Base Editing in Human Cells to Produce Single‐Nucleotide‐Variant Clonal Cell Lines

Vasquez, Carlos Alberto; Cowan, Quinn T.; Komor, Alexis C.

doi:10.1002/cpmb.129

Cited by 9 publications

(4 citation statements)

References 90 publications

(136 reference statements)

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“…15070063), at 37°C with 5% CO2. Transfection of plasmid DNA into HEK293T cells for the purpose of generating isogenic cell lines has been previously described ( 79 ). Briefly, cells were plated at a density of 50,000 cells per well in 250 μl of P/S-free medium per well in 48-well plates and transfected 16 hours after plating.…”

Section: Methodsmentioning

confidence: 99%

“…The 96-well plate was immediately placed into a tissue culture incubator after sorting. Subculturing and genotyping of single cells after clonal expansion was conducted as previously described ( 79 ). Genotyping of 26 clones confirmed the presence of three clones containing a heterozygous genotype and one clone containing a homozygous genotype (fig.…”

Section: Methodsmentioning

confidence: 99%

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Functional EPAS1 / HIF2A missense variant is associated with hematocrit in Andean highlanders

Lawrence,

Gu,

Bohlender

et al. 2024

Sci. Adv.

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Hypoxia-inducible factor pathway genes are linked to adaptation in both human and nonhuman highland species. EPAS1 , a notable target of hypoxia adaptation, is associated with relatively lower hemoglobin concentration in Tibetans. We provide evidence for an association between an adaptive EPAS1 variant (rs570553380) and the same phenotype of relatively low hematocrit in Andean highlanders. This Andean-specific missense variant is present at a modest frequency in Andeans and absent in other human populations and vertebrate species except the coelacanth. CRISPR-base-edited human cells with this variant exhibit shifts in hypoxia-regulated gene expression, while metabolomic analyses reveal both genotype and phenotype associations and validation in a lowland population. Although this genocopy of relatively lower hematocrit in Andean highlanders parallels well-replicated findings in Tibetans, it likely involves distinct pathway responses based on a protein-coding versus noncoding variants, respectively. These findings illuminate how unique variants at EPAS1 contribute to the same phenotype in Tibetans and a subset of Andean highlanders despite distinct evolutionary trajectories.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Functional EPAS1 / HIF2A missense variant is associated with hematocrit in Andean highlanders

Lawrence,

Gu,

Bohlender

et al. 2024

Sci. Adv.

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“…40 CRISPR-CBE can be used to convert the 'C' in E4 to 'T' in E3, an irreversible DNA conversion, without requiring double-stranded DNA (dsDNA) breaks by using a Cas9 nickase (Cas9n). 41,42 Cas9n and cytidine deaminase enzyme fusion proteins, along with endogenous DNA repair systems, are used to effect the 'C'-'T' substitution, leading to correction of ~15-75% of total in vitro cellular DNA with minimal (≤ 1%) INDEL formation and minimal off-target editing vitro. 34,41 In addition, CBE allows editing in both dividing and non-dividing cells such as brain neurons.…”

Section: Introductionmentioning

confidence: 99%

Successful Gene Editing of Apolipoprotein E4 to E3 in Brain of Alzheimer Model Mice After a Single IV Dose of Synthetic Exosome-Delivered CRISPR

Teter,

Campagna,

Zhu

et al. 2024

Preprint

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Background. The gene for apolipoprotein E4 (ApoE4 E4) confers an increased risk for development and lowers the age of onset of Alzheimers disease (AD). It is a highly suitable target for CRISPR-based editing because ApoE4 differs from ApoE3 by a single nucleotide polymorphism in the codon for residue 112 that codes for arginine (CGC) in E4 and cysteine (TGC) in E3. Editing of E4 to E3 could lower the risk of AD or ameliorate E4-related AD phenotypes. For AD, in order to deliver CRISPR components across the blood-brain barrier to the brain, we have developed a delivery platform termed Synthetic Exosomes (SEs) microfluidically-synthesized deformable nanovesicles approximately the size of natural exosomes that have the ability to cross the BBB and deliver cargo to the brain. Here, we describe our use of SEs carrying CRISPR to successfully edit E4 to E3 in brain tissue of an E4-expressing mouse model. Methods. Several CRISPR guide RNAs (gRNA) and Cytosine Base Editor (CBE) mRNAs were synthesized by chemical and in vitro transcription syntheses, respectively. Four combinations of gRNA and CBE mRNA were tested in vitro for their relative activity to edit the E4 (cytosine) to E3 (thymine) in E4-expressing neuroblastoma (E4-N2A) and human Kelly-neuroblastoma cells, to assess which combination produced the highest E4 to E3 base editing efficiency. The CRISPR RNA combination with the highest efficiency was encapsulated in SEs and injected intravenously (IV) via the tail vein into an AD model E4-expressing (E4-5XFAD) transgenic mouse; as a negative control, an E4-5XFAD mouse was injected with empty SEs. Five days after injection, mice were euthanized and brain, liver, and buffy coat (white blood cells (WBC)) collected to determine the editing of E4 to E3 measured by Next Generation Sequencing. In addition, E3 mRNA was measured in the brain and liver and compared to the %E3 gene editing. Results. The highest gRNA+CBE mRNA editing efficiency was ~50% in E4-N2A cells and the same gRNA+CBE combination delivered in SEs to Kelly neuroblastoma cells showed 6.5% editing efficiency. In the E4-5XFAD mouse in vivo, five days after IV delivery of a single dose of the highest-activity SE-CRISPR gRNA+CBE mRNA, the percent of E4 edited to E3 was 0.14% in brain, 0.8% in liver, and 0.36 % in WBCs. As evidence of functional editing, SE-CRISPR-treated mice had 0.03% E3 mRNA in brain and 0.09% E3 mRNA in liver. Conclusions. While this level of ApoE4 to E3 editing achieved five days after a single IV injection of SE-CRISPR is small, it provides initial in vivo proof-of-concept that the ApoE4 gene can be successfully edited and editing results in functional expression of ApoE3 mRNA. The findings presented herein supports further optimization of the SE-CRISPR approach to increase the level of editing in brain as part of clinical development of SE-CRISPR as a powerful novel therapeutic approach for AD.

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“…However, pre-college students are less aware of newer genome engineering tools like base editors (BEs). BEs enable scientists to introduce point mutations at targeted sites in the genome of living cells with high efficiency and precision (21,22) and thus have the therapeutic potential to treat thousands of human genetic disorders (Figure 1A-B) (23)(24)(25). A hands-on laboratorybased experiment that uses base editing would introduce students to cutting-edge genome editing technologies while building upon previous knowledge of CRISPR technologies (as BEs are modified CRISPR systems).…”

Section: Introductionmentioning

confidence: 99%

Curing “GFP-itis” in Bacteria with Base Editors: Development of a Genome Editing Science Program Implemented with High School Biology Students

Vasquez

Evanoff

Ranzau

et al. 2023

Preprint

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The flexibility and precision of CRISPR-Cas9 and related technologies have made these genome editing tools increasingly popular in agriculture, medicine, and basic science research over the past decade. Genome editing will continue to be relevant and utilized across diverse scientific fields in the future. Given this, students should be introduced to genome editing technologies and encouraged to consider their ethical implications early on in pre-college biology curricula. Furthermore, instruction on this topic presents an opportunity to create partnerships between researchers and educators at the K-12 levels that can strengthen student engagement in science, technology, engineering, and mathematics (STEM). To this end, we present a three-day student-centered learning program to introduce high school students to genome editing technologies through a hands-on base editing experiment in E. coli, accompanied by a relevant background lecture and facilitated ethics discussion. This unique partnership aims to educate students and provides a framework for research institutions to implement genome editing outreach programs at local high schools.

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Base Editing in Human Cells to Produce Single‐Nucleotide‐Variant Clonal Cell Lines

Cited by 9 publications

References 90 publications

Functional EPAS1 / HIF2A missense variant is associated with hematocrit in Andean highlanders

Functional EPAS1 / HIF2A missense variant is associated with hematocrit in Andean highlanders

Successful Gene Editing of Apolipoprotein E4 to E3 in Brain of Alzheimer Model Mice After a Single IV Dose of Synthetic Exosome-Delivered CRISPR

Curing “GFP-itis” in Bacteria with Base Editors: Development of a Genome Editing Science Program Implemented with High School Biology Students

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