籼稻品质分析的近红外光谱模型建立及其应用研究

为了满足籼稻品质快速分析的需求,本研究利用籼稻精米粉近红外光谱建立了直链淀粉含量、蛋白质含量、碱消值、垩白度的回归预测模型.结果表明,本研究提供的预测模型具有良好的测定效果,用偏最小二乘法(PLS)获得的籼稻精米粉直链淀粉含量、蛋白质含量、碱消值、垩白度的回归模型和交叉验证显示最优校正决定系数(R~2)和交叉检验均方误差(RMSECV)分别为0.9561、1.55,0.9510、0.258,0.9076、0.283,0.9014、4.14.说明所建的近红外光谱预测模型具有实用价值.     

贵州地方芝麻种质资源品质性状的分析与评价

为探究贵州芝麻种质资源的品质特征,并对地方芝麻资源进行初步鉴定与评价,本研究对73份贵州芝麻种质资源的8个品质性状进行测试分析。结果表明:(1)贵州芝麻种质资源含油量介于41.45%~52.12%之间,平均含量为49.69%。在脂肪酸组成中,油酸、亚油酸等不饱和脂肪酸的平均含量分别为35.65%和50.66%;而棕榈酸、硬脂酸等饱和脂肪酸的平均含量仅为8.40%和4.79%。此外,贵州芝麻资源中芝麻素、芝麻林素和木质素的平均含量分别为5.03 mg/g、2.63 mg/g和4.79 mg/g。8个品质性状的变异系数介于3.69%~32.62%范围内,其中芝麻素含量变异系数最大,含油量变异系数最小。而芝麻素含量、芝麻林素含量及硬脂酸含量的变异系数均大于10%,表明这3个性状在芝麻样本间存在较大差异。(2)相关性分析结果显示:含油量与油酸、芝麻素含量呈极显著正相关,与亚油酸含量呈极显著负相关;油酸含量与芝麻素含量呈极显著正相关,与亚油酸含量呈极显负相关;亚油酸含量与芝麻素含量呈极显著负相关。表明品质性状间相关性大、关联程度较高,性状间相互影响较大。(3)主成分分析将8个品质性状综合为3个主成分,分别为油酸因子、含油量因子和芝麻素因子,3个主成分因子包含了贵州芝麻种质资源品质性状的绝大部分信息,累计贡献率达96%以上。(4)在欧氏距离D=9.75处将73份贵州芝麻资源划分为6个类群:第Ⅰ类群包含2份资源、第Ⅱ类群有7份、第Ⅲ类群有12份、第Ⅳ类群有5份、第Ⅴ类群有16份、第Ⅵ类群有31份。其中第Ⅵ类群油酸含量最高,且含油量、芝麻素含量较高。本研究探明了贵州芝麻品质的特征特性,可为芝麻种质资源的利用和创新提供依据,为芝麻品种选育和遗传改良提供参考。     

大麦种质资源主要啤酒酿造品质性状分析

采用国际标准的分析方法,对连云港市农业技术推广中心引进和选育的828份酿造大麦品种(系)进行了品质分析,分析项目为大麦籽粒蛋白含量、麦芽无水浸出物、糖化力、可溶性氮和库尔巴哈值等5个性状,初步摸清了现有种质资源的品质状况,筛选出了一批品质优、综合农艺性状好的品种(系),其中冈2、港啤1号和苏农21等品种已通过审定,并在生产上大面积应用。     

64份淮山种质资源品质性状分析

对64份淮山种质资源品质性状进行了分析,结果表明:铁、氨基酸、总皂甙、锌含量的变异系数较大,分别为66.2%、59.9%、44.09%、42.77%;3种类型的淮山种质资源,其淀粉含量差异较大,褐苞薯蓣(23.52%)参薯(20.48%)薯蓣(12.93%);因子分析结果显示,淀粉和蛋白质含量累计贡献率达66.786%,可用这2个主成分较好地代替6个品质特性来评价与评判淮山品质;相关性分析表明,淀粉含量与总皂甙含量呈显著正相关,蛋白质含量与总皂甙含量呈极显著正相关,淀粉、蛋白质含量这2个主成分与总皂甙含量之间存在相互促进的效用;聚类分析表明,整个淮山资源可分为3大类,分别为高淀粉型、低淀粉型、高铁型。淮山种质资源品质性状分析,可为日后进行淮山种质资源的创新利用、新品种的选育提供可靠的依据。     

271份豌豆种质资源农艺性状遗传多样性分析

以来自五大洲57个国家和地区的271份豌豆资源为材料,利用主成分分析和聚类分析的方法,评价其2个质量性状和7个数量性状的遗传变异水平。结果表明,参试资源的农艺性状具有丰富的遗传多样性。其中遗传多样性指数最高的是始荚节位(2.0590),其次是主茎节数(2.0421);性状变异系数最大的是小区产量(64.874%),其次是百粒重(61.870%)。采用SPSS 22.0软件对参试资源7个数量性状的主成分分析结果表明,前3个主成分因子累计贡献率达66.021%,Ward法聚类将参试的271份豌豆资源划分为4大类群,其中第Ⅱ类群属于高秆、大粒、高产种质,具有很高的丰产潜力,为我国杂交育种亲本选择提供了原材料。对取材数大于等于5的来自于四大洲17个国家的参试资源进一步分析发现,不同地理区域资源间遗传变异显著,其中印度的遗传多样性指数最高(1.7533),巴基斯坦的最低(0.9685),波兰的变异系数和遗传多样性都较高。综合分析国外种质资源的农艺性状,有助于我国豌豆育种项目亲本选配。     

206份芋种质资源品质性状分析

对206份芋种质资源品质性状进行了分析,结果表明:按球茎类型来分,干物质含量魁芋>多头芋>魁子兼用芋>多子芋。淀粉含量魁芋>魁子兼用芋>多头芋>多子芋,干物质和淀粉含量都以魁芋最高,分别为27.38%、20.21%,多子芋最低,分别为19.54%、13.35%。蛋白质含量多头芋>魁芋>多子芋>魁子兼用芋,以多头芋的含量最高为1.54%,其他类型相差不大。可溶性糖含量魁芋>魁子兼用芋>多子芋>多头芋,以魁芋的可溶性糖含量最高为1.21%,其他芋类型相差不大。按母芋芽色来分,多子芋中,干物质、淀粉和蛋白质含量红芽多子芋>白芽多子芋,可溶性糖含量白芽多子芋>红芽多子芋;多头芋中,干物质、淀粉、可溶性糖白芽多头芋>红芽多头芋,蛋白质含量红芽多头芋>白芽多头芋。在整个芋种质资源中,芋的干物质含量与淀粉含量(r=0.9583**)、干物质含量与蛋白质含量(r=0.5529**)、淀粉含量与蛋白质含量(r=0.5284**)呈极显著正相关,干物质含量与可溶性糖含量(r=-0.2934**)、淀粉含量与可溶性糖含量(r=-0.3391**)、蛋白质含量与可溶性糖含量(r=-0.4498**)均呈极显著负相关。此外本研究还按叶柄颜色类型对芋种质资源品质性状进行了分析。     

豌豆种质资源形态标记遗传多样性分析

通过对国内外不同地理来源624份豌豆资源20个形态性状的评价,初步了解其遗传多样性特点,为解决种质创新与品种改良遗传基础狭窄问题提供思路.对性状表现平均值、变异系数、遗传多样性指数研究结果表明,国内外不同地理来源豌豆资源群闻的遗传变异大;三维主成分分析探测到参试资源由国内和国外两大基因库构成;资源群体间遗传距离的UPG-MA聚类分析结果也表明,国内外豌豆资源聚成两大不同类群,印证了三维主成分分析得到的豌豆资源两大基因库构成的结论.本研究证明基于形态性状评价的遗传多样性分析结果同样可靠.     

198份大麻种质资源农艺及品质性状综合评价

本研究以198份国内外大麻种质资源为材料,开展了 14个农艺和品质性状多样性鉴定,并进行变异分析、相关性分析、主成分分析和聚类分析,为我国大麻种质资源创新和资源高效利用提供基础材料和技术参考.变异分析结果表明,198份国内外大麻种质资源具有较为丰富的遗传多样性,14个性状的变异系数范围为4.79％～64.45％,变异系...     

紫花苜蓿种质资源表型性状与品质多样性分析

旨在利用形态指标、农艺指标和品质性状指标探讨引进紫花苜蓿( M.sativa.)种质资源遗传多样性,为紫花苜蓿品种改良和选择亲本提供科学依据。研究了不同地理来源的75份紫花苜蓿种质资源的21项指标,利用主成分分析和聚类方法,了解其多样性。结果表明：不同紫花苜蓿种质的各特征存在广泛变异,农艺性状变异最大,随后是形态性状和品质性状;主成分分析结果显示前八个主成分累计贡献率达到82.77%,其中茎秆干重、叶干重、单株鲜重、单株干重4个性状是造成紫花苜蓿种质表型差异的主要因素;以21个性状为基础的聚类分析将所研究的75份种质材料分为5类。     

作物种质资源品质性状鉴定评价现状与展望

作物种质资源品质性状鉴定评价是作物种质资源研究的重要方面,是深入挖掘、广泛利用作物种质资源的基础。本文对近年来作物种质资源品质性状鉴定评价情况进行了回顾,总结了鉴定评价工作取得的主要进展:完成了近20万份的作物种质资源(约占保存总数的50%)主要营养品质性状的初步鉴定评价;作物种质资源品质鉴定评价内容涉及面广、鉴定的品质性状变异性大、多样性丰富;提高了作物种质资源品质性状鉴定评价标准化程度。此外还介绍了国际上有关品质性状鉴定的发展趋势,并对未来国内作物种质资源品质性状鉴定评价提出了意见和建议。     

Solute Heterogeneity and Osmotic Adjustment in Different Leaf Structures of Semi-Leafless Pea (Pisum sativum L.) Subjected to Water Stress

Abstract: Semi-leafless varieties of pea have considerable agronomic importance and it has been suggested that they may have a superior response to water deficits than conventional varieties. However, these varieties are poorly characterized from a physiological point of view and there is lack of a physiological basis for their supposed better performance under conditions of water deficit. Here, we describe the solute distribution in the different leaf structures of a semi-leafless pea variety ( Pisum sativum L.) under non-limiting water conditions and under water stress. A conventional variety was subjected to the same conditions for comparative purposes. A detailed study was carried out both at the tissue level and at the single cell level. In control conditions, epidermal vacuoles of tendrils showed a different ion distribution of those of the laminar leaf structures. However, under water deficit, only stipules of the semi-leafless variety showed a significantly higher capability to increase osmolarity. This occurred by accumulating potassium, magnesium and chloride to a higher extent than other leaf structures. The inability of performing an adequate osmotic adjustment in tendrils may be the cause of the lack of a better response to water deficit.     

Somatic embryogenesis in pea (Pisum sativum L.): effect of explant, genotype and culture conditions

In this study 16 cultivars of pea (Pisum sativum L.) were screened in vitro for the formation of somatic embryos which were dependent on the genotype, culture conditions and explant source used. The cultivars Stehgolt, Maro and Progreta showed the highest tendency to form somatic embryos (c. 25%) while Alaska, Rondo and Ascona did not show any embryo production. Using the cultivar Belman, the highest embryo production was achieved by using nodal explants of shoots (10.6%) and a cotyledon-free embryo as explant source (14.1%) in the light (15.8%) compared to using apices as explants (1.8%) and a seedling as the explant source (9.4%) in the dark (3.3%). Media containing picloram (0.75 mg/litre) followed by BA (1 mg/litre) or kinetin (1 mg/litre), each for four weeks gave the highest somatic embryo production. The development of embryos to whole plants was unreliable and some 90% of the embryos induced did not develop any further, died, recallused or formed secondary embryos. The size of the embryo at separation and the timing of the separation from the original callus were important factors determining success for complete development to whole plant. Regeneration of 184 plants was achieved with ensuing flowering, pod formation and viable seed production from the techniques described.     

褐藻胶寡糖对豌豆种子萌发和幼苗的某些生理特性的影响

褐藻胶寡糖(ADO)对豌豆种子萌发和幼苗生长有促进作用,种子发芽率升高,幼苗高度.根长、生物量均有增加;幼苗叶中叶绿素含量增高;叶片净光合速率、胞间CO_2浓度、气孔导度和蒸腾速率增加;根系活力增强;种子中α和β-淀粉酶活性增强。低浓度ADO的效果明显优于高浓度的ADO,其中以0.125?O的效果最佳。     

Effect of Sowing Date and Cultivar on Root System Development in Pea (Pisum sativum L.)

In many species, root system development depends on cultivar and sowing date, with consequences for aerial growth, and seed yield. Most of the peas (Pisum sativum L.) grown in France are sown in spring or in mid-November. We analyzed the effect of two sowing periods (November and February) and three pea cultivars (a spring cultivar, a winter cultivar, a winter recombinant inbred line) on root development in field conditions. For all treatments, rooting depth at various dates seemed to be strongly correlated with cumulative radiation since sowing. Maximum root depth varied from 0.88 to 1.06 m, with the roots penetrating to greater depths for February sowing than for November sowing in very cold winters. The earlier the crop was sown, the sooner maximum root depth was reached. No difference in root dynamics between cultivars was observed. In contrast, the winter recombinant inbred line presented the highest root density in the ploughed layer. These findings are discussed in terms of their possible implications for yield stability and environmental impact.     

Population genetic structure and classification of cultivated and wild pea (Pisum sp.) based on morphological traits and SSR markers

Pea (Pisum sativum L.) is an important legume crop that is widely grown worldwide for human consumption and livestock feed. Despite extensive studies, the population genetic structure and classification of cultivated and wild pea (Pisum sp.) remain controversial. To characterize patterns of genetic and morphological variation and investigate the classification of Pisum, we conducted comprehensive population genetic analyses for 323 accessions from cultivated and wild pea, representing three species of Pisum and utilizing 34 morphological traits and 87 polymorphic simple sequence repeat markers. First, we identified three distinct genetic groups among all samples. Group I was primarily composed of Pisum fulvum, Pisum abyssinicum, and some wild P. sativum accessions, whereas Groups II and III consisted of the two genetic groups under P. sativum that represented different geographic distributions of cultivated pea. Analyses of morphological variation revealed significant differences among the three species. Second, among pea germplasms representing eight taxa of Pisum, P. fulvum and P. abyssinicum possessed unique genetic backgrounds and morphological characteristics, corroborating their independent species status. The intraspecific subdivisions of P. sativum described by some authors were not supported in this study, with the exception of several genotypes of P. sativum subsp. elatius that clustered with P. fulvum and P. abyssinicum. Finally, we confirmed that the Chinese pea germplasm was genetically distinct and could be divided into two genetic groups, each of which included both spring-sowing and autumn-sowing ecotypes. These results provide a robust foundation for understanding pea domestication and the utilization of wild genetic resources of pea.     

Roots of Pisum sativum L. exhibit hydrotropism in response to a water potential gradient in vermiculite

In the present study, root hydrotropism in an agravitropic mutant of Pisum sativum L. grown in vermiculite with a steep water potential gradient was examined. When wet and dry vermiculite were placed side by side, water diffused from the wet (-0.04 MPa) to the dry (-1.2 MPa) and a steep water potential gradient became apparent in the dry vermiculite close to the boundary between the two. The extent and location of the gradient remained stable between the fourth and sixth day after filling a box with vermiculite, and the steepest gradient (approx. 0.02 MPa mm-1) was found in the initially dry vermiculite between 60 and 80 mm from the boundary. When seedlings with 25-35 mm long roots were planted in the initially dry vermiculite near where the gradient had been established, each of the main roots elongated toward the wet vermiculite, i.e. toward the high water potential. Control roots elongated without curvature in both the wet and the dry vermiculite, in which no water potential gradient was detectable. These results show that pea roots respond to the water potential gradient around them and elongate towards the higher water potential. Therefore, positive hydrotropism occurs in vermiculite just as it does in air. Hydrotropism in soil may be significant when a steep water potential gradient is apparent, such as when drip irrigation is applied.     

Field Assessment of Outcrossing from Transgenic Pea (Pisum Sativum L.) Plants

The frequency of outcrossing from a transgenic line of peas into three cultivars ('Carneval', 'Montana', 'Tipu') was studied in the field in 1997 and 1999. Two dominant traits, normal leaf form and a highly-expressed -glucuronidase (gusA) gene, were used as markers of pollen transfer. Because of heterogeneity in the commercial seed sources, leaf form alone was unreliable for assessing pollen migration into 'trap' plants. Of approximately 9000 offspring tested, only five plants scored positive for the presence of both markers. All five were located in 'trap' plots situated near the transgenic line. This represents a mean outcrossing rate of 0.07%.