[1]Nelson J C. Genetic associations between photosynthetic characteristics and yield: review of the evidence. Plant Physiology and Biochemistry, 1988, 26: 543-554.[2]Evans J R. Acclimation by the thylakoid membranes to growth irradiance and the partitioning of nitrogen between soluble and insoluble proteins. Australian Journal of Plant Physiology, 1988, 15: 93-106.[3]Spano G, Di Fonzo N, Perrotta C, Platani C, Ronga G, Lawlor D W, Napier J A, Shewry P R. Physiological characterization of `stay green' mutants in durum wheat. Journal of Experimental Botany, 2003, 54: 1415-1420.[4]Tollenaar M, Daynard T B. Leaf senescence in short-season maize hybrids. Canadian Journal of Science, 1978, 58: 869-874.[5]Wolfe D W, Henderson D W, Hsiao T C, Alvino A. Interactive water and nitrogen effects on senescence of maize. I. leaf area duration, nitrogen distribution, and yield. Agronomy Journal, 1988, 80: 859-864.[6]Ma B L, Dwyer L M. Nitrogen uptake and use of two contrasting maize hybrids differing in leaf senescence. Plant and Soil, 1998, 199: 283-291.[7]Borrell A K, Hammer G L, Henzell R G. Does maintaining green leaf area in sorghum improve yield under drought? II. dry matter production and yield. Crop Science, 2000, 40: 1037-1048.[8]Hörtensteiner S. Stay-green regulates chlorophyll and chlorophyll- binding protein degradation during senescence. Trends in Plant Science, 2009, 14: 155-162.[9]Cha K W, Lee Y J, Koh H J, Lee B M, Nam Y W, Paek N C. Isolation, characterization, and mapping of the stay green mutant in rice. Theoretical and Applied Genetics, 2002, 104: 526-532.[10]Cornelius S B. The stay-green revolution: Recent progress in deciphering the mechanisms of chlorophyll degradation in higher plants. Plant Science, 2009, 176: 325-333.[11]陈文峻, 蒯本科. 植物的滞绿突变. 植物生理学通讯, 1999, 35(4): 321-324.Chen W J, Kuai B K. Stay-green mutations in plants. Plant Physiology Communications, 1999, 35(4): 321-324. (in Chinese)[12]Porra R J. The chequered history of the development and use of simultaneous equations for the accurate determination of chlorophyll a and b. Photosynthesis Research, 2002, 73: 149-156.[13]Zhang L T, Zhang Z S, Gao H Y, Xue Z C, Yang C, Meng X L, Meng Q W. Mitochondrial alternative oxidase pathway protects plants against photoinhibition by alleviating inhibition of the repair of photodamaged PSII through preventing formation of reactive oxygen species in Rumex K-1 leaves. Physiologia Plantarum, 2011, 143: 396-407.[14]Schansker G, Srivastava A, Govindjee, Strasser R J. Characterization of the 820-nm transmission signal paralleling the chlorophyll a fluorescence rise (OJIP) in pea leaves. Functional Plant Biology, 2003, 30: 785-796.[15]任丽丽, 高辉远. 低温弱光胁迫对野生大豆和大豆栽培种光系统功能的影响. 植物生理与分子生物学学报, 2007, 33(4): 333-340.Ren L L, Gao H Y. The influence of chilling and low light to the photosystems of wild and cultivate soybean. Journal of Plant Physiology and Molecular Biology, 2007, 33(4): 333-340. (in Chinese)[16]Zhang Z S, Jia Y J, Gao H Y, Zhang L T, Li H D, Meng Q W. Characterization of PSI recovery after chilling-induced photoinhibition in cucumber (Cucumis sativus L.) leaves. Planta, 2011, 234: 883-889.[17]Strasser B J, Strasser R J. Measuring fast fluorescence transients to address environmental questions: the JIP-test//Proceedings of the Xth International Photosynthesis Congress, Montpellier, France, 1995: 977-980. [18]李鹏民, 高辉远, Strasser R J. 快速叶绿素荧光诱导动力学分析在光合作用研究中的应用. 植物生理与分子生物学学报, 2005, 31(6): 559-566. Li P M, Gao H Y, Strasser R J. Application of the chlorophyll fluorescence Induction dynamics in photosynthesis study. Journal of Plant Physiology and Molecular Biology, 2005, 31(6): 559-566. (in Chinese)[19]Jiang H X, Tang N, Zheng J G, Chen L S. Antagonistic actions of boron against inhibitory effects of aluminum toxicity on growth, CO2 assimilation, ribulose-1,5-bisphosphate carboxylase/oxygenase, and photosynthetic electron transport probed by the JIP-test, of Citrus grandis seedlings. BMC Plant Biology, 2009, 9: 102.[20]Lin Z H, Chen L S, Chen R B, Zhang F Z, Jiang H X, Tang N. CO2 assimilation, ribulose-1,5-bisphosphate carboxylase/oxygenase, carbohydrates and photosynthetic electron transport probed by the JIP-test, of tea leaves in response to phosphorus supply. BMC Plant Biology, 2009, 9: 43.[21]Ludewig F, Sonnewald U. High CO2-mediated down-regulation of photosynthetic gene transcripts is caused by accelerated leaf senescence rather than sugar accumulation. FEBS Letters, 2000, 479: 19-24.[22]Miersch I, Heise J, Zelmer I, Humbeck K. Differential degradation of the photosynthetic apparatus during leaf senescence in barley (Hordeum vulgare L.). Plant Biology, 2000, 2: 618-623.[23]Chiba A, Ishida H, Nishizawa N K, Makino A, Mae T. Exclusion of ribulose-1,5-bisphosphate carboxylase⁄oxygenase from chloroplasts by specific bodies in naturally senescing leaves of wheat. Plant Cell Physiology, 2003, 44: 914-921.[24]Andersson A, Keskitalo J, Sjödin A, Bhalerao R, Sterky F, Wissel K, Tandre K, Aspeborg H, Moyle R, Ohmiya Y, Bhalerao R, Brunner A, Gustafsson P, Karlsson J, Lundeberg J, Nilsson O, Sandberg G, Strauss S, Sundberg B, Uhlen M, Jansson S, Nilsson P. A transcriptional timetable of autumn senescence. Genome Biology, 2004, 5: R24.[25]Buchanan-Wollaston V, Page T, Harrison E, Breeze E, Lim P O, Nam H G, Lin J F, Wu S H, Swidzinski J, Ishizaki K, Leaver C J. Comparative transcriptome analysis reveals significant differences in gene expression and signalling pathways between developmental and dark/starvation-induced senescence in Arabidopsis. The Plant Journal, 2005, 42: 567-585. |