BCL11A enhancer dissection by Cas9-mediated in situ saturating mutagenesis

Canver, Matthew C.; Smith, Elenoe C.; Sher, Falak; Pinello, Luca; Sanjana, Neville E.; Shalem, Ophir; Chen, Diane D.; Schupp, Patrick G.; Vinjamur, Divya S.; Garcia, Sara P.; Luc, Sidinh; Kurita, Ryo; Nakamura, Yukio; Fujiwara, Yuko; Maeda, Takahiro; Yuan, Guo Cheng; Zhang, Feng; Orkin, Stuart H.; Bauer, Daniel E.

doi:10.1038/nature15521

Cited by 789 publications

(721 citation statements)

References 61 publications

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“…Fetal haemoglobin does not form long chains, so tricking cells into producing it could result in less clogging by red blood cells. A team of researchers including Feng Zhang of the Broad Institute in Cambridge, Massachusetts, recently showed that using CRISPR-Cas9 to make cuts in the genomic region that controls the expression of BCL11A increases the production of fetal haemoglobin 1 .…”

Section: Naturecommentioning

confidence: 99%

Medicine: Expanding possibilities

Gewin¹

2015

Nature

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Section: Naturecommentioning

confidence: 99%

Medicine: Expanding possibilities

Gewin¹

2015

Nature

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“…For hemoglobinopathies, gene editing strategizes shown to be successful include either induction of endogenous fetal hemoglobin 55,56 , modification of the causal β-globin gene mutation by targeted nucleases 57 or therapeutic transgene integration 58 , or a combined approach 59,60 . Inactivation of an erythroid specific enhancer of BCL11A by gene editing leads to suppression of BCL11A and up-regulation of γ-globin in erythroid lineage cells 61,62 . These gene editing strategizes are being performed in CD34+ stem and progenitor cells 63 or in induced pluripotent stem cells (iPSCs) capable of differentiating into any somatic cell type [64][65][66] .…”

Section: Recent Advances In Genetic Manipulation Technologymentioning

confidence: 99%

Gene therapy for hemoglobin disorders - a mini-review

Rai¹

2016

J Rare Dis Res Treat

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Gene therapy by either gene insertion or editing is an exciting curative therapeutic option for monogenic hemoglobin disorders like sickle cell disease and β-thalassemia. The safety and efficacy of gene transfer techniques has markedly improved with the use of lentivirus vectors. The clinical translation of this technology has met with good success, although key limitations include number of engraftable transduced hematopoietic stem cells and adequate transgene expression that results in complete correction of β0 thalassemia major. This highlights the need to identify and address factors that might be contributing to the in-vivo survival of the transduced hematopoietic stem cells or find means to improve expression from current vectors. In this review, we briefly discuss the gene therapy strategies specific to hemoglobinopathies, the success of the preclinical models and the current status of gene therapy clinical trials.

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“…The group identified sgRNAs that caused complete knockout of BCL11A, with subsequent upregulation of HbF expression. 39 This important work provides a framework for therapeutic gene editing in hematopoietic stem cells to restore HbF expression and ameliorate the sickle cell phenotype. The particular enhancer targeted is specific to erythroid elements, thus preserving BCL11A expression in nonerythroid tissues and reducing side effects.…”

Section: Gene Therapy Protocols Using Genome Editing Technologiesmentioning

confidence: 99%

Gene Editing: Powerful New Tools for Nephrology Research and Therapy

Miyagi

Humphreys

2016

JASN

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Biologic research is experiencing a transformation brought about by the ability of programmable nucleases to manipulate the genome. In the recently developed CRISPR/ Cas system, short RNA sequences guide the endonuclease Cas9 to any location in the genome, causing a DNA double-strand break (DSB). Repair of DSBs allows the introduction of targeted genetic manipulations with high precision. Cas9-mediated gene editing is simple, scalable, and rapid, and it can be applied to virtually any organism. Here, we summarize the development of modern gene editing techniques and the biology of DSB repair on which these techniques are based. We discuss technical points in applying this technology and review its use in model organisms. Finally, we describe prospects for the use of gene editing to treat human genetic diseases. This technology offers tremendous promise for equipping the nephrology research community to better model and ultimately, treat kidney diseases.

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BCL11A enhancer dissection by Cas9-mediated in situ saturating mutagenesis

Cited by 789 publications

References 61 publications

Medicine: Expanding possibilities

Medicine: Expanding possibilities

Gene therapy for hemoglobin disorders - a mini-review

Gene Editing: Powerful New Tools for Nephrology Research and Therapy

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