Neuronal DNA repair reveals strategies to influence CRISPR editing outcomes

Gokul N. Ramadoss; Samali J. Namaganda; Jennifer Hamilton; Rohit Sharma; Karena G. Chow; Bria L Macklin; Mengyuan Sun; Jiacheng Liu; Christof Fellmann; Hannah L. Watry; Julianne Jin; Barbara S. Perez; Cindy R. Sandoval Espinoza; Madeline Matia; Serena H Lu; Luke M. Judge; André Nussenzweig; Britt Adamson; Niren Murthy; Jennifer A. Doudna; Martin Kampmann; Bruce R. Conklin

doi:10.1101/2024.06.25.600517

Neuronal DNA repair reveals strategies to influence CRISPR editing outcomes

Gokul N. Ramadoss(Gladstone Institutes), Samali J. Namaganda(Gladstone Institutes), Jennifer Hamilton(Innovative Genomics Institute), Rohit Sharma(Innovative Genomics Institute), Karena G. Chow(Gladstone Institutes), Bria L Macklin(Gladstone Institutes), Mengyuan Sun(Gladstone Institutes), Jiacheng Liu(National Cancer Institute), Christof Fellmann(Gladstone Institutes), Hannah L. Watry(Gladstone Institutes), Julianne Jin(University of California, San Francisco), Barbara S. Perez(Innovative Genomics Institute), Cindy R. Sandoval Espinoza(Innovative Genomics Institute), Madeline Matia(Gladstone Institutes), Serena H Lu(Gladstone Institutes), Luke M. Judge(Gladstone Institutes), André Nussenzweig(National Cancer Institute), Britt Adamson(Princeton University), Niren Murthy(Innovative Genomics Institute), Jennifer A. Doudna(QB3), Martin Kampmann(University of California, San Francisco), Bruce R. Conklin(Gladstone Institutes)

bioRxiv (Cold Spring Harbor Laboratory)

June 26, 2024

10.1101/2024.06.25.600517

Cited by 14Open Access

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Abstract

Genome editing is poised to revolutionize treatment of genetic diseases, but poor understanding and control of DNA repair outcomes hinders its therapeutic potential. DNA repair is especially understudied in nondividing cells like neurons, which must withstand decades of DNA damage without replicating. This lack of knowledge limits the efficiency and precision of genome editing in clinically relevant cells. To address this, we used induced pluripotent stem cells (iPSCs) and iPSC-derived neurons to examine how postmitotic human neurons repair Cas9-induced DNA damage. We discovered that neurons can take weeks to fully resolve this damage, compared to just days in isogenic iPSCs. Furthermore, Cas9-treated neurons upregulated unexpected DNA repair genes, including factors canonically associated with replication. Manipulating this response with chemical or genetic perturbations allowed us to direct neuronal repair toward desired editing outcomes. By studying DNA repair in postmitotic human cells, we uncovered unforeseen challenges and opportunities for precise therapeutic editing.

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