Prime editing in hematopoietic stem cells—From ex vivo to in vivo CRISPR-based treatment of blood disorders

Abstract: Prime editing of human hematopoietic stem cells has the potential to become a safe and efficient way of treating diseases of the blood directly in patients. By allowing site-targeted gene intervention without homology-directed repair donor templates and DNA double-stranded breaks, the invention of prime editing fuels the exploration of alternatives to conventional recombination-based ex vivo genome editing of hematopoietic stem cells. Prime editing is as close as we get today to a true genome editing drug that… Show more

“…The synergistic activation of p53 observed in HSPCs exposed to G-CSF and CRISPR-Cas9 RNPs is analogous to the enhanced p53 stimulation previously reported when HSPC gene editing was performed in conjunction with transduction of AAV6 DNA donor template delivery vectors [10][11][12] . In the future, it will be important to ascertain the impact of post-transplant G-CSF on human HSPCs subjected to emerging gene correction technologies that do not rely on DSB formation (i.e., base editing [38][39][40] and prime editing [40][41][42][43] ) or are independent of the cellular DDR (i.e., recombinases 40,[44][45][46][47] and RNA-guided transposon systems 40,47 ). Globally, our findings further expand the body of evidence delineating p53 as a central hub in a molecular network orchestrating a variety of DDR pathways, including cell cycle checkpoints, apoptosis and immune responses.…”

Post-Transplant Administration of G-CSF Impedes Engraftment of Gene Edited Human Hematopoietic Stem Cells by Exacerbating the p53-Mediated DNA Damage Response

“…The synergistic activation of p53 observed in HSPCs exposed to G-CSF and CRISPR-Cas9 RNPs is analogous to the enhanced p53 stimulation previously reported when HSPC gene editing was performed in conjunction with transduction of AAV6 DNA donor template delivery vectors [10][11][12] . In the future, it will be important to ascertain the impact of post-transplant G-CSF on human HSPCs subjected to emerging gene correction technologies that do not rely on DSB formation (i.e., base editing [38][39][40] and prime editing [40][41][42][43] ) or are independent of the cellular DDR (i.e., recombinases 40,[44][45][46][47] and RNA-guided transposon systems 40,47 ). Globally, our findings further expand the body of evidence delineating p53 as a central hub in a molecular network orchestrating a variety of DDR pathways, including cell cycle checkpoints, apoptosis and immune responses.…”

Post-Transplant Administration of G-CSF Impedes Engraftment of Gene Edited Human Hematopoietic Stem Cells by Exacerbating the p53-Mediated DNA Damage Response

CRISPR-based precision medicine for hematologic disorders: Advancements, challenges, and prospects

Post-transplant G-CSF impedes engraftment of gene-edited human hematopoietic stem cells by exacerbating p53-mediated DNA damage response