آمار
| تعداد نشریات | 44 |
| تعداد شمارهها | 1,323 |
| تعداد مقالات | 16,270 |
| تعداد مشاهده مقاله | 52,954,093 |
| تعداد دریافت فایل اصل مقاله | 15,624,771 |
Effect of salinity stress on the root proteome pattern of spring bread wheat | ||
| Journal of Plant Physiology and Breeding | ||
| دوره 13، شماره 1، شهریور 2023، صفحه 51-68 اصل مقاله (843.21 K) | ||
| نوع مقاله: Research Paper | ||
| شناسه دیجیتال (DOI): 10.22034/jppb.2023.16406 | ||
| نویسندگان | ||
| Somayeh Shahbazi1؛ Mahmoud Toorchi* 2؛ Mohammad Moghaddam3؛ Saeid Aharizad1؛ Ali Bandehhagh1 | ||
| 1Department of Plant Breeding and Biotechnology, University of Tabriz, Tabriz, Iran | ||
| 2Department of Plant Breeding and Biotechnology, University of Tabriz, Tabriz, Iran; Center of Excellence for Cereal Molecular Breeding, University of Tabriz, Tabriz, Iran | ||
| 3ِDepartment of Plant Breeding and Biotechnology, University of Tabriz, Tabriz, Iran; Center of Excellence for Cereal Molecular Breeding, University of Tabriz, Tabriz, Iran | ||
| چکیده | ||
| In this experiment, the effect of salt stress on the root proteome pattern of Arg (tolerant to salinity) and Moghan3 (sensitive to salinity) cultivars of wheat was investigated by two-dimensional polyacrylamide gel electrophoresis. Salinity was applied at two levels of 0 and 150 mM in the third-leaf stage for three weeks under greenhouse conditions. The proteome analysis of the roots revealed 120 reproducible protein spots, among which 15 spots showed significant changes in expression. In Moghan3, four protein spots with a significant reduction in expression were identified. In the tolerant cultivar of Arg, 11 protein spots showed significant changes in expression, among which five protein spots had an increased expression and six protein spots had a decreased expression. These proteins were classified based on their function into several groups such as the proteins involved in metabolism and energy, reactive oxygen species scavenging and detoxification, the proteins associated with cell walls, and the proteins involved in folding and degradation. Probably, the tolerance to salt stress in the Arg cultivar was related to the increased expression of pyruvate dehydrogenase, phosphoglycerate mutase, catalase, and malate dehydrogenase proteins. While in the sensitive variety of Moghan3, the decrease in the expression of enolase, peroxidase, and glutathione peroxidase proteins under salinity stress conditions probably caused oxidative stress in the plants due to increased production of reactive oxygen species. These findings can be useful for improving the salt tolerance in the breeding programs of wheat. | ||
| کلیدواژهها | ||
| proteome analysis؛ reactive oxygen species؛ salt stress؛ two-dimensional electrophoresis | ||
| مراجع | ||
|
Anonymous, 2013. Identification and introduction of new wheat and barley varieties adapted to dry climatic conditions. South Khorasan Agricultural and Natural Resources Research Center, Birjand, Iran (In Persian).
Abdalla KO and Rafudeen MS, 2012. Analysis of the nuclear proteome of the resurrection plant Xerophyta viscosa in response to dehydration stress using iTRAQ with 2DLC and tandem mass spectrometry. Journal of Proteomics 75: 2361-2374.
Adabavazeh F and Razavizadeh R, 2015. Comparison of drought tolerance of four varieties of Brassica napus under in vitro culture. Advances in Environmental Biology 9: 135-143.
Ahmad R, Hussain S, Anjum MA, Khalid MF, Saqib M, Zakir I, Hassan A, Fahad S, and Ahmad S, 2019. Oxidative stress and antioxidant defense mechanisms in plants under salt stress. In: Hasanuzzaman M, Hakeem K, Nahar K, and Alharby H (eds.). Pp. 191-205. Plant Abiotic Stress Tolerance. Springer, Switzerland.
Ahmad P, Jaleel CA, Azooz MM, and Nabi G, 2009. Generation of ROS and non-enzymatic antioxidants during abiotic stress in plants. Botany Research International 2: 11-20.
Alvarez S, Roy Choudhury S, and Pandey S, 2014. Comparative quantitative proteomics analysis of the ABA response of roots of drought-sensitive and drought-tolerant wheat varieties identifies proteomic signatures of drought adaptability. Journal of Proteome Research 13: 1688-1701.
Apel K and Hirt H, 2004. Reactive oxygen species: metabolism, oxidative stress and signal transduction. Annual Review of Plant Biology 55: 373-399.
Asada K, 1999. The water–water cycle in chloroplasts: scavenging of active oxygen and dissipation of excess photons. Annual Review of Plant Physiology and Plant Molecular Biology 50: 601-639.
Banaei-Asl F, Bandehagh A, Dorani Uliaei E, Farajzadeh D, Sakata K, Mustafa G, and Komatsu S, 2015. Proteomic analysis of canola root inoculated with bacteria under salt stress. Journal of Proteomics 124: 88-111.
Bandehagh A, Hosseini Salekdeh Gh, Toorchi M, Mohammadi SA, and Komatsu S, 2011. Comparative proteomic analysis of canola leaves under salinity stress. Proteomics 11: 1965-1975.
Bandehagh A and Taylor NL, 2020. Can alternative metabolic pathways and shunts overcome salinity induced inhibition of central carbon metabolism in crops? Frontiers in Plant Science 11: 1072.
Barakat NAM, 2011. Oxidative stress markers and antioxidant potential of wheat treated with phytohormones under salinity stress. Journal of Stress Physiology and Biochemistry 7: 250-267.
Bazargani MM, Sarhadi E, Bushehri AAS, Matros A, Mock HP, Naghavi MR, Hajihoseini V, Mardi M, Hajirezaei MR, Moradi F, and Ehdaie B, 2011. A proteomics view on the role of drought-induced senescence and oxidative stress defense in enhanced stem reserves remobilization in wheat. Journal of Proteomics 74: 1959-1973.
Ben-Hayyim G, Gueta-Dahan Y, Avsian-Kretchmer O, Weichert H, and Feussner I, 2001. Preferential induction of a 9-lipoxygenase by salt in salt-tolerant cells of Citrus sinensis L. Osbeck. Planta 212: 367-375.
Berg JM, Tymoczko JL, and Stryer L, 2002. Biochemistry. 5th edition. WH Freeman, New York, USA.
Bradford MM, 1976. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry 72: 248-254.
Busam G, Junghanns KT, Kneusel RE, Kassemeyer HH, and Matern U, 1997. Characterization and expression of caffeoyl-coenzyme A 3-O-methyltransferase proposed for the induced resistance response of Vitis vinifera L. Plant Physiology 115: 1039-1048.
Caruso G, Cavaliere C, Guarino C, Gubbiotti R, Foglia P, and Laganà A, 2008. Identification of changes in Triticum durum L. leaf proteome in response to salt stress by two-dimensional electrophoresis and MALDI-TOF mass spectrometry. Analytical and Bioanalytical Chemistry 391: 381-390.
Chun HJ, Baek D, Cho HM, Lee SH, Jin BJ, Yun DJ, Hong YS, and Kim MC, 2019. Lignin biosynthesis genes play critical roles in the adaptation of Arabidopsis plants to high-salt stress. Plant Signaling and Behavior 14(8).
Dai H, Cao F, Chen X, Zhang M, Ahmed IM, Chen Z-H, Li C, Zhang G, and Wu F, 2013. Comparative proteomic analysis of aluminum tolerance in Tibetan wild and cultivated barleys. PLoS ONE 8(5): e63428.
Damerval C, De Vienne D, Zivy M, and Thiellement H, 1986. Technical improvements in two‐dimensional electrophoresis increase the level of genetic variation detected in wheat‐seedling proteins. Electrophoresis 7: 52-54.
Davies G and Henrissat B, 1995. Structures and mechanisms of glycosyl hydrolases. Current Biology. Structure 3(9): 853-859.
Demirevska K, Simova-Stoilova L, Vassileva V, Vaseva I, Grigorova B, and Feller U, 2008. Drought-induced leaf protein alterations in sensitive and tolerant wheat varieties. General and Applied Plant Physiology 34: 79-102.
Dadashi Dooki AD, Mayer‐Posner FJ, Askari H, Zaiee AA, and Salekdeh GH, 2006. Proteomic responses of rice young panicles to salinity. Proteomics 6: 6498-6507.
Dubey R and Singh A, 1999. Salinity induces accumulation of soluble sugars and alters the activity of sugar metabolizing enzymes in rice plants. Biologia Plantarum 42: 233-239.
Elavumoottil O, Martín J, and Moreno M, 2003. Changes in sugars, sucrose synthase activity and proteins in salinity tolerant callus and cell suspension cultures of Brassica oleracea L. Biologia Plantarum 46: 7-12.
Ford KL, Cassin A, Bacic AF, 2011. Quantitative proteomic analysis of wheat cultivars with differing drought stress tolerance. Frontiers in Plant Science, 2: 44.
Forsthoefel NR, Cushman MAF, and Cushman JC, 1995. Posttranscriptional and posttranslational control of enolase expression in the facultative crassulacean acid metabolism plant Mesembryanthemum crystallinum L. Plant Physiology 108: 1185-1195.
Gao L, Yan X, Li X, Guo G, Hu Y, Mac W, and Yan Y, 2011. Proteome analysis of wheat leaf under salt stress by two-dimensional difference gel electrophoresis (2D-DIGE). Phytochemistry 72: 1180-1191.
Gietl C, 1992. MDH isoenzymes: cellular localization and role in the flow of metabolites between the cytoplasm and cell organelles. Biochimica et Biophysica Acta 1100: 217-234.
Guo G, Ge P, MaC, Li X, Lv D, Wang S, Ma W, and Yan Y, 2012. Comparative proteomic analysis of salt response proteins in seedling roots of two wheat varieties. Journal of Proteomics 75: 1867-1885.
Hajheidari M, Abdollahian-Noghabi M, Askari H, and Heidari M, 2005. Proteome analysis of sugar beet leaves under drought stress. Proteomics 5: 950-960.
Heidari M, 2009. Antioxidant activity and osmolyte concentration of sorghum (Sorghum bicolor) and wheat (Triticum aestivum) genotypes under salinity stress. Asian Journal of Plant Sciences 8: 240-244.
Higa A, Hidaka T, Minai Y, Matsuoka Y, and Haga M, 2001. Active oxygen radicals induce peroxidase activity in rice blade tissues. Bioscience, Biotechnology & Biochemistry 65: 1852-1855.
Hojati M, Modarres-Sanavy SAM, Karimi M, and Ghanati F, 2011. Responses of growth and antioxidant systems in Carthamus tinctorius L. under water deficit stress. Acta Physiologiae Plantarum 33: 105-112.
Hosseini Salekdeh G, Reynolds M, Bennett J, and Boyer J, 2009. Conceptual framework for drought phenotyping during molecular breeding. Trends in Plant Science 14: 488-496.
Jiang Y, Yang B, Harris NS, and Deyholos MK, 2007. Comparative proteomic analysis of NaCl stress-responsive proteins in Arabidopsis roots. Journal of Experimental Botany 58: 3591-3607.
Johnsen U and Schonheit P, 2007. Characterization of cofactor-dependent and cofactor-independent phosphoglycerate mutases from Archaea. Extremophiles, 11, 647.
Kang G, Li G, Zheng B, Han Q, Wang C, Zhu Y, and Guo T, 2012. Proteomic analysis on salicylic acid-induced salt tolerance in common wheat seedlings (Triticum aestivum L.). Biochimica et Biophysica Acta 1824: 1324-1333.
Kang J, Xie W, Sun Y, Yang Q, and Wu M, 2010. Identification of genes induced by salt stress from Medicago truncatula L. seedlings. African Journal of Biotechnology 9(45): 7589-7594.
Kausar R, Arshad M, Shahzad A, and Komatsu S, 2013. Proteomics analysis of sensitive and tolerant barley genotypes under drought stress. Amino Acids 44: 345-359.
Kawano T, 2003. Roles of the reactive oxygen species-generating peroxidase reactions in plant defense and growth induction. Plant Cell Reports 21: 829-837.
Koh CS, Didierjean C, Navrot N, Panjikar S, Mulliert G, Rouhier N, Jacquot JP, Aubry A, Shawkataly O, Corbier C, 2007. Crystal structures of a poplar thioredoxin peroxidase that exhibits the structure of glutathione peroxidases: insights into redox-driven conformational changes. Journal of Molecular Biology 370: 512-529.
Kosova K, Prasil I, and Vitamvas P, 2013. Protein contribution to plant salinity response and tolerance acquisition. International Journal of Molecular Sciences 14: 6757-6789.
Koyro HW, Ahmad P, and Geissler N, 2012. Abiotic stress responses in plants: An overview. In: Ahmad P and Prasad MNV (eds.). Pp. 1-28. Environmental Adaptations and Stress Tolerance of Plants in the Era of Climate Change. Springer, Germany.
Krishnamurthy P, Ranathunge K, Nayak S, Schreiber L, and Mathew MK, 2011. Root apoplastic barriers block Na+ transport to shoots in rice (Oryza sativa L.). Journal of Experimental Botany 62(12): 4215-4228.
Kumar RG, Shah K, and Dubey RS, 2000. Salinity induced behavioral changes in malate dehydrogenase and glutamate dehydrogenase activities in rice seedlings of differing salt tolerance. Plant Science 156: 23-34.
Kuhn H and Borchert A, 2002. Regulation of enzymatic lipid peroxidation: the interplay of peroxidizing and peroxide reducing enzymes. Free Radical Biology and Medicine 33(2): 154-72.
Kurth E, Cramer GR, Lauchli A, and Epstein E, 1986. Effects of NaCl and CaCl2 on cell enlargement and cell production in cotton roots. Plant Physiology 82: 1102-1106.
Li C, Liang Y, and Hew CS, 2002. Responses of Rubisco and sucrose-metabolizing enzymes to different CO2 in a C3 tropical epiphytic orchid Oncidium goldiana. Plant Science 163(2): 313-320.
Lushchak OV, Piroddi M, Galli F, and Lushchak VI, 2014. Aconitase post-translational modification as a key in linkage between Krebs cycle, iron homeostasis, redox signaling, and metabolism of reactive oxygen species. Redox Report 19(1): 8-15.
Manaa A, Ben Ahmed H, Valot B, Bouchet JP, Aschi-Smiti S, Causse M, and Faurobert M, 2011. Salt and genotype impact on plant physiology and root proteome variations in tomato. Journal of Experimental Botany 62: 2797-2813.
Mallick N and Mohn FH, 2000. Reactive oxygen species: response of algal cells. Journal of Plant Physiology 157(2): 183-193.
Merewitz EB, Du H, Yu W, Liu Y, Gianfagna T, and Huang B, 2011. Elevated cytokinin content in ipt transgenic creeping bentgrass promotes drought tolerance through regulating metabolite accumulation. Journal of Experimental Botany 63: 1315-1328.
Miao Y, Lv D, Wang P, Wang XC, Chen J, Miao C, and Song CP, 2006. An Arabidopsis glutathione peroxidase functions as both a redox transducer and a scavenger in abscisic acid and drought stress responses. The Plant Cell 18: 2749-2766.
Moeder W, del Pozo O, Navarre DA, Martin GB, and Klessig DF, 2007. Aconitase plays a role in regulating resistance to oxidative stress and cell death in Arabidopsis and Nicotiana benthamiana. Plant Molecular Biology 63: 273-287.
Molina A, Bueno P, Marín MC, Rodríguez‐Rosales MP, Belver A, Venema K, and Donaire JP, 2002. Involvement of endogenous salicylic acid content, lipoxygenase and antioxidant enzyme activities in the response of tomato cell suspension cultures to NaCl. New Phytologist 156: 409-415.
Ndimba BK, Chivasa S, Simon WJ, and Slabas AR, 2005. Identification of Arabidopsis salt and osmotic stress responsive proteins using two‐dimensional difference gel electrophoresis and mass spectrometry. Proteomics 5: 4185-4196.
Neupane P, Bhuju S, Thapa N, Bhattarai HK, 2019. ATP synthase: structure, function and inhibition. Biomolecular Concepts 10: 1-10.
O'Farrell PH, 1975. High resolution two-dimensional electrophoresis of proteins. Journal of Biological Chemistry 250: 4007-4021.
Peng J, Liu J, Zhang L, Luo J, Dong H, Ma Y, Zhao X, Chen B, Sui N, Zhou Z, and Meng Y, 2016. Effects of soil salinity on sucrose metabolism in cotton leaves. PLoS One 11(5): e0156241.
Podda A, Checcucci G, Mouhaya W, Centeno D, Rofidal V, del Carratore R, Luro F, Morillon R, Ollitrault P, and Maserti BE, 2013. Salt-stress induced changes in the leaf proteome of diploid and tetraploid mandarins with contrasting Na+ and Cl− accumulation behavior. Journal of Plant Physiology 170: 1101-1112.
Riccardi F, Gazeau P, de Vienne D, and Zivy M, 1998. Protein changes in response to progressive water deficit in maize: quantitative variation and polypeptide identification. Plant Physiology 117: 1253-1263.
Sadak M Sh, Abd El-Hameid AR, Zaki FSA, Dawood MG, and El-Awadi M, 2020. Physiological and biochemical responses of soybean (Glycine max L.) to cysteine application under sea salt stress. Bulletin of the National Research Centre 44: 1.
Sanchez-Aguayo I, Rodriguez-Galan JM, Garcia R, Torreblanca J, and Pardo JM, 2004. Salt stress enhances xylem development and expression of S-adenosyl-L-methionine synthase in lignifying tissues of tomato plants. Planta 220: 278-285.
Siedow JN, 1991. Plant lipoxygenase: structure and function. Annual Review of Plant Physiology and Plant Molecular Biology 42: 145-188.
Sharma P, Jha AB, Dubey RS, and Pessarakli M, 2012. Reactive oxygen species, oxidative damage, and antioxidative defense mechanism in plants under stressful conditions. Journal of Botany Vol. 2012. doi.org/10.1155/2012/217037.
Sharma A, Kumar V, Shahzad B, Ramakrishnan M, Sidhu GPS, Bali AS, Handa N, Kapoor D, Yadav P, Khanna K, Bakshi P, Rehman A, Kohli SK, Khan EA, Parihar RD, Yuan H, Thukral AK, Bhardwaj R, and Zheng B, 2020. Photosynthetic response of plants under different abiotic stresses: a review. Journal of Plant Growth Regulation 39: 509-531.
Strand A, Foyer CH, Gustafsson P, Gardestrom P, and Hurry V. 2003. Altering flux through the sucrose biosynthesis pathway in transgenic Arabidopsis thaliana modifies photosynthetic acclimation at low temperatures and the development of freezing tolerance. Plant, Cell & Environment 26: 523-535.
Umeda M, Hara C, Matsubayashi Y, Li HH, Liu Q, Tadokoro F, Aotsuka S, and Uchimiya H, 1994. Expressed sequence tags from cultured cells of rice (Oryza sativa L.) under stressed conditions: analysis of transcripts of genes engaged in ATP generating pathways. Plant Molecular Biology 25: 469-478.
Viswanath KK, Varakumar P, Ramachandra Reddy P, Jeelan Basha S, Mehta S, Dinakara Rao A, 2020. Plant lipoxygenases and their role in plant physiology. Journal of Plant Biology 63(2): 83-95.
Vitamvas P, Prasil IT, Kosova K, Planchon S, and Renaut J, 2012. Analysis of proteome and frost tolerance in chromosome 5A and 5B reciprocal substitution lines between two winter wheats during long‐term cold acclimation. Proteomics 12: 68-85.
Voet D, Voet JG, and Pratt CW, 2008. Fundamentals of Biochemistry: Life at the Molecular Level. 3rd ed. John Wiley and Sons, Inc., NJ, USA.
Wang MC, Pen, ZY, Li CL, Li F, Liu C, and Xia GM, 2008. Proteomics analysis on a high salt tolerance introgression strain of Triticum aestivum/Thinopyrum ponticum. Journal of Proteomics 8: 1470-1489.
Wang W, Vinocur B, and Altman A, 2003. Plant responses to drought, salinity and extreme temperatures: towards genetic engineering for stress tolerance. Planta 218:1-14.
Wang W, Vinocur B, Shoseyov O, and Altman A, 2004. Role of plant heat-shock proteins and molecular chaperones in the abiotic stress response. Trends in Plant Science 9: 244-252.
Witzel K, Weidner A, Surabhi GK, Borner A, and Mock HP, 2009. Salt stress-induced alterations in the root proteome of barley genotypes with contrasting response towards salinity. Plant Molecular Biology 70: 535-546.
Xu CP, Sibicky T, and Huang BR, 2010. Protein profile analysis of salt-responsive proteins in leaves and roots in two cultivars of creeping bentgrass differing in salinity tolerance. Plant Cell Reports 29: 595-615.
Yan L, Fu D, Li C, Blechl A, Tranquilli G, Bonafede M, Sanchez A, Valarik M, Yasuda S, and Dubcovsky J, 2006. The wheat and barley vernalization gene VRN3is an orthologue of FT. PNAS 103(51): 19581-19586.
Yang J, Zhang J, Wang Z, and Zhu Q, 2001. Activities of starch hydrolytic enzymes and sucrose‐phosphate synthase in the stems of rice subjected to water stress during grain filling. Journal of Experimental Botany 52: 2169-2179.
Yang G, Wang Y, Zhang K, and Gao C, 2014. Expression analysis of nine small heat shock protein genes from Tamarix hispida in response to different abiotic stresses and abscisic acid treatment. Molecular Biology Reports 41: 1279-1289.
Yoshimura K, Masuda A, Kuwano M, Yokota A, and Akashi K, 2008. Programmed proteome response for drought avoidance/tolerance in the root of a C3 xerophyte (wild watermelon) under water deficits. Plant and Cell Physiology 49: 226-241.
Yoshimura K, Miyao K, Gaber A, Takeda T, Kanaboshi H, Miyasaka H, and Shigeoka S, 2004. Enhancement of stress tolerance in transgenic tobacco plants overexpressing Chlamydomonas glutathione peroxidase in chloroplasts or cytosol. The Plant Journal 37: 21-33.
Ziveri J, Tros F, Guerrera IC, Chiara Guerrera I, Chhuon C, Audry M, Dupuis M, Barel M, Korniotis S, Fillatreau S, Gales L, Cahoreau E, and Charbit A, 2017. The metabolic enzyme fructose-1,6-bisphosphate aldolase acts as a transcriptional regulator in pathogenic Francisella. Nature Communications 8: 853. | ||
|
آمار تعداد مشاهده مقاله: 302 تعداد دریافت فایل اصل مقاله: 377 |
||