Primary structure of A B1 hordein gene from barley

DNA authentication of brewery products: basic principles and methodological approaches

Beer DNA authentication is the process of authentication by identification of barley malt Hordeum vulgare or its substitutes, as well as hops and yeast. The method is based on molecular genetic analysis of residual quantities of nucleic acids extracted from the cellular debris of the final product. The aim of the study was to analyse scientific and methodical approaches to extraction of residual quantities of beer raw materials nucleic acids and beer DNA authentication for their later application in determining brewing products authenticity. The technological level discloses the method of DNA extraction from wines, modified for extraction of nucleic acids from beer samples. The method includes the following characteristic peculiarities: stage enzymatic hydrolysis of polysaccharides and polypeptides of dissolved lyophilisate, multiple sedimentation and resursuspension of nucleoproteid complex, RNA removal followed by DNA extraction by organic solvents, and additional DNA purification by magnetic particle adsorption. This review presents the analysis of genetic targets used as molecular markers for gene identification of malting barley varieties and beer DNA authentication. We also provided the interpretation of PCR analysis of Hordeum vulgare varieties and samples of commercial beer. Data on SSR- and SNP-markers of Hordeum vulgare nuclear DNA, used for barley varieties identification and potentially suitable for beer DNA authentication, are also presented. We also analysed genetic targets used in malting barley substitute detection, as well as hops and yeast identification in beer. Data on correlation of amplified DNA targets with beer quality indicators were systematised.

The B-hordein prolamin family of barley

The spectrum of B-hordein prolamins and genes in the single barley cultivar Barke is described from an in silico analysis of 1452 B-hordein ESTs and available genomic DNA. Eleven unique B-hordein proteins are derived from EST contigs. Ten contigs encode apparent full-length B-hordeins and the eleventh contains a premature stop codon that will lead to a truncated B-hordein. The 11 sequences are placed within the two previously described classes, i.e., the B1- and B3-type B-hordeins. The number of ESTs assigned to each sequence is used as an estimate of relative gene transcription and expression. Three of the sequences account for 79% of the total ESTs, with one sequence comprises 32% of the total ESTs and has a variant C-terminus caused by an undefined sequence change history near the 3' coding terminus. The 70× difference in EST distribution among sequences points to the importance of understanding differential rates of expression within closely related gene families. Analysis of available genomic sequences confirms the EST assembly and reveals one full-length and two partial sequences of pseudogenes as evidenced by no matching ESTs for the sequences and premature stop codons and frame shifts.

Structural and expressional analysis of the B-hordein genes in Tibetan hull-less barley

The B-hordein gene family was analyzed from two Tibetan hull-less barley cultivars Z09 and Z26 (Hordeum vulgare subsp. vulgare). Fourteen B-hordein genes, designated BZ09-2 to BZ09-5 (from Z09) and BZ26-1 to BZ26-10 (from Z26), were sequenced. Seven of them, similar to a previously reported BZ09-1 from Z09, were predicted to encode putative active proteins each with a signal peptide, a repetitive domain, and a C-terminal region; seven of them were predicted to be pseudogenes. The B-hordein gene family was analyzed using all known representatives of B-hordein sequences and two most similar LMW-GSs of Triticum aestivum. Alignment of these seven putative proteins with known B-hordeins and two most similar LMW-GSs of T. aestivum revealed that they shared a common motif. A large variation was observed between numbers of repeat units of predicted B-hordeins of Z26 and Z09. Phylogenetic analysis revealed that all BZ26 clones were clustered in a subgroup, and BZ09-1 formed another subgroup by itself in the putative eight active genes. In addition, six 5'-upstream regulatory sequences of the B-hordein genes were isolated from the two accessions by a single oligonucleotide nested PCR, and several different mutations were identified in the cis-acting element GLM and two distinctive sequences (Z09P-2 and Z26P-3). Phylogenetic analysis of 5'-upstream regulatory regions of the B-hordein genes showed that members from the same accession were clustered together except for two distinct members. Quantitative real time PCR analysis indicated distinct expression levels of B-hordein genes in four developing stages of developing grains in two accessions. These findings suggest B-hordein genes have intrinsic differences between accessions, and this knowledge will be useful for incorporating the B-hordeins protein in barley breeding programs.

Cloning and characterization of four B-hordein genes from Tibetan hull-less barley (Hordeum vulgare subsp. vulgare)

Four B-hordein genes, designated BH1-BH4, were cloned using PCR amplification from two hull-less barley cultivars, ZQ7239 and ZQ148, collected from Tibet. The results of sequencing indicated that BH1-BH4 contained complete open reading frames (ORFs). Comparison of their predicted polypeptide sequences with the published sequences suggested that they all share the same basic protein structure. Phylogenetic analysis indicated that the deduced amino-acid sequences of BH1-BH4 genes were more closely related to B-hordeins from cultivated barley (Hordeum vulgare L.) than to any other prolamins from wild barley and Aegilops tauschii. Comparison of the coding regions of BH1-BH4 genes showed that BH1 had a lower sequence identity to other previously published B-hordeins than the other three B-hordeins obtained in this study. BH1 was then cloned in a bacterial expression vector based on bacteriophage T7 RNA polymerase. The resulting plasmid produced a 28.15 kDa protein in Escherichia coli. The potential value of B-hordein genes in grain quality improvement of hull-less barley has been discussed.

Comparison of promoters in transgenic rice

Reports of the use of rice storage protein gene promoters to express transgenes in rice grain have demonstrated that rice grain can be used as a production platform for end-use quality or seed-based edible vaccines. The generation of transgenic rice with multitraits (gene stacking), which requires the use of multiple transgenes under the control of different promoters, necessitates the use of promoters from rice and other cereals, as this is highly advantageous in reducing homology-based transcriptional gene silencing. Using the green fluorescent protein gene (gfp) as a reporter gene and a transgenic rice platform, promoters of storage protein and non-storage protein genes from barley, wheat and rice were compared with regard to their spatial and temporal control of expression. Storage protein promoters from barley (549-bp B-hordein and 433-bp D-hordein) and wheat (425-bp high-molecular-weight glutenin) directed the expression of green fluorescent protein (GFP) in endosperm but not embryo; however, expression was leaky, as it was also observed in seed maternal tissues, leaf and root tissues. As expected, the rice promoters (1350-bp alpha-glutelin B-1 and 1007-bp alpha-globulin) directed the endosperm-specific expression of GFP in transgenic rice. Our results indicate that seed-specific promoters from barley and wheat, although containing endosperm and GCN4 motifs, which are important for endosperm-specific expression in rice, may not be spatially regulated in the same manner as they are in their native species. The analysis of GFP expression under the control of various promoters in rice grain indicates that promoters from other cereals can drive high levels of endosperm-specific expression in rice, but their utility for seed-specific expression may depend on their tissue specificity.

[Isolation and characterization of a low molecular weight glutenin gene from Taenitherum Nevski]

More and more low-molecular-weight glutenin(LMW glutenin) genes were isolated and characterized from hexaploid wheat (Triticum aestivum L.). However, few homologous genes were obtained from its relative species, which limited our understanding of the relationships among them. Therefore, it is necessary to isolate LMW glutenin homologous genes from wheat wild relative species. Using a pair of specific oligonucleotide PCR primers for Taenitherum genomic DNA, a LMW glutenin gene sequence, with nucleotide sequence in 1 035 bp and deduced amino acid sequence with 343 amino acid residues, was obtained. This sequence was a typical LMW glutenin sequence and characterized by a signal peptide of 21 amino acid residues, a N-terminal conservative domain of 13 amino acid residues, a repetitive domain of short peptide, and a C-terminal conservative domain. Sequence alignment showed the main differences and the relationships between LMW glutenin genes from wheat and Taenitherum. The results presented here give a reference to isolate LMW glutenin gene from Taenitherum, as well as other wheat wild relatives.

Glycosylated F4 (K88) fimbrial adhesin FaeG expressed in barley endosperm induces ETEC-neutralizing antibodies in mice

The F4-positive enterotoxigenic Escherichia coli (ETEC) strains are a frequent cause of porcine post-weaning diarrhea. Orally administered F4 fimbriae or FaeG, the major subunit and adhesin of F4, induce a protective mucosal immune response in F4 receptor-positive piglets. Feed plants carrying immunogenic subunit proteins can offer great advantages for oral vaccination of domestic animals. Here, we describe high-level endosperm-specific production (1% of total soluble proteins) of FaeG in the crop plant barley. The endoplasmic reticulum-targeted recombinant endospermic FaeG (erFaeG) was shown to be heterogeneously glycosylated. The erFaeG showed resistance at digestive conditions simulating piglet gastric fluid. Glycosylation did not abolish the immunogenic character of the FaeG protein, since erFaeG was able to induce F4 fimbria-specific antibodies in mice. Biological activity of these anti-F4 antibodies was demonstrated in vitro by blocking the attachment of the F4+ ETEC to the F4 receptors present on porcine intestinal enterocytes.

From analysis of mutants to genetic engineering

This chapter describes the research of developing transgenic barley for synthesis of recombinant proteins with practical significance and of metabolic engineering of proanthocyanidin-free barley. The results were obtained by graduate students, postdoctoral researchers, and visiting scientists at the Carlsberg Laboratory from 1972-1996 and during the past ten years at Washington State University. It is written in appreciation of their enthusiasm, skill, and perseverance.

Cloning and characterization of a gamma-3 hordein mRNA (cDNA) from Hordeum chilense (Roem. et Schult.)

Hordeum chilense is a wild relative of H. vulgare, cultivated barley, that has been successfully used in the synthesis of amphiploids by crossing with Triticum spp. These amphiploids-named generically x Tritordeum-have been tested under field conditions, and one of them, the hexaploid tritordeum obtained following chromosome doubling of the hybrid H. chilense x T. turgidum, shows traits of interest inherited from the barley parent. Of great interest is the allelic variation observed in the endosperm storage proteins and their influence on the breadmaking and malting quality of tritordeum. We report here two mRNA (cDNA) sequences for a gamma-3 hordein from two accession lines of H. chilense, H1 and H7, and their characterization by quantitative real time (QRT)-PCR in the developing endosperm. Sequences were obtained by rapid amplification of cDNA ends and "edge-to-edge" amplification of open reading frames from cDNA of H. chilense. Eight putative single nucleotide polymorphisms and one codon insertion were identified in the sequences of the H1 and H7 gamma-3 hordeins. The deduced amino acid sequences showed similar features to that of the gamma-3 hordein and gamma-gliadins from barley and wheat, respectively. While the repetitive motif (PQQQPF) is similar to that of the gamma-3 hordein from H. vulgare, there are 19 motif repeats in H. vulgare, whereas H. chilense shows 15 tandem repeats. The transcription of the genes encoding for the gamma-3 hordein were monitored by QRT-PCR: in both lines maximum transcription occurred 12 days after flowering.

Overexpression of thioredoxin h leads to enhanced activity of starch debranching enzyme (pullulanase) in barley grain

Biochemically active wheat thioredoxin h has been overexpressed in the endosperm of transgenic barley grain. Two DNA constructs containing the wheat thioredoxin h gene (wtrxh) were used for transformation; each contained wtrxh fused to an endosperm-specific B(1)-hordein promoter either with or without a signal peptide sequence for targeting to the protein body. Twenty-two stable, independently transformed regenerable lines were obtained by selecting with the herbicide bialaphos to test for the presence of the bar herbicide resistance gene on a cotransformed plasmid; all were positive for this gene. The presence of wtrxh was confirmed in 20 lines by PCR analysis, and the identity and level of expression of wheat thioredoxin h was assessed by immunoblots. Although levels varied among the different transgenic events, wheat thioredoxin h was consistently highly expressed (up to 30-fold) in the transgenic grain. Transgenic lines transformed with the B(1)-hordein promoter with a signal peptide sequence produced a higher level of wheat thioredoxin h on average than those without a signal sequence. The overexpression of thioredoxin h in the endosperm of germinated grain effected up to a 4-fold increase in the activity of the starch debranching enzyme, pullulanase (limit dextrinase), the enzyme that specifically cleaves alpha-1,6 linkages in starch. These results raise the question of how thioredoxin h enhances the activity of pullulanase because it was found that the inhibitor had become inactive before the enzyme showed appreciable activity.

Barley BLZ2, a seed-specific bZIP protein that interacts with BLZ1 in vivo and activates transcription from the GCN4-like motif of B-hordein promoters in barley endosperm

A barley endosperm cDNA, encoding a DNA-binding protein of the bZIP class of transcription factors, BLZ2, has been characterized. The Blz2 mRNA expression is restricted to the endosperm, where it precedes that of the hordein genes. BLZ2, expressed in bacteria, binds specifically to the GCN4-like motif (GLM; 5'-GTGAGTCAT-3') in a 43-base pair oligonucleotide derived from the promoter region of a Hor-2 gene (B1-hordein). This oligonucleotide also includes the prolamin box (PB; 5'-TGTAAAG-3'). Binding by BLZ2 is prevented when the GLM is mutated to 5'-GTGctTCtc-3' but not when mutations affect the PB. The BLZ2 protein is a potent transcriptional activator in a yeast two-hybrid system where it dimerizes with BLZ1, a barley bZIP protein encoded by the ubiquitously expressed Blz1 gene. Transient expression experiments in co-bombarded developing barley endosperms demonstrate that BLZ2 transactivates transcription from the GLM of the Hor-2 gene promoter and that this activation is also partially dependent on the presence of an intact PB. A drastic decrease in GUS activity is observed in co-bombarded barley endosperms when using as effectors equimolar mixtures of Blz2 and Blz1 in antisense constructs. These results strongly implicate the endosperm-specific BLZ2 protein from barley, either as a homodimer or as a heterodimer with BLZ1, as an important transcriptional activator of seed storage protein genes containing the GLM in their promoters.

Characterization of the maize prolamin box-binding factor-1 (PBF-1) and its role in the developmental regulation of the zein multigene family

A maize prolamin box (P-box)-binding factor (PBF-1) has been purified and characterized from immature endosperm tissue. PBF-1 has a molecular weight of 38kDa. It is detected only in endosperm, but not in root or leaf tissues, consistent with its tissue-specific function. Site-directed mutagenesis experiments reveal that both the P-box and its flanking sequences are important for PBF-1 DNA binding. Developmental studies show that PBF-1 accumulates in the endosperm from 8 to at least 30days after pollination (DAP). From 16 to 24DAP, however, multiple shifted bands of protein(s)-DNA complexes can be observed, which correlate with an increase in zein gene expression. PBF-1 can also bind to the P-box from '22-kDa' and '19-kDa' zein promoters, but at a lower affinity than to the '27-kDa' zein promoter. The effects of protein dephosphorylation and zinc ion chelators on PBF-1 DNA binding activity are also shown. A model is proposed where PBF-1 serves as a 'recruiter' of class-specific transcription factors like Opaque2 (O2).

Modulation of gene expression by DNA-protein and protein-protein interactions in the promoter region of the zein multigene family

A common cis-acting element in the promoter region of many genes expressed during endosperm development of cereal seeds, the prolamine-box or P-box, is only 20bp upstream of the alpha-class 22-kDa zein gene-specific cis element, the O2-box, which is recognized by the b-ZIP transcription factor, Opaque-2 (O2). The proximity of these two boxes has prompted a study of how two DNA-binding proteins of a different hierarchy might be involved in the activation and modulation of the 22-kDa zein-encoding genes. This was accomplished by utilizing a highly purified P-box-binding-factor-1 (PBF-1) and a bacterially expressed truncated form of the O2 protein. After adding the recombinant O2 to the purified fraction of PBF-1, binding studies were performed with a series of DNA probes combining the P- and O2-boxes from zein promoters. These studies have revealed an interesting inhibitory effect of PBF-1 over O2 function dependent on their ratio, consistent with its in-vivo properties and the developmental expression profiles of zein genes. We also could show that the P-box is specifically recognized by topoisomerase II and single-strand DNA-binding proteins, indicating a possible additional linkage between P-box and the scaffold-attachment-region (SAR).

The bifactorial endosperm box of gamma-zein gene: characterisation and function of the Pb3 and GZM cis-acting elements

The proximal region of the gamma-zein promoter (gamma Z) has a functional bifactorial prolamin box element containing two cis-acting elements, a prolamin-box motif (Pb3) and a GCN4-like motif (GZM). By particle bombardment of maize endosperms with 5' deletions and internal deletions of gamma Z fused to the GUS gene, we have shown that a 135 bp region containing the bifactorial element is involved in the transcriptional activation of the gamma Z promoter. However, the 135 bp region was unable to activate the gamma Z promoter in the absence of a 84 bp downstream sequence. Using in vivo footprinting and gel mobility shift assays with 15 DAP endosperm nuclear extracts, we have demonstrated the presence of trans-acting factors that interact with Pb3 and GZM target sites. Base-substitution mutations within Pb3 and GZM decreased transcription activity of the gamma Z promoter suggesting a co-ordinated function between the two cis-acting elements. Two additional cis-motifs upstream of the bifactorial prolamin element have been identified: a motif with high homology to the AACA elements of rice glutelin genes and an AZM motif containing an ACGT core which binds nuclear proteins other than the Opaque 2 (O2).

An endosperm-specific DOF protein from barley, highly conserved in wheat, binds to and activates transcription from the prolamin-box of a native B-hordein promoter in barley endosperm

A cDNA encoding a DNA-binding protein of the DOF class of transcription factors was isolated from a barley endosperm library. The deduced amino acid sequence for the corresponding protein is 94% identical through the DOF domain to the prolamin-box (P-box) binding factor PBF from maize. The gene encoding the barley PBF (BPBF) maps to chromosome 7H, and its expression is restricted to the endosperm where it precedes that of the hordein genes. The BPBF expressed in bacteria as a GST-fusion binds a P-box 5'-TGTAAAG-3' containing oligonucleotide derived from the promoter region of an Hor2 gene. Binding was prevented when the P-box motif was mutated to 5'-TGTAgAc-3'. A P-box binding activity, present in barley and wheat endosperm nuclei, interacted similarly to BPBF with this synthetic oligonucleotide, and the binding was abolished by 1,10-phenanthroline. Transient expression experiments in developing barley endosperms demonstrate that BPBF transactivates transcription from the P-box element of a native Hor2 promoter and that direct binding of BPBF to its target site is essential for transactivation since mutations in the DOF DNA-binding domain or in the P-box motif of this promoter abolished both binding and transactivation. Evidence was also obtained for the presence in wheat of a Pbf homologue having similar DNA-binding properties to that of BPBF. These results strongly implicate this endosperm-specific DOF protein from barley as an important activator of hordein gene expression and suggest the evolutionary conservation of the Pbf gene function among small grain cereals.

Rapid PCR amplification of chimeric products and its direct application to in vivo [corrected] testing of recombinant DNA construction strategies

This article describes a simple and rapid method for efficient production of chimeric products by polymerase chain reaction (PCR). This protocol is amenable to site-directed mutagenesis strategies and can be done without the time-consuming gel purification step. The PCR products generated can also be directly used for direct gene transfer into plant cells without further subcloning to test construction strategies.

Hordein promoter methylation and transcriptional activity in wild-type and mutant barley endosperm

B- and C-hordein gene transcription is severely reduced in the endosperm of the regulatory barley mutant lys3a, and this is correlated with persistent hypermethylation of the promoters. In contrast, D-hordein is expressed at normal levels in the mutant. To confirm the connection between methylation and transcriptional activity, a genomic D-hordein clone was isolated and sequenced. The nucleotide composition of the promoter region revealed a CpG island and methylation analysis, using bisulphite treatment of genomic DNA, confirmed that the D-hordein promoter is unmethylated in endosperm and leaf tissue. Immunocytochemical studies localized D-hordein to the reticular component of protein bodies in both the wild-type Bomi and lys3a. Transient expression of GUS reporter gene constructs in barley endosperm, following transfection by particle bombardment revealed the D-hordein promotors. Comparison of transient expression in Bomi and lys3a endosperm demonstrated that the activities of the unmethylated D-hordein and the Hor1-14 C-hordein promoters were equivalent, while the activities in the mutant of the Horl-17 C-hordein and the Hor2-4 B-hordein promoters were reduced two- and tenfold, respectively. Methylation of plasmids in vitro prior to expression severely inhibited B- and D-hordein promoter activities. Based on these observations two categories of promoters for endosperm-specific expression of storage proteins are recognized and a model involving methylation and modulation of chromatin structure in the regulation by the Lys3 gene is presented.

The relationship between physical and genetic distances at the Hor1 and Hor2 loci of barley estimated by two-colour fluorescent in situ hybridization

The hordeins are the major class of storage proteins in barley. They are encoded by multigene families. The B- and C-hordein loci have been mapped physically to the distal end of chromosome 5 (1I) of cultivated barley by fluorescent in situ hybridization. Based on measurements of chromosomal distances between the two hordein loci, the relationship between genetic and physical distances has been estimated to be about 1 mega base pairs per centiMorgan. This is four times higher than the mean value for the barley genome as a whole and confirms the tendency to increased recombination in distal chromosome regions. The resolving power of two-colour FISH is discussed. It is concluded that the method is suitable for estimating the relationship between genetic and physical distances of regions of about 10 Mbp or larger.

Transient expression of a lysine-rich vicilin gene ofVicia faba in barley endosperm detected by immunological tissue printing after particle bombardment

Using immunological tissue printing we detected transient expression of a faba bean vicilin gene with or without introns driven by the B1 hordein promoter in barley endosperm after particle bombardment. The described method generally allows the analysis of transient expression of genes without depending on reporter gene constructs and specifically suggests correct splicing of dicot introns by a monocot splicing machinery.

Sensitivity enhancement of fluorescence in situ hybridization on plant chromosomes

An improved in situ hybridization procedure is presented, based on synchronization of root meristems of barley and wheat, enzymatic digestion, a protoplast drop technique, and the use of the fluorescent dye Cy3. The combination of these approaches resulted in a significant increase of well-spread metaphases suitable for in situ hybridization as compared to squash preparations, and to a significantly enhanced number and intensity of hybridization signals as demonstrated for a B-hordein-specific low-copy probe of barley. In the case of Cy3 all metaphases displayed a signal, more than 60% of them on both chromatids of each gene-bearing chromosome.

Analysis of nuclear proteins interacting with a wheat alpha/beta-gliadin seed storage protein gene

The promoter region (-524 to -46) of the wheat alpha/beta-gliadin seed storage protein gene was analyzed for interactions with nuclear proteins from developing wheat seeds. Six complexes were detected within the first 165 bp upstream of the transcriptional start site. One of the proteins was a non-sequence specific AT-binding protein. The remaining five proteins bound in a sequence specific manner. One (CABP) mapped to a conserved CA-rich element at -134 to -112 while another (PalBP) mapped to an adjacent, palindromic sequence at -112 to -106. Three proteins (CTBPs 1-3) formed complexes at two, independent homologous sites. The activities of four of the binding proteins, CTBPs 1-3 and CABP, exhibited similar patterns of expression during seed development: they first appeared at early to mid stages, reached a maximum at mid stage and subsequently decreased, paralleling the pattern of gliadin mRNA accumulation. The non-specific AT-binding protein was detected at relatively high levels only at mid development. PalBP activity, on the other hand, first appeared at mid stage and was present at a constant level throughout later stages of development. The results suggest that the binding proteins may regulate gliadin expression in an antagonistic manner.

Evolutionary relationship of the members of the sulphur-rich hordein family revealed by common antigenic determinants

Five monoclonal antibodies raised against an enriched C hordein fraction have been characterized in detail and were found to be specific for the members of the sulphur-rich hordein family. Two antibodies specific for B hordein polypeptides were identified, one of which reacted predominantly with CNBr cleavage class III polypeptides. γ1 hordein was recognized by two antibodies, of which one also reacted with γ2 hordein and several members of the CNBr cleavage class II B hordein polypeptides. One antibody recognized γ3 hordein but cross-reacted at higher antibody concentration with almost all of the B and C hordein polypeptides. The specificity of the monoclonal antibodies was confirmed by Western blotting of one- or two-dimensionally separated hordein from the B hordein-deficient mutant hor2ca and its wild-type Carlsberg II and the γ3 hordein-deficient genotype Nevsky. The identification of the γ hordein-specific monoclonal antibodies was further supported by immune precipitation of in-vitro transcribed and translated γ2 hordein, and hor2ca and Carlsberg II mRNA translation products. The monoclonal antibodies were used to screen for mutants in γ hordein synthesis. Two mutants, one deficient in γ 1 hordein synthesis and a second in γ 2 or closely related B hordein polypeptides were identified. A model is proposed for the evolution of the sulphur-rich hordein loci Hor5 and Hor2.

Molecular characterization of two types of 22 kilodalton alpha-zein genes in a gene cluster in maize

Five genes of the alpha-zein subfamily four (SF4) are located in a 56 kb genomic region of the maize inbred line W22. Their nucleotide and deduced amino acid sequences have been determined. The sequences define two types of alpha-zein SF4 genes-type 1 (T1) and type 2 (T2). The single T1 alpha-zein SF4 gene codes for an alpha-zein protein with a M(r) of about 22,000. This is the first alpha-zein SF4 gene sequenced that contains no early in-frame stop codons in its coding sequence. The four T2 alpha-zein SF4 genes in this cluster contain one or two early in-frame stop codons. In addition, our T1 and T2 genes differ markedly in the base sequences of their distal 5' non-translated flanking regions. The nucleotide and the deduced amino acid sequences of these two types of alpha-zein SF4 genes are similar (greater than 90%) to one another and to all known alpha-zein SF4 genes and cDNAs. Of the known W22 alpha-zein SF4 genes, only one in six does not contain an early in-frame stop codon. If the number of alpha-zein SF4 genes is 15-20, then we estimate that only about 4 of the W22 alpha-zein SF4 genes are without in-frame early stop codons.

Conserved structure and organization of B hordein genes in the Hor 2 locus of barley

This work presents new information on the structure and organization of B hordein genes in the Hor 2 locus of barley. Data obtained by Southern blot analysis and cloning and sequencing of different members of this multigene family are discussed.

A plant serpin gene. Structure, organization and expression of the gene encoding barley protein Z4

A 3133-bp nucleotide sequence of the gene Paz1 on chromosome 4 of barley, encoding endosperm protein Z4, has been determined. The sequence includes 1079 bp 5' upstream and 523 bp 3' downstream of the coding region. The 1079-bp 5' upstream region of the gene shows little similarity to 5' regions of other sequences genes expressed in the developing cereal endosperm. The coding sequence is interrupted by one 334-bp-long intron (bases 1497-1830). The deduced amino acid sequence, which was corroborated by peptide sequences, consists of 399 amino acids and has a molecular mass of 43,128 Da. This sequence confirms protein Z4 to be a member of the serpin superfamily of proteins. The similarity with other members of the family expressed as amino acids in identical positions is in the order of 25-30% and pronounced in the carboxy-terminal half of the molecule. Sequence residues assumed to form clusters stabilizing the tertiary structure are highly conserved. Protein Z4 is synthesized in the developing endosperm without a signal peptide and protein Z4 mRNA was evenly distributed among the free and membrane-bound polyribosomes of the endosperm cell. An internal hydrophobic region of 21 amino acids (residues 36-56) may serve as a signal for targeting the polypeptide into the lumen of the endoplasmic reticulum. The gene for protein Z4 could not be detected in the barley variety Maskin and some of its descendants. The 'high-lysine' allees, lys1 (Hiproly barley) and lys3a (Bomi mutant 1508) on chromosome 7, enhance and repress, respectively, the expression of the protein Z4 gene. Also, 1554 bp of another 8-kbp fragment of the barley genome Paz psi, similar to the protein-Z4-coding region, have been determined. Small insertions and deletions and the presence of an internal stop codon identify this fragment as part of a pseudogene related to the protein Z4 gene.

The bifunctional α-amylase/subtilisin inhibitor of barley: nucleotide sequence and patterns of seed-specific expression

We have cloned and sequenced a full-length cDNA from barley (Hordeum vulgare L.) seeds encoding the bifunctional α-amylase/subtilisin inhibitor (BASI). The nucleotide sequence predicts an open reading frame coding for a protein of 203 amino acids. The first 22 amino acids exhibit the sequence characteristic of a signal peptide, as found in several other plant protease inhibitors. Northern blot hybridization experiments indicate that BASI mRNA accumulation is strictly tissue-specific and is developmentally programmed. BASI mRNA transcripts were only identified in 1) developing starchy endosperm tissue from 14 days after flowering and 2) aleurone tissue of germinating seeds. In this latter tissue, BASI mRNA accumulation is enhanced by abscisic acid and abolished by gibberellic acid. Expression of BASI mRNA was also studied in the lys 3a high-lysine barley mutants Risø No. 1508 and Piggy. These high-lysine barleys show 2-4-fold higher levels as well as prolonged accumulation of BASI mRNA compared to the normal motherline Bomi. This correlates with the increased deposition of BASI protein in lys 3a barley mutants. Genomic blot analysis of barley DNA suggests that there are one or two BASI structural genes per haploid genome. Possible roles of BASI as part of a defence mechanism against precocious germination and pathogens are discussed.

Mapping of the Hor2 locus in barley by pulsed field gel electrophoresis

High molecular weight DNA released from isolated protoplasts was digested with rare-cutting restriction enzymes and separated by pulsed field gel electrophoresis. The average size of undigested DNA was above 1500 kbp. Digests made with NotI, SfiL, Mlul and SalI was hybridized to a probe, common to all genes of the Hor2 locus encoding B-hordein polypeptides, and this revealed the maximum size of the locus to be 360 kbp. Two probes, specific for individual B-hordein genes, enabled the identification of two fragment classes in the locus, each containing an equal number of B-hordein genes. Double digests allowed ordering of sites and construction of a map covering 650 kbp around the Hor2 locus. No evidence for physical linkage of the two fragment classes was obtained. The possible assignment of the two classes of hybridizing fragments to the B1- and B3-hordein subgroups is discussed.

Structural elements regulating zein gene expression

Zeins are a group of alcohol-soluble proteins that are synthesized in the endosperm of developing maize seeds. These proteins are encoded by a large number of genes located on several chromosomes; based upon the number of mutants that have been isolated, zein gene regulation is complex. Comparisons of gene flanking regions reveal conserved sequences that may be important for their regulation. Studies of transformed plant tissues support the assertion that cis-acting elements with the 5' flanking regions of zein genes are required for accurate transcription. Although the genes are transcribed in transgenic tobacco and petunia plants, they are not properly regulated. This appears to be due to transcriptional effects rather than protein or mRNA instability.

Molecular characterization of an active wheat LMW glutenin gene and its relation to other wheat and barley prolamin genes

The isolation and characterisation by DNA sequencing of a low molecular weight (LMW) glutenin gene from wheat is described. The deduced protein contains a signal peptide, a central repetitive region rich in proline and glutamine and N and C terminal non-repetitive domains, similar to other prolamins. A detailed comparison of the C terminal domain of 20 prolamin genes enabled us to divide them into 4 families. The LMW glutenin family is distinct from the alpha, beta- and gamma-gliadin families of wheat and is closest to the B hordein genes of barley. This and other comparisons were also used to assess the pattern of genetic variation among prolamin sequences and to provide a molecular basis for the interpretation of prolamin size polymorphism. The 5' flanking fragment of the isolated gene was previously shown to direct endosperm-specific expression of a reporter gene in transgenic tobacco. Evidence is provided that the isolated gene is also active in wheat and its transcription initiation site was determined. Features of the gene which may be relevant to its activity are discussed.

A γ-hordein gene

The 1614 bp nucleotide sequence of a barley gene encoding a γ-hordein endosperm storage polypeptide is presented. The deduced amino acid sequence is 305 amino acids long. It comprises a 19 amino acid signal peptide, an N-terminal half composed of proline-glutamine blocks organized in repeating units and a C-terminal half where the repeats are dispersed and less conserved. The deduced amino acid sequence shows strong homology to a γ-gliadin polypeptide from wheat and a γ-secalin polypeptide from rye and less homology to a B1 hordein polypeptide from barley. The 378 bp 5' non-coding region contains a TATA box at-85, an AGGA sequence at-105 and a-300 element typical of prolamin storage protein genes. The transcript start is 56 bp upstream of the ATG codon and 30 bp downstream of the TATA box. The 318 bp 3' non-coding region contains 2 putative polyadenylation signals, 76 and 132 bp downstream of the stop codon. γ-Hordein polypeptides are encoded by a small multigene family. The γ-hordein gene family is not part of the deleted chromosome 5 region, containing the Hor 2 locus, in the B hordein-deficient mutant hor 2ca. Two mRNA size classes of 1350 and 1450 nt are detectable in wild-type endosperms from 8 to 26 days after anthesis. The mutant hor 2ca contains as much γ-hordein mRNA as the wild type, whereas the B and C hordein-deficient mutant lys 3a contains barely detectable amounts.

Primary structure of a C-hordein gene from barley

The nucleotide sequence of a 2065 base pair HindIII fragment, containing a gene (lambda hor1-14) belonging to the Hor1 locus in barley, has been determined. The fragment consists of 1044 bp of coding region interrupted by an amber codon at base 481, a 5' non-coding region of 428 bp and a 3' non-coding region with 593 bp. The deduced amino acid sequence of the mature protein (327 amino acids) is characterized by an octapeptide motif PQQPFPQQ which is repeated throughout the peptide chain between a unique 12 amino acid long NH2-terminal and an equally unique 10 amino acid long COOH-terminal end. The proline + glutamine content is 62% and the next three most abundant amino acids are leucine (9%), phenylalanine (8%) and isoleucine (3%). In the 5' non-coding region there is a TATA box at -98 bp from the start methionine. The 3' non-coding region has a polyadenylation signal 76 bp downstream from the TAA stop codon. The deduced amino acid sequences of the NH2- and COOH-terminals of lambda hor1-14 are very similar but not identical to those known from the Edman degradation and carboxypeptidase Y analysis of C-hordein polypeptides. The 3' coding and non-coding region of lambda hor1-14 is closely similar but different in detail to the known C-hordein cDNA clones. One polyadenylation signal is found in lambda hor1-14 whereas two are present in each of the three known C-hordein cDNAs. These differences and the amber codon interrupting the open reading frame indicate that this gene is silent.

N-terminal sequences of oat avenins compared to other cereal prolamins

Like the alcohol-soluble seed storage proteins (also called prolamins) of other cereals, avenins, the oat prolamins, are a series of polymorphic molecules belonging to a multigenic family stored within the protein bodies of the starchy endosperm. Nevertheless, they exhibit some pecularities: among the seed storage proteins, their proportion is low compared to prolamins from other cereal species; their net charge is higher; the amount of Gln + Pro only reaches 49 mol%; they are less polymorphic. We have isolated and purified several avenins and sequenced their N-terminal end. The microheterogeneity and the pecularity of avenins are revealed by the comparison of the N-terminal sequences. Like other prolamins, they exhibit tandem repeats; these repetitive peptides are slightly different from those of other prolamins of the Festucoideae, and the repetition begins earlier in the sequence. As for prolamins from other species, their predicted secondary structure reveals successive beta-turns which might be arranged in a pseudo-helix structure.

Characterization and genetic control of the prolamins of Haynaldia villosa: relationship to cultivated species of the Triticeae (rye, wheat, and barley)

Haynaldia villosa is a wild grass of the tribe Triticeae, other members of which include the cultivated cereals barley, rye, and wheat. We have made an electrophoretic and chemical characterization of the major seed storage proteins (prolamins) of H. villosa and determined the chromosomal locations of the structural genes for some components using the available wheat/H. villosa chromosome addition lines. As in wheat, barley, and rye, groups of high molecular weight (polymeric), sulfur-poor (monomeric), and sulfur-rich (monomeric gamma-type and polymeric) prolamins can be recognized. Most of the components are encoded by genes on chromosome 1 Ha, which is homologous with the chromosomes controlling many of the prolamins in wheat and rye and all of those in barley. In addition, H. villosa also contains alpha-type sulfur-rich prolamins, previously detected only in wheat and its close relatives. These may be encoded by genes on chromosome 6Ha, which is homologous with the group 6 chromosomes that control the alpha-type gliadins of wheat. Despite the proposed close relationship between Haynaldia and ryes, no evidence was found for the presence of proteins closely related to the Mr 75,000 gamma-secalins which are characteristic of wild and cultivated species of Secale.

Analyses of alpha/beta-type gliadin genes from diploid and hexaploid wheats

The alpha/beta-gliadin genes isolated from both hexaploid wheat (cv. Yamhill) and the diploid A genome progenitor Triticum urartu had remarkably similar sequences and differ by only a few point mutations. Primer extension analysis indicated that the transcriptional start points for individual genes in the family cluster within a few nucleotides. Comparison of the promoter region of several alpha/beta-gliadin and B-hordein genes reveals two conserved regions at about -130 and -250 bp. DNA from the hexaploid cultivars, Cheyenne and Chinese Spring, and the diploid progenitors T. urartu and Aegilops squarrosa was analysed by Southern blotting. Restriction fragment lengths of the alpha/beta-gliadin genes varied only slightly between the various wheats, although the overall copy number varied significantly. A region between approx. -1700 and -700 bp upstream from the TATA box was highly repeated in all three wheat genomes. For the hexaploid-derived gene, over 1700 bp of sequence upstream from the TATA box was determined, revealing an additional open reading frame between approx. -1550 and -1250 bp relative to the gliadin TATA box. Northern blot analysis indicated that RNA homologous to this repeated sequence family was present only in developing seed and accumulated to a maximum at late stages of maturation.