不同水分条件下氮素供应对小麦植株氮代谢及籽粒蛋白质积累的影响

土壤水分逆境是限制小麦籽粒品质形成的重要生态因子,明确土壤水分逆境下小麦籽粒品质形成的生理机制及调优技术途径,对于深化小麦品质生理生态研究和指导小麦调优栽培具有重要的理论意义和应用前景。在防雨池栽条件下,设置渍水、干旱和对照3个水分处理,每个水分处理下再设置120和240 kg.hm-2两个施氮水平,研究了花后渍水和干旱逆境下氮素对两个籽粒蛋白质含量不同的小麦品种植株氮代谢和籽粒蛋白质积累的影响。结果表明,与正常水分处理相比,花后干旱和渍水均降低旗叶硝酸还原酶活性、叶片总氮含量和游离氨基酸含量。干旱处理提高了茎鞘总氮与游离氨基酸含量以及籽粒蛋白质含量,而渍水处理则使其降低。水分逆境下增施氮肥提高旗叶硝酸还原酶活性、叶片与茎鞘总氮和游离氨基酸含量以及籽粒游离氨基酸和蛋白质含量。花后干旱和渍水均显著降低了小麦籽粒产量和蛋白质产量。增施氮肥提高适宜水分和水分亏缺条件下小麦籽粒产量,但不利于渍水下小麦产量的提高。这说明,花后渍水和干旱逆境下施用氮肥对小麦植株氮代谢和籽粒蛋白质积累有明显的调节效应。     

氮、钾水平对小麦籽粒蛋白质合成关键酶活性的影响

在大田栽培条件下,以蛋白质含量差异的两个冬小麦(Triticum aestivum L.)品种宁麦9号(低蛋白)和扬麦10号(中蛋白)为材料,研究了不同氮、钾施肥水平对小麦旗叶与籽粒中游离氨基酸含量、蛋白质合成关键酶活性和籽粒蛋白质含量的影响及其与开花期旗叶氮、钾营养的关系.结果表明,氮、钾施肥显著提高了小麦花后旗叶与籽粒中游离氨基酸和籽粒蛋白质含量、旗叶谷氨酰胺合成酶(GS)及籽粒GS和谷丙转氨酶(GPT)活性,其中氮肥的作用大于钾肥、氮钾肥配合达到最大,对扬麦10号的效应大于宁麦9号.开花期旗叶氮/钾比随施氮水平的增加呈二次曲线变化,随施钾水平的增加呈下降趋势.旗叶GS活性和成熟期籽粒蛋白质含量与氮/钾比均呈显著或极显著的二次曲线关系.因此,旗叶和籽粒中蛋白质合成关键酶活性受开花期旗叶氮/钾比的显著影响,是氮、钾素影响小麦籽粒蛋白质形成的重要生理原因.     

小麦叶片中硝酸还原酶活性、游离氨基酸和粗蛋白含量与籽粒蛋白质含量关系研究

试验以５个八倍体小偃麦、野生二粒小麦、硬粒小麦和１３个普通小麦品种（系）为材料,研究了叶片中硝酸还原酶活性（ＮＲＡ）、氨基酸和粗蛋白含量与籽粒蛋白质含量之间的关系。结果表明,叶片中ＮＲＡ在拔节、抽穗、开花三个生育时期与籽粒蛋白质含量存在显著的正相关系;叶片中氨基酸总量与籽粒蛋白质含量在拔节和抽穗期显著相关,在开花期相关不显著;抽穗期旗叶中粗蛋白含量与籽粒蛋白质含量相关显著。籽粒蛋白质含量高的基因型材料其叶片中ＮＲＡ、氨基酸和粗蛋白含量一般高于低蛋白基因型材料,三者的变化趋势一致,这反映了不同基因型Ｎ素代谢的特点。因此适宜生育时期叶片中ＮＲＡ、氨基酸和粗蛋白含量可作为品质育种选择过程中的参考生理指标。     

不同施肥水平对不同品种小麦籽粒蛋白质和地上器官游离氨基酸含量的影响

研究了小麦不同品种开花后各地上器官游离氨基酸含量的变化动态及其与籽粒蛋白质含量的关系,以及氮素营养的调节作用。结果表明,小麦叶片和颖壳十穗轴游离氨基酸含量均在开花后持续增加,至花后14d达到最大值,之后开始下降。茎和叶鞘游离氨基酸含量则在开花后上升较缓慢,至花后21d达最大值。籽粒游离氨基酸含量一般在开花后就持续降低。各地上器官游离氨基酸含量与成熟期籽粒蛋白质含量均呈显著或极显著正相关,说明源器宫中游离氨基酸供应充足,有利于籽粒蛋白质积累。增施氮肥能够提高各地上器官中的游离氨基酸含量,进而促进籽粒蛋白质的合成,提高籽粒蛋白质含量。品种之间籽粒蛋白质含量的差异,是由各地上营养器官向籽粒运输氨基酸的综合作用所造成的。     

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。     

水分胁迫对水稻籽粒蛋白质积累及营养品质的影响

以生产上广泛使用的水稻(Oryza sativa)品种‘汕优63’、‘扬稻6号’和‘武育粳3号’为材料,研究了水分胁迫对结实期水稻籽粒蛋白质积累及营养品质的影响。结果表明:正常施氮水平下,花后10~20 d的水分胁迫提高了谷氨酰胺合成酶(Glutamine synthetase,GS)和谷氨酸合酶(Glutamate synthase,GOGAT)活性,提高了籽粒自身利用无机氮合成氨基酸的能力,从而利于籽粒内蛋白质的积累,而高氮水平下,水分胁迫降低了籽粒自身合成氨基酸的能力。以重量为基数的蛋白质含有率在整个灌浆过程中呈“V”型消长,正常施氮水平下,水分胁迫明显提高了花后15 d至成熟期蛋白质含有率,而高氮水平下,水分胁迫处理的蛋白质含有率明显低于水层灌溉。与水层灌溉相比,水分胁迫提高了正常施氮水平下精米中醇溶蛋白和谷蛋白含量,但却明显降低了高氮水平下精米中醇溶蛋白和谷蛋白含量。水分胁迫对稻米中赖氨酸含量的影响因品种、植株的氮营养水平的不同而不同,水分胁迫显著降低了两种氮肥水平下‘汕优63’中赖氨酸含量,但却明显提高‘扬稻6号’中赖氨酸含量;而‘武育粳3号’于两种氮肥水平下表现恰好相反,正常施氮水平下赖氨酸含量略有升高;而高氮水平下赖氨酸含量明显降低。     

土壤肥力和施氮量对小麦氮素吸收运转及籽粒产量和蛋白质含量的影响

在不同土壤肥力条件下,研究了施氮量对小麦氮素吸收、转化及籽粒产量和蛋白质含量的影响。结果表明,增施氮肥可以提高小麦各生育阶段的吸氮强度,尤以生育后期提高的幅度为大认为是增施氮肥提高小麦籽粒产量和蛋白质含量的基础,增施氮肥虽提高了小麦植株的吸氮强度。吸氮量增加,但开花后营养器官氮素向籽粒中的转移率降低,增施氮肥不仅促进了小麦植株对肥料氮的吸收,而且也促进了对土壤氮的吸收,并讨论了在高、低土壤肥力条件下氮肥合理运筹的问题。     

耕作方式及施氮量对砂姜黑土区小麦氮代谢及籽粒产量和蛋白质含量的影响

为明确砂姜黑土区小麦(Triticum aestivum)产量和品质形成的耕作方式及施氮量最优组合, 在大田试验条件下, 以深松、旋耕和常规耕作3种耕作方式为主区, 0、120、225、330 kg·hm^-2 4个施氮量为副区, 研究了不同耕作方式及施氮量组合对小麦拔节后氮代谢、籽粒产量和蛋白质含量的影响。结果表明, 随着生育期的推进, 叶片谷氨酰胺合成酶活性、游离氨基酸含量和可溶性蛋白含量均呈先升后降的趋势, 深松方式配合中高氮处理的峰值在花后10天, 而常规耕作和旋耕的4个施氮处理以及深松的低氮处理峰值多在开花期。与常规耕作和旋耕相比, 深松耕作显著降低了10-40 cm的土壤容重, 提高了土壤总空隙度和根干质量, 有利于中后期根系氮素吸收。耕作方式和施氮量对籽粒产量和蛋白质含量影响显著, 均以深松方式最高。3种耕作方式下小麦产量和蛋白质含量均随施氮量增加而增加, 籽粒产量以深松方式配合330 kg·hm^-2施氮量最高, 而常规耕作和旋耕方式的产量在施氮量为225 kg·hm^-2时达到最大。3种耕作方式下籽粒蛋白质含量均以施氮225 kg·hm^-2最高。因此, 在砂姜黑土区宜采用深松耕作方式配合适宜的施氮量, 以改善土壤条件, 促进根系氮素吸收, 延长叶片功能期, 达到产量与蛋白品质提升之目的。     

旱地小麦休闲期覆盖增磷对籽粒蛋白质积累的影响

为探索旱地小麦休闲期覆盖保水配施磷肥高产、优质的技术途径,在山西农业大学闻喜试验基地采用大田试验研究了休闲期覆盖或不覆盖条件下低(75 kg/hm2)、中(112.5 kg/hm2)、高(150 kg/hm2)施磷水平对土壤水分、籽粒蛋白质形成的影响及其生理机制。结果表明:休闲期覆盖后,播种期0-100 cm土壤蓄水量显著提高,达39-42 mm,而开花期60-100 cm土层降低。覆盖后,花后旗叶和籽粒GS和GOGAT活性提高,籽粒游离氨基酸和灌浆后期GMP含量提高,籽粒蛋白质及其组分含量、谷/醇均提高。增加施磷量,开花期20-60 cm、80-100 cm土层蓄水量降低,而花后旗叶和籽粒GS活性提高,且覆盖条件下花后0-15 d、20 d旗叶GOGAT活性,花后5 d、15 d、25-30 d籽粒GOGAT活性,籽粒游离氨基酸含量、籽粒GMP含量提高,籽粒蛋白质及其组分含量、谷/醇、蛋白质产量显著提高,产量提高940-1452 kg/hm2。此外,休闲期覆盖配施磷肥条件下,开花期深层土壤水分与旗叶GS和GOGAT活性密切相关,旗叶和籽粒GS和GOGAT活性均与游离氨基酸含量、谷/醇、蛋白质产量关系密切。总之,旱地小麦休闲期覆盖有利于提高底墒,且配合施磷量150 kg/hm2可促进根系吸收深层土壤水分,提高产量的同时也提高了籽粒蛋白质含量、GMP含量和谷/醇。     

不同形态氮素对专用型小麦花后氮代谢关键酶活性及籽粒蛋白质含量的影响

采用盆栽方法研究了氮素形态对不同专用型小麦开花后氮素同化关键酶活性及籽粒蛋白质含量的影响。结果表明:不同专用型小麦氮素同化关键酶硝酸还原酶、谷氨酰胺合成酶和谷氨酸合酶对氮素形态的反应不同。强筋小麦豫麦34施用酰胺态氮对旗叶硝酸还原酶和谷氨酰胺合成酶活性、籽粒谷氨酰胺合成酶和谷氨酸合酶活性具有明显的促进作用,最终籽粒蛋白质含量较高;中筋小麦豫麦4 9在施用铵态氮时,3种氮素同化关键酶活性均有较大增强,籽粒蛋白质含量最高;弱筋小麦豫麦5 0硝酸还原酶活性以铵态氮处理最高,而籽粒和旗叶谷氨酰胺合成酶和谷氨酸合酶活性在酰胺态氮处理下明显增强,酰胺态氮对籽粒中蛋白质含量的增加具有明显的促进作用。相关性分析表明,籽粒蛋白质含量与旗叶GS活性和籽粒GOGAT活性呈显著或极显著正相关,与旗叶NR活性和GS活性、籽粒GOGAT活性相关性不显著     

Root exudates of plants

Summary Comparisons have been made of the amount and composition of seed and seedling exudates in barley, wheat, cucumber, and bean. Except in the case of wheat a greater proportion of the total nitrogen content in the seed exudates was formed by protein and peptide nitrogen than by nitrogen of free amino acids. In contrast, the greater part of the total nitrogen in the exudates of seedlings was formed by free amino acid nitrogen, except in the case of barley. Peptides represented 8 to 26 per cent of the protein and peptide fraction in seed exudates, the highest amount being found in bean. On an equal weight basis, the spectrum of amino acids released from seeds and seedlings differed little between barley, wheat and cucumber; greater differences were observed in bean exudates. Seedlings exuded reducing substances to a considerably greater extent than seeds. The spectrum of reducing sugars in seed and root exudates differed greatly, especially in the case of keto sugars. Differences in the organic acid spectra were small, except for bean plants, the seedling exudate of which contained more organic acids with a richer spectrum than seed exudate. Both seeds and seedlings of cucumber exuded a small quantity and a poor spectrum of organic acids.     

AAP1 regulates import of amino acids into developing Arabidopsis embryos

The embryo of Arabidopsis seeds is symplasmically isolated from the surrounding seed coat and endosperm, and uptake of nutrients from the seed apoplast is required for embryo growth and storage reserve accumulation. With the aim of understanding the importance of nitrogen (N) uptake into developing embryos, we analysed two mutants of AAP1 (At1g58360), an amino acid transporter that was localized to Arabidopsis embryos. In mature and desiccated aap1 seeds the total N and carbon content was reduced while the total free amino acid levels were strongly increased. Separately analysed embryos and seed coats/endosperm of mature seeds showed that the elevated amounts in amino acids were caused by an accumulation in the seed coat/endosperm, demonstrating that a decrease in uptake of amino acids by the aap1 embryo affects the N pool in the seed coat/endosperm. Also, the number of protein bodies was increased in the aap1 endosperm, suggesting that the accumulation of free amino acids triggered protein synthesis. Analysis of seed storage compounds revealed that the total fatty acid content was unchanged in aap1 seeds, but storage protein levels were decreased. Expression analysis of genes of seed N transport, metabolism and storage was in agreement with the biochemical data. In addition, seed weight, as well as total silique and seed number, was reduced in the mutants. Together, these results demonstrate that seed protein synthesis and seed weight is dependent on N availability and that AAP1-mediated uptake of amino acids by the embryo is important for storage protein synthesis and seed yield.     

施用氮肥对油用牡丹叶片氮素吸收积累与籽粒品质的影响

利用田间栽培试验,研究0 (对照)、18、24和30 g N·m^-2 4个氮肥用量对油用牡丹“凤丹”叶片氮素吸收转运以及籽粒产量和品质的影响.结果表明: 施用氮肥处理牡丹株高、冠幅、花径和花干质量与对照相比均显著增加,其中,24和30 g·m^-2氮肥处理株高比对照分别增加14.7%和15.2%.施用氮肥提高了牡丹籽粒的相关指标,24和30 g·m^-2氮肥处理籽粒产量达到最大,分别比对照增加15.2%和15.4%.施用氮肥明显增加了叶片氮素积累量、叶片氮素转移量和籽粒氮素积累量.其中,24 g·m^-2氮肥处理叶片氮素对籽粒贡献率最大.与对照相比,施用氮肥明显提高了籽粒蛋白氮、总氨基酸,以及部分饱和脂肪酸和不饱和脂肪酸的含量.在本试验条件下,施氮量为24 g N·m^-2时,叶片积累氮素向籽粒的转移量、转移率和贡献率均达到较高水平,籽粒产量较高,并且蛋白氮、氨基酸含量和不饱和脂肪酸含量也相对较高.     

Amino Acid composition of germinating cotton seeds

Total and free amino acid composition of germinating cotton seeds (Gossypium hirsutum L.) was determined. The germinating seeds were separated into cotyledon and developing axis fractions daily and the composition of each tissue was summed to get the whole seed composition. By separating the developing seeds into these two tissue fractions, and determining total and free amino acids, a balance sheet was developed for each amino acid. This technique allowed changes in distribution with time of each amino acid to be followed in each tissue. Data for total content and amount in protein of each amino acid are presented. Asparagine increased in the whole seed, and most of this increase was found in the free pool of the developing axis. Other amino acids (e.g. arginine, glutamic acid) increased in the free pool but showed an over-all decrease, indicating that they were being metabolized. Amino acid contents of storage and nonstorage protein isolates were determined.     

Changes in soluble amino nitrogen,protein, nitrate reductase activity and abscisic acid during development of wheat grain

Trends in the time course, changes in the moisture, soluble amino acids, proline, abscisic acid contents and nitrate reductase activity determined byin vivo method in the developing seeds of wheat were studied. Maximum dry matter augmentation in the seed took place in the period between 10–30 days after anthesis. Per cent moisture and moisture content started declining 15 days and 25 days after anthesis, respectively. Levels of soluble amino acids, proline and nitrate reductase activity were higher during initial stages of seed development, but decreased with increasing magnitude of dehydration and accumulation of abscisic acid (ABA) in the maturing seeds.     

Accumulation of high levels of free amino acids in soybean seeds through integration of mutations conferring seed protein deficiency

Soybean ( Glycine max [L.] Merr.) seeds are rich in protein, most of which is contributed by the major storage proteins glycinin (11S globulin) and beta-conglycinin (7S globulin). Null mutations for each of the subunits of these storage proteins were integrated by crossbreeding to yield a soybean line that lacks both glycinin and beta-conglycinin components. In spite of the absence of these two major storage proteins, the mutant line grew and reproduced normally, and the nitrogen content of its dry seed was similar to that for wild-type cultivars. However, protein bodies appeared underdeveloped in the cotyledons of the integrated mutant line. Furthermore, whereas free amino acids contribute only 0.3-0.8% of the seed nitrogen content of wild-type varieties, they constituted 4.5-8.2% of the seed nitrogen content in the integrated mutant line, with arginine (Arg) being especially enriched in the mutant seeds. Seeds of the integrated mutant line thus appeared to compensate for the reduced nitrogen content in the form of glycinin and beta-conglycinin by accumulating free amino acids as well as by increasing the expression of certain other seed proteins. These results indicate that soybean seeds are able to store nitrogen mostly in the form of either proteins or free amino acids.     

Protein content and amino acid spectrum of finger millet [Eleusine coracana (L.) Gaertn.] as influenced by nitrogen and sulphur fertilizers

Summary The effect of N and S fertilizers on yield, protein content and amino acid composition of the tropical cereal finger millet was studied in field and sand culture experiments. In the field the grain yield measured from 2400 to 4100 kg/ha, and the seed crude protein from 7 to 13% with rates of N up to 150 kg/ha. Seed crude protein was high in methionine and cystine, but contained less sulphur amino acids when the seed was high in protein.Supplies in excess failed to increase the lower methionine and cystine contents of the crude protein.Sulphur deficiency drastically reduced the synthesis of sulphur amino acids, concomitantly raising the aspartic acid/asparagine content of the leaves up to 45 per cent of their total N content. An S:N weight ratio of 1:10 in the seeds and 1:15 in the leaves indicates adequate supply of sulphur. The importance of finger millet for human nutrition is considered in relation to increasing substitution with other crops, use of nitrogen fertilizers, and the actual sulphur status of soils in East Africa.Sponsored by the Norwegian Agency for International Development.Sponsored by the Norwegian Agency for International Development.     

Ectopic expression of an amino acid transporter (VfAAP1) in seeds of Vicia narbonensis and pea increases storage proteins

Storage protein synthesis is dependent on available nitrogen in the seed, which may be controlled by amino acid import via specific transporters. To analyze their rate-limiting role for seed protein synthesis, a Vicia faba amino acid permease, VfAAP1, has been ectopically expressed in pea (Pisum sativum) and Vicia narbonensis seeds under the control of the legumin B4 promoter. In mature seeds, starch is unchanged but total nitrogen is 10% to 25% higher, which affects mainly globulin, vicilin, and legumin, rather than albumin synthesis. Transgenic seeds in vitro take up more [14C]-glutamine, indicating increased sink strength for amino acids. In addition, more [14C] is partitioned into proteins. Levels of total free amino acids in growing seeds are unchanged but with a shift toward higher relative abundance of asparagine, aspartate, glutamine, and glutamate. Hexoses are decreased, whereas metabolites of glycolysis and the tricarboxylic acid cycle are unchanged or slightly lower. Phosphoenolpyruvate carboxylase activity and the phosphoenolpyruvate carboxylase-to-pyruvate kinase ratios are higher in seeds of one and three lines, indicating increased anaplerotic fluxes. Increases of individual seed size by 20% to 30% and of vegetative biomass indicate growth responses probably due to improved nitrogen status. However, seed yield per plant was not altered. Root application of [15N] ammonia results in significantly higher label in transgenic seeds, as well as in stems and pods, and indicates stimulation of nitrogen root uptake. In summary, VfAAP1 expression increases seed sink strength for nitrogen, improves plant nitrogen status, and leads to higher seed protein. We conclude that seed protein synthesis is nitrogen limited and that seed uptake activity for nitrogen is rate limiting for storage protein synthesis.     

Nonprotein amino acid composition of flatpea (Lathyrus sylvestris L.) as affected by ethephon seed treatments and seedling fertilization

Use of flatpea (Lathyrus sylvestris L.) as a forage is limited because of nonuniform seed germination and the potentially toxic effects of 2,4-diaminobutyric acid (A₂bu), a nonprotein amino acid found in seeds and vegetative tissues. The effects of ethephon (2-chloroethyl phosphonic acid) on seed germination, amino acid leachates of seeds, and amino acid composition (particularly A₂bu) of seedlings were investigated. Germination of flatpea seeds, imbibed for 16 h in 0, 100, 200, 400, 800, and 1600 mg/L ethephon, did not differ, but amino acid leachates tended to increase up to 200 mg/L ethephon and then decline at higher concentrations. The major amino acid constituents in leachates were A₂bu, 4-aminobutyric acid (Abu), and homoserine (Hse). Dry matter accumulation of seedlings grown from ethephon-treated seeds was reduced for second cuttings grown from ethephon-treated seeds and high nitrogen grown plants. During regrowth, free amino acid accumulation was most pronounced in leaves of plants supplied with high nitrogen. The most abundant free amino acids in flatpea tissues were the same as those in seed leachates, but concentration and relative abundance varied with nitrogen level, plant part, and ethephon treatment. Results suggest that ethephon seed treatments can have persistent effects on the growth and amino acid composition of flatpea seedlings grown under different nitrogen regimes.     

Nonprotein amino acid composition of flatpea (Lathyrus sylvestris L.) as affected by ethephon seed treatments and seedling fertilization

Use of flatpea (Lathyrus sylvestris L.) as a forage is limited because of nonuniform seed germination and the potentially toxic effects of 2,4-diaminobutyric acid (A₂bu), a nonprotein amino acid found in seeds and vegetative tissues. The effects of ethephon (2-chloroethyl phosphonic acid) on seed germination, amino acid leachates of seeds, and amino acid composition (particularly A₂bu) of seedlings were investigated. Germination of flatpea seeds, imbibed for 16 h in 0, 100, 200, 400, 800, and 1600 mg/L ethephon, did not differ, but amino acid leachates tended to increase up to 200 mg/L ethephon and then decline at higher concentrations. The major amino acid constituents in leachates were A₂bu, 4-aminobutyric acid (Abu), and homoserine (Hse). Dry matter accumulation of seedlings grown from ethephon-treated seeds was reduced for second cuttings grown from ethephon-treated seeds and high nitrogen grown plants. During regrowth, free amino acid accumulation was most pronounced in leaves of plants supplied with high nitrogen. The most abundant free amino acids in flatpea tissues were the same as those in seed leachates, but concentration and relative abundance varied with nitrogen level, plant part, and ethephon treatment. Results suggest that ethephon seed treatments can have persistent effects on the growth and amino acid composition of flatpea seedlings grown under different nitrogen regimes.