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PLOS ONE 2012

OsLEA3-2, an Abiotic Stress Induced Gene of Rice Plays a Key Role in Salt and Drought Tolerance

DOI: 10.1371/journal.pone.0045117

Jianli Duan, Weiming Cai

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Abstract:

Late embryogenesis abundant (LEA) proteins are involved in tolerance to drought, cold and high salinity in many different organisms. In this report, a LEA protein producing full-length gene OsLEA3-2 was identified in rice (Oryza sativa) using the Rapid Amplification of cDNA Ends (RACE) method. OsLEA3-2 was found to be only expressed in the embryo and can be induced by abiotic stresses. The coding protein localizes to the nucleus and overexpression of OsLEA3-2 in yeast improved growth performance compared with control under salt- and osmotic-stress conditions. OsLEA3-2 was also inserted into pHB vector and overexpressed in Arabidopsis and rice. The transgenic Arabidopsis seedlings showed better growth on MS media supplemented with 150 mM mannitol or 100 mM NaCl as compared with wild type plants. The transgenic rice also showed significantly stronger growth performance than control under salinity or osmotic stress conditions and were able to recover after 20 days of drought stress. In vitro analysis showed that OsLEA3-2 was able to protect LDH from aggregation on freezing and inactivation on desiccation. These results indicated that OsLEA3-2 plays an important role in tolerance to abiotic stresses.

References

[1]	Baker J, Steele C, LIII D (1988) Sequence and characterization of 6 Lea proteins and their genes from cotton. Plant Molecular Biology 11: 277–291.
[2]	Bartels D, Singh M, Salamini F (1988) Onset of desiccation tolerance during development of the barley embryo. planta 175: 485–492.
[3]	Bostock RM, Quatrano RS (1992) Regulation of Em Gene Expression in Rice : Interaction between Osmotic Stress and Abscisic Acid. Plant Physiol 98: 1356–1363.
[4]	Wilhelm KS, Thomashow MF (1993) Arabidopsis thaliana cor15b, an apparent homologue of cor15a, is strongly responsive to cold and ABA, but not drought. Plant Mol Biol 23: 1073–1077.
[5]	Bray EA (1993) Molecular Responses to Water Deficit. Plant Physiol 103: 1035–1040.
[6]	Hellwege EM, Dietz KJ, Hartung W (1996) Abscisic acid causes changes in gene expression involved in the induction of the landform of the liverwort Riccia fluitans L. Planta. 198: 423–432.
[7]	Moons A, De Keyser A, Van Montagu M (1997) A group 3 LEA cDNA of rice, responsive to abscisic acid, but not to jasmonic acid, shows variety-specific differences in salt stress response. Gene 191: 197–204.
[8]	Godoy JA, Pardo JM, Pintor-Toro JA (1990) A tomato cDNA inducible by salt stress and abscisic acid: nucleotide sequence and expression pattern. Plant Mol Biol 15: 695–705.
[9]	Bies-Etheve N, Gaubier-Comella P, Debures A, Lasserre E, Jobet E, et al. (2008) Inventory, evolution and expression profiling diversity of the LEA (late embryogenesis abundant) protein gene family in Arabidopsis thaliana. Plant Mol Biol 67: 107–124.
[10]	Battaglia M, Olvera-Carrillo Y, Garciarrubio A, Campos F, Covarrubias AA (2008) The enigmatic LEA proteins and other hydrophilins. Plant Physiol 148: 6–24.
[11]	Hundertmark M, Hincha DK (2008) LEA (late embryogenesis abundant) proteins and their encoding genes in Arabidopsis thaliana. BMC Genomics 9: 118.
[12]	Dure L 3rd (1993) A repeating 11-mer amino acid motif and plant desiccation. Plant J 3: 363–369.
[13]	Roberts JK, DeSimone NA, Lingle WL, Dure L 3rd (1993) Cellular Concentrations and Uniformity of Cell-Type Accumulation of Two Lea Proteins in Cotton Embryos. Plant Cell 5: 769–780.
[14]	Hong B, Uknes S, Ho T (1988) Cloning and characterization of a cDNA encoding a mRNA rapidly-induced by ABA in barley aleurone layers. Plant Mol Biol 11: 495–506.
[15]	Curry J, Morris CF, Walker-Simmons MK (1991) Sequence analysis of a cDNA encoding a group 3 LEA mRNA inducible by ABA or dehydration stress in wheat. Plant Mol Biol 16: 1073–1076.
[16]	White CN, Rivin CJ (1995) Sequence and regulation of a late embryogenesis abundant group 3 protein of maize. Plant Physiol 108: 1337–1338.
[17]	Takahashi R, Joshee N, Kitagawa Y (1994) Induction of chilling resistance by water stress, and cDNA sequence analysis and expression of water stress-regulated genes in rice. Plant Mol Biol 26: 339–352.
[18]	Xu D, Duan X, Wang B, Hong B, Ho T, et al. (1996) Expression of a Late Embryogenesis Abundant Protein Gene, HVA1, from Barley Confers Tolerance to Water Deficit and Salt Stress in Transgenic Rice. Plant Physiol 110: 249–257.
[19]	Lal S, Gulyani V, Khurana P (2008) Overexpression of HVA1 gene from barley generates tolerance to salinity and water stress in transgenic mulberry (Morus indica). Transgenic Res 17: 651–663.
[20]	Liu Y, Zheng Y, Zhang Y, Wang W, Li R (2010) Soybean PM2 protein (LEA3) confers the tolerance of Escherichia coli and stabilization of enzyme activity under diverse stresses. Curr Microbiol 60: 373–378.
[21]	Mao J, Zhang YC, Sang Y, Li QH, Yang HQ (2005) From The Cover: A role for Arabidopsis cryptochromes and COP1 in the regulation of stomatal opening. Proc Natl Acad Sci U S A 102: 12270–12275.
[22]	Clough SJ, Bent AF (1998) Floral dip: a simplified method for Agrobacterium-mediated transformation of Arabidopsis thaliana. Plant J 16: 735–743.
[23]	Hiei Y, Ohta S, Komari T, Kumashiro T (1994) Efficient transformation of rice (Oryza sativa L.) mediated by Agrobacterium and sequence analysis of the boundaries of the T-DNA. Plant J 6: 271–282.
[24]	Goyal K, Walton L, Tunnacliffe A (2005) LEA proteins prevent protein aggregation due to water stress. Biochem J: 151–157.
[25]	Thomashow MF (1999) PLANT COLD ACCLIMATION: Freezing Tolerance Genes and Regulatory Mechanisms. Annu Rev Plant Physiol Plant Mol Biol 50: 571–599.
[26]	Xiong L, Schumaker KS, Zhu JK (2002) Cell signaling during cold, drought, and salt stress. Plant Cell 14 Suppl: S165–183
[27]	Close T (1997) Dehydrins: a commonality in the response of plants to dehydration and low temperature. Physiol Plant: 291–296.
[28]	Browne J, Tunnacliffe A, Burnell A (2002) Plant desiccation gene found in a nematode. Nature 38.
[29]	Bai Y, Yang Q, Kang J, Sun Y, Gruber M, et al. (2012) Isolation and functional characterization of a Medicago sativa L. gene, MsLEA3–1. Mol Biol Rep 39: 2883–2892.
[30]	Imai R, Chang L, Ohta A, Bray EA, Takagi M (1996) A lea-class gene of tomato confers salt and freezing tolerance when expressed in Saccharomyces cerevisiae. Gene 170: 243–248.
[31]	Zhang L, Ohta A, Takagi M, Imai R (2000) Expression of plant group 2 and group 3 lea genes in Saccharomyces cerevisiae revealed functional divergence among LEA proteins. J Biochem 127: 611–616.
[32]	Wang B, Wang Y, Zhang D, Li H, Yang C (2008) Verification of the resistance of a LEA gene from Tamarix expression in Saccharomyces cerevisiae to abiotic stresses. Journal of Forestry Research: 58–62.
[33]	Honjoh KI, Matsumoto H, Shimizu H, Ooyama K, Tanaka K, et al. (2000) Cryoprotective activities of group 3 late embryogenesis abundant proteins from Chlorella vulgaris C-27. Biosci Biotechnol Biochem 64: 1656–1663.
[34]	Hara M, Terashima S, Kuboi T (2001) Characterisation and cryoprotective activity of cold-responsive dehydrin from Citrus unshiu. J Plant Physiol: 1333–1339.
[35]	Sanchez-Ballesta MT, Rodrigo MJ, Lafuente MT, Granell A, Zacarias L (2004) Dehydrin from citrus, which confers in vitro dehydration and freezing protection activity, is constitutive and highly expressed in the flavedo of fruit but responsive to cold and water stress in leaves. J Agric Food Chem 52: 1950–1957.

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