通过计算引导和 CRISPRi- 驱动的稳健性调控来定制微生物的适应性。

Cell systems Pub Date : 2024-12-18 Epub Date: 2024-12-11 DOI:10.1016/j.cels.2024.11.012
Bin Yang, Chao Wu, Yuxi Teng, Katherine J Chou, Michael T Guarnieri, Wei Xiong
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引用次数: 0

摘要

转基因微生物(GMMs)在各行各业的广泛应用突出表明,迫切需要强有力的策略来降低其潜在失控逸散所带来的风险。本研究将计算建模与 CRISPR 干扰(CRISPRi)相结合,以完善转基因微生物代谢的稳健性。利用集合建模,我们实现了对易受表达改变影响的酶靶点的高通量硅学筛选。通过转化这些见解,我们开发出了功能性 CRISPRi,通过多重基因敲除提高了适应性控制。我们的方法通过改进绝缘体的 gRNA 结构和控制紧凑型 Cas12m 的关断开关电路得到了增强,从而合理地设计出了逃逸频率低于美国国立卫生研究院标准的菌株。这种方法的有效性在各种条件下都得到了证实,展示了其安全管理 GMM 的能力。这项研究强调了微生物新陈代谢的恢复能力,通过对关键节点进行战略性改造,使其停止生长而不产生明显的抗药性,从而实现更可靠、更精确的 GMM 控制。本论文的同行评审过程透明,记录见补充信息。
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Tailoring microbial fitness through computational steering and CRISPRi-driven robustness regulation.

The widespread application of genetically modified microorganisms (GMMs) across diverse sectors underscores the pressing need for robust strategies to mitigate the risks associated with their potential uncontrolled escape. This study merges computational modeling with CRISPR interference (CRISPRi) to refine GMM metabolic robustness. Utilizing ensemble modeling, we achieved high-throughput in silico screening for enzymatic targets susceptible to expression alterations. Translating these insights, we developed functional CRISPRi, boosting fitness control via multiplexed gene knockdown. Our method, enhanced by an insulator-improved gRNA structure and an off-switch circuit controlling a compact Cas12m, resulted in rationally engineered strains with escape frequencies below National Institutes of Health standards. The effectiveness of this approach was confirmed under various conditions, showcasing its ability for secure GMM management. This research underscores the resilience of microbial metabolism, strategically modifying key nodes to halt growth without provoking significant resistance, thereby enabling more reliable and precise GMM control. A record of this paper's transparent peer review process is included in the supplemental information.

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