Mitigative effects of spermidine on photosynthesis and carbon–nitrogen balance of cucumber seedlings under Ca(NO3)2 stress

详细信息    查看全文

• 作者：Jing Du ; Sheng Shu ; Qiaosai Shao ; Yahong An ; Heng Zhou…
• 关键词：Ca(NO3)2 stress ; Carbon–nitrogen balance ; Cucumis sativus L. ; Photosynthesis ; Spermidine
• 刊名：Journal of Plant Research
• 出版年：2016
• 出版时间：January 2016
• 年：2016
• 卷：129
• 期：1
• 页码：79-91
• 全文大小：631 KB
• 参考文献：Agren GI, Wetterstedt JAM, Billberger MFK (2012) Nutrient limitation on terrestrial plant growth—modeling the interaction between nitrogen and phosphorus. New Phytol 194:953–960PubMed CrossRef
  Ahmad P, Sharma S (2008) Salt stress and phytobiochemical responses of plants. Plant Soil Environ 54:89–99
  Alcázar R, Altabella T, Marco F, Bortolotti C, Reymond M, Koncz C, Carrasco P, Tiburcio AF (2010) Polyamines: molecules with regulatory functions in plant abiotic stress tolerance. Planta 231:1237–1249PubMed CrossRef
  Alcázar R, Cuevas JC, Planas J, Zarza X, Bortolotti C, Carrasco P, Salinas J, Tiburcio AF, Altabella T (2011) Integration of polyamines in the cold acclimation response. Plant Sci 180:31–38PubMed CrossRef
  Aurisano N, Bertani A, Reggiani R (1995) Involvement of calcium and calmodulin in protein and amino acid metabolism in rice roots under anoxia. Plant Cell Physiol 36:1525–1529
  Bao A, Zhao Z, Ding G, Shi L, Xu F, Cai H (2014) Accumulated expression level of cytosolic glutamine synthetase 1 gene (OsGS1;1 or OsGS1;2) alter plant development and the carbon-nitrogen metabolic status in rice. PLoS One 9(4):e95581PubMed PubMedCentral CrossRef
  Bradford MM (1976) A rapid method for the quantitation of microgram quantities of protein utilizing the principle of protein–dye binding. Anal Biochem 72:248–254PubMed CrossRef
  Buysse J, Merckx R (1993) An important colorimetric method to quantify sugar content of 307 plant tissue. J Exp Bot 44:1627–1629CrossRef
  Campbell WH (2001) Structure and function of eukaryotic NAD(P)H: nitrate reductase. Cell Mol Life Sci 58:194–204PubMed CrossRef
  Cataldo DA, Haroon M, Schrader LE, Youngs VL (1975) Rapid colorimetric determination of nitrate in plant tissue by nitration of salicylic acid. Commun Soil Sci Plant Anal 6:71–80CrossRef
  Datta R, Sharma R (1999) Temporal and spatial regulation of nitrate reductase and nitrite reductase in greening maize leaves. Plant Sci 144:77–83CrossRef
  Debez A, Saadaoui D, Ramani B, Ouerghi Z, Koyro H-W, Huchzermeyer B, Abdelly C (2006) Leaf H+-ATPase activity and photosynthetic capacity of Cakile maritima under increasing salinity. Environ Exp Bot 57:285–295CrossRef
  Demetriou G, Neonaki C, Navakoudis E, Kotzabasis K (2007) Salt stress impact on the molecular structure and function of the photosynthetic apparatus—the protective role of polyamines. Biochim Biophys Acta 1767:272–280PubMed CrossRef
  Desikan R, Griffiths R, Hancock J, Neill S (2002) A new role for an old enzyme: nitrate reductase mediated nitric oxide generation is required for abscisic acid-induced stomatal closure in Arabidopsis thaliana. Proc Natl Acad Sci 99:16314–16318PubMed PubMedCentral CrossRef
  Evans JR (1989) Photosynthesis and nitrogen relationships in leaves of C3 plants. Oecologia 78:9–19CrossRef
  Fariduddin Q, Varshney P, Yusuf M, Ahmad A (2013) Polyamines: potent modulators of plant responses to stress. J Plant Interact 8:1–16CrossRef
  Farquhar GD, Sharkey TD (1982) Stomatal conductance and photosynthesis. Annu Rev Plant Physiol 33:317–345CrossRef
  Flowers TJ, Colmer TD (2008) Salinity tolerance in halophytes. New Phytol 179:945–963PubMed CrossRef
  Fontaine JX, Tercé-Laforgue T, Armengaud P, Clément G, Renou JP, Pelletier S, Catterou M, Azzopardi M, Gibon Y, Lea PJ, Hirel B, Dubois F (2012) A characterization of a NADH-dependent glutamate dehydrogenase mutant of Arabidopsis demonstrates the key role of this enzyme in root carbon and nitrogen metabolism. Plant Cell 24:4044–4065PubMed PubMedCentral CrossRef
  Forde BG, Lea PJ (2007) Glutamate in plants: metabolism, regulation, and signalling. J Exp Bot 58:2339–2358PubMed CrossRef
  Foyer CH, Noctor G, Verrier P (2006) Photosynthetic carbon nitrogen interactions: modelling inter-pathway control and signalling. In: Plaxton W, McManus MT (eds) Annual plant reviews: control of primary metabolism in plants, chapter 14. Blackwell, Oxford, pp 325–347CrossRef
  Foyer CH, Noctor G, Hodges M (2011) Respiration and nitrogen assimilation: targeting mitochondria-associated metabolism as a means to enhance nitrogen use efficiency. J Exp Bot 62:1467–1482PubMed CrossRef
  Gupta K, Dey A, Gupta B (2013) Plant polyamines in abiotic stress responses. Acta Physiol Plant 35:2015–2036CrossRef
  Hussin S, Geissler N, Koyro HW (2013) Effect of NaCl salinity on Atriplex nummularia (L.) with special emphasis on carbon and nitrogen metabolism. Acta Physiol Plant 35:1025–1038CrossRef
  Kasukabe Y, He L, Nada K, Misawa S, Ihara I, Tachibana S (2004) Overexpression of Spermidine synthase enhances tolerance to multiple environmental stresses and up-regulates the expression of various stress-regulated genes in transgenic Arabidopsis thaliana. Plant Cell Physiol 45:712–722PubMed CrossRef
  Kavi Kishor PB, Sangam S, Amrutha RN, Sri Laxmi P, Naidu KR, Rao KRSS, Rao S, Reddy KJ, Theriappan P, Sreenivasulu N (2005) Regulation of proline biosynthesis, degradation, uptake and transport in higher plants: its implications in plant growth and abiotic stress tolerance. Curr Sci 88:424–438
  Keys AJ (2006) The re-assimilation of ammonia produced by photorespiration and the nitrogen economy of C3 higher plants. Photosynth Res 87:165–175PubMed CrossRef
  Kitamura Y, Yano T, Honna T, Yamamoto S, Inosako K (2006) Causes of farmland salinization and remedial measures in the Aral Sea basin-research on water management to prevent secondary salinization in rice-based cropping system in arid land. Agric Water Manage 85:1–14CrossRef
  Koyro HW, Ahmad P, Geissler N (2012) Abiotic stress responses in plants: an overview. In: Ahmad P, Prasad MNV (eds) Environmental adaptations and stress tolerance of plants in the era of climate change, chapter 1. Springer, New York, pp 1–28CrossRef
  Kronzucker HJ, Brittoa DT, Davenportb RJ, Testerb M (2001) Ammonium toxicity and the real cost of transport. Trends Plant Sci 6:335–337PubMed CrossRef
  Kusano T, Berberich T, Tateda C, Takahashi Y (2008) Polyamines: essential factors for growth and survival. Planta 228:367–381PubMed CrossRef
  Labboun S, Tercé-Laforgue T, Roscher A, Bedu M, Restivo FM, Velanis CN, Skopelitis DS, Moschou PN, Roubelakis-Angelakis KA, Suzuki A, Hirel B (2009) Resolving the role of plant glutamate dehydrogenase. I. In vivo real time nuclear magnetic resonance spectroscopy experiments. Plant Cell Physiol 50:1761–1773PubMed PubMedCentral CrossRef
  Lea PJ, Miflin BJ (2011) Nitrogen assimilation and its relevance to crop improvement. In: Foyer CH, Zhang H (eds) Nitrogen metabolism in plants in the Post-Genomic Era. Wiley-Blackwell, Chichester, pp 1–40
  Li D, Wu Z, Liang C, Chen L (2004) Characteristics and regulation of greenhouse soil environment. Chin J Ecol 23:192–197
  Lin CC, Kao CH (1996) Disturbed ammonium assimilation is associated with growth inhibition of roots in rice seedlings caused by NaCl. Plant Growth Regul 18:233–238CrossRef
  Liu K, Fu HH, Bei QX, Luan S (2000) Inward potassium channel in guard cells as a target for polyamine regulation of stomatal movements. Plant Physiol 124:1315–1325PubMed PubMedCentral CrossRef
  Lòpez-Millàn AF, Morales F, Andaluz S, Gogorcena Y, Abadìa A, De Las Rivas J, Abadìa J (2000) Responses of sugar beet roots to iron deficiency. Changes in carbon assimilation and oxygen use. Plant Physiol 124:885–897PubMed PubMedCentral CrossRef
  Mansour MMF (2000) Nitrogen containing compounds and adaptation of plants to salinity stress. Biol Plant 43:491–500CrossRef
  Mattoo AK, Sobolev AP, Neelam A, Goyal RK, Handa AK, Segre AL (2006) Nuclear magnetic resonance spectroscopy-based metabolite profiling of transgenic tomato fruit engineered to accumulate spermidine and spermine reveals enhanced anabolic and nitrogen–carbon interactions. Plant Physiol 142:1759–1770PubMed PubMedCentral CrossRef
  Miura K (2013) Nitrogen and phosphorus nutrition under salinity stress. In: Ecophysiology and responses of plants under salt stress. Springer, pp 425–441
  Novitskaya S, Trevanion SD, Driscoll CH Foyer, Noctor G (2002) How does photorespiration modulate leaf amino acid contents. A dual approach through modelling and metabolite analysis. Plant Cell Environ 25:821–836CrossRef
  Nunes-Nesi A, Fernie AR, Stitt M (2010) Metabolic and signaling aspects underpinning the regulation of plant carbon nitrogen interactions. Mol Plant 3:973–996PubMed CrossRef
  Rosales EP, Iannone MF, Groppa MD, Benavides MP (2012) Polyamines modulate nitrate reductase activity in wheat leaves: involvement of nitric oxide. Amino Acids 42:857–865PubMed CrossRef
  Roy P, Niyogi K, Sengupta DN, Ghosh B (2005) Spermidine treatment to rice seedlings recovers salinity stress induced damage of plasma membrane and PM-bound H+-ATPase in salt-tolerant and salt sensitive rice cultivars. Plant Sci 168:583–591CrossRef
  Schlüter U, Colmsee C, Scholz U, Bräutigam A, Weber APM, Zellerhoff N, Bucher M, Fahnenstich H, Schlüter US (2013) Adaptation of maize source leaf metabolism to stress related disturbances in carbon, nitrogen and phosphorus balance. BMC Genom 14:442CrossRef
  Shevyakova NI, Shorina MV, Rakitin VY, Kuznetsov W (2006) Stress-dependent accumulation of spermidine and spermine in the halophyte Mesembryanthemum crystalinum under salinity conditions. Russ J Plant Physiol 53:739–745CrossRef
  Shevyakova NI, Ilina EN, Stetsenko LA, Kuznetsov VIV (2010) Nickel accumulation in rape shoots (Brassica napus L.) increased by putrescine. Int J Phytoremediation 13:345–356CrossRef
  Shi H, Chan Z (2014) Improvement of plant abiotic stress tolerance through modulation of the polyamine pathway. J Integr Plant Biol 56:114–121PubMed CrossRef
  Shi H, Ye T, Chan Z (2013a) Comparative proteomic and physiological analyses reveal the protective effect of exogenous polyamines in the bermuda grass (Cynodon dactylon) response to salt and drought stresses. J Proteome Res 12:4807–4829CrossRef
  Shi H, Ye T, Chen F, Cheng Z, Wang Y, Yang P, Zhang Y, Chan Z (2013b) Manipulation of arginase expression modulates abiotic stress tolerance in Arabidopsis: effect on arginine metabolism and ROS accumulation. J Exp Bot 64:1367–1379PubMed PubMedCentral CrossRef
  Shu S, Guo S, Sun J, Yuan L (2012a) Effects of salt stress on the structure and function of the photosynthetic apparatus in Cucumis sativus and its protection by exogenous putrescine. Physiol Plantarum 146:285–296CrossRef
  Shu S, Guo S, Yuan L (2012b) A review: polyamines and photosynthesis, advances in photosynthesis—fundamental aspects. InTech, pp 440–464
  Singh RP, Srivastava HS (1983) Regulation of glutamate dehydrogenase activity by amino acids in maize seedlings. Physiol Plant 57:549–554CrossRef
  Skopelitis DS, Paranychianakis NV, Paschalidis KA, Pliakonis ED, Delis ID, Yakoumakis DI, Kouvarakis A, Papadakis AK, Stephanou EG, Roubelakis-Angelakis KA (2006) Abiotic stress generates ROS that signal expression of anionic glutamate dehydrogenases to form glutamate for proline synthesis in tobacco and grapevine. Plant Cell 18:2767–2781PubMed PubMedCentral CrossRef
  Skopelitis DS, Paranychiankis NV, Kouvarakis A, Spyros A, Stephanou EG, Roubelakis-Angelakis KA (2007) The isoenzyme 7 of tobacco NADH-dependent glutamate dehydrogenase exhibits high deaminating and low aminating activity. Plant Physiol 145:1–9CrossRef
  Skrdleta V, Gaudinova A, Nemcova M (1979) Relationships between nitrate level, nitrate reductase activity and anaerobic nitrite production in Pisum sativum leaf tissue. Biol Plant 21:307–310CrossRef
  Slama I, Ghnaya T, Hssini K, Messedi D, Savouré A, Abdelly C (2007) Comparative study of mannitol and PE osmotic stress effects on growth, and solute accumulation in Sesuvium portulacastrum. Environ Exp Bot 61:10–17CrossRef
  Solorzano L (1969) Determination of ammonia in natural waters by the phenolhy pochlorite method. Limnol Oceanogr 14:799–801CrossRef
  Sun W, Huang A, Sang Y, Fu Y, Yang Z (2013) Carbon–nitrogen interaction modulates plant growth and expression of metabolic genes in rice. J Plant Growth Regul 32:575–584CrossRef
  Takahashi T, Kakehi JI (2010) Polyamines: ubiquitous polycations with unique roles in growth and stress responses. Ann Bot 105:1–6PubMed PubMedCentral CrossRef
  Tassoni A, Franceschetti M, Bagni N (2008) Polyamines and salt stress response and tolerance in Arabidopsis thaliana flowers. Plant Physiol Biochem 46:607–613PubMed CrossRef
  Todorova D, Katerova Z, Sergiev I, Alexieva V (2013) Role of polyamines in alleviating salt stress. ecophysiology and responses of plants under salt stress. In: Ahmad P, Azooz MM, Prasad MNV (eds) Chapter 13. Springer, New York, pp 355–380
  Tonon G, Kevers C, Rampant OF, Graziani M, Gaspar T (2004) Effect of NaCl and mannitol iso-osmotic stresses on proline and free polyamine levels in embryogenic Fraxinus angustifolia callus. J Plant Physiol 161:701–708PubMed CrossRef
  Vinocur B, Altman A (2005) Cellular basis of salinity tolerance in plants. Environ Exp Bot 52:113–122
  Wang ZQ, Yuan YZ, Ou JQ, Lin QH, Zhang CF (2007) Glutamine synthetase and glutamate dehydrogenase contribute differentially to proline accumulation in leaves of wheat (Triticum aestivum) seedlings exposed to different salinity. J Plant Physiol 164:695–701PubMed CrossRef
  Wang H, Wu Z, Han J, Zheng W, Yang C (2012) Comparison of ion balance and nitrogen metabolism in old and young leaves of alkali-stressed rice plants. PLoS One 7(5):e37817PubMed PubMedCentral CrossRef
  Wei G, Yang L, Zhu Y, Chen G (2009) Changes in oxidative damage, antioxidant enzyme activities and polyamine contents in leaves of grafted and non-grafted eggplant seedlings under stress by excess of calcium nitrate. Sci Hortic 120:443–451CrossRef
  Wingler A, Lea PJ, Quick WP, Leegood RC (2000) Photorespiration: metabolic pathways and their role in stress protection. Phil Trans R Soc Lond B 355:1517–1529CrossRef
  Yu H, Li T, Zhou J (2005) Secondary salinization of greenhouse soil and its effects on soil properties. Soils 37:581–586
  Yuan L, Yuan Y, Du J, Sun J, Guo S (2012) Effects of 24-epibrassinolide on nitrogen metabolism in cucumber seedlings under Ca(NO3)2 stress. Plant Physiol Bioch 61:29–35CrossRef
  Zapata PJ, Serrano M, Pretel MT, Amoros A, Botella M (2004) Polyamines and ethylene changes during germination of different plant species under salinity. Plant Sci 167:781–788CrossRef
  Zhang G, Liu Z, Zhou J, Zhu Y (2008) Effects of Ca(NO3)2 stress on oxidative damage, antioxidant enzymes activities and polyamine contents in roots of grafted and non-grafted tomato plants. Plant Growth Regul 56:7–19CrossRef
  Zhang Y, Hu XH, Shi Y, Zou ZR, Yan F, Zhao YY, Zhang H, Zhao JZ (2013) Beneficial role of exogenous spermidine on nitrogen metabolism in tomato seedlings exposed to saline-alkaline stress. J Am Soc Hort Sci 138:28–49
  
• 作者单位：Jing Du (1)
  Sheng Shu (1)
  Qiaosai Shao (1)
  Yahong An (1)
  Heng Zhou (1)
  Shirong Guo (1)
  Jin Sun (1)
  
  1. Key Laboratory of Southern Vegetable Crop Genetic Improvement, Ministry of Agriculture, College of Horticulture, Nanjing Agricultural University, Nanjing, 210095, People’s Republic of China
  
• 刊物类别：Biomedical and Life Sciences
• 刊物主题：Life Sciences
  Plant Sciences
  Plant Ecology
  Plant Physiology
  Plant Biochemistry
  
• 出版者：Springer Japan
• ISSN：1618-0860

文摘

Ca(NO₃)₂ stress is one of the most serious constraints to plants production and limits the plants growth and development. Application of polyamines is a convenient and effective approach for enhancing plant salinity tolerance. The present investigation aimed to discover the photosynthetic carbon–nitrogen (C–N) mechanism underlying Ca(NO₃)₂ stress tolerance by spermidine (Spd) of cucumber (Cucumis sativus L. cv. Jinyou No. 4). Seedling growth and photosynthetic capacity [including net photosynthetic rate (P _N), stomatal conductance (Gs), intercellular CO₂ concentration (Ci), and transpiration rate (Tr)] were significantly inhibited by Ca(NO₃)₂ stress (80 mM). However, a leaf-applied Spd (1 mM) treatment alleviated the reduction in growth and photosynthesis in cucumber caused by Ca(NO₃)₂ stress. Furthermore, the application of exogenous Spd significantly decreased the accumulation of NO₃ − and NH₄ + caused by Ca(NO₃)₂ stress and remarkably increased the activities of N metabolism enzymes simultaneously. In addition, photosynthesis N-use efficiency (PNUE) and free amino acids were significantly enhanced by exogenous Spd in response to Ca(NO₃)₂ stress, thus promoting the biosynthesis of N containing compounds and soluble protein. Also, the amounts of several carbohydrates (including sucrose, fructose and glucose), total C content and the C/N radio increased significantly in the presence of Spd. Based on our results, we suggest that exogenous Spd could effectively accelerate nitrate transformation into amino acids and improve cucumber plant photosynthesis and C assimilation, thereby enhancing the ability of the plants to maintain their C/N balance, and eventually promote the growth of cucumber plants under Ca(NO₃)₂ stress. Keywords Ca(NO₃)₂ stress Carbon–nitrogen balance Cucumis sativus L. Photosynthesis Spermidine