A systems biology approach to investigate the response of Synechocystis sp. PCC6803 to a high salt environment.

Saline systems Pub Date : 2009-09-07 DOI:10.1186/1746-1448-5-8

Jagroop Pandhal, Josselin Noirel, Phillip C Wright, Catherine A Biggs

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引用次数: 26

Abstract

Background: Salt overloading during agricultural processes is causing a decrease in crop productivity due to saline sensitivity. Salt tolerant cyanobacteria share many cellular characteristics with higher plants and therefore make ideal model systems for studying salinity stress. Here, the response of fully adapted Synechocystis sp. PCC6803 cells to the addition of 6% w/v NaCl was investigated using proteomics combined with targeted analysis of transcripts.

Results: Isobaric mass tagging of peptides led to accurate relative quantitation and identification of 378 proteins, and approximately 40% of these were differentially expressed after incubation in BG-11 media supplemented with 6% salt for 9 days. Protein abundance changes were related to essential cellular functional alterations. Differentially expressed proteins involved in metabolic responses were also analysed using the probabilitistic tool Mixed Model on Graphs (MMG), where the role of energy conversion through glycolysis and reducing power through pentose phosphate pathway were highlighted. Temporal RT-qPCR experiments were also run to investigate protein expression changes at the transcript level, for 14 non-metabolic proteins. In 9 out of 14 cases the mRNA changes were in accordance with the proteins.

Conclusion: Synechocystis sp. PCC6803 has the ability to regulate essential metabolic processes to enable survival in high salt environments. This adaptation strategy is assisted by further regulation of proteins involved in non-metabolic cellular processes, supported by transcriptional and post-transcriptional control. This study demonstrates the effectiveness of using a systems biology approach in answering environmental, and in particular, salt adaptation questions in Synechocystis sp. PCC6803.

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用系统生物学方法研究聚囊藻PCC6803对高盐环境的响应。

背景:由于对盐的敏感性，农业生产过程中的盐过量导致作物生产力下降。耐盐蓝藻与高等植物具有许多相同的细胞特征，因此是研究盐胁迫的理想模型系统。本研究采用蛋白质组学和转录本靶向分析相结合的方法，研究了全适应聚囊藻PCC6803细胞对6% w/v NaCl的响应。结果:肽的等压质量标记使378个蛋白得到了准确的相对定量和鉴定，其中约40%的蛋白在添加6%盐的BG-11培养基中孵育9天后存在差异表达。蛋白质丰度变化与基本细胞功能改变有关。还使用概率工具混合图模型(MMG)分析了参与代谢反应的差异表达蛋白，其中强调了通过糖酵解的能量转换和通过戊糖磷酸途径的还原能力的作用。还进行了时间RT-qPCR实验，以研究14种非代谢蛋白在转录物水平上的蛋白表达变化。14例中有9例mRNA的变化与蛋白的变化一致。结论:聚囊藻PCC6803具有调节必需代谢过程的能力，使其能够在高盐环境中生存。这种适应策略是通过参与非代谢细胞过程的蛋白质的进一步调节来辅助的，并得到转录和转录后控制的支持。这项研究证明了使用系统生物学方法在回答Synechocystis sp. PCC6803的环境，特别是盐适应问题方面的有效性。

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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Saline systems

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