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Systems-Level Modeling for CRISPR-Based Metabolic Engineering

Ryan Cardiff, James M. Carothers, Jesse G. Zalatan, Herbert M. Sauro

2024ACS Synthetic Biology11 citationsDOI

Abstract

The CRISPR-Cas system has enabled the development of sophisticated, multigene metabolic engineering programs through the use of guide RNA-directed activation or repression of target genes. To optimize biosynthetic pathways in microbial systems, we need improved models to inform design and implementation of transcriptional programs. Recent progress has resulted in new modeling approaches for identifying gene targets and predicting the efficacy of guide RNA targeting. Genome-scale and flux balance models have successfully been applied to identify targets for improving biosynthetic production yields using combinatorial CRISPR-interference (CRISPRi) programs. The advent of new approaches for tunable and dynamic CRISPR activation (CRISPRa) promises to further advance these engineering capabilities. Once appropriate targets are identified, guide RNA prediction models can lead to increased efficacy in gene targeting. Developing improved models and incorporating approaches from machine learning may be able to overcome current limitations and greatly expand the capabilities of CRISPR-Cas9 tools for metabolic engineering.

Topics & Concepts

CRISPRGenome engineeringCas9Computational biologySynthetic biologyMetabolic engineeringComputer scienceGenome editingSystems biologyBiochemical engineeringGeneBiologyEngineeringGeneticsCRISPR and Genetic EngineeringMicrobial Metabolic Engineering and BioproductionRNA and protein synthesis mechanisms
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