在蓝藻中设计和分析 LacI 阻遏启动子和 DNA 环化。

Design and analysis of LacI-repressed promoters and DNA-looping in a cyanobacterium.

机构信息

Microbial Chemistry, Department of Chemistry-Ångström Laboratory, Science for Life Laboratory, Uppsala University, P,O, Box 523, SE-75120 Uppsala, Sweden.

出版信息

J Biol Eng. 2014 Jan 27;8(1):4. doi: 10.1186/1754-1611-8-4.

DOI:10.1186/1754-1611-8-4

PMID:24467947

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3922697/

Abstract

BACKGROUND

Cyanobacteria are solar-powered prokaryotes useful for sustainable production of valuable molecules, but orthogonal and regulated promoters are lacking. The Lac repressor (LacI) from Escherichia coli is a well-studied transcription factor that is orthogonal to cyanobacteria and represses transcription by binding a primary lac operator (lacO), blocking RNA-polymerase. Repression can be enhanced through DNA-looping, when a LacI-tetramer binds two spatially separated lacO and loops the DNA. Ptrc is a commonly used LacI-repressed promoter that is inefficiently repressed in the cyanobacterium Synechocystis PCC 6803. Ptrc2O, a version of Ptrc with two lacO, is more efficiently repressed, indicating DNA-looping. To investigate the inefficient repression of Ptrc and cyanobacterial DNA-looping, we designed a Ptrc-derived promoter library consisting of single lacO promoters, including a version of Ptrc with a stronger lacO (Ptrc1O-proximal), and dual lacO promoters with varying inter-lacO distances (the Ptrc2O-library).

RESULTS

We first characterized artificial constitutive promoters and used one for engineering a LacI-expressing strain of Synechocystis. Using this strain, we observed that Ptrc1O-proximal is similar to Ptrc in being inefficiently repressed. Further, the Ptrc2O-library displays a periodic repression pattern that remains for both non- and induced conditions and decreases with longer inter-lacO distances, in both E. coli and Synechocystis. Repression of Ptrc2O-library promoters with operators out of phase is less efficient in Synechocystis than in E. coli, whereas repression of promoters with lacO in phase is efficient even under induced conditions in Synechocystis. Two well-repressed Ptrc2O promoters were highly active when tested in absence of LacI in Synechocystis.

CONCLUSIONS

The artificial constitutive promoters herein characterized can be utilized for expression in cyanobacteria, as demonstrated for LacI. The inefficient repression of Ptrc and Ptrc1O-proximal in Synechocystis, as compared to E. coli, may be due to insufficient LacI expression, or differences in RNAP subunits. DNA-looping works as a transcriptional regulation mechanism similarly as in E. coli. DNA-looping contributes strongly to Ptrc2O-library repression in Synechocystis, even though they contain the weakly-repressed primary lacO of Ptrc1O-proximal and relatively low levels of LacI/cell. Hence, Synechocystis RNAP may be more sensitive to DNA-looping than E. coli RNAP, and/or the chromatin torsion resistance could be lower. Two strong and highly repressed Ptrc2O promoters could be used without induction, or together with an unstable LacI.

摘要

背景

蓝藻是利用太阳能的原核生物，可用于可持续生产有价值的分子，但缺乏正交和调控的启动子。来自大肠杆菌的 Lac 阻遏物（LacI）是一种研究得很好的转录因子，它与蓝藻正交，通过结合一个主要的 lac 操纵子（lacO）来抑制转录，阻止 RNA 聚合酶。当 LacI-四聚体结合两个空间分离的 lacO 并形成 DNA 环时，可以增强抑制作用。Ptrc 是一种常用的 LacI 抑制启动子，在蓝藻集胞藻 PCC 6803 中的抑制效率较低。Ptrc2O 是 Ptrc 的一个版本，带有两个 lacO，抑制效率更高，表明存在 DNA 环。为了研究 Ptrc 和蓝藻 DNA 环的抑制效率低下，我们设计了一个由单个 lacO 启动子组成的 Ptrc 衍生启动子文库，包括一个带有更强 lacO（Ptrc1O-proximal）的 Ptrc 版本和带有不同 lacO 间隔距离的双 lacO 启动子（Ptrc2O 文库）。

结果

我们首先对人工组成型启动子进行了表征，并使用其中一个启动子在集胞藻中构建了一个表达 LacI 的菌株。利用该菌株，我们观察到 Ptrc1O-proximal 与 Ptrc 一样，抑制效率较低。此外，Ptrc2O 文库显示出周期性的抑制模式，在大肠杆菌和集胞藻中均保持不变，并且随着 lacO 之间的距离增加而减小。在集胞藻中，与相位的 lacO 相比，失相的 Ptrc2O 文库启动子的抑制效率较低，而在诱导条件下，与相位的 lacO 相比，抑制效率较高。在集胞藻中，两个抑制效率较高的 Ptrc2O 启动子在没有 LacI 的情况下在集胞藻中表现出高度活性。

结论

本文所描述的人工组成型启动子可用于蓝藻的表达，如在 LacI 中的表达所示。与大肠杆菌相比，集胞藻中 Ptrc 和 Ptrc1O-proximal 的抑制效率较低，可能是由于 LacI 表达不足，或 RNA 聚合酶亚基的差异。DNA 环作为一种转录调控机制，在大肠杆菌中同样起作用。在集胞藻中，DNA 环对 Ptrc2O 文库的抑制作用很强，即使它们包含较弱抑制的 Ptrc1O-proximal 的主要 lacO 和相对较低水平的 LacI/细胞。因此，集胞藻 RNA 聚合酶可能比大肠杆菌 RNA 聚合酶对 DNA 环更敏感，或者染色质扭转阻力可能较低。两个强且高度抑制的 Ptrc2O 启动子可以在没有诱导的情况下使用，或者与不稳定的 LacI 一起使用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9b61/3922697/a0006f00fff3/1754-1611-8-4-1.jpg

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在蓝藻中设计和分析 LacI 阻遏启动子和 DNA 环化。

Design and analysis of LacI-repressed promoters and DNA-looping in a cyanobacterium.

机构信息

Microbial Chemistry, Department of Chemistry-Ångström Laboratory, Science for Life Laboratory, Uppsala University, P,O, Box 523, SE-75120 Uppsala, Sweden.