江淮下游地区大豆地方品种的初步研究——Ⅱ.数量性状的遗传变异

本文研究了江淮下游大豆地方品种生育期、产量、机械化栽培方面共17种数量性状的遗传变异。试验材料为本地区有代表性的78个地方品种,四次重复,随机区组设计。 性状的遗传型变异系数(GCV)、遗传力(h~2)以及预期遗传进度(GS)表明本区大豆地方品种自然群体生育前期、后期、全生育期,产量、分枝数、主茎节数、每节荚数、百粒重、瘪粒率、一株荚数、一株粒数、一株粒重、株高、结荚高度、倒伏性等15种数量性状具有丰富的遗传变异、选择潜力和良好的预期选择效果。证明除每荚粒数、茎粗两性状外,本区大豆地方品种主要数量性状的多基因资源十分丰富,是大豆育种宝贵的基本材料。     

普通甜荞主要数量性状相关遗传力的测定

对24个普通甜荞品种,7个主要数量性状,进行了遗传力、遗传相关和相关遗传力的测定．结果表明：株粒数与株粒重h_xy~2=0.8208,有效花序数与株粒重h_xy~2=0.6829,千粒重与株粒重h_xy~2=0.4498;株高、主茎节数,一级分枝数3个性状与株粒重的相关遗传力差异均不显著。     

大明绿系选后代遗传多样性与高产特征分析

以内蒙古中东部地区61份绿豆品种大明绿系选后代为研究材料,通过对农艺性状的多样性及通径分析,明确了后代品系遗传类型及高产群体性状特征。结果表明,大明绿后代品系间性状差异显著,单株荚数变异系数最大为31.61%,其次为单株粒重28.05%,遗传多样性较丰富,多样性指数为单株荚数2.02,每荚粒数2.01,百粒重1.89,单株粒重1.96。后代品系主要有6种类型,各性状对单株粒重影响大小依次为:单株荚数>每荚粒数>百粒重>节数>株高。高产类型品系主要特征指标为单株粒重超过15 g,单株荚数超过30荚,每荚粒数8~10粒,株高48~60 cm,节数9~10节,百粒重可根据不同需求制定标准。     

菜用大豆产量相关性状的遗传分析

对 19个菜用大豆品种与产量有关的10个农艺性状进行遗传分析的结果表明,生育期和主茎节数遗传力偏高;单株荚数、分枝数遗传力偏低;单株产量、单株荚数的遗传变异系数很大,其遗传进度的值也较大;生育期的遗传变异系数小, 遗传进度也小,遗传相关分析结果表明,产量与生育期、单株结荚数相关关系密切。菜用大豆遗传参数分析结果与前人对食用大豆的研究结果趋势一致。     

大豆滞绿(stay-green)突变体诱变后代表型性状变异分析

本文利用大豆滞绿突变体Z-94320经60Co-γ射线诱变的突变体后代M5、M6代为材料,进行两年的田间性状观察记录统计,用相关性分析、主成分分析、聚类分析对其17个主要表型性状统计分析。结果表明:诱变后代产生了丰富的变异,出现了多种种皮色和子叶色,产生了非滞绿性状,形成了各种生育周期,且分离出晚熟性状。通过相关性分析发现,单株粒重与株重、茎粗、主茎荚数、分枝荚数、一粒荚数、二粒荚数、三粒荚数、瘪粒荚数、虫食数呈极显著正相关,这些性状可以对产量进行预测;主成分分析在M5代提取出“产量因子”、“株型因子”、“粒荚因子”、“茎荚因子”四个主成分,对农艺性状累计贡献率达到70.50%,M6代提取出“产量因子”、“虫害因子”、“株型因子”、“茎杆因子”四个主成分,对农艺性状累计贡献率达到71.54%;聚类分析将M5、M6代材料分别划分为6类,发现同代中各类群农艺性状情况大致相似,但是各农艺性状在两代之间的变化明显,在株重、结荚高度、单株粒重等方面M6代显著高于M5代,并筛选出两株高产品系和一株特色滞绿品系。本研究逐步完善了对滞绿大豆突变体库的构建,为滞绿大豆诱变后代的遗传多样性研究提供了基础的数据分析。     

160份外引鹰嘴豆种质主要农艺性状的遗传多样性分析

对引自国际半干旱热带作物研究中心的160份鹰嘴豆种质资源的13个农艺性状进行了评价鉴定,并筛选了特异种质,为我国鹰嘴豆种质资源创新和品种选育提供参考。结果表明,该批鹰嘴豆种质资源具有较为丰富的遗传多样性,7个数量性状的变异系数由大到小分别为主茎分枝数单株荚数百粒重产量株高单荚粒数生育期,6个质量性状的Shannon多样性指数由大到小分别为粒色株型花色种子表面粒形复叶叶型;产量与粒形、单株荚数极显著正相关,与百粒重显著正相关;前4个主成分的累计贡献率为63.417%,其中第1主成分与产量性状和产量有关,第2主成分与生育期有关,第3主成分与形态性状有关,第4主成分与株高和粒形有关;聚类分析在遗传距离为5时将160份资源分为3个类群,其中第Ⅰ类群的株高较高,第Ⅱ类群的产量较高,第Ⅲ类群的籽粒较大;筛选出63份早熟、矮秆、无分枝、多荚、荚粒数多、大粒、高产的特异种质资源。     

大豆航天搭载SP4选择效果与SP2代变异率相关分析

摘要：为了明确大豆航天搭载早期世代农艺性状选择的依据,提高航天搭载育种早期世代选择效果。对6个大豆品种经过航天搭载后的SP2代变异率和SP4代选择效果进行了分析,结果表明遗传力高的SP2代的单株荚数和单株粒数2个农艺性状的变异率与SP4代入选单株数相关达到极显著水平;SP2代遗传力较高底荚高度和节间长度的变异率与SP4代入选单株相关达到显著水平,SP2代遗传力不高的植株高度和主茎节数变异率与SP4代入选单株相关不显著;SP2代对单株荚数、单株粒数、底荚高度、节间长度进行选择有效,而对植株高度和主茎节数选择效果不明显。     

大豆种质资源农艺性状和产量的年份间差异及其关系

明确大豆种质资源农艺性状的变化及其与产量的关系对大豆遗传育种具有重要的意义。以249份大豆种质资源为材料,应用多元统计方法分析了大田条件下两年间大豆农艺性状与产量的变化。结果表明,大豆种质资源的农艺性状和产量两年变异系数分别为6.2%~78.0%和6.3%~48.5%,变异较大。生育日数因在黄淮海区域生态类型较接近,变异系数较小;而主茎节数变异系数也较小。株高、有效分枝数、底荚高度、单株荚数、单株粒数、每荚粒数、单株粒重、百粒重、单位面积产量则相对变异较大。品种之间农艺性状和产量差异均显著。不同年份间生态因子（温度、降水量及日照时数）对大豆农艺性状和产量的影响较大,年份间不同指标差异亦显著。分别对两年农艺性状采用主成分分析,简化为4个与产量相关的独立指标,并建立了产量与农艺性状之间的方程Y=17.5-1.76x1+1.32x2+0.30x3+2.50x4和Y=198.8-3.12x1+7.71x2+0.08x3+2.71x4以表达其量化关系;采用聚类分析方法将两年中249份大豆种质资源分别聚为5类,并分析了各类品种的特性,为高产稳产大豆新品种的选育以及高产栽培措施的调控提供理论依据。     

大豆航天搭载SP4代选择效果与SP2代变异率相关性分析

为了明确大豆空间诱变早期世代农艺性状选择的依据,提高空间诱变育种早期世代选择效果,对6个大豆品种经过航天搭载后的SP2代变异率和SP4代选择效果进行了分析,结果表明遗传力高的SP2代的单株荚数和单株粒数2个农艺性状的变异率与SP4代入选单株数相关性达到极显著水平;SP2代遗传力较高的底荚高度和节间长度的变异率与SP4代入选单株相关性达到显著水平,SP2代遗传力不高的植株高度和主茎节数变异率与SP4代入选单株相关不显著;SP2代对单株荚数、单株粒数、底荚高度、节间长度进行选择有效,而对植株高度和主茎节数选择效果不明显。     

黄淮海大豆种质农艺与品质性状分析及综合评价

以303份黄淮海地区大豆种质资源为研究对象,利用变异系数和Shannon-Weaver多样性指数对11个农艺性状和2个品质性状进行多样性分析,通过主成分、相关性以及逐步回归分析对大豆种质资源进行综合评价和评价指标筛选,为黄淮海大豆种质创新和品种选育提供参考。结果表明：13个性状变异系数的变化范围为5.52%～27.61%,生育日数、每荚粒数、蛋白含量、脂肪含量等4个性状较稳定,株高、单株粒数、单株荚数、单株粒重、百粒重等5个性状变异丰富;13个性状多样性指数变化范围为1.9906～2.0956。聚类分析将303份大豆种质资源分为7个类群,其中第Ⅴ类群综合性状最好,可作为黄淮海大豆育种的优质亲本。主成分分析将13个性状简化为4个主成分,累积贡献率为75.051%,第1主成分与单株荚数、粒数有关;第2主成分与蛋白质、脂肪含量有关;第3主成分与籽粒大小有关;第4主成分与单株产量有关。303份大豆种质资源综合评价F值均值为0.549,ZDD04189涟水天鹅蛋的F值最高（0.935）,ZDD23089晋品42的F值最低（0.207）。通过逐步回归分析得到生育日数、株高、单株粒数、单株粒重、蛋白...     

播种季节和种植方式对多年生苦荞主要农艺性状的影响

该研究选取六个多年生苦荞新品系,对春季、秋季直播与秋季再生其主要农艺性状进行调查。结果表明:(1)不同播种季节对多年生苦荞新品系主花序的花粉可育率、总结实率、有效结实率、植株株高、主茎粗、主茎分枝数、主茎节数、籽粒百粒重、单株粒数、单株产量的影响均达到显著或极显著水平;秋播主花序花粉可育率、总结实率、有效结实率、植株主茎分枝数、籽粒百粒重、单株粒数、单株产量均极显著高于春播;植株株高、主茎粗、主茎节数均极显著低于春播;主花序花朵大小、籽粒种子长宽比无显著差异。(2)不同种植方式对主花序花粉可育率、有效结实率、植株主茎节数及籽粒百粒重的影响达到显著或极显著水平;秋季再生主花序花粉可育率、籽粒单株粒数显著高于秋季直播;主花序有效结实率、植株主茎粗、主茎节数、籽粒百粒重显著低于秋季直播;主花序花朵大小、总结实率、植株株高、主茎分枝数、籽粒种子长宽比、单株产量无显著差异;相关分析表明,各生长季节下主花序有效结实率及单株粒数与单株产量的相关系数均最高。(3)所有参试品系中,1612-241秋季直播的单株产量显著高于其他品系; 1612-16、1612-33秋季再生单株产量较正季优势显著。该研究结果有助于筛选出适宜一季播种两季收获的优良品系,为今后多年生苦荞的选择育种提供线索基础。     

Estimates of broad-sense heritability for seed yield and yield criteria in faba bean (Vicia faba L.)

Eight faba bean (Vicia faba L.) genotypes were grown at lowlands of the west-Mediterranean region of Turkey in order to estimate the broad-sense heritability for plant height, number of stems and pods per plant, seed yield, biological yield, 100-seed weight, days to flowering and maturity. The heritability for plant height, number of stems and pods per plant, seed yield, biological yield, 100-seed weight, days to flowering and maturity were estimated as 83%, 63%, 43%, 62%, 52%, 99%, 97% and 97%, respectively. It was found that seed weight was the least affected trait across changing environmental conditions and followed by days to flowering and maturity. On the other hand, number of pods per plant, biological and seed yields and number of stems per plant were the most affected traits versus environmental conditions.     

不同结荚习性夏大豆种质的农艺表现及其与产量的相关分析

以533份不同结荚习性大豆种质为试验材料,研究了不同结荚习性大豆种质在黄淮夏播生态区的农艺性状表现,并对主要农艺性状和产量的相关性进行了分析。结果表明:大豆种质的营养期、株高、有效分枝、单株荚数、倒伏性、株型等性状的平均值随无限-亚有限-有限结荚习性递减,生殖期、单株粒重、百粒重、小区产量等性状平均值的变化趋势则相反。相关分析表明,无限结荚习性种质的产量与株高、单株粒重呈极显著正相关,偏相关系数分别为0.602**、0.566**,与有效分枝、倒伏性呈显著负相关,偏相关系数分别为-0.384*、-0.451*。亚有限结荚习性种质的产量与生殖期、单株粒重呈显著、极显著正相关,偏相关系数分别为0.156*、0.536*,与有效分枝呈极显著负相关,偏相关系数为-0.323**。有限结荚习性种质的产量与单株粒重、株高呈极显著正相关,偏相关系数分别为0.433**、0.262**,与株型、单株荚数呈显著、极显著负相关,偏相关系数分别为-0.149*、-0.198**。结合不同结荚习性品种的生长特点,本研究认为,无限结荚习性品种株高较高且株高与产量呈极显著正相关,适合干旱地区种植;亚有限结荚习性品种生殖期与产量呈正相关,生殖期内生长旺盛需要较多的养分供应;有限结荚习性品种的营养生长持续时间短,株高较矮,吸收光能有限,实现高产主要依赖各性状器官间的平衡。生产中,有限结荚习性品种的营养生长期间既需要充足的肥水促其生长,又要防止旺长。     

An Analysis of the Influence of Plant Density on the Growth of Vicia faba: I. THE INFLUENCE OF DENSITY ON THE PATTERN OF DEVELOPMENT

The competitive effects of varying the density on the developmentof Vicia faba have been studied in a series of multifactorialexperiments where the spacing both between and within rows wassimultaneously altered. Over densities ranging from 11 to 67plants per metre² seed production on an area basis tended tobe maximal at 35–45 plants per metre² in the winter typeand at the highest density for the spring type. As the densityincreased the number of pods per plant and the extent of branchingfell progressively but there was no appreciable change in eitherseed size or the number of seeds per pod: thus seed productionwas solely governed by the number of mature pods formed. Thenumber of flowers per plant was more dependent on the numberof inflorescences than on the number of flowers per inflorescence.Increasing the population diminished the number of nodes bearinginflorescences particularly in the upper part of the shoot,while the size of the inflorescence was decreased to a lesserextent. The number of flowers forming mature pods was very small(9–14 per cent.). At the top of the shoot the flowerswere infertile, while above the middle node most of the podsformed were shed while still immature. Thus the primary effectof increasing density was to depress the number of nodes onthe lower half of the stems which produced mature pods. By thetime the flowering stage was reached plant height was alreadycorrelated with density due more to a change in internode lengththan an alteration in the number of differentiated nodes; atmaturity the differences in height were smaller due to the greaternumber of nodes in the widely spaced plants. For a given density,alterations in the distance between rows had little influenceon development. The possible physiological factors responsiblefor the changing pattern of development brought about by varyingdensity are discussed.     

Inheritance of quantitative traits in crosses between two Pisum sativum subspecies with particular reference to their breeding value

The experimental study was conducted during the period of 2008-2010 at the experimental field of the Institute of Forage Crops in Pleven. The hybridization scheme included direct and back crosses covering four varieties of forage pea (Pisum sativum L.), namely two spring ones, Usatii 90 and Kamerton from Ukraine, and a winter one from Bulgaria, Pleven 10. There was analyzed the inheritance of quantitative traits such as plant height, height to first pod, pod number per plant, seed number per plant, seed number per pod, seed weight per plant and number of fertile nodes per plant of parental components (P1 and P2) and both first (F1) and second (F2) hybrid generations. The cross Usatii 90 x Pleven 10 showed the highest real heterosis effect for plant height (8.26%), pods per plant (158.79%), seeds per plant (272.16%), seeds per pod (42.09%), seed weight per plant (432.43%) and number of fertile nodes per plant (117.14%). The cross Pleven 10 x Usatii 90 had the highest real heterosis effect height to first pod (11.06%). In F2 plants, the strongest depression for plant height (5.88%), seeds per plant (57.88%), seeds per pod (55.93%) and seed weight per plant (55.99%) was in the cross Usatii 90 x Pleven 10, for height to first pod (1.47%) in the cross Kamerton x Pleven 10 and for number of fertile nodes per plant (15.91%) in the cross Pleven 10 x Usatii 90. The highest positive degree of transgression for number of fertile nodes per plant (165.64%) and seed weight per plant (162.10%) was in the cross Pleven 10 x Kamerton and for pod number per plant (102.54%) and seeds per plant (99.13%) in Kamerton x Pleven 10. The stability of the characters was determined. Low variability in F1 and F2 was found in plant height (3.97-6.85%). Variability of number seeds per plant in F1 was highest (11.86-33.23%). For all other traits, the variability varied from average to high. A lower narrow-sense heritability coefficient was observed for plant height, height to first pod, pods per plant, seeds per plant and seed weight per plant (from 0.001 to 0.230). In few cases, such as in fertile nodes per plant (0.39 and 0.81) and seeds per pod (0.44), the coefficients ofbroad-sense heritability were higher.     

Residual effect of germination temperature on the growth of peas

Summary In Pisum sativum there is a marked difference in the final height of the plants depending on the temperature at which the seed is germinated. Significant differences were also found in such parameters as growth rate, node of first flower, seeds per plant, pods per plant as well as flowers per plant.     

Inheritance of quantitative traits in crosses between two <Emphasis Type="Italic">Pisum sativum</Emphasis> subspecies with particular reference to their breeding value

The experimental study was conducted during the period of 2008–2010 at the experimental field of the Institute of Forage Crops in Pleven. The hybridization scheme included direct and back crosses covering four varieties of forage pea (Pisum sativum L.), namely two spring ones, Usatii 90 and Kamerton from Ukraine, and a winter one from Bulgaria, Pleven 10. There was analyzed the inheritance of quantitative traits such as plant height, height to first pod, pod number per plant, seed number per plant, seed number per pod, seed weight per plant and number of fertile nodes per plant of parental components (P₁ and P₂) and both first (F₁) and second (F₂) hybrid generations. The cross Usatii 90 × Pleven 10 showed the highest real heterosis effect for plant height (8.26%), pods per plant (158.79%), seeds per plant (272.16%), seeds per pod (42.09%), seed weight per plant (432.43%) and number of fertile nodes per plant (117.14%). The cross Pleven 10 × Usatii 90 had the highest real heterosis effect height to first pod (11.06%). In F₂ plants, the strongest depression for plant height (5.88%), seeds per plant (57.88%), seeds per pod (55.93%) and seed weight per plant (55.99%) was in the cross Usatii 90 × Pleven 10, for height to first pod (1.47%) in the cross Kamerton × Pleven 10 and for number of fertile nodes per plant (15.91%) in the cross Pleven 10 × Usatii 90. The highest positive degree of transgression for number of fertile nodes per plant (165.64%) and seed weight per plant (162.10%) was in the cross Pleven 10 × Kamerton and for pod number per plant (102.54%) and seeds per plant (99.13%) in Kamerton × Pleven 10. The stability of the characters was determined. Low variability in F₁ and F₂ was found in plant height (3.97–6.85%). Variability of number seeds per plant in F₁ was highest (11.86–33.23%). For all other traits, the variability varied from average to high. A lower narrow-sense heritability coefficient was observed for plant height, height to first pod, pods per plant, seeds per plant and seed weight per plant (from 0.001 to 0.230). In few cases, such as in fertile nodes per plant (0.39 and 0.81) and seeds per pod (0.44), the coefficients of broad-sense heritability were higher.     

Genetic analyses of agronomic and seed quality traits of synthetic oilseedBrassica napus produced from interspecific hybridization ofB. campestris andB. oleracea

The heritability, the number of segregating genes and the type of gene interaction of nine agronomic traits were analysed based on F₂ populations of synthetic oilseedBrassica napus produced from interspecific hybridization ofB. campestris andB. oleracea through ovary culture. The nine traits—plant height, stem width, number of branches, length of main raceme, number of pods per plant, number of seeds per pod, length of pod, seed weight per plant and 1000-seed weight—had heritabilities of 0.927, 0.215, 0.172, 0.381, 0.360, 0.972, 0.952, 0.516 and 0.987 respectively, while the mean numbers of controlling genes for these characters were 7.4, 10.4, 9.9, 12.9, 11.5, 21.7, 20.5, 19.8 and 6.4 respectively. According to estimated coefficients of skewness and kurtosis of the traits tested, no significant gene interaction was found for plant height, stem width, number of branches, length of main raceme, number of seeds per pod and 1000-seed weight. Seed yield per plant is an important target for oilseed production. In partial correlation analysis, number of pods per plant, number of seeds per pod and 1000-seed weight were positively correlated with seed yield per plant. On the other hand, length of pod was negatively correlated (r = -0.69) with seed yield per plant. Other agronomic characters had no significant correlation to seed yield per plant. In this experiment, the linear regressions of seed yield per plant and other agronomic traits were also analysed. The linear regression equation wasy = 0.074x₈ + 1.819x₉ + 6.72x₁₂ -60.78 (R ² = 0.993), wherex ₈, x₉ and x₁₂ represent number of pods per plant, number of seeds per pod and 1000-seed weight respectively. The experiment also showed that erucic acid and oil contents of seeds from F₂ plants were lower than those of their maternal parents. However, glucosinolate content was higher than that of the maternal plants. As for protein content, similar results were found in the F₂ plants and their maternal parents. It was shown that the four quality traits, i.e. erucic acid, glucosinolate, oil content, and protein content, had heritability values of 0.614, 0.405, 0.153 and 0.680 respectively.     

Effects of Gibberellic Acid on Growth and Parthenocarpy in the Dwarf Telephone Pea

Growth in height and production of seedless pods wore studied in Dwarf Telephone pea seedlings treated with relatively large amounts of the potassium salt of gibberellic acid applied in solution to leaflets. Such treatment produced a saturation in growth in height with 2 mg or more per plant when the plants were allowed to grow to maturity. Larger amounts caused no inhibitory effects on growth. Maximum growth with 1 mg per plant was attained only if the treated leaflets were left on the plant for about 14 days, at least, but increasing numbers of weekly 10-mg applications produced no additional growth affects beyond two applications. Increasing age of plants from 10 to 59 days of age at the time of single 10-mg applications per plant resulted in decreasing final heights. Gibberellic acid caused the formation of seedless pods a number of weeks after application, and deformed flower petals, elongated peduncles, and conspicuously inflated pods were associated with seedlessness. GA was most effective in inducing parthenocarpy when applied to the first true leaves of young seedlings and became progressively less effective with age. A complete absence of seeds in pods formed on the main plant axis was produced by one application of 10 mg GA per plant, while six applications were required for the suppression of seed formation on side branches.