A multiplexed gRNA piggyBac transposon system facilitates efficient induction of CRISPRi and CRISPRa in human pluripotent stem cells

Hazelbaker, Dane Z.; Beccard, Amanda; Angelini, Gabriella; Mazzucato, Patrizia; Messana, Angelica; Lam, Daisy; Eggan, Kevin; Barrett, Lindy E.

doi:10.1038/s41598-020-57500-1

Cited by 33 publications

(51 citation statements)

References 39 publications

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“…Refinements to our protocol may facilitate genomic dosage alteration, including modifying transfection conditions to attain more PB integrations 35,41 , enhancing gRNA expression levels, harnessing other CRISPR systems 47,48 , and/or lengthening the duration of editing by prolonging Cas9 induction 49 . Although we found no relationship between PB DNA input and numbers of integrations per cell, multiple experiments exploring a wider range of PB input levels and alternative delivery techniques have reported higher per-cell PB integration counts [34][35][36] . Thus, PB integrations could be increased to provide more mutational opportunities for any fixed number of iPSC lines.…”

Section: Production Of Multiple Cnv Microdeletionscontrasting

confidence: 87%

“…First, PB transposons can be scarlessly excised from cellular genomes 33 , such that final models would genetically differ only by CRISPR-induced mutations 34 . Second, the PB system has previously been utilized for genome engineering and more recently for CRISPR applications [35][36][37] , having demonstrated efficient editing in iPSCs with indel frequencies of 40-50% 34 . Third, adjusting the amounts of transposon and transposase plasmids transfected allows some control over how many PB integrations occur per cell 35,41 .…”

Section: Resultsmentioning

confidence: 99%

“…Given the relatively high efficiency of these CRISPR strategies, they should dovetail well with our PB system. Fourth, PB libraries increase multiplexing capacity for CRISPR activation/interference applications 36,37 . In all these ways, our PB method will promote systematic efforts to compile large collections of cellular models in isogenic backgrounds.…”

Section: Production Of Multiple Cnv Microdeletionsmentioning

confidence: 99%

“…Here we leveraged the PB transposon, a mobile genetic element that can be scarlessly removed from the cellular genome 33 , to deliver Cas9 [34][35][36][37] together with a gRNA library to iPSCs and perform parallelized genome engineering. We explored both CNV and indel formation, balancing our interest in modeling reciprocal genomic disorders (RGDs) and dosage sensitivity with our desire to develop a method with broad applicability.…”

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confidence: 99%

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Parallelized engineering of mutational models using piggyBac transposon delivery of CRISPR libraries

Nuttle

Burt

Currall

et al. 2020

Preprint

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Novel gene and variant discoveries have reached unprecedented scale with the emergence of exome and genome sequencing studies across a spectrum of human disease initiatives. Highly parallelized functional characterization of these variants is now paramount to deciphering disease mechanisms, and approaches that facilitate editing of induced pluripotent stem cells (iPSCs) to derive otherwise inaccessible tissues of interest (e.g., brain) have become critical in genomics research. Here, we sought to facilitate scalable editing of multiple genes and variants by developing a genome engineering approach that incorporates libraries of CRISPR/Cas9 guide RNAs (gRNAs) into a piggyBac (PB) transposon system. To test the efficiency of inducing small indels, targeted deletions, and large reciprocal copy number variants (CNVs), we simultaneously delivered to human iPSCs both Cas9 and a library including 59 single gRNAs targeting segmental duplications, 70 paired gRNAs flanking particular genic regions, and three single gRNAs targeting the coding sequence of an individual gene, MAGEL2. After editing, we isolated single cells, expanded resultant colonies, and genotyped their gRNA contents and mutational outcomes. We observed that 97.7% of gRNA constructs were integrated into at least one colony, with 85.6% of colonies containing three or fewer PB integrations. This PB editing method generated 354 cell lines with 57.8% of sequenced gRNA cleavage sites modified in at least one line, 14.4% of these lines altered at multiple targets, and single-copy indel mutagenesis predominating. Among the edits generated were eight targeted genomic deletions, including pathogenic microdeletions at chromosome 15q11-q13 (∼5.3 Mbp), chromosome 16p11.2 (∼740 kbp), and chromosome 17q11.2 (∼1.4 Mbp). These data highlight PB editing as a powerful platform for gene inactivation and testify to its strong potential for oligogenic modeling. The ability to rapidly establish high-quality mutational models at scale will facilitate the development of near-isogenic cellular collections and catalyze comparative functional genomic studies, better positioning us to investigate the roles of hundreds of genes and mutations in development and disease.

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Section: Production Of Multiple Cnv Microdeletionscontrasting

confidence: 87%

Section: Resultsmentioning

confidence: 99%

Section: Production Of Multiple Cnv Microdeletionsmentioning

confidence: 99%

mentioning

confidence: 99%

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Parallelized engineering of mutational models using piggyBac transposon delivery of CRISPR libraries

Nuttle

Burt

Currall

et al. 2020

Preprint

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“…Unlike nodal and ventricular types, the atrial PSC-CM markers are not fully characterised. Further insights from novel fluorescent atrial PSC-CM reporter lines, such as PITX2 and KCNA5 , in combination with atrial-promoting differentiation approaches including retinoic acid treatment and CRISPRa/CRISPRi-mediated transcriptional activation/inhibition of atrial-regulating pathways [ 136 , 137 ], could assist the development of atrial cell isolation protocols.…”

Section: Discussionmentioning

confidence: 99%

Fluorescent PSC-Derived Cardiomyocyte Reporter Lines: Generation Approaches and Their Applications in Cardiovascular Medicine

Sontayananon

Redwood

Davies

et al. 2020

Biology

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Recent advances have made pluripotent stem cell (PSC)-derived cardiomyocytes an attractive option to model both normal and diseased cardiac function at the single-cell level. However, in vitro differentiation yields heterogeneous populations of cardiomyocytes and other cell types, potentially confounding phenotypic analyses. Fluorescent PSC-derived cardiomyocyte reporter systems allow specific cell lineages to be labelled, facilitating cell isolation for downstream applications including drug testing, disease modelling and cardiac regeneration. In this review, the different genetic strategies used to generate such reporter lines are presented with an emphasis on their relative technical advantages and disadvantages. Next, we explore how the fluorescent reporter lines have provided insights into cardiac development and cardiomyocyte physiology. Finally, we discuss how exciting new approaches using PSC-derived cardiomyocyte reporter lines are contributing to progress in cardiac cell therapy with respect to both graft adaptation and clinical safety.

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Manipulating and studying gene function in human pluripotent stem cell models

Balmas,

Sozza,

Bottini

et al. 2023

FEBS Letters

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Human pluripotent stem cells (hPSCs) are uniquely suited to study human development and disease and promise to revolutionize regenerative medicine. These applications rely on robust methods to manipulate gene function in hPSC models. This comprehensive review aims to both empower scientists approaching the field and update experienced stem cell biologists. We begin by highlighting challenges with manipulating gene expression in hPSCs and their differentiated derivatives, and relevant solutions (transfection, transduction, transposition, and genomic safe harbor editing). We then outline how to perform robust constitutive or inducible loss‐, gain‐, and change‐of‐function experiments in hPSCs models, both using historical methods (RNA interference, transgenesis, and homologous recombination) and modern programmable nucleases (particularly CRISPR/Cas9 and its derivatives, i.e., CRISPR interference, activation, base editing, and prime editing). We further describe extension of these approaches for arrayed or pooled functional studies, including emerging single‐cell genomic methods, and the related design and analytical bioinformatic tools. Finally, we suggest some directions for future advancements in all of these areas. Mastering the combination of these transformative technologies will empower unprecedented advances in human biology and medicine.

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A multiplexed gRNA piggyBac transposon system facilitates efficient induction of CRISPRi and CRISPRa in human pluripotent stem cells

Cited by 33 publications

References 39 publications

Parallelized engineering of mutational models using piggyBac transposon delivery of CRISPR libraries

Parallelized engineering of mutational models using piggyBac transposon delivery of CRISPR libraries

Fluorescent PSC-Derived Cardiomyocyte Reporter Lines: Generation Approaches and Their Applications in Cardiovascular Medicine

Manipulating and studying gene function in human pluripotent stem cell models

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