不同水分状况下追施氮肥对冬小麦产量及其构成因素的影响

通过盆栽试验研究了不同水分状况下追施氮肥对冬小麦产量及其构成因素的影响,结果表明,干旱胁迫条件下,氮肥早施比晚施好,低量氮肥比高量氮好,而且不同施氮处理对有效穗数和每穗粒数的影响差异达显著水平,但对千粒重无明显影响;水肥配合条件下,氮素的作用得到充分发挥,产量得到大幅度提高,而且对有效穗数,每穗粒数和千粒重都产生显著的影响,拔节期是冬小麦对水肥效应的关键期和亏缺敏感期,这个时期供水供肥可以显著提高产量,同时增加了穗粒数和千粒重。     

外源褪黑素对干旱胁迫下大豆结荚期光合及生理的影响

以"绥农26"为供试大豆品种,采用盆栽方式,研究外施100μmol·L~(-1)褪黑素对干旱胁迫下大豆结荚期光合及生理的影响。结果表明:与正常供水相比,随时间延长,干旱胁迫处理大豆植株生长受到抑制,结荚数量减少,并最终造成产量降低,光合作用和叶绿素荧光不断降低,抗氧化酶活性和渗透调节物质则呈先上升后下降趋势,而膜脂过氧化水平则不断升高;外源褪黑素提高了干旱胁迫下大豆结荚期地上部和地下部鲜干重、株高、叶面积和结荚数量并提高产量,缓解光合及叶绿素荧光下降,增加大豆叶片抗氧化酶(SOD、POD、CAT、APX)活性和渗透调节物质(可溶性糖、可溶性蛋白、脯氨酸)含量,调节膜脂过氧化平衡(MDA、H2O2和相对电导率);褪黑素处理提高了干旱胁迫下大豆叶片Pn、Tr、Gs,分别提高14.1%～30. 0%、7. 3%～19. 6%、12. 4%～20. 3%,Fv/Fo、Fv/Fm、ΦPSⅡ和ETR分别提高3.5%～15.5%、5.4%～9.4%、2.6%～5.9%、3.0～18.2%;褪黑素处理籽粒鲜重、籽粒干重、籽粒数量、结荚数量和株高较干旱胁迫处理分别提高37.5%～51.4%、35.2%～150.0%、23.4%～42.1%、6.6%～28.7%、2.6%～9.6%,褪黑素处理单株荚数、单株粒数、单株粒重和百粒重较干旱胁迫处理分别提高8.6%、7.1%、10.5%和6.5%。综上所述,外源褪黑素可以提高干旱胁迫条件下光合和抗氧化酶活性并能缓解生长抑制,增强了大豆抵御干旱的能力并提高其产量。     

棉花花铃期短期干旱下氮素对干物质及氮素累积分配的影响

通过盆栽试验进行水分(正常灌水和干旱后复水)和施氮处理(0、240、480kgN·hm-2),研究花铃期短期干旱再复水后氮素对棉花各器官干物质重、氮素累积与分配及产量与品质的影响.结果表明:花铃期土壤干旱显著降低了棉株各器官的干物质重与氮素累积量,而增大了棉株各器官的氮素含量,同时亦降低了棉株干物质与氮素在叶片中的分配指数,但提高了在根系的分配指数,从而增大了根冠比;增施氮肥可以提高干旱条件下棉株的干物质重与氮素累积量,但亦增大水分胁迫指数.复水对干旱处理棉株生长具有明显的补偿效应,尤其是根系的干物质重与氮素累积量显著高于相应正常灌水处理,且增施氮肥可以提高棉株的补偿效应.花铃期干旱结束时与复水后第10天,干旱处理棉株均以240kgN·hm-2水平下的生殖器官干物质重与分配指数最高,而根冠比最小,地上部与地下部生长最为协调,最终籽棉产量最高、纤维品质最优;而施氮不足(0kgN·hm-2)或过量(480kgN·hm-2)均不利于棉花产量的提高与纤维品质的改善.     

花后干旱或渍水逆境下氮素对小麦籽粒产量和品质的影响

 池栽试验条件下,设置渍水、干旱和对照3个水分处理,每个水分处理下设置两个施氮水平 ,研究了花后渍水或干旱逆境下氮素营养对两个不同类型小麦（Triticum aestivum） 品种籽粒产量和品质性状的影响。结果表明,与对照相比,花后渍水或干旱处理显著降低了小麦的千粒重、穗粒数和籽粒产量。在适宜水分和干旱条件下,增施氮肥增加了小麦籽粒产量,而在渍水条件下,增施氮肥降低了产量。干旱处理提高了蛋白质含量,干、湿面 筋含量,沉降值和降落值;而渍水处理则降低了小麦籽粒蛋白质含量和干、湿面筋含量。同 一水分处理下,增施氮肥提高了蛋白质含量,谷蛋白/醇溶蛋白比,支链淀粉含量和支/直链淀粉比。在小麦籽粒主要品质性状上存在显著的水氮互作效应,且水分、氮肥及水氮互作效 应对小麦籽粒产量和品质的影响因品种的不同而异。     

干旱胁迫对大豆生长的影响及抗旱性评价方法与指标筛选

2014-2015年在年降雨量不足40 mm的敦煌市,设干旱和正常灌水两个处理,通过测定12份大豆品种的8个形态指标(株高、主茎节数、有效分枝数、单株荚数、单株粒数、单株粒重、单株生物量和百粒重)及小区产量,采用改进抗旱指数法及权重隶属函数值D对其进行抗旱性评价,并筛选出3份不同抗旱类型的大豆品种进行生理指标测定,验证该方法和指标。结果显示,与灌水处理(CK)相比较,干旱胁迫下的8个形态指标及产量,2014年除有效分枝数及百粒重差异不显著外,其余考察性状均达到了极显著差异,2015年所有考察表型性状均达到极显著差异;两年权重隶属函数法评价结果显著相关,小区产量与两年两种评价方法极显著相关;两种处理下,中度抗旱(中黄24)、弱抗旱品种(WDD00172)的SOD活性、POD活性、CAT活性、丙二醛含量、可溶性糖含量差异极显著,且与权重隶属函数值D显著相关,而强抗旱品种(晋豆21号)中SOD活性、POD活性、脯氨酸含量差异不显著,且6个生理指标与权重隶属函数值D均不相关。因此,权重隶属函数法和小区产量可作为大豆抗旱性评价单一可靠的方法与指标。     

甘蔗—大豆间作对大豆鲜荚产量和农艺性状的影响

为探讨甘蔗-大豆间作模式对大豆鲜荚产量和农艺性状的影响,于2009—2011年连续3年在广州市华南农业大学农场进行大田试验,试验设置2种施氮水平(常规施氮(525kg·hm-2)和减量施氮(300kg·hm-2))和3种种植模式(甘蔗-大豆(1∶1)、甘蔗-大豆(1∶2)、单作大豆)。结果表明:甘蔗-大豆间作(1∶2)模式下,2009年减量施氮水平的大豆鲜荚产量较常规施氮水平提高了33%,2010和2011年不同施氮水平间均无显著差异;甘蔗-大豆间作模式对大豆的单株鲜荚重、多粒荚数和百粒鲜重无显著影响;大豆单株鲜荚重与多粒荚数在不同种植模式下均呈显著相关(P<0.05),在常规施氮间作模式下与大豆单株荚数呈显著相关(P<0.05)。甘蔗-大豆间作没有降低大豆的单株鲜荚产量,也没有对大豆的农艺性状产生负面影响,从增产增收、提高土地生产力来考虑,减量施氮模式下甘蔗-大豆间作具有一定的可行性。     

波浪冠层栽培模式对高油大豆产量品质及微环境生态因子的影响

2005～2006年,在菏泽市农科院试验田,以高油大豆品种鲁豆9为试验材料,研究波浪冠层栽培模式对大豆产量、产量构成因素、蛋白质、脂肪、脂肪酸组分以及微环境生态因子的影响.结果表明,与对照相比,波浪冠层群体增产253.65kg/hm2,增产11.76%;株高降低1.21cm,降低1.46%;在籽粒脂肪总量提高1.52%基础上,亚油酸含量提高1.60%,亚麻酸和硬脂酸含量分别降低0.14%和7.20%.波浪冠层各密度群体间株高和分枝数差异均达极显著水平,单株粒数和单株粒重差异均达显著水平,百粒重差异不显著.波浪冠层群体光照强度和CO2浓度分别增加67.68μmol · m-2 · s-1和8.31μmol · mol-1,分别增加5.06%和2.45%;湿度增加0.33mbar,增高4.47%;低温生育期时温度增加1.86℃,增加0.69%,高温生育期时温度平均降低0.17℃,降低0.51%.光照、温度、湿度和CO2等微环境生态因子的变化,更利于高油大豆产量的形成和品质的改善.     

花期渍水逆境下氮素对油菜产量及氮肥利用效率的影响

温室盆栽试验条件下,设置渍水和对照2个水分处理,每个水分处理下设置3个施氮水平(0.05、0.2、0.3 g N·kg^-1土),研究了花后渍水逆境下氮素营养对两个氮高效基因型‘Monty’、‘湘油15’和两个氮低效基因型‘R210’、‘Bin270’油菜产量、产量性能及氮肥利用效率的影响.结果表明:与对照相比,花后渍水处理显著降低了油菜的单株角果数、千粒重、每角粒数和籽粒产量.在适宜水分条件下,增施氮肥显著增加了油菜籽粒产量,而在渍水逆境处理下,增施氮肥对油菜籽粒产量的形成贡献不大.氮高效基因型较氮低效基因型对花后渍水逆境下的籽粒灌浆充实具有一定的促进作用.在同一水分处理下,花后渍水明显降低了油菜氮肥利用率、氮肥偏生产力、氮肥农学利用率、氮素吸收效率和氮收获指数,渍水显著影响了不同基因型油菜的氮素吸收利用能力,而氮高效基因型在渍水逆境下较氮低效基因型更有利于将氮素转运、再分配到角果中,提高籽粒生产效率.油菜产量性能参数存在显著的水氮互作效应,水分、氮肥及水氮互作对油菜籽粒产量和产量性能参数的影响因基因型的不同而异.     

干旱胁迫和正常灌溉条件下玉米产量性状的QTL分析

产量及其产量因子是衡量玉米耐旱能力的重要性状。本研究利用Lo1067×Y i72的F2∶3家系进行产量性状的数量性状位点(QTL)的分析。结果表明,在正常水分条件和开花期干旱胁迫条件下,分别有14个QTL与产量性状穗重、粒重、轴重、百粒重、穗数、穗粒数有关。此外,还检测到7个与抗旱指数(TI)相关的QTL。各QTL所解释的表型变异在1%~78%;这些QTL以部分显性和超显性为主。不同胁迫条件下检测到的QTL不一致,说明存在显著的QTL与环境互作。     

小麦花后水分亏缺和复水对同化物转运和籽粒灌浆的影响

为了阐明水分亏缺对小麦花后同化物转运和籽粒灌浆的影响及其生理机制的相关变化,以盆栽小麦旱作品种‘长旱58’为材料,自花后9 d起,设置正常供水(WW)、中度干旱胁迫后复水(MD)和重度干旱胁迫后复水 (SD)3个水分处理,比较干旱胁迫后复水处理对小麦籽粒产量、产量构成因素及水分利用效率、强弱势粒灌浆动态、旗叶光合性能、茎鞘非结构性碳水化合物(NSC)转运、籽粒形成关键酶活性变化等的影响。结果表明：(1)与WW相比,MD处理显著增加了小麦穗粒数和千粒重,进而提高籽粒产量、水分利用效率和小麦弱势粒的最大灌浆速率和平均灌浆速率,对强势粒则无显著影响,而SD处理则显著降低了穗粒数、千粒重、强弱势粒的最大灌浆速率和平均灌浆速率,但水分利用效率显著高于WW处理。(2)MD处理植株旗叶在小麦灌浆过程中维持了与WW基本相同的净光合速率,同时在小麦花后9~20 d时MD处理下气孔导度和蒸腾速率变化不明显,而在SD处理下气孔导度和蒸腾速率则急剧下降;另外,与WW相比,在整个灌浆期MD处理下旗叶叶绿素含量变化不显著,而SD处理下叶绿素含量呈大幅下降趋势。(3)MD处理提高了小麦弱势粒蔗糖合成酶和腺苷二磷酸葡萄糖焦磷酸化酶活性;同时使灌浆中后期有较高的果聚糖水解酶(FEH)活性和较低果聚糖含量,显著增强了茎鞘同化物质转运,提高茎鞘储藏物质对粒重的贡献率。研究发现,中度水分胁迫后复水处理小麦植株具有较好的叶片性能、花后较多的茎鞘同化物向籽粒转运以及较高的弱势粒库活性,从而提高旱作小麦弱势粒灌浆速率,增加穗粒数和粒重, 进而提高籽粒产量。     

Comparing the Effects of Rust on Plot Yield, Plant Yield, Yield Components, and Vegetative Parts of Soybean

To determine the plant variable for coupling a disease model to a soybean growth model, effects of soybean rust (caused by Phakopsora pachyrhizi) on soybean were quantified at four levels: vegetative parts, yield components, plant yield, and plot yield. Path analysis was conducted to determine the most correlated components to disease in each level. The responses of vegetative parts, such as shoot weight and branches/plant, to disease effects were inconsistent among cultivars. Yield components responded consistently to disease effects among the cultivars, indicated by the high values of correlation coefficients between disease and the components. Path coefficients indicated that reduction of 100-seed weight was the most important cause of yield loss in this level. No significant within-plant compensation was detected using path coefficient analysis except for that between pod length to pod width. The most consistent response to disease effect was at population level. Correlation of disease to plant yield was as significant as these to plot yield. Correlations between disease and these plant levels were in the order of plot yield, plant yield, yield components, and vegetative parts. Regression between plot yield and green leaf area duration (GLAD) from flowering to seed full size was highly significant (P < 0,001). This study suggests that green leaf area at population level was the best variable for coupling disease model to crop model.     

群体分布对夏大豆产量和水分利用效率的影响

在田间试验条件下研究了群体不同分布对夏大豆产量构成和水分利用的影响.夏大豆‘鲁豆4号'(Glycine max cv. Ludou 4)在同一群体密度(3.09×10~5株/hm~2)下设5种分布方式,即行距×株距分别为A:18 cm×18 cm,B:27 cm×12 cm,C:36 cm×9 cm,D:45 cm×7.2 cm,E:54 cm×6cm.结果表明,群体分布影响夏大豆的产量、叶片水分特征和水分利用效率(WUE).A、B处理的产量显著高于D、E处理(P<0.05),其他处理间均无显著差异;随着行距加大,单株有效荚数、粒数及百粒重呈下降趋势;叶片相对含水量(RWC)、水势(Ψw)和渗透势(Ψs)随生育进程的推进呈整体下降趋势,其中,A、B处理RWC、Ψw 和Ψs的平均值均显著高于D、E处理,E处理的Ψw在日变化的正午阶段明显低于其他处理;WUE与行距呈负相关(R=-0.935~*),与产量呈正相关(R=0.997~(**)),其中,A、B处理的WUE显著高于其他处理(P<0.05),D、E处理极显著低于B处理(P<0.01).夏大豆植株相对均匀分布的处理可改善产量构成因素及叶片水分状况,进而形成较高的产量,提高水分利用效率.     

Effects of Drought Stress on Key Enzymes of Carbon Metabolism,Photosynthetic Characteristics and Agronomic Traits of Soybean at the Flowering Stage under Different Soil Substrates

Soybean is an important legume food crop, and its seeds are rich in nutrients, providing humans and animals with edible oil and protein feed. However, soybean is sensitive to water requirements, and drought is an important factor limiting soybean yield and quality. This study used Heinong 84 (drought resistant variety) and Hefeng 46 (intermediate variety) as tested varieties planted in chernozem, albic, and black soils. The effects of drought stress on the activities of key enzymes in carbon metabolism and photosynthetic characteristics of soybean were studied during the flowering stage, most sensitive to water. (1) The activities of SS-1, 6PGDH, and G6PDH enzymes in soybean leaves first increased and then decreased under drought stress. The enzyme activity was the highest under moderate drought stress and weakest in the blank group. (2) Drought stress increased Phi2, PhiNO, and Fm in soybean leaves and reached the highest value under severe drought; with the increase in drought stress, PhiNPQ and Fv/Fm of soybean leaves gradually decreased, reaching the lowest under severe drought. (3) With the increase in drought stress, F₀ and Fs of soybean leaves showed a single peak curve, and the maximum was at moderate drought. (4) Correlation analysis showed that F₀ was greatly affected by varieties and soil types; Fs, F0, and Fm soil varieties had a great influence, and chlorophyll fluorescence parameters were affected differently under drought stress with different drought degrees. (5) Drought stress changed the agronomic traits and yield of soybean. With the increase of drought degree, plant height, node number of main stem, effective pod number, 100-seed weight and total yield decreased continuously. (6) Drought stress affected the dry matter accumulation of soybean. With the increase of drought degree, the dry matter accumulation gradually decreased. Among them, the leaf was most seriously affected by drought, and SD decreased by about 55% compared with CK. Under the condition of black soil, the dry matter accumulation of soybean was least affected by drought.     

不同结荚习性夏大豆种质的农艺表现及其与产量的相关分析

以533份不同结荚习性大豆种质为试验材料,研究了不同结荚习性大豆种质在黄淮夏播生态区的农艺性状表现,并对主要农艺性状和产量的相关性进行了分析。结果表明:大豆种质的营养期、株高、有效分枝、单株荚数、倒伏性、株型等性状的平均值随无限-亚有限-有限结荚习性递减,生殖期、单株粒重、百粒重、小区产量等性状平均值的变化趋势则相反。相关分析表明,无限结荚习性种质的产量与株高、单株粒重呈极显著正相关,偏相关系数分别为0.602**、0.566**,与有效分枝、倒伏性呈显著负相关,偏相关系数分别为-0.384*、-0.451*。亚有限结荚习性种质的产量与生殖期、单株粒重呈显著、极显著正相关,偏相关系数分别为0.156*、0.536*,与有效分枝呈极显著负相关,偏相关系数为-0.323**。有限结荚习性种质的产量与单株粒重、株高呈极显著正相关,偏相关系数分别为0.433**、0.262**,与株型、单株荚数呈显著、极显著负相关,偏相关系数分别为-0.149*、-0.198**。结合不同结荚习性品种的生长特点,本研究认为,无限结荚习性品种株高较高且株高与产量呈极显著正相关,适合干旱地区种植;亚有限结荚习性品种生殖期与产量呈正相关,生殖期内生长旺盛需要较多的养分供应;有限结荚习性品种的营养生长持续时间短,株高较矮,吸收光能有限,实现高产主要依赖各性状器官间的平衡。生产中,有限结荚习性品种的营养生长期间既需要充足的肥水促其生长,又要防止旺长。     

A study on soybean responses to drought stress and rehydration

To investigate soybean responses to drought stress and growth through metabolism compensation after rehydration, and for the establishment of an optimal water-saving irrigation model, we used the soybean variety Suinong 14 as experimental material and adopted a weighing method for water control in potted plants. We exposed soybean plants to stress treatments at different growth stages using different stress levels and durations. We then studied the effects of drought stress and rehydration on soybean growth and development, osmoregulation, and endogenous hormonal regulations, as well as antioxidant systems. The results showed that drought stress inhibited increases in the soybean plant height and leaf area. This inhibition became more significant as the level, duration, and frequency of the drought stress increased. After rehydration, the soybean plant heights and leaf areas exhibited rapid increases and partial compensation for their decreased sizes. As the level, duration, and frequency of drought stress increased, the compensation effect decreased, but it did not return to the control level. Drought stress reduced the chlorophyll content and relative water content in the soybean leaves and increased the osmolyte contents, antioxidant potential, and peroxidation of the membrane lipids. In addition, the changes mentioned above became more dramatic as the drought stress level, duration, and frequency increased. Upon rehydration, various levels of growth compensation were observed in each physio-biochemical parameter. As the drought stress level, duration, and frequency increased, the compensation effect also increased. Overall, the compensation effect for drought stress that occurred at the early growth stages was higher than that at the later growth stages. Drought stress led to decreases in the ZR/IAA and ZR/ABA ratios in soybean leaves and an increase in the ABA/(IAA + GA + ZR) ratio; thus, the plant growth was inhibited. These hormone ratios exhibited more dramatic changes when the drought stress level became more severe and the stress duration was prolonged. After rehydration, these hormone ratios produced equal compensation effects. Therefore, the compensatory effect of rewatering after drought stress is conditional. Severe stress, especially long-term severe stress, will reduce the compensatory effect. At the same time, drought resistance treatment at seedling stage can improve the adaptability and compensatory effect of re-drought at grain filling stage.     

Foliar application of zinc improves morpho-physiological and antioxidant defense mechanisms,and agronomic grain biofortification of wheat (Triticum aestivum L.) under water stress

Agronomic biofortification with zinc (Zn) may be engaged to improve the nutritious value of food crops along-with tolerance to water deficit conditions. The Zn may increase plant resistance to water stress by boosting physiological and enzymatic antioxidants defense mechanisms. Major objective of this study was to investigate the effect of foliar applied Zn on grain zin biofortification and drought tolerance in wheat. Treatments include application of Zinc at terminal growth phases (BBCH growth stage 49 and BBCH growth stage 65) with five levels: 0 (control-ck), water spray, 5, 10 and 15 mM under two levels of water regimes; well-watered (where 80% water holding capacity (WHC) was maintained in the soil) and water stress, (where 40% WHC was maintained in the soil). Results revealed that water stress significantly reduced relative water contents, gas exchange attributes, plant height, yield and yield related attributes of wheat. In contrast, hydrogen peroxide, free proline levels, activities of malondialdehyde, and concentration of soluble protein were markedly increased under water stress condition. Application of various levels of Zn significantly improved the CAT, SOD, POD and ASP activities at 40% WHC compared with control treatment. Foliarly applied 10 and 15 mM Zn predominantly reduced the damaging impact of water stress by improving the plant status in the form of plant height, RWC and gas exchange attributes. Likewise, wheat plant treated with 10 mM Zn under water stress condition increased the grain yield by improving number of grains per spike, 100 grain weight and biological yield compared with control. Moreover, increasing Zn levels also increased Zn concentration in grains and leaves. Overall, this study suggests that optimum level of Zn (10 mM) might be promising for alleviating the adverse impacts of water stress and enhance the grain biofortification in wheat.     

Effects of water shortage on the yield of winter wheat

The effects of water shortage on the yield of winter wheat (cv. Maris Huntsman) were investigated in covered field plots on silt-loam soil. Plants were subjected to drought at different stages of growth, but none of the treatments significantly decreased yield. Some treatments decreased the number of ears per unit area, and number of grains per ear, but these effects were offset by increases in individual grain weight. We estimate that the soil water deficit (151 mm) in the treatment which had the largest effect on yield, albeit non-significant, would be expected in nature about 15 years in 100 or less. Drought also had little effect on plant water potential and stomatal conductance. The lack of effect of drought on plant water status and yield may be attributable to the large available water content of the silt loam and the deep rooting of winter wheat. On this type of soil, therefore, water shortage appears not to be an important cause of variation in the yield of winter wheat.     

大豆滞绿(stay-green)突变体诱变后代表型性状变异分析

本文利用大豆滞绿突变体Z-94320经60Co-γ射线诱变的突变体后代M5、M6代为材料,进行两年的田间性状观察记录统计,用相关性分析、主成分分析、聚类分析对其17个主要表型性状统计分析。结果表明:诱变后代产生了丰富的变异,出现了多种种皮色和子叶色,产生了非滞绿性状,形成了各种生育周期,且分离出晚熟性状。通过相关性分析发现,单株粒重与株重、茎粗、主茎荚数、分枝荚数、一粒荚数、二粒荚数、三粒荚数、瘪粒荚数、虫食数呈极显著正相关,这些性状可以对产量进行预测;主成分分析在M5代提取出“产量因子”、“株型因子”、“粒荚因子”、“茎荚因子”四个主成分,对农艺性状累计贡献率达到70.50%,M6代提取出“产量因子”、“虫害因子”、“株型因子”、“茎杆因子”四个主成分,对农艺性状累计贡献率达到71.54%;聚类分析将M5、M6代材料分别划分为6类,发现同代中各类群农艺性状情况大致相似,但是各农艺性状在两代之间的变化明显,在株重、结荚高度、单株粒重等方面M6代显著高于M5代,并筛选出两株高产品系和一株特色滞绿品系。本研究逐步完善了对滞绿大豆突变体库的构建,为滞绿大豆诱变后代的遗传多样性研究提供了基础的数据分析。