TRACE-Seq Reveals Clonal Reconstitution Dynamics of Gene Targeted Human Hematopoietic Stem Cells

Sharma, Rajiv P.; Dever, Daniel P.; Lee, Ciaran M.; Azizi, Armon; Pan, Yidan; Camarena, Joab; Köhnke, Thomas; Bao, Gang; Porteus, Matthew H.; Majeti, Ravindra

doi:10.1101/2020.05.25.115329

Cited by 5 publications

(7 citation statements)

References 61 publications

(70 reference statements)

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“…1F, G). The heterogeneity in the primary recipients suggests that gene-edited functional HSCs may be at low abundance, similar to the recently observed oligo-clonality of human gene-edited HSCs 20,21 . Consistent with the idea that gene editing caused some toxicity within HSCs, gene editing reduced total donor engraftment levels in competitive transplantation assays (against 1 × 10 6 whole bone marrow cells) by >30% longterm (Supplementary Fig.…”

Section: Resultssupporting

confidence: 74%

“…In particular, the heterogeneity in engraftment chimerism points toward oligoclonality in gene editing of functional HSCs. Interestingly, this has also been recently observed in human HSPC gene editing via barcoding analysis 20,21 , suggesting this is likely to become an important area for improvement as these approaches move toward the clinic. Unlike current human HSC culture conditions, we can now stably maintain mouse HSCs ex vivo over several weeks 16,17 .…”

Section: Discussionmentioning

confidence: 70%

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Cas9-AAV6 gene correction of beta-globin in autologous HSCs improves sickle cell disease erythropoiesis in mice

et al. 2021

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CRISPR/Cas9-mediated beta-globin (HBB) gene correction of sickle cell disease (SCD) patient-derived hematopoietic stem cells (HSCs) in combination with autologous transplantation represents a recent paradigm in gene therapy. Although several Cas9-based HBB-correction approaches have been proposed, functional correction of in vivo erythropoiesis has not been investigated previously. Here, we use a humanized globin-cluster SCD mouse model to study Cas9-AAV6-mediated HBB-correction in functional HSCs within the context of autologous transplantation. We discover that long-term multipotent HSCs can be gene corrected ex vivo and stable hemoglobin-A production can be achieved in vivo from HBB-corrected HSCs following autologous transplantation. We observe a direct correlation between increased HBB-corrected myeloid chimerism and normalized in vivo red blood cell (RBC) features, but even low levels of chimerism resulted in robust hemoglobin-A levels. Moreover, this study offers a platform for gene editing of mouse HSCs for both basic and translational research.

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Section: Resultssupporting

confidence: 74%

Section: Discussionmentioning

confidence: 70%

Cas9-AAV6 gene correction of beta-globin in autologous HSCs improves sickle cell disease erythropoiesis in mice

et al. 2021

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“…However, we could still confirm engraftment of edited HSCs in secondary recipient mice ( Figure S1F,G ). The heterogeneity in the primary recipients suggests that gene edited functional HSCs may be at low abundance, similar to the recently observed oligo-clonality of human gene-edited HSCs 20 . Consistent with the idea that gene editing caused some toxicity within HSCs, gene editing reduced total donor engraftment levels in competitive transplantation assays (against 1×10 6 whole bone marrow cells) by >30% long-term ( Figure S1H ), even though few differences between mock and RNP+AAV-edited HSCs could be observed in the ex vivo cell cultures ( Figure S1I-K ).…”

Section: Resultssupporting

confidence: 74%

“…In particular, the heterogeneity in engraftment chimerism points towards oligo-clonality in gene editing of functional HSCs. Interestingly, this has also been recently observed in human HSPC gene editing via barcoding analysis 20 , suggesting this is also likely to become an important area for improvement as these approaches move towards the clinic.…”

Section: Discussionmentioning

confidence: 70%

Cas9-AAV6 Gene Correction of Beta-Globin in Autologous HSCs Improves Sickle Cell Disease Erythropoiesis in Mice

Wilkinson

Dever

Baik

et al. 2020

Preprint

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CRISPR/Cas9-mediated beta-globin (HBB) gene correction of Sickle Cell Disease (SCD) patient-derived hematopoietic stem cells (HSCs) in combination with autologous transplantation represents a novel paradigm in gene therapy. Although several Cas9-based HBB-correction approaches have been proposed, functional correction of in vivo erythropoiesis has not been investigated. Here, we used a humanized globin-cluster SCD mouse model to study Cas9-AAV6-mediated HBB-correction in functional HSCs within the context of autologous transplantation. We discover that long-term multipotent HSCs can be gene corrected ex vivo and stable hemoglobin-A production can be achieved in vivo from HBB-corrected HSCs following autologous transplantation. We observed a direct correlation between increased HBB-corrected myeloid chimerism and normalized in vivo RBC features, but even low levels of chimerism resulted in robust hemoglobin-A levels. Moreover, this study offers a platform for gene editing of mouse HSCs for both basic and translational research.

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“…One major caveat of this method is that it has limited sensitivity, depends on the animal model used, and may miss low frequency events (Sato et al, 2019). Alternative in vivo approaches have developed technology to track clonality of cell-based products following ex vivo HSPC editing and transplantation through barcodes included in the HDR template (Ferrari et al, 2021;Sharma et al, 2021) or by tracking indel diversity (Magis et al, 2022). These technologies can identify clones that have expanded abnormally and hint towards genomic events that led to the oncogenic transformation.…”

Section: Linking Genomic Outcomes To Off-target Significancementioning

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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TRACE-Seq Reveals Clonal Reconstitution Dynamics of Gene Targeted Human Hematopoietic Stem Cells

Cited by 5 publications

References 61 publications

Cas9-AAV6 gene correction of beta-globin in autologous HSCs improves sickle cell disease erythropoiesis in mice

Cas9-AAV6 gene correction of beta-globin in autologous HSCs improves sickle cell disease erythropoiesis in mice

Cas9-AAV6 Gene Correction of Beta-Globin in Autologous HSCs Improves Sickle Cell Disease Erythropoiesis in Mice

CRISPR nuclease off-target activity and mitigation strategies

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