[1] 黎裕, 王建康, 邱丽娟, 马有志, 李新海, 万建民. 中国作物分子育种性状与发展前景. 作物学报, 2010, 36(9): 1425-1430.
Li Y, Wang J K, Qiu L J, Ma Y Z, Li X H, Wan J M. The traits and development prospect of crop molecular breeding in China. Acta Agronomica Sinica, 2010, 36(9): 1425-1430. (in Chinese)
[2] Wang C R, Yang A F, Yue G D, Gao Q, Yin H Y, Zhang J R. Enhanced expression of phospholipase C1 (ZmPLC) improves drought tolerance in transgenic maize. Planta, 2008, 227: 1127-1140.
[3] Liu X, Zhai S, Zhao Y, Sun B, Liu C, Yang A, Zhang J. Overexpression of the phosphatidylinositol synthase gene (ZmPIS) conferring drought stress tolerance by altering membrane lipid composition and increasing ABA synthesis in maize. Plant Cell and Environment, 2013, 36: 1037-1055.
[4] He C M, He Y, Liu Q, Liu T, Liu C, Wang L, Zhang J. co-expression of genes ApGSMT2 and ApDMT2 for glycine betaine synthesis in maize enhances the drought tolerance of plant. Molecular Breeding, 2013, 31: 559-573.
[5] Quan R D, Shang M, Zhang H, Zhao Y, Zhang J. Engineering of enhanced glycine betaine synthesis improves drought tolerance in maize. Plant Biotechnology Journal, 2004, 2: 477-486.
[6] Wei A Y, He C M, Li B, Li N, Zhang J R. The pyramid of transgenes TsVp and BetA effectively enhances the drought tolerance of maize plants. Plant Biotechnology Journal, 2011, 9: 216-229.
[7] Li B, Wei A, Song C, Li N, Zhang J. Heterologous expression of the TsVP gene improves the drought resistance of maize. Plant Biotechnology Journal, 2008, 6: 146-159.
[8] Lightfoot D A, Mungur R, Ameziane R, Nolte S, Long L, Bernhard K, Colter A, Jones K, Iqbal M J, Varsa E, Young B. Improved drought tolerance of transgenic Zea mays plants that express the glutamate dehydrogenase gene (gdhA) of E. coli. Euphotic, 2007, 156: 103-116.
[9] Shou H X, Bordallo P, Wang K. Expression of the Nicotiana protein kinase (NPK1) enhanced drought tolerance in transgenic maize. Journal of Experimental Botany, 2004, 55: 1013-1019.
[10] Zhang S J, Li N, Gao F, Yang A, Zhang J. Over-expression of TsCBF1 gene confers improved drought tolerance n transgenic maize. Molecular Breeding, 2010, 26: 455-465.
[11] Nelson D E, Repetti P P, Adams T R, Creelman R A, Wu J, Warner D C, Anstrom D C, Bensen R J, Castiglioni P P, Donnarummo M G, Hinchey B S, Kumimoto R W, Maszle D R, Canales R D, Krolikowski K A, Dotson S B, Gutterson N, Ratcliffe O J, Heard J E. Plant nuclear factor Y (NF-Y) B subunits confer drought tolerance and lead to improved corn yields on water-limited acres. Proceedings of the National Academy of Science of the USA, 2007, 104: 16450-16455.
[12] Virlouvet L, Jacquemot M P, Gerentes D, Corti H, Bouton S, Gilard F, Valot B, Trouverie J, Tcherkez G, Falque M, Damerval C, Rogowsky P, Perez P, Noctor G, Zivy M, Coursol S. The ZmASR1 protein influences branched-chain amino acid biosynthesis and maintains kenel yield in maize under water-limited conditions. Plant Physiology, 2011, 157: 917-936.
[13] Castiglioni P, Warner D, Bensen R J, Anstrom D C, Harrison J, Stoecker M, Abad M, Kumar G, Salvador S, D’Ordine R, Navarro S, Back S, Fernandes M, Targolli J, Dasgupta S, Bonin C, Luethy M H, Heard J E. Bacterial RNA chaperones confer abiotic stress tolerance in plants and improved grain yield in maize under water-limited conditions. Plant Physiology, 2008, 147: 446-455.
[14] Shinozaki K, Yamaguchi-Shinozaki K. Gene expression and signal transduction in water-stress response. Plant Physiology, 1997, 115: 327-334.
[15] Xiong L, Ishitani M, Lee H, Zhu J K. The Arabidopsis LOS5/ABA3 locus encodes a molybdenum cofactor sulfurase and modulates cold stress- and osmotic stress-responsive gene expression. The Plant Cell, 2001, 13: 2063-2083.
[16] Xiao B Z, Chen X, Ceng B, Tang N, Zhang Q F, Xiong L Z. Evaluation of seven function-known candidate genes for their effects on improving drought resistance of transgenic rice under field conditions (Special Issue: Abiotic stress tolerance: from gene discovery in model organisms to crop improvement). Molecular Plant, 2009, 2(1): 73-83.
[17] Yue Y S, Zhang M C, Zhang J C, Tian X L, Duan L S, Li Z H. Overexpression of the AtLOS5 gene increased abscisic acid level and drought tolerance in transgenic cotton. Journal of Experimental Botany, 2012, 63: 3741-3748.
[18] Li Y J, Zhang J C, Zhang J, Hao L, Hua J P, Duan L S, Zhang M C, Li Z H. Expression of an Arabidopsis molybdenum factor sulphurase gene in soybean enhances drought tolerance and increases yield under field conditions. Plant Biotechnology Journal, 2013, 11: 747-758.
[19] Yue Y S, Zhang M C, Zhang J C, Duan L S, Li Z H. Arabidopsis LOS5/ABA3 overexpression in transgenic tobacco (Nicotiana tabacum cv. Xanthi-nc) results in enhanced drought tolerance. Plant Science, 2011, 181: 405-411.
[20] Gao S, Yuan L, Zhai H, Liu C L, He S Z, Liu Q C. Transgenic sweet potato plants expressing an LOS5 gene are tolerant to salt stress. Plant Cell Tissue & Organ Culture, 2011, 107(2): 205-213.
[21] Liu L, Duan L, Zhang J, Mi G, Zhang X, Zhang Z, Ren H. Arabidopsis LOS5 gene enhances chilling and salt stress tolerance in cucumber. Journal of Integrative Agriculture, 2013, 12: 825-834.
[22] Zhang J, Yu H, Zhang Y, Wang Y, Li M, Zhang J, Duan L, Zhang M, Li Z. Increased abscisic acid levels in transgenic maize overexpressing At LOS5 mediated root ion fluxes and leaf water status under salt stress. Journal of Experimental Botany, 2016, 67: 1339-1355.
[23] Lu U Y, Li Y J, Zhang J C, Xiao Y T, Yue Y S, Duan L S, Zhang M Z, Li Z H. Overexpression of Arabidopsis molybdenum cofactor sulfurase gene confers drought tolerance in maize (Zea mays L.). Plos One, 2013, 8(1): 39 ref.
[24] 杨启良, 孙英杰, 齐亚峰, 刘艳伟, 王成武, 刘小刚, 戈振扬. 不同水量交替灌溉对小桐子生长调控与水分利用的影响. 农业工程学报, 2012, 28(18): 121-126.
Yang Q L, Sun Y J, Qi Y F, Liu Y W, Wang C W, Liu X G, Ge Z Y. Effect on growth regulation and water use efficiency of Jatropha Curcas by different water alternate irrigation. Journal of Agricultural Engineeing, 2012, 28(18): 121-126. (in Chinese)
[25] 孙宝成, 刘成, 王天宇, 黎裕, 张登峰, 李亮, 唐怀君, 石云素, 宋燕春. 转基因玉米株高、ASI和穗部性状与抗旱性的关系研究. 新疆农业科学, 2012, 49: 1961-1965.
Sun B C, Liu C, Wang T Y, Li Y, Zhang D F, Li L, Tang H J, Shi Y S, Song Y C. Studies on the relationship between plant height, ASI, ear traits and drought resistance of transgenic maize. Xinjiang Agricultural Sciences, 2012, 49: 1961-1965. (in Chinese)
[26] 黎裕, 王天宇, 刘成, 石云素, 宋燕春. 玉米抗旱品种的筛选指标研究. 植物遗传资源学报, 2004, 5: 210-215.
Li Y, Wang T Y, Liu C, Shi Y S, Song Y C. Analysis of criteria for screening drought tolerant maize hybrids. Journal of Plant Genetic Resources, 2004, 5: 210-215. (in Chinese)
[27] 艾天成, 李方敏, 周治安, 张敏, 吴海荣. 作物叶片叶绿素含量与SPAD值相关性研究. 湖北农学院学报, 2000, 20(1): 6-8.
Ai T C, Li F M, Zhou Z A, Zhang M, Wu H R. Correlation study on chlorophyll content and SPAD value of crop leaves. Journal of Hubei College of Agriculture, 2000, 20(1): 6-8. (in Chinese)
[28] JOSE L R, DAVID A, RAMIRE Z, WENDY Y, PHILIPPE M, ROBERTO Q. Leaf greenness as a drought tolerance related trait in potato (Solanum tuber sum L.). Environmental and Experimental Botany, 2015, 10: 27-35.
[29] HIDETOSHI A, BENJAMIN K S, HAEFELE M S, KHAMDOK S, KOKI H, YOSHIYUKI K, YOSHIO I, TAT-SUHIKO S, TAKESHI H. Biochar amendment techniques for upland rice production in Northern Laos, 1. Soil physical properties, leaf SPAD and grain yield. Field Crops Research, 2009, 111: 81-84.
[30] RAHIMI A, MADAH H S, POORYOOSEF M, FATATEH I. Variation of leaf water potential, relative water content and SPAD under gradual drought stress and stress recovery in two medicinal species of Plant ago ovata and P. psyllium. Plant Ecophysiology, 2010(2): 53-60.
[31] 陈春梅, 高聚林, 苏治军, 于晓芳, 胡树平, 赵晓亮. 玉米自交系吐丝期叶片光合参数与其耐旱性的关系. 作物学报, 2014, 40(9): 1667-1676.
CHEN C M, GAO J L, SU Z J, YU X F, HU S P, ZHAO X L. Relationship between leaf photosynthetic parameters and drought resistance at silking stage in maize inbred lines. Acta Agronomica Sinica, 2014, 40(9): 1667-1676. (in Chinese) |