Nicole A Becker, Justin P Peters, Elizabeth Lewis, Camden L Daby, Karl Clark, L James Maher
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引用次数: 0
摘要
自然原核生物基因抑制系统通常利用 DNA 循环,通过远端结合的抑制蛋白的贡献,增加受调控启动子上基因抑制蛋白的局部浓度。利用大肠杆菌 lac 操作子的原理,我们设计了基于目标序列可编程转录激活因子样效应二聚体(TALED)蛋白的类似抑制系统。这种工程开关可能对合成生物学和治疗应用很有价值。以前的 TALED 具有可诱导的非共价二聚化,但由于抑制蛋白的二聚化平衡,这种基于 DNA 环的抑制显示出了可检测到的有限抑制。在这里,我们展示了共价 TALED 强大的 DNA 环依赖性细菌启动子抑制作用,并验证了 DNA 环显著增强了大肠杆菌启动子抑制作用。我们利用一个热力学模型对抑制进行了描述,该模型量化了 DNA 循环的这种有利贡献。这项分析明确而定量地证明,经过优化的 TALED 蛋白可以在大肠杆菌中驱动环依赖性启动子抑制,其效果可与天然的 LacI 抑制剂系统相媲美。这项工作阐明了关键的设计原则,为广泛应用基于 DNA 环的 TALED 依赖性抑制目标基因奠定了基础。
Engineered transcription activator-like effector dimer proteins confer DNA loop-dependent gene repression comparable to Lac repressor.
Natural prokaryotic gene repression systems often exploit DNA looping to increase the local concentration of gene repressor proteins at a regulated promoter via contributions from repressor proteins bound at distant sites. Using principles from the Escherichia coli lac operon we design analogous repression systems based on target sequence-programmable Transcription Activator-Like Effector dimer (TALED) proteins. Such engineered switches may be valuable for synthetic biology and therapeutic applications. Previous TALEDs with inducible non-covalent dimerization showed detectable, but limited, DNA loop-based repression due to the repressor protein dimerization equilibrium. Here, we show robust DNA loop-dependent bacterial promoter repression by covalent TALEDs and verify that DNA looping dramatically enhances promoter repression in E. coli. We characterize repression using a thermodynamic model that quantitates this favorable contribution of DNA looping. This analysis unequivocally and quantitatively demonstrates that optimized TALED proteins can drive loop-dependent promoter repression in E. coli comparable to the natural LacI repressor system. This work elucidates key design principles that set the stage for wide application of TALED-dependent DNA loop-based repression of target genes.
期刊介绍:
Nucleic Acids Research (NAR) is a scientific journal that publishes research on various aspects of nucleic acids and proteins involved in nucleic acid metabolism and interactions. It covers areas such as chemistry and synthetic biology, computational biology, gene regulation, chromatin and epigenetics, genome integrity, repair and replication, genomics, molecular biology, nucleic acid enzymes, RNA, and structural biology. The journal also includes a Survey and Summary section for brief reviews. Additionally, each year, the first issue is dedicated to biological databases, and an issue in July focuses on web-based software resources for the biological community. Nucleic Acids Research is indexed by several services including Abstracts on Hygiene and Communicable Diseases, Animal Breeding Abstracts, Agricultural Engineering Abstracts, Agbiotech News and Information, BIOSIS Previews, CAB Abstracts, and EMBASE.
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