2 research outputs found
CRISPR/Cas9-mediated genome editing in naïve human embryonic stem cells
Get PDFThe combination of genome-edited human embryonic stem cells (hESCs) and subsequent neural differentiation is a powerful tool to study neurodevelopmental disorders. Since the naive state of pluripotency has favourable characteristics for efficient genome-editing, we optimized a workflow for the CRISPR/Cas9 system in these naive stem cells. Editing efficiencies of respectively 1.3-8.4% and 3.819% were generated with the Cas9 nuclease and the D10A Cas9 nickase mutant. Next to this, wildtype and genome-edited naive hESCs were successfully differentiated to neural progenitor cells. As a proofof- principle of our workflow, two monoclonal genome-edited naive hESCs colonies were obtained for TUNA, a long non-coding RNA involved in pluripotency and neural differentiation. In these genome-edited hESCs, an effect was seen on expression of TUNA, although not on neural differentiation potential. In conclusion, we optimized a genome-editing workflow in naive hESCs that can be used to study candidate genes involved in neural differentiation and/or functioning
