HPV16 E7-CT (gp96) fusion protein: Molecular cloning, expression and purification of a recombinant 6xHis-tagged protein in E. coli

The development of a therapeutic vaccine against human papillomavirus (HPV) is important for the control of cervical cancer. E7 is the major transforming protein produced in cervical cancers, and therefore represents potential tumor-specific antigen that could be the target of immunotherapy for cervical cancer. Among different vaccine strategies, protein-based vaccines are capable of generating CD8+ T cell responses in vaccinated animals and humans. Recently, development of novel strategies that enhance protein vaccine potency is important for generation of effective cancer vaccines and immunotherapies. Heat shock proteins (HSPs) including Gp96 have been shown to act as potent immuno-adjuvant to enhance antigen-specific tumor immunity. Therefore, the HSP-based protein vaccines can be administered by fusing antigens to HSPs, in vitro. It has been known that the HSP fragments (e.g., N-/or C-terminal regions) as mini-chaperones are better choice for immunization. The most straightforward method to produce large amounts of recombinant protein suitable for a vaccine is to clone the gene into a prokaryotic expression vector and produce the protein in Escherichia coli. In current study, we describe cloning of the HPV16 E7 gene linked to C-terminal fragment of gp96, identification and purification of the resultant E7-CT (gp96) fusion protein for next usage as a potential vaccine candidate protein against HPV in a pre-clinical trial. The recombinant E7-CT (gp96) migrated as a 51 kDa protein in SDS-PAGE. In Western blot experiment, the existence of a 51 kDa band for rE7-CT (gp96) was confirmed by rabbit anti-His as well as mouse anti-HPV16 E7 monoclonal antibodies. The protein of interest was both in the insoluble and the soluble fraction; therefore, purification was performed under denaturating and native conditions by affinity chromatography on Ni-NTA resin using 6xHis-tag

In Silico Analysis of Six Known Leishmania major Antigens and In Vitro Evaluation of Specific Epitopes Eliciting HLA-A2 Restricted CD8 T Cell Response

Leishmaniasis is currently a serious health as well as economic problem in underdeveloped and developing countries in Africa, Asia, the Near and Middle East, Central and South America and the Mediterranean region. Cutaneous leishmaniasis is highly endemic in Iran, remarkably in Isfahan, Fars, Khorasan, Khozestan and Kerman provinces. Since effective prevention is not available and current curative therapy is expensive, often poorly tolerated and not always effective, alternative therapies including vaccination against leishmaniasis are of priority to overcome the problem. Although Th1 dominant response is so far considered as a pre-requisite for the immune system to overcome the infection, CD8+ T cell response could also be considered as a potent arm of immune system fighting against intracellular Leishmania. Polytope vaccine strategy may open up a new way in vaccine design against leishmaniasis, since they act as a potent tool to stimulate multi-CD8 T cell responses. Clearly there is a substantial need to evaluate the promising epitopes from different proteins of Leishmania parasite species. Some new immunoinformatic tools are now available to speed up this process, and we have shown here that in silico prediction can effectively evaluate HLA class I-restricted epitopes out of Leishmania proteins

C-Terminal Domain Deletion Enhances the Protective Activity of cpa/cpb Loaded Solid Lipid Nanoparticles against Leishmania major in BALB/c Mice

Cutaneous leishmaniasis (CL) is the most common form of leishmaniasis with an annual incidence of approximately 2 million cases and is endemic in 88 countries, including Iran. CL's continued spread, along with rather ineffectual treatments and drug-resistant variants emergence has increased the need for advanced preventive strategies. We studied Type II cysteine proteinase (CPA) and Type I (CPB) with its C-terminal extension (CTE) as cocktail DNA vaccine against murine and canine leishmaniasis. However, adjuvants' success in enhancing immune responses to selected antigens led us to refocus our vaccine development programs. Herein, we discuss cationic solid lipid nanoparticles' (cSLN) ability to improve vaccine-induced protective efficacy against CL and subsequent lesion size and parasite load reduction in BALB/c mice. For this work, we evaluated five different conventional as well as novel parasite detection techniques, i.e., footpad imaging, footpad flowcytometry and lymph node flowcytometry for disease progression assessments. Vaccination with cSLN-cpa/cpb-CTE formulation showed highest parasite inhibition at 3-month post vaccination. Immunized mice showed reduced IL-5 level and significant IFN-ã increase, compared to control groups. We think our study represents a potential future and a major step forward in vaccine development against leishmaniasis

Antibiotic-Free Nanoplasmids as Promising Alternatives for Conventional DNA Vectors

DNA vaccines with their extraordinary properties are the best choice as vectors for subunit vaccines but are not in compliance with safety regulations, mainly because of the antibiotic resistance genes on their backbone. New generations of plasmids with minimum bacterial backbones are now developed as promising alternatives to pass the safety rules and be replaced for conventional plasmids. Here we have compared the nanoplasmid (with RNA-out selection system and professional HTLV-1 containing promoter) and the conventionally used pcDNA plasmid, as regards the transfection efficiency. The EGFP gene was cloned in both pcDNA-3.1+ and NTC9385R-MSC and transfected into COS-7 cells for expression evaluation by flow cytometry. Meanwhile, qPCR was used to analyze the EGFP mRNA copy numbers. It was concluded that the nanoplasmid, with its extraordinary properties, can be a tempting alternative to conventional pcDNA in equal or equimolar concentrations for vaccine design. These promising results can put DNA vaccines back into focus, especially regarding diseases controlled by robust cellular immune responses

Anti-leishmanial activity of Brevinin 2R and its Lauric acid conjugate type against L. major: In vitro mechanism of actions and in vivo treatment potentials.

Leishmaniasis, as a major health problem in tropical and sub-tropical areas in the world, needs novel, safe, nontoxic and plausible therapeutic solutions for its control. As a part of innate immune system, natural antimicrobial peptides have a potential to be used as new generation of antibiotics especially after persistent resistance of conventional antimicrobial agents. Brevinin 2R, a member of Defensin families of host defense peptides, showed promising effects against bacterial and fungal infections as well as cancerous cell lines. In the current research, the anti-leishmanial effect of Brevinin 2R and its lauric acid conjugate was investigated against Leishmania major (L. major) parasite. The data revealed that, conjugation of fatty acid to Brevinin 2R, strengthen its effect on L. major promastigotes as well as toxicity and hemolytic effect. These peptides showed anitleishmanial activity through cell membrane disruption and changes in the electrical and mitochondrial membrane potential. No signs of apoptosis induction or caspase activation were detected. Despite its hemolytic and cytotoxic effect in in vitro conditions, lauric acid- Brevinin 2R (L- Brevinin 2R) did not show site specific adverse reactions in animal model. Treatment course with L- Brevinin 2R in the L. major infected mice exhibited decreased parasite load in the lymph nodes adjacent to the infected site despite cytokine production profile and footpad swelling data