Transcriptomic profiling of the salt-stress response in the halophyte Halogeton glomeratus

Wang, Juncheng; Li, Baochun; Meng, Yali; Ma, Xiao; Lai, Yong; Si, Erjing; Yang, Ke; Ren, Ping; Shang, Xianwen; Wang, Huajun

doi:10.1186/s12864-015-1373-z

Cited by 67 publications

(53 citation statements)

References 57 publications

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“…Consistent with our results, previous studies have shown that the levels of proteins related to CO 2 assimilation and light reactions of the Calvin cycle increased under salt stress (Wang et al. ). In addition, many studies have reported that the photosynthetic activity of algae under moderate stress is still high (Gao et al.…”

Section: Discussionsupporting

confidence: 93%

Photosynthetic activity and proteomic analysis highlights the utilization of atmospheric CO₂ by Ulva prolifera (Chlorophyta) for rapid growth

Gao

et al. 2016

Journal of Phycology

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Free-floating Ulva prolifera is one of the causative species of green tides. When green tides occur, massive mats of floating U. prolifera thalli accumulate rapidly in surface waters with daily growth rates as high as 56%. The upper thalli of the mats experience environmental changes such as the change in carbon source, high salinity, and desiccation. In this study, the photosynthetic performances of PSI and PSII in U. prolifera thalli exposed to different atmospheric carbon dioxide (CO ) levels were measured. Changes in photosynthesis within salinity treatments and dehydration under different CO concentrations were also analyzed. The results showed that PSII activity was enhanced as CO increased, suggesting that CO assimilation was enhanced and U. prolifera thalli can utilize CO in the atmosphere directly, even when under moderate stress. In addition, changes in the proteome of U. prolifera in response to salt stress were investigated. Stress-tolerance proteins appeared to have an important role in the response to salinity stress, whereas the abundance of proteins related to metabolism showed no significant change under low salinity treatments. These findings may be one of the main reasons for the extremely high growth rate of free-floating U. prolifera when green tides occur.

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Section: Discussionsupporting

confidence: 93%

Photosynthetic activity and proteomic analysis highlights the utilization of atmospheric CO₂ by Ulva prolifera (Chlorophyta) for rapid growth

Gao

et al. 2016

Journal of Phycology

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“…TF BTF3 homolog 4‐like was down‐regulated at 72 hr dehydration. BTF3 was earlier reported in salt stress response (Wang et al, ). Transcription repressor OFP1, transcription initiation factor IIE subunit alpha‐like and probable NOT transcription complex subunit VIP2 isoform X1 showed consistent up‐regulation under dehydration.…”

Section: Resultsmentioning

confidence: 76%

Dehydration‐responsive nuclear proteome landscape of chickpea (Cicer arietinum L.) reveals phosphorylation‐mediated regulation of stress response

Barua

Lande

Subba

et al. 2018

Plant Cell & Environment

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Nonavailability of water or dehydration remains recurring climatic disorder affecting yield of major food crops, legumes in particular. Nuclear proteins (NPs) and phosphoproteins (NPPs) execute crucial cellular functions that form the regulatory hub for coordinated stress response. Phosphoproteins hold enormous influence over cellular signalling. Four-week-old seedlings of a grain legume, chickpea, were subjected to gradual dehydration, and NPs were extracted from unstressed control and from 72- and 144-hr stressed tissues. We identified 4,832 NPs and 478 phosphosites, corresponding to 299 unique NPPs involved in multivariate cellular processes including protein modification and gene expression regulation, among others. The identified proteins included several novel kinases, phosphatases, and transcription factors, besides 660 uncharacterized proteins. Spliceosome complex and splicing related proteins were dominant among differentially regulated NPPs, indicating their dehydration modulated regulation. Phospho-motif analysis revealed stress-induced enrichment of proline-directed serine phosphorylation. Association mapping of NPPs revealed predominance of differential phosphorylation of spliceosome and splicing associated proteins. Also, regulatory proteins of key processes viz., protein degradation, regulation of flowering time, and circadian clock were observed to undergo dehydration-induced dephosphorylation. The characterization of novel regulatory proteins would provide new insights into stress adaptation and enable directed genetic manipulations for developing climate-resilient crops.

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“…The effect of salinity on decomposition may be attributed to low microbial activity 8 . High salinity severely affects plant growth 21 and productivity 22 , though some plants have physiological mechanisms to tolerate and recover from high salt stress 23 . On the other hand, the ameliorative role of SOD against oxidative stress is well documented 24,25 .…”

Section: Discussionmentioning

confidence: 99%

Exposure of <i>Eichhornia crassipes</i> (Mart.) Solms to Salt Water and its Implications

Imchen¹,

Sawant²,

Ezaz³

2017

Current Science

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In this article, we discuss the effect of salinity on the viability and decomposition of Eichhornia crassipes plant under normal photoperiod, dark condition and physiological response. Highest concentration of total organic carbon (27.43 mg C l -1 ) was recorded in 15 psu salinity after 45 days. The TOC output was more in case of leaf (3.6 mg C l -1 ) than petiole (2.39 mg C l -1 ) under dark condition, after 21 days in freshwater. Salt stress was found to enhance the superoxide dismutase activity at 20 psu in both leaf and petiole. Enzyme activity declined when salt-stressed plants were transferred to nutrient enriched freshwater. This indicated that 20 psu could be a plant's salt tolerance limit. The potential transfer test conducted in this study showed that Eichorrnia introduction through shipping activities is less likely.Keywords: Eichhornia crassipes, salinity stress, superoxide dismutase, total organic carbon.EICHHORNIA CRASSIPES (Mart.) Solms (water hyacinth) is an invasive aquatic macrophyte. The ability of the plant to flourish in any condition has made it a noxious and invasive weed in tropical and subtropical regions 1,2 . The plant has a wide range of tolerance to temperature, lighting conditions, pH, drought resistance and salinity 1,3 . The backwaters in Cochin including Cochin Port area, KeralaIndia, become infested by this plant during monsoon when the sluice gates of Thannermukkom salt-water barrier are opened. The sluice gates prevent the E. crassipes plants growing upstream to move downstream. As a consequence, the plant is subjected to a varying range of salinities both in the upstream and downstream areas. The high salinity condition affects the plant and it starts decaying. Further, these plants are also subjected to physical damage, breaking into pieces, due to movement of mechanized boats, trawlers and ships in the area. The dead plants generate detrital matter, which is a major organic source in an aquatic system. The extent of detritus decomposition depends on the type of metabolic activities taking place in the system 4 . During decomposition of the plants, three main types of microbial activity occuraerobic, facultative anaerobic and anaerobic. Besides these, various factors both external and biochemical are also involved in the process of decomposition 4-6 , biotic and abiotic 7,8 . However, some authors have indicated that tissue chemistry influences the decomposition process more than environmental conditions 3,9,10 . Earlier decomposition studies on E. crassipes showed that physical leaching and biological degradation are the two principal processes involved [11][12][13] . Litter decomposition is also influenced by nutrient concentration 14 , water salinity 15 and seasonal periodicity 16 . The sudden appearance of E. crassipes during monsoon in the Port area and its subsequent disappearance, add to the complexity of the ecosystem. It therefore, becomes imperative to investigate the organic matter supply to ecosystem due to plant decomposition. In view of the perennial E. crassip...

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Transcriptomic profiling of the salt-stress response in the halophyte Halogeton glomeratus

Cited by 67 publications

References 57 publications

Photosynthetic activity and proteomic analysis highlights the utilization of atmospheric CO₂ by Ulva prolifera (Chlorophyta) for rapid growth

Photosynthetic activity and proteomic analysis highlights the utilization of atmospheric CO₂ by Ulva prolifera (Chlorophyta) for rapid growth

Dehydration‐responsive nuclear proteome landscape of chickpea (Cicer arietinum L.) reveals phosphorylation‐mediated regulation of stress response

Exposure of <i>Eichhornia crassipes</i> (Mart.) Solms to Salt Water and its Implications

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Transcriptomic profiling of the salt-stress response in the halophyte Halogeton glomeratus

Cited by 67 publications

References 57 publications

Photosynthetic activity and proteomic analysis highlights the utilization of atmospheric CO2 by Ulva prolifera (Chlorophyta) for rapid growth

Photosynthetic activity and proteomic analysis highlights the utilization of atmospheric CO2 by Ulva prolifera (Chlorophyta) for rapid growth

Dehydration‐responsive nuclear proteome landscape of chickpea (Cicer arietinum L.) reveals phosphorylation‐mediated regulation of stress response

Exposure of <i>Eichhornia crassipes</i> (Mart.) Solms to Salt Water and its Implications

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Photosynthetic activity and proteomic analysis highlights the utilization of atmospheric CO₂ by Ulva prolifera (Chlorophyta) for rapid growth

Photosynthetic activity and proteomic analysis highlights the utilization of atmospheric CO₂ by Ulva prolifera (Chlorophyta) for rapid growth