小麦品种氮利用效率的评价指标及其氮营养特性研究

选用40个不同小麦基因型在2个不同生态区进行田间试验,系统地分析了不同N利用效率指标的基因型与环境差异及其与N营养特性的关系．结果表明,N收获指数在基因型间的变异相对较小。其余指标受品种影响较大．N吸收效率、氮流效率受环境影响较小,其余指标受环境影响较大．所有指标均受基因型和环境互作的显著影响．氮流效率与N吸收效率、植株N生产力和土壤N生产力极显著相关,综合反映了植株干物质生产和N利用状况,可作为一个有效的N利用效率评价指标．指出提高开花后,N同化量和转运量有利于提高氮流效率．     

不同生活型被子植物功能性状与基因组大小的关系

基因组大小在被子植物物种之间存在着巨大的变异, 但目前对不同生活型被子植物功能性状与基因组大小的关系缺乏统一的认识。本研究基于被子植物245科2,226属11,215个物种的基因组大小数据, 探讨了不同生活型物种种子重量、最大植株高度和叶片氮、磷含量4个功能性状与基因组大小之间的关系。结果表明, 被子植物最大植株高度和种子重量与基因组大小间的关系在草本和木本植物中存在显著差异。草本植物最大植株高度与基因组大小的关系不显著, 但种子重量与其呈极显著的正相关关系。木本植物最大植株高度与基因组大小显著负相关, 但种子重量与其关系不显著。木本植物叶片氮含量与基因组大小呈显著正相关, 但其他生活型植物的叶片氮、磷含量与基因组大小均无显著相关性。本研究表明被子植物功能性状与基因组大小的相关性在不同生活型间存在差异, 这为深入研究植物多种功能性状和植物生活型与基因组大小的权衡关系在植物演化和生态适应中的作用提供了重要依据。     

高肥力土壤条件下不同基因型花生对氮素利用的差异

在桶栽条件下,利用¹⁵N示踪技术,选用20个基因型花生为供试材料,研究了高肥力土壤条件下不同基因型花生对氮素利用的差异.结果表明:高肥力土壤条件下花生氮素营养以土壤氮为主,根瘤固氮次之,肥料氮最低.不同基因型间花生对全氮、肥料氮、土壤氮和根瘤固氮的吸收和积累均存在显著差异,基因型间遗传变异以根瘤固氮最大,肥料氮和土壤氮相当.氮素荚果生产效率和氮肥利用率基因型间差异显著,最高值分别为最低值的3.6和2.1倍.全氮、肥料氮、土壤氮和根瘤固氮的氮素收获指数基因型间均存在显著遗传变异,且以根瘤固氮的氮素收获指数基因型间遗传变异最大.花生荚果产量与不同氮源氮素积累量及氮素收获指数、氮素荚果生产效率和氮肥利用率呈显著或极显著正相关.依据花生对不同氮源氮素吸收积累和荚果产量筛选出全氮高积累高产型、肥料氮高积累高产型、土壤氮高积累高产型和根瘤固氮高积累高产型四大类型花生,其中四大类型特征兼有的有4个花生基因型.     

烟草不同基因型耐低氮能力差异评价

以单株叶重及其氮素反应指数作为耐低氮能力的评价指标,分析了烟草种质资源的耐低氮能力以及单株叶重及其氮素反应指数与主要农艺性状间的相关关系。结果表明,不同施氮水平下多数农艺性状基因型间差异较大,在低氮水平下表现最大;和其他农艺性状相比,单株叶重在不同氮素水平间平均差异最大。不同施氮水平下,单株叶重均与最大叶叶面积、单株生物量呈显著或极显著正相关;单株叶重的氮素反应指数与单株叶重、生物量呈显著或极显著正相关,且低氮水平下单株叶重的氮素反应指数与上述性状间的相关性比中氮水平下更为密切。在供试的36个烟草品种中,永定400号、金烟6号、红花大金元、G80、Nc82等烟草种质具有较强的耐低氮能力,可以作为氮高效的烟草品种利用。     

小麦籽粒中植酸、戊聚糖含量及其与相关性状关系的研究

选用不同基因型小麦,测定了籽粒中植酸、蛋白质及戊聚糖的含量,并对其进行遗传相关分析,结果表明：(1)各性状在品种间存在显著性差异,且植酸的广义遗传力比较低;(2)植酸含量与蛋白质含量呈极显著的正相关,与戊聚糖呈极显著负相关。通过对参试的18个不同基因型小麦中植酸和戊聚糖含量进行聚类分析,可以将18个基因型小麦聚为四类,并初步认为豫麦47是参试品种中最适宜于用作饲用小麦。     

西方蜜蜂产浆量的动态遗传研究

应用条件和非条件遗传效应分析方法对3个西方蜜蜂(Apis mellifera L.)品种的蜂群产浆量、台浆量和台基接受率进行了发育遗传研究。结果表明：蜂群产浆量、台浆量在各个时期均存在显著或极显著的基因型方差,台基接受率在大部分时期存在显著或极显著的基因型方差,说明这3个性状主要由遗传因素决定。条件遗传分析发现,在某些无法检测到非条件方差的时期存在显著水平的条件方差,证明在产浆期的不同阶段,3个性状都有基因的新表达。同一性状不同时期的遗传相关分析表明：蜂群产浆量以及台浆量在各个时期均检测到显著或极显著的基因型相关,台基接受率在大多时期存在显著的基因型相关,表明控制产浆量和台浆量早期表现的遗传效应总是以相同的方式调节后期的表现,而台基接受率则不然。成对性状之间的相关研究表明：蜂群产浆量和台浆量之间在各个时期存在显著或极显著的遗传相关,说明2性状基因效应之间的协同作用是一致的,而蜂群产浆量和台基接受率之间在大多时期存在显著的遗传相关,但在一些时期没有相关,2性状之间的基因效应协同作用较差。     

施氮量对小麦氮磷钾养分吸收利用和产量的影响

高产条件下研究了不同施氮量对小麦植株氮、磷、钾养分吸收利用及籽粒产量的影响.结果表明,适量施氮可促进小麦植株对氮素的吸收与积累,较高的施氮量不利于起身期之后的氮素积累,致使成熟期小麦氮素积累量未能显著提高;与不施氮肥相比,施氮显著提高植株磷素积累量;随施氮量增加,植株磷素积累量增加不显著;施氮量增加促进小麦生育前期对钾素的吸收积累,在生育后期降低植株钾素的流失.随施氮量增加,籽粒氮素含量呈先增后降的趋势,氮素向籽粒的分配比例趋于降低,植株氮素利用效率无显著变化,氮素收获指数下降;不同施氮处理之间籽粒磷素含量和钾素含量无显著差异,施氮量增加,营养器官钾素含量、钾素积累量和钾素向叶片的分配比例均呈增加趋势;同时,磷素和钾素利用效率降低;不同施氮处理间,植株磷素、钾素收获指数无显著差异.籽粒产量随施氮量增加呈先增加后降低的趋势,以施氮195 kg/hm2的处理籽粒产量最高.     

水肥运筹对小麦旗叶光合特性及产量的影响

研究了不同灌水次数及等氮量不同施氮方式对优质强筋小麦品种郑麦9023旗叶净光合速率(Pn)、叶绿素荧光参数等光合性能及产量的影响。结果表明,旗叶Pn、PSⅡ的潜在活性(Fv／Fo)、PSⅡ的光化学最大效率(Fv／Fm)、光化学猝灭系数(qP)、非光化学猝灭系数(qN)及产量在不同灌水次数间的差异均达到显著或极显著水平,其中不灌水处理与灌水处理间的差异较大;在不同施氮处理问,氮肥全部基施与返青期追施(占40％)处理间植株旗叶的Pn、Fv／Fo、Fv／Fm、qP和qN差异不大,但两处理的上述光合参数及产量均明显低于拔节期或孕穗期追施(40％)处理,表明拔节期或孕穗期追施氮肥有助于减缓旗叶光合功能的衰退,延长叶片功能期,提高植株的光合产物积累。研究结果还表明,水、氮运筹对Pn、叶绿素荧光参数及产量性状的调控存在显著的互作效应,其中以灌拔节水 孕穗水并于孕穗期追施氮肥(W2N4)处理组合表现最好。     

不同小麦品种氮效率与氮吸收对氮素供应的响应及生理机制

以具有典型特征的不同氮效率小麦品种为材料,研究了低氮和高氮条件下小麦的生物学性状、生理参数和氮同化代谢酶活性.结果表明:低氮条件下,不同氮效率小麦品种根系干质量、茎叶干质量、植株氮累积量基本上为氮高效品种>中效品种>低效品种.低氮条件下,氮吸收高效品种（冀97-6360）的根系活跃吸附面积、TTC还原力、叶片硝酸还原酶活性和叶片NO₃^-含量最大;生理高效品种(石新5418)具有较高的叶片亚硝酸还原酶活性和谷氨酰胺合成酶活性,较低的植株全氮含量、叶片NO₃^-含量和硝酸还原酶活性.低氮条件下植株氮利用效率与氮吸收系数显著相关.不同小麦品种在高氮条件下的生物学性状、生理参数和氮同化代谢酶活性与低氮条件下不尽一致.     

小麦糊化特性参数稳定性分析及其与其它品质性状关系的研究

通过测定黄淮麦区2年度3试点13个小麦区试品种糊化特性(RVA)参数及其它主要品质性状,研究了小麦RVA参数稳定性及其与其它主要品质性状间的关系.结果表明:基因型对峰值粘度、保持粘度、稀懈值、最终粘度、回升值起主导作用,环境对糊化温度和峰值时间影响较大.峰值粘度、保持粘度、最终粘度在品种间变幅较大,分别为2 055.50 cp～3 935.50 cp、1 046.42 cp～2 589.00 cp和2 412.00 cp～4 341.50 cp,峰值粘度、保持粘度、稀懈值的变异系数较高,分别为10.74 %、12.17 %、21.25 %.除峰值时间外,其它RVA参数品种间差异极显著.峰值粘度与保持粘度、稀懈值、最终粘度及回升值间极显著正相关.峰值粘度、保持粘度、最终粘度、回升值与蛋白质含量、湿面筋含量和Zeleny沉降值间极显著负相关.同时依据RVA参数对参试品种进行了聚类分析.峰值粘度可作为衡量小麦淀粉特性的最重要指标,由于品种间淀粉品质差异大,因此品种选育过程中应同时注重蛋白质和淀粉品质.     

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.     

QTL and QTL x environment effects on agronomic and nitrogen acquisition traits in rice

Agricultural environments deteriorate due to excess nitrogen application.Breeding for low nitrogen responsive genotypes can reduce soil nitrogen input.Rice genotypes respond variably to soil available nitrogen.The present study attempted quantification of genotype x nitrogen level interaction and mapping of quantitative trait loci (QTLs) associated with nitrogen use efficiency (NUE) and other associated agronomic traits.Twelve parameters were observed across a set of 82 double haploid (DH) lines derived from IR64/Azucena.Three nitrogen regimes namely,native (0 kg/ha; no nitrogen applied),optimum (100 kg/ha) and high (200 kg/ha) replicated thrice were the environments.The parents and DH lines were significantly varying for all traits under different nitrogen regimes.All traits except plant height recorded significant genotype x environment interaction.Individual plant yield was positively correlated with nitrogen use efficiency and nitrogen uptake.Sixteen QTLs were detected by composite interval mapping.Eleven QTLs showed significant QTL x environment interactions.On chromosome 3,seven QTLs were detected associated with nitrogen use,plant yield and associated traits.A QTL region between markers RZ678,RZ574 and RZ284 was associated with nitrogen use and yield.This chromosomal region was enriched with expressed gene sequences of known key nitrogen assimilation genes.     

不同小麦品种吸收利用氮素效率的差异及有关机理研究 Ⅰ.吸收和利用效率对产量的影响

用盆栽试验研究了１２个冬小麦品种（ＴｒｉｔｉｃｕｍａｅｓｔｉｖｕｍＬ．）在低、高氮条件下的籽粒产量差异,及吸收和利用氮素的效率对其影响。结果证明在低氮处理中吸收效率和利用效率（ＵｔＥＧ）的共同影响导致了产量差异,但利用效率的影响更大;高氮处理则主要是吸收效率的影响,利用效率的影响较小。研究还发现能高效吸收或利用氮素的品种多为矮秆品种,因此高产品种多为矮秆。在低氮处理中的高产品种具有高效吸收或高效利用的特点;高氮处理中的高产品种主要具有高效吸收的特点,利用效率并不高。在所有品种中,只有低氮条件下的太核５０２５兼具高效吸收和高效利用的优点,说明多数品种的吸收、利用效率有待提高,以充分发挥氮肥的增产效果,达到少施氮肥多增产和保护环境的目的     

Effects of level,time, and splitting of urea on the yield of irrigated direct seeded rice

Summary To determine effects of level and time of application of urea on grain yields, components of grain yield, and nitrogen use efficiency by irrigated direct seeded rice (Oryza sativa L. var. IR 298-12-1-1-1), three field experiments were conducted at the Gezira Agricultural Research Station during the period 1976–78. The treatments included the factorial combination of three levels of nitrogen as urea (0,75 and 150 kg N/ha) two or three splits, and three times of topdressing of urea (early season application, 10 days after rice emergence, DRE; maximum tillering stage, 40 DRE; and panicle initiation stage, 75 DRE).Without application of nitrogen, grain yields averaged 1.5 t/ha. The yields averaged for rate and time of split significantly increased with increase in nitrogen applied to 3.9 and 5.0 t/ha, but nitrogen use efficiency (kg rice/kg N) decreased from 31 to 23 with the application of 75 and 150 kg N/ha respectively.As compared to other treatments of time of urea application, topdressing of urea at maximum tillering and panicle initiation stages significantly improved nitrogen use efficiency by promoting production of more panicles per unit land area, and increasing grain weight. Three splits were no better than the two splits given at maximum tillering and panicle initiation stages.     

Identification and characterization of quantitative trait loci for grain yield and its components under different nitrogen fertilization levels in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

A set of rice (Oryza sativa L.) recombinant inbred lines from a cross between Zhenshan 97 (indica) and HR5 (indica) was planted for four different growing seasons in two locations at three nitrogen (N) fertilization levels (N300, 300 kg urea/ha; N150, 150 kg urea/ha; and N0, 0 kg urea/ha). Grain yield and its components were evaluated, including grain yield per plant (GYPP), panicle number per plant (PNPP), grain number per panicle (GNPP), filled grains per panicle (FGPP), spikelet fertility percentage (SFP) and 100-grain weight (HGW). Correlation and path analysis indicated that SFP had the greatest contribution to GYPP at the N300 and N150 levels, but FGPP contributed the most to GYPP at the N0 level. Quantitative trait loci (QTL) were mapped based on a mixed linear model; genetic components (main effects, epistatic effects and QTL-by-environment interactions) were estimated separately. Six to 15 QTL with main effects were detected for each trait except SFP. Clusters of main-effect QTL associated with PNPP, GNPP, SFP and HGW were observed in regions on chromosomes 1, 2, 3, 5, 7 and 10. The main-effect QTL (qGYPP-4b and qGNPP-12) were only detected at the N0 level and explained 10.9 and 10.2% of the total phenotypic variation, respectively. A total of 33 digenic interactions among grain yield and its components were also identified. The identification of genomic regions associated with yield and its components at different nitrogen levels will be useful in marker-assisted selection for improving the nitrogen use efficiency of rice.     

The effect of Rhizobium inoculation and nitrogen fertiliser on nitrogen fixation and seed yield of dry beans (Phaseolus vulgaris)

The potential benefit to be derived from seed inoculation of Phaseolus vulgaris beans with effective strains of Rhizobium phaseoli, was investigated in field experiments over three years on a site low in soil nitrogen and lacking indigenous effective strains of R. phaseoli. Inoculation with R. phaseoli (strain RCR 3644) produced significant increases in nodulation, nitrogenase activity and plant growth in all experiments. In trials in 1978 and 1979, with cv. Seafarer, inoculation, in the absence of nitrogen fertiliser doubled seed yields. In 1978, the seed yields from inoculated beans without nitrogen fertiliser (1–6 t/ha) were not significantly different from those obtained with uninoculated beans receiving the optimum nitrogen fertiliser treatment of 120 kg N/ha (1–75 t/ha). In 1979, with lower rainfall favouring more efficient utilisation of nitrogen fertiliser, inoculation gave seed yields (1–88 t/ha) equivalent to those obtained with 60 kg N/ha (1–70 t/ha) but significantly less than with 120 kg N/ha (2–88 t/ha). More precise estimates from nitrogen response curves showed that inoculation supplied the fertiliser equivalent of 105 and 70 kg N/ha in 1978 and 1979 respectively. In both years, significant benefits were also obtained by the combination of inoculation and nitrogen fertiliser. In a separate experiment in 1979, with four R. phaseoli strains inoculated onto eight bean cultivars, three were highly effective nitrogen fixers on all cultivars. Two strains (RCR 3644 and NVRS 963A) each increased mean yields, in the absence of nitrogen fertiliser, from 1–39 t/ha uninoculated to c. 2–5 t/ha inoculated whilst strain RCR 3622 was outstanding with a mean yield of 3-0 t/ha. An analysis of the nitrogen content of seed showed that gains from nitrogen fixation were 37–57 kg N/ha/growing cycle for the combination RCR 3644 with cv. Seafarer. However, 106 kg N/ha/growing cycle was recorded for the combination RCR 3622 and cv. Aurora.     

Comparison of isotope techniques and non-nodulating isolines to study the effect of ammonium fertilization on dinitrogen fixation in soybean,Glycine max

Summary Two experiments were carried out with two nodulating and non-nodulating soybean isolines, with three different levels of N as (¹⁵NH₄)₂SO₄ at the equivalent of 0, 25 and 50 kg N/ha. In the first experiment three seeds were sown in each pot and the plants harvested at 35, 55 and 75 days. In the second experiment only one seed was sown per pot and harvested at 75 days.Isotope dilution technique and in certain cases natural isotope variation (¹⁵N) was used to determine directly the origin of nitrogen in the plant, whether from soil, fertilizer or biological N₂-fixation. The use of nodulating and non-nodulating isolines enabled comparison with the classical method of estimating N₂-fixation by difference from total plant N. Results at the 75 day harvest were similar for either method, but at the earlier harvests, particularly at 35 days, the total-N method was inadequate. The isotope method appeared more sensitive while the total-N method suffered from greater variability with correspondingly high standard errors and significant differences.It was found that by the 35 and 55 day harvests hardly any N₂-fixation had taken place, plant nitrogen being almost entirely derived from soil or fertilizer N. Plants in competition used up soil fertilizer N more rapidly, thus stimulating symbiotic nitrogen fixation. When only one plant was grown in each pot it had a greater proportion of N derived from soil or fertilizer, and less N derived from fixation. In general the¹⁵N data showed that only about 25% of the applied fertilizer N was absorbed by the plant.The nodulating isoline absorbed more N than the non-nodulating plants. This suggests a possible synergistic effect of N₂-fixation on N derived from other sources, giving an increase in total-N content of nudulated plants. The N derived from N₂-fixation was scarcely detectable in the roots but appeared to be translocated almost entirely to shoots and pods.With 25 kg N/ha the greater proportion of the nitrogen in the pods was derived from N₂-fixation. Even with 50 kg N/ha the nitrogen in the pods derived from fixation remained high, that being derived from fertilizer being less than 15%. About 80% of the nitrogen in the nodules was due to fixation.In the present experiment the application of 25 kg N/ha appeared sufficient to give maximum N absorption by both isolines. At this level symbiotic fixation by Rhizobium remained high in nodulating plants, while the proportion of total N due to fixation was reduced with 50 kg N/ha.UNDP/IAEA Project BRA 78/006.     

Effect of nitrogen application on flowering and yield of eggplant (Solanum melongena L.)

Effect of nitrogen application on number of flowers per plant, number of different types of flowers per plant, length of style, number of fruits per plant and fruit yield/ha of eggplant was investigated under controlled greenhouse conditions. Nitrogen was supplied at 50, 75, 100, 125, 150, 175 and 200 kg N/ha with one control (no nitrogen) treatment. Nitrogen supplied at 200 kg N/ha gave best results and significantly produced the highest number of flowers per plant, fruits per plant and yield (32.24 ton/ha) over control plants. Nitrogen failed to influence style length and type of flowers i.e. long, medium, pseudo-short and short styled flowers. Nitrogen application at 150 and 175 kg N/ha showed comparable results with nitrogen applied at 200 kg N/ha.     

Nitrogen fixation (N-15 dilution) with soybeans under Thai field conditions. IV. Effect of N addition and Bradyrhizobium japonicum inoculation in soils with indigenous B. japonicum populations

The effects of Bradyrhizobium japonicum inoculation and pre-plant additions of N fertilizer on soybean ( Glycine max L. Merrill) yields and levels of N₂ fixation were studied under field conditions at two sites in Thailand. Bacterial inoculants were composed of B. japonicum strains selected for high N₂ fixation levels in Thai soils. Nitrogen fertilizer addition rates used were from 0 to 250 kg N/ha in 50 kg N/ha increments. At the Chiang Mai site in northern Thailand, bacterial inoculation increased nodule weights on plants receiving 100 kg N/ha or less. Increases in nodule parameters due to inoculation were evident at 45 d after planting (DAP) but disappeared by 60 DAP. Addition of N fertilizers decreased the incidence of nodulation and sap ureide contents and decreased the contribution of N₂ fixation to the N content of plants at maturity as measured by N-15 isotope dilution methods. At the Kampang Saen site in central Thailand, bacterial inoculation had significant positive effects on nodule numbers and weights, ARA, sap ureide contents and levels of N₂ fixed as measured by N-15 isotope dilution methods. Addition of N fertilizers at this site also reduced the effectiveness of N₂-fixing symbioses. It was concluded that small additions of N fertilizer added before planting did not significantly decrease N₂ fixation levels, but did have a significant positive effect on plant growth. Larger N additions would reduce N₂ fixation levels in excess of the benefits of adding more N in chemical form.     

Field evaluation of N2-fixation and N-utilization by phaseolus bean varieties determined by15N isotope dilution*

Summary Differences in N₂-fixation byPhaseolus vulgaris bean cultivars were successfully evaluated in the field using¹⁵N isotope dilution technique with a non-fixing test crop of a different species (wheat). The Phaseolus cultivars could have been similarly ranked for N₂-fixation capacity from either seed yield or total nitrogen yield, but the isotope method provided a direct measure of N₂-fixation and made it possible to estimate the proportion of fixed to total nitrogen in the crop and in plant parts. Amounts of nitrogen fixed varied between 24.59 kg N/ha for the 60-day cultivar Goiano precoce to 64.91 kg N/ha for the 90-day cultivar Carioca. The per cent of plant nitrogen due to fixation was 57–68% for the 90-day cultivars and 37% for Goiano precoce (60-day cultivar). Fertilizer utilization was 17–30% of a 20 kg N/ha fertilizer application. 100 kg N/ha fertilizer application decreased N₂-fixation without suppressing it totally. Differences in yield between the highest yielding (Carioca) and the lowest (Moruna) 90-day cultivars were also due apparently to varietal differences in efficiency of conversion of nitrogen to economic matteri.e. seed, as well as to differences in capacity of genotypes for N₂-fixation. The work described here was in part supported by IAEA Research Contract No. RC/2084 UNDP/IAEA Project BRA/78/006