花后盐与渍水逆境对小麦籽粒产量及蛋白质和淀粉积累的影响

采用盆栽试验,研究了花后渍水、盐胁迫和盐渍处理对2个小麦品种（扬麦12和淮麦17）籽粒产量及蛋白质和淀粉积累与组分的影响.结果表明：与对照相比,花后渍水、盐胁迫和盐渍处理显著降低了小麦花前贮藏氮素（花前贮藏干物质）转运量和花后同化氮素（花后同化物）输入籽粒量,从而导致小麦籽粒产量、蛋白质和淀粉产量显著降低,其中盐胁迫和盐渍处理表现更为明显.与对照和渍水处理相比,盐胁迫和盐渍处理显著降低了小麦籽粒蛋白质积累量及谷/醇蛋白比,显著提高了蛋白质组分含量;同时降低了小麦籽粒淀粉积累量、淀粉组分含量及直/支链淀粉比;盐胁迫处理对扬麦12的影响较盐渍处理明显,而盐渍处理对淮麦17的影响较盐胁迫处理明显.渍水条件下小麦籽粒蛋白质和淀粉积累量均下降,除淮麦17谷蛋白和清蛋白含量有所提高外,淮麦17其他蛋白组分含量和扬麦12各蛋白组分含量均下降.     

花后干旱和渍水对不同品质类型小麦籽粒品质形成的影响

 防雨池栽条件下研究了花后干旱和渍水胁迫对两个不同品质类型小麦（Triticum aestivum）品种籽粒产量和品质形成的影响。结果表明,花后渍水和干旱处理明显降低了小麦籽粒产量和蛋白质产量。在整个灌浆期内干旱处理明显提高了籽粒蛋白质和醇溶蛋白含量,而渍水处理降低了籽粒蛋白质及其组分的积累量。籽粒总淀粉和直链淀粉含量以渍水处理最高,而支链淀粉以对照最高。干旱处理提高了籽粒干、湿面筋含量、沉降值和降落值,而渍水处理降低了上述品质指标。试验表明干旱和渍水胁迫对小麦籽粒蛋白质与淀粉的含量和组分及面粉品质等均有不同程度的影响,从而改变了不同品质类型小麦的籽粒品质。     

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。     

花后干旱或渍水下氮素供应对小麦光合和籽粒淀粉积累的影响

防雨池栽条件下,设置渍水、干旱和对照3个土壤水分处理,每水分处理下再设置两个施氮水平,研究了花后渍水和干旱逆境下氮素水平对两个蛋白质含量不同的小麦品种光合特性和籽粒淀粉积累的影响.结果表明,与对照相比,花后渍水和干旱处理显著降低小麦旗叶净光合速率和SPAD值,干物质积累量下降.干旱处理下,增施氮肥提高旗叶光合速率和SPAD值,渍水处理下则相反.水分逆境明显降低籽粒可溶性总糖含量,且渍水处理下增施氮肥降低小麦叶片和籽粒可溶性总糖含量,干旱状态下规律相反.渍水处理下增施氮肥降低淀粉积累速率.水分逆境明显降低小麦粒重、产量和淀粉产量,且干旱处理下增施氮肥有利于籽粒重、产量和淀粉产量的提高,而渍水下增施氮肥使粒重和产量进一步降低.试验结果表明,花后渍水和干旱逆境下施用氮肥对小麦旗叶光合速率和籽粒淀粉积累有明显的调节效应.     

遮光对小麦籽粒淀粉品质和花前贮存非结构碳水化合物转运的影响

以耐荫品种扬麦158和不耐荫品种扬麦11两个小麦品种为材料,研究了拔节至成熟期遮光对小麦籽粒产量、淀粉含量和淀粉糊化特性的影响,并分析了花前营养器官非结构碳水化合物转运及其与籽粒产量、淀粉含量和淀粉糊化特性的关系.结果表明：遮光条件下小麦花前营养器官中可溶性总糖转运量的下降是造成小麦籽粒产量降低的原因之一;小麦支链淀粉在遮光条件下显著降低而直链淀粉变化不明显,导致小麦籽粒总淀粉含量和支／直显著下降;遮光降低了两品种小麦籽粒淀粉峰值粘度;降低了不耐荫品种扬麦11的低谷粘度,提高了其糊化温度,但对耐荫品种扬麦158的低谷粘度和糊化温度无显著影响.     

氮肥基追比与灌浆中期高温胁迫对小麦产量和品质的影响

以优质强筋小麦品种‘济麦20’为供试材料,研究了不同氮肥基追比（基肥：追肥为1：1、1：2、1：5）和灌浆中期高温胁迫对小麦籽粒产量和品质的影响.结果显示,灌浆中期高温胁迫处理能显著降低小麦千粒重、籽粒产量以及籽粒的淀粉含量、支链淀粉含量、支链淀粉/直链淀粉比例,峰值粘度、稀懈值、最终粘度也相应降低,而籽粒蛋白质含量相应提高,导致淀粉品质变劣而面团的流变学特性得以改善;在基追比例1：1的基础上增大拔节期氮素追施比例,能显著提高小麦常温和高温胁迫下籽粒产量,缓解高温胁迫对小麦千粒重和籽粒产量的不良影响,而对小麦籽粒面团流变学特性及面粉的粘度指标影响甚微.研究表明,适当提高拔节期氮肥追施比例可有效减缓灌浆中期高温胁迫对小麦产量的负面影响,但对小麦籽粒品质影响较小.     

高温下干旱和渍水对冬小麦花后旗叶光合特性和物质转运的影响

以蛋白质含量不同的两个冬小麦品种扬麦9号和豫麦34为材料,研究了不同温度和水分条件下小麦花后旗叶光合特性的变化、营养器官花前贮藏干物质和氮素转运特征及其与籽粒产量和品质形成的关系.结果表明,高温及干旱和渍水均明显降低了旗叶光合速率和叶绿素含量（SPAD值）,但高温下干旱和渍水对光合作用的影响加重.小麦营养器官花前贮藏干物质、氮素转运量和转运率在适温下表现为干旱>对照>渍水,高温下则表现为对照>干旱>渍水.适温下花后同化物积累量表现为对照>渍水>干旱,高温下则表现为对照>干旱>渍水.花后氮素积累量在适温和高温下均表现为对照>渍水>干旱.籽粒淀粉含量以适温适宜水分处理最高,高温渍水下最低;蛋白质含量以高温干旱下最高,适温渍水下最低.温度和水分逆境下小麦粒质量和淀粉含量的降低与花后较低的光合能力及干物质积累有关,而蛋白质含量则与花前贮藏氮素的转运量和转运率有关.     

氮素营养水平对冬小麦碳氮运转的影响

在大田试验条件下,研究了不同施氮水平对2种穗型冬小麦品种花后干物质和氮素积累与运转的影响及其与产量和品质的关系,以探讨氮素营养水平对冬小麦碳氮运转的影响.结果显示,适宜的施氮量（180 kg·hm^-2）能够极显著增加2种穗型冬小麦品种叶片、茎鞘等营养器官花前贮藏物质及花前贮藏氮素的再运转量和运转率以及总再运转量和运转率,也能够极显著增加成熟期籽粒氮素含量和花前贮藏氮素总运转量对籽粒氮素含量的贡献率.各施氮处理对2种穗型小麦品种花后氮素积累量对籽粒氮素含量贡献率的影响效应不明显.结果表明,适宜的施氮量有利于小麦籽粒和蛋白质产量的提高.     

灌浆期高温和水分逆境对冬小麦籽粒蛋白质和淀粉含量的影响

灌浆期高温和水分逆境是影响小麦籽粒产量和品质的关键气候因子。以扬麦9号、徐州26和豫麦34三个小麦品种为材料,利用人工气候室模拟灌浆期高温和水分胁迫环境,研究了花后高温及温度和水分互作对小麦籽粒蛋白质和淀粉形成的影响。结果表明,高温显著提高了小麦籽粒蛋白质含量及清蛋白、球蛋白和醇溶蛋白含量,但降低了谷蛋白含量,导致麦谷蛋白／醇溶蛋白比值降低。高温显著降低了籽粒总淀粉和支链淀粉含量及支／直比。籽粒蛋白质和淀粉及其组分形成所需的适宜昼夜温差随小麦品质类型而异,但温度水平对籽粒蛋白质和淀粉的影响较温差大。在高温和水分逆境下,温度对籽粒蛋白质和淀粉含量的影响较水分逆境大,且存在显著的互作效应。小麦籽粒蛋白质含量均表现为干旱〉对照〉渍水,以高温干旱最高,适温渍水最低;淀粉含量为对照〉干旱〉渍水,以适温对照最高,而高温渍水最低。高温和水分逆境显著提高了籽粒醇溶蛋白含量而降低了谷蛋白含量及支链淀粉含量,使蛋白质谷／醇比和淀粉支／直比降低,以高温渍水对籽粒蛋白质和淀粉组分的影响最为显著。不同品种之间,高蛋白小麦籽粒蛋白质和组分的形成受高温和水分逆境的影响更大,而低蛋白品种籽粒淀粉形成显著受温度和水分逆境的调节。分析表明,在高温和水分逆境下籽粒蛋白质含量与清蛋白和醇溶蛋白显著正相关,籽粒淀粉含量与谷蛋白、支链淀粉含量及支／直比显著正相关。     

遮光对小麦植株氮素转运及品质的影响

以耐弱光性不同的冬小麦品种扬麦158(耐弱光品种)和扬麦11(不耐弱光品种)为材料,研究了拔节至成熟期遮光对小麦籽粒产量、植株氮素代谢及籽粒和面团品质的影响.结果表明:拔节至成熟期遮光22%和33%时,扬麦158和扬麦11籽粒产量分别比对照下降4.1%～9.9%和15.3%～25.8%;而小麦籽粒蛋白质产量分别下降3.0%～8.3%和10.4%～14.1%,且随着遮光程度的加重,小麦籽粒氮素积累对花后氮素积累的依赖性增强.遮光条件下各营养器官中花前贮存氮素转运量均下降,但叶片氮素转运效率(RENP)上升,从而补偿了茎鞘、穗壳中RENP的下降,因此营养器官总RENP未受遮光条件的显著影响.拔节至成熟期遮光提高了小麦籽粒蛋白质含量,这与弱光下籽粒蛋白质积累量下降幅度小于产量下降幅度所形成的"浓缩效应"有关.弱光对成熟期小麦籽粒清蛋白和球蛋白含量无显著影响,但显著提高了醇溶蛋白和麦谷蛋白含量,导致小麦湿面筋含量、面团形成时间和稳定时间提高,面团弱化度降低.     

播期播量对旱地小麦土壤水分消耗和植株氮素运转的影响

为解决旱地小麦等雨播种的生产现状,明确播量对土壤水分利用和产量形成的调控机制,于2015—2017年在山西闻喜试验基地开展大田试验,以早播(9月20日,EB)、晚播(10月10日,LB)两个播期为主区,以低密度(67.5 kg·hm^-2,LD)、中密度 (90 kg·hm^-2,MD)、高密度(112.5 kg·hm^-2,HD)3个播量为副区,研究播期播量对旱地小麦土壤水分消耗和植株氮素运转的影响.结果表明: 早播较晚播生育期土壤总耗水量增加11～22 mm;随播种密度的增加,生育期土壤总耗水量增加2～20 mm,且早播条件下,花前土壤耗水量增加,晚播条件下,花后土壤耗水量显著增加.早播较晚播在低、中密度条件下花前氮素运转量、花后氮素积累量增加,高密度条件下降低.早播条件下,花前氮素运转量,茎秆+叶鞘、穗轴+颖壳花前氮素运转量对籽粒的贡献率以及花后氮素积累量均以低密度条件下最高;晚播条件下,花前氮素运转量和花后氮素积累量随播种密度增加而增加.早播较晚播产量显著提高163～996 kg·hm^-2,提高幅度达5%～26%,水分利用效率提高幅度达2%～21%,氮素吸收效率提高幅度达3%～36%,氮素收获指数提高幅度最高达11%.早播条件下产量、水分利用效率、氮素吸收效率、氮素收获指数以低密度条件下最高;晚播条件下以高密度条件下最高.此外,花前氮素运转量与花前100～200 cm土壤耗水量显著相关,尤其是茎秆+叶鞘、穗轴+颖壳;花后植株氮素积累量与花后100～300 cm土壤耗水量呈显著相关.总之,旱地小麦9月20日配套播量67.5 kg·hm^-2、10月10日配套播量112.5 kg·hm^-2有利于增产增效.     

Relationship between Carbon Isotope Discrimination and Grain Yield in Spring Wheat Cultivated under Different Water Regimes

In C3 plants, carbon isotope discrimination (△) has been proposed as an indirect selection criterion for grain yield. Reported correlations between △ and grain yield however, differ highly according to the analyzed organ or tissue, the stage of sampling, and the environment and water regime. In a first experiment carried out in spring wheat during two consecutive seasons in the dry conditions of northwest Mexico (Ciudad Obregon, Sonora), different water treatments were applied,corresponding to the main water regimes available to spring wheat worldwide, and the relationships between △ values of different organs and grain yield were examined. Under terminal (post-anthesis) water stress, grain yield was positively associated with △ in grain at maturity and in leaf at anthesis, confirming results previously obtained under Mediterranean environments. Under early (pre-anthesis) water stress and residual moisture stress, the association between grain △ and yield was weaker and highly depended on the quantity of water stored in the soil at sowing. No correlation was found between △ and grain yield under optimal irrigation. The relationship between △ and grain yield was also studied during two consecutive seasons in 20 bread wheat cultivars in the Ningxia region (Northern China), characterized by winter drought(pre-anthesis water stress). Wheat was grown under rainfed conditions in two locations (Guyuan and Pengyang) and under irrigated conditions in another two (Yinchuan and Huinong). In Huinong, the crop was also exposed to salt stress.Highly significant positive associations were found between leaf and grain △ and grain yields across the environments.The relationship between △ and yield within environments highly depended on the quantity of water stored in the soil at sowing, the quantity and distribution of rainfall during the growth cycle, the presence of salt in the soil, and the occurrence of irrigation before anthesis. These two experiments confirmed the value of △ as an indirect selection criterion for yield and a phenotyping tool under post-anthesis water stress (including limited irrigation).     

Effect of Water Stress on Grain Growth and Assimilate Partitioning in two Cultivars of Wheat Contrasting in their Yield Stability in a Drought-Environment

Grain growth pattern and grain weight in relation to its positionbetween and within spikelets showed assimilate limitation tobe a factor reducing grain yield in wheat plants grown on storedmoisture in the field. Estimation of the relative contributionof pre- and post-anthesis assimilates to grain yield by a ¹⁴Clabelling technique indicated that cultivar C 306, known forits stability in yield and drought-tolerance, was characterizedby substantial mobilization of pre-anthesis assimilate (P),both in irrigated (24 per cent) and unirrigated (33 per cent)plants. As against this, in Kalyansona, a high yielding cultivarwith moderate stress tolerance, the contribution of P to grainyield was only 13 and 22 per cent in irrigated and unirrigatedplants, respectively. The mobilization of amino acids, estimatedfrom nitrogen contents at anthesis and maturity, was decreasedby water stress and was accompanied by a corresponding increasedtransport of carbohydrates. Assimilate partitioning, drought tolerance, grain growth, stability, water stress, wheat     

Nitrogen fertiliser rate and post-anthesis waterlogging effects on carbohydrate and nitrogen dynamics in wheat

Waterlogging is predicted to increase in both magnitude and frequency along with global warming, and will become one of the most severe adversities for crop production in many regions. Nitrogen is considered to be an effective up-regulatory nutrient for crops grown under stress and non-stress conditions. In this study, we try to evaluate N fertiliser effects on contents of carbohydrate and N dynamics, dry matter accumulation in shoot, yield under post-anthesis waterlogging. Waterlogging after anthesis significantly reduced grain yield due to decrease in thousand-kernel-weight and in grain number per spike. High N fertiliser application aggravated grain yield loss due to post-anthesis waterlogging. These yield losses were related to the decreases in dry matter accumulation, redistribution of stored photosynthate to the grain, and the conversion capacity from carbohydrate to starch in grain. The decrease in dry matter accumulation could be attributed to the reduced activities of Pn (photosynthesis) and SPS (sucrose phosphate synthase) in the flag leaf, while the low capacity in starch synthesis could be explained by the reduced activities of sucrose synthase (SS) and soluble starch synthase (SSS) in grain. Total N uptake in shoot was also reduced, which could contribute to the losses in biomass and yield by waterlogging. The decrease in Pn was inconsistent with the increase in N content in the flag leaf at high N fertiliser application under post-anthesis waterlogging.     

强筋与弱筋小麦籽粒蛋白质组分与加工品质对灌浆期弱光的响应

选用强筋小麦品种济麦20和弱筋小麦品种山农1391,在大田试验条件下,分别于籽粒灌浆前期(花后6—9 d)、中期(花后16—19 d)和后期(花后26—29 d)对小麦进行弱光照处理,研究了籽粒产量、蛋白质组分及加工品质的变化。灌浆期弱光显著降低小麦籽粒产量,灌浆中期对济麦20和灌浆后期对山农1391的产量降幅最大。弱光处理后,籽粒氮素积累量及氮素收获指数减少。但弱光使籽粒蛋白质含量显著升高,其中灌浆中期弱光升幅最大,原因可能是由于其粒重降低造成的。弱光对可溶性谷蛋白无显著影响,但增加不溶性谷蛋白含量,使谷蛋白聚合指数显著升高,面团形成时间和稳定时间亦升高,籽粒灌浆中、后期弱光对上述指标的影响较前期大。灌浆期短暂的弱光照对改善强筋小麦粉质仪参数有利,但使弱筋小麦变劣;并均伴随籽粒产量的显著降低这一不利影响。     

氮肥后移对抽穗后水分胁迫下冬小麦光合特性及产量的影响

采用子母桶栽土培法模拟冬小麦抽穗后不同的水分胁迫状态,研究了氮肥后移对冬小麦光合特性及产量的影响.设置3个氮肥处理,分别为N₁(基肥∶拔节肥∶开花肥=10∶0∶0)、N₂(6∶4∶0)和N₃(4∶3∶3),模拟冬小麦抽穗后2种水分胁迫(渍水胁迫、干旱胁迫),设正常供水为对照.结果表明：相同供水条件下,N₂和N₃处理较N₁处理显著提高冬小麦灌浆期旗叶的SPAD和光合速率,确保了收获时较高的穗数、穗粒数和地上部分生物量;氮肥后移处理显著提高了冬小麦的耗水量,但其籽粒产量和水分利用效率也显著提高.相同氮肥条件下,干旱胁迫和渍水胁迫处理较正常供水显著降低了冬小麦开花期和灌浆期旗叶的光合速率、千粒重、穗粒数和产量.与正常供水相比,各氮肥条件下干旱胁迫和渍水胁迫处理花后旗叶光合速率及籽粒产量的减小幅度均表现为N₁＞N₂＞N₃.表明氮肥后移通过提高旗叶SPAD、减缓花后旗叶光合速率的下降幅度、增加地上部分干物质积累量,调控产量及其构成要素,以减轻逆境灾害(干旱和渍水胁迫)对产量的影响.     

渍水对四川小麦生理性状及产量的影响

采用二因素裂区设计,连续2年（2011-2012和2012-2013年）以川麦104和内麦836为对象,在小麦苗期、拔节期、孕穗期、开花期分别进行35 d的渍水处理,研究渍水对四川小麦生长和产量形成的影响.结果表明： 苗期渍水减产最大,减产10%～15%,随渍水时期的后移,对产量的影响减小.苗期渍水降低了第3～6叶SPAD值、单株分蘖力和单株成穗数,降低了有效穗数、花后干物质积累量和成熟期干物质量.拔节期渍水降低了第4～7叶SPAD值,孕穗期渍水降低了倒4、倒3、倒2叶SPAD值,拔节期和孕穗期渍水导致花后旗叶SPAD值下降,渐增期灌浆速率（R₁）和平均灌浆速率（R_mean）下降,千粒重下降.开花期渍水对产量影响较小.表明苗期渍水是四川稻茬小麦渍害临界期.