氮形态对不同小麦基因型氮素吸收和光合作用的影响

利用水培试验,研究了3个小麦基因型对不同形态N素吸收和积累的差异.结果表明,在不同N浓度下,小麦对增铵营养和NH⁺的吸收速率显著高于NO₃^-营养,且在较高浓度下,增铵营养处理具有更强的吸收优势.与次敏感型莱州953和钝感型江东门相比,敏感型扬麦158不仅具有较强的NO₃^-和NH⁺吸收能力,而且具有最强的增铵营养吸收能力.增铵营养促进了扬麦158和莱州953对NO₃^-和NH⁺的吸收,但在一定程度上抑制了江东门对NO₃^-的吸收.与NO₃^-营养及NH⁺营养相比,增铵营养显著提高了扬麦158和莱州953的全株、地上部N积累量和叶片光合速率,而对江东门影响较小因此,增铵营养促进了植株的N吸收,提高了N积累和光合速率,从而促进了小麦生长     

作物增铵营养的生理效应

阐述了作物对不同形态氮素营养的生长反应及其生理基础,增铵营养促进作物生长和氮素利用的可能机制,以及实现作物增铵营养的前景与技术途径。     

形态对不同小麦基因型氮素吸收的光合作用的影响

利用水培试验,研究了3个小麦基因型对不同形态N素吸收和积累的差异,结果表明,在不同N浓度优势,与次敏感型莱州953和钝感到江东门相比,敏感型扬麦158不仅具有较强的NO3^-和NH4^ 吸收能力,而且具有最强的增铵营养吸收能力,增铵营养促进了扬麦158和莱州953对NO3^-和NH4^ 的吸收,但在一定程度上抑制了江东门对NO3^-的吸收,与NO3^-营养及NH4^ 营养相比,增铵营养显著提高了杨表158和莱州953的全株、地上部N积累量和叶片合速率,而对江东门影响较小,因此,增铵营养促进了植株的N吸收,提高了N积累和光合速率,从而促进了小麦生长。     

不同生育时期增铵营养对小麦生长及氮素利用的影响

通过两年的田间试验,研究了不同生育时期增铵营养(EAN)对小麦生长和氮素利用的影响.结果表明,田间增铵营养促进了小麦植株的生长和氮素吸收.其中基肥、分蘖期、拔节期EAN提高了小麦的干物质积累量、地上部氮积累量、有效穗数、叶面积指数、叶片叶绿素含量以及小麦的籽粒产量;孕穗期EAN效果不明显;全生育期EAN在促进生长方面的效果并无明显优势,但可有效降低土壤N₃^--N的淋溶损失.与对照相比,EAN提高了氮流效率和吸收效率,但以拔节前处理最为明显.拔节期EAN主要在于改善后期的叶片光合性能,并促进同化物向籽粒的再分配,而基肥和分蘖期EAN主要在于提高有效分蘖数.     

不同生育时期增铵营养对小麦生长及氮素利用的影响

通过两年的田间试验,研究了不同生育时期增铵营养(EAN)对小麦生长和氮素利用的影响．结果表明,田间增铵营养促进了小麦植株的生长和氮素吸收．其中基肥、分蘖期、拔节期EAN提高了小麦的干物质积累量、地上部氮积累量、有效穗数、叶面积指数、叶片叶绿素含量以及小麦的籽粒产量;孕穗期EAN效果不明显;全生育期EAN在促进生长方面的效果并无明显优势,但可有效降低土壤NO3^--N的淋溶损失．与对照相比,EAN提高了氮流效率和吸收效率,但以拔节前处理最为明显．拔节期EAN主要在于改善后期的叶片光合性能,并促进同化物向籽粒的再分配,而基肥和分蘖期EAN主要在于提高有效分蘖数．     

铜和营养缺失对海州香薷两个种群生长、耐性及矿质营养吸收的差异影响

以来自铜矿区(CS)和非矿区(UCS)两个海州香薷种群为对象,通过室内水培实验,分析了两种群幼苗在铜及营养缺失胁迫下植物生长、铜富集及矿质营养含量的差异.结果显示,铜、低营养胁迫及其相互作用对非矿区种群生长具有明显的抑制作用,而对矿区种群的影响则远比非矿区种群小,且较低铜浓度(25μmol/L Cu)明显促进了矿区种群的生长;从耐性指数结果看,矿区种群铜耐性指数和营养胁迫耐性指数均高于非矿区种群.这表明矿区种群不仅进化为铜耐受种群,同时也进化成营养胁迫耐受种群.低营养胁迫明显促进了植物对铜的吸收和运转,如在低营养胁迫和25 μmol/L Cu复合处理下,矿区种群根铜含量约为单一铜处理的25倍,非矿区种群是单一铜处理5倍多.低营养胁迫和过量铜显著减少了非矿区种群矿质营养元素如P,Mg,K和Mn的吸收积累,而矿区种群则仍然能保持相对稳定;在铜和营养缺失复合作用下,两个种群矿质营养除Ca和部分Fe外,均显著减少,但矿区种群减少程度明显比非矿区种群小.这些结果表明,矿区种群在胁迫条件下具有保持营养相对稳定和平衡的能力,这种能力使其能在高铜污染和营养缺乏的土壤中正常生长和定居.     

增铵营养对小麦光合作用及硝酸还原酶和谷氨酰胺合成酶的影响

采用水培试验研究不同形态氮营养(NH4^+／NO3^-分别为0／100、50／50和100／0)对小麦光合作用及氮代谢关键酶活性的影响．结果表明,增铵营养较单—NO₃^-营养显著提高叶片叶绿素含量、净光合速率及可溶性糖含量,叶、根中可溶性蛋白质含量和叶片硝酸还原酶活性。而对谷铵酰胺合成酶活性影响较小．与单—NO₃^-营养相比。增氨营养下叶片较高的可溶性糖含量与净光合速率的提高相关。而维持较高的叶片和根系可溶性糖／可溶性蛋白质比例有利于氮同化和生长．因此,增铵营养下提高了叶片净光合速率、可溶性糖含量和硝酸还原酶活性。维持较高叶片和根系可溶性糖／蛋白质比例。从而促进小麦生长．     

不同氮效率水稻全生育期内对增硝营养的响应及其生理机制

通过添加硝化抑制剂（二氰胺,DCD）来控制硝化作用的水培试验方法,研究了氮高效水稻品种南光和氮低效水稻品种ELIO的籽粒产量对增硝营养（NH4＋∶NO3-比例为100∶0和75∶25）的响应,同时从产量构成、不同生育时期水稻生长、氮素吸收和同化4个方面研究了造成其产量差异的生理机制。结果表明：增NO3-营养可以显著促进氮高效水稻品种南光的生长,从而使其籽粒产量水平提高21%,而对氮低效水稻品种ELIO的籽粒产量没有显著影响。进一步分析表明：在增NO3-营养条件下,南光的穗粒数增加了25%,结实率增加了16%,而氮低效水稻品种ELIO的结实率和穗粒数在两种营养条件下没有显著变化;增NO3-营养可以促进南光对氮素的吸收,使其在苗期、分蘖盛期、齐穗期和成熟期对氮素的吸收量平均增加了36%,进而促进了其生长,干物质积累量在四个生育时期平均增加了30%;南光叶片硝酸还原酶和根系谷氨酰胺合成酶的活力在增硝营养条件下分别增加了100%和95%,说明增硝营养促进了南光对NH4＋和NO3-的同化利用。与氮低效水稻品种（ELIO）相比,氮高效水稻品种（南光）对增硝营养表现出较强的生理响应。     

无机营养对春小麦抗旱适应性的影响

本文研究了无机营养对春小麦一些抗旱适应性的影响,主要包括:渗透调节的大小和变化过程、可溶性糖的积累、脯氨酸的积累、叶片导度的变化、离体叶片的失水速率、叶面积和耗水量的变化、根系生长和根/植冠值,并且分析了各个处理植株的水分利用效率(WUE)和产量的变异。认为,在干旱条件下,无机营养对于春小麦不同器官、不同生理功能,并不都具有一致的作用。有的利于提高植株的抗旱性,有的可以改变一些适应性产生的时间和发展过程,有的则不利于植株的抗旱性。通过综合分析,提出旱地施肥使作物增产的主要原因是,营养元素满足了作物生长所需,促进了根系发育,利于吸收水分、维持水分平衡和正常生理功能,但对作物自身的耐旱性并没有产生显著影响。     

天机营养对春小麦抗旱适应性的影响

本文研究了无机营养对春小麦一些抗旱适应性的影响,主要包括：渗透调节的大小和变化过程、可溶性糖的积累、脯氨酸的积累、叶片导度的变化、离体叶片的失水速率、叶面积和耗水量的变化、根系生长和根／植冠值,并且分析了各个处理植株的水分利用效率(WUE)和产量的变异。认为,在干旱条件下,无机营养对于春小麦不同器官、不同生理功能,并不都具有一致的作用。有的利于提高植株的抗旱性,有的可以改变一些适应性产生的时间和发展过程,有的则不利于植株的抗旱性。通过综合分析,提出旱地施肥使作物增产的主要原因是,营养元素满足了作物生长所需,促进了根系发育,利于吸收水分、维持水分平衡和正常生理功能,但对作物自身的耐旱性并没有产生显著影响。     

Applications of mineral nutrients to heavily N-fertilized Scots pine trees: Effects on arginine and mineral nutrient concentrations

The aim of the investigation was to study if improved nutrient status in Scots pine (Pinus sylvestris L) trees would be reflected in decreased concentrations of arginine in the needles. The studies trees had imbalanced mineral nutrient composition and elevated needle arginine concentrations caused by long-term fertilization with N. Concentrations of arginine and mineral nutrients in needles were followed over three consecutive years of additional fertilization with N alone or with P, K, Mg and micronutrients in combination with and without N.Analysis of needle mineral concentrations suggested that there were deficiencies only in K and Mg. The N concentration increased both in trees fertilized with N alone and in trees fertilized with N in combination with mineral nutrients. In the control treatment and in trees fertilized with mineral nutrients other than N the N concentration remained fairly constant. The highest Ca/N, K/N and P/N ratios were found in trees fertilized with mineral nutrients other than N while the lowest ratios were found in trees fertilized with N alone. Arginine concentrations in needles from trees fertilized with N alone remained at a high level throughout the experiment while arginine concentrations in trees given the other treatments decreased.The results show that the mineral nutrient balance can be improved with appropriate fertilization and that this improvement is reflected in decreasing arginine levels. Furthermore the study demonstrates that when N supply is reduced the arginine concentration also decreases also as an effect of reduced N supply per se. The study also indicates that arginine may be a better measure of the N status in pine trees than total N.     

Plant species diversity affects plant nutrient pools by affecting plant biomass and nutrient concentrations in high-nitrogen ecosystems

Plant species diversity affects plant nutrient pools, however, previous studies have not considered plant nutrient concentrations and biomass simultaneously. In this study, we conducted an experimental system with 90 microcosms simulating constructed wetlands (CWs). Four species were selected to set up a plant species richness gradient (1, 2, 3, 4 species) and fifteen species compositions. The plant biomass, plant N, phosphorus (P), potassium (K), calcium (Ca), and magnesium (Mg) concentrations and pools were analyzed. Results showed that, (1) plant species richness increased plant biomass, and the presence of Oenanthe javanicae increased while the presence of Reineckia carnea decreased plant biomass; (2) plant species richness only increased plant K and Mg concentrations of the communities and plant Mg concentration of the species, and the presence of O. Javanica increased while the presence of R. Japonicus decreased plant N and P concentrations of the communities; (3) plant species richness increased plant N, P, K, Ca, and Mg pools, and the presence of O. Javanica increased while the presence of R. Carnea decreased plant N, P, K, Ca and Mg pools; (4) the four-species mixture produced more biomass and nutrient pools than the corresponding highest specific species monocultures. In case the plant uptake can remove nutrients from CWs through harvesting, the results suggest that both nutrient concentrations and biomass must be considered when evaluating the accumulation of nutrients. Assembling plant communities with high species richness (four species) or certain species (such as O. Javanica) is recommended to remove more nutrients from CWs through harvesting.     

RETRACTED ARTICLE: CO<Subscript>2</Subscript> effects on plant nutrient concentration depend on plant functional group and available nitrogen: a meta-analysis

Elevated CO₂ is expected to lower plant nutrient concentrations via carbohydrate dilution and increased nutrient use efficiency. Elevated CO₂ consistently lowers plant foliar nitrogen, but there is no consensus on CO₂ effects across the range of plant nutrients. We used meta-analysis to quantify elevated CO₂ effects on leaf, stem, root, and seed concentrations of B, Ca, Cu, Fe, K, Mg, Mn, P, S, and Zn among four plant functional groups and two levels of N fertilization. CO₂ effects on plant nutrient concentration depended on the nutrient, plant group, tissue, and N status. CO₂ reduced B, Cu, Fe, and Mg, but increased Mn concentration in the leaves of N₂ fixers. Elevated CO₂ increased Cu, Fe, and Zn, but lowered Mn concentration in grass leaves. Tree leaf responses were strongly related to N status: CO₂ significantly decreased Cu, Fe, Mg, and S at high N, but only Fe at low N. Elevated CO₂ decreased Mg and Zn in crop leaves grown with high N, and Mn at low N. Nutrient concentrations in crop roots were not affected by CO₂ enrichment, but CO₂ decreased Ca, K, Mg and P in tree roots. Crop seeds had lower S under elevated CO₂. We also tested the validity of a “dilution model.” CO₂ reduced the concentration of plant nutrients 6.6% across nutrients and plant groups, but the reduction is less than expected (18.4%) from carbohydrate accumulation alone. We found that elevated CO₂ impacts plant nutrient status differently among the nutrient elements, plant functional groups, and among plant tissues. Our synthesis suggests that differences between plant groups and plant organs, N status, and differences in nutrient chemistry in soils preclude a universal hypothesis strictly related to carbohydrate dilution regarding plant nutrient response to elevated CO₂.     

Nutrient balance and P,K, Ca,Mg, S and B accumulation in a Norway spruce stand following ammonium sulphate application,fertigation, irrigation,drought and N-free-fertilisation

The nutrient balance and above ground accumulation of macro nutrients, except for N, resulting from improved or deteriorated availability of water and nutrients in a 25 year old Norway spruce stand in SW Sweden is presented. The site and the productivity of the stand is typical for the area. Treatment include irrigation (I); artificial drought (D1); ammonium sulphate addition (NS); N-free-fertilisation (V) and irrigation with liquid fertilisers including a complete set of nutrients according to the Ingestad principle (IF). At start of the experiment the stand contained 86.5 t dry mass, 342 kg N, 33 kg P, 142 kg K, 172 kg Ca, 36 kg Mg and 34 kg S ha^-1. Enhanced accumulation vs control of S was seen in the NS and IF treatments. In the V and IF treatments P accumulation was 7–9 times higher and Ca and Mg, 2–4 times higher compared to the control. K accumulation was increased for the IF treatment. B that accumulated in the needles was decreased in the NS and D1 treatments and increased in the IF and V treatments, as compared to the control. The gross accumulation of nutrients relative to the amounts added was in the IF and V treatments 56 and 47% for P, 40 and 64% for K, 40 and 24% for Mg and, 22 and 8% for S, respectively. We conclude that application with N-free fertilizer, Skogvital (V), including macro nutrients and essential micro nutrients, results in a fast and efficient accumulation above ground of P, K, Ca, Mg and B. The treatment is efficient when aiming at restoring nutrient imbalances in Norway spruce. Application with ammonium sulphate at a rate of 5–6 times higher than the current deposition of N and S did not lead to decreased accumulation above ground of any of the macro nutrients P, K, Ca or Mg. The accumulation of B, however, was significantly reduced. Results from this and other studies indicate that today, N alone, generally is a growth limiting nutrient for Norway spruce in Southern Sweden.     

铜处理对菠菜幼苗矿质营养吸收和细胞超微结构的影响

土壤重金属积累严重影响植物生长和生态系统平衡,探寻植物对重金属的耐性机理尤为重要.菠菜可能具有一定的耐铜性,但Cu对其矿质元素吸收、细胞超微结构等方面的耐性机理尚不明确.本研究以菠菜幼苗为研究对象,通过盆栽试验,探究不同浓度铜处理对菠菜幼苗生长、矿质元素吸收、叶片细胞超微结构等指标的影响.结果表明: 100 mg·L^-1 CuSO₄处理浓度时,菠菜幼苗根Cu²⁺积累量小于地上部,其根系生长量增加,地上部生长量稍有下降,继续增加铜处理浓度,植物体各器官生长参数均呈下降趋势.低浓度铜处理时(<400 mg·L^-1 CuSO₄),菠菜幼苗叶N、K、Ca、Mg、Fe含量增加,P含量减少;根N、P、K含量减少,Ca、Mg、Fe含量增加;叶片细胞内各细胞器清晰可见,基粒片层排列仍较为整齐,叶绿体内外膜完整.高浓度铜处理时(>600 mg·L^-1 CuSO₄),菠菜幼苗叶N含量增加,P、K、Ca、Mg、Fe含量减少;根N、P、K、Ca、Mg、Fe含量均减少;叶片细胞内叶绿体变圆,叶绿体膜变薄,基质、基粒片层变少,层堆积高度下降,细胞核解体,液泡、细胞壁中有黑色小点分布,可能是大量Cu²⁺聚集导致细胞内膨压增大所致.低浓度铜处理并未对菠菜幼苗的生长生理特性产生明显的负面影响,而高浓度铜处理并未终止菠菜幼苗的生长.说明菠菜幼苗具有一定的耐铜性.     

追施氮肥对桉树各器官养分浓度及贮量的影响

采用田间定位试验的方法,研究了追施氮肥对2年生桉树各器官生物量积累及养分浓度与贮量的影响.结果表明:与对照相比,追施氮肥使桉树生物量增加24.2%,其中树枝增幅最高,为38.2%,树叶最少.追施氮肥显著促进了桉树对养分的吸收,其增幅顺序为PKNMgCaSi;叶片中N、P、Mg、Si含量最高,K在树干中的贮量最大,树枝部位的养分浓度与贮量增加最为显著.桉树N、P、K养分以内循环为主,叶片凋落前分别有73.8%、79.1%和72.9%的N、P、K养分被转移到植株体内,其外循环量仅为全树贮量的14.8%、7.7%和8.6%;Ca、Mg、Si养分则以外循环方式为主,其中Ca最明显,树叶中89.2%的Ca随叶片凋落,其外循环通量占全树Ca总贮量的25.9%.     

Seasonal Dynamics of the Accumulation, Distribution and Redistribution of Dry Matter and Mineral Nutrients in a Weedy Species of Gladiolus (Gladiolus caryophyllaceus)

The seasonal dynamics of the accumulation, distribution andredistribution of dry matter and 12 mineral nutrients by a weedyspecies of gladiolus (Gladiolus caryophyllaceus) were studiedat Perth, Western Australia, where it has colonized the nutrient-poorsandy soils. Parent corms sprouted in autumn, and the plantshad completed their growth cycle by early summer. The maturereplacement corm had 15-25% of the plant's P, Ca, Na, Zn andCu, 5-15% of its K, N, Cl, Mg, S and dry matter, and < 5%of its Fe and Mn. Seeds had 26% of the plant's dry matter, 60%of its N and P, 21-33% of its S, Mg, Cu and K, 5-20% of itsFe, Mn and Zn, and < 5% of its Ca and Na. The mature vegetativeshoot had 47% of the plant's dry matter and over 40% of eachnutrient, except for N, P and Cu. Phosphorus, K and N were redistributedfrom the parent corm with over 85% efficiency, S, Mg, Zn andCu with 60-70% efficiency, but there was < 10% redistributionof Ca, Na, Cl, Fe and Mn. The efficiency of redistribution fromthe leafy shoot was over 70% for N and P, 29-52% for K, Mg andCu, 16-20% for S, Zn and Cl, but negligible for Ca, Na, Fe andMn. Redistribution from the shoot could have provided the replacementcorm and seeds with 53-98% of their Cu, Mg, N, P and K, and29-38% of their S, Zn and dry matter. Seeds contained over 60%of each nutrient in a capsule, except for Ca, Na and Fe. Redistributionfrom the capsule walls could have provided 13-19% of the P,Cu and Zn, and 3-7% of the N, K, Mg and dry matter accumulatedby seeds. Each plant produced an average of 520 seeds. Removalof flowers and buds at first anthesis resulted in a larger replacementcorm containing a greater quantity of most nutrients, indicatingcompetition between the replacement corm and seeds for nutrients.Redistribution from parent to replacement cormlets in the absenceof shoot and root development was high, with over 50% of thedry matter and each nutrient, except for Ca, being transferred.Concentration of nutrients were low in all organs of G. caryophyllaceus,especially the replacement corm. It was concluded that the effectiveredistribution of key nutrients, such as N and P, to reproductivestructures and tolerance of low internal concentrations of nutrientscontribute to the capacity of G. caryophyllaceus to colonizeand persist on infertile soils.Copyright 1993, 1999 AcademicPress Gladiolus caryophyllaceus, corm, distribution, dry matter, gladiolus, mineral nutrients, nutrient accumulation, nutrient redistribution, seasonal growth, weed     

The Chemical Elements of Planted Forest of Pinus tabnlaeformis

The concentration of chemical elements in the edifieator Pinus tabulaeformis of 28- aged pine plantation from leaves, small branches(< 1.5 cm diameter), branches (> 1.5 cm diameter) to trunk graduately declined. C was the most abundant element in pine plantation. The N content was more abundant in leaves, Ca, K, Mg. P were plentiful as well. The mineral content in small root (<2 cm diameter) was richer than that in root (>2 cm diameter). There were plenty of C, N, P. and Ca in the shrub layer, especially in the leaves of shrubs. The concentration of mineral elements in aboveground part of grasses was obviously lower than those in the leaves of shrubs. Comparing chemical elements of litter with those in living leaves and branches, the contents of Fe and A1 in the litter increased, the other elements more or less decreased. The accumulation of C in different layer of plantation except litter reached 22.43 t/ha, the accumulation amounts of Ca and N ranged 157–161 kg/ha. The retention of C in pine plantation was the highest among the elements, Ca retained in tree layer and N, K in shrub layer showed very plentiful also. Ca returned by litter was more than the others except C. The efficiency of P and K uptaked by plant from soil was high. To use the P and K fertilizers will accelerate the growth of Pine plantation.