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Acta Agron Sin ›› 2009, Vol. 35 ›› Issue (3): 483-489.doi: 10.3724/SP.J.1006.2009.00483

• TILLAGE & CULTIVATION·PHYSIOLOGY & BIOCHEMISTRY • Previous Articles     Next Articles

Proteome Analysis of Relieving Effect of gibberellin on the Inhibition of rice Seed Germination by Salt stress

WEN Fu-Ping12;ZHANG Tan1;ZHANG Zhao-Hui2;PAN Ying-Hong2*   

  1. 1College of Forestry, Northwest A & F University, Yangling 712100,China;2Institute of Crop Sciences/National Key Facility for Crop Gene Resources and Genetic Improvement, Chinese Academy of Agricultural Sciences, Beijing 100081,China
  • Received:2008-08-15 Revised:2008-12-13 Online:2009-03-12 Published:2009-01-16
  • Contact: PAN Ying-Hong

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Abstract:

Salinity stress is a major abiotic stress to most plant including rice. It has been reported that gibberellic acid (GA3) can exert a natural beneficial effect on salt stressed rice. In this paper, the effect of salt stress on rice (Oryza sativa L. cv.Nipponbare) seed germination and the effect of GA3 on salt-stressed rice were investigated. A proteomic approach was employed to further understand the relieving effect of gibberellin on the inhibition of rice seed germination by salt stress. The 5-day-old rice seedlings were treated with H2O (control), 5 g L-1 NaCl (treated group I), and 5 g L-1 NaCl + 100 μmol L-1 GA3 (treated group II) for 48 h respectively. The proteins extracted from buds were separated by two-dimensional gel electrophoresis (2-DE) and analyzed with Matrix Assisted Laser Desorption/Ionization Time of Flight Mass Spectrometry (MALDI-TOF MS). The results showed that the seed germination of Nipponbare was inhibited by salt stress significantly (see Table 1), while GA3 could reduce the inhibition significantly (see Table 2). Four protein spots showed differential expression in 2-DE. Three of these proteins were down-regulated (spots 1–3) and one protein disappeared (spots 4) under salt stress. Expression levels of these proteins were recovered partly when treated with GA3 and NaCl at the same time (see Fig. 1 and Fig. 2). Two protein spots were identified as isoflavone reductase-like protein and phosphoglucomutase (see Table 3). These differential expression proteins may play important role in the mechanism of the relieving effect of gibberellin on the inhibition of rice germination by salt stress.

Key words: Rice, Gibberellin, Salt stress, Proteome

[1]Chitteti B R, Peng Z. Proteome and phosphoproteome differential expression under salinity stress in rice (Oryza sativa) roots. J Proteome Res, 2007, 6: 1718–1727
[2]Dooki A D, Mayer-Posner F J, Askari H, Zaiee A A, Salekdeh G H. Proteomic responses of rice young panicles to salinity. Proteomics, 2006, 6: 6498–6507
[3]Parker R, Flowers T J, Moore A L, Harpham N V. An accurate and reproducible method for proteome profiling of the effects of salt stress in the rice leaf lamina. J Exp Bot, 2006, 57: 1109–1118
[4]Walia H, Wilson C, Zeng L, Ismail A M, Condamine P, Close T J. Genome-wide transcriptional analysis of salinity stressed japonica and indica rice genotypes during panicle initiation stage. Plant Mol Biol, 2007, 63: 609–623
[5]Nohzadeh Malakshah S, Habibi Rezaei M, Heidari M, Hosseini Salekdeh G. Proteomics reveals new salt responsive proteins associated with rice plasma membrane. Biosci Biotechnol Biochem, 2007, 71: 2144–2154
[6]Hoffmann-Benning S, Kende H. On the role of abscisic acid and gibberellin in the regulation of growth in rice. Plant Physiol, 1992, 99: 1156–1161
[7]Raskin I, Kende H. Role of gibberellin in the growth response of submerged deep water rice. Plant Physiol, 1984, 76: 947–950
[8]Kefford N P. Auxin-Gibberellin interaction in rice coleoptile elongation. Plant Physiol, 1962, 37: 380–386
[9]Konishi H, Yamane H, Maeshima M, Komatsu S. Characterization of fructose-bisphosphate aldolase regulated by gibberellin in roots of rice seedling. Plant Mol Biol, 2004, 56: 839–848
[10]Komatsu S, Konishi H. Proteome analysis of rice root proteins regulated by gibberellin. Genomics Proteomics Bioinformatics, 2005, 3: 132–142
[11]Komatsu S, Zang X, Tanaka N. Comparison of two proteomics techniques used to identify proteins regulated by gibberellin in rice. J Proteome Res, 2006, 5: 270–276
[12]Konishi H, Maeshima M, Komatsu S. Characterization of vacuolar membrane proteins changed in rice root treated with gibberellin. J Proteome Res, 2005, 4: 1775–1780
[13]Shen S, Sharma A, Komatsu S. Characterization of proteins responsive to gibberellin in the leaf-sheath of rice (Oryza sativa L.) seedling using proteome analysis. Biol Pharm Bull, 2003, 26: 129–136
[14]Rodríguez A A, Stella A M, Storni M M, Zulpa G, Zaccaro M C. Effects of cyanobacterial extracellular products and gibberellic acid on salinity tolerance in Oryza sativa L. Saline Systems, 2006, 2: 7
[15]Liu W-X(刘伟霞), Pan Y-H(潘映红). Sample preparation methods suitable for wheat leaf proteome analysis. Sci Agric Sin (中国农业科学), 2007, 40(10): 2169–2176 (in Chinese with English abstract)
[16]Pan R-C(潘瑞炽). Plant Physiology (植物生理学). Beijing: Higher Education Press, 2003. pp 292–293 (in Chinese)
[17]Ueguchi-Tanaka M, Ashikari M, Nakajima M, Itoh H, Katoh E, Kobayashi M, Chow T Y, Hsing Y I, Kitano H, Yamaguchi I, Matsuoka M. GIBBERELLIN INSENSITIVE DWARF1 encodes a soluble receptor for gibberellin. Nature, 2005, 437: 693–698
[18]Jiang C, Fu X. GA action: turning on de-DELLA repressing signaling. Curr Opin Plant Biol, 2007, 10: 461–465
[19]Feng S, Martinez C, Gusmaroli G, Wang Y, Zhou J, Wang F, Chen L, Yu L, Iglesias-Pedraz J M, Kircher S, Sch?fer E, Fu X, Fan L M, Deng X W. Coordinated regulation of Arabidopsis thaliana development by light and gibberellins. Nature, 2008, 451: 475–479
[20]Achard P, Cheng H, De Grauwe L, Decat J, Schoutteten H, Moritz T, Van Der Straeten D, Peng J, Harberd N P. Integration of plant responses to environmentally activated phytohormonal signals. Science, 2006, 311: 91–94
[21]Salekdeh G H, Siopongco J, Wade L J, Ghareyazie B, Bennett J. Proteomic analysis of rice leaves during drought stress and recovery. Proteomics, 2002, 2: 1131–1145
[22]Petrucco S, Bolchi A, Foroni C, Percudani R, Rossi G L, Ottonello S. A maize gene encoding an NADPH binding enzyme highly homologous to isoflavone reductases 1s activated in response to sulfur starvation. Plant Cell, 1996, 1: 69–80
[23]Babiychuk E, Kushnir S, Belles-Boix E, Van Montagu M, Inzé D. Arabidopsis thaliana NADPH oxidoreductase homologs confer tolerance of yeasts toward the thiol-oxidizing drug diamide. J Biol Chem, 1995, 270: 26224–26231
[24]Lers A, Burd S, Lomaniec E, Droby S, Chalutz E. The expression of a grapefruit gene encoding an isoflavone reductaselike protein is induced in response to UV irradiation. Plant Mol Biol, 1998, 36: 847–856
[25]Caspar T, Huber S C, Somerville C. Alterations in growth, photosynthesis, and respiration in a starch less mutant of Arabidopsis thaliana (L.) deficient in chloroplast phosphoglucomutase activity. Plant Physiol, 1985, 79: 11–17
[26]Hanson K R, McHale N A. A starchless mutant of Nicotiana sylvestris containing a modified plastid phosphoglucomutase. Plant Physiol, 1988, 88: 838–844
[27]Ke Y-Q(柯玉琴), Pan T-G(潘廷国), Ai Y-F(艾育芳). Effect of NaCl stress on permeability of plasma membrane and substance transformation in germinated rice seeds. Chin J Eco-agric (中国生态农业学报), 2002, 10(4): 10–12 (in Chinese with English abstract)
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