作 者 :郭天财;宋晓;马冬云;王永华;谢迎新;查菲娜;岳艳军;岳彩凤
期 刊 :作物学报 2007年 33卷 12期 页码:1977-1981
Keywords:Winter wheat, Photosynthetic characteristics, Nitrogen effect, Yield,
摘 要 :在大田试验条件下,对大穗型小麦品种兰考矮早八旗叶光合特性及氮素调控效应进行了研究。结果表明,旗叶叶绿素含量随籽粒灌浆进程呈逐渐降低的趋势。PSⅡ潜在活性、PSⅡ光化学的最大效率、荧光光化学猝灭系数等随生育进程呈先升高后降低的变化趋势,且均在开花期达到最大值,之后逐渐下降;荧光非光化学猝灭系数则在成熟期达到最大值。氮肥对旗叶光合特性有一定的调控效应,Chl,Fv/Fo,Fv/Fm及qP均随施氮水平的增加呈增加的趋势,其中Chl和Fv/Fo以N3(180 kg hm-2)处理最大,Fv/Fm和qP(除孕穗期外)以N4(360 kg hm-2)处理最大;qN则随施氮水平增加呈降低的趋势,以N4处理最小。适宜的施氮量(180 kg hm-2)改善了兰考矮早八的光合色素性状,提高PSⅡ潜在活性及PSⅡ光化学的最大效率,减少荧光非光化学猝灭系数,从而有助于籽粒产量的提高。
Abstract:Nitrogen nutrient influences crop growth and grain yield through its direct effects on chlorophyll, rubisco, and photosynthetic structure. Many researches have focused on photosynthetic rate and dark reaction in winter wheat (Triticum aestivum L.) and explained in details the photosynthetic physiology of the flag leaf and canopy in late growing stages. In the present field experiment, a large-spike wheat cultivar, Lankaoaizao 8, was used for photoreaction study, which was seldom mentioned in former reports. Four nitrogen application rates with 0 (N1), 90 (N2), 180 (N3), and 360 kg N ha-1 (N4) were respectively arranged in a randomized block design with three replicates. In each plot (3 m´5 m), half of the nitrogen fertilizer was applied before sowing, and the other half was topdressed at jointing stage. Additional P2O5 (150 kg ha-1) and K2O (150 kg ha-1) were supplied as basal fertilizer. Since the 5th day after anthesis, flag leaves on ten stems from each plot were sampled every five days to determinate contents both of Chl and Car. Six fluorescence dynamic parameters of the flag leaf, fluorescence maximum (Fm), fluorescence origin (Fo), PSⅡ potential activity (Fv/Fo), the maximal quantum efficiency of PSⅡ photochemistry (Fv/Fm), photochemical quenching coefficient (qp), and non-photochemical quenching coefficient (qN), were measured at booting, flowering, early filling, and harvest stages, respectively. Content of Chl (a+b) decreased gradually with the process of grain filling in N1 treatment (control), but increased (P<0.01) at 5–15 days after anthesis (DAA), then decreased (P<0.01) in all three nitrogen treatments, and reached the peak in N3 treatment. Content of Car in the control decreased sharply at 20–30 DAA, and obtained the maximum value in N3 treatment. These results indicated that nitrogen application could avail photosynthetic pigments and delay leaf senescence. Fv/Fo, Fv/Fm, and qP in both control and nitrogen treatments reached their peaks at flowering stage, but most of them in nitrogen treatments were significantly (P<0.05) higher than those in control at the same growing stage. The qN showed a ascending trend from booting to harvest stages with its peak appearing at harvest stage in all the treatments. Compared with the control (N1), the N3 and N4 treatments showed the biggest effects on Fv/Fo and Fv/Fm, qP, and qN, respectively. It is suggested that proper nitrogen application rate (180 kg ha-1) may promote grain yield by enhancing photosynthetic pigment contents, PSⅡ potential activity, and the maximal quantum efficiency of PSⅡ photochemistry, as well as reducing non-photochemical quenching coefficient.
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