Hansol Park scite author profile

Gene-editing systems such as CRISPR-Cas9 readily enable individual gene phenotypes to be studied through loss of function. However, in certain instances, gene compensation can obfuscate the results of these studies, necessitating the editing of multiple genes to properly identify biological pathways and protein function. Performing multiple genetic modifications in cells remains difficult due to the requirement for multiple rounds of gene editing. While fluorescently labeled guide RNAs (gRNAs) are routinely used in laboratories for targeting CRISPR-Cas9 to disrupt individual loci, technical limitations in single gRNA (sgRNA) synthesis hinder the expansion of this approach to multicolor cell sorting. Here, we describe a modular strategy for synthesizing sgRNAs where each target sequence is conjugated to a unique fluorescent label, which enables fluorescence-activated cell sorting (FACS) to isolate cells that incorporate the desired combination of gene-editing constructs. We demonstrate that three short strands of RNA functionalized with strategically placed 5′-azide and 3′-alkyne terminal deoxyribonucleotides can be assembled in a one-step, template-assisted, copper-catalyzed alkyne–azide cycloaddition to generate fully functional, fluorophore-modified sgRNAs. Using these synthetic sgRNAs in combination with FACS, we achieved selective cleavage of two targeted genes, either separately as a single-color experiment or in combination as a dual-color experiment. These data indicate that our strategy for generating double-clicked sgRNA allows for Cas9 activity in cells. By minimizing the size of each RNA fragment to 41 nucleotides or less, this strategy is well suited for custom, scalable synthesis of sgRNAs.

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Selectivity and Efficiency of the Ligation of The Pyrene:Abasic Base Pair by T4 DNA Ligase: Towards Abasic Lesion Detection by Ligation

Park

Gibbs

2022

Preprint

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Remarkable selectivity was observed in the ligation of 5’-phosphate 1-pyrene nucleotide terminated strands across from an abasic lesion in a DNA-templated ligation reaction by two different ligase suggesting that pyrene-terminated strands could be used in abasic site detection. This selectivity is significantly greater than other reported unnatural base pairs at the same position revealing the unique properties of the abasic:pyrene pair.

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Minimizing Product Inhibition in DNA Self-Replication: Insights for Prebiotic Replication from the Role of the Enzyme in Lesion-Induced DNA Amplification

Park

Parshotam

Hales

et al. 2022

Preprint

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Self-replication of nucleic acids in the absence of enzymes such as polymerases or ligases represents an important and poorly understood step in the origin of life. In fact, the self-replication of nucleic acids remains strongly hindered by product inhibition, even when enzymes are present. Studying one of the few successful examples of enzymatic DNA self-replication based on a simple ligation chain reaction can shed light on how this fundamental process may have originally evolved. Previously, our group reported lesion-induced DNA amplification (LIDA), which is an isothermal ligase chain reaction. It was proposed that the lesion, a destabilizing abasic group, played an important role in reducing product inhibition. However, using abasic groups in non-enzymatic ligation cycles did not yield appreciable amplification. In order to identify the unknown factors that overcome product inhibition in LIDA, we have performed a detailed kinetic and thermodynamic analysis of the process, employing isothermal titration calorimetry (ITC) and global fitting of PAGE fluorescence data to characterize the individual steps of the amplification process. We found that in the absence of an enzyme, the ligated product binds four to five orders of magnitude more tightly to the template than to the shorter unligated strands of the intermediate complex. In the presence of T4 DNA ligase, this stability gap was reduced by two orders of magnitude, such that the intermediate and product complexes were roughly equal in stability. Thus, the ligase helps overcome product inhibition by reducing the affinity difference between the DNA product duplex and the intermediate complex. Furthermore, kinetic simulations showed that the stability of the intermediate complex, as well as the rate constant of ligation, significantly impacts the rate of self-replication, suggesting that catalysts that stabilize the intermediate complex might be a route to efficient nonenzymatic replication.

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CRISPR-Click Enables Multi-Gene Editing with Modular Synthetic sgRNAs

Park

Osman

Cromwell

et al. 2021

Preprint

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Gene editing systems such as CRISPR/Cas9 readily enable individual gene phenotypes to be studied through loss-of-function. However, in certain instances, gene compensation can obfuscate the results of these studies, necessitating the editing of multiple genes to properly identify biological pathways and protein function. Performing multiple genetic modifications in cells remains difficult due to the requirement for multiple rounds of gene editing. While fluorescently labeled guide RNAs (gRNAs) are routinely used in laboratories for targeting CRISPR/Cas9 to disrupt individual loci, technical limitations in single guide RNA (sgRNA) synthesis hinder the expansion of this approach to multi-color cell sorting. Here, we describe a modular strategy for synthesizing sgRNAs where each target sequence is conjugated to a unique fluorescent label, which enables fluorescence-assisted cell sorting (FACS) to isolate cells that incorporate the desired combination of gene-editing constructs. We demonstrate that three short strands of RNA functionalized with strategically placed 3’-azide and 5’-alkyne terminal deoxyribonucleotides can be assembled in a one-step, template-assisted, copper-catalyzed alkyne-azide cycloaddition (CuAAC) to generate fully functional, fluorophore-modified sgRNAs. Using these synthetic sgRNA in combination with FACS, we achieved selective cleavage of two targeted genes, either separately as a single color experiment or in combination as a dual-color experiment. These data indicate that our strategy for generating doubly-clicked sgRNA allows for Cas9 activity in cells. By minimizing the size of each RNA fragment to 41 nucleotides or less, this strategy is well suited for custom, scalable synthesis of sgRNAs.

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Selectivity and efficiency in the ligation of the pyrene:abasic base pair by T4 and PBCV-1 DNA ligases

Park

Gibbs

2022

Chem. Commun.

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Hansol Park

CRISPR-Click Enables Dual-Gene Editing with Modular Synthetic sgRNAs

Selectivity and Efficiency of the Ligation of The Pyrene:Abasic Base Pair by T4 DNA Ligase: Towards Abasic Lesion Detection by Ligation

Minimizing Product Inhibition in DNA Self-Replication: Insights for Prebiotic Replication from the Role of the Enzyme in Lesion-Induced DNA Amplification

CRISPR-Click Enables Multi-Gene Editing with Modular Synthetic sgRNAs

Selectivity and efficiency in the ligation of the pyrene:abasic base pair by T4 and PBCV-1 DNA ligases

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