Pavinee Kurdrid scite author profile

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 twocomponent 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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Comparative analysis of the Spirulina platensis subcellular proteome in response to low- and high-temperature stresses: uncovering cross-talk of signaling components

Kurdrid

Senachak

Sirijuntarut

et al. 2011

Proteome Sci

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The present study focused on comparative proteome analyses of low- and high-temperature stresses and potential protein-protein interaction networks, constructed by using a bioinformatics approach, in response to both stress conditions.The data revealed two important points: first, the results indicate that low-temperature stress is tightly linked with oxidative stress as well as photosynthesis; however, no specific mechanism is revealed in the case of the high-temperature stress response. Second, temperature stress was revealed to be linked with nitrogen and ammonia assimilation. Moreover, the data also highlighted the cross-talk of signaling pathways. Some of the detected signaling proteins, e.g., Hik14, Hik26 and Hik28, have potential interactions with differentially expressed proteins identified in both temperature stress conditions. Some differentially expressed proteins found in the Spirulina protein-protein interaction network were also examined for their physical interactions by a yeast two hybrid system (Y2H). The Y2H results obtained in this study suggests that the potential PPI network gives quite reliable potential interactions for Spirulina. Therefore, the bioinformatics approach employed in this study helps in the analysis of phenomena where proteome analyses of knockout mutants have not been carried out to directly examine for specificity or cross-talk of signaling components.

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Revealing the complementation of ferredoxin by cytochrome b 5 in the Spirulina-∆6-desaturation reaction by N-terminal fusion and co-expression of the fungal-cytochrome b 5 domain and Spirulina-∆6-acyl-lipid desaturase

Hongsthong

Subudhi²,

Sirijuntarut³

et al. 2006

Appl Microbiol Biotechnol

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Spirulina-acyl-lipid desaturases are integral membrane proteins found in thylakoid and plasma membranes. These enzymes catalyze the fatty acid desaturation process of Spirulina to yield gamma-linolenic acid (GLA) as the final desaturation product. It has been reported that the cyanobacterial desaturases use ferredoxin as an electron donor, whereas the acyl-lipid desaturase in plant cytoplasm and the acyl-CoA desaturase of animals and fungi use cytochrome b (5). The low level of ferredoxin present in Escherichia coli cells leads to an inability to synthesize GLA when the cells are transformed with the Spirulina-(6) desaturase, desD, and grown in the presence of the reaction substrate, linoleic acid. In this study, Spirulina-(6) desaturase, encoded by the desD gene, was N-terminally fused and co-expressed with the cytochrome b (5) domain from Mucor rouxii. The product, GLA, made heterologously in E. coli and Saccharomyces cerevisiae, was then detected and analyzed. The results revealed the production of GLA by Spirulina-(6) desaturase fused or co-expressed with cytochrome b (5) in E. coli cells, in which GLA production by this gene cannot occur in the absence of cytochrome b (5). Moreover, the GLA production ability in the E. coli host cells was lost after the single substitution mutation was introduced to H52 in the HPGG motif of the cytochrome b (5) domain. These results revealed the complementation of the ferredoxin requirement by the fusion or co-expression of the fungal-cytochrome b (5) domain in the desaturation process of Spirulina-(6) desaturase. Furthermore, the free form of cytochrome b (5) domain can also enhance GLA production by the Spirulina-desD gene in yeast cells.

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Revealing the key point of the temperature stress response of Arthrospira platensis C1 at the interconnection of C- and N- metabolism by proteome analyses and PPI networking

Kurdrid

Phuengcharoen

Senachak

et al. 2020

BMC Mol and Cell Biol

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Background: Growth-temperature stress causes biochemical changes in the cells and reduction of biomass yield. Quantitative proteome of Arthrospira platensis C1 in response to low-and high temperature stresses was previously analysed to elucidate the stress response mechanism. The data highlighted the linkage of signaling proteins and proteins involved in nitrogen and ammonia assimilation, photosynthesis and oxidative stress. Results: After phosphoproteome analysis was carried out in this study, the tentative temperature response cascade of A. platensis C1 was drawn based on data integration of quantitative proteome and phosphoproteome analysis and protein-protein interaction (PPI) networks. The integration revealed 31 proteins regulated at the proteinexpression and post-translational levels; thus, this group of proteins was designated bi-level regulated proteins. PPI networks were then constructed based on A. platensis C1 gene inference from publicly available interaction data. The key two-component system (TCS) proteins, SPLC1_S082010 and SPLC1_S230960, were identified as bi-level regulated proteins and were linked to SPLC1_S270380 or glutamate synthase, an important enzyme in nitrogen assimilation that synthesizes glutamate from 2-oxoglutarate, which is known as the signal compound that regulates the carbon/nitrogen (C/N) balance of cells. Moreover, the role of the p-site in the PPIs of some phosphoproteins of interest was determined using site-directed mutagenesis and a yeast two-hybrid system. Evidence showing the critical role of the p-site in the PPI was observed for the multi-sensor histidine kinase SPLC1_S041070 (Hik28) and glutamate synthase. PPI subnetwork also showed that the Hik28 involved with the enzymes in fatty acid desaturation and nitrogen metabolism. The effect of Hik28-deletion was validated by fatty acid analysis and measurement of photosynthetic activity under nitrogen depletion.

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Pavinee Kurdrid

Subcellular proteomic characterization of the high-temperature stress response of the cyanobacterium Spirulina platensis

Comparative analysis of the Spirulina platensis subcellular proteome in response to low- and high-temperature stresses: uncovering cross-talk of signaling components

Revealing the complementation of ferredoxin by cytochrome b 5 in the Spirulina-∆6-desaturation reaction by N-terminal fusion and co-expression of the fungal-cytochrome b 5 domain and Spirulina-∆6-acyl-lipid desaturase

Revealing the key point of the temperature stress response of Arthrospira platensis C1 at the interconnection of C- and N- metabolism by proteome analyses and PPI networking

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