期刊
ACS SYNTHETIC BIOLOGY
卷 6, 期 10, 页码 1931-1943出版社
AMER CHEMICAL SOC
DOI: 10.1021/acssynbio.7b00163
关键词
CRISPR/dCas9; gene multiplexing; metabolic engineering; ribozymes; inducible sgRNAs
资金
- Camille Dreyfus Teacher-Scholar Award
- Air Force Office of Scientific Research [FA9550-14-1-0089]
- National Defense Science and Engineering (NDSEG)
Standard approaches for dCas9-based modification of gene expression are limited in the ability to multiplex targets, establish streamlined cassettes, and utilize commonly studied Pol II promoters. In this work, we repurpose the dCas9-VPR activator to act as a dual-mode activator/repressor that can be programmed solely on the basis of target position at gene loci. Furthermore, we implement this approach using a streamlined Pol II-ribozyme system that allows expression of many sgRNAs from a single transcript. By stepping dCas9-VPR within the promoter region and ORF we create graded activation and repression (respectively) of target genes, allowing precise control over multiplexed gene modulation. Expression from the Pol II system increased the net amount of sgRNA production in cells by 3.88-fold relative to the Pol III SNR52 promoter, leading to a significant improvement in dCas9-VPR repression strength. Finally, we utilize our Pol II system to create galactose-inducible switching of gene expression states and multiplex constructs capable of modulating up to 4 native genes from a single vector. Our approach represents a significant step toward minimizing DNA required to assemble CRISPR systems in eukaryotes while enhancing the efficacy (greater repression strength), scale (more sgRNAs), and scope (inducibility) of dCas9-mediated gene regulation.
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