Efficiency of SpCas9 and AsCpf1 (Cas12a) programmable nucleases at genomic safe harbor loci in HEK293 cells

Rationale: The development of eukaryote genome engineering tools based on CRISPR-Cas programmable bacterial nucleases systems opens wide horizons for gene therapies, human disease cell modeling, as well as investigation into manifestation of disease phenotypes and visualization of cellular processes. The safety and approximation of experiments both at the cellular and organismal levels depend on the accuracy of introducing double-stranded breaks into the target DNA regions. The search for new variants of more accurate CRISPR-Cas nucleases and evaluation of their ability to hydrolyze nucleosome DNA in vivo is considered a critical task for the development of the genome engineering technologies.Aim: To analyze the activity of the programmable nuclease AsCpf1 (Cas12a), with low level of off-target activity, in the human genome loci that are safe for the introduction of transgenic constructs (“safe harbor”) and to compare its efficiency with that of the widely used SpCas9 nuclease in HEK293 cells.Materials and methods: We performed the bioinformatics analysis of the association between target regions with nucleosomes and other proteins in the safe harbor loci AAVS1 and GSH-Ch1 and the transcriptionally inactive gene MYBPC3 (cardiac myosin binding protein 3) based on ATAC-seq data for the HEK293FT cells obtained from the NCBI SRA database. Plasmids encoding SpCas9 and AsCpf1 nucleases and guide RNA to the target regions were constructed and transfected into the HEK293FT cells. Events in the target regions of the HEK293FT cell genome were studied in the sequenograms with the TIDE algorithm.Results: The results of the ATAC-seq experiments for HEK293FT cells have shown that the AAVS1 locus can be referred as open chromatin with a low nucleosome density, while the GSH-Ch1 locus can be attributed to closed chromatin. In HEK293FT cells, the cardiac MYBPC3 gene has intermediate chromatin density. Assessment of the efficiency of introducing breaks into the studied HEK293FT cell chromatin loci by nucleases has shown that SpCas9 is able to cope with chromatin of any nucleosome density, while AsCpf1 can effectively introduce DNA breaks only at loci with open chromatin, such as AAVS1 and MYBPC3. Editing events occur at a very low rate at the GSH-Ch1 locus with a high nucleosome density.Conclusion: We have found low efficiency of the AsCpf1 nuclease in the genomic safe harbor locus GSH-Ch1, which is characterized by a high nucleosome density. When planning an experiment on AsCpf1 nuclease genome editing, the epigenetic chromatin landscape and the nucleosome density should be considered, as well as chromatin opening substances should be used.

Design, Synthesis, and Biological Investigation of Novel Classes of 3-Carene-Derived Potent Inhibitors of TDP1

Two novel structural types of tyrosyl-DNA phosphodiesterase 1 (TDP1) inhibitors with hexahydroisobenzofuran 11 and 3-oxabicyclo [3.3.1]nonane 12 scaffolds were discovered. These monoterpene-derived compounds were synthesized through preliminary isomerization of (+)-3-carene to (+)-2-carene followed by reaction with heteroaromatic aldehydes. All the compounds inhibit the TDP1 enzyme at micro- and submicromolar levels, with the most potent compound having an IC50 value of 0.65 μM. TDP1 is an important DNA repair enzyme and a promising target for the development of new chemosensitizing agents. A panel of isogenic clones of the HEK293FT cell line knockout for the TDP1 gene was created using the CRISPR-Cas9 system. Cytotoxic effects of topotecan (Tpc) and non-cytotoxic compounds of the new structures were investigated separately and jointly in the TDP1 gene knockout cells. For two TDP1 inhibitors, 11h and 12k, a synergistic effect was observed with Tpc in the HEK293FT cells but was not found in TDP1 −/− cells. Thus, it is likely that the synergistic effect is caused by inhibition of TDP1. Synergy was also found for 11h in other cancer cell lines. Thus, sensitizing cancer cells using a non-cytotoxic drug can enhance the efficacy of currently used pharmaceuticals and, concomitantly, reduce toxic side effects.