Changes in the glutathione thiol-disulfide status in wheat grain by foliar sulphur fertilization: consequences for the rheological properties of dough

Storage proteins and glutathione in wheat play an important role in gluten network formation and can be modified by supplementation of nitrogen (N) and sulphur (S) in wheat plants. The glutathione thiol-disulfide status and its relationship to the molecular weight distribution wheat polymeric protein and dough rheological properties have been examined after different foliar S fertilizations (S derived from micronized elemental S and NS, a mixture of N urea and elemental S) applied at the post-anthesis stage. Changes in levels of reduced glutathione (GSH), glutathione disulfide (GSSG), polymeric protein-glutathione mixed disulfide (PPSSG) were analysed by reversed phase high performance liquid chromatography, during grain development using the wheat cultivars, Soissons and Trémie. During the grain desiccation phase, S supplementation (i) increased the GSSG/GSH ratio by 23–25% (ii) induced PPSSG accumulation, and (iii) decreased the formation of SDS-unextractable polymeric protein (UPP) and its molecular mass distribution. However, simultaneous N and S supplementation results in: (i) a decrease in PPSSG formation by 20–30% and (ii) an increase of UPP by 7–18% by enhancing both the branching of the aggregated proteins and their molecular weight. The mixograph parameters show that all forms of endogenous glutathione are linked to dough weakening and are negatively correlated with dough mixing tolerance, dough strength and consistency, while UPP is positively correlated with dough strength and consistency. These findings indicate that S nutrition influences dynamics of the glutathione forms in the grain and results in modification the degree of polymerization of storage protein. Thus both the changes in the form of glutathione and protein polymerization influence the rheological properties of dough.     

表达大肠杆菌K88ac-ST1-LTB融合蛋白工程菌株的免疫原性研究

已构建的能表达大肠杆菌K88ac-ST1-LTB融合蛋白的工程菌株BL21（DE3）（pXKST3LT5)及其表达产物经动物试验证实没有毒性反应。用从IPTG诱导的工程菌中提取的包涵体或经甲醛灭活的工程菌制成抗原，免疫小鼠，结果免疫小鼠至少能抵抗2MLD的大肠杆菌强毒株C83902（K88ac,ST^ ,L^ )的攻击，用提取的包涵体免疫家兔后，采集的血清能够中和天然ST1的毒性，这表明构建的工程菌株BL21（DE3）（pXKST3LT5)可以作为预防幼畜大肠杆菌性腹泻基因工程菌苗的候选株。     

小麦远缘杂交后代节燕98-2分离类型贮藏蛋白的研究

采用A-PAGE和SDS-PAGE聚丙烯酰胺凝胶电泳方法,对远缘组合分离出来的节燕98-2类型入选11个遗传性基本稳定的具有高产、多抗的小麦株系的醇溶蛋白和高分子量谷蛋白亚基进行了分析.结果表明,在A-PAGE电泳分析中,11个供试株系具有11种不同的醇溶蛋白带型.在SDS-FAGE电泳分析中,出现了7种不同的高分子量谷蛋白亚基(HMW-GS)及6种亚基组合类型,优质亚基及亚基组合所占的比例较少,品质评分偏低,其变幅为5～8分,平均为6.36分.但在所分析的材料中,出现了一个少见的特殊亚基:2 10 12.并研究了这些HMW-GS和组合频率及特点.11个株系中7个具有45 10优质亚基和2个具有2*亚基,它们可供小麦优质育种利用.研究表明,通过远缘杂交能够选育出具有高产、抗病和优质的小麦新材料.     

高分子量麦谷蛋白亚基的品质效应研究进展

介绍了小麦高分子量谷蛋白亚基(HMW—GS)的遗传，不同基因位点及位点内各等位亚基对品质的效应等研究进展，提出了通过回交转育创建几套不同高分子量谷蛋白亚基的近等基因系群，然后在同一遗传背景和不同遗传背景条件下分析高分子量谷蛋白亚基及其组合的品质效应及与遗传基础的关系。     

Molecular characterization of Ascaridia galli from Bangladesh and development of a PCR method for distinguishing A. galli from Heterakis spp.

We analyzed the nuclear ribosomal internal transcribed spacer (ITS) 1 and ITS2 sequences for Bangladesh isolates of Ascaridia galli, and we determined that the sequences were unreliable as molecular markers for distinguishing A. galli from other Ascaridia species, because the sequences showed high identity with that of A. columbae. However, the ITS1 sequences were available for designing PCR primers distinguishable between Ascaridia galli and Heterakis spp. Bangladesh isolates of A. galli constituted a monophyletic clade along with other geographical isolates in the cytochrome c oxidase subunit I (COI) phylogenetic tree, however, we could not clarify the phylogenetic relationships between A. galli and other Ascaridia spp., because their available sequences in GenBank were very few. The developed PCR method using DNA from A. galli and Heterakis spp. eggs would enable differential diagnosis of the individual infections in the future.     

陕西省部分小麦栽培品种高分子量麦谷蛋白亚基组成及其与品质关系

本研究以36个陕西省主要栽培品种为材料,利用SDS-PAGE方法分析了高分子量麦谷蛋白亚基组成,并对其SDS沉淀值进行了测定,分析了高分子量麦谷蛋白亚基组成与代表面包烘烤品质的SDS沉淀值间的关系.结果表明:Glu-1位点存在着广泛的等位基因变异,在所分析的36个品种中,Glu-A1位点亚基1出现频率最高,为63.9%;Glu-B1位点等位基因变异最丰富,其中亚基7 8和7 9出现频率最高,其次为亚基14 15;Glu-D1位点亚基组成以2 12为主;对各位点品质评分与SDS沉淀值的简单相关分析结果表明各位点品质评分与SDS沉淀值均存在着显著或极显著相关关系,各位点影响大小依次为Glu-D1＞Glu-A1＞Glu-B1;Glu-1品质评分与SDS沉淀值极显著正相关.     

大豆(Glycine max) GmDREB5互作蛋白GmGβ1的筛选及鉴定

从大豆(Glycine max)中克隆了一个与抗逆相关的DREB (Dehydration Responsive Element Binding Protein) 基因GmDREB5。功能分析证明, GmDREB5基因能够显著提高烟草的抗旱性和耐盐性。为了筛选GmDREB5的互作蛋白, 采用酵母双杂交系统以GmDREB5蛋白73~226位氨基酸区段为诱饵筛选干旱处理的大豆cDNA文库, 发现一个互作蛋白含有保守的WD40结构域, 与棉花(Gossypium hirsutum)和水稻(Oryza sativa)的G蛋白β亚基分别具有61%和52%的同源性, 说明蛋白可能是一类新的大豆G蛋白β亚基, 将其定名为GmGβ1。将GmDREB5与GmGβ1共转化酵母菌株AH109, 转化的酵母能够在四营养缺陷型培养基上(SD/ trp- leu- his- ade-)正常生长, 而对照不能生长; 同时, 共转化的酵母能够激活LacZ报告基因的表达, 证明GmGβ1与GmDREB5之间存在相互作用。表达特性分析表明, GmGβ1基因受干旱、低温、高盐等胁迫和激素ABA处理的诱导而表达, 证明GmGβ1不仅参与植物对非生物胁迫的响应, 同时参与对GmDREB5蛋白水平的调控。     

施氮水平对7S亚基缺失大豆根系形态和结瘤固氮的影响

为有效推广功能型大豆7S亚基缺失品种,以7S亚基缺失大豆品系东富2号为研究对象,设置4种施氮水平(纯N),N0(0 mg·kg~(-1))、N1(25 mg·kg~(-1))、N2(50 mg·kg~(-1))、N3(75 mg·kg~(-1)),采用桶栽法研究大豆根系形态和结瘤固氮对不同施氮水平的响应。结果表明:N1(25 mg·kg~(-1))水平下根系干重加大,根冠比增大,根瘤固氮潜力高,单株产量较高。N2(50 mg·kg~(-1))水平下根长、根表面积、根体积在生育后期增长较快,根系干重较大,根冠比低,固氮酶活性最高,单株籽粒产量最高。N3(75 mg·kg~(-1))水平下植株干重较大,无效生长较多,根瘤数少,固氮潜力和根冠比低,单株产量不高。综合籽粒产量和根系特性指标,功能型大豆7S亚基缺失品系东富2号的适宜施肥量为25~50 mg·kg~(-1)。     

Survey and new insights in the application of PCR‐based molecular markers for identification of HMW‐GS at the Glu‐B1 locus in durum and bread wheat

Wheat, among all cereal grains, possesses unique characteristics conferred by gluten; in particular, high molecular weight glutenin subunits (HMW‐GS) are of considerable interest as they strictly relate to bread‐making quality and contribute to strengthening and stabilizing dough. Thus, the identification of allelic composition, in particular at the Glu‐B1 locus, is very important to wheat quality improvement. Several PCR‐based molecular markers to tag‐specific HMW glutenin genes encoding Bx and By subunits have been developed in recent years. This study provides a survey of the molecular markers developed for the HMW‐GS at the Glu‐B1 locus. In addition, a selection of molecular markers was tested on 31 durum and bread wheat cultivars containing the By8, By16, By9, Bx17, Bx6, Bx14 and Bx17 Glu‐B1 alleles, and a new assignation was defined for the ZSBy9_aF1/R3 molecular marker that was specific for the By20 allele. We believe the results constitute a practical guide for results that might be achieved by these molecular markers on populations and cultivars with high variability at the Glu‐B1 locus.     

Disulphide structure of high-molecular-weight (HMW-) gliadins as affected by terminators

This study aimed at elucidating SS-bonds of HMW-gliadins (HGL) from wheat with the focus on terminators of glutenin polymerisation. HGL from wheat flour extracts non-treated or treated with the S-alkylation reagent N-ethylmaleinimide (NEMI) were compared. HGL from wheat flour Akteur were isolated, hydrolysed with thermolysin and the resulting peptides pre-separated by gel permeation chromatography and analysed by liquid chromatography/mass-spectrometry using alternating electron transfer dissociation/collision-induced dissociation. Altogether, 22 and 28 SS-peptides from samples without and with NEMI treatment, respectively, were identified. Twenty-six peptides included standard SS-bonds of α- and γ-gliadins, high-molecular-weight and low-molecular-weight glutenin subunits. Eleven SS-bonds were identified for the first time. Fifteen peptides unique to HGL contained cysteine residues from gliadins with an odd number of cysteines (ω5-, α- and γ-gliadins). Thus, gliadins with an odd number of cysteines, glutathione and cysteine had acted as terminators of glutenin polymerisation. Decisive differences between samples without and with NEMI treatment were not obvious showing that the termination of polymerisation was already completed in the flour. The two HGL samples, however, were different in the majority of ten peptides that included disulphide-linked low-molecular-weight (LMW) thiols such as glutathione and cysteine with the former being enriched in the non-treated HGL-sample.