黑土和棕壤中甲胺磷的根际降解脱毒模拟研究

利用塑料根际盒研究了甲胺磷在黑土和棕壤大豆根际和非根际环境中的降解脱毒行为.结果表明,甲胺磷虽是急性毒性较高的农药,但在土壤环境中能很快降解,并且同等条件下,甲胺磷在黑土中的残留量普遍低于棕壤.在无大豆种植情况下(对照处理),培养试验第2天,棕壤甲胺磷残留量约为33%,黑土只有26%.在大豆根际圈中,甲胺磷的降解明显加快,尤其是在黑土中.第9天,根际盒中层黑土和棕壤的农药残留分别比无植物对照低87.5%和76.0%.甲胺磷的土壤降解过程符合一级动力学方程,降解半衰期为2 d左右.     

硫素对不同大豆品种成熟期AM真菌群落多样性的影响

研究硫素对不同大豆品种成熟期丛枝菌根（arbuscular mycorrhizal,AM）真菌群落多样性的影响,探索有利于提高3个特定大豆品种根围土壤和根系AM真菌多样性的最佳施硫量,为提高大豆产量和改善大豆品质提供理论依据。试验采用盆栽,选用黑农44（HN44）、黑农48（HN48）、黑农37（HN37）3个大豆品种作为试验材料,设4个硫素处理S1（对照）,S2（0.02g/kg）,S3（0.04g/kg）和S4（0.06g/kg）。采用PCR-DGGE技术分析3个大豆品种根围土壤和根系中AM真菌群落多样性。结果表明：在S2处理下HN37和HN44根围土壤和根系AM真菌多样性最高,而在S3处理下HN48根围土壤和根系AM真菌多样性最高;DGGE图谱中各样品优势种群变化显著,球囊霉属Glomus和柄囊霉属Funneliformis真菌为3个大豆品种根围土壤和根系中AM真菌的优势菌群。由此可见,硫素对不同大豆品种根围土壤和根系AM真菌群落多样性有显著影响,适量施硫能够提高大豆根围土壤和根系中AM真菌的多样性,不施或过高施硫反而抑制AM真菌的多样性。     

不同生长期盆栽大豆的土壤呼吸昼夜变化及其影响因子

通过盆栽试验 ,用静态箱法采样 ,气相色谱测定样品 CO2 浓度 ,分别在大豆开花期、结荚期和鼓粒期测定土壤呼吸速率 ,研究大豆不同生长期土壤呼吸的昼夜变化规律及其主要影响因素。在结荚期灌水后测定土壤呼吸速率 ,以研究水分对土壤呼吸昼夜变化的影响。结果表明在大豆不同生长期中 ,土壤呼吸均具有明显的昼夜变化规律 ,且均呈单峰曲线型 ,峰值出现在 12 :0 0到 16 :0 0之间。6 :0 0～ 18:0 0的 CO2 排放占总排放的 6 1%～ 6 9% ,昼夜平均土壤呼吸速率最接近于 18:0 0～ 2 1:0 0之间的速率。如果忽略大豆生长对土壤有机质分解的激发效应 ,大豆根际呼吸占总土壤呼吸的 85 %～ 96 %。裸土土壤呼吸与温度呈极显著的指数和线性相关 ,种大豆的土壤呼吸与温度的关系因生长期而异 ,鼓粒期的相关性最好 ,结荚期最差。这些都说明大豆生长和生长阶段影响土壤呼吸及其与温度的关系。灌水后使大豆土壤呼吸昼夜变化增强 ,平均土壤呼吸速率增大。由此可见植物生长时期、温度和水分是影响土壤呼吸昼夜变化的主要因素     

转基因高蛋氨酸大豆对根际土壤主要有机元素和酶活性的影响

【目的】为了评估转基因高蛋氨酸大豆ZD91对土壤生态系统的安全性,开展了其对土壤主要有机元素和酶活性影响的实验。【方法】连续2年,在大豆苗期、花期、鼓粒期和成熟期,采用抖落法采集根际土壤样品,通过室内测定,分析了转基因大豆ZD91对根际土壤含水量、pH、主要有机元素和酶活性的影响。【结果】转基因大豆ZD91较之对应的非转基因大豆对根际土壤含水量、pH、主要有机元素和酶活性无显著影响,但同一种酶活在不同年份和不同生育期存在显著差异。【结论】转基因大豆ZD91对土壤生态系统具有安全性。     

摩西管柄囊霉Funneliformis mosseae对连作大豆分枝期根系AM真菌群落结构的影响

本文研究摩西管柄囊霉Funneliformis mosseae对短期连作3个大豆品种分枝期根系AM真菌群落结构的影响,旨在探索不同大豆品种与AM真菌在连作土壤中的互作效应。通过向黑农44（HN44）、黑农48（HN48）和恳丰16（KF16）3个大豆品种盆栽土壤中接种F. mosseae,对接菌连作0年（未连作对照组）、连作1年、连作2年土壤中的大豆根系,采用Nested-Program Control Register-DGGE技术分析。结果表明,接种F. mosseae后,不同大豆品种根系AM真菌多样性指数和丰度值表现为连作2年的土壤>连作1年的土壤>未连作的土壤;其中,球囊霉属Glomus和F. mosseae为3个大豆品种根系中AM真菌的优势菌群。接种F. mosseae对连作1年、连作2年3个大豆品种根系AM真菌群落结构具有显著影响。     

硼肥对甜荞根际土壤养分、根系形态及产量形成的影响

为了明确硼肥对甜荞植株构型及产量的影响,本研究以甜荞品种'综甜2号'为试验材料,在花蕾期对其叶片喷施不同浓度的硼肥,于成熟期测定甜荞根际土壤养分的含量、根系形态、农艺性状及产量.结果表明:硼肥的施用能显著增加'综甜2号'根际土壤铵态氮、速效钾含量,以及pH、根系表面积和根系体积,而且显著降低根际土壤有机质的含量.当硼肥...     

保护性施氮在缓解大豆重（迎）茬根际微生态障碍中的效应

通过保护性施氮技术的应用,改善重（迎）茬条件下大豆根际微生态环境,达到调节根际微生物相平衡,保护共生固氮体系的正常发育及其功能的发挥,协调大豆对根瘤氮和土壤（肥料）氮源的需求,从而有效地缓解了重迎茬大豆氮素同化过程中的生理性障碍,也就为大豆正常的生长发育及其经济性状的发挥创造了条件。     

鹤岗市种植大豆适宜性研究

大豆是鹤岗市农业生产的主要作物之一,大豆属低产作物,单产较低,近年来受市场价格的影响,效益差,大豆种植面积逐年缩减。本次试验根据鹤岗市地力评价结果,评价出适宜种植大豆的区域。从大豆不同适宜性耕地的地力等级的分布特征来看,耕地等级的高低与地形部位、土壤类型及土壤质地密切相关。高中产耕地从行政区域看,主要分布在中部、南部的乡镇,这一地区土壤类型以暗棕壤、草甸土、黑土为主,地势较平缓低洼,坡度较小;低产土壤则主要分布在西北部、北部的一部分地区,这些地区的耕地土层薄,质地差,地势起伏较大或者低洼,行政区域包括东方红乡、蔬园乡,土壤类型主要是白浆土,沼泽土等土壤类型。     

抗草甘膦转基因大豆对根际土壤细菌及根瘤菌的影响

转基因大豆是全球种植最广泛的转基因作物,抗除草剂是其最主要的转基因特性.微生物群落是土壤质量的监测指标之一,抗草甘膦转基因大豆及配施草甘膦是否影响大豆根际土壤细菌及根瘤菌群落尚不清楚.本研究基于大田试验,以非转基因亲本大豆‘中豆32’为对照(CK),分析转G10-epsps基因耐除草剂大豆SHZD32-01(GR)及配施草甘膦(GR+G)在大豆各生育时期对根际土壤细菌和根瘤菌的影响.结果表明: 与CK相比,GR、GR+G处理对苗期和成熟期根际土壤pH、总有机碳(TOC)、总氮(TN)、NH₄⁺-N含量等产生影响;GR处理显著增加结荚期根际土壤细菌群落丰度及多样性,GR+G处理显著增加结荚期根际土壤细菌群落多样性,但显著降低苗期和结荚期根际土壤细菌群落丰度;GR、GR+G处理改变了部分优势细菌类群的相对丰度,但不同生育期根际土壤优势细菌类群均为变形菌门、酸杆菌门、拟杆菌门、绿弯菌门、浮霉菌门和放线菌门;GR、GR+G处理改变了根瘤菌类群的相对丰度,但未影响慢生根瘤菌和中华根瘤菌两种主要大豆根瘤菌的相对丰度,且GR+G处理结荚期根际土壤根瘤菌相对丰度显著降低.环境因子分析显示,根际土壤放线菌和根瘤菌群落丰度主要受土壤pH影响.抗草甘膦转基因大豆或配施草甘膦显著影响结荚期根际土壤细菌和根瘤菌,但其影响随大豆的生长而消失.     

桑树/大豆间作对植物生长及根际土壤微生物数量和酶活性的影响

利用根系分隔试验的方法,研究了桑树/大豆间作体系中植株生长、根际土壤酶和土壤微生物的变化.结果表明： 根系不分隔处理的桑树和大豆的株高、叶片数、根长和根冠比等生长指标均高于塑料膜分隔和尼龙网分隔处理,大豆有效根瘤数较多.不分隔、尼龙网分隔处理的桑树和大豆的根际土壤磷含量比塑料膜分隔分别高10.3%、11.1%和5.1%、4.6%.不分隔和尼龙网分隔处理的桑树和大豆根际微生物数量、微生物多样性和土壤酶活性均高于塑料膜分隔处理.表明桑树和大豆间作具有明显的种间促进效应.     

Phosphorus and Nitrogen Interactions in Field-Grown Soybean as Related to Genetic Attributes of Root Morphological and Nodular Traits

Two field experiments with different soybean (Glycine max L.) materials were conducted to investigate the interactions between phosphorus (P) and nitrogen (N) as related to the genetic attributes of root morphological and nodular traits. In experiment one, 13 cultivated soybean varieties were grown in a field with relatively low soil P and N availability. P application with 160 kg P/hm2 as triple superphosphate produced a significant simultaneous increase in the content of both P and N in shoot, demonstrating positive P and N interactions. The addition of P also increased root dry weight, root nodule number, nodule mass, nodule size, and nodulation index, but decreased root length and root surface area, indicating that P may affect N nutrition in soybean through a number of root morphological and nodular traits. Interestingly,like P content, N content appeared to be more correlated with root morphological traits (root weight, root length, and root surface area) than with root nodular traits (nodule number, nodule size, nodule mass, and nodulation index) at both P levels, implying that N taken up by the roots may contribute more to the plant N status than biological N2 fixation under the present experimental conditions. In experiment two, 57 soybean lines of a recombinant inbred line (RIL) population derived from a cross between a cultivated variety and a wild genotype were grown on another field site with moderately sufficient P and N levels to further characterize the genetic attributes of root morphological and nodular traits and their relationships with P and N interactions. The results indicated that all morphological and nodular traits measured continually segregated in the RIL population with a normal distribution of the phenotypic values, indicating that these traits are possibly controlled by quantitative trait loci (QTLs). Genetic analysis revealed that all these root traits had relatively low heritabilities (h2b=74.12, 70.65, 73.76, 56.34, 52.59, and 52.24 for root weight, root length,root surface area, nodule number, nodule mass, and nodule size, respectively), suggesting that root morphology and nodule formation are influenced greatly by environmental factors. Correlation analysis of the RILs showed that shoot N content was significantly correlated with P content, confirming positive P×N interactions. Similar to experiment one, shoot N content was only significantly correlated with root morpho logical traits, but not with root nodular traits, again denoting the fact that the N status in soybean could be attributed more to N uptake from the soil than to biological N2 fixation under the present experimental conditions.     

Evaluation of high yielding soybean germplasm under water limitation

Limited information is available for soybean root traits and their plasticity under drought stress. To date, no studies have focused on examining diverse soybean germplasm for regulation of shoot and root response under water limited conditions across varying soil types. In this study, 17 genetically diverse soybean germplasm lines were selected to study root response to water limited conditions in clay (trial 1) and sandy soil (trial 2) in two target environments. Physiological data on shoot traits was measured at multiple crop stages ranging from early vegetative to pod filling. The phenotypic root traits, and biomass accumulation data are collected at pod filling stage. In trial 1, the number of lateral roots and forks were positively correlated with plot yield under water limitation and in trial 2, lateral root thickness was positively correlated with the hill plot yield. Plant Introduction (PI) 578477A and 088444 were found to have higher later root number and forks in clay soil with higher yield under water limitation. In sandy soil, PI458020 was found to have a thicker lateral root system and higher yield under water limitation. The genotypes identified in this study could be used to enhance drought tolerance of elite soybean cultivars through improved root traits specific to target environments.     

Effects of Drought Stress on Key Enzymes of Carbon Metabolism,Photosynthetic Characteristics and Agronomic Traits of Soybean at the Flowering Stage under Different Soil Substrates

Soybean is an important legume food crop, and its seeds are rich in nutrients, providing humans and animals with edible oil and protein feed. However, soybean is sensitive to water requirements, and drought is an important factor limiting soybean yield and quality. This study used Heinong 84 (drought resistant variety) and Hefeng 46 (intermediate variety) as tested varieties planted in chernozem, albic, and black soils. The effects of drought stress on the activities of key enzymes in carbon metabolism and photosynthetic characteristics of soybean were studied during the flowering stage, most sensitive to water. (1) The activities of SS-1, 6PGDH, and G6PDH enzymes in soybean leaves first increased and then decreased under drought stress. The enzyme activity was the highest under moderate drought stress and weakest in the blank group. (2) Drought stress increased Phi2, PhiNO, and Fm in soybean leaves and reached the highest value under severe drought; with the increase in drought stress, PhiNPQ and Fv/Fm of soybean leaves gradually decreased, reaching the lowest under severe drought. (3) With the increase in drought stress, F₀ and Fs of soybean leaves showed a single peak curve, and the maximum was at moderate drought. (4) Correlation analysis showed that F₀ was greatly affected by varieties and soil types; Fs, F0, and Fm soil varieties had a great influence, and chlorophyll fluorescence parameters were affected differently under drought stress with different drought degrees. (5) Drought stress changed the agronomic traits and yield of soybean. With the increase of drought degree, plant height, node number of main stem, effective pod number, 100-seed weight and total yield decreased continuously. (6) Drought stress affected the dry matter accumulation of soybean. With the increase of drought degree, the dry matter accumulation gradually decreased. Among them, the leaf was most seriously affected by drought, and SD decreased by about 55% compared with CK. Under the condition of black soil, the dry matter accumulation of soybean was least affected by drought.     

接种量对费氏中华根瘤菌HN01DL根圈定殖与结瘤的影响

在灭菌土和未灭菌土盆栽系统中 ,研究了大豆种子的表面初始接种量对费氏中华根瘤菌HN0 1DL在大豆根圈中的定殖动态与结瘤的影响。结果表明 ,与 3个接种量对应的早期根圈定殖动态和水平有明显差异 ,但随着宿主植物根系的生长其差异逐渐减小 ,整个定殖动态曲线的变化和定殖密度趋向一致 ,并且发现 3个不同的初始接种量对HN0 1DL在大豆黑农 33根系上的结瘤数量和占瘤率没有显著影响。     

干旱胁迫对花生根系生长发育和生理特性的影响

以花育17号和唐科8号两个花生品种为试验材料,在防雨棚栽培池内进行土柱栽培试验,研究了中度干旱胁迫和正常供水处理下花生生育后期根系形态发育特征和生理特性.结果表明: 唐科8号具有较发达的根系及较高的产量和抗旱系数,花育17号根系对干旱胁迫的适应性小于唐科8号.两品种根长密度、根系生物量均主要分布于0～40 cm土层中,但同一土层内两品种根系性状存在差异.与正常供水处理相比,干旱胁迫处理使花育17号各生育期总根长、根系总表面积和总体积均降低,而唐科8号除花针期显著降低外,其余生育期均明显升高;干旱胁迫增加了两品种20～40 cm土层内根系生物量、根系表面积和体积,而降低了40 cm以下土层内各根系性状;干旱胁迫处理使两品种饱果期40 cm以下土层内根系活力降低,且花育17号降低幅度高于唐科8号.干旱胁迫下两品种生育后期根系发育和生理特性的差异表明其根系在干旱胁迫下对水分吸收和利用存在差异.     

Effect of soil moisture stress on legume-rhizobium symbiosis in soybeans

Summary In a pot culture experiment, the influence of soil moisture stress at different physiological stages of soybean, cv. Hark, on nodulation, symbiosis and nitrogen accumulation was studied. Moisture stress reduced leghemoglobin content of root nodules and nitrogen uptake by plants. It had no effect on number of bacteroids. Stress at mid bloom and rapid pod filling stages reduced yield and seed protein content. However, these parameters were not affected by stress at nodule initiation and early flowering stages, though, flower initiation and maturity of the plant were delayed. Moisture stress at any stage did not alter nitrogen status of roots.     

大豆出苗期和苗期对盐胁迫的响应及耐盐指标评价

比较了4个大豆品种出苗期和苗期的耐盐性,测定150 mmol/L NaCl胁迫下的株高、下胚轴长、侧根数、地上干/鲜重、根干/鲜重、MDA含量、SOD活性、游离Pro含量,并将幼苗移栽到田间生长至成熟。结果表明:出苗期和苗期盐胁迫下4个品种的株高都显著降低、地上干/鲜重和根干/鲜重降低;出苗期胁迫侧根数减少,下胚轴长降低;而苗期胁迫侧根数增加,下胚轴长升高。未胁迫条件下,出苗期和苗期耐盐性强的品种22021-1的MDA含量和SOD活性高于耐盐性弱的品种22293-1。胁迫后,22021-1的MDA含量降低、SOD活性升高,其MDA含量分别比对照低51.03%和21.45%,SOD活性比对照高5.85%和45.77%;22293-1的MDA含量出苗期比对照高58.97%,苗期基本无变化,SOD活性出苗期和苗期升高都不显著。MDA和SOD可以作为大豆耐盐性筛选指标。早期的短时胁迫对不同耐盐性大豆品种的经济产量影响不同。     

Identification of QTLs for seed and pod traits in soybean and analysis for additive effects and epistatic effects of QTLs among multiple environments

Soybean seed and pod traits are important yield components. Selection for high yield style in seed and pod along with agronomic traits is a goal of many soybean breeders. The intention of this study was to identify quantitative trait loci (QTL) underlying seed and pod traits in soybean among eleven environments in China. 147 recombinant inbred lines were advanced through single-seed-descent method. The population was derived from a cross between Charleston (an American high yield soybean cultivar) and DongNong594 (a Chinese high yield soybean cultivar). A total of 157 polymorphic simple sequence repeat markers were used to construct a genetic linkage map. The phenotypic data of seed and pod traits [number of one-seed pod, number of two-seed pod, number of three-seed pod, number of four-seed pod, number of (two plus three)-seed pod, number of (three plus four)-seed pod, seed weight per plant, number of pod per plant] were recorded in eleven environments. In the analysis of single environment, fourteen main effect QTLs were identified. In the conjoint analysis of multiple environments, twenty-four additive QTLs were identified, and additive QTLs by environments interactions (AE) were evaluated and analyzed at the same time among eleven environments; twenty-three pairs of epistatic QTLs were identified, and epistasis (additive by additive) by environments interactions (AAE) were also analyzed and evaluated among eleven environments. Comparing the results of identification between single environment mapping and multiple environments conjoint mapping, three main effect QTLs with positive additive values and another three main effect QTLs with negative additive values, had no interactions with all environments, supported that these QTLs could be used in molecular assistant breeding in the future. These different effect QTLs could supply a good foundation to the gene clone and molecular asisstant breeding of soybean seed and pod traits.     

Genetic variability in nodulation and root growth affects nitrogen fixation and accumulation in pea

BACKGROUND AND AIMS: Legume nitrogen is derived from two different sources, symbiotically fixed atmospheric N(2) and soil N. The effect of genetic variability of root and nodule establishment on N acquisition and seed protein yield was investigated under field conditions in pea (Pisum sativum). In addition, these parameters were related to the variability in preference for rhizobial genotypes. METHODS: Five different spring pea lines (two hypernodulating mutants and three cultivars), previously identified in artificial conditions as contrasted for both root and nodule development, were characterized under field conditions. Root and nodule establishment was examined from the four-leaf stage up to the beginning of seed filling and was related to the patterns of shoot dry matter and nitrogen accumulation. The genetic structure of rhizobial populations associated with the pea lines was obtained by analysis of nodule samples. The fraction of nitrogen derived from symbiotic fixation was estimated at the beginning of seed filling and at physiological maturity, when seed protein content and yield were determined. KEY RESULTS: The hypernodulating mutants established nodules earlier and maintained them longer than was the case for the three cultivars, whereas their root development and nitrogen accumulation were lower. The seed protein yield was higher in 'Athos' and 'Austin', the two cultivars with increased root development, consistent with their higher N absorption during seed filling. CONCLUSION: The hypernodulating mutants did not accumulate more nitrogen, probably due to the C cost for nodulation being higher than for root development. Enhancing exogenous nitrogen supply at the end of the growth cycle, by increasing the potential for root N uptake from soil, seems a good option for improving pea seed filling.     

Developing of a simple method for screening soybean seedling cadmium accumulation to select soybean genotypes with low seed cadmium

Significant inter-cultivar differences of soybean seed cadmium (Cd) concentrations arise from the inter-cultivar differences in root Cd accumulation ability. The Cd concentration in the shoots of plants at the vegetative stage is already controlled by the roots Cd concentration in the same way that it determines seed Cd concentration. Based on these results we conjectured that there is no need to wait until the full maturity stage because the inter-cultivar difference in seed Cd concentration can be predicted from the Cd concentration in the shoots of seedlings. To test this theory, we cultivated 150 cultivars/lines to the harvest stage in a field not contaminated with Cd and measured seed Cd concentration. We also planted seeds in pots filled with contaminated soil, cultivated them for 3 weeks, and measured the Cd concentration of the seedling obtained at the 5th-node (V5) stage when the 4th trifoliolate leaf had expanded. The 150 cultivars/lines were roughly divided into 2 groups based on the relationship between these 2 Cd concentrations. One group was cultivars in which seedlings and seeds both had low Cd concentrations (low Cd accumulation group, n?=?129), and the other group was the opposite (high Cd accumulation group, n?=?21). Further, when we predicted seed Cd concentration using the ratio of Cd and Zn concentrations in seedlings, we were able to clearly divide the 2 groups with no overlap. Measuring Cd/Zn in seedlings therefore makes it possible to select cultivars with low Cd accumulation tendency readily, without waiting to harvest the seeds. Additionally, by investigating genealogies we found that varieties in the high-Cd accumulation group were descended from certain cultivars such as Harosoy.