基于 CRISPR 的代谢工程的系统级建模。

IF 3.7 2区 生物学 Q1 BIOCHEMICAL RESEARCH METHODS ACS Synthetic Biology Pub Date : 2024-09-20 Epub Date: 2024-08-09 DOI:10.1021/acssynbio.4c00053
Ryan A L Cardiff, James M Carothers, Jesse G Zalatan, Herbert M Sauro
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引用次数: 0

摘要

CRISPR-Cas 系统通过使用导向 RNA 对目标基因进行定向激活或抑制,开发出了复杂的多基因代谢工程程序。为了优化微生物系统中的生物合成途径,我们需要改进模型,为转录程序的设计和实施提供信息。最近的进展带来了新的建模方法,用于识别基因靶标和预测导向 RNA 靶向的效果。基因组尺度模型和通量平衡模型已成功应用于确定靶标,以利用组合 CRISPR 干扰(CRISPRi)程序提高生物合成产量。可调动态 CRISPR 激活(CRISPRa)新方法的出现有望进一步提高这些工程能力。一旦确定了合适的靶标,引导 RNA 预测模型就能提高基因靶向的效率。开发改进的模型并结合机器学习方法,也许能克服目前的局限性,大大扩展 CRISPR-Cas9 工具在代谢工程方面的能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Systems-Level Modeling for CRISPR-Based Metabolic Engineering.

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.

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来源期刊
CiteScore
8.00
自引率
10.60%
发文量
380
审稿时长
6-12 weeks
期刊介绍: The journal is particularly interested in studies on the design and synthesis of new genetic circuits and gene products; computational methods in the design of systems; and integrative applied approaches to understanding disease and metabolism. Topics may include, but are not limited to: Design and optimization of genetic systems Genetic circuit design and their principles for their organization into programs Computational methods to aid the design of genetic systems Experimental methods to quantify genetic parts, circuits, and metabolic fluxes Genetic parts libraries: their creation, analysis, and ontological representation Protein engineering including computational design Metabolic engineering and cellular manufacturing, including biomass conversion Natural product access, engineering, and production Creative and innovative applications of cellular programming Medical applications, tissue engineering, and the programming of therapeutic cells Minimal cell design and construction Genomics and genome replacement strategies Viral engineering Automated and robotic assembly platforms for synthetic biology DNA synthesis methodologies Metagenomics and synthetic metagenomic analysis Bioinformatics applied to gene discovery, chemoinformatics, and pathway construction Gene optimization Methods for genome-scale measurements of transcription and metabolomics Systems biology and methods to integrate multiple data sources in vitro and cell-free synthetic biology and molecular programming Nucleic acid engineering.
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