CRISPR-Cas9 (Clustered Regularly Interspaced Short Palindromic Repeats-CRISPR associated enzyme 9) is known for its simplicity, versatility, and scalability in genome editing applications. In vitro Cas9, when complexed with sgRNA, binds and cleaves the complementary target sequences with almost perfect precision. The enzyme is exploited for various applications in understanding and changing gene function. dCas9 (deactivated or dead Cas9) is a double mutated version of Cas9 that bears mutations in the nuclease domains of the enzyme and thus cannot cleave the target DNA. dCas9 is equally advantageous since it can alter gene expression using various transcriptional activators CRISPRa and repressors CRISPRi. Additionally, dCas9 can bind to the desired target gene without cleaving it, making it a unique reagent to study the kinetics and stability of RNA-protein-DNA interactions required to design more efficient and specific gene-editing nucleases. An appreciable quantity of pure and homogeneous protein is needed to characterise dCas9 for its structural and functional understanding. This study used an N-terminal acidic tag to express the dCas9 in an E. coli-bacterial host. A simple single-step protocol for robust and efficient production of dCas9 has been described. The study and methods are distinctive as the purification is performed in a single step using inexpensive multi-modal hydroxyapatite chromatography. The purified protein can be used in different in vitro and in vivo studies.
Keywords: EMSA; Genome editing; Hydroxyapatite chromatography; Ion exchange; dCas9.
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