Universal Template-Assisted, Cloning-free Method for the Generation of Small RNA-Expressing Dumbbell-Shaped DNA Vectors

Dumbbell-shaped DNA minimal vectors represent genetic vectors solely composed of the gene expression cassette of interest and terminal closing loop structures. Dumbbell vectors for small hairpin RNA or microRNA expression are extremely small-sized, which is advantageous with regard to cellular delivery and nuclear diffusion. Conventional strategies for the generation of small RNA-expressing dumbbell vectors require cloning of a respective plasmid vector, which is subsequently used for dumbbell production. Here, we present a novel cloning-free method for the generation of small RNA-expressing dumbbell vectors that also does not require any restriction endonucleases. This new PCR-based method uses a universal DNA template comprising an inverted repeat of the minimal H1 promoter and the miR-30 stem. The sequences coding for small RNA expression are introduced by the PCR primers. Dumbbells are formed by denaturing and reannealing of the PCR product and are covalently closed using ssDNA ligase. The new protocol generates plus- and/or minus-strand dumbbells, both of which were shown to trigger efficient target gene knockdown. This method enables fast, cheap production of small RNA-expressing dumbbell vectors in a high throughput-compatible manner for functional genomics screens or, as dumbbells are not prone to transgene silencing, for knockdown studies in primary cells.

Advanced Design of Minimalistic Dumbbell-shaped Gene Expression Vectors

Minimal DNA vectors exclusively comprising therapeutically relevant sequences hold great promise for the development of novel therapeutic regimen. Dumbbell-shaped vectors represent non-viral non-integrating DNA minimal vectors which have entered an advanced stage of clinical development ( Hardee et al., 2017 ). Spliceable introns and DNA nuclear import signals such as SV40 enhancer sequences are molecular features that have found multiple applications in plasmid vectors to improve transgene expression. In dumbbells however, effects triggered by introns were not investigated and DNA-based nuclear import sequences have not found applications yet, presumably because dumbbell vectors have continuously been minimized with regard to size. We investigated the effects of an intron and/or SV40 enhancer derived sequences on dumbbell vector driven reporter gene expression. The implementation of a spliceable intron was found to enhance gene expression unconditionally in all investigated cell lines. Conversely, the use of the SV40 enhancer improved gene expression in a cell type-dependent manner. Though both features significantly enlarge dumbbell vector size, neither the intron nor the enhancer or a combination of both revealed a negative effect on gene expression. On the contrary, both features together improved dumbbell-driven gene expression up to 160- or 56-fold compared with plasmids or control dumbbells. Thus, it is highly recommended to consider an intron and the SV40 enhancer for dumbbell vector design. Such an advanced design can facilitate pre-clinical and clinical applications of dumbbell-shaped DNA vectors.