邵在胜, 赵轶鹏, 宋琪玲, 贾一磊, 王云霞, 杨连新, 王余龙. 大气CO2和O3浓度升高对水稻'汕优63'叶片光合作用的影响[J]. 中国生态农业学报(中英文), 2014, 22(4): 422-429. DOI: 10.3724/SP.J.1011.2014.31083
引用本文: 邵在胜, 赵轶鹏, 宋琪玲, 贾一磊, 王云霞, 杨连新, 王余龙. 大气CO2和O3浓度升高对水稻'汕优63'叶片光合作用的影响[J]. 中国生态农业学报(中英文), 2014, 22(4): 422-429. DOI: 10.3724/SP.J.1011.2014.31083
SHAO Zaisheng, ZHAO Yipeng, SONG Qiling, JIA Yilei, WANG Yunxia, YANG Lianxin, WANG Yulong. Impact of elevated atmospheric carbon dioxide and ozone concentrations on leaf photosynthesis of 'Shanyou 63' hybrid rice[J]. Chinese Journal of Eco-Agriculture, 2014, 22(4): 422-429. DOI: 10.3724/SP.J.1011.2014.31083
Citation: SHAO Zaisheng, ZHAO Yipeng, SONG Qiling, JIA Yilei, WANG Yunxia, YANG Lianxin, WANG Yulong. Impact of elevated atmospheric carbon dioxide and ozone concentrations on leaf photosynthesis of 'Shanyou 63' hybrid rice[J]. Chinese Journal of Eco-Agriculture, 2014, 22(4): 422-429. DOI: 10.3724/SP.J.1011.2014.31083

大气CO2和O3浓度升高对水稻'汕优63'叶片光合作用的影响

Impact of elevated atmospheric carbon dioxide and ozone concentrations on leaf photosynthesis of 'Shanyou 63' hybrid rice

  • 摘要: 大气CO2浓度升高使水稻光合作用增强, 而地表O3浓度增加则相反, 但人们对大气CO2和O3浓度同时升高情景下水稻光合作用的响应和适应知之甚少。本文利用新型的自然光气体熏蒸平台, 以杂交籼稻'汕优63'为供试材料, 设置室内对照(CK, 大气本底浓度, 实时模拟室外环境)、高浓度CO2(CO2本底浓度+200 μmol·mol-1)、高浓度O3(O3本底浓度的1.6 倍)、高浓度CO2+O3 4个处理, 于拔节期、抽穗期和灌浆期测定稻叶的主要光合参数。整个布气期间, CO2和O3浓度平均的控制目标完成比(TAR)分别为1.04和1.00。与CK相比, CO2处理使拔节、抽穗和灌浆期净光合速率(Pn)分别增加15%、11%和28%, O3处理使对应生育期Pn分别降低32%、32%和88%, CO2+O3处理对拔节期和抽穗期Pn无显著影响, 但成熟期Pn平均下降48%。CO2处理使拔节和抽穗期叶片气孔导度(Gs)和蒸腾速率(Tr)显著下降, 但灌浆期无显著变化; O3处理对各期GsTr的影响明显大于CO2处理, 且以灌浆期的降幅最大; CO2+O3处理叶片GsTr的降幅总体上明显低于单独的O3处理。CO2处理或CO2+O3处理叶片胞间CO2浓度(Ci)明显增加, 而O3处理叶片Ci的变化相对较小。CO2处理使各期水分利用效率(WUE)增加, 而O3处理则呈相反趋势, 特别是生长后期。CO2+O3处理叶片拔节期和抽穗期WUE平均增加约15%, 但灌浆期因O3的累积伤害, WUE不升反降。以上结果表明, 大气CO2浓度升高将使杂交稻'汕优63'叶片光合能力增强, 但地表同步升高的O3浓度则使光合能力削弱并表现出明显的累积伤害, 大气CO2和O3浓度同时升高可缓解O3胁迫对'汕优63'光合作用的负效应。

     

    Abstract: Elevated atmospheric carbon dioxide (CO2) concentration increases plant photosynthesis while elevated tropospheric ozone (O3) concentration could have the opposite effect. The interactive effects of the two gaseous processes have remained largely unclear. By using a new sola-illuminated gas fumigation platform, an Indica hybrid rice cultivar 'Shanyou 63' was exposed to these gases in four gas treatments. The treatments included the control (real time ambient CO2/O3 condition), elevated CO2 (CO2) (200 μmol·mol-1 above ambient CO2), elevated O3 (O3) (60% higher than ambient value) and combined elevated CO2+O3 (CO2+O3). Photosynthesis of rice grown in the chambers was determined at jointing stage, heading stage and filling stage, respectively. Over the growing season, the target achievement ratios of CO2 and O3 concentrations were 1.04, 1.00, respectively. Compared with the control, CO2 increased net photosynthetic rate (Pn) of rice by 15%, 11% and 28% at jointing, heading and grain-filling stages, respectively. However, O3 decreased Pn by 32%, 32% and 88% at the respective growth stages. Compared with the control, leaf Pn was not altered by the CO2+O3 treatment at jointing and heading stages, but was 48% lower during grain-filling stage. CO2 significantly decreased stomatal conductance (Gs) and transpiration rate (Tr) at jointing and heading stages, but the two variables remained unaffected at grain-filling stage. The magnitude of O3 effect on Gs and Tr was larger than that of CO2, with the highest effect of O3 detected during grain filling. The effects of CO2+O3 treatment on Gs and Tr were generally smaller than those of individual O3 treatment. Compared with the control, intercellular CO2 concentration (Ci) in rice substantially increased with CO2 or CO2+O3 treatment while limited response of Ci was observed in individual O3 treatments. Leaf water use efficiency (WUE) increased with CO2 treatment, while reverse trend was noted under O3, especially during filling stage. CO2+O3 increased leaf WUE by about 15% at jointing and heading stages, while the reverse trend was noted in the late season, due mainly to cumulative O3 damage. The above findings suggested that the projected rise of atmospheric CO2 level increased the photosynthetic capacity, while the elevated tropospheric O3 concentration decreased it at a progressive severity over the growing season. The concurrent increases in CO2 and O3 ameliorated the severity of deleterious effects of O3 on leaf photosynthesis of 'Shanyou 63'.

     

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