DOI: 10.1177/25731599261457618 ISSN: 2573-1599

Evaluation of Prime Editing Efficiency in Human Immortalized MSC-TERT Cells with Osteogenic Potential for Modeling FGFR2 -Linked Craniosynostosis

Max Gijsbertsen, Filipa M. Duarte, Ana Fuentes Manjón, Tiany Maduro, Moustapha Kassem, John van der Oost, Irene M.J. Mathijssen, Johannes P.T.M. van Leeuwen, Jeroen van de Peppel

Craniosynostosis is a rare congenital bone condition where skull sutures fuse prematurely and is linked to mutations in over 60 genes. Generating mutation-specific in vitro models allows investigation of craniosynostosis-associated mutations without the need for patient-derived material or transgenic gene expression. Here, we developed a human in vitro disease model with the CRISPR-Cas9 prime editing variant, using an immortalized TERT-immortalized mesenchymal bone marrow-derived stem (MSC-TERT) cell line with osteogenic potential. MSC-TERT cells showed a higher resistance to prime editing, compared with HEK293FT cells. Addition of dnMLH1 and epegRNAs resulted in higher editing efficiencies in HEK293FT cells, but not in MSC-TERT cells. Prime editing efficiency varied between targeted loci and was found to be more efficient in nonadherent cells compared with adherent cells. Prime editing continued over 4 days in an isolated nonadherent HEK293FT culture. Our results present a foundation on the use of prime editing to establish FGFR2 mutation-specific in vitro models and their application in MSC-TERT cells.

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