CO_2浓度加倍下水氮耦合对黄瓜叶片碳氮代谢及其关键酶活性的影响  被引量：5

作　　者：李曼[1] 董彦红[1] 崔青青[1] 张文东[1] 艾希珍[1,2] 刘彬彬[2] 李清明[1,2,3] LI Man DONG Yan-Hong CUI Qing-Qing ZHANG Wen-Dong AI Xi-Zhen LIU Bin-Bin LI Qing-Ming(College of Horticulture Science and Engineering, Shandong Agricultural University, Taian, Shandong 271018, China State Key Laboratory of Crop Biology, Taian, Shandong 271018, China Scientific Observing and Experimental Station of Environment Controlled Agricultural Engineering in Huang-Huai-Hai Region, Ministry of Agriculture, Taian, Shandong 271018, China)

机构地区：[1]山东农业大学园艺科学与工程学院,山东泰安271018 [2]作物生物学国家重点实验室,山东泰安271018 [3]农业部黄淮海设施农业工程科学观测实验站,山东泰安271018

出　　处：《植物生理学报》2017年第9期1717-1727,共11页Plant Physiology Journal

基　　金：国家自然科学基金(31471918);山东省自然科学基金(ZR2013CM008);山东省农业重大应用技术创新项目(鲁财农指[2016]36号)~~

摘　　要：以‘津优35号’黄瓜(Cucumis sativus)为试材,采用三裂式裂区试验设计,研究了CO_2浓度加倍下水氮耦合对黄瓜叶片碳、氮代谢及其关键酶活性的影响。主区因素为CO_2浓度,设大气CO_2浓度(400μmol·mol^(-1))和加倍CO_2浓度[(800±20)μmol·mol^(-1)]两个水平;裂区因素为水分处理,设无干旱胁迫(灌水上限为田间持水量的95%)和干旱胁迫(灌水上限为田间持水量的75%)两个水平;再裂区因素为施氮量,设施氮量450 kg·hm-2(低氮)和900 kg·hm^(-2)(高氮)两个水平。结果表明:(1)CO_2浓度加倍提高了干旱和高氮条件下黄瓜的株高,且使高氮下的叶面积显著增加。(2)CO_2浓度加倍显著提高了黄瓜叶片蔗糖、淀粉、还原糖含量,蔗糖合成酶(SS)的活性显著增加;高氮显著增加了CO_2浓度加倍条件下SS和蔗糖磷酸合成酶(SPS)活性,促进蔗糖积累和淀粉分解。干旱胁迫使SS活性显著增加,SPS活性显著降低,CO_2浓度加倍显著提高了干旱胁迫下SS和SPS活性以及蔗糖和还原糖含量,且SS和SPS活性以及蔗糖含量随氮素的增加而显著增加。(3)CO_2浓度加倍显著提高了硝酸还原酶(NR)活性,但是谷氨酰胺合成酶(GS)和谷氨酸合酶(GOGAT)活性并未同步增加。在CO_2浓度加倍条件下,高氮使干旱胁迫的黄瓜叶片NR和GOGAT活性显著提高,GS活性的降低得到缓解。(4)加倍CO_2浓度、无干旱胁迫、高氮处理下产量最高,其次是加倍CO_2浓度、干旱胁迫、高氮处理。在大气CO_2浓度和干旱条件下,低氮处理产量最大,继续增施氮肥产量无显著差异,而在CO_2浓度加倍和干旱条件下,增施氮肥黄瓜产量则显著上升。因此,在CO_2浓度加倍条件下高氮促进了干旱胁迫的光合产物转化,使氮同化能力的降低得到缓解或改变,促进干旱胁迫下黄瓜叶片的碳氮代谢,能在一定程度上缓解干旱胁迫造成的不利影响,从而提高黄瓜生长量和产量,可为设施黄瓜CO_2施肥及水分�Using three-factor split-plot design, effects of water-nitrogen coupling on the metabolites and key enzyme activities of carbon and nitrogen metabolism in cucumber（Cucumis sativus） cv. ‘Jinyou No. 35＇ under doubled CO_2 concentration were investigated. The main plot factor was CO_2 concentrations： ambient CO_2 concentration（400 μmol·mol-1） and doubled CO_2 concentration [（800±20） μmol·mol^（-1）]. The split plot factor was water treatments： no drought stress（95% of field capacity） and drought stress（75% of field capacity）. The splitsplit plot factor was nitrogen application rate： low nitrogen（450 kg·hm-1） and high nitrogen（900 kg·hm-1）. The results showed that：（1） Under the condition of drought stress and high nitrogen, doubled CO_2 concentration enhanced the plant height of cucumber, and no matter what kind of water condition, doubled CO_2 concentration significantly increased the leaf area under high nitrogen.（2） Doubled CO_2 concentration remarkably increased sucrose, starch and reducing sugar contents, as well as sucrose synthetase（SS） activity. Under doubled CO_2 concentration, high nitrogen remarkably increased the activities of SS and sucrose phosphate synthase（SPS）, which led to accumulation of sucrose and decomposition of starch. Drought stress significantly improved SS activity, but decreased SPS activity, while doubled CO_2 concentration significantly improved the activities of SS and SPS, and contents of sucrose and reducing sugar under drought stress. High nitrogen enhanced SS and SPS activities, and sucrose content.（3） Doubled CO_2 concentration significantly improved the activity of nitrate reductase（NR）, but not activities of glutamine synthetase（GS） and glutamate synthase（GOGAT）. Under doubled CO_2 concentration, high nitrogen remarkably improved NR and GOGAT activities, and alleviated the decline of GS activity.（4） The yield of cucumber under doubled CO_2 concentration, no drought stress, and high nitrogen was h

关 键 词：黄瓜 CO2浓度加倍 水氮耦合 碳氮代谢 

分 类 号：S642.2[农业科学—蔬菜学]