Sneha Suresh scite author profile

The combination of Cas9, guide RNA and repair template DNA can induce precise gene editing and the correction of genetic diseases in adult mammals. However, clinical implementation of this technology requires safe and effective delivery of all of these components into the nuclei of the target tissue. Here, we combine lipid nanoparticle–mediated delivery of Cas9 mRNA with adeno-associated viruses encoding a sgRNA and a repair template to induce repair of a disease gene in adult animals. We applied our delivery strategy to a mouse model of human hereditary tyrosinemia and show that the treatment generated fumarylacetoacetate hydrolase (Fah)-positive hepatocytes by correcting the causative Fah-splicing mutation. Treatment rescued disease symptoms such as weight loss and liver damage. The efficiency of correction was >6% of hepatocytes after a single application, suggesting potential utility of Cas9-based therapeutic genome editing for a range of diseases.

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Structure-guided chemical modification of guide RNA enables potent non-viral in vivo genome editing

Yin

et al. 2017

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Efficient genome editing with Cas9–sgRNA in vivo has required the use of viral delivery systems, which have limitations for clinical applications. Translational efforts to develop other RNA therapeutics have shown that judicious chemical modification of RNAs can improve therapeutic efficacy by reducing susceptibility to nuclease degradation. Guided by the structure of the Cas9–sgRNA complex, we identify regions of sgRNA that can be modified while maintaining or enhancing genome-editing activity, and we develop an optimal set of chemical modifications for in vivo applications. Using lipid nanoparticle formulations of these enhanced sgRNAs (e-sgRNA) and mRNA encoding Cas9, we show that a single intravenous injection into mice induces >80% editing of Pcsk9 in the liver. Serum Pcsk9 is reduced to undetectable levels, and cholesterol levels are significantly lowered about 35% to 40% in animals. This strategy may enable non-viral, Cas9-based genome editing in the liver in clinical settings.

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Partial DNA-guided Cas9 enables genome editing with reduced off-target activity

et al. 2018

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CRISPR–Cas9 is a versatile RNA-guided genome editing tool. Here we demonstrate that partial replacement of RNA nucleotides with DNA nucleotides in CRISPR RNA (crRNA) enables efficient gene editing in human cells. This strategy of partial DNA replacement retains on-target activity when used with both crRNA and sgRNA, as well as with multiple guide sequences. Partial DNA replacement also works for crRNA of Cpf1, another CRISPR system. We find that partial DNA replacement in the guide sequence significantly reduces off-target genome editing through focused analysis of off-target cleavage, measurement of mismatch tolerance and genome-wide profiling of off-target sites. Using the structure of the Cas9–sgRNA complex as a guide, the majority of the 3′ end of crRNA can be replaced with DNA nucleotide, and the 5 - and 3′-DNA-replaced crRNA enables efficient genome editing. Cas9 guided by a DNA–RNA chimera may provide a generalized strategy to reduce both the cost and the off-target genome editing in human cells.

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Enhanced Cas12a editing in mammalian cells and zebrafish

Liu

Luk

Shin

et al. 2019

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Type V CRISPR–Cas12a systems provide an alternate nuclease platform to Cas9, with potential advantages for specific genome editing applications. Here we describe improvements to the Cas12a system that facilitate efficient targeted mutagenesis in mammalian cells and zebrafish embryos. We show that engineered variants of Cas12a with two different nuclear localization sequences (NLS) on the C terminus provide increased editing efficiency in mammalian cells. Additionally, we find that pre-crRNAs comprising a full-length direct repeat (full-DR-crRNA) sequence with specific stem-loop G-C base substitutions exhibit increased editing efficiencies compared with the standard mature crRNA framework. Finally, we demonstrate in zebrafish embryos that the improved LbCas12a and FnoCas12a nucleases in combination with these modified crRNAs display high mutagenesis efficiencies and low toxicity when delivered as ribonucleoprotein complexes at high concentration. Together, these results define a set of enhanced Cas12a components with broad utility in vertebrate systems.

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Precise therapeutic gene correction by a simple nuclease-induced double-stranded break

Iyer

Suresh

Guo

et al. 2019

Nature

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Genome-wide profiling of prime editor off-target sites in vitro and in vivo using PE-tag

Liang

Ponnienselvan

et al. 2023

Nat Methods

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Genetic Diversity of Moringa (Moringa Oleifera Lam.)

Lakshmidevamma

Ugalat

Apoorva

et al. 2021

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Genomic Designing for Biotic Stress Resistance in Sorghum

Fakrudin

Lakshmidevamma

Ugalat

et al. 2021

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Sneha Suresh

Therapeutic genome editing by combined viral and non-viral delivery of CRISPR system components in vivo

Structure-guided chemical modification of guide RNA enables potent non-viral in vivo genome editing

Partial DNA-guided Cas9 enables genome editing with reduced off-target activity

Enhanced Cas12a editing in mammalian cells and zebrafish

Precise therapeutic gene correction by a simple nuclease-induced double-stranded break

Genome-wide profiling of prime editor off-target sites in vitro and in vivo using PE-tag

Genetic Diversity of Moringa (Moringa Oleifera Lam.)

Genomic Designing for Biotic Stress Resistance in Sorghum

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