Dissection of the MeCP2 Repressor Protein Enables CRISPR Platform Optimization via Localization Engineering.

Abstract

Clustered regularly interspaced short palindromic repeat interference (CRISPRi), the fusion of nuclease-inactive Cas9 with transcriptional repressor domains, is a powerful platform enabling site-specific gene knockdown across diverse biological contexts. Previously described CRISPRi systems typically utilize two distinct domain classes: (1) Krüppel-associated box domains and (2) truncations of the multifunctional protein, MeCP2. Despite widespread adoption of MeCP2 truncations for developing CRISPRi platforms, individual contributions of subdomains within MeCP2's transcriptional repression domain (TRD) toward enhancing gene knockdown remain unclear. Here, we dissect MeCP2's TRD and observe that two subdomains, the expected NcoR/SMRT interaction domain (NID) and an embedded nuclear localization signal (NLS), can separately enhance gold-standard CRISPRi platform performance beyond levels attained with the canonical MeCP2 protein truncation. Incorporating side-by-side analyses of nuclear localization and gene knockdown for over 30 constructs featuring MeCP2 subdomains or virus-derived NLS sequences, we demonstrate that appending C-terminal NLS motifs to dCas9-based transcriptional regulators, both repressors and activators, can significantly improve their effector function across several cell lines. We also observe that NLS placement greatly impacts CRISPRi repressor performance, and that modifying the subdomain configuration natively found within MeCP2 can also enhance gene suppression capabilities in certain contexts. Overall, this work demonstrates the interplay of two complimentary chimeric protein design considerations, transcriptional domain 'dissection' and NLS motif placement, for optimizing CRISPR-mediated transcriptional regulation in mammalian systems.