Engineering novel CRISPRi repressors for highly efficient mammalian gene regulation.

BACKGROUND: CRISPR interference (CRISPRi), the repurposing of the RNA-guided endonuclease dCas9 as a programmable transcriptional repressor, allows highly specific repression (knockdown) of gene expression. CRISPRi platforms can often have incomplete knockdown, performance variability across cell lines and gene targets, and inconsistencies dependent on the guide RNA sequence employed. RESULTS: Here, we explore the combination of novel repressor domains with strong Krüppel-associated box (KRAB) repressors, screening > 100 bipartite and tripartite fusion proteins for their ability to reduce gene expression as CRISPRi effectors. We show that these novel repressor fusions have reduced dependence on guide RNA sequences, better slow cell growth when used to knock down expression of essential genes, and function in either fusion or scaffold modalities. Furthermore, we isolate and characterize a particularly effective CRISPRi platform, dCas9-ZIM3(KRAB)-MeCP2(t), which shows improved gene repression of endogenous targets both at the transcript and protein level across several cell lines and when deployed in genome-wide screens. CONCLUSIONS: We posit that these novel repressor fusions can enhance the reproducibility and utility of CRISPRi in mammalian cells.