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

Isolation, characterization, and functional study of extracellular vesicles derived from Leishmania tarentolae

Leishmania (L.) species are protozoan parasites with a complex life cycle consisting of a number of developmental forms that alternate between the sand fly vector and their host. The non-pathogenic species L. tarentolae is not able to induce an active infection in a human host. It has been observed that, in pathogenic species, extracellular vesicles (EVs) could exacerbate the infection. However, so far, there is no report on the identification, isolation, and characterization of L. tarentolae EVs. In this study, we have isolated and characterized EVs from L. tarentolaeGFP+ (tEVs) along with L. majorGFP+ as a reference and positive control. The EVs secreted by these two species demonstrated similar particle size distribution (approximately 200 nm) in scanning electron microscopy and nanoparticle tracking analysis. Moreover, the said EVs showed similar protein content, and GFP and GP63 proteins were detected in both using dot blot analysis. Furthermore, we could detect Leishmania-derived GP63 protein in THP-1 cells treated with tEVs. Interestingly, we observed a significant increase in the production of IFN-γ, TNF-α, and IL-1β, while there were no significant differences in IL-6 levels in THP-1 cells treated with tEVs following an infection with L. major compared with another group of macrophages that were treated with L. major EVs prior to the infection. Another exciting observation of this study was a significant decrease in parasite load in tEV-treated Leishmania-infected macrophages. In addition, in comparison with another group of Leishmania-infected macrophages which was not exposed to any EVs, tEV managed to increase IFN-γ and decrease IL-6 and the parasite burden. In conclusion, we report for the first time that L. tarentolae can release EVs and provide evidence that tEVs are able to control the infection in human macrophages, making them a great potential platform for drug delivery, at least for parasitic infections.ISSN:2235-298