喷洒氯化钾对油菜植株硝酸盐再利用的影响

从植物体本身着手研究植物氮素高效利用的机理与途径,这是近几年来植物氮素营养研究的热点之一,而调动植物液泡中的硝酸盐使之得到更高程度的再利用,这是提高植物氮素利用效率和降低植物体内硝酸盐含量的途径之一。试验采用土培试验,研究叶面喷施质量分数为1%的氯化钾溶液对油菜角果初期和收获期植株硝酸盐累积再利用的影响,以喷施质量分数为1.17%的硫酸钾溶液(要求氯化钾和硫酸钾溶液中钾离子的物质的量浓度相同)和清水作为对照,在开花后期开始喷施,连续隔日喷洒15天,喷施部位在茎和叶,重点喷洒叶的背面,尽量不喷施至叶柄,于角果初期和收获期采样。结果表明,喷施氯化钾溶液能显著降低油菜角果初期和收获期茎、叶、根硝酸盐含量和植株硝酸盐总量,促进硝酸盐再利用;可以增强角果初期叶片硝酸还原酶的活性;能增加收获期干物质累积量,但不影响角果初期干物质累积量。     

镉对油菜幼苗生长及微量元素含量的影响

通过营养液培养,重点研究了不同浓度镉（Cd）胁迫下,中双9号冬油菜（Brassica napus L.）幼苗体内生理生化及微量元素（Fe、Mn、Zn、Cu）含量的变化特征,目的是进一步阐明Cd胁迫对油菜生长产生毒害的作用机理。结果发现,Cd胁迫显著抑制了油菜幼苗的生长,植株根系和地上部干重随着Cd浓度的升高而显著降低;油菜幼苗叶片中光合色素含量也随着Cd浓度的升高而显著降低;油菜幼苗根系和地上部4种微量元素浓度也随着Cd浓度的升高发生了显著变化;同时,油菜幼苗体内抗氧化酶（SOD、POD和CAT）活性随着Cd浓度的升高表现出先显著升高后显著降低的趋势。这些结果表明,外源Cd胁迫通过降低油菜幼苗光合色素含量、抑制植株光合作用,引起幼苗体内养分代谢紊乱,诱导产生氧化胁迫等抑制了油菜幼苗的生长。研究还发现,中双9号油菜幼苗地上部Cd浓度和Cd富集量显著低于根系,中双9号应该属于低吸收Cd的冬油菜品种。     

利用小孢子胚离体培养筛选抗除草剂的油菜

选用4个甘蓝型油菜（Brassica napus L．）F、（7039，7040，282和5102）为小孢子培养供体材料，分别对小孢子胚在含草甘膦和盖草能的培养基上进行培养，以筛选出抗草甘膦和抗盖草能的胚状体，进而获得再生植株。其中，基因型7039和7040用于草甘膦筛选，282和5102用于盖草能的筛选。选取子叶期胚状体，在含0．006％的草甘膦及0．01％和0．02％盖草能的MS-2培养基上培养2周，不抗草甘膦和小抗盖草能的胚状体2周内变褐死去，抗草甘膦和抗盖草能的胚状体转绿。随后转绿胚状体转移至正常MS-2培养基中继续培养，直至获得再生植株。再生植株喷施0．25％的草甘膦液表明均抗草甘膦；而对植株喷施0．05％的盖草能液时，0．02％筛选出的植株大部分为抗盖草能，而0．01％筛选出的植株却大部分死去，表明用0．02％浓度筛选抗盖草能植株的方法更有效。用170mg／L秋水仙碱直接处理再生植株20和30h，染色体加倍率分别达到了34％和52％。     

Phosphorus Efficiency of Winter Canola Cultivars and Rhizosphere Properties in Rhizobox Technique

Production of oilseed crops requires balanced fertilization, while environmental problems of applied fertilizers must be considered. We evaluated seven winter canola cultivars (Brassica napus L.) for their relative efficiency to use or acquire phosphorus (P) under deficient and sufficient conditions. Average root mean diameter (RMD), total root length (RL) and root surface area (RA), of plants were measured as well as rhizosphere properties in rhizobox technique. Water-soluble P (WSP) and phosphatase activity of treatments containing plant were higher than control. WSP increased by 2.86 mg kg^?1 soil in Gabriela and 2.63 mg kg^?1 soil in Elvis at P deficient condition, compared to the control soil. The Olsen extractable P of the treatments decreased compared to control. Variations in total dry weights of cultivars were mainly explained by the differences in P solubilizing bacteria (PSB) population, pH, and phosphatase activity. The responsible mechanism for the P efficient (PE) cultivars can be higher P uptake through larger root and changes in rhizosphere properties.     

The effect of co‐composted cabbage and ground phosphate rock on the early growth and P uptake of oilseed rape and perennial ryegrass

Phosphorus (P) availability to crops in organic systems can be a major issue, with the use of readily available forms often restricted. One product that can be used in organically managed systems, that is also relatively easily accessible to growers, is phosphate rock, although its solubility and therefore crop availability is often poor. One possible approach to improve this situation is co‐composting phosphate rock with selected organic waste materials. Various ratios of phosphate rock and cabbage (Brassica oleracea L.) residues were co‐composted and the products tested at different rates of application. The effects were assessed over 12 weeks using oilseed rape (Brassica napus L.) and perennial ryegrass (Lolium perenne L.) as bioassay crops in a pot experiment. At harvest, estimates of P derived from cabbage and phosphate rock for the lowest of two rates of compost were ≈ 2 and 10 mg P pot^–1 for oilseed rape, compared to 5 and 2 mg P pot^–1 for perennial ryegrass, respectively. Roots tended to have higher P concentrations than shoots. The crops showed differences in their abilities to access various P sources, with oilseed rape effectively taking P from phosphate rock, whereas perennial ryegrass was more effective at accessing cabbage‐derived P (the main substrate in the compost). Oilseed rape was able to take up 20% of the total P applied as phosphate rock, whereas perennial ryegrass took up less than 5% of the total P applied from this material. Both pre‐ and post‐application solubilisation/transformation mechanisms were involved in supplying plant‐available P. Quantifying the relative contribution from individual P sources remains problematic even within this relatively simple system.     

Effects of Boron and Calcium Supply on Calcium Fractionation in Plants and Suspension Cells of Rape Cultivars with Different Boron Efficiency

Abstract

In this study, the effects of boron (B) and calcium (Ca) supply on Ca fractionation in suspension cells and different tissues of rape (Brassica napus L.) plants of two cultivars with different B efficiency were studied, with a purpose to elucidate the mechanism by which B affects Ca concentration in plants. As Ca supply increased in nutrient solution or culture medium, the relatively easily extractable Ca fractions, that is H₂O and 80% ethanol extractable Ca in leaves, 1 mol L^?1 NaCl extractable Ca in upper leaves, roots and suspension‐cell were significantly increased. While the recalcitrant Ca fractions extracted by 2% acetic acid, 0.6 mol L^?1 HCl and Ca in the residue were not affected by Ca supply. Increasing B supply in nutrient solution or culture media significantly reduced 1 mol L^?1NaCl extracted Ca in suspension cell and roots of both cultivars, which were most likely related to the alteration of cell wall metabolism. Calcium extracted by 2% acetic acid, 0.6 mol L^?1 HCl and Ca in residue in suspension‐cell and roots of B inefficient cultivar Bakow were easily improved by B deficiency as compared to that of B efficient cultivar Tezao16. Increasing of these relative recalcitrant Ca fractions was related to the different response of cultivars to the B deficiency, which may reflected different extent that Ca deposited in the two cultivars due to impaired membrane integrity under B deficiency. The effects of B on Ca concentration in lower and upper leaves of the two cultivars were quite different and were the integrated effects of B on Ca metabolism, Ca transport in plants and growth of certain organ. Increasing B supply increased total Ca concentration in upper leaves of Bakow and reduced that of Tezao16, which might relate to the different adaptability of the two cultivars to comparatively higher B supply.     

油菜硼高效的遗传

Field experiments were conducted to study the inheritance of boron efficiency in oilseed rape (Brassica napus L.) by evaluating the boron (B) efficiency coefficient (BEC, the ratio of the seed yield at below the critical boron level to that at the boron-sufficient level) with 657 F_2:3 lines of a population derived from a cross between a B-efficient cultivar, Qingyou 10, and a B-inefficient cultivar, Bakow. Qingyou 10 had high BEC as well as high seed yield at low available soil B. On the contrary, Bakow produced low seed yield at low B status. Boron deficiency decreased the seed yield of the F_2:3 lines to different extents and the distribution of BEC of the population showed a bimodal pattern. When the 657 F_2:3 lines were grouped into B-efficient lines and B-inefficient lines according to their BEC, the ratio of B-efficient lines to B-inefficient lines fitted the expected ratio (3:1), indicating that one major gene controlled the B-efficiency trait. 127 F_2:3 lines selected from the population at random, with distribution of BEC similar to that of the overall population, were used to identify the target region for fine mapping of the boron efficiency gene.     

甘蓝型油菜正季与反季材料小孢子的培养

本文以甘蓝型油菜Westar的F1代为供试材料,通过对8个正季和同样的8个反季材料进行小孢子培养对比实验。结果表明,相同材料（基因型）正季能获得胚状体的反季一样能获得胚状体,但是相同材料的出胚数反季要比正季少50%,并且出胚时间要晚5～8d。正季与反季材料的成苗百分率相同,平均达到93%,加倍率基本一样,达到80%。由此可见,用反季节材料培养小孢子同样能获得成功,对特殊材料可以利用此法进一步加速育种进程。     

GENOTYPIC DIFFERENCES IN ROOT MORPHOLOGY AND PHOSPHORUS UPTAKE KINETICS IN BRASSICA NAPUS UNDER LOW PHOSPHORUS SUPPLY

Application of phosphorus (P) fertilizer is important in crop production because of the low bioavailability of phosphorus to plants in both acidic and calcareous soils. Although rapeseed (Brassica napus) is generally sensitive to P deficiency, different cultivars differ widely in this respect. Differences in P uptake and utilization between two rapeseed cultivars, one P-efficient (‘97081’) and one P-inefficient (‘97009’), were evaluated in solution culture by studying the changes in root morphology and parameters of P uptake kinetics in response to low-P stress. The P-efficient cultivar had lower Km and Cmin values and higher Vmax and developed longer and denser lateral root hair with greater number of root tips and branches under low-P stress, which resulted in a better developed root system and more efficient uptake of P. That, in turn, led to higher concentration and accumulation of P in the plants, culminating in higher biomass production. However, P utilization efficiency (biomass production per unit P accumulated in plant) of the P-efficient ‘97081’ was lower than that of ‘97009’ when P was deficient. These results suggest that P efficiency in rapeseed is due to a better developed root system as well as efficient uptake of P.     

Physiological and genetic responses to boron deficiency in Brassica napus: A review

Abstract

Boron (B) is an essential microelement for the growth and development of plants, and B deficiency affects many biochemical and physiological processes. Brassica napus L. has a high demand for B and is extremely sensitive to B deficiency. Seed yields and oil quality of B. napus are often limited by the low availability of B in soils. Developing new cultivars of B. napus with high B efficiency is therefore required, which requires a greater understanding of responses to B deficiency. Significant genotypic differences in response to low soil B have been observed among varieties of B. napus. B-efficient genotypes can grow and yield normally and usually have a larger root system than B-inefficient genotypes at low B conditions. The mechanisms for B efficiency in B. napus are attributed to B absorption, transportation and utilization. In addition, the cell wall component plays an important role in the tolerance of B. napus to B deficiency, and the B-efficient line presents fewer B-binding sites in the cell walls compared with the B-inefficient line. Genetic and proteomic analyses in B. napus revealed the modulation of a complex network in response to B deficiency. This review gives a comparative overview of the physiological and genetic responses to B deficiency in B. napus and discusses the possible underlying mechanisms of B efficiency.     

比较研究苏北沿海滩涂盐土上不同油菜品种生物学特征和产量构成

以实验室自育的5个油菜品种(系)及其他6份油菜品种(系)为试验材料,研究了这11份油菜品种(系)在轻(中)度盐化土中的越冬性状、生物学特性、产量构成特性,得出如下结论:南盐油系列品系(种)在盐土上植株生长势强,从基部开始分枝,分枝多;南盐油系列品种(系)茎粗与宁油16、三北98、秦油66和秦油9号差异不明显,但高于宝杂油1号和秦油33;各品种(系)株高差异不大;荚长与荚宽差异也不大。南盐油系列品系(种)产量显著高于对比的宝杂油1号、秦油66、秦油9和秦油33,一次与二次分枝数与菜籽产量的回归分析显示其R2均达极显著水平。     

Genetic Survey of Chinese and Swedish Oilseed Rape (Brassica napus L.) by Simple Sequence Repeats (SSRs)

Eleven Chinese and twelve Swedish rapeseed (Brassica napus) genotypes were analysed by PCR with 41 microsatellite primers, generating a total of 50 loci. For these 50 loci, the number of alleles ranged from 1 to 14, and the average number of alleles per loci was 2.7. As an example of simple sequence repeat (SSR) scoring in Metaphor agarose gel, a single marker could distinguish 14 different DNA profiles. Based on cluster analysis (UPGMA), the dendrogram clearly distinguished three clusters, a cluster with exclusively Swedish genotypes, and two clusters with Chinese genotypes. The genetic diversity within the Chinese genotypes was broad compared to the genetic diversity within the Swedish material. The genetic similarity within the Swedish breeding lines ranged from 69.5 to 95.6%, while that of Chinese genotypes ranged from 57.1 to 81.6%. The results in this report will permit to establish a set of microsatellite primers that can be used for selecting appropriate parents for Brassica napus hybrids and for monitoring hybridity level.     

Impact of sulfur applications on the agronomic performance of rapeseed–clover mixtures

Rapeseed (Brassica napus L.) is a crop requiring high levels of nitrogen (N) fertilizer for growth and to optimize yield and seed quality. To limit the environmental pollution associated with intensive N fertilizer use, rapeseed–clover (Trititcum incarnatum L.) mixtures were grown in lysimeters under low N conditions (100 kg N ha⁻¹). Considering the high sulfur (S) requirements of both rapeseed and clover, two inputs of S fertilizer (30 and 60 kg S ha⁻¹) were applied. The effects S input on the agronomic performance of rapeseed in mixture and monocrops considered as reference, the N₂‐fixing capacity of clover, and the leaching of nitrate and sulfate were monitored. This study showed that the N₂‐fixing capacity (%Ndfa) of clover was improved (1.3‐fold) when it was grown in mixture with rapeseed at S60. However, irrespective of the type of cropping (monocrops or mixtures) and S application level (30 or 60 kg S ha⁻¹), the biomasses and total N and S contents of both plants were not significantly different, nor was the rapeseed seed quality. Moreover, the yield of rapeseed grown in mixture at S60 was significantly lower than the yield of rapeseed grown as a monocrop (331.5 ± 9.8 versus 380.8 ± 3.5 g DW m⁻², respectively). The results demonstrate that, in our field conditions, rapeseed mixed with clover required only 30 kg S ha⁻¹ to maintain yield and seed quality, despite the high S needs of both plants. More surprisingly, compared to the rapeseed monocrop, the rapeseed–clover mixture led to an increase in N (‐N) and S (‐S) leaching during the early winter period of cultivation.     

Interactive Effect of Sulfur and Nitrogen on Nitrogen Accumulation and Harvest in Oilseed Crops Differing in Nitrogen Assimilation Potential

ABSTRACT

Field experiments were conducted to determine the interactive effect of sulfur (S) and nitrogen (N) on nitrogen accumulation, its distribution in various plant parts, and nitrogen harvest of oilseed crops viz. rapeseed (Brassica campestris L. cv. ‘Pusa Gold’) and taramira (Eruca sativa Mill.) differing in their N-assimilation potential. Two combinations of S and N (in Kg/ha): 0S + 100N (?S+N) and 40S + 100N (+S+N) were used. The results showed that combined application of S and N (+S+N) significantly (P < 0.05) increased the nitrogen accumulation in both the genotypes at all the growth stages compared with N applied alone (?S+N). This increase in nitrogen accumulation was due to the improvement in the reduction of nitrate into reduced nitrogen as evident from higher nitrate reductase (NR) activity in the leaves of plants grown with both S and N, compared with N alone. Nitrate-N content in the leaves of plants grown with only N (?S+N) was higher compared to those grown with both S and N (+S+N), showing that combined application of S along with N (+S+N) appreciably reduced the nitrate content in the leaves due to higher NR activity. This decline in nitrate (NO₃ ^?) was followed by an overall increase in N-accumulation in the plants. Consequently, the nitrogen content in the plant was increased by 29–148% in rapeseed and 38-166% in taramira with +S+N treatment. Combined application of S along with N (+S+N) also increased seed protein content and nitrogen harvest index of both the genotypes. It is concluded that combined application of S along with N (+S+N) not only increased the N-accumulation, but also its mobilization towards economic sinks.     

甘蓝型油菜品种航天诱变后代性状分析

通过对搭载实践8号育种卫星的6个甘蓝型油菜品种(系)种子及其后代连续多年种植选择,对其SP3农艺性状及品质性状进行诱变效应分析,对SP4产量和农艺性状等进行鉴定与结果分析。结果表明,6个搭载品种的植株性状、生育期和抗逆性在SP1与对照相比均没有明显变化。对SP2进行田间观测,发现有多个主花序、主茎萎缩和小花瓣等变异株。对SP3室内考种和品质测试,发现了矮杆、大粒等有利变异株,还有一些芥酸、硫苷和含油率发生改变的变异群体。对SP4田间产量鉴定,得到了1份高产材料TK407,产量为3 048.35 kg·hm-2,产量构成三要素合理,分别为单株有效角果数365角、每角粒数23.43粒、千粒重4.61g。研究表明,航天诱变后代能产生变异植株,通过育种目标性状多代选择,能选育出高产、优质的新品种。     

Efficiency of foliar selenium application on oilseed rape (Brassica napus L.) as influenced by rainfall and soil characteristics

The Czech Republic is characterized by a low Se soil content, resulting in Se deficiency in crops, humans, and animals. This study investigated the response of oilseed rape to foliar application of selenate solution in a microscale field experiment conducted at two locations differing in soil and climatic conditions but with comparable total Se contents. Sodium selenate (Na₂SeO₄) was applied at two rates (25 and 50 g Se ha^?1). The potential effect of Se application on the uptake of essential elements was also evaluated. The foliar Se application resulted in an effective stepwise increase in the Se contents of all the plant components studied (leaves > stems > roots > siliques ~ seeds), as expected. No significant influence of Se fortification on the other investigated macro- and microelements was observed. However, the soil and climatic conditions influenced the Se uptake, such that a higher Se content was observed in plants grown in the most acidic location (Cambisol soil) that had a higher oxidizable carbon content and higher average annual rainfall compared to the less acidic location (Luvisol soil). These observations indicated the necessity to optimize the Se application for the particular soil and climatic conditions to achieve a maximum biofortification effect.     

Effect of nitrogen fertilization on nitrogen dynamics in oilseed rape using 15N‐labeling field experiment

In order to optimize nitrogen (N) fertilization and to reduce the environmental impact of oilseed rape without decreasing yield, a clearer understanding of N dynamics inside the plant is crucial. The present investigation therefore aimed to study the effects of different N‐application rates on the dynamics of N uptake, partitioning, and remobilization. The experiment was conducted on winter oilseed rape (Brassica napus L. cv. Capitol) under three levels of N input (0, 100, and 200 kg N ha^–1) from stem elongation to maturity using ¹⁵N‐labeling technique to distinguish between N uptake and N retranslocation in the plant. Nitrogen fertilization affected the time‐course of N uptake and also the allocation of N taken up from flowering to maturity. Most pod N came from N remobilization, and leaves accounted for the largest source of remobilized N regardless the N‐application rate. However, the contribution of leaves to the remobilized N pool increased with the N dose whereas the one of taproot decreased. Stems were the main sink for remobilized N from stem elongation to flowering. Leaves remained longer on N200 than on N0 and N100 plants, and N concentration in fallen leaves increased with the N treatment and in N100 plants along an axial gradient from the basal to the upper leaves. Overall, these results show that the timing of N supply is more crucial than the N amount to attain a high N efficiency.     

广东省土壤磷素状况及磷肥需求预测

阐明了广东省不同耕作制下 ,土壤速效磷含量差异很大 ,大致为菜地土壤 >水稻田 >果园土壤 ;预测广东省年磷肥需求量应在 2 0 0 0年的基础上增加 3 0 %～ 44.4%。指出磷肥使用中存在的问题 ,建议加强磷肥领域的研究 ,促进因土因作物适量配施磷肥。     

缓释硼肥种肥用量对红壤油菜生长发育和产量的影响

为明确种肥同播条件下红壤耕地的适宜硼肥用量,在红壤旱地和水田通过开展种肥同播不同硼肥用量试验,本研究设置施硼肥量为0(T1,对照)、4.5(T2)、9.0(T3)、13.5 kg·hm^-2(T4)4个处理,研究其对油菜出苗、生长发育、硼肥吸收利用效果、籽粒产量、品质等的影响。结果表明,红壤耕地增施硼肥,油菜花期可缩短9~20 d,全生育期缩短2~11 d。红壤中有效硼含量严重缺乏,增施硼肥可显著提高油菜生物量和菜籽产量。适宜的硼肥用量可通过增加成株率、单株角果数和每角粒数提高产量。施硼量为9.0 kg·hm^-2时,菜籽产量达最佳水平,为2 131.6 kg·hm^-2,较对照增产336.1%。收获期硼吸收量和各器官中硼含量随施硼量增加而增加,施硼量为13.5 kg·hm^-2时硼吸收量和各器官中硼含量均达到最大值。硼肥利用率随施硼量增加呈降低趋势,土壤基础有效硼含量越低,硼肥贡献率越大,施硼增产效果越好。施硼量为9.0 kg·hm^-2时,菜籽含油量和产油量达最佳水平,与对照相比含油量增加6.7个百分点,产油量达996.4 kg·hm^-2,较对照增加401.5%。综合菜籽产量、含油量、硼肥利用率和产油量等因素,推荐红壤旱地硼肥施用量为9.0 kg·hm^-2,水田可适当增加施用量,但不宜超过13.5 kg·hm^-2。本研究为我省红壤耕地油菜生产硼肥施用和油菜全程机械化生产提供了技术参考和理论依据。     

Impact of arbuscular mycorrhizal fungi on the growth and expression of gene encoding stress protein – metallothionein BnMT2 in the non‐host crop Brassica napus L.

Arbuscular mycorrhizal (AM) fungi are an important component of the soil biota in most agroecosystems, and their association can directly or indirectly affect the diversity of soil microorganisms, nutrient cycling, and growth of host plants. Since not all crops are symbiotic, we hypothesized that the presence of AM fungi can: (1) inhibit the growth of non‐host plants by resulting in biotic stress, or (2) promote their growth indirectly by increased nutrient mobilization. These hypotheses were tested in the present study on the non‐mycorrhizal crop canola (Brassica napus L.) in the presence and absence of other autochthonous soil microorganisms. The soil was inoculated with a mixture of AM fungi (Acaulospora longula, Glomus geosporum, G. mosseae, Scutellospora calospora) and as a control, a non‐inoculated soil was used. The impact of inoculation on plant growth (biomass production, nutrient concentrations) and expression of the stress protein metallothionein gene BnMT2 was investigated in the shoots. B. napus L. did not form mycorrhizal associations on its roots, but its growth was promoted after inoculation with AM fungi. In the soil with autochthonic microorganisms, growth inhibition after inoculation was observed compared to the control. The concentrations of N, P, K, and S in the shoot were always significantly increased after inoculation with AM fungi. However, this was partly combined with reduced growth and thereby decreased total uptake of nutrients. Expression of BnMT2 in the leaves was increased after inoculation with AM spores at the soil devoid of indigenous microorganisms, but decreased in their presence. The expression of stress proteins (BnMT2) significantly increased with increasing length and biomass of shoots. In conclusion, the inhibition of the non‐host plant B. napus L. following inoculation with AM fungi was confirmed, however, only in combination with autochthonous microorganisms. Growth promotion of B. napus L. in the presence of AM fungi in the absence of autochthonous soil microorganisms suggest that plant growth depression in the presence of AM fungi was based on interactive effects of AM fungi with the autochthonous microorganisms in the soil rather than on a direct impact of the AM fungi.