两种旱地高产小麦品种花后衰老过程中脱落酸和iPAs的含量变化(简报)

在旱地大田条件下高产小麦Ｌ２１花后衰老过程中旗叶、根系与籽粒中ｉＰＡｓ含量下降和ＡＢＡ含量增加均慢于Ｄ２７,因而有利于形成高产。     

土层厚度对旱地小麦花后根系衰老的影响

随土层加深,根系活力、根系ＳＯＤ、ＣＡＴ活性及可溶性蛋白质含量增加,ＭＤＡ含量减少,土层愈薄,其根系衰老愈快。从整个土层看,处理３（１６０ｃｍ）与对照（２００ｃｍ）无显著差异,处理１（８０ｃｍ）和处理２（１２０ｃｍ）与对照差异显著,由此可以认为延迟旱地小麦衰老的土层厚度应在１６０ｃｍ左右,并可据此制定管理方案,以获得高产高效。     

新一代旱地龙简介

新疆汇通 (集团 )股份有限公司研制的“新一代旱地龙”是一种多功能抗旱营养调节和高效土壤活化剂 ,主要用于各种农作物、蔬菜和园林的叶面喷施及滴灌、渗灌。叶面喷施可以满足植物对各种营养元素的需求 ,提高作物的光合作用和酶的活性 ,促进植物体内氧化还源、增加叶绿素含量、促进新陈代谢、加快细胞分裂分化速度 ,提高植物体内原激素的含量 ,调节糖、酸、维生素的衡定比例 ,使作物具有延缓衰老、保花、保果、复青、高产的作用。“新一代旱地龙”还可促进植物根系对水分和养分的再吸收能力。由于旱地龙内含高活性黄腐殖酸 ,喷施后可促进蛋…     

施肥深度对旱地小麦花后根系衰老的影响

研究了施肥深度对旱地小麦花后根系衰老的影响,结果层次（20－40cm)施肥,其根中保护酶系SOD,CAT活性可保持较高水平,根系活力和根可溶性蛋白质含量降低慢,抑制膜脂过氧化产物MDA的产生,利于延迟根系衰老,施肥过浅（0－20cm)和施肥过深（60－80cm）,根系衰老快,产量较低,从整体看,处理产生,利于延迟根系衰耆 ,施肥过浅（0－20cm施肥）及处理4（60－80cm施肥）差异显著,与处理3（40－60cm施肥）差异较少,可以认为,延迟旱地小麦根系衰老的施肥深度应在20－40cm左右,据此制定管理方案,以获得旱地小麦的高产高效。     

激动素和丁二酸拌种对玉米衰老过程中抗氧化系统和植物激素的影响

以‘郑单958’（晚衰型品种）和‘豫单2002’（早衰型品种）为实验材料,采用盆栽方式,0．03μg·kg-1的外源激动素（KT）和300mg·kg-1丁二酸复合剂进行拌种处理,研究拌种后玉米根叶衰老指标的变化及其化学调控效应。结果表明：激动素和丁二酸混合拌种后根系与叶片中超氧阴离子（O2-）产生速率、丙二醛（MDA）及脱落酸（ABA）含量低于其对照,而超氧化物歧化酶（SOD）活性和生长素（IAA）含量却较高,据此认为膜脂过氧化得到缓解,根叶的生理功能期延长;且在整个生育期内各个叶位叶的MDA含量、SOD活性、ABA和IAA含量高于根系,但其O2-和IAA／ABA较低,表明根系的衰老早于叶片。综上可以推测,激动素和丁二酸拌种能有效防止根叶早衰,为提高玉米产量打下基础。     

黄腐酸拌种对春小麦产量和水分利用效率的影响

在大田研究了黄腐酸拌种对春小麦产量形成和水分利用效率的影响。实验设４个处理：对照（ＣＫ）,播种前种子不处理;ＦＡ处理：播种前用ＦＡ拌种;ＷＭ处理：浇３０ｍｍ底墒水,覆膜;处理ＷＭＦＡ：浇３０ｍｍ底墒水,覆膜,播种前用ＦＡ拌种。２个覆膜处理均在播种后６２ｄ揭膜。同ＣＫ相比,ＦＡ拌种后,根系生长良好,吸收利用了更多的土壤水分,增加了穗重、单穗籽粒重和收获指数,产量和水分利用效率均显著提高。ＷＭ和ＷＭＦ     

孕穗期渍水对冬小麦根系衰老的影响

选用耐湿性不同的３个冬小麦栽培品种,采用土柱栽培试验方法研究了孕穗期渍水逆境对冬小麦根系生长发育、＾３２Ｐ吸收、分配及根系衰老的影响。结果表明,孕穗期渍水逆境降低了地下根系干重、根系活力和根系ＳＯＤ酶活性;使根系质膜相对透性和膜脂过氧化水平（ＭＤＡ含量）提高;同时,孕穗期渍水逆境严重影响根系吸收、运输和分配＾３２Ｐ的能力,从而加速了根系衰老。     

三唑酮对绿豆幼苗叶片衰老的延缓作用

三唑酮处理可提高离体绿豆（ＰｈａｓｅｏｌｕｓｒａｄｉａｔｕｓＬ．）幼苗叶片叶绿素和蛋白质含量。叶片衰老过程中超氧物歧化酶（ＳＯＤ）、过氧化物酶（ＰＯＤ）、过氧化氢酶（ＣＡＴ）和抗坏血酸过氧化物酶（ＡｓＡＰＯＤ）活性及抗坏血酸（ＡｓＡ）和还原型谷胱甘肽（ＧＳＨ）含量降低。２０ｍｇ／Ｌ三唑酮可提高ＰＯＤ、ＡｓＡＰＯＤ活性和ＡｓＡ、ＧＳＨ含量,对ＳＯＤ、ＣＡＴ活性无影响。丙二醛（ＭＤＡ）含量在叶片衰老过程中提高,并与ＰＯＤ、ＡｓＡＰＯＤ活性和ＡｓＡ、ＧＳＨ含量呈显著负相关,三唑酮可降低ＭＤＡ含量。表明三唑酮有提高植物对膜脂过氧化作用的保护能力,延缓叶片的衰老作用。     

施肥深度对旱地小麦花后旗叶衰老及产量的影响

土柱栽培研究了施肥深度对旱地小麦花后旗叶衰老及产量的影响。结果表明：较深层次（20-40cm)施肥,旗叶SOD、CAT活性可保持较高水平,可溶性蛋白质含量降低慢,抑制MDA含量的产生,有利于延迟旗叶衰老。施肥过浅和施肥过深,施叶衰老快,产量较低,从整体看,处理2与处理1及处理4差异显著,与处理3差异较少,由此认为延迟旱地小麦旗叶衰老的施肥深度应在20-40cm左右,并可据此制定管理方案,以获得高产高效。     

大穗型水稻生育后期叶片和根系生理的特性

Ｇ Ｅ Ｒ１ 是从玉米 Ｄ Ｎ Ａ 导入水稻的后代变异材料中筛选出的大穗型高产变异系⒚对 Ｇ Ｅ Ｒ１ 生育后期叶片和根系生理特性的研究表明：与受体湘早籼 ８ 号和三系杂交稻汕优 ６３相比, Ｇ Ｅ Ｒ１ 的顶三叶叶绿素含量、蛋白质含量、光合速率、过氧化物酶和超氧化物歧化酶活性降幅小,丙二醛含量增幅小,叶片衰老得到延缓,生育后期根量和根系伤流量较大、发根力和根系 α萘胺氧化力较强⒚生育后期叶片和根系的延缓衰老使得叶片功能期长、光合产物供应充足,是实现大穗多穗条件下水稻高结实率和充实度好的主要内在原因⒚     

密度、施肥对旱地春小麦产量、水分利用效率和籽粒养分含量的补偿效应

为了探明旱作条件下无机营养对作物产量和水分利用效率的补偿效应,我们在宁南黄土高原半干旱地区开展了为期两年的春小麦密度与肥料试验。通过4种播种密度和5种肥力水平的综合研究结果表明,在不同处理的籽粒产量和水分利用效率排序中,播种密度为500粒／m^2时,以施肥量90kg／hm^2N和135kg／hm^2P2O5处理的产量和水分利用效率为最大。与不施肥的对照相比,增施肥料与籽粒产量和水分利用效率的提高成显著的正相关关系,相关系数分别达到0．959和0．894,而播种密度则与产量和水分利用效率的相关性不显著。增施肥料虽然能够提高可育小花数,但随着播种密度的增大,穗粒数和千粒重反而呈下降趋势,表明可育小花数对肥料水平反应敏感,而穗粒数和千粒重主要受播种密度的影响。施肥能够促进春小麦根系的生长发育,特别是促进浅层根量的增加,增强了作物的水分养分吸收。另外,不同种类肥料配施的结果表明,单施P肥或者N、P、K配合施用,可使春小麦产量分别提高44．6％和55．4％。N、P、K配合施肥还能够提高品质,使籽粒中的P、N、K含量分别提高18．5％、18．4％和8．1％。上述研究结果说明,控制播种密度、改善土壤肥力对于促进旱地春小麦高效利用有限水分具有明显的补偿效应。     

植物多糖类复合制剂对冬小麦产量及物质转运的影响

在大田栽培条件下,采用生物质多糖(P₁)、生物质多糖和5 氨基乙酰丙酸复配(P₂),以及生物质多糖、5-氨基乙酰丙酸和缩节胺为有效成分复配(P₃)的3种不同制剂,研究在冬小麦始花期叶面喷施制剂对其产量构成、蔗糖、可溶性总糖、干物质贮运以及氮磷养分累积与转移的影响.结果表明: 喷施3种制剂使冬小麦穗粒数和千粒重增加,增产8.5%以上;喷施20 d内,小麦旗叶蔗糖含量较对照明显增加;喷施P₁和P₃使小麦籽粒可溶性糖含量分别比对照增加4.5%和11.0%.P₃增加了小麦花后干物质及氮磷养分累积量,分别较对照增加48.5%、116.9%和18.1%,P₃还显著提高了小麦花后干物质及养分累积对产量的贡献,但花前养分向籽粒转移对产量的贡献小于其他处理.小麦增产与植物多糖类复合制剂有效调控营养器官光合产物输出、籽粒可溶性糖积累,以及促进花后干物质和氮磷养分累积有关.     

烯效唑干拌种对小麦氮素积累和运转及籽粒蛋白质品质的影响

通过田间试验,研究了不同烯效唑干拌种剂量对3个不同筋力小麦品种植株氮素积累、运转和籽粒蛋白质品质的影响,结果表明,基因型、环境及烯效唑处理对小麦品质的影响效应依次减小,且均达到了极显著水平,但三者的互作效应较小。烯效唑处理后提高了不同生态点下不同小麦品种籽粒蛋白质含量和产量,处理后的面筋含量和沉淀值增加,面团形成时间和稳定时间延长;干拌种增加了开花期各营养器官中的氮素含量和单株氮素积累量,花后氮素总转移量、总转移率及其对籽粒氮的贡献率极显著提高,且处理后旗叶中可溶性蛋白质含量在花后15 d内均显著高于对照;对籽粒中氮含量而言,烯效唑处理后提高了灌浆初期籽粒中的非蛋白氮含量,花后5—20 d内均高于对照,灌浆期间籽粒蛋白氮含量均高于对照,因而处理后的粗蛋白质含量变化动态特点为谷底高、回升快。研究认为,烯效唑处理如同基因、环境一样独立影响小麦籽粒品质,而烯效唑处理后提高了开花初期旗叶中的可溶性蛋白质含量和花前营养器官中氮素含量及花后氮素转运量,可能是其提高籽粒非蛋白氮含量、促进籽粒蛋白质含量增加和蛋白质质量提高的重要原因之一,烯效唑干拌种对小麦籽粒蛋白质品质的改善具有广适性。     

The pleiotropic effects of extract containing rhizobial Nod factors on pea growth and yield

Rhizobial lipochitooligosacharides (Nod factors) influence the development of legume roots, including growth stimulation, nodule induction and root hair curling. However, their effect on the green parts of plants is less known, therefore we evaluated seed and foliar application of an extract containing Nod factors on pea growth and yield. Pea plants were examined from emergence to full maturity, including growth dynamics and morphological (nodule number and weight, the quantity and surface area of leaves) or physiological (photosynthesis and transpiration intensity, chlorophyll and nitrogen content) parameters. The foliar application Nod factor extract, or seed dressing followed by foliar application, resulted in the best outcomes. The number and weight of root nodules, the chlorophyll content in leaves, and the intensity of net photosynthesis were all elevated. As a consequence of Nod factor treatment, the dynamics of dry mass accumulation of pea organs were improved and the pod number was increased. A significant increase in pea yield was observed after Nod factor application. Increase of nodule and pod numbers and improved growth of roots appear to be amongst the beneficial effects of Nod factor extract on the activation of secondary plant meristems.     

Impact of oxygation on soil respiration,yield and water use efficiency of three crop species

Aims Oxygation refers to irrigation of crops with aerated water, through air injection using the venturi principle or the supply of hydrogen peroxide in the root zone, both using subsurface drip irrigation (SDI) system. Oxygation improves water use efficiency (WUE), producing more yield and, and therefore, optimizes the use of drip and SDI. But the efficiency of oxygation is quite possibly dependent on a number of factors. The primary objective of this study was, therefore, to quantify the effects of oxygation, emitter depths and soil type on crop root zone oxygen content, soil respiration, plant physiological response, biomass yield, quality and WUE of three crop species.Methods This study investigated the potential of oxygation to enhance soil respiration, plant growth, yield and water use efficiencies (WUE) of cotton and wheat in experiments in enclosed heavy-duty concrete troughs (tubs) and pineapple and cotton in field experiments. Experimental treatments in tubs for wheat included comparisons between two soil types (vertisol and ferrosol) and superimposed were two oxygation methods (Mazzei air injector and Seair Diffusion System) compared to a control, and for cotton, emitters at two depths using Mazzei air injectors were compared to a control. The field experiments compared Mazzei air injectors and a control for cotton in Emerald and pineapple in Yeppoon, both in central Queensland, Australia.Important findings In all experiments, soil oxygen content and soil respiration markedly increased in response to the oxygation treatments. The O 2 concentration in the crop root zone increased by 2.4–32.6%, for oxygation compared to control at the same depth. The soil respiration increased by 42–100%. The number of wheat ears, leaf dry weight and total dry matter were significantly greater in Mazzei and Seair oxygation compared to the control. Fresh biomass of wheat increased by 11 and 8%, and dry weight of wheat increased by 8 and 3% in Mazzei and Seair oxygation treatments compared to the control, respectively. Likewise, the irrigation water use efficiency increased with oxygation compared to the control in wheat. The yield, WUE and number of other physiological parameters in wheat were enhanced in vertisol compared to ferrosol. The seed cotton yield in the tub experiment increased with oxygation by 14%, and significant differences for fresh biomass, dry matter and yield were also noted between oxygation and the control in the field. Lint yield and WUE both increased by 7% using Mazzei in the cotton field trial during 2008–09. There were significant effects of oxygation on pineapple fresh biomass, and dry matter weight, industry yield and a number of quality parameters were significantly improved. The total fruit yield and marketable increased by 17 and 4% and marketable WUE increased by 3% using Mazzei. Our data suggest that the benefits of oxygation are notable not only for dicotyledonous cotton but also for monocotyledonous wheat and pineapple representing different rooting morphologies and CO₂ fixation pathways.     

豆科作物-小麦轮作方式下旱地小麦花后干物质及养分累积、转移与产量的关系

研究旱作条件下豆科绿肥轮作影响旱地小麦产量变化的作物营养生态机制,对优化旱地作物种植施肥制度,促进水分资源高效利用、土壤培肥、作物增产有重要意义。通过两年定位试验,分析了与不同豆科作物轮作引起的后茬小麦产量变化及其与干物质、氮磷钾养分累积、转移的关系。结果表明:与秋豆轮作的第一季,小麦籽粒产量无显著变化,但第二季小麦产量提高23.4%;与绿豆轮作,两季产量分别降低19.2%和4.4%;与大豆轮作,产量无显著变化。与秋豆轮作增加了小麦花后干物质及氮、磷养分累积,和对照相比分别增加了35.1%,128.8%和14.0%,而与大豆和绿豆轮作花后干物质累积分别降低26.7%和17.0%,花后氮累积分别降低44.2%和24.4%,花后磷累积与对照相比无显著差异。与此对应,秋豆-小麦轮作,其后茬小麦花后干物质及养分累积对产量形成的贡献显著增加,茎叶花前累积氮、磷向籽粒的转移对产量的贡献明显小于大豆-小麦和绿豆-小麦轮作处理。与氮、磷不同,小麦茎叶花前累积钾素向籽粒转移的同时,花后植株钾素没有累积,反而明显损失,其中与秋豆轮作的小麦花后植株钾素损失量较小,为3.8 kg/hm2,籽粒钾素占转移钾的81.0%;休闲或与大豆、绿豆轮作的小麦花后植株钾素损失较多,分别为10.9,12.6和5.5kg/hm2,籽粒钾素占转移钾的52.9%,52.9%和66.8%。与秋豆-小麦轮作处理小麦增产的主要原因是花后植株能累积更多干物质和氮、磷养分,减少了花前累积于茎叶的钾素在花后的损失。     

小麦开花期灌水对土壤养分及根系分布的影响

本研究通过分析开花期灌水对小麦产量、植株养分分配和土壤养分分布的影响及其与根系特性的关系,为小麦充分利用水肥资源提供理论支撑。以抗旱高产品种‘洛麦28'和高光效品种‘百农207'为材料,采用2 m深土柱栽培方法,设置开花期灌水(T₁)和开花期不灌水(T₂)两个水分处理,测定了不同组织器官、不同土层土壤氮、磷、钾含量及根系分布特性等指标。结果表明: 小麦收获期土壤中铵态氮、速效磷和速效钾主要分布在0～80 cm土层中,硝态氮主要分布在80 cm以下土层中,开花期灌水促进小麦吸收0～60 cm土层的铵态氮、速效磷、速效钾和80 cm以下土层的硝态氮,减少了硝态氮向深层土壤的淋溶;小麦根系主要集中在0～60 cm土层中,随土壤深度的增加而减少。成熟期干物质积累量、全氮和全磷主要分配在小麦籽粒中,而全钾主要分配在茎秆中;开花期灌水显著增加了小麦百粒重,提高了小麦产量;根系形态指标与土壤硝态氮在0～40 cm土层中呈显著负相关,与土壤铵态氮在80～100 cm土层中呈极显著正相关,与土壤速效磷在0～100 cm土层中呈显著正相关。开花期灌水促进了根系在小麦生育末期对土壤养分的充分吸收,延长了养分从营养器官向生殖器官的转运功能期,使营养器官中的养分充分地转运到籽粒中去,增加小麦粒重,进而提高产量。     

Identification of Differentially Senescing Mutants of Wheat and Impacts on Yield,Biomass and Nitrogen Partitioning

Increasing photosynthetic capacity by extending canopy longevity during grain filling using slow senescing stay-green genotypes is a possible means to improve yield in wheat.Ethyl methanesulfonate (EMS...