Year-to-Year and Maturity Variation in Rainfed Soybean Yield by Planting Dates

The interactions on rainfed soybean yield among planting date, maturity, and year-to-yearclimate change were studied using CROPGRO-soybean model. Simulations were based on 19 plantingdates, maturity groupsⅢ, ⅣandⅤ, 30 years recorded weather data from Corbin, Suffolk,West Point in Virginia, USA. Yield was similar on early plantings and went down with lateplantings. Both grand and year-to-year variation of soybean yield declined linearly withplanting date. Year-to-year climate variation was dominant yield variation source inrainfed soybean production. Interaction occurred between planting date and maturity.Optimal planting dates for different sites lied within 130th-170th day of a year.Irrigation is recommended for profitable crops, especially in Corbin and West Point.

Effects of Planting and Maturity Dates on Shattering Patterns under Early Soybean Production System

Seed shattering is a common problem in early soybean production system (ESPS) in the Midsouth, which mainly uses maturity group (MG) IV soybeans. Many studies have been conducted on the genetics of soybean shattering resistance for individual varieties;however, information on the physiology of soybean shattering pattern under specific environmental conditions, which is often critical to soybean growers, is very limited. Field experiments were conducted at Stoneville MS from 2007 to 2009 to investigate the shattering patterns of 80-132 MG IV soybean varieties each year. Results from 2007 and 2008 indicated that, when April-planted MG IV soybeans matured in mid- to late August, pods of most soybean varieties did not shatter within the first three weeks after maturity (WAM) and there was no significant shattering effect on final yields. However, differences in pod shattering among the varieties became apparent in the fourth WAM. Late-planted MG IV soybeans, which matured in early September, had a low shattering rate and could hold seeds up to 6 WAM before reaching a critical shattering point. Most soybean varieties planted in April 2009 did not show significant pod shattering by the end of the fourth WAM. The critical point of shattering was not reached until 6 - 7 WAM. Relatively lower temperatures and abundant rainfall during the late growing season in 2009 may be the main reasons causing delayed shattering in April-planted MG IV soybeans. Results from the May-planting of 2007 and the April-planting of 2009 indicated that soybeans maturing after September have much less problematic shattering. Different weather patterns, especially temperature and rainfall in each year could be essential factors affecting seed shattering patterns.

Study on Plant Morphological Traits and Production Characteristics of Super High-Yielding Soybean

Super high-yielding soybean cultivar Liaodou 14, soybean cultivars from Ohio in the United States, and the common soybean cultivars from Liaoning Province, China, with similar geographic latitudes and identical pod-bearing habits were used as the study materials for a comparison of morphological traits and production characteristics to provide a theoretical basis for the breeding of improved super high-yielding soybean cultivars. Using a randomized block design, different soybean cultivars from the same latitude were compared under conventional and unconventional treatments for their production characteristics, including morphological traits, leaf area index （LAI）, net photosynthesis rate, and dry matter accumulation. The specific characteristics of the super high-yielding soybean cultivar Liaodou 14 were analyzed. The results showed that the plant height of Liaodou 14 was significantly lower than that of the common cultivars from Liaoning, whereas the number of its main-stem nodes was higher than that of the cultivars from Ohio or Liaoning. A high pod density was observed in Liaodou 14 under conventional treatments. Under both conventional and unconventional treatments, the branch number of Liaodou 14 was markedly higher than that of the common cultivars from Liaoning, and its branch length and leaf inclination angle were significantly higher than those of common cultivars from Liaoning or Ohio. Only small changes in the leaf inclination angle were observed in Liaodou 14 treated with conventional or unconventional methods. Under each treatment, Liaodou 14 exhibited the lowest amplitude of reduction in SPAD values and net photosynthesis rates from the grain-filling to ripening stages; the cultivars from Ohio and the common cultivars from Liaoning exhibited more significant reductions. Liaodou 14 reached its peak LAI later than the other cultivars but maintained its LAI at a higher level for a longer duration. Under both conventional and unconventional treatments, Liaodou 14 produced a higher yield than the other two cultivars, with significant differences from the Ohio cultivars. In summary, super high-yielding soybean cultivars have several main features： suitable plant height, high pod density, good leaf structure with strong functionality, and slow leaf senescence at the late reproductive stage, which is conducive to the accumulation of dry matter and improved yield.

Development of 2BZJ-3/4 Precision Planter for Soybean Narrow-row flatdense Planting Method

Based on the study on cultivation models of soybean narrow-row-flat-dense planting under the conditions of different between-row spacing and inter-plant spacing by using the comparison field experiment, and technical studies of the contour following the seeder unit, the anti-block, the lateral and stratified the deep fertilizing, according to the design ideas of planting units integration and variable between-row spacing from 30 to 45 cm, the 2BZJ-3/4 precision planter matched with 18-32 hp tractors has been developed for the popularization of the narrow-row-flat-dense planting soybean technique by means of Virtual Prototyping （VP） technology.

Effect of Plant Density on Modern Soybean Cultivars Released from Ohio and Liaoning

Seeding rate is an important management practice for soybean production.Chinese and U.S.soybean growers use different seeding rates,and breeders in the two countries have developed cultivars adapted to respective plant densities.The objective of this study was to compare the effect of plant density on cultivars recently released in different breeding programs,using four cultivars developed in Liaoning,China and four in Ohio,USA.We used 3 plant density treatments(7.5,15.0,22.5 x 104 plants/hm2) and assessed yield and agronomic traits from 2004 to 2006 in Liaoning.There was no significant effect of plant density on yield for either group of the cultivars.The average yield of Ohio cultivars was higher than that of Liaoning cultivars,and there was no significant interaction between plant density and cultivar for all the assessed traits.The plant height of Liaoning cultivars was significantly higher than that of Ohio cultivars,and there was a significant effect of plant density on plant height.The average branch number of Ohio cultivars was larger than that of Liaoning cultivars;higher plant density reduced the branch number per plant greatly.Plant density had a signifi-cant effect on the node number and internode length,Liaoning cultivars generally had longer internode length.Plant density had a significant effect on seed yield:stem ratio,as the plant density increased the seed yield:stem ratio decreased for both groups of cultivars.However,100-seed weight was not affected by plant density.

菜用大豆(Soybean)引种试验研究

[目的]筛选适宜大规模栽培的大豆优良株系。[方法]对引进的5个菜用大豆株系在种植生态条件下的植物学特征,农艺性状等进行评价及筛选。[结果]结果表明,通过比较分析,4号株系表现的生育期短,干耔产量较低,结荚个数较少;可利用的鲜粒,鲜荚较大,籽粒饱满,秕荚率低;矮株抗倒伏,6月份收获鲜荚。[结论]大豆可考虑引进栽培。

Specific Expression of a Novel Nodulin GmN479 Gene in the Infected Cells of Soybean (Glycine max) Nodules

A novel nodulin gene, GmN479 genomic clone composing of 3 630 nucleotides was isolated from mature soybean nodules using GmN479 cDNA as a probe by subtractive hybridization procedure. GmN479 encodes 170 amino acids with 2.09 kb nucleotides promoter region, and contains two important upstream promoter elements, one is a conserved cis-acting sequence motif 5′-AAAGAT-3′ controlling nodulin gene expression, and the other is typical CAAT boxes. GmN479 gene has a single zinc-finger C2H2 domain YSCAFCQRGFSNAQALLGGHMNIH and a conserved motif, QALGGHMN in the zinc-finger with a short leucine repeat in the LDLELRLGL motif closed to C-terminal. These two conserved motifs share respectively higher identity with those in the floral regulator SUPERMAN gene, indicating that GmN479 may function as a transcriptional regulator, and is a likely candidate for playing a role in nodule-morphogenesis. Blotting data showed that GmN479 is a single copy presenting in the genome of soybean nodule, and its expression profile is similar to that of Lb-a, but it is different from that of ENOD2. GUS staining showed that GmN479 promoter just functions in the infected cells of nodules, indicating that the GmN479 is one of the truly symbiotically induced host genes, and belongs to a late nodulin gene. The expression pattern of GmN479 gene seems to imply that it may be closely related to the development of the nodule. In a sense, it may be a useful marker for identifying the development of the infected cell system in the nodules of soybean.

植物基乳产业的发展趋势与技术创新

植物基乳产品作为植物基食品产业的重要组成部分,其发展水平对促进植物基食品产业有着举足轻重的作用。分析了全球植物基乳产品的市场规模和我国植物乳产品的市场情况:2023年,全球规模为296亿美元,并以11.4%的速度增长;我国植物基饮品包括豆奶、椰奶、核桃乳、杏仁乳等呈稳定性增长趋势,粉体类产品市场也较稳定(达30万t)。指出植物基乳作为未来食品需要进一步完善定义,充分体现植物基乳特征和属性要求;要加大力度开发满足新消费场景和渠道的新技术、新产品,解决消费者关心的植物基乳产品口味、价格和清洁标签等关键问题,加快植物基酸奶、冷饮等技术的成熟和落地,并通过开发满足不同消费场景、特殊营养、健康需求的产品,为植物基乳产品价值和市场竞争力赋能,创立多元化的植物基乳产业发展新模式。

大豆株型与产量相关性状QTL定位及候选基因预测

为探究与大豆株型和产量相关QTL位点及候选基因,对以东农42(♀)和东农50(♂)为亲本,与168个家系构建的F_(2:12)、F_(2:13)重组自交系(Recombination inbred lines,RILs)群体的株高、分枝数、四粒荚数、百粒重性状测定表型数据,运用IBM SPSS Statistics、R语言进行统计和相关性分析,并利用完备区间作图法(Inclusive composite interval mapping,ICIM)进行加性效应及上位效应分析,共计定位到43个QTL位点,贡献率超过10%的主效位点为14个,包括株高3个、分枝数8个、四粒荚数1个和百粒重2个;其中11个位点与前人已报道位点重合,分别位于4、6、8、16和19号染色体上;qBN-6-2(13.21%)、qBN-6-5(19.96%)和qBN-6-6(13.69%)为3个环境重复定位到的位点,qHSW-19-1与多个已报道位点均有重合。通过上位性分析,获得株高、分枝数、四粒荚数和百粒重位点分别为3、6、6和62对。根据所定位到的物理区间和定量预测,筛选到Glyma.04G238800、Glyma.03G181600、Glyma.08G271900、Glyma.18G278800和Glyma.19G187000等5个与株高、分枝数、四粒荚数和百粒重性状相关的候选基因,为分子辅助育种奠定基础。

高低两种密度条件下耐密植优异大豆种质鉴定

为筛选耐密植大豆种质,本研究选用160份大豆种质资源为研究对象,设置高密度45万株·hm^(-2)和低密度25万株·hm^(-2)两个处理,调查R6和R8期的倒伏级别等相关耐密植性状。经过2018—2020年鉴定,筛选出茎秆强度、株高、主茎节数、节间长度和底荚高度作为大豆倒伏性的鉴定指标,鉴定出14份耐密植的种质资源,分别是Fiskeby1040-4-2、N07、N32、黑河21、黑河41、坂本早生、合交N13-333、合交N13-498、金源71、合丰42、丰收24、克09-95(棕种皮)、克09-95(黄种皮)和克14-758。

勉县玉米-大豆带状复合种植玉米品种筛选试验

玉米-大豆带状复合种植技术目标是保证带状复合种植条件下玉米与单作相比不减产,增收一季豆。与玉米常规种植相比,种植的株行距变化较大,密度增加,玉米品种的株型、耐密性、抗逆性、丰产性等指标成为此项技术应用成功的前提。通过试验,“1.8m带型2+2模式”玉米-大豆带状复合种植玉米品种主推登海605、农科大8号和延科288,搭配种植五单2号、中金368。

基于抗倒伏性的大豆耐密性资源评价与筛选

为筛选在黑龙江省不同地区稳定耐密植的大豆资源,为大豆的区域栽培生产提供指导和理论依据,以黑龙江省不同生态区20份春大豆资源为材料,以哈尔滨、海伦和五大连池为环境背景,设置常规栽培区和高密度处理区两个处理,以高密区未倒伏占比与常规区未倒伏占比的比值作为耐密指数,基于耐密指数值,利用欧氏距离组间平均联接法对不同大豆品种进行聚类分析,对供试材料进行等级划分。同时,利用双标图数据分析方法进行耐密性种质资源的综合评价。结果显示:哈尔滨区域背景条件下,当欧氏距离为3.0时,初步将20个参试品种(系)划分为5大类,获得耐密植品种(系)7个;海伦区域背景下,欧氏距离为4.0时,初步将20个参试品种(系)划分为4大类,获得耐密植品种(系)3个;欧氏距离为4.0时,初步将20个参试品种(系)划分为4大类,获得耐密植品种(系)5个。双标图显示,耐密品种的耐密能力顺序为克豆87>牡豆56>黑农94>黑农531>克小粒1号>黑农311>龙海1号,多环境稳定性顺序为黑农94>龙海1号>克豆87>黑农531>黑农311>牡豆56>克小粒1号。综合比较而言,耐密性强且多环境稳定性较好的品种为黑农94、克豆87和黑农531。研究结果为提升区域大豆增产能力提供了理论依据和技术支持。

大豆玉米带状复合种植技术探讨

大豆玉米带状复合种植技术可以充分发挥大豆固氮作用和玉米边际效应,实现良种良法配套、农技农艺融合、种地养地有机结合,有效解决传统作物套种生产效率低下、争光、争肥和争水等问题,有效提升农业生产效益。以灵台县农业生产实际情况为例,对大豆玉米带状复合种植技术进行研究,以期为广大种植户提供技术参考。

玉米大豆带状复合种植模式研究

为探讨适宜云南玉米大豆带状复合种植模式,2022年选用玉米云瑞668和大豆台湾75-3为试验材料进行大田试验,研究玉米大豆带状复合种植不同模式下不同处理对玉米和大豆农艺性状和产量构成因素的影响。结果表明,可机械化作业的田块应优先选用玉米大豆行比4∶4和4∶3模式,山区或半山区推广玉米大豆行比2∶2模式。该研究为玉米、大豆带状复合种植在云南省保山市及气候类似地区推广提供了理论依据。

大豆株型与高光效育种的理论与实践——我50年大豆育种科学生涯(第一部分)

文章总结了杜维广从1975年到2024年从事大豆育种50年的研究经历,包括常规育种、高光效育种、理想株型育种、践行分子模块设计育种和全基因组QTL-allele设计育种(组合设计和基因型设计)新方法。本文系统总结了大豆株型与高光效育种的理论与实践,阐述了大豆植株是光能吸收的载体,从而株型与高光效关联;提出理想株型和理想型设计方案及其育种瓶颈,并对耐密大豆株型进行了探讨;提出高光效育种理念和技术路线及其高光效光合生理基础和高光效育种瓶颈。通过对30年高光效育种历程的总结,为从事大豆育种研究的科技人员作进一步研究提供参考。

大豆玉米带状种植模式下玉米摘穗机设计与试验

针对丘陵山区大豆玉米带状种植模式的玉米果穗收获有机难用、无机可用的现状,设计一款自走式小型玉米摘穗机。该机采用纵卧式摘穗辊实现果穗摘取,并通过输送装置收集装袋;采用“Y”型布局的L型小甩刀实现茎秆粉碎。对摘穗过程进行动力学分析、对粉碎过程进行静力学分析,确定其核心装置设计参数并进行样机试制。以茎秆粉碎长度合格率、果穗损失率、籽粒破碎率为试验指标进行田间试验,来验证该机设计的合理性。试验表明:在生产率为0.8 hm^(2)/d、果穗籽粒含水率为26.38%、茎秆含水量为71.25%的条件下进行试验,茎秆粉碎长度合格率为92.4%、果穗损失率为2.06%、籽粒破碎率为0.61%。该机设计各项指标符合国家相关标准,能够满足丘陵山地地区玉米机械化收获需求。

大豆垄上三行密植行间除草装置设计与试验

针对大豆垄上三行密植种植模式下,苗带间距较小,现有除草装置行间除草率低、伤苗率高、中耕除草作业困难等问题,设计了一种大豆垄上三行密植行间除草装置,主要由定位圆盘、弹齿固定连杆和弹齿等组成。根据中耕时期大豆苗和杂草的生长状态,确定了定位圆盘和除草装置的安装距离;通过对弹齿除草过程进行动力学分析,建立弹齿入土部分曲线方程,并对弹齿进行运动学分析;以圆周弹齿组数、弹齿入土角和轴向弹齿个数为试验因素,松土率和弹齿平均工作阻力为指标,利用离散元仿真方法进行Box-Behnken多因素试验,得到圆周弹齿组数为10、弹齿入土角为80°、轴向弹齿个数为5,具有最佳效果。以机具前进速度、除草组件转速和入土深度为试验因素,以除草率和伤苗率为评价指标,对除草装置进行单因素田间性能试验,结果表明:当除草深度35mm、机具前进速度2.5km/h时,平均除草率、伤苗率分别为88.24%、2.77%,机具作业性能稳定,未出现堵塞现象,满足大豆行间除草农艺要求。

带宽和株距对带状间作大豆物质积累分配及产量形成的影响

间套作系统中合理的田间配置能改善作物生长环境,增加系统产量。为进一步完善西南地区大豆-玉米带状间作系统高产高效的田间配置技术,本研究以大豆-玉米带状间作为研究对象,采用二因素裂区试验设计,综合分析2.0 m(B1)和2.4 m(B2)2个带宽与9 cm(P1)、11 cm(P2)、14 cm(P3)、18 cm(P4)4个株距对大豆物质积累分配、籽粒灌浆和产量的影响。结果表明,B2带宽下各株距处理的净光合速率均高于B1,其2年平均值在B2下较B1增加14.26%;相同带宽下净光合速率在B1P4和B2P4达到最大,开花期较B1P1和B2P1增加13.57%和25.21%。2个带宽下大豆群体物质积累均随株距增加呈先增后减的趋势且分别在B1P3和B2P2下达到最大,完熟期B2较B1增加9.82%~22.08%。同时,带宽与株距的增加促进了大豆花后物质的积累与向籽粒的转移,与B1相比,B2处理使大豆花后干物质积累量与干物质转移量分别增加13.82%~28.01%和13.38%~37.76%,籽粒物质积累占比增加到41.80%~44.26%。物质积累的增加改善籽粒灌浆过程,B2带宽下籽粒灌浆活跃期(D)较B1延长2~3 d;2种带宽下平均灌浆速率均在P4达到最大且分别较P1增加5.80%和6.58%。产量结果表明,大豆-玉米带状间作模式中,带宽和株距的增加降低了群体有效株数,增加了单株粒数和百粒重;B2带宽下的大豆产量较B1增加22.32%~36.87%,2个带宽下分别在B1P3和B2P2达到最大值,2年间较B1P1和B2P1增加17.83%~26.44%和10.71%~10.76%。综上所述,2.4m带宽下大豆株距为11 cm时能有效改善大豆花后干物质积累和分配,促进籽粒灌浆,增加单株粒数和百粒重,提高大豆群体产量,实现大豆-玉米带状间作系统的高产高效。

辽宁省不同年代大豆品种农艺性状和产量的遗传改良

为了明确辽宁省未来大豆性状的改良方向,选取辽宁省不同年代育成的146份大豆品种为试验材料,种植密度设置为15万株·hm-2,综合分析不同年代间大豆品种的茎秆强度、叶柄夹角、成熟期的株型和产量性状的遗传改良趋势。结果表明:随着育成年代的推进,大豆鼓粒期上、中、下层叶柄夹角均逐渐减小,在2020年代均达到最小;而茎秆强度显著增加,在2020年代达到251.49 N。在成熟期株高、植株重量平衡点高度和底荚高度随着品种育成年份的演替呈显著下降趋势,均在2020年代达到最小。但主茎节数、主茎粗和分枝数变化不显著。随着大豆品种的遗传改良,籽粒产量呈显著增加趋势,2020年代育成品种达到3319.63kg·hm^(-2)。单株荚数和单株粒数均呈上升趋势,百粒重变化不显著。相关分析结果表明:籽粒产量与株高、底荚高度呈极显著负相关,相关系数分别为-0.316和-0.249,与单株粒数呈极显著正相关,相关系数为0.229。通径分析表明:株高、底荚高度和单株粒数对产量的直接贡献最大,直接通径系数分别为-0.241,-0.304,0.228。综上可知,辽宁省大豆品种遗传改良偏重选育株型紧凑株高适宜、底荚高度较低和单株粒数较多的稳产型大豆品种。

Breeding and cultivation technology of high protein soybean variety ‘Qindou 2014’

Soybean variety ‘Qindou 2014’ with high protein content(47.79%) was bred through hybridization and pod mixed individual selection method. ‘96 E218’ and ‘Pudou 10’ were used as female and male parent respectively. Near-infrared analytical method was used in low generation selection. ‘Qindou 2014’ also performed consistent high yield(3,739.8 kg/ha averagely), strong resistance to mosaic virus disease,wide adaptation, and good fitness to mechanized harvesting. The regional examination test was carried out and it was approved by the cultivar registration committee of Shaanxi Province in 2017. Experiments of sowing date and density were conducted to explore the suitable cultivation technologies for high yield. Results indicated that ‘Qindou 2014’ could fully exert its yield potential as sown at the density of 290,000 plants/ha from May 25 to June 15. This study provides high quality soybean germplasm for future soybean industry.