vaccines is still pursued due to affordability issues and type-restricted protection of the marketed vaccines. Investigational second generation prophylactic HPV vaccines are mostly exploiting epitopes from the virus minor capsid protein (L2), which despite many advantages suffer from low immunogenicity, a common problem of epitope vaccines. Adjuvants such as TLR agonists may overcome this drawback. In this study, different immunoinformatics and computational tools were employed to design a novel peptide vaccine for protection against cervical cancer. Two immunodominant epitope domains (amino acids 10-36 and 65-89) from the L2 protein of HPV 16 with potential to promote Th1, Th2, CTL, B-cell, and INF-gamma responses were selected. Flagellin, as a TLR5 agonist, a short synthetic TLR4 agonist, and two universal T-helper agonists (PADRE and TpD) were added to ensure strong induction of immune responses. Different segments were joined by proper linkers, and the physicochemical, structural, and immunological characteristics of the resultant construct were evaluated. Modeling, refinement, and validation were done to achieve a high quality 3D structure of the vaccine protein. Docking and molecular dynamics (MD) studies demonstrated an appropriate and stable interaction between the vaccine and TLR5 during the simulation period. Totally, a potential vaccine candidate with proper immunological and physicochemical properties was designed for HPV prophylaxis. The designed vaccine is expected to be capable of generating humoral and cellular responses, which are vital for protection against HPV.

Investigating CRISPR-Cas systems in Clostridium botulinum via bioinformatics tools.

The Clustered regularly interspaced short palindromic repeats (CRISPR) systems are a type of innate immunity found in some prokaryotes, which protect them against alien genetic elements by targeting foreign nucleic acids. Some other functions are also attributed to these systems. Clostridium botulinum bacteria produce botulinum neurotoxins (BoNT), one of the deadliest known toxins for humans and some animals. Food poisoning due to these bacteria is still a challenge in food industries. On the other hand, BoNT has been widely investigated for therapeutic applications including different muscle disorders. Bont genes may be located on bacterial chromosomes, plasmids, or even prophages. Generally, the genomes of Cl. botulinum show a high level of plasticity. In order to investigate the presence and characteristics of CRISPRs in these anaerobe bacteria, an in silico study on 113 CRISPR arrays identified in 38 Cl. botulinum strains was performed. A high occurrence of CRISPR arrays (80%) were found, with a remarkable frequency on plasmids. Several (CRISPR-associated) Cas proteins from different types were recognized in the studied strains, which were mostly Cas6. The CRISPR-Cas systems were identified as type I or III, but no type II. The spacers showed more homology with bacterial plasmids than phages. Active CRISPR-Cas systems can prevent the transfer of foreign genes, which may also include bont genes. This study provides the first insight into the probable roles of CRISPR-Cas systems in Cl. botulinum strains such as toxigenicity.

Harnessing self-assembled peptide nanoparticles in epitope vaccine design.

Vaccination has been one of the most successful breakthroughs in medical history. In recent years, epitope-based subunit vaccines have been introduced as a safer alternative to traditional vaccines. However, they suffer from limited immunogenicity. Nanotechnology has shown value in solving this issue. Different kinds of nanovaccines have been employed, among which virus-like nanoparticles (VLPs) and self-assembled peptide nanoparticles (SAPNs) seem very promising. Recently, SAPNs have attracted special interest due to their unique properties, including molecular specificity, biodegradability, and biocompatibility. They also resemble pathogens in terms of their size. Their multivalency allows an orderly repetitive display of antigens on their surface, which induces a stronger immune response than single immunogens. In vaccine design, SAPN self-adjuvanticity is regarded an outstanding advantage, since the use of toxic adjuvants is no longer required. SAPNs are usually composed of helical or ß-sheet secondary structures and are tailored from natural peptides or de novo structures. Flexibility in subunit selection opens the door to a wide variety of molecules with different characteristics. SAPN engineering is an emerging area, and more novel structures are expected to be generated in the future, particularly with the rapid progress in related computational tools. The aim of this review is to provide a state-of-the-art overview of self-assembled peptide nanoparticles and their use in vaccine design in recent studies. Additionally, principles for their design and the application of computational approaches to vaccine design are summarized.

Immunoinformatics analysis and in silico designing of a novel multi-epitope peptide vaccine against Staphylococcus aureus.

Staphylococcus aureus is a pathogen that causes a variety of infections in humans. Methicillin-resistant S. aureus, which is an antibiotic-resistant form, is responsible for nosocomial staphylococcal infections, whose frequency is increasing in healthy people. Thereby, the development of novel techniques is required to overcome this bacterial infection. In this context, the use of vaccines to control infections is an appropriate alternative. In this study, immunoinformatics analysis is used on three antigenic determinants as vaccine candidates, and a novel multi-epitope vaccine is designed to induce cellular, humoral, and innate immune responses against S. aureus. Alpha-enolase, clumping factor A, and iron surface determinant B were selected as the protective antigens; and phenol-soluble modulin alpha 4was applied as the adjuvant. Epitopes identification was done for each antigen using various immunoinformatics servers. Moreover, the tertiary structure of our protein vaccine was predicted and validated. Subsequently, the best-modeled protein structure was used for the refinement process. There fined model was then applied for docking studies with Toll-like receptor 2 (TLR2).In the next step, molecular dynamics (MD) simulation was used to evaluate the stability of vaccine molecule and TLR2-vaccine complex. The high ranked epitopes were selected from the mentioned antigens. The selected epitopes and the adjuvant were fused together by proper linkers. Then, the modeled protein structure was selected and validated. Validation results indicated that the initial model needs refinement. After a refinement process, the final model was generated. Finally, the best-docked model of vaccine and TLR2 complex was selected. In this research, we attempted to design an efficient subunit vaccine, which could stimulate humoral and cellular immune responses. Therefore, we expect that our designed vaccine could defeat antibiotic-resistant staphylococcal infections.

Studying the features of 57 confirmed CRISPR loci in 29 strains of Escherichia coli.

Clustered Regularly Interspaced Short Palindromic Repeats (CRISPRs) system is a novel type of innate defense system in prokaryotes for destruction of exogenous elements. To gain further insight into behavior and organization of the system, the extensive analysis of the available sequenced genomes is necessary. The dynamic nature of CRISPR loci is possibly valuable for typing and relative analyses of strains and microbial population. There are a few orderly bioinformatics investigations about the structure of CRISPR sequences in the Escherichia coli strains. In this study, 57 CRISPR loci were selected from 32 Escherichia coli strains to investigate their structural characteristics and potential functions using bioinformatics tools. Our results showed that most strains contained several loci that mainly included conserved direct repeats, while the spacers were highly variable. Moreover, RNA analysis of the sequences indicated that all loci could form stable RNA secondary structures and showed homology mostly with phages compared to plasmids. Only three strains included cas genes around their loci.