[1]冷翔鹏. 葡萄应答铜胁迫的分子机理研究[D]. 南京:南京农业大学博士学位论文,2015:1-2. [2] Mostofa M G, Hossain M A, Fujita M et al.Physiological and biochemical mechanisms associated with trehalose-induced copper-stress tolerance in rice[J].SSci. Rep.S5, 2015,11433. [3] Mostofa, M. G.S SFujita, M.SSalicylic acid alleviates copper toxicity in rice (Oryza sativaSL.) seedlings by up-regulating antioxidative and glyoxalase systems[J]. Ecotoxicology.S2013,22, 959-973 . [4]尹博,梁国鹏,贾文等.外源油菜内酯介导Cu胁迫下番茄生长及Cu、Fe、Zn的吸收与分配[J].中国生态农业学报,2014,22(5):578-584. [5]Ma J F. Plant root responses to three abundant soil minerals: silicon,aluminum and iron. Critical Reviews in Plant Sciences,2005,24(4):267-281. [6]LIU J J,LIN S H,XU P L,et al. Effects of exogenous Silicon on the activities of antioxidant enzymes and lipid peroxidation in chilling-stressed cucumber leaves[J]. Agricultural Sciences in China,2009,8 ( 9) : 1075. [7]ASHRAF M,RAHMATULLAH M,AHMAD R,et al.Amelioration of salt stress in sugarcane ( Saccharum officinarum L.) by supplying potassium and silicon in hydroponics[J]. Pedosphere,2010,20 ( 2) : 153. [8]ZHANG Q,YAN C L,LIU J C,et al.Silicon alleviates Cadmium toxicity in Avicennia marina ( Forsk. ) Vierh.seedlings in relation to root anatomy and radial oxygen loss[J]. Marine Pollution Bulletin,2013,76 ( 1/2) : 187. [9] NWUGO C C,HUERTA A J.The effect of silicon on the leaf proteome of rice ( Oryza sativa L.) plants under cadmium-stress[J]. Journal of Proteome Research,2011,10 ( 2) : 518. [10]Upadhyay RK,Panda SK. Copper induced growth inhibition,oxidative stress and ultrastructural alterations in freshly grown water lettuce ( Pistia stratiotes L.).Comptes Rendus Biologies,2009,332: 623- 632. [11] 王小玲,刘腾云,幸学俊等. 硅对Cd、Pb、Cu、Zn正交胁迫下水稻丙二醛含量的影响[J]. 湖北农业科学,2016,22(55):5571-5776. [12] 黄秋婵,许元明,曾振芳等. 硅对镉胁迫下水稻幼苗茎叶元素含量的影响[J].湖北农业科学,2013,11:56-59. [13]卢志红,朱美英,石庆华等. 硫硅配施对铜胁迫下水稻幼苗生长及其吸收累积铜的影响[J]. 江西农业大学学报,2013,6:89-91. [14]张黛静,马建辉,杨淑芳等. 硅对铜胁迫下小麦幼根细胞超微结构的影响[J]. 河南师范大学生命科学学院,2014,8:69-72. [15]张志雯,秦素平,陈于和等. 硅对铬、铜胁迫下小麦幼苗生理生化指标的影响[J]. 华北农学报,2014,29(增刊):229-233. [16] 尹博,梁国鹏,贾文等.外源油菜内酯介导Cu胁迫下番茄生长及Cu、Fe、Zn的吸收与分配[J].中国生态农业学报,2014,22(5):578-584. [17] 窦巧慧,王娟,尹博等. 外源油菜素内酯(EBR)对Cu胁迫期间番茄幼苗的缓解效应[J]. 植物生理学报,S2015,03(51),287-294. [18] SP ChamarthyS, R Pinal. Interaction of brassinosteroids and polyamines enhances copper stress tolerance in raphanus sativus[J]. Journal of Experimental Botany,SS2012S,S63S(15)S:5659. [19]李涛涛,高永锋,马瑄等. 外源油菜素内酯对三种杨树在干旱、盐和铜胁迫下光合生理的影响[J]. 基因组学与应用物学,2016,1:121-123. [20] Boldizsa r A,Simon-Sarkadi L,Szirtes K,et al. Nitric oxide affects salt-induced changes in free amino acid levels in maize[J]. Journal of Plant Physiology,2013,170: 1020-1027. [21]Saxena I,Shekhawat GS. Nitric oxide ( NO) in alleviation of heavy metal induced phytotoxicity and its role inprotein nitration[J]. Nitric Oxide,2013,32: 13-20. [22]Mhadhbi H,Fotopoulos V,Mylona P V,et al. Antioxidant gene-enzyme responses in Medicago truncatula genotypes with different degree of sensitivity to salinity[J]. Physiologia Plantarum,2011,141: 201-214. [23]Panda P,Nath S,Chanu TT,et al . Cadmium stress-induced oxidative stress and role of nitric oxide in rice ( Oryza sativa L.) [J]. Acta Physiologiae Plantarum,2011,33: 1737-1747. [24]Gill SS, Hasanuzzaman M,Nahar K,et al.Importance of nitric oxide in cadmium stress tolerance in crop plants[J]. Plant Physiology and Biochemistry,2013,63:254-261 [25] 王逸筠,李晓云,王建等. 外源NO介导Cu2+胁迫下番茄幼苗活性氧与内源代谢的研究[J]. 生态毒理学报,2014,9(4):678-688. [26] Mostofa, M. G.,SSeraj, Z. I.S SFujita, M.SExogenous sodium nitroprusside and glutathione alleviate copper toxicity by reducing copper uptake and oxidative damage in rice (Oryza sativaSL.) seedlings[J].SProtoplasmaS2014,251, 1373–1386. [27] 王建,窦巧惠,于世欣等. 外源NO对Cu 胁迫下番茄幼苗L-精氨酸代谢的影响[J]. 生态毒理学报,2015,10( 3) : 112-122. [28] 张敏,梁国鹏,姜春辉等. 外源一氧化氮介导铜胁迫下番茄幼苗中铁、锌、锰的累积及亚细胞分布[J]. 植物营养与肥料学报,2014,3:69-71. [29]王建,于世欣,王逸筠等. 外源NO对铜胁迫下番茄植物螯合肽及精氨酸代谢的影响[J]. 水土保持学报, 2014,4:80-82. [30]王建,于世欣,张敏等. 外源NO介导Cu 胁迫下番茄GSH-PCs 合成途径[J]. 应用生态学报,2014,25( 9) : 2629-2636. [31] 刘颖,邓明华,龚明等. 外源NO对Cu2+胁迫下小桐子幼苗抗氧化能力的影响[J]. 西北植物学报,2013,7:34-36. [32]叶伟栋,李赛男,鲍若栋等. 硝普钠对铜胁迫下水稻幼苗生长的缓解效应[J]. 台州学院学报,2015,3:65-67. [33]叶丽萍,钟凤林,林义章等. 外源NO对铜胁迫下小白菜SBPase基因表达特性及其光合速率的影响[J]. 植物营养与肥料学报,2016,3:98-100. [34]姜春辉. 外源一氧化氮对番茄幼苗铜胁迫缓解效应的研究[D].山东:山东农业大学.2012:2. [35]赵慧. 外源NO对铜、镉及其复合胁迫下狭叶香蒲幼苗的影响[D]. 南京:南京农业大学硕士学位论文,2014:2-3. [36]李晓京. 外源一氧化氮(NO)缓解小白菜铜胁迫的生理效应[D].山东:山东农业大学硕士学位论文,2009:2-3. [37]徐根娣, 葛淑芳,章艺等. 外源水杨酸对Cu 胁迫下水培烟草生长及营养元素吸收利用的影响[J]. 作物学报,2015, 41(6): 956-962. [38]李魏飞. 萘乙酸对铜胁迫下刺槐幼苗生理特性的影响[J]. 贵州农业科学. 2013,3:99-101. [39] 王红霞,胡金朝,施国新等. 外源多胺对铜胁迫下水鳖叶片多胺代谢、抗氧化系统和矿质营养元素的影响[J].生态学报,2010, 30(10):2784-2792. [40]丁佳红,薛正链,杨超英. 水杨酸对铜胁迫下水稻幼苗膜脂过氧化作用的影响[J]. 黑龙江农业科学,2013(1):14-18. [41]葛淑芳,章艺,梅笑漫等. 外源水杨酸对铜胁迫下烟草叶片碳代谢的影响[J].水土保持学报,2014,4:78-80. [42]韩承华,潘瑞瑞,刘野等. Cu、Zn 对水蕹菜生长的影响及Se 的缓解作用[J]. 生态学杂志,2016,35( 2) : 470-477. [43]陈金峰,胡斌杰,韩艳霞等. 钙对铜胁迫下大豆种子的解毒作用[J]. 大豆科学,2008,6:89-91. [44]王晓维,徐健程,孙丹平等. 生物炭对铜胁迫下红壤地油菜苗期叶绿素和保护性酶活性的影响[J]. 农业环境科学学报, 2016,4:89-91. [45]MK SammaS, H ZhouS, W CuiS, et al. Methane alleviates copper-induced seed germination inhibition and oxidative stress in Medicago sativa[J]. Biometals,S2017,S30(1):97-111. [46]柯文山,陈世俭,熊治廷等. 铜和营养缺失对海州香薷两个种群生长、耐性及矿质营养吸收的差异影响[J]. 生态学报,2013, 33( 15) :4737-4743. [47]徐惠全. EDTA 和有机肥对植物生长及铜吸收特征的影响[D]. 兰州:甘肃农业大学硕士学位论文,2012:1-2. [48]孔文杰. 畜禽商品有机肥与化肥配施对土壤-萝卜系统重金属平衡影响[J].水土保持学报,2011(2):90-92.
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