Frequent aneuploidy in primary human T cells after CRISPR–Cas9 cleavage

Nahmad, Alessio D.; Reuveni, Eli; Goldschmidt, Ella; Tenne, Tamar; Liberman, Meytal; Horovitz-Fried, Miriam; Khosravi, Rami; Kobo, Hila; Reinstein, Eyal; Madi, Asaf; Ben‐David, Uri; Barzel, Adi

doi:10.1038/s41587-022-01377-0

Cited by 113 publications

(86 citation statements)

References 50 publications

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“…Still, this risk will require additional monitoring when translated to clinical manufacturing procedures. 55 Such concerns would be especially relevant for any multiplexed editing design (e.g., VFC-CAR with simultaneous PD-1 knockout). Finally, additional work to track changes to phenotype over the course of manufacture, and at various time points in vivo , could further elucidate the nuances of cytotoxicity dynamics in RV-CAR products, TRAC -CAR products, and VFC-CAR products targeting other genomic insertion sites.…”

Section: Discussionmentioning

confidence: 99%

Production and characterization of virus-free, CRISPR-CAR T cells capable of inducing solid tumor regression

Mueller

Piscopo

Forsberg

et al. 2022

J Immunother Cancer

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BackgroundChimeric antigen receptor (CAR) T cells have demonstrated high clinical response rates against hematological malignancies (e.g., CD19+ cancers) but have shown limited activity in patients with solid tumors. Recent work showed that precise insertion of a CAR at a defined locus improves treatment outcomes in the context of a CD19 CAR; however, it is unclear if such a strategy could also affect outcomes in solid tumors. Furthermore, CAR manufacturing generally relies on viral vectors for gene delivery, which comprise a complex and resource-intensive part of the manufacturing supply chain.MethodsAnti-GD2 CAR T cells were generated using CRISPR/Cas9 within 9 days using recombinant Cas9 protein and nucleic acids, without any viral vectors. The CAR was specifically targeted to the T cell receptor alpha constant gene (TRAC). T cell products were characterized at the level of the genome, transcriptome, proteome, and secretome using CHANGE-seq, targeted next-generation sequencing, scRNA-seq, spectral cytometry, and ELISA assays, respectively. Functionality was evaluated in vivo in an NSG™ xenograft neuroblastoma model.ResultsIn comparison to retroviral CAR T cells, virus-free CRISPR CAR (VFC-CAR) T cells exhibit TRAC-targeted genomic integration of the CAR transgene, elevation of transcriptional and protein characteristics associated with a memory-like phenotype, and low tonic signaling prior to infusion arising in part from the knockout of the T cell receptor. On exposure to the GD2 target antigen, anti-GD2 VFC-CAR T cells exhibit specific cytotoxicity against GD2+ cells in vitro and induce solid tumor regression in vivo. VFC-CAR T cells demonstrate robust homing and persistence and decreased exhaustion relative to retroviral CAR T cells against a human neuroblastoma xenograft model.ConclusionsThis study leverages virus-free genome editing technology to generate CAR T cells featuring a TRAC-targeted CAR, which could inform manufacturing of CAR T cells to treat cancers, including solid tumors.

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Section: Discussionmentioning

confidence: 99%

Production and characterization of virus-free, CRISPR-CAR T cells capable of inducing solid tumor regression

Mueller

Piscopo

Forsberg

et al. 2022

J Immunother Cancer

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“…Until now, investigation of the potential source of genotoxicity during gene editing mainly focused on off-target nuclease activity and the occurrence of genomic rearrangements at the target site ( Adikusuma et al., 2018 ; Boutin et al., 2021 ; Kosicki et al., 2018 ; Lattanzi et al., 2021 ; Leibowitz et al., 2021 ; Nahmad et al., 2022 ; Turchiano et al., 2021 ). The genotoxic risk ascribed to DNA template delivery, its persistence, and its integration in edited cells ( Colella et al., 2018 ; Penaud-Budloo et al., 2018 ; Schnödt and Büning, 2017 ) remains poorly investigated, especially for HSPCs.…”

Section: Introductionmentioning

confidence: 99%

Choice of template delivery mitigates the genotoxic risk and adverse impact of editing in human hematopoietic stem cells

et al. 2022

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“…While the off-target detection methods described above are most useful for identifying localized effects of DNA double-strand breaks (DSBs), larger scale off-target effects have been observed. These include gross chromosomal rearrangements such as translocations ( Bothmer et al, 2020 ; Stadtmauer et al, 2020 ; Samuelson et al, 2021 ), chromothripsis ( Leibowitz et al, 2021 ), and aneuploidy ( Amendola et al, 2022 ; Nahmad et al, 2022 ). Translocation events most often occur as a consequence of: 1) on-target cleavage and recombination with a homologous region of the genome ( Turchiano et al, 2021 ); 2) simultaneous cleavage at an on-target and off-target sequence ( Lattanzi et al, 2021 ); or 3) following multiple on-target cleavage events in multiplexed editing workflows ( Qasim et al, 2017 ; Bothmer et al, 2020 ; Stadtmauer et al, 2020 ; Samuelson et al, 2021 ; Diorio et al, 2022 ).…”

Section: Introductionmentioning

confidence: 99%

CRISPR nuclease off-target activity and mitigation strategies

Wienert¹,

Cromer

2022

Front. Genome Ed.

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The discovery of CRISPR has allowed site-specific genomic modification to become a reality and this technology is now being applied in a number of human clinical trials. While this technology has demonstrated impressive efficacy in the clinic to date, there remains the potential for unintended on- and off-target effects of CRISPR nuclease activity. A variety of in silico-based prediction tools and empirically derived experimental methods have been developed to identify the most common unintended effect—small insertions and deletions at genomic sites with homology to the guide RNA. However, large-scale aberrations have recently been reported such as translocations, inversions, deletions, and even chromothripsis. These are more difficult to detect using current workflows indicating a major unmet need in the field. In this review we summarize potential sequencing-based solutions that may be able to detect these large-scale effects even at low frequencies of occurrence. In addition, many of the current clinical trials using CRISPR involve ex vivo isolation of a patient’s own stem cells, modification, and re-transplantation. However, there is growing interest in direct, in vivo delivery of genome editing tools. While this strategy has the potential to address disease in cell types that are not amenable to ex vivo manipulation, in vivo editing has only one desired outcome—on-target editing in the cell type of interest. CRISPR activity in unintended cell types (both on- and off-target) is therefore a major safety as well as ethical concern in tissues that could enable germline transmission. In this review, we have summarized the strengths and weaknesses of current editing and delivery tools and potential improvements to off-target and off-tissue CRISPR activity detection. We have also outlined potential mitigation strategies that will ensure that the safety of CRISPR keeps pace with efficacy, a necessary requirement if this technology is to realize its full translational potential.

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Frequent aneuploidy in primary human T cells after CRISPR–Cas9 cleavage

Cited by 113 publications

References 50 publications

Production and characterization of virus-free, CRISPR-CAR T cells capable of inducing solid tumor regression

Production and characterization of virus-free, CRISPR-CAR T cells capable of inducing solid tumor regression

Choice of template delivery mitigates the genotoxic risk and adverse impact of editing in human hematopoietic stem cells

CRISPR nuclease off-target activity and mitigation strategies

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