Analysis of Dynamic Accumulation of Three Types of Glutenin Subunits and Their Content in Relation to Sedimentation Value in Common Wheat

The biosynthetic time and accumulations of A-, B-, and C-type glutenin subunits in 7 winter wheat cultivars with different quality （strong, medium, weak gluten） were analyzed by SDS-PAGE. The results showed that no glutenin subunit was observed within 8 d after anthesis. Parts or all A-, B-, and C-type subunits appeared around day 12 in different cultivars. Other A-, B-, and C-type subunits appeared gradually. The accumulation of A-, B-, and C-type subunits fluctuated before maturity. The results of analysis of correlation between the ratios of A/T （total content of glutenin subunits）, A/C, AJ （B＋C）, （A＋B）/C, and （A＋B）/T and SDS-sedimentation value suggested that they were more significant. The negative correlation between the ratio of （B＋C）/T and SDS-sedimentation value was more significant, and the correlations between the ratio C/T and the SDS-sedimentation value were significantly negative.

Study on Relationship Between the Size Distribution of Glutenin Polymeric Protein and Wheat Flour Mixing Properties

Parental varieties Suneca and Cook have contrasting alleles at each of the five glutenin subunit loci (Glu-B1, Glu-D1 Glu-A3, Glu-B3, and Glu-D3), a set of 60 lines homozygous at these loci from the F4 progeny population of Suneca X Cook was chosen to analyze the variation of the size distribution of glutenin polymeric protein (measured by SE-HPLC) and flour mixing properties of these lines and to study relationship between the size distribution of glutenin polymeric protein and wheat flour mixing properties. The results showed that there were very significant differences among the relative size distributions of glutenin polymeric protein (i.e. percentage of unextracTable polymeric protein in the total polymeric protein, or UPP%) and dough development times (i.e. peak time of mixograph, or PTM) of different homozygous lines, respectively. Flour mixograph shape was closely related to UPP% value. The results also indicated that UPP% was very strongly positive correlation with PTM and negative correlation with peak height of mixograph (PHM). Comparing with flour protein content (FP%), UPP% gave greater effect on PTM and PHM, i.e. flour mixing properties, and it can be considered as one of criteria for quality selecting from early generation of breeding program.

Effect of high-nitrogen fertilizer on gliadin and glutenin subproteomes during kernel development in wheat(Triticum aestivum L.)

Nitrogen(N),a macronutrient essential for plant growth and development,is needed for biosynthesis of protein and starch,which affect grain yield and quality.Application of high-N fertilizer increases plant growth,grain yield,and flour quality.In this study,we performed the first comparative analysis of gliadin and glutenin subproteomes during kernel development in the elite Chinese wheat cultivar Zhongmai 175 under high-N conditions by reversed-phase ultra-performance liquid chromatography and twodimensional difference gel electrophoresis(2D-DIGE).Application of high-N fertilizer led to significant increases in gluten macropolymer content,total gliadin and glutenin content,and the accumulation of individual storage protein components.Of 126 differentially accumulated proteins(DAPs)induced by high-N conditions,24 gliadins,12 high-molecularweight glutenins,and 27 low-molecular-weight glutenins were significantly upregulated.DAPs during five kernel developmental stages displayed multiple patterns of accumulation.In particular,gliadins and glutenins showed respectively five and six accumulation patterns.The accumulation of storage proteins under high-N conditions may lead to improved dough properties and bread quality.

Composition and Content of High-Molecular-Weight Glutenin Subunits and Their Effects on Wheat Quality

Sedimentation values, flour glutenin macropolymer (GMP) contents, composition and contents of high-molecular-weight (HMW) glutenin subunits (GS) of 233 flour samples were determined. Our data indicated that subunit 1 occurred more frequently at Glu-A1 , subunit pair 7 + 8 at Glu-B1 and 2 + 12 at Glu-D1. The significant relationships between Glu-1 quality score and total HMW glutenin content, sedimentation value and GMP content suggested that the composition of HMW-GS affects wheat quality strongly. Moreover, the total content of HMW-GS was correlated with certain quality parameters more significantly. Relationship between subunit 5 + 10 content and breadmaking quality was better than others, but 2 + 12, 7 + 8, 7 + 9 and 4 + 12 also correlated with certain quality parameters significantly. The contents of total HMW-glutenin, x-type subunits and y-type subunits related with sedimentation value, flour GMP content, and Glu-1 quality score more strongly than that of individual subunit or subunit pair. The flour GMP content, with excellent correlation to sedimentation value, total contents of HMW glutenin, x- and y-type subunits and many other quality parameters, could be an ideal indicator of breadmaking quality at earlier generations for breeding purpose for its simple procedure and small scale.

Allelic Variation and Genetic Diversity at HMW Glutenin Subunits Loci in Yunnan, Tibetan and Xinjiang Wheat

Allelic variation and genetic diversity at HMW glutenin subunits loci, Glu-A1, Glu-B1and Glu-D1 were investigated in 64 accessions of three unique wheats of western Chinausing sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE). Two HMWglutenin patterns (i.e., null, 7+8, 2+12 and null, 7, 2+12) in 34 Yunnan wheataccessions, 3 HMW glutenin patterns (i.e., null, 7+8, 2+12; null, 6+8, 2+12 andnull, 7+8, 2) in 24 Tibetan accessions and 1 HMW glutenin pattern (null, 7, 2+12) in6 Xinjiang wheat accessions were found. The Tibetan accession TB18 was found to be witha rare subunit 2 encoded by Glu-D1. A total of 4 (i.e., Glu-A1c, Glu-B1a, Glu-B1b andGlu-D1a), 5 (i.e., Glu-A1c, Glu-B1d, Glu-B1b, Glu-D1a and Glu-D1) and 3 alleles (i.e.,Glu-A1c, Glu-B1a and Glu-D1a) at Glu-1 locus were identified among Yunnan, Tibetan andXinjiang unique wheat accessions, respectively. For Yunnan wheat, Tibetan wheat andXinjiang wheat, the Neis mean genetic variation indexes were 0.1574, 0.1366 and 0,respectively, which might indicate the higher genetic diversity at HMW glutenin subunitsloci of Yunnan and Tibetan wheat accessions as compared to that of Xinjiang wheataccessions. Among the three genomes of hexaploid wheats of western China, the highestNeis genetic variation index was appeared in B genome with the mean value of 0.2674,while the indexes for genomes A and D were 0 and 0.0270, respectively. It might bereasonable to indicate that Glu-B1 showed the highest, Glu-D1 the intermediate and Glu-A1 always the lowest genetic diversity.

High-Molecular-Weight Glutenin Subunit Composition of Chinese Wheat Germplasm

The objective of the present study was to characterize the high molecular glutenin subunits （HMW-GS） composition and the presence of 1B/1R translocation in newly developed wheat （Triticum aestivum L.） germplasm, which have one or more traits that are useful in wheat improvement. Sodium dodecyl sulphate polyacrylamide-gel electrophoresis （SDS-PAGE） and acid polyacrylamide-gel electrophoresis （A-PAGE） were used to detect HMW-GS composition and the presence of 1B/1R wheat-rye （Secale cereale L.） chromosome translocation in the wheat germplasm. Bread-making quality scores of these lines were determined. A high level of variations in HMW-GS encoded by Glu-1 locus was observed. Sixteen major HMW-GS, with 30 combinations, were detected. The percentage of cultivars with more than two desirable subunits was 38.7%. Thirteen cultivars had bread-making quality scores of 10 in combination with one or two desirable agronomical traits, such as high-yield potential, dwarfing stem, resistance to diseases, and/or tolerance to abiotic stress. Sixty-eight （36.6%） cultivars possessed 1B/1R translocation. The newly developed germplasm with HMW-GS for good quality can be promising resources for improving bread-making quality of wheat.

引进美国小麦种质资源抗病性及品质性状鉴定

为了挖掘新的种质资源,本研究对引自美国的442份小麦材料对白粉病和条锈病的抗病性、蛋白含量以及高分子量麦谷蛋白(HMW-GS)亚基组成进行了鉴定分析。抗病性鉴定结果显示,153份材料抗白粉病,27份抗条锈病,6份兼抗两种病害。蛋白质含量达到GB/T 17892-1999《优质小麦强筋小麦》一等(粗蛋白质含量≥15.0%)的样品有143份。高分子量麦谷蛋白检测发现,供试材料共含18种HMW-GS亚基和100种不同亚基组合类型,其中N,7+9,5+10出现次数最多,优质亚基1、2*、7^(oe)、17+18、5+10的材料分别占总材料数的25.6%、5.2%、27.8%、7.7%和25.6%,含7^(oe),5+10亚基的有36份,含2*,5+10亚基的有1份,含2*,7^(oe)亚基的有7份。综合抗病性及品质分析结果显示,PI 17738等11份材料至少抗1种病害,且蛋白含量≥15.0%,湿面筋含量≥35.0%,同时含有稀有优质亚基。以上11份材料可作为我国优质、抗病小麦培育亲本,为我国小麦抗病和品质遗传改良提供优异基因源。

7^(OE)+8^(*)亚基对东北强筋小麦品种品质性状影响研究

小麦品质改良是东北春麦区强筋小麦育种的主要目标之一。Glu-B1位点7^(OE)+8^(*)亚基为超强筋小麦品种必备基因。为了明确该亚基在东北春麦区强筋小麦遗传背景下的品质遗传效应,本研究利用分子标记和选择回交相结合的手段,将7^(OE)+8^(*)亚基定向导入到强筋小麦品种龙麦26和龙麦35(Glu-B1位点均为7+9亚基)的遗传背景之中,对BC_(5)F_(1)、BC_(6)F_(1)群体和自交BC6F2鉴定获得的纯合品系进行7^(OE)+8^(*)亚基遗传效应评价。结果表明,在强筋小麦品种龙麦26(7+9)和龙麦35(7+9)遗传背景下转入7^(OE)+8^(*)亚基后,其干面筋、面筋指数、形成时间、稳定时间、断裂时间、拉伸面积、延伸性和最大抗延阻力等品质指标3年平均分别提高1.3%(P=0.82)和1.8%(P=0.49)、6.6%(P=0.59)和4.7%(P=0.37)、55.0%(P=0.24)和35.8%(P=0.56)、44.5%(P=0.43)和32.8%(P=0.73)、41.4%(P=0.31)和30.0%(P=0.66)、28.0%(P=0.05)和23.4%(P=0.37)、6.5%(P=0.47)和5.8%(P=0.42)、19.5%(P=0.31)和18.0%(P=0.38);Zeleny沉降值2年平均分别提高6.8%和11.4%。以上结果表明,在2个强筋小麦品种遗传背景下,Glu-B1位点转入7^(OE)+8^(*)亚基较7+9亚基对各项品质指标改良均存在正向效应,但提高幅度存在差异,对形成时间、稳定时间、断裂时间、最大抗延阻力、拉伸面积等衡量面筋质量的指标提高幅度更大,表明该亚基对面筋质量改良效应显著。综上所述,7^(OE)+8^(*)亚基可作为东北春麦区强筋小麦遗传背景下品质性状进一步改良的优选基因,为超强筋小麦育种的重要基因资源。

甘肃冬小麦品种(系)面粉品质性状相关基因分析

为了解甘肃省近20年育成的106份冬小麦品种(系)中加工品质性状相关基因分布情况,用22个分子标记对供试材料的HMW-GS、LMW-GS、面粉色泽及籽粒硬度等品质性状相关基因进行了分析。结果发现,供试品种(系)的HMW-GS相关基因中,在Glu-A1位点检测到34份品种(系)含有AxNull,频率为32.08%;在Glu-B1位点检测到Bx7+By8和Bx14+By15共2种基因组合,分别占17.92%和25.47%;在Glu-D1位点检测到11份品种(系)含有Dx5+Dy10,占10.38%。对LMW-GS鉴定结果显示,29份品种(系)含Glu-A3d基因,分布频率为27.36%。HMW-GS和LMW-GS亚基组合中,含有4个、3个和2个位点优质亚基基因组合的品种(系)分别占0.94%、8.49%和3.77%。对面粉色泽相关基因Ppo-A1、Ppo-D1、Psy-A1、Lox-B1和TaPod-A1位点的检测发现,优异等位变异占比分别为39.62%、50.94%、31.13%、30.19%和38.68%。对籽粒硬度相关基因检测发现,在Pina、Pinb和Pinb-2等位变异位点的检测到6种基因型,分别为Pina-D1a、Pina-D1b、Pinb-D1a、Pinb-D1b、Pinb-2v2和Pinb-2v3,分别占比90.57%、9.43%、41.51%、58.49%、14.15%和85.85%。综上所述,甘肃省近20年育成的小麦品种(系)中,麦谷蛋白亚基、籽粒硬度和面粉色泽相关基因组成丰富,但品质性状相关优质基因出现频率低且聚合多位点优势基因品种(系)少,品质改良工作亟需进一步加强。

优质强筋春小麦种质筛选及高分子量谷蛋白序列分析

小麦是重要的口粮作物,加工品质的遗传改良是小麦育种的重要目标之一。为了丰富小麦加工品质育种的基因资源,本研究在收集的种质资源中筛选出农艺性状优良的SG-1、SG-2和SG-3,并对其进行加工品质分析和籽粒储藏蛋白组成分析,并评估它们在育种上的利用价值和方式,使用SDS-PAGE、A-PAGE、高分子量谷蛋白亚基编码基因测序、SDS沉降值分析等技术,对这些小麦品种的籽粒储藏蛋白亚基组成进行分析。研究发现,SG-1携带非优质的高分子量谷蛋白亚基Dx2+Dy12,而SG-2和SG-3携带优质的高分子量谷蛋白亚基Dx5+Dy10。在醇溶蛋白方面,3份资源都检测到了γ-1型醇溶蛋白,但只有SG-3检测到了γ-2型醇溶蛋白。加工品质分析显示,SG-1的加工品质优于天津推广的优质强筋春小麦品种津强6号。高分子量谷蛋白亚基序列分析发现,SG-1和SG-3在By8亚基存在序列变异,表明尽管它们在SDS-PAGE水平上亚基类型一致,但在DNA序列上仍然存在变异。本研究结果初步解释了携带优质亚基的小麦品种在加工品质上表现不佳的原因可能是DNA序列存在差异。同时,研究人员还发现携带非优质亚基但具有优良加工品质的SG-1,说明SG-1可能存在其他能够提升小麦加工品质的机制。本研究拓宽了小麦加工品质育种的基因资源,并为加工品质形成机制的解析提供了新的资源和理论依据。

超微粉碎协同麦谷蛋白改善麦麸理化和功能特性的研究

基于食品组分相互作用研究超微粉碎协同麦谷蛋白对麦麸理化和功能特性的影响,揭示超微粉碎时间(5、10、15、20、25、30 min)及不同超微粉碎工艺(超微粉、混匀粉、复合粉)处理下,麦麸颜色、粒径、膳食纤维含量及功能特性的变化规律。结果显示:在粉碎时间超过20 min时,超微粉碎协同麦谷蛋白处理的复合粉显著提高了麦麸超微粉的L^(*)值,降低了a^(*)值、b^(*)值和麦麸粒径;在粉碎时间为30 min时,超微粉碎协同麦谷蛋白处理显著降低了麦麸超微粉不溶性膳食纤维含量,增加了可溶性膳食纤维含量,显著提高了麦麸超微粉的膨胀率(P<0.05);通过扫描电镜对其微观结构观察发现,超微粉碎协同麦谷蛋白处理的复合粉颗粒尺寸更小,颗粒间的孔隙较多。

Effect of HMW-GS 5+10 on Quality Parameters in Four Leading Wheat Cultivars

HMW-GS 5 + 10 was introduced to four major wheat cultivars Kehan9, Kefeng3, Longmai20 and Kenda4 through 5 or 6 consecutive backcrosses. No significant difference in protein content and dry gluten content was observed between cultivars containing 5 + 10 and 2 + 12 or 3 + 12 (P>0.1). In cultivars containing HMW-GS 5 + 10, the ratio of wet gluten content to dry gluten content was 2. 9 - 5.0% (P<0. 01) lower than the ratio from the cultivars containing 2 + 12 or 3 + 12, the ratio of Zeleny sedimentation volume to dry gluten content was 4. 5 - 13. 4% (P<0.05) higher. The degree of softening in cultivars having 5 + 10 was 15 -25 FU (P<0. 01) lower, while the maximum resistance was 82 - 193 EU (P<0. 05) higher. Backcrosses with biochemical marker assisted selection in the improvement of quality in wheat cultivars was discussed.

Allelic Variation and Genetic Diversity at Glu-1 Loci in Chinese Wheat (Triticum aestivum L.) Germplasms

Wheat processing quality is greatly influenced by the seed proteins especially the high molecular weight glutenin subunit (HMW-GS) components, the low molecular weight glutenin subunit (LMW-GS) components and gliadin components. Genes encoding the HMW-GS and LMW-GS components were located on the long arms and the short arms of homoeologous group 1 chromosomes, respectively. HMW-GS components in 5 129 accessions of wheat germplasms were analyzed systematically, including 3 459 landraces and 1 670 modern varieties. These accessions were chosen as candidate core collections to represent the genetic diversity of Chinese common wheat ( Triticum aestivum) germplasms documented and conserved in the National Gene Bank. These candidate core collections covered the 10 wheat production regions in China. In the whole country, the dominating alleles at the three loci are Glu-A1b (null), Glu-B1b (7 + 8), and Glu-D1a (2 + 12), respectively. The obvious difference between the land race and the modern variety is the dramatic frequency increase of alleles Glu-A1a (1), Glu-B1c (7 + 9), Glu-B1h (14 + 15), Glu-D1d (5 + 10) and allele cording 5 + 12 subunits in the later ones. In the whole view, there is minor difference on the genetic(allelic)richness between the landrace and the modern variety at Glu-1, which is 28 and 30 respectively. However, the genetic dispersion index (Simpson index) based on allelic variation and frequencies at Glu-A1, Glu-B1 and Glu-D1 suggested that the modern varieties had much higher genetic diversity than the landraces. This revealed that various isolating mechanisms (such as auto-gamous nature, low migration because of undeveloped transposition system) limited the gene flow and exchange between populations of the landraces, which led up to some genotypes localized in very small areas. Modern breeding has strongly promoted gene exchanges and introgression between populations and previous isolated populations. In the three loci, Glu-Bl has the highest genetic diversity , then Glu-D1, while Glu-A1 always keeps the lowest genetic diversity. In the landrace, the three regions with the highest allelic richness are Huanghuai Winter Wheat Region, Northwest Spring Wheat Region and Southwestern Winter Wheat Region. For the bred varieties, the highest allelic richness existed in Southwest Winter Wheat Region, Huanghuai Winter Wheat Region, Low & Middle Branch Winter Wheat Region of Yangtze River. Introduction and utilization of foreign varieties in cross breeding has had great effects on the allelic components and frequency of the three loci, which greatly affected the genetic dispersion index. This has made 'population' of the modern variety quite different from that of the landrace.

Allelic Variation of Glu-A1, Glu-B1 and Glu-Dl in Chinese Released Wheat Varieties in the Last 50 Years

: The high-molecular-weight glutenin subunit (HMW-GS) components from about 85 varieties were fractionated by SDS-PAGE, including 22 corner stone breeding parents, 45 varieties taking important role in Chinese wheat production and 18 varieties with good bread making quality. The 22 corner stone breeding lines carry either null (c) or l(a) summits on Glu-Al loci. Five types are detected on Glu-Bl, which are 7 + 8(b), 7 + 9 (c), 14 + 15 (h), 17 + 18 (i), 6 + 8 (d). 7 + 8 and 7 + 9 are the two major types. Six types have been detected on Glu-Dl, which are 2 + 12 (a), 2 + 10 (e), 5 + 10 (d), 4 + 10 (j), 4 + 12 (c), 2 + 11 (g). 2 + 12 and 2 + 11 are the two major types. In the corner stone breeding lines, early premium from American carries 5 + 10, St2422/464 from Italy carries the 14 + 15. In addition, two relatively essential varieties, Mara and Alondra carry 5 + 10. In the 45 commercialized varieties, sowed more than 666 000 ha (10 million mu) annually, only Yangmai 5 conveys the 5 + 10 on Glu-Dl, and Xiaoyan 6 and Yumai 7 carry the 14 + 15 on Glu-B1. Four varieties, Funo, Nongda 139, Zhengzhou 683 and Fan 6 convey the 17 + 18 on Glu-B1. The 18 bread wheat varieties recommended by the Ministry of Agriculture in 1992 could be classified into two groups, 5 + 10 and 14 + 15. Zhongzuo 8131 and its selections are the typical genotype of 5 + 10. Genes coding the two subunits are from either Yecora F-70 or IRN68-181. Xiaoyan 6 and its derivative varieties are the typical genotype of 14 + 15. The genes coding 17 + 18 subunits in Chinese varieties were derived from Funo or its selections. These results basically reflect allelic changes on Glu-1 in Chinese wheat varieties in the past 50 years. It is also proven that HMW-GS components may have great diversity between lines from the same cross, which causes great difference on baking quality.

Swelling Index of Glutenin (SIG) Related to Protein Quality, DoughCharacters and Noodle Quality

The swelling index of glutenin (SIG) and the protein fraction of 25 Chinese wheat varieties were studied with new protein fractions extracting method. The protein fractions compose of monomeric protein, soluble glutenin and insoluble glutenin. The relations between other protein index, dough character, and fresh noodle quality were also discussed. The SIG results at different time is positively and highly significantly related to the insoluble glutenin content (r= 0.808 -0.867, P< 0.01). The SIG result can reflect the insoluble glutenin content. The protein content, gluten index, farinograph stability time, extensibility length and extensigram energy were positively and significantly correlated with SIG5 and SIG20 (r= 0.516 - 0.734, P<0.05, 0.01).SIG proved to be applicable in Chinese wheat dough evaluation. Fresh noodle making quality parameters were evaluated by fresh noodle length, thickness, maximum resistance to extension, extension area and extension distance, while cooked noodle texture was determined by cutting firmness, compression recovery, surface firmness and TPA by using a texture analyzer of TA.XT2i. The noodle cooking quality was significantly correlated with SIG value. The surface firmness and cutting firmness were more desirable for predicating the quality difference than TPA test and compression. Cooking loss and water absorption were negatively related to SIG value and insoluble content (r = -0.556 - - 0.787, P < 0.05, 0.01). The results showed that SIG test was also suitable in evaluating noodle making and cooking quality in very small sample size, which was very important in wheat breeding programs. Therefore, SIG test, as a small scale test, is suitable to evaluate dough rheological properties for Chinese wheat varieties, and will be helpful in cereal research and wheat breeding program, especially, in early generations.

强筋小麦贮藏蛋白的积累动态、种类及相对含量分析

小麦贮藏蛋白是面粉品质的主要评价指标。本研究以不同高分子量麦谷蛋白亚基组合的强筋小麦(济麦44和济麦229)和中筋小麦(济麦22)为试材,分析强筋小麦和中筋小麦及4+12和5+10高分子量麦谷蛋白亚基组合的籽粒醇溶蛋白、麦谷蛋白及谷蛋白大聚合体(GMP)在小麦灌浆期的积累动态和成熟籽粒中的贮藏蛋白种类、相对含量。结果表明,强筋小麦和中筋小麦的麦谷蛋白和醇溶蛋白在整个小麦灌浆期的积累趋势相同,均持续上升,但GMP积累却存在较大差异,强筋小麦的GMP含量持续增加而中筋小麦呈“下降-上升-下降-上升”的趋势。从高分子量麦谷蛋白亚基组成类型上看,5+10亚基组合的醇溶蛋白、麦谷蛋白及GMP在灌浆中后期的含量均高于4+12亚基组合类型。通过TMT(tandem mass tags)蛋白质组学分析发现,3个小麦品种的成熟籽粒共检测到53个贮藏蛋白,共分为三类,包括27个醇溶蛋白、16个Avenin-like蛋白和10个麦谷蛋白。济麦44较济麦22相对含量高的原因是大多数贮藏蛋白的表达量高,而济麦229相对含量高的原因是部分贮藏蛋白超高量表达。本研究结果可为我国小麦品质改良和优质小麦生产提供技术参考。

强筋小麦龙麦26Glu-A3d基因遗传效应初步研究

龙麦26是东北春麦区强筋小麦育种的核心亲本,为进一步提高该品种品质潜力,拓宽其遗传基础,利用分子标记和6次选择性回交相结合的手段,将Glu-A3位点最优基因Glu-A3d导入龙麦26遗传背景之中,利用BC5F1、BC6F1群体和龙麦26的Glu-A3位点近等基因系为试材进行Glu-A3d基因遗传效应评价。结果表明,在强筋小麦品种龙麦26遗传背景下,导入Glu-A3d基因使籽粒蛋白、干面筋、面筋指数、吸水率、形成时间和稳定时间等指标3年平均分别提高0.07%、-2.13%、10.73%、0.13%、1.57%和4.97%。Zeleny沉降值和粉质仪的断裂时间2年平均分别提高3.05%和12.65%。以上结果表明,导入Glu-A3d基因使龙麦26品质性状均有不同程度提高。

A genetic evidence of chromosomal fragment from bridge parent existing in substitution lines between two common wheat varieties

Locating of important agronomic genes onto chromosome is helpful for efficient development of new wheat varieties. Wheat chromosome substitution lines between two varieties have been widely used for locating genes because of their distinctive advantages in genetic analysis, compared with the aneuploid genetic materials. Apart from the substituted chromosome, the other chromosomes between the substitution lines and their recipient parent should be identical, which eases the gene locating practice. In this study, a set of chromosome substitution lines with cv. Wichita （WI） as the recipient parent and cv. Cheyenne （CNN） as the donor parent were studied for the composition of high molecular weight glutenin subunits （HMW-GS） as well as a range of agronomic important traits. Results revealed that the substitution lines of WI（CNN5D）, WI（CNN6A） and WI（CNN7B） had higher plant heights than the two parents of WI and CNN, and WI（CNN3D） had later maturity than the parents. By sodium dodecyl sulfate polyacrylamide gel electrophoresis （SDS-PAGE） and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry （MALDI-TOF-MS） analysis, a substitution line WI（CNN5B） was found to contain different HMW-GS patterns from its two parents, in which 1 By9 was replaced by 1 By8 on chromosome 1BL. Simple sequence repeat （SSR） analysis confirmed that the variation on 1BL in WI（CNN5B） was originated from Chinese Spring （CS）. It is concluded that chromosomal fragments from bridge material and donor parent were quite often retained in intracultivaral chromosome substitution lines except the substituting chromosomes.

反相超高效液相色谱分析小麦麦谷蛋白组分研究

为利用反相超高效液相色谱(RP-UPLC)分离、定量分析小麦麦谷蛋白组分,研究了流动相比例、洗脱时间、柱温、流速和进样量对色谱分离结果的影响,并利用新建立的分离麦谷蛋白亚基的方法分析了基因型及环境对麦谷蛋白组分的影响。结果表明,最优的洗脱程序为79%的流动相A(含0.08%三氟乙酸的超纯水)和21%的流动相B(含0.08%三氟乙酸的乙腈溶液)洗脱5 min,在25 min内,流动相A逐渐降低至48%,流动相B逐渐增加至52%,最后维持5 min,柱温、流速和进样量分别为55℃、0.5 mL·min^(-1)和16μL,该方法可以精确分离至少11种高分子量麦谷蛋白亚基(HMW-GS)。单个HMW-GS的相对含量和HMW-GS与低分子量麦谷蛋白亚基(LMW-GS)的比值均受基因型和环境的影响,且基因型的影响大于环境。

叶面喷施钼锌肥对冬小麦籽粒品质的影响

【目的】探明钼锌肥配施对冬小麦籽粒品质的影响,为钼锌肥的应用及冬小麦籽粒品质的改善提供参考。【方法】在河南省冬小麦产区开展叶面喷施钼锌试验,以喷施清水为CK,设置喷施0.10%钼肥、喷施0.10%锌肥、喷施0.10%钼肥+0.10%锌肥处理,考察不同处理小麦籽粒品质的变化。【结果】叶面单独施钼、单独施锌和钼锌配施能有效提高冬小麦籽粒中支链淀粉含量,在一定程度上能增加淀粉总量;钼锌配施能有效提高冬小麦籽粒中醇溶蛋白和麦谷蛋白含量。与CK相比,钼锌配施冬小麦籽粒中钼含量提高0.03~0.09 mg/kg,增幅为10.34%~39.13%;锌含量增加0.88~4.34 mg/kg,增幅为3.65%~18.11%。【结论】冬小麦叶面喷施钼肥与锌肥均能有效提高籽粒中支链淀粉含量,钼锌配施能有效提高籽粒中醇溶蛋白和麦谷蛋白含量,钼锌肥在优质冬小麦生产中具有较高的应用价值。