Subcellular proteomic characterization of the high-temperature stress response of the cyanobacterium Spirulina platensis
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  • 作者:Apiradee Hongsthong (1)
    Matura Sirijuntarut (3)
    Rayakorn Yutthanasirikul (3)
    Jittisak Senachak (1)
    Pavinee Kurdrid (1)
    Supapon Cheevadhanarak (2)
    Morakot Tanticharoen (1)
  • 刊名:Proteome Science
  • 出版年:2009
  • 出版时间:December 2009
  • 年:2009
  • 卷:7
  • 期:1
  • 全文大小:3394KB
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  • 作者单位:Apiradee Hongsthong (1)
    Matura Sirijuntarut (3)
    Rayakorn Yutthanasirikul (3)
    Jittisak Senachak (1)
    Pavinee Kurdrid (1)
    Supapon Cheevadhanarak (2)
    Morakot Tanticharoen (1)

    1. BEC Unit, National Center for Genetic Engineering and Biotechnology, 83 Moo8, Thakham, Bangkhuntien, Bangkok, 10150, Thailand
    3. Pilot Plant Development and Training Institute, King Mongkut's University of Technology Thonburi, 83 Moo8, Thakham, Bangkhuntien, Bangkok, 10150, Thailand
    2. School of Bioresources and Technology; King Mongkut's University of Technology Thonburi, 83 Moo8, Thakham, Bangkhuntien, Bangkok, 10150, Thailand
文摘
The present study examined the changes in protein expression in Spirulina platensis upon exposure to high temperature, with the changes in expression analyzed at the subcellular level. In addition, the transcriptional expression level of some differentially expressed proteins, the expression pattern clustering, and the protein-protein interaction network were analyzed. The results obtained from differential expression analysis revealed up-regulation of proteins involved in two-component response systems, DNA damage and repair systems, molecular chaperones, known stress-related proteins, and proteins involved in other biological processes, such as capsule formation and unsaturated fatty acid biosynthesis. The clustering of all differentially expressed proteins in the three cellular compartments showed: (i) the majority of the proteins in all fractions were sustained tolerance proteins, suggesting the roles of these proteins in the tolerance to high temperature stress, (ii) the level of resistance proteins in the photosynthetic membrane was 2-fold higher than the level in two other fractions, correlating with the rapid inactivation of the photosynthetic system in response to high temperature. Subcellular communication among the three cellular compartments via protein-protein interactions was clearly shown by the PPI network analysis. Furthermore, this analysis also showed a connection between temperature stress and nitrogen and ammonia assimilation.

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