Gubi J, Vaňková R, ervená V, et al. Transformed tobacco plants with increased tolerance to drought[J]. South African Journal of Botany, 2007, 73: 505-511.
[2]
Yamada M, Morishita H, Urano K, et al. Effects of free proline accumulation in petunias under drought stress[J]. Journal of Experimental Botany, 2005, 56: 1975-1981.
[3]
Romero C, Bellés J M, Vayá J L, et al. Expression of the yeast trehalose-6-phosphate synthase gene in transgenic tobacco plants: pleiotropic phenotypes include drought tolerance[J]. Planta, 1997, 201: 293-297.
[4]
Miranda J, Avonce N, Suárez R, et al. A bifunctional TPS-TPP enzyme from yeast confers tolerance to multiple and extreme abiotic-stress conditions in transgenic Arabidopsis[J]. Planta, 2007, 226: 1411-1421.
[5]
Karim S, Aronsson H, Ericson H, et al. Improved drought tolerance without undesired side effects in transgenic plants producing trehalose[J]. Plant Molecular Biology, 2007, 64: 371-386.
[6]
Jang I C, Oh S J, Seo J S, et al. Expression of a bifunctional fusion of the Escherichia coli genes for trehalose-6-phosphate synthase and trehalose-6-phosphate phosphatase in transgenic rice plants increases trehalose accumulation and abiotic stress tolerance without stunting growth[J]. Plant Physiology, 2003, 131: 516-524.
[7]
Wu R, Garg A. Engineering rice plants with trehalose-producing genes improves tolerance to drought, salt, and low temperature[R]. ISB News Report, 2003.
[8]
Abebe T, Guenzi A C, Martin B, et al. Tolerance of mannitol-accumulating transgenic wheat to water stress and salinity[J]. Plant Physiology, 2003, 131: 1748-1755.
[9]
Karakas B, Ozias-Akins P, Stushnoff C, et al. Salinity and drought tolerance of mannitol-accumulating transgenic tobacco[J]. Plant, Cell & Environment, 1997, 20: 609-616.
[10]
Vaucheret H. Post-transcriptional small RNA pathways in plants: mechanisms and regulations[J]. Genes & Development, 2006, 20: 759-771.
[11]
Bartels D, Sunkar R. Drought and salt tolerance in plants[J]. Critical Reviews in Plant Sciences, 2005, 24: 23-58.
[12]
Finkelstein R R, Gampala S S, Rock C D. Abscisic acid signaling in seeds and seedlings[J]. Plant Cell, 2002, 14(Suppl): 15-45.
[13]
Fujita Y, Fujita M, Satoh R,et al. AREB1 is a transcription activator of novel ABRE-dependent ABA signaling that enhances drought stress tolerance in Arabidopsis[J/OL]. The Plant Cell Online, 2005, 17: 3470-3488.
[14]
Ding Z, Li S, An X,et al. Transgenic expression of MYB15 confers enhanced sensitivity to abscisic acid and improved drought tolerance in Arabidopsis thaliana[J]. Journal of Genetics and Genomics, 2009, 36: 17-29.
[15]
Cominelli E, Galbiati M, Vavasseur A,et al. A guard-cell-specific MYB transcription factor regulates stomatal movements and plant drought tolerance[J]. Current Biology, 2005, 15: 1196-1200.
[16]
Oh S J, Kim Y S, Kwon C W,et al. Overexpression of the transcription factor AP37 in rice improves grain yield under drought conditions[J]. Plant Physiology, 2009, 150: 1368-1379.
Liu Q, Kasuga M, Sakuma Y,et al. Two transcription factors, DREB1 and DREB2, with an EREBP/AP2 DNA binding domain separate two cellular signal transduction pathways in drought- and low-temperature-responsive gene expression, respectively, in Arabidopsis[J/OL]. The Plant Cell Online, 1998, 10: 1391-1406.
[19]
Bhatnagar-Mathur P, Devi M J, Vadez V,et al. Differential antioxidative responses in transgenic peanut bear no relationship to their superior transpiration efficiency under drought stress[J]. Journal of Plant Physiology, 2009, 166: 1207-1217.
[20]
Dubouzet J G, Sakuma Y, Ito Y,et al. OsDREB genes in rice, Oryza sativa L., encode transcription activators that function in drought-, high-salt- and cold-responsive gene expression[J]. The Plant Journal, 2003, 33: 751-763.
[21]
Tran L S P, Nakashima K, Sakuma Y,et al. Isolation and functional analysis of Arabidopsis stress-inducible NAC transcription factors that bind to a drought-responsive cis-element in the early responsive to dehydration stress 1 promoter[J/OL]. The Plant Cell Online, 2004, 16: 2481-2498.
[22]
Hu H, Dai M, Yao J,et al. Overexpressing a NAM, ATAF, and CUC (NAC) transcription factor enhances drought resistance and salt tolerance in rice[J]. Proceedings of the National Academy of Sciences, 2006, 103: 12987-12992.
[23]
Sakamoto H, Maruyama K, Sakuma Y,et al. Arabidopsis Cys2/His2-type zinc-finger proteins function as transcription repressors under drought, cold, and high-salinity stress conditions[J]. Plant Physiology, 2004, 136: 2734-2746.
[24]
Kim S, Hong J, Lee S,et al. CAZFP1, Cys2/His2-type zinc-finger transcription factor gene functions as a pathogen-induced early-defense gene in Capsicum annuum[J]. Plant Molecular Biology, 2004, 55: 883-904.
[25]
Ashraf M. Inducing drought tolerance in plants: recent advances[J]. Biotechnology Advances, 2010, 28: 169-183.
[26]
Ashraf M, Foolad M R. Roles of glycine betaine and proline in improving plant abiotic stress resistance[J]. Environmental and Experimental Botany, 2007, 59: 206-216.
[27]
Shen Y G, Du B X, Zhang W K,et al. AhCMO, regulated by stresses in Atriplex hortensis, can improve drought tolerance in transgenic tobacco[J]. Theoretical and Applied Genetics, 2002, 105: 815-821.
[28]
De Ronde J A, Cress W A, Krüger G H J,et al. Photosynthetic response of transgenic soybean plants, containing an Arabidopsis P5CR gene, during heat and drought stress[J]. Journal of Plant Physiology, 2004, 161: 1211-1224.
[29]
Gubi J, Vaňková R, ervená V,et al. Transformed tobacco plants with increased tolerance to drought[J]. South African Journal of Botany, 2007, 73: 505-511.
[30]
Yamada M, Morishita H, Urano K,et al. Effects of free proline accumulation in petunias under drought stress[J]. Journal of Experimental Botany, 2005, 56: 1975-1981.
[31]
Romero C, Bellés J M, Vayá J L,et al. Expression of the yeast trehalose-6-phosphate synthase gene in transgenic tobacco plants: pleiotropic phenotypes include drought tolerance[J]. Planta, 1997, 201: 293-297.
[32]
Miranda J, Avonce N, Suárez R,et al. A bifunctional TPS-TPP enzyme from yeast confers tolerance to multiple and extreme abiotic-stress conditions in transgenic Arabidopsis[J]. Planta, 2007, 226: 1411-1421.
[33]
Munne-Bosch S. The role of α-tocopherol in plant stress tolerance[J]. Journal of Plant Physiology, 2005, 162: 743-748.
Akashi K, Miyake C, Yokota A. Citrulline, a novel compatible solute in drought-tolerant wild watermelon leaves, is an efficient hydroxyl radical scavenger[J]. FEBS Letters, 2001, 508: 438-442.
[36]
Kusvuran S, Dasgan H Y, Abak K. Citrulline is an important biochemical indicator in tolerance to saline and drought stresses in melon[J]. The Scientific World Journal, 2013, 8: 11-55.
[37]
Groppa M D, Benavides M P. Polyamines and abiotic stress: recent advances[J]. Amino Acids, 2008, 34: 35-45.
Alcázar R, Altabella T, Marco F,et al. Polyamines: molecules with regulatory functions in plant abiotic stress tolerance[J]. Planta, 2010, 231: 1237-1249.
[40]
Alcázar R, Marco F, Cuevas J C,et al. Involvement of polyamines in plant response to abiotic stress[J]. Biotechnology Letters, 2006, 28: 1867-1876.
[41]
Kasukabe Y, He L, Nada K,et al. Overexpression of spermidine synthase enhances tolerance to multiple environmental stresses and up-regulates the expression of various stress-regulated genes in transgenic Arabidopsis thaliana[J]. Plant and Cell Physiology, 2004, 45: 712-722.
[42]
Urano K, Yoshiba Y, Nanjo T,et al. Arabidopsis stress-inducible gene for arginine decarboxylase AtADC2 is required for accumulation of putrescine in salt tolerance[J]. Biochemical and Biophysical Research Communications, 2004, 313: 369-375.
[43]
Vaucheret H. Post-transcriptional small RNA pathways in plants: mechanisms and regulations[J]. Genes & Development, 2006, 20: 759-771.
[44]
Sunkar R, Zhu J K. Novel and stress-regulated microRNAs and other small RNAs from Arabidopsis[J]. Plant Cell, 2004, 16: 2001-2019.
[45]
Jones-Rhoades M W, Bartel D P. Computational identification of plant microRNAs and their targets, including a stress-induced miRNA[J]. Molecular Cell, 2004, 14: 787-799.
[46]
Arenas-Huertero C, Perez B, Rabanal F,et al. Conserved and novel miRNAs in the legume Phaseolus vulgaris in response to stress[J]. Plant Molecular Biology Reporter, 2009, 70: 385-401.
[47]
Liu H H, Tian X, Li Y J,et al. Microarray-based analysis of stress-regulated microRNAs in Arabidopsis thaliana[J]. RNA, 2008, 14: 836-843.
[48]
Lu S, Sun Y H, Chiang V L. Stress-responsive microRNAs in Populus[J]. Plant Journal, 2008, 55: 131-151.
[49]
Yamaguchi-Shinozaki K, Shinozaki K. Organization of cis-acting regulatory elements in osmotic- and cold-stress-responsive promoters[J]. Trends in Plant Science, 2005, 10: 88-94.
[50]
Wang W, Vinocur B, Altman A. Plant responses to drought, salinity and extreme temperatures: towards genetic engineering for stress tolerance[J]. Planta, 2003, 218: 1-14.
[51]
Reference:
[52]
Boyer J S. Plant productivity and environment[J]. Science, 1982, 218: 443-448.
[53]
Ramachandra Reddy A, Chaitanya K V, Vivekanandan M. Drought-induced responses of photosynthesis and antioxidant metabolism in higher plants[J]. Journal of Plant Physiology, 2004, 161: 1189-1202.
[54]
Shinozaki K, Yamaguchi-Shinozaki K, Seki M. Regulatory network of gene expression in the drought and cold stress responses[J]. Current Opinion In Plant Biology, 2003, 6: 410-417.
[55]
Umezawa T, Fujita M, Fujitam Y, et al. Engineering drought tolerance in plants: discovering and tailoring genes to unlock the future[J]. Current Opinion in Biotechnology, 2006, 17: 113-122.
[56]
Vinocur B, Altman A. Recent advances in engineering plant tolerance to abiotic stress: achievements and limitations[J]. Current Opinion in Biotechnology, 2005, 16: 123-132.
[57]
Shou H, Bordallo P, Wang K. Expression of the Nicotiana protein kinase (NPK1) enhanced drought tolerance in transgenic maize[J]. Journal of Experimental Botany, 2004, 55: 1013-1019.
[58]
Cutler S, Ghassemian M, Bonetta D, et al. A protein farnesyl transferase involved in abscisic acid signal transduction in Arabidopsis[J]. Science, 1996, 273: 1239-1241.
[59]
Boudsocq M, Barbier-Brygoo H, Laurière C. Identification of nine sucrose nonfermenting 1-related protein kinases 2 activated by hyperosmotic and saline stresses in Arabidopsis thaliana[J]. Journal of Biological Chemistry, 2004, 279: 41758-41766.
[60]
Umezawa T, Yoshida R, Maruyama K, et al. SRK2C, a SNF1-related protein kinase 2, improves drought tolerance by controlling stress-responsive gene expression in Arabidopsis thaliana[J]. Proceedings of the National Academy of Sciences of the United States of America, 2004, 101: 17306-17311.
[61]
Cheong Y H, Kim K N, Pandey G K, et al. CBL1, a calcium sensor that differentially regulates salt, drought, and cold responses in Arabidopsis[J/OL]. The Plant Cell Online, 2003, 15: 1833-1845.
[62]
Posas F, Saito H. Osmotic activation of the HOG MAPK pathway via Ste11p MAPKKK: scaffold role of Pbs2p MAPKK[J]. Science,1997, 276: 1702-1705.
[63]
Bartels D, Sunkar R. Drought and salt tolerance in plants[J]. Critical Reviews in Plant Sciences, 2005, 24: 23-58.
[64]
Finkelstein R R, Gampala S S, Rock C D. Abscisic acid signaling in seeds and seedlings[J]. Plant Cell, 2002, 14(Suppl): 15-45.
[65]
Fujita Y, Fujita M, Satoh R, et al. AREB1 is a transcription activator of novel ABRE-dependent ABA signaling that enhances drought stress tolerance in Arabidopsis[J/OL]. The Plant Cell Online, 2005, 17: 3470-3488.
[66]
Ding Z, Li S, An X, et al. Transgenic expression of MYB15 confers enhanced sensitivity to abscisic acid and improved drought tolerance in Arabidopsis thaliana[J]. Journal of Genetics and Genomics, 2009, 36: 17-29.
[67]
Cominelli E, Galbiati M, Vavasseur A, et al. A guard-cell-specific MYB transcription factor regulates stomatal movements and plant drought tolerance[J]. Current Biology, 2005, 15: 1196-1200.
[68]
Oh S J, Kim Y S, Kwon C W, et al. Overexpression of the transcription factor AP37 in rice improves grain yield under drought conditions[J]. Plant Physiology, 2009, 150: 1368-1379.
[69]
Wang Z, Liu J X. Advances in studies on DREB/CBF transcription factors,and their applications in genetic engineering for stress tolerance of turf and forage grasses[J]. Acta Prataculturae Sinica, 2011, 20(1): 222-236.
[70]
Liu Q, Kasuga M, Sakuma Y, et al. Two transcription factors, DREB1 and DREB2, with an EREBP/AP2 DNA binding domain separate two cellular signal transduction pathways in drought- and low-temperature-responsive gene expression, respectively, in Arabidopsis[J/OL]. The Plant Cell Online, 1998, 10: 1391-1406.
[71]
Bhatnagar-Mathur P, Devi M J, Vadez V, et al. Differential antioxidative responses in transgenic peanut bear no relationship to their superior transpiration efficiency under drought stress[J]. Journal of Plant Physiology, 2009, 166: 1207-1217.
[72]
Dubouzet J G, Sakuma Y, Ito Y, et al. OsDREB genes in rice, Oryza sativa L., encode transcription activators that function in drought-, high-salt- and cold-responsive gene expression[J]. The Plant Journal, 2003, 33: 751-763.
[73]
Tran L S P, Nakashima K, Sakuma Y, et al. Isolation and functional analysis of Arabidopsis stress-inducible NAC transcription factors that bind to a drought-responsive cis-element in the early responsive to dehydration stress 1 promoter[J/OL]. The Plant Cell Online, 2004, 16: 2481-2498.
[74]
Hu H, Dai M, Yao J, et al. Overexpressing a NAM, ATAF, and CUC (NAC) transcription factor enhances drought resistance and salt tolerance in rice[J]. Proceedings of the National Academy of Sciences, 2006, 103: 12987-12992.
[75]
Sakamoto H, Maruyama K, Sakuma Y, et al. Arabidopsis Cys2/His2-type zinc-finger proteins function as transcription repressors under drought, cold, and high-salinity stress conditions[J]. Plant Physiology, 2004, 136: 2734-2746.
[76]
Kim S, Hong J, Lee S, et al. CAZFP1, Cys2/His2-type zinc-finger transcription factor gene functions as a pathogen-induced early-defense gene in Capsicum annuum[J]. Plant Molecular Biology, 2004, 55: 883-904.
[77]
Ashraf M. Inducing drought tolerance in plants: recent advances[J]. Biotechnology Advances, 2010, 28: 169-183.
[78]
Ashraf M, Foolad M R. Roles of glycine betaine and proline in improving plant abiotic stress resistance[J]. Environmental and Experimental Botany, 2007, 59: 206-216.
[79]
Shen Y G, Du B X, Zhang W K, et al. AhCMO, regulated by stresses in Atriplex hortensis, can improve drought tolerance in transgenic tobacco[J]. Theoretical and Applied Genetics, 2002, 105: 815-821.
[80]
De Ronde J A, Cress W A, Krüger G H J, et al. Photosynthetic response of transgenic soybean plants, containing an Arabidopsis P5CR gene, during heat and drought stress[J]. Journal of Plant Physiology, 2004, 161: 1211-1224.
[81]
Wojtaszek P. Oxidative burst: an early plant response to pathogen infection[J]. Biochemical Journal, 1997, 322: 681-692.
[82]
Jia X J, Dong L H, Ding C B et al. Effects of drought stress on reactive oxygen species and their scavenging systems in Chlorophytum capense var.medio-pictum leaf[J]. Acta Prataculturae Sinica, 2013, 22(5): 248-255.
[83]
Wang F Z, Wang Q B, Kwon S Y, et al. Enhanced drought tolerance of transgenic rice plants expressing a pea manganese superoxide dismutase[J]. Journal of Plant Physiology, 2005, 162: 465-472.
[84]
Mittler R, Zilinskas B A. Regulation of pea cytosolic ascorbate peroxidase and other antioxidant enzymes during the progression of drought stress and following recovery from drought[J]. The Plant Journal, 1994, 5: 397-405.
[85]
Lee S H, Ahsan N, Lee K W, et al. Simultaneous overexpression of both Cu/Zn superoxide dismutase and ascorbate peroxidase in transgenic tall fescue plants confers increased tolerance to a wide range of abiotic stresses[J]. Journal of Plant Physiology, 2007, 164: 1626-1638.
[86]
Luna C M, Pastori G M, Driscoll S, et al. Drought controls on H2O2 accumulation, catalase (CAT) activity and CAT gene expression in wheat[J]. Journal of Experimental Botany, 2005, 56: 417-423.
[87]
Shikanai T, Takeda T, Yamauchi H, et al. Inhibition of ascorbate peroxidase under oxidative stress in tobacco having bacterial catalase in chloroplasts[J]. FEBS Letters, 1998, 428: 47-51.
[88]
Rizhsky L, Hallak-Herr E, Van Breusegem F, et al. Double antisense plants lacking ascorbate peroxidase and catalase are less sensitive to oxidative stress than single antisense plants lacking ascorbate peroxidase or catalase[J]. The Plant Journal, 2002, 32: 329-342.
[89]
Munne-Bosch S. The role of α-tocopherol in plant stress tolerance[J]. Journal of Plant Physiology, 2005, 162: 743-748.
[90]
Yu L, Liu Y H, Zhou L P et al. A study on the changes of ascorbic acid and related physiological indexes in different cultivars of Zoysia under drought stress[J]. Acta Prataculturae Sinica, 2013, 22(4): 106-115.
[91]
Akashi K, Miyake C, Yokota A. Citrulline, a novel compatible solute in drought-tolerant wild watermelon leaves, is an efficient hydroxyl radical scavenger[J]. FEBS Letters, 2001, 508: 438-442.
[92]
Kusvuran S, Dasgan H Y, Abak K. Citrulline is an important biochemical indicator in tolerance to saline and drought stresses in melon[J]. The Scientific World Journal, 2013, 8: 11-55.
[93]
Groppa M D, Benavides M P. Polyamines and abiotic stress: recent advances[J]. Amino Acids, 2008, 34: 35-45.
[94]
Liu Y,Zhang C M, Xie X R et al. Effect of drought stress on polyamine metabolism in the leaves and roots of alfalfa[J]. Acta Prataculturae Sinica, 2012, 21(6): 102-107.
[95]
Alcázar R, Altabella T, Marco F, et al. Polyamines: molecules with regulatory functions in plant abiotic stress tolerance[J]. Planta, 2010, 231: 1237-1249.
[96]
Alcázar R, Marco F, Cuevas J C, et al. Involvement of polyamines in plant response to abiotic stress[J]. Biotechnology Letters, 2006, 28: 1867-1876.
[97]
Kasukabe Y, He L, Nada K, et al. Overexpression of spermidine synthase enhances tolerance to multiple environmental stresses and up-regulates the expression of various stress-regulated genes in transgenic Arabidopsis thaliana[J]. Plant and Cell Physiology, 2004, 45: 712-722.
[98]
Urano K, Yoshiba Y, Nanjo T, et al. Arabidopsis stress-inducible gene for arginine decarboxylase AtADC2 is required for accumulation of putrescine in salt tolerance[J]. Biochemical and Biophysical Research Communications, 2004, 313: 369-375.
[99]
Sunkar R, Zhu J K. Novel and stress-regulated microRNAs and other small RNAs from Arabidopsis[J]. Plant Cell, 2004, 16: 2001-2019.
[100]
Jones-Rhoades M W, Bartel D P. Computational identification of plant microRNAs and their targets, including a stress-induced miRNA[J]. Molecular Cell, 2004, 14: 787-799.
[101]
Arenas-Huertero C, Perez B, Rabanal F, et al. Conserved and novel miRNAs in the legume Phaseolus vulgaris in response to stress[J]. Plant Molecular Biology Reporter, 2009, 70: 385-401.
[102]
Liu H H, Tian X, Li Y J, et al. Microarray-based analysis of stress-regulated microRNAs in Arabidopsis thaliana[J]. RNA, 2008, 14: 836-843.
[103]
Lu S, Sun Y H, Chiang V L. Stress-responsive microRNAs in Populus[J]. Plant Journal, 2008, 55: 131-151.
[104]
Yamaguchi-Shinozaki K, Shinozaki K. Organization of cis-acting regulatory elements in osmotic- and cold-stress-responsive promoters[J]. Trends in Plant Science, 2005, 10: 88-94.
[105]
Wang W, Vinocur B, Altman A. Plant responses to drought, salinity and extreme temperatures: towards genetic engineering for stress tolerance[J]. Planta, 2003, 218: 1-14.
[106]
Qin F, Sakuma Y, Li J, et al. Cloning and functional analysis of a novel DREB1/CBF transcription factor involved in cold-responsive gene expression in Zea mays L[J]. Plant and Cell Physiology, 2004, 45: 1042-1052.
[107]
Novillo F, Alonso J M, Ecker J R, et al. CBF2/DREB1C is a negative regulator of CBF1/DREB1B and CBF3/DREB1A expression and plays a central role in stress tolerance in Arabidopsis[J]. Proceedings of the National Academy of Sciences of the United States of America, 2004, 101: 3985-3990.
[108]
Pellegrineschi A, Reynolds M, Pacheco M, et al. Stress-induced expression in wheat of the Arabidopsis thaliana DREB1A gene delays water stress symptoms under greenhouse conditions[J]. Genome, 2004, 47: 493-500.
[109]
Oh S J, Song S I, Kim Y S, et al.Arabidopsis CBF3/DREB1A and ABF3 in transgenic rice increased tolerance to abiotic stress without stunting growth[J]. Plant Physiology, 2005, 138: 341-351.
[110]
Aharoni A, Dixit S, Jetter R, et al. The SHINE clade of AP2 domain transcription factors activates wax biosynthesis, alters cuticle properties, and confers drought tolerance when overexpressed in Arabidopsis[J/OL]. The Plant Cell Online, 2004, 16: 2463-2480.
[111]
Zhang J Y, Broeckling C D, Blancaflor E B, et al. Overexpression of WXP1, a putative Medicago truncatula AP2 domain-containing transcription factor gene, increases cuticular wax accumulation and enhances drought tolerance in transgenic alfalfa (Medicago sativa)[J]. The Plant Journal, 2005, 42: 689-707.
[112]
Guo Q, Zhang J, Gao Q, et al. Drought tolerance through overexpression of monoubiquitin in transgenic tobacco[J]. Journal of Plant Physiology, 2008, 165: 1745-1755.
[113]
Quan R, Shang M, Zhang H, et al. Engineering of enhanced glycine betaine synthesis improves drought tolerance in maize[J]. Plant Biotechnology Journal, 2004, 2: 477-486.
[114]
Vendruscolo E C G, Schuster I, Pileggi M, et al. Stress-induced synthesis of proline confers tolerance to water deficit in transgenic wheat[J]. Journal of Plant Physiology, 2007, 164: 1367-1376.
[115]
参考文献:
[116]
Boyer J S. Plant productivity and environment[J]. Science, 1982, 218: 443-448.
[117]
Ramachandra Reddy A, Chaitanya K V, Vivekanandan M. Drought-induced responses of photosynthesis and antioxidant metabolism in higher plants[J]. Journal of Plant Physiology, 2004, 161: 1189-1202.
[118]
Shinozaki K, Yamaguchi-Shinozaki K, Seki M. Regulatory network of gene expression in the drought and cold stress responses[J]. Current Opinion In Plant Biology, 2003, 6: 410-417.
[119]
Umezawa T, Fujita M, Fujitam Y,et al. Engineering drought tolerance in plants: discovering and tailoring genes to unlock the future[J]. Current Opinion in Biotechnology, 2006, 17: 113-122.
[120]
Vinocur B, Altman A. Recent advances in engineering plant tolerance to abiotic stress: achievements and limitations[J]. Current Opinion in Biotechnology, 2005, 16: 123-132.
[121]
Shou H, Bordallo P, Wang K. Expression of the Nicotiana protein kinase (NPK1) enhanced drought tolerance in transgenic maize[J]. Journal of Experimental Botany, 2004, 55: 1013-1019.
[122]
Cutler S, Ghassemian M, Bonetta D,et al. A protein farnesyl transferase involved in abscisic acid signal transduction in Arabidopsis[J]. Science, 1996, 273: 1239-1241.
[123]
Boudsocq M, Barbier-Brygoo H, Laurière C. Identification of nine sucrose nonfermenting 1-related protein kinases 2 activated by hyperosmotic and saline stresses in Arabidopsis thaliana[J]. Journal of Biological Chemistry, 2004, 279: 41758-41766.
[124]
Umezawa T, Yoshida R, Maruyama K,et al. SRK2C, a SNF1-related protein kinase 2, improves drought tolerance by controlling stress-responsive gene expression in Arabidopsis thaliana[J]. Proceedings of the National Academy of Sciences of the United States of America, 2004, 101: 17306-17311.
[125]
Cheong Y H, Kim K N, Pandey G K,et al. CBL1, a calcium sensor that differentially regulates salt, drought, and cold responses in Arabidopsis[J/OL]. The Plant Cell Online, 2003, 15: 1833-1845.
[126]
Posas F, Saito H. Osmotic activation of the HOG MAPK pathway via Ste11p MAPKKK: scaffold role of Pbs2p MAPKK[J]. Science,1997, 276: 1702-1705.
[127]
Karim S, Aronsson H, Ericson H,et al. Improved drought tolerance without undesired side effects in transgenic plants producing trehalose[J]. Plant Molecular Biology, 2007, 64: 371-386.
[128]
Jang I C, Oh S J, Seo J S,et al. Expression of a bifunctional fusion of the Escherichia coli genes for trehalose-6-phosphate synthase and trehalose-6-phosphate phosphatase in transgenic rice plants increases trehalose accumulation and abiotic stress tolerance without stunting growth[J]. Plant Physiology, 2003, 131: 516-524.
[129]
Wu R, Garg A. Engineering rice plants with trehalose-producing genes improves tolerance to drought, salt, and low temperature[R]. ISB News Report, 2003.
[130]
Abebe T, Guenzi A C, Martin B,et al. Tolerance of mannitol-accumulating transgenic wheat to water stress and salinity[J]. Plant Physiology, 2003, 131: 1748-1755.
Wang F Z, Wang Q B, Kwon S Y,et al. Enhanced drought tolerance of transgenic rice plants expressing a pea manganese superoxide dismutase[J]. Journal of Plant Physiology, 2005, 162: 465-472.
[135]
Mittler R, Zilinskas B A. Regulation of pea cytosolic ascorbate peroxidase and other antioxidant enzymes during the progression of drought stress and following recovery from drought[J]. The Plant Journal, 1994, 5: 397-405.
[136]
Lee S H, Ahsan N, Lee K W,et al. Simultaneous overexpression of both Cu/Zn superoxide dismutase and ascorbate peroxidase in transgenic tall fescue plants confers increased tolerance to a wide range of abiotic stresses[J]. Journal of Plant Physiology, 2007, 164: 1626-1638.
[137]
Luna C M, Pastori G M, Driscoll S,et al. Drought controls on H2O2 accumulation, catalase (CAT) activity and CAT gene expression in wheat[J]. Journal of Experimental Botany, 2005, 56: 417-423.
[138]
Shikanai T, Takeda T, Yamauchi H,et al. Inhibition of ascorbate peroxidase under oxidative stress in tobacco having bacterial catalase in chloroplasts[J]. FEBS Letters, 1998, 428: 47-51.
[139]
Rizhsky L, Hallak-Herr E, Van Breusegem F,et al. Double antisense plants lacking ascorbate peroxidase and catalase are less sensitive to oxidative stress than single antisense plants lacking ascorbate peroxidase or catalase[J]. The Plant Journal, 2002, 32: 329-342.
[140]
Qin F, Sakuma Y, Li J,et al. Cloning and functional analysis of a novel DREB1/CBF transcription factor involved in cold-responsive gene expression in Zea mays L[J]. Plant and Cell Physiology, 2004, 45: 1042-1052.
[141]
Novillo F, Alonso J M, Ecker J R,et al. CBF2/DREB1C is a negative regulator of CBF1/DREB1B and CBF3/DREB1A expression and plays a central role in stress tolerance in Arabidopsis[J]. Proceedings of the National Academy of Sciences of the United States of America, 2004, 101: 3985-3990.
[142]
Pellegrineschi A, Reynolds M, Pacheco M,et al. Stress-induced expression in wheat of the Arabidopsis thaliana DREB1A gene delays water stress symptoms under greenhouse conditions[J]. Genome, 2004, 47: 493-500.
[143]
Oh S J, Song S I, Kim Y S,et al. Arabidopsis CBF3/DREB1A and ABF3 in transgenic rice increased tolerance to abiotic stress without stunting growth[J]. Plant Physiology, 2005, 138: 341-351.
[144]
Aharoni A, Dixit S, Jetter R,et al. The SHINE clade of AP2 domain transcription factors activates wax biosynthesis, alters cuticle properties, and confers drought tolerance when overexpressed in Arabidopsis[J/OL]. The Plant Cell Online, 2004, 16: 2463-2480.
[145]
Zhang J Y, Broeckling C D, Blancaflor E B,et al. Overexpression of WXP1, a putative Medicago truncatula AP2 domain-containing transcription factor gene, increases cuticular wax accumulation and enhances drought tolerance in transgenic alfalfa (Medicago sativa)[J]. The Plant Journal, 2005, 42: 689-707.
[146]
Guo Q, Zhang J, Gao Q,et al. Drought tolerance through overexpression of monoubiquitin in transgenic tobacco[J]. Journal of Plant Physiology, 2008, 165: 1745-1755.
[147]
Quan R, Shang M, Zhang H,et al. Engineering of enhanced glycine betaine synthesis improves drought tolerance in maize[J]. Plant Biotechnology Journal, 2004, 2: 477-486.
[148]
Vendruscolo E C G, Schuster I, Pileggi M,et al. Stress-induced synthesis of proline confers tolerance to water deficit in transgenic wheat[J]. Journal of Plant Physiology, 2007, 164: 1367-1376.
