Salt-adaptive strategies in oil seed crop Ricinus communis early seedlings (cotyledon vs. true leaf) revealed from proteomics analysis.

[1]  M. Yusupov,et al.  Structural Insights into the Role of Diphthamide on Elongation Factor 2 in mRNA Reading-Frame Maintenance. , 2018, Journal of molecular biology.

[2]  B. Blasco,et al.  Hydrogen sulphide increase the tolerance to alkalinity stress in cabbage plants (Brassica oleracea L. 'Bronco') , 2018 .

[3]  A. Kumari,et al.  Metabolomics and network analysis reveal the potential metabolites and biological pathways involved in salinity tolerance of the halophyte Salvadora persica , 2018 .

[4]  Yunxia Zhang,et al.  Comparative Proteomics of Contrasting Maize Genotypes Provides Insights into Salt-Stress Tolerance Mechanisms. , 2018, Journal of proteome research.

[5]  P. Jha,et al.  Quantitative proteomics analysis reveals the tolerance of wheat to salt stress in response to Enterobacter cloacae SBP-8 , 2017, PloS one.

[6]  U. Roessner,et al.  Epidermal bladder cells confer salinity stress tolerance in the halophyte quinoa and Atriplex species. , 2017, Plant, cell & environment.

[7]  G. Hu,et al.  Proteome dynamics and physiological responses to short-term salt stress in Leymus chinensis leaves , 2017, PloS one.

[8]  A. Fernie,et al.  Protein-protein interactions and metabolite channelling in the plant tricarboxylic acid cycle , 2017, Nature Communications.

[9]  Xiaojuan Li,et al.  iTRAQ‐based quantitative proteomic analysis of wheat roots in response to salt stress , 2017, Proteomics.

[10]  M. Acencio,et al.  Impacts of the overexpression of a tomato translationally controlled tumor protein (TCTP) in tobacco revealed by phenotypic and transcriptomic analysis , 2017, Plant Cell Reports.

[11]  Yingnan Wang,et al.  Effects of arbuscular mycorrhizal fungi on the growth, photosynthesis and photosynthetic pigments of Leymus chinensis seedlings under salt-alkali stress and nitrogen deposition. , 2017, The Science of the total environment.

[12]  Xiaoping Niu,et al.  Proteomic changes in kenaf (Hibiscus cannabinus L.) leaves under salt stress. , 2016 .

[13]  Sixue Chen,et al.  Na2CO3-responsive mechanisms in halophyte Puccinellia tenuiflora roots revealed by physiological and proteomic analyses , 2016, Scientific Reports.

[14]  K. Kosová,et al.  Proteomic Response of Hordeum vulgare cv. Tadmor and Hordeum marinum to Salinity Stress: Similarities and Differences between a Glycophyte and a Halophyte , 2016, Front. Plant Sci..

[15]  Sixue Chen,et al.  Chilling-responsive mechanisms in halophyte Puccinellia tenuiflora seedlings revealed from proteomics analysis. , 2016, Journal of proteomics.

[16]  G. Zhu,et al.  Proteomic and phosphoproteomic analysis reveals the response and defense mechanism in leaves of diploid wheat T. monococcum under salt stress and recovery. , 2016, Journal of proteomics.

[17]  Qiuying Pang,et al.  Global proteomic mapping of alkali stress regulated molecular networks in Helianthus tuberosus L. , 2016, Plant and Soil.

[18]  M. Ludwig Evolution of carbonic anhydrase in C4 plants. , 2016, Current opinion in plant biology.

[19]  N. A. El-Kader,et al.  Redox halopriming: A Promising Strategy for Inducing Salt Tolerance in Bread Wheat , 2016 .

[20]  Qiuying Pang,et al.  Integrated proteomics and metabolomics for dissecting the mechanism of global responses to salt and alkali stress in Suaeda corniculata , 2016, Plant and Soil.

[21]  Yingnan Wang,et al.  Physiological and biochemical responses of Jerusalem artichoke seedlings to mixed salt-alkali stress conditions. , 2015 .

[22]  F. Baluška,et al.  Nitric oxide accumulation and protein tyrosine nitration as a rapid and long distance signalling response to salt stress in sunflower seedlings. , 2015, Nitric oxide : biology and chemistry.

[23]  Shucai Wang,et al.  Physiological Strategies of Sunflower Exposed to Salt or Alkali Stresses: Restriction of Ion Transport in the Cotyledon Node Zone and Solute Accumulation , 2015 .

[24]  Jie Liu,et al.  Proteomic Analysis of Seedling Roots of Two Maize Inbred Lines That Differ Significantly in the Salt Stress Response , 2015, PloS one.

[25]  Hao Ma,et al.  Comparative proteomic analysis reveals molecular mechanism of seedling roots of different salt tolerant soybean genotypes in responses to salinity stress , 2014 .

[26]  H. Hilhorst,et al.  Physiological and biochemical responses of Ricinus communis seedlings to different temperatures: a metabolomics approach , 2014, BMC Plant Biology.

[27]  Jiachao Zhou,et al.  The role of cotyledons in the establishment of Suaeda physophora seedlings , 2014 .

[28]  Yanrong Wang,et al.  Overexpression of an alfalfa GDP-mannose 3, 5-epimerase gene enhances acid, drought and salt tolerance in transgenic Arabidopsis by increasing ascorbate accumulation , 2014, Biotechnology Letters.

[29]  M. C. Lima Neto,et al.  Dissipation of excess photosynthetic energy contributes to salinity tolerance: a comparative study of salt-tolerant Ricinus communis and salt-sensitive Jatropha curcas. , 2014, Journal of plant physiology.

[30]  X. Li,et al.  Physiological adaptive mechanisms of Leymus chinensis during germination and early seedling stages under saline and alkaline conditions. , 2014 .

[31]  P. Qin,et al.  Castor bean growth and rhizosphere soil property response to different proportions of arbuscular mycorrhizal and phosphate-solubilizing fungi , 2014, Ecological Research.

[32]  J. Peralta-Videa,et al.  Seedling emergence, growth, and leaf mineral nutrition of Ricinus communis L. cultivars irrigated with saline solution , 2013 .

[33]  Lizhong He,et al.  Proteomics reveal cucumber Spd-responses under normal condition and salt stress. , 2013, Plant physiology and biochemistry : PPB.

[34]  T. Chung,et al.  The effects of NaCl stress on Jatropha cotyledon growth and nitrogen metabolism , 2013 .

[35]  Tai Wang,et al.  Physiological and molecular features of Puccinellia tenuiflora tolerating salt and alkaline-salt stress. , 2013, Journal of integrative plant biology.

[36]  B. Jurczyk,et al.  Short-term growth of meadow fescue with atmospheric CO2 enrichment decreases freezing tolerance, modifies photosynthetic apparatus performance and changes the expression of some genes during cold acclimation , 2013, Acta Physiologiae Plantarum.

[37]  Sixue Chen,et al.  Comparative Proteomic Analysis of Puccinellia tenuiflora Leaves under Na2CO3 Stress , 2013, International journal of molecular sciences.

[38]  G. Guo,et al.  Comparative proteomic analysis of salt response proteins in seedling roots of two wheat varieties. , 2012, Journal of proteomics.

[39]  Walid A Houry,et al.  The role of Hsp90 in protein complex assembly. , 2012, Biochimica et biophysica acta.

[40]  Guangdi D. Li,et al.  Comparison of inorganic solute accumulation in shoots, radicles and cotyledons of Vicia cracca during the seedling stage under NaCl stress , 2012 .

[41]  P. Qin,et al.  Ameliorative effect of castor bean (Ricinus communis L.) planting on physico-chemical and biological properties of seashore saline soil , 2012 .

[42]  M. Janmohammadi,et al.  Influence of NaCl treatments on growth and biochemical parameters of castor bean (Ricinus communis L.) , 2012, Acta agriculturae Slovenica.

[43]  L. You,et al.  Effects of Salinity on Metabolic Profiles, Gene Expressions, and Antioxidant Enzymes in Halophyte Suaeda salsa , 2011, Journal of Plant Growth Regulation.

[44]  R. Oomen,et al.  Over-expression of an Na+-and K+-permeable HKT transporter in barley improves salt tolerance. , 2011, The Plant journal : for cell and molecular biology.

[45]  K. Dietz Peroxiredoxins in plants and cyanobacteria. , 2011, Antioxidants & redox signaling.

[46]  Sixue Chen,et al.  Physiological and proteomic analysis of salinity tolerance in Puccinellia tenuiflora. , 2011, Journal of proteome research.

[47]  Sixue Chen,et al.  Proteomic identification of differentially expressed proteins in Arabidopsis in response to methyl jasmonate. , 2011, Journal of plant physiology.

[48]  A. K. Swami,et al.  Differential proteomic analysis of salt stress response in Sorghum bicolor leaves , 2011 .

[49]  J. Hershey,et al.  Eukaryotic translation initiation factor (eIF) 5A stimulates protein synthesis in Saccharomyces cerevisiae , 2011, Proceedings of the National Academy of Sciences.

[50]  Karl H. Mühling,et al.  Proteomic changes in maize roots after short‐term adjustment to saline growth conditions , 2010, Proteomics.

[51]  J. Kopka,et al.  Metabolome and water homeostasis analysis of Thellungiella salsuginea suggests that dehydration tolerance is a key response to osmotic stress in this halophyte. , 2010, The Plant journal : for cell and molecular biology.

[52]  G. Abogadallah Insights into the significance of antioxidative defense under salt stress , 2010, Plant signaling & behavior.

[53]  Nobuhiro Suzuki,et al.  Reactive oxygen species homeostasis and signalling during drought and salinity stresses. , 2010, Plant, cell & environment.

[54]  Pei Qin,et al.  Leaf chlorophyll fluorescence, hyperspectral reflectance, pigments content, malondialdehyde and proline accumulation responses of castor bean (Ricinus communis L.) seedlings to salt stress levels , 2010 .

[55]  Z. Cui,et al.  The microfilament cytoskeleton plays a vital role in salt and osmotic stress tolerance in Arabidopsis. , 2010, Plant biology.

[56]  Changhua Jiang,et al.  RceIF5A, encoding an eukaryotic translation initiation factor 5A in Rosa chinensis, can enhance thermotolerance, oxidative and osmotic stress resistance of Arabidopsis thaliana , 2010, Plant Molecular Biology.

[57]  A. Naceur,et al.  Effects of salt stress on photosynthesis, PSII photochemistry and thermal energy dissipation in leaves of two corn (Zea mays L.) varieties , 2009, Photosynthetica.

[58]  T. Thannhauser,et al.  Aluminum induced proteome changes in tomato cotyledons , 2009, Plant signaling & behavior.

[59]  J. Flexas,et al.  Photosynthesis under drought and salt stress: regulation mechanisms from whole plant to cell. , 2009, Annals of botany.

[60]  J. González,et al.  The role of cotyledon metabolism in the establishment of quinoa (Chenopodium quinoa) seedlings growing under salinity , 2009, Plant and Soil.

[61]  G. Surabhi,et al.  Proteomic analysis of salt stress responses in foxtail millet (Setaria italica L. cv. Prasad) seedlings , 2008 .

[62]  M. Heidari,et al.  Salinity effects on compatible solutes, antioxidants enzymes and ion content in three wheat cultivars. , 2008, Pakistan journal of biological sciences : PJBS.

[63]  J. V. Silva,et al.  Leaf gas exchange, chloroplastic pigments and dry matter accumulation in castor bean (Ricinus communis L) seedlings subjected to salt stress conditions , 2008 .

[64]  Volkhard Scholz,et al.  Prospects and risks of the use of castor oil as a fuel , 2008 .

[65]  S. Yadav,et al.  AN OVERVIEW ON THE ROLE OF METHYLGLYOXAL AND GLYOXALASES IN PLANTS , 2008, Drug metabolism and drug interactions.

[66]  Deli Wang,et al.  Osmotic adjustment and ion balance traits of an alkali resistant halophyte Kochia sieversiana during adaptation to salt and alkali conditions , 2007, Plant and Soil.

[67]  R. Munns Genes and salt tolerance: bringing them together. , 2005, The New phytologist.

[68]  R. Mittler,et al.  Reactive oxygen gene network of plants. , 2004, Trends in plant science.

[69]  M. Hills Control of storage-product synthesis in seeds. , 2004, Current opinion in plant biology.

[70]  I. Sánchez-Aguayo,et al.  Molecular characterization of glyoxalase-I from a higher plant; upregulation by stress , 1995, Plant Molecular Biology.

[71]  I. D. Teare,et al.  Rapid determination of free proline for water-stress studies , 1973, Plant and Soil.

[72]  J. Oliveira,et al.  Proline accumulation and glutamine synthetase activity are increased by salt-induced proteolysis in cashew leaves. , 2003, Journal of plant physiology.

[73]  H. Rolletschek,et al.  Control of storage protein accumulation during legume seed development , 2001 .

[74]  R. Bressan,et al.  The dawn of plant salt tolerance genetics. , 2000, Trends in plant science.

[75]  H. Mock,et al.  Influence of cesium on tetrapyrrole biosynthesis in etiolated and greening barley leaves , 1997 .

[76]  A. Huang Oleosins and Oil Bodies in Seeds and Other Organs , 1996, Plant physiology.

[77]  F. Hartl,et al.  Chapter 26 Chaperonin-mediated protein folding , 1992 .

[78]  T. Kozlowski,et al.  Importance of Photosynthetic Cotyledons for Early Growth of Woody Angiosperms , 1976 .

[79]  P. Lovell,et al.  COTYLEDON PHOTOSYNTHESIS DURING SEEDLING DEVELOPMENT IN ACER , 1976 .