Functional properties of a new low-molecular-weight glutenin subunit gene from a bread wheat cultivar

Some allelic forms of low-molecular-weight glutenin subunit (LMW-GS) can greatly influence the end-use of wheat flours, understanding the function of each allele of LMW-GS is important to wheat quality breeding. A LMW-GS gene XYGluD3-LMWGS 1(AY263369) has been cloned from bread wheat cultivar Xiaoyan 6. The deduced protein contained nine cystine residues, one more than that in all other LMW-GSs reported previously, indicating that it is either a new gene or a new allele of a known LMW-GS gene. In this study, the gene was expressed in E. coil in large scale for the testing of its functional property. Reactive Red 120-Agarose resin was used efficiently to purify the expressed LMW-GS proteins from bacteria, with the lactic acid–sodium lactate buffer (pH 4.5) which contained low concentration SDS as elution solution. The purified protein (belonging to the LMW-m family, MW about 35 KDa) was supplemented into a base flour, the results of 10 g dough mixing test indicated that incorporation of the LMW-GS increased the strength of the dough, with significant increases in mixing time (MT) and peak width (PW), and decrease in breakdown in resistance (RBD) compared with the control. In addition, the dough with incorporation of the LMW-GS had more glutenin macropolyeric protein than the control, suggesting that the LMW-GS participated in forming larger glutenin polymers, and greatly contributed to dough strength. The changes in mixing parameters and the amount of glutenin macropolyeric protein were related to the quantity of incorporating subunits.     

Characterization of Low Molecular Weight Glutenin Subunit Gene Representing Glu-B3 Locus of Indian Wheat Variety NP4

Low molecular weight (LMW) glutenin subunits represent major part (30%) of storage proteins in wheat endosperm and determine the quality of dough. Despite their importance few LMW glutenin genes have been characterized so far and none from Indian wheat variety. In the present investigation PCR technique was employed to characterize LMW-GS gene representing Glu-B3 locus from Indian bread wheat cultivar NP4. The deduced protein sequence coded by Glu-B3 locus of LMW-GS gene from NP4 showed the presence of regular structure of the repetitive domain with varying numbers of glutamine (Q) residues and the presence of 1^st cysteine residue within the repetitive domain at 40^th position in mature polypeptide. Such structure might increase and stabilize the gluten polymer through intermolecular interactions of the large numbers of glutamine side chains and cysteine residues for intermolecular disulphide bond formation leading to stronger dough quality of NP4. Moreover, Glu-B3 specific primers could also be used for identifying 1BL/1RS translocation in addition to amplifying LMW glutenin genes. There was no amplification in 1B/1R translocation lines as short arm of wheat was replaced by short arm of rye chromosome in these lines. Such information can be useful in wheat improvement for dough properties for better chapati and bread quality.     

Molecular characterization and genomic organization of low molecular weight glutenin subunit genes at the Glu-3 loci in hexaploid wheat (Triticum aestivum L.)

In this study, we report on the molecular characterization and genomic organization of the low molecular weight glutenin subunit (LMW-GS) gene family in hexaploid wheat (Triticum aestivum L.). Eighty-two positive BAC clones were identified to contain LMW-GS genes from the hexaploid wheat ‘Glenlea’ BAC library via filter hybridization and PCR validation. Twelve unique LMW glutenin genes and seven pseudogenes were isolated from these positive BAC clones by primer-template mismatch PCR and subsequent primer walking using hemi-nested touchdown PCR. These genes were sequenced and each consisted of a single-open reading frame (ORF) and untranslated 5′ and 3′ flanking regions. All 12 LMW glutenin subunits contained eight cysteine residues. The LMW-m-type subunits are the most abundant in hexaploid wheat. Of the 12 LMW-GS, 1, 2 and 9 are i-type, s-type and m-type, respectively. The phylogenetic analysis suggested that the LMW-i type gene showed greater differences to LMW-s and LMW-m-type genes, which, in turn, were more closely related to one another. On the basis of their N-terminal sequences, they were classified into nine groups. Fingerprinting of the 82 BAC clones indicated 30 BAC clones assembled into eight contigs, while the remaining clones were singletons. BAC end sequencing of the 82 clones revealed that long terminal repeat (LTR) retrotransposons were abundant in the Glu-3 regions. The average physical distance between two adjacent LMW-GS genes was estimated to be 81 kb. Most of LMW-GS genes are located in the d-genome, suggesting that the Glu-D3 locus is much larger than the Glu-B3 locus and Glu-A3 locus. Alignments of sequences indicated that the same type (starting with the same N-terminal sequence) LMW-GS genes were highly conserved in the homologous genomes between hexaploid wheat and its donors such as durum wheat and T. tauschii. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Identification of LMW glutenin-like genes from Secale sylvestre host

Three low-molecular-weight (LMW) glutenin-like genes (designated as Ssy1, Ssy2 and Ssy3) from Secale sylvestre Host were isolated and characterized. The three genes consist of a predicted highly conservative signal peptide with 20 amino acids, a short N-terminal region with 13 amino acids, a highly variable repetitive domain and a less variable C-terminal domain. The deduced amino acid sequences of the three genes were the LMW-m type due to a methionine residue at the N-terminus. The phylogenic analysis indicated that the prolamin genes could be perfectly clustered into five groups, including HMW-GS, LMW-GS, alpha/beta-, gamma- and omega-prolamin. The LMW glutenin-like genes of S. sylvestre were more orthologous with the LMW-GS genes of wheat and B hordein genes of barley, which also had been confirmed by the homology analysis with the LMW-GS of wheat at Glu-A3, Glu-B3 and Glu-D3 loci. These results indicated that a chromosome locus (designated as Glu-R3) might be located on the R genome of S. sylvestre with the functions similar to the Glu-3 locus in wheat and its related species.     

低分子量麦谷蛋白基因XYGluD3-LMWGS1原核表达增溶体系的探索

为研究SUMO标签增溶体系和小麦低分子量麦谷蛋白亚基功能,利用SUMO标签构建XYGluD3-LM-WGS基因原核表达可溶性增强的系统,采用PCR方法从已有质粒XYGluD3-LMWGS1/pGEM-Teasy中克隆到该基因不含上游启动子片段XYGluD3-LMWGS1-no Promoter 798 bp(简称LnoP),构建原核表达载体LnoP/pGEX-4T-1,并借助已有质粒SUMO1/pET-41a( )构建原核表达载体LnoP-SUMO1/pET-41a( )与LnoP-SUMO1-N2/pET-41a( )以及LnoP-SUMO1/pET-32a( ),分别诱导表达融合蛋白分析其可溶性,结果显示;(1)融合蛋白GST-LnoP、GST-SUMO1-LnoP、SUMO1-LnoP和Trx-SUMO1-LnoP表达成功;(2)电泳和Western blot分析显示,GST-LnoP和GST-SUMO1-LnoP的可溶蛋白表达均为电泳不可见,SUMO1-LnoP与Trx-SUMO1-LnoP有微量可溶表达.结果表明,试验首次实现人的SUMO1标签在麦谷蛋白低分子量亚基中的融合表达;尽管人的SUMO1做为融合标签对于增加低分子量麦谷蛋白D位点亚基可溶性的作用并未达到预期效果,但研究结果为SUMO标签增溶体系的建立和小麦低分子量麦谷蛋白亚基功能研究奠定了基础.     

Classification of wheat low-molecular-weight glutenin subunit genes and its chromosome assignment by developing LMW-GS group-specific primers

On the basis of sequence analysis, 69 known low-molecular-weight glutenin subunit (LMW-GS) genes were experimentally classified into nine groups by the deduced amino acid sequence of the highly conserved N-terminal domain. To clarify the chromosomal locations of these groups, 11 specific primer sets were designed to carry out polymerase chain reactions (PCR) with the genomic DNA of group 1 ditelosomic lines of Chinese Spring, among which nine primer sets proved to be LMW-GS group-specific. Each group of LMW-GS genes was specifically assigned on a single chromosome arm and hence to a specific locus. Therefore, these results provided the possibility to predict the chromosome location of a new LMW-GS gene based on its deduced N-terminal sequence. The validity of the classification was confirmed by the amplifications in 27 diploid wheat and Aegilops accessions. The length polymorphisms of LMW-GS genes of groups 1 and 2, and groups 3 and 4.1 were detected in diploid A-genome and S-genome accessions, respectively. The diploid wheat and Aegilops species could be used as valuable resources of novel allele variations of LMW-GS gene in the improvement of wheat quality. The nine LMW-GS group-specific primer sets could be utilized to select specific allele variations of LMW-GS genes in the marker-assisted breeding. Electronic Supplementary Material Supplementary material is available for this article at Hai Long and Yu-Ming Wei are the two authors who have contributed equally to this paper     

带芒草属低分子量谷蛋白基因的克隆及序列分析

在普通小麦中获得了大量的低分子量谷蛋白基因序列, 而在小麦近缘属物种中获得的同源基因则比较少, 导致对麦类低分子量谷蛋白基因家族成员间的关系还不清楚。因此, 进行近缘属物种低分子量谷蛋白基因的研究是非常必要的。此研究通过特殊设计的1对引物, 以小麦近缘属带芒草物种的基因组DNA为模板, 经过PCR和克隆, 从中得到了一条核苷酸序列长度为1 035 bp, 推测的氨基酸序列为343个氨基酸残基的低分子量谷蛋白基因, 该基因序列具有小麦低分子量谷蛋白基因的典型特征, 包括21个氨基酸残基的信号肽、13个氨基酸的N-端和由可重复的短肽单元组成的重复区以及1个C末端。序列比对结果揭示了来自带芒草的低分子量谷蛋白基因与小麦同源基因的差异及相互关系。此研究结果对从带芒草属以及其他小麦近缘属物种中分离未知低分子量谷蛋白基因有参考价值和借鉴意义。     

Characterisation and marker development for low molecular weight glutenin genes from<Emphasis Type="Italic"> Glu-A3</Emphasis> alleles of bread wheat (<Emphasis Type="Italic">Triticum aestivum.</Emphasis> L)

PCR was used to amplify low-molecular-weight (LMW) glutenin genes from the Glu-A3 loci of hexaploid wheat cultivars containing different Glu-A3 alleles. The complete coding sequence of one LMW glutenin gene was obtained for each of the seven alleles Glu-A3a to Glu-A3g. Chromosome assignment of PCR products using Chinese Spring nulli-tetrasomic lines confirmed the amplified products were from chromosome 1A. All sequences were classified as LMW-i-type genes based on the presence of an N-terminal isoleucine residue and eight cysteine residues located within the C-terminal domain of the predicted, mature amino acid sequence. All genes contained a single uninterrupted open reading frame, including the sequence from the Glu-A3e allele, for which no protein product has been identified. Comparison of LMW glutenin gene sequences obtained from different alleles showed a wide range of sequence identity between the genes, with between 1 and 37 single nucleotide polymorphisms and between one and five insertion/deletion events between genes from different alleles. Allele-specific PCR markers were designed based on the DNA polymorphisms identified between the LMW glutenin genes, and these markers were validated against a panel of cultivars containing different Glu-A3 alleles. This collection of markers represents a valuable resource for use in marker-assisted breeding to select for specific alleles of this important quality-determining locus in bread wheat.Communicated by P. Langridge     

Analysis and validation of genome-specific DNA variations in 5' flanking conserved sequences of wheat low-molecular-weight glutenin subunit genes

The thirty-three 5' flanking conserved sequences of the known low-molecular-weight subunit (LMW-GS) genes have been divided into eight clusters, which was in agreement with the classification based on the deduced N-terminal protein sequences. The DNA polymorphism between the eight clusters was obtained by sequence alignment, and a total of 34 polymorphic positions were observed in the approximately 200 bp regions, among which 18 polymorphic positions were candidate SNPs. Seven cluster-specific primer sets were designed for seven out of eight clusters containing cluster-specific bases, with which the genomic DNA of the ditelosomic lines of group 1 chromosomes of a wheat variety 'Chinese Spring' was employed to carry out chromosome assignment. The subsequent cloning and DNA sequencing of PCR fragments validated the sequences specificity of the 5' flanking conserved sequences between LMW-GS gene groups in different genomes. These results suggested that the coding and 5' flanking regions of LMW-GS genes are likely to have evolved in a concerted fashion. The seven primer sets developed in this study could be used to isolate the complete ORFs of seven groups of LMW-GS genes, respectively, and therefore possess great value for further research in the contributions of a single LMW-GS gene to wheat quality in the complex genetic background and the efficient selections of quality-related components in breeding programs.     

Comprehensive identification of LMW-GS genes and their protein products in a common wheat variety

Although it is well known that low-molecular-weight glutenin subunits (LMW-GS) from wheat affect bread and noodle processing quality, the function of specific LMW-GS proteins remains unclear. It is important to find the genes that correspond to individual LMW-GS proteins in order to understand the functions of specific proteins. The objective of this study was to link LMW-GS genes and haplotypes characterized using well known Glu-A3, Glu-B3, and Glu-D3 gene-specific primers to their protein products in a single wheat variety. A total of 36 LMW-GS genes and pseudogenes were amplified from the Korean cultivar Keumkang. These include 11 Glu-3 gene haplotypes, two from the Glu-A3 locus, two from the Glu-B3 locus, and seven from the Glu-D3 locus. To establish relationships between gene haplotypes and their protein products, a glutenin protein fraction was separated by two-dimensional gel electrophoresis (2-DGE) and 17 protein spots were analyzed by N-terminal amino acid sequencing and tandem mass spectrometry (MS/MS). LMW-GS proteins were identified that corresponded to all Glu-3 gene haplotypes except the pseudogenes. This is the first report of the comprehensive characterization of LMW-GS genes and their corresponding proteins in a single wheat cultivar. Our approach will be useful to understand the contributions of individual LMW-GS to the end-use quality of flour.     

普通小麦低分子量麦谷蛋白亚基核心编码区与面团强度关系的研究

为分析LMW-GS基因对面团强度的影响, 利用两个重组自交系99G45/京771和Pm97034/京771的F9代,对LMW-GS基因特异位点和与其紧密连锁的Gli-1位点进行分析, 研究对面团强度影响差异显著的Glu-B3位点的等位基因核心编码区的序列差异。结果表明, 3个亲本LMW-GS核心编码区都具有6个半胱氨酸残基, 但PB较GB和JB缺失了一个7氨基酸序列的重复单元, 并且在不同序列中出现了氨基酸代换, 其中有2个代换可能影响氨基酸序列的亲水性, 进而影响面团强度。     

Identification of LMW Glutenin-Like Genes from <Emphasis Type="Italic">Secale sylvestre</Emphasis> Host

Three low-molecular-weight (LMW) glutenin-like genes (designated as Ssy1, Ssy2, and Ssy3) from Secale sylvestre Host were isolated and characterized. The three genes consist of a predicted highly conservative signal peptide with 20 amino acids, a short N-terminal region with 13 amino acids, a highly variable repetitive domain and a less variable C-terminal domain. The deduced amino acid sequences of the three genes were the LMW-m type due to a methionine residue at the N-terminus. The phylogenetic analysis indicated that the prolamin genes could be perfectly clustered into five groups, including HMW-GS, LMW-GS, α/β-, γ-, and κ-prolamin. The LMW glutenin-like genes of S. sylvestre were more orthologous with the LMW-GS genes of wheat and B hordein genes of barley, which also had been confirmed by the homology analysis with the LMW-GS of wheat at Glu-A3, Glu-B3, and Glu-D3 loci. These results indicated that a chromosome locus (designated as Glu-R3) might be located on the R genome of S. sylvestre with the functions similar to the Glu-3 locus in wheat and its related species.     

LMW-GS genes in Agropyron elongatum and their potential value in wheat breeding

To study the usefulness of low-molecular-weight glutenin subunits (LMW-GS) of Agropyron elongatum (Host) Nevski to wheat (Triticum aestivum L.) quality improvement, we characterized LMW-GS genes of A. elongatum. Nine LMW-GS genes of A. elongatum, which were named AeL1 to AeL9, were cloned by genomic PCR. After sequencing, we obtained complete open reading frames from AeL2 to AeL8 and partial genes of AeL1 and AeL9. All nine sequences are homoeologous to those of wheat and related grasses. Comparison of the deduced amino acid sequences with those of published LMW-GS suggests that the basic structures of all the subunits are very similar. However, except for AeL4 and AeL5, which contain the identical N-terminal sequence with LMW-m, other LMW-GS sequences separated from A. elongatum cannot be classified according to previous criteria for the three types: LMW-m (methionine), LMW-s (serine), and LMW-i (isoleucine), and then 12 groups. In addition, there are some characters in the LMW-GS sequences of A. elongatum: AeL2, AeL3, and AeL6 involve a Cys residue in the signal peptide respectively, which is absent in most of LMW-GS; AeL3, AeL6, AeL8, and AeL9 start their first Cys residues in the N-terminal repetitive domains, respectively; both AeL2 and AeL5 have nine Cys residues, with an extra Cys residue in the N-terminal repetitive domain and the repetitive and glutamine-rich domain; AeL2, AeL3, AeL6, and AeL9 comprise long repetitive domains. Phylogenetic analysis indicates that there is a relatively weak sequence identity between the LMW-GS genes from A. elongatum cloned in this study and those reported from other plants. Three LMW-GS sequences, AeL2, AeL3, and AeL6, are clustered to Glu-A3 from wheat than to those from other plants. The possible use of these genes in relation to the high quality of hybrid wheat is discussed.     

四川小麦地方品种AS1643中低分子量谷蛋白基因的克隆及其蛋白质的二级结构预测

根据小麦低分子量谷蛋白基因保守区序列设计引物P1/P2, 采用PCR法对四川小麦地方品种AS1643的基因组DNA进行扩增, 获得1条约900 bp的片段, 分离、纯化后连接到载体pMD18-T上, 对筛选阳性克隆测序, 获得1个低分子量谷蛋白基因LMW-AS1643(GenBank登录号: EF190322), 其编码区长度为909 bp, 可编码302个氨基酸残基组成的成熟蛋白。序列分析结果表明, LMW-AS1643具有典型的低分子量谷蛋白基因的基本结构, 其推导氨基酸序列与其它已知的LMW-GS相比, 最高相似性为93.40%。生物信息学分析表明, 在LMW-AS1643低分子量谷蛋白中, 无规则卷曲含量最高, 为67.90 %, 其次是a-螺旋, 占30.46 %, b-折叠含量最少, 为1.64 %。     

Identification of new low-molecular-weight glutenin subunit genes in wheat

To clarify the composition of low-molecular-weight glutenin subunits (LMW-GSs) in a soft wheat cultivar, we cloned and characterized LMW-GS genes from a cDNA library and genomic DNA in Norin 61. Based on alignment of the conserved N- and C- terminal domains of the deduced amino-acid sequences, these genes are classified into 12 groups. One of these groups (group 5), the corresponding gene of which has not been reported previously, contains two additional hydrophobic amino-acid clusters interrupting the N-terminal repetitive domain. Other groups (groups 11 and 12), which were not identified in other cultivars as a protein product, showed all eight cysteines in the C-terminal conserved domain. With specific primer sets for these groups it was revealed that Glu-D3 and Glu-A3 encoded the former and the latter, respectively. Both groups of genes were expressed in immature seeds. The presence of these groups of LMW-GSs may affect the dough strength of soft wheat. Received: 26 March 2001 / Accepted: 16 July 2001     

Development of a new marker system for identifying the complex members of the low-molecular-weight glutenin subunit gene family in bread wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

Low-molecular-weight glutenin subunits (LMW-GSs) play an important role in determining the bread-making quality of bread wheat. However, LMW-GSs display high polymorphic protein complexes encoded by multiple genes, and elucidating the complex LMW-GS gene family in bread wheat remains challenging. In the present study, using conventional polymerase chain reaction (PCR) with conserved primers and high-resolution capillary electrophoresis, we developed a new molecular marker system for identifying LMW-GS gene family members. Based on sequence alignment of 13 LMW-GS genes previously identified in the Chinese bread wheat variety Xiaoyan 54 and other genes available in GenBank, PCR primers were developed and assigned to conserved sequences spanning the length polymorphism regions of LMW-GS genes. After PCR amplification, 17 DNA fragments in Xiaoyan 54 were detected using capillary electrophoresis. In total, 13 fragments were identical to previously identified LMW-GS genes, and the other 4 were derived from unique LMW-GS genes by sequencing. This marker system was also used to identify LMW-GS genes in Chinese Spring and its group 1 nulli–tetrasomic lines. Among the 17 detected DNA fragments, 4 were located on chromosome 1A, 5 on 1B, and 8 on 1D. The results suggest that this marker system is useful for large-scale identification of LMW-GS genes in bread wheat varieties, and for the selection of desirable LMW-GS genes to improve the bread-making quality in wheat molecular breeding programmes.     

Analysis and validation of genome-specific DNA variations in 5′ flanking conserved sequences of wheat low-molecular-weight glutenin subunit genes

The thirty-three 5′ flanking conserved sequences of the known low-molecular-weight subunit (LMW-GS) genes have been divided into eight clusters, which was in agreement with the classification based on the deduced N-terminal protein sequences. The DNA polymorphism between the eight clusters was obtained by sequence alignment, and a total of 34 polymorphic positions were observed in the approximately 200 bp regions, among which 18 polymorphic positions were candidate SNPs. Seven cluster-specific primer sets were designed for seven out of eight clusters containing cluster-specific bases, with which the genomic DNA of the ditelosomic lines of group 1 chromosomes of a wheat variety ‘Chinese Spring’ was employed to carry out chromosome assignment. The subsequent cloning and DNA sequencing of PCR fragments validated the sequences specificity of the 5′ flanking conserved sequences between LMW-GS gene groups in different genomes. These results suggested that the coding and 5′ flanking regions of LMW-GS genes are likely to have evolved in a concerted fashion. The seven primer sets developed in this study could be used to isolate the complete ORFs of seven groups of LMW-GS genes, respectively, and therefore possess great value for further research in the contributions of a single LMW-GS gene to wheat quality in the complex genetic background and the efficient selections of quality-related components in breeding programs.     

Isolation of low-molecular-weight glutenin subunit genes from wild emmer wheat (Triticum dicoccoides)

Three low-molecular-weight glutenin subunit (LMW-GS) genes, designated LMW-Td1, LMW-Td2 and LMW-Td3, were isolated from wild emmer wheat (Triticum dicoccoides), which is the tetraploid progenitor of common wheat (T. aestivum). The complete nucleotide sequence lengths of LMW-Td1, LMW-Td2 and LMW-Td3 are 858, 900 and 1062 bp, respectively. LMW-Td1 and LMW-Td3 can encode proteins with 284 and 352 amino acid residues, respectively, whereas LMW-Td2 is a putative pseudogene due to the presence of 3 inframe stop codons in its C-terminal domain. The deduced protein sequences of the 3 genes share the same typical polypeptide structures with known LMW-GS genes containing 8 cysteines in the mature protein domains. LMW-Td1 was clearly distinguished from all known LMW-GS genes, and considered as a novel LMW-GS gene. Two hydrophobic motifs (i.e. PIIIL and PVIIL) were observed in the repetitive domain of LMW-Td3. Sequence comparison indicates that sequences of the 3 LMW-GS genes from this study are strongly similar to known LMW-GS genes. Our phylogenetic analysis suggests that LMW-Td1 and LMW-Td2 are homologous with genes on chromosome 1A, and LMW-Td3 is closely related to genes on chromosome 1B.     

Molecular characterization of a LMW-GS gene located on chromosome 1B and the development of primers specific for the Glu-B3 complex locus in durum wheat

 Low-molecular-weight glutenin subunits (LMW-GS) represent a specific class of wheat storage proteins encoded at the Glu-3 loci. Particularly interesting are the LMW-GS encoded at the Glu-B3 locus because they have been shown to play an important role in determining the pasta-making properties of durum wheat. Genes encoding LMW-GS have been characterized but only a few of them have been assigned to specific loci. Notably, no complete LMW-GS gene encoded at the Glu-B3 locus has yet been described. The present paper reports the isolation and characterization of a lmw-gs gene located at the Glu-B3 locus. The clone involved, designated pLDNLMW1B, contains the entire coding region and 524 bp of the 5′ upstream region. A nucleotide comparison between the pLDNLMW1B clone and other LMW-GS genes showed the presence of some peculiar structural characteristics, such as short insertions in the promoter region, the presence of a cysteine codon in the repetitive domain, and a more regular structure of this region, which could be important for its tissue-specific expression and for the functional properties of the encoded protein, respectively. Received : 30 May 1997 / Accepted : 29 July 1997