Characterizing chloroplast sensor kinase

Q2 Agricultural and Biological Sciences

Bioscience Horizons Pub Date : 2009-06-01 DOI:10.1093/BIOHORIZONS/HZP022

I. Ibrahim

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引用次数: 1

Abstract

In higher plants and green algae, photosynthesis takes place within specialized sub-cellular organelles called chloroplasts. Chloroplasts were once prokaryotes and evolved by endosymbiosis from cyanobacteria. They contain a semi-autonomous genetic system that encodes for core proteins of photosynthetic reaction centres in the energy-transducing membrane known as the chloroplast thylakoid. The photosynthetic apparatus in the thylakoid membrane makes use of excitation energy from sunlight to remove four electrons and protons from two water molecules. The electrons transfer them to the electron acceptor ferredoxin and NADPþ, respectively. In this system, plastoquinone acts as a mobile electron and proton carrier between Photosystem I and Photosystem II in reduction–oxidation or ‘redox’ reactions. A balanced redox state in the chloroplast is important for efficient energy conversion. However, the slightest error could lead to photo-inactivation as well as DNA mutation. Therefore, photosynthetic enzymes that are involved in photosynthesis are tightly regulated. In this study we analyse the mechanism of redox regulation involved in chloroplast gene expression that requires chloroplast sensor kinase (CSK). CSK is a bacterial-like histidine kinase that functions as a two-component system. Such simple but effective signalling transduction is abundant in prokaryotes, but found less widely in eukaryotic cells. CSK is encoded by the nuclear genomes of all higher plants examined, and the CSK proteins are targeted to chloroplasts where they function as a redox sensor. Through the cloning process, the result expressed the full-length CSK and the putative sensor domain (GAF domain) into a pGEX-6P-2 plasmid containing a GST tag. The construction was over-expressed into Escherichia coli cells. From bioinformatics study, it was found that in higher plants CSK is a modified histidine kinase, whereas in diatoms and red algae it is a typical histidine kinase.

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叶绿体传感器激酶的特性

在高等植物和绿藻中，光合作用发生在称为叶绿体的特殊亚细胞细胞器内。叶绿体曾经是原核生物，由蓝藻内共生进化而来。它们包含一个半自主的遗传系统，该系统编码能量转导膜中称为叶绿体类囊体的光合反应中心的核心蛋白质。类囊体膜中的光合作用装置利用来自阳光的激发能从两个水分子中去除四个电子和质子。电子将它们分别转移到电子受体铁氧还蛋白和NADPþ上。在这个系统中，质体醌在还原-氧化或“氧化还原”反应中作为光系统I和光系统II之间的移动电子和质子载体。叶绿体中平衡的氧化还原状态对于有效的能量转换是重要的。然而，最微小的错误可能导致光失活和DNA突变。因此，参与光合作用的光合酶受到严格的调控。在本研究中，我们分析了叶绿体基因表达的氧化还原调控机制，该机制需要叶绿体传感器激酶(chloroplast sensor kinase, CSK)的参与。CSK是一种细菌样组氨酸激酶，其功能为双组分系统。这种简单而有效的信号转导在原核生物中大量存在，但在真核细胞中较少发现。CSK由所有高等植物的核基因组编码，并且CSK蛋白靶向叶绿体，在那里它们作为氧化还原传感器起作用。通过克隆过程，结果将全长CSK和假定的传感器结构域(GAF结构域)表达到含有GST标签的pGEX-6P-2质粒中。该构建物在大肠杆菌细胞中过表达。通过生物信息学研究发现，在高等植物中，CSK是一种修饰的组氨酸激酶，而在硅藻和红藻中，它是一种典型的组氨酸激酶。

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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来源期刊

Bioscience Horizons Agricultural and Biological Sciences-Agricultural and Biological Sciences (all)

CiteScore

1.50

自引率

0.00%

发文量