Primary immunodeficiencies, including Wiskott-Aldrich syndrome (WAS), are a main target for genome-editing strategies using specific nucleases (SNs) because a small number of corrected hematopoietic stem cells could cure patients. In this work, we have designed various WAS gene-specific CRISPR/Cas9 systems and compared their efficiency and specificity with homodimeric and heterodimeric WAS-specific zinc finger nucleases (ZFNs), using K-562 cells as a cellular model and plasmid nucleofection or integration-deficient lentiviral vectors (IDLVs) for delivery. The various CRISPR/Cas9 and ZFN SNs showed similar efficiency when using plasmid nucleofection for delivery. However, dual IDLVs expressing ZFNs were more efficient than dual IDLVs expressing Cas9 and guide RNA or all-in-one IDLVs, expressing Cas9 and guide RNA in the same vector. The specificity of heterodimeric ZFNs and CRISPR/Cas9, measured by increments in γ-H2AX focus formation in WAS-edited cells, was similar for both, and both outperformed homodimeric ZFNs independently of the delivery system used. Interestingly, we show that delivery of SNs, using IDLVs, is more efficient and less genotoxic than plasmid nucleofection. We also show the similar behavior of heterodimeric ZFNs and CRISPR/Cas9 for homology-directed gene knock-in strategies, with 88 and 83% of the donors inserted in the WAS locus, respectively, whereas when using homodimeric ZFNs only 45% of the insertions were on target. In summary, our data indicate that CRISPR/Cas9 and heterodimeric ZFNs are both good alternatives to further develop SN-based gene therapy strategies for WAS. However, IDLV delivery of WAS-specific heterodimeric ZFNs was the best option of all systems compared in this study.
Over recent decades, gene therapy, which has enabled the treatment of several incurable diseases, has undergone a veritable revolution. Cell therapy has also seen major advances in the treatment of various diseases, particularly through the use of adult stem cells (ASCs). The combination of gene and cell therapy (GCT) has opened up new opportunities to improve advanced therapy medicinal products for the treatment of several diseases. Despite the considerable potential of GCT, the use of retroviral vectors has major limitations with regard to oncogene transactivation and the lack of physiological expression. Recently, gene therapists have focused on genome editing (GE) technologies as an alternative strategy. In this review, we discuss the potential benefits of using GE technologies to improve GCT approaches based on ASCs. We will begin with a brief summary of different GE platforms and techniques and will then focus on key therapeutic approaches that have been successfully used to treat diseases in animal models. Finally, we discuss whether ASC GE could become a real alternative to retroviral vectors in a GCT setting.
BackgroundChimeric antigen receptor (CAR) T cells directed against CD19 have achieved impressive outcomes for the treatment of relapsed/refractory B lineage lymphoid neoplasms. However, CAR-T therapy still has important limitations due to severe side effects and the lack of efficiency in 40-50% of the patients. Most CARs-T products are generated using retroviral vectors with strong promoters. However, high CAR expression levels can lead to tonic signalling, premature exhaustion and over-stimulation of CAR-T cells, reducing efficacy and increasing side effects. TCR-like expression of the CAR through genome editing resulted in enhanced anti-tumour potency, reducing tonic signalling and improving CAR-T phenotype. In this manuscript, we searched for LVs that mimic the TCR expression pattern as a closer-to-clinic alternative for the generation of improved CAR-T cells.MethodsDifferent LVs containing viral and human promoters were analysed to select those that closely mimic a TCR-like kinetic profile upon T-cell activation. WAS gene proximal promoter-driven LVs (AW-LVs) were selected to express a second generation 4-1BB aCD19 CAR (ARI-0001) into T cells to generate AWARI CAR-T cells. TCR-like AWARI and EF1α-driven ARI CAR T cells were analysed for in vitro and in vivo killing efficiency using leukaemia and lymphoma cellular models. Tonic signalling, exhaustion markers and phenotype were determined by flow cytometry. Large-scale automated manufacturing of AWARI CAR-T cells was performed in a CliniMACs Prodigy bioreactor.ResultsOur data showed that LVs expressing the transgene through the WAS gene proximal promoter mimic very closely the TCR (CD3) expression pattern kinetic upon TCR stimulation or antigen encounter. Compared to EF1α-driven ARI CAR-T cells, AWARI CAR-T cells exhibited a higher proportion of naïve/stem cell memory T cells with less exhausted phenotype after efficient killing of CD19+ cells both in vitro and in vivo. AWARI CAR-T cells also showed lower tonic signalling and reduced secretion of pro-inflammatory cytokines and were efficiently manufactured in large-scale GMP-like conditions.ConclusionsWAS-gene-promoter driven LVs can be used to generate physiological 4-1BB-CAR-T cell products with lower tonic signalling, improved phenotype and a safer profile. We propose the use of TCR-like LVs as an alternative to strong-promoter driven LVs for the generation of CAR-T products.
In spite of the enormous potential of CRISPR/Cas in basic and applied science, the levels of undesired genomic modifications cells still remain mostly unknown and controversial. Nowadays, the efficiency and specificity of the cuts generated by CRISPR/Cas is the main concern. However, there are also other potential drawbacks when DNA donors are used for gene repair or gene knock-ins. These GE strategies should take into account not only the specificity of the nucleases, but also the fidelity of the DNA donor to carry out their function. The current methods to quantify the fidelity of DNA donor are costly and lack sensitivity to detect illegitimate DNA donor integrations. In this work, we have engineered two reporter cell lines (K562_SEWAS84 and K562GWP) that efficiently quantify both the on-target and the illegitimate DNA donor integrations in a WAS-locus targeting setting. K562_SEWAS84 cells allow the detection of both HDR-and HITI-based donor integration, while K562GWP cells only report HDR-based GE. To the best of our knowledge, these are the first reporter systems that allow the use of gRNAs targeting a relevant locus to measure efficacy and specificity of DNA donor-based GE strategies. By using these models, we have found that the specificity of HDR is independent of the delivery method and that the insertion of the target sequence into the DNA donor enhances efficiency but do not affect specificity. Finally, we have also shown that the higher the number of the target sites is, the higher the specificity and efficacy of GE will be.
Pompe disease (PD) is a rare disorder caused by mutations in the acid alpha-glucosidase (GAA) gene. Most gene therapies (GT) partially rely on the cross-correction of unmodified cells through the uptake of the GAA enzyme secreted by corrected cells. In the present study, we generated isogenic murine GAA-KO cell lines resembling severe mutations from Pompe patients. All of the generated GAA-KO cells lacked GAA activity and presented an increased autophagy and increased glycogen content by means of myotube differentiation as well as the downregulation of mannose 6-phosphate receptors (CI-MPRs), validating them as models for PD. Additionally, different chimeric murine GAA proteins (IFG, IFLG and 2G) were designed with the aim to improve their therapeutic activity. Phenotypic rescue analyses using lentiviral vectors point to IFG chimera as the best candidate in restoring GAA activity, normalising the autophagic marker p62 and surface levels of CI-MPRs. Interestingly, in vivo administration of liver-directed AAVs expressing the chimeras further confirmed the good behaviour of IFG, achieving cross-correction in heart tissue. In summary, we generated different isogenic murine muscle cell lines mimicking the severe PD phenotype, as well as validating their applicability as preclinical models in order to reduce animal experimentation.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.