Naïve Induced Pluripotent Stem Cells Generated From β-Thalassemia Fibroblasts Allow Efficient Gene Correction With CRISPR/Cas9

Yang, Yuanyuan; Zhang, Xiaobai; Li, Yi; Hou, Zhenzhen; Chen, Jiayu; Kou, Xiaochen; Zhao, Yanhong; Wang, Hong; Sun, Xiaofang; Jiang, Cizhong; Wang, Yixuan; Gao, Shaorong

doi:10.5966/sctm.2015-0157

Cited by 71 publications

(54 citation statements)

References 29 publications

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“…A recent study reported efficiency of CRISPR/Cas9 system for correction of HBB in iPSCs|: up to 57% of the clones showed modification of at least one HBB allele in experimental series, as well as minimal off-target activity [28].…”

Section: Experimental Studiesmentioning

confidence: 99%

Clinical implementation of genome editing for correction of human diseases

Popova¹,

Lepik²,

Sergeev³

et al. 2017

CTT

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SummaryGenome editing is a breakthrough technology which consists of the process of precise modifications introduction into the genome of any organism. This scientific breakthrough provides a powerful tool for the errors correction in the nucleotide sequence of DNA. The development of the genome editing has inverted the concept of an available target for the therapeutic correction. The opportunity of highly precise and safe entering of single-and double-stranded breaks into the human DNA followed by natural DNA repair mechanisms has changed current approaches of the gene therapy and opened up new horizons in the treatment of numerous diseases. Genome editing is being developed to treat not only monogenic diseases but also infectious diseases and cancer. In the current review, we discuss the therapeutic application of genome editing.

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Section: Experimental Studiesmentioning

confidence: 99%

Clinical implementation of genome editing for correction of human diseases

Popova¹,

Lepik²,

Sergeev³

et al. 2017

CTT

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“…Этот подход уже был использован в экспериментах по коррекции мутаций, вызы-вающих тяжелые наследственные болезни (му-ковисцидоз [15], миодистрофия Дюшенна [16], дегенерация сетчатки глаза [17]), для лечения инфекционных заболеваний (вИЧ) [18] и в ис-следованиях тонкой структурно-функциональ-ной организации генома человека. Недавно с помощью этой технологии были проведены эксперименты на мышах, а затем на зиготах че-ловека для коррекции мутаций гена β-глобина, вызывающих тяжелое и частое наследственное заболевание -β-талассемию [19]. Результаты этих экспериментов вызвали большой науч-ный резонанс.…”

Section: достижения вспомогательных репродуктивных технологий и новыеunclassified

Achievements, sensations and problemsof molecular prenatal diagnostics

2016

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“…Precisely engineered iPSCs are needed for stem cell-based modelling of genetic disease, and for providing an unlimited source of gene-edited lines for potential use in regenerative medicine [228,229]. Recent studies have reported successful gene correction of beta thalassaemia mutations using Cas9WT in iPSCs [35][36][37]138]. Cooperative strategies, (i.e.…”

Section: Discussion and Future Directionsmentioning

confidence: 99%

“…While the generation of iPSCs from the fibroblasts of beta thalassaemia individual [26][27][28][35][36][37] and amniotic fluids cells [38] has previously been reported [28,187] he production of footprint-free iPSCs from fibroblasts derived from patients with the Mediterranean mutation IVSII-1(G>A) of beta thalassaemia has not been reported to date (Table1-1). IVSII-1(G>A) is a splice junction mutation that affects the 5′ splice site leading to a severe form of beta thalassaemia in the homozygous state.…”

Section: Excision Of the Selection Cassettementioning

confidence: 99%

“…The Sendai virus [35] excisable integrating vector (STEMCCA/Cre/loxP) [36] and episomes [37,38] were used for the derivation of integration-free iPSCs from patients with inherited haemoglobinopathies (Table1-1). Although transgene-free iPSCs can be derived with the STEMCCA vector, the excision process leaves a short DNA sequence in the host genome [39] that may have consequences for the functionality of the gene [40].…”

Section: Methods For Deriving Ipscs With a Beta Thalassaemia Mutationmentioning

confidence: 99%

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CRISPR/Cas9-mediated traceless gene correction and activation of the HBB locus in iPSCs with the beta thalassaemia mutation

Al-Ateeq¹

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Beta thalassaemia is caused by mutations in the adult haemoglobin gene (HBB) and is one of the most prevalent monogenic blood disorders worldwide. The transplantation of haematopoietic stem cells derived from gene-corrected patient induced pluripotent stem cells (iPSCs) could provide a promising therapeutic strategy. Here, the generation and characterisation of footprint-free iPSCs from dermal fibroblasts of an individual with a homozygous beta thalassaemia-causing mutation affecting splicing is described (Chapter III). Successful gene correction of the disease-causing mutation was achieved by employing a CRISPR/Cas9 dual nickase approach and two donor design strategies aimed at reducing undesired on-target mutagenesis (Chapter IV), followed by the This study combined cutting-edge cellular reprogramming methods to generate beta thalassaemia iPSCs, a double nickase-mediated gene editing approach and piggyBac transposase-aided excision to achieve seamless gene repair, and a CRISPRa approach to model the impact of the diseasecausing mutation and demonstrate restoration of normal transcription following genetic repair.Having established a platform for precise gene correction and for validation of the restoration of the functional allele in this monogenic disease, this strategy may provide a viable avenue for iPSCiii based cell therapy of beta thalassaemic patients provided mature engraftable blood cells can be generated from hiPSCs in the future.iv

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Naïve Induced Pluripotent Stem Cells Generated From β-Thalassemia Fibroblasts Allow Efficient Gene Correction With CRISPR/Cas9

Cited by 71 publications

References 29 publications

Clinical implementation of genome editing for correction of human diseases

Clinical implementation of genome editing for correction of human diseases

Achievements, sensations and problemsof molecular prenatal diagnostics

CRISPR/Cas9-mediated traceless gene correction and activation of the HBB locus in iPSCs with the beta thalassaemia mutation

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