Accumulation of 15-Kilodalton Zein in Novel Protein Bodies in Transgenic Tobacco

Zeins, the seed storage proteins of maize, are a group of alcohol-soluble polypeptides of different molecular masses that share a similar amino acid composition but vary in their sulfur amino acid composition. They are synthesized on the rough endoplasmic reticulum (ER) in the endosperm and are stored in ER-derived protein bodies. Our goal is to balance the amino acid composition of the methionine-deficient forage legumes by expressing the sulfur amino acid-rich 15-kD zeins in their leaves. However, it is crucial to know whether this protein would be stable in nonseed tissues of transgenic plants. The major focus of this paper is to compare the accumulation pattern of the 15-kD zein protein with a vacuolar targeted seed protein, [beta]-phaseolin, in nonseed tissues and to determine the basis for its stability/instability. We have introduced the 15-kD zein and bean [beta]-phaseolin-coding sequences behind the 35S cauliflower mosaic virus promoter into tobacco (Nicotiana tabacum) and analyzed the protein's accumulation pattern in different tissues. Our results demonstrate that the 15-kD seed protein is stable not only in seeds but in all nonseed tissues tested, whereas the [beta]-phaseolin protein accumulated only in mid- and postmaturation seeds. Interestingly, zein accumulates in novel protein bodies both in the seeds and in nonseed tissues. We attribute the instability of the [beta]-phaseolin protein in nonseed tissues to the fact that it is targeted to protease-rich vacuoles. The stability of the 15-kD zein could be attributed to its retention in the ER or to the protease-resistant nature of the protein.     

A modified storage protein is synthesized,processed, and degraded in the seeds of transgenic plants

In vitro mutagenesis was used to supplement the sulfur amino acid codon content of a gene encoding -phaseolin, a Phaseolus vulgaris storage protein. The number of methionine codons in the phaseolin gene was increased from three to nine by insertion of a 45 base pair (bp) synthetic duplex. Either modified or normal phaseolin genes were integrated into the genome of tobacco plants through Agrobacterium tumefaciens-mediated transformation. Although similar levels of phaseolin RNA are detected in seeds of plants transformed with either the normal or modified (himet) gene, the quantity of himet protein is consistently much lower than normal -phaseolin. Himet phaseolin is expressed in a temporal- and organ-specific fashion, and is N-glycosylated and assembled into trimers in the manner of normal phaseolin. After germination, both types of phaseolin are hydrolyzed, but the himet protein is more quickly degraded. Electron microscopic immunocytochemical observations of developing seeds indicate that the himet protein is primarily localized in the endoplasmic reticulum (ER) and in Golgi apparatus secretion vesicles. Himet phaseolin is absent from protein storage vacuoles, termed protein bodies, where normal phaseolin is deposited in transgenic tobacco. We interpret the immunocytochemical data to indicate that himet phasolin is transported through the ER and Golgi apparatus and is then degraded in Golgi secretion vesicles or the protein bodies.Mention of trademark, proprietary product, or vendor does not constitute a guarantee of warranty of the product by the United States Department of Agriculture and does not imply its approval to the exclusion of other products or vendors that may also be suitable. Publication No. 70 from Agrigenetics Advanced Science Company.     

Developmental control of the β-phaseolin gene requires positive, negative, and temporal seed-specific transcriptional regulatory elements and a negative element for stem and root expression

To identify cis-acting regulatory elements responsible for developmental control of the common bean seed storage protein β-phaseolin, a series of 5′-deletion mutants of the 782 bp upstream sequence together with the coding and 3′-regions of the β-phaseolin gene were used to transform tobacco. One major positive regulatory element (?295/?228) and a putative minimal promoter (?64/?14) were indicated by large reductions in phaseolin mRNA and protein concentrations in seeds of plants deficient for these regions. In addition, minor negative (?422/?296) and positive (?782/?423) elements also influenced the level of phaseolin mRNA expression in seeds. One temporal element (?295/?107) governed late expression of phaseolin mRNA in seeds, and possibly a second (?64/?14) regulated early expression. The ?64/?14 promoter containing two TATA boxes conferred spatially regulated gene expression, and was sufficient for a low level of expression in root and stem. Significant levels of phaseolin mRNA and protein were detected in stem cortices and secondary roots of plants lacking the ?295/?107 negative element. No significant expression in leaf tissue was detected. Results demonstrate that developmental control of β-phaseolin requires a minimal promoter, one element for the suppression of expression in root and stem tissue, three elements governing quantitative expression in seeds, and at least one temporal element controlling expression in seeds.     

Developmentally regulated plant genes: the nucleotide sequence of a wheat gliadin genomic clone

Gliadins, the major wheat seed storage proteins, are encoded by a multigene family. Northern blot analysis shows that gliadin genes are transcribed in endosperm tissue into two classes of poly(A)+ mRNA, 1400 bases (class I) and 1600 bases (class II) in length. Using poly(A)+ RNA from developing wheat endosperm we constructed a cDNA library from which a number of clones coding for alpha/beta and gamma gliadins were identified by hybrid-selected mRNA translation and DNA sequencing. These cDNA clones were used as probes for the isolation of genomic gliadin clones from a wheat genomic library. One such genomic clone was characterized in detail and its DNA sequence determined. It contains a gene for a 33-kd alpha/beta gliadin protein (a 20 amino acid signal peptide and a 266 amino acid mature protein) which is very rich in glutamine (33.8%) and proline (15.4%). The gene sequence does not contain introns. A typical eukaryotic promoter sequence is present at -104 (relative to the translation initiation codon) and there are two normal polyadenylation signals 77 and 134 bases downstream from the translation termination codon. The coding sequence contains some internal sequence repetition, and is highly homologous to several alpha/beta gliadin cDNA clones. Homology to a gamma-gliadin cDNA clone is low, and there is no homology with known glutenin or zein cDNA sequences.     

Differential accumulation of four phaseolin glycoforms in transgenic tobacco

An intron-less phaseolin gene [15] was used to express phaseolin polypeptides in transgenic tobacco plants. The corresponding amounts of phaseolin immunoreactive polypeptides and mRNA were similar to those found in plants transformed with a bean genomic DNA sequence that encodes an identical -phaseolin subunit. These results justified the use of the intron-less gene for engineering of the phaseolin protein by oligonucleotide-directed mutagenesis. Each and both of the two Asn residues that serve as glycan acceptors in wild-type phaseolin were modified to prevent N-linked glycosylation. Wild-type (wt^i–) and mutant phaseolin glycoforms (dgly ₁, dgly ₂ and dgly _1,2) were localized to the protein body matrix by immunogold microscopy. Although quantitative slot-blot hybridization analysis showed similar levels of phaseolin mRNA in transgenic seed derived from all constructs, seed from the dgly ₁ and dgly ₂ mutations contained only 41% and 73% of that expressed from the wild-type control; even less (23%) was present in seed of plants transformed with the phaseolin dgly _1,2 gene. Additionally, the profile of 25–29 kDa processed peptides was different for each of the glycoforms, indicating that processing of the full-length phaseolin polypeptides was modified. Thus, although targeting of phaseolin to the protein body was not eliminated by removal of the glycan side-chains, decreased accumulation and stability of the full-length phaseolin protein in transgenic tobacco seed were evident.Abbreviations bp base pair(s) - DAF days after flowering - GUS -glucuronidase - kb kilobase - kDa kilodalton     

Structure, expression, and heterogeneity of the rice seed prolamines

By screening two rice (Oryza sativa L.) seed cDNA libraries, recombinant cDNA clones encoding the rice prolamine seed storage protein were isolated. Based on cross-hybridization and restriction enzyme map analyses, these clones can be divided into two homology classes. All clones contain a single open reading frame encoding a putative rice prolamine precursor (molecular weight = 17,200) possessing a typical 14-amino acid signal peptide. The deduced primary structures of both types of prolamine polypeptides are devoid of repetitive sequences, a feature prevalent in other cereal prolamines. Clones of these two homology classes diverge mainly by insertions/deletions of short nucleotide stretches and point mutations. An isolated genomic clone about 15.5 kilobases in length displays a highly conserved 2.5-kilobase EcoRI fragment, repeated in tandem four times, each containing the prolamine coding sequence. Close homology is exhibited by the coding segments of the genomic and cDNA sequences, although the 5′ ends of the untranslated regions are widely divergent. The sequence heterogeneity displayed by these genomic and cDNA clones and large gene copy number (~80-100 copies/haploid genome) indicate that the rice prolamines are encoded by a complex multigene family.     

Cell Ablation Reveals That Expression from the Phaseolin Promoter Is Confined to Embryogenesis and Microsporogenesis

Most previous studies of the [beta]-phaseolin (phas) gene, which encodes the major storage protein in bean (Phaseolus vulgaris L.), have shown its expression to be rigorously confined to the developing seed, both in bean and transgenic tobacco (Nicotiana tabacum L. cv Xanthi) plants. To confirm unequivocally the lack of phas expression in vegetative tissues, we placed the diphtheria toxin A-chain (DT-A) coding region under the control of [beta]-phaseolin promoter sequences. Tobacco plants transgenic for phas/DT-A were phenotypically normal until flowering, when they produced anthers that were externally normal but contained no viable pollen. Microscopic examination of immature anthers revealed a normal tapetum, but the pollen mother cells did not undergo meiosis and subsequently degenerated, resulting in male-sterile plants. This demonstration of phas expression during microsporogenesis was corroborated by the expression of [beta]-glucuronidase in pollen of plants transformed with comparable phas/uidA constructs. Although these findings suggested that similarities in phas expression may exist between seed and pollen maturation, no phas activity could be detected in bean pollen. After fertilization of the DT-A-transformed plants with pollen from wild-type tobacco, 50% of the resulting embryos aborted at the heart stage, defining this as the earliest time for phas expression during embryogenesis.     

Expression pattern and activity of six glutelin gene promoters in transgenic rice

The shortage of strong endosperm-specific expression promoters for driving the expression of recombinant protein genes in cereal endosperm is a major limitation in obtaining the required level and pattern of expression. Six promoters of seed storage glutelin genes (GluA-1, GluA-2, GluA-3, GluB-3, GluB-5, and GluC) were isolated from rice (Oryza sativa L.) genomic DNA by PCR. Their spatial and temporal expression patterns and expression potential in stable transgenic rice plants were examined with beta-glucuronidase (GUS) used as a reporter gene. All the promoters showed the expected spatial expression within the endosperm. The GluA-1, GluA-2, and GluA-3 promoters directed GUS expression mainly in the outer portion (peripheral region) of the endosperm. The GluB-5 and GluC promoters directed GUS expression in the whole endosperm, with the latter expressed almost evenly throughout the whole endosperm, a feature different from that of other rice glutelin gene promoters. The GluB-3 promoter directed GUS expression solely in aleurone and subaleurone layers. Promoter activities examined during seed maturation showed that the GluC promoter had much higher activity than the other promoters. These promoters are ideal candidates for achieving gene expression for multiple purposes in monocot endosperm but avoid promoter homology-based gene silencing. The GluC promoter did not contain the endosperm specificity-determining motifs GCN4, AACA, and the prolamin-box, which suggests the existence of additional regulatory mechanism in determining endosperm specificity.     

Expression and localization of human lysozyme in the endosperm of transgenic rice

In order to understand the characteristics of recombinant protein expression and sublocalization in rice ( Oryza sativa L.) endosperm, we examined the expression level of human lysozyme protein and its subcellular location in transgenic rice seeds driven by rice glutelin and globulin promoters and signal peptides. A time course of human lysozyme expression during endosperm development was analyzed. The results showed that the expression profile of recombinant protein accumulation in endosperm paralleled that of the two storage proteins. Immunofluorescence microscopy revealed that human lysozyme and storage proteins co-localized to type-II protein bodies. Both promoter-signal peptide parings targeted recombinant protein to the protein bodies. In addition, a transgenic line with a higher lysozyme expression level exhibited morphologically different protein bodies with an unbalanced composition of lysozyme and native storage proteins. The high-level expression of recombinant protein distorted the trafficking and sorting of native storage proteins in rice endosperm and affected the expression of native storage protein.     

Quantitative nature of the Prolamin-box, ACGT and AACA motifs in a rice glutelin gene promoter: minimal cis-element requirements for endosperm-specific gene expression

The -197 bp promoter of the rice seed storage protein gene, GluB-1, is capable of conferring endosperm-specific gene expression. This proximal 5' flanking region contains four motifs, GCN4, AACA, ACGT and Prolamin-box, which are conserved in many seed storage protein genes. We previously showed that multiple copies of GCN4 conferred endosperm expression pattern when fused to the -46 core promoter of CaMV 35S. In this paper we demonstrate, using a similar approach, that tandem repeated copies of any of the other three motifs are unable to direct expression in seeds as well as other tissues of transgenic rice plants. Mutational analysis of individual motifs in the -197 bp promoter resulted in remarkable reductions in promoter activity. These results indicate that the GCN4 motif acts as an essential element determining endosperm-specific expression and that the AACA, ACGT and Prolamin-box are involved in quantitative regulation of the GluB-1 gene. A set of gain-of-function experiments using transgenic rice showed that either the Prolamin-box or AACA, although often coupled with GCN4 in many genes, is insufficient to form a functional promoter unit with GCN4, whereas a combination of GCN4, AACA and ACGT motifs was found sufficient to confer a detectable level of endosperm expression. Taken together, our results provide direct insight into the importance of combinatorial interplay between cis-elements in regulating the expression of seed storage protein genes.     

Correct targeting of the bean storage protein phaseolin in the seeds of transformed tobacco

The storage protein phaseolin accumulates during seed development in protein bodies in cotyledons of the common bean Phaseolus vulgaris. Hall et al. (In L Van Vloten-Doting, TC Hall, eds, Molecular Form and Function of the Plant Genome, 1985 Plenum Press, In press) recently reported the expression of a gene coding for phaseolin and the accumulation of phaseolin protein in developing seeds of tobacco plants regenerated from transformed callus cells. The protein did not accumulate in other organs of the plants. Mature seeds from normal and transformed tobacco plants were obtained and the subcellular distribution of phaseolin in the seeds was examined using both light and electron microscopic immunocytochemical methods. Phaseolin was found in six of seven transformed tobacco embryos examined, but was present in only one endosperm of five. When present, phaseolin was located exclusively in the protein bodies of the embryonic and endospermic cells. Furthermore, phaseolin was restricted solely to the amorphous matrix of the protein bodies and was excluded from the globoid and proteinaceous crystalloid components of these organelles. The subcellular location of phaseolin in seeds from transformed tobacco plants is similar to that seen in mature seeds of the common bean indicating that in the transformed cells the protein is targeted to the right subcellular compartment.     

Characterization of a barley gene coding for an α-amylase inhibitor subunit (CMd protein) and analysis of its promoter in transgenic tobacco plants and in maize kernels by microprojectile bombardment

A gene coding for a barley CMd protein was isolated from a genomic library using a cDNA probe encoding the wheat CM3 protein. Promoter sequence analysis reveals motifs found in genes specifically expressed in endosperm and aleurone cells, as well as TATA and other putative functional boxes. 720 bp of the Hv85.1 CMd protein gene promoter, when fused to a gus coding region, were unable to direct GUS activity in the seeds of transgenic tobacco plants. In contrast, the same construction delivered into immature maize kernels by microprojectile bombardment was able to direct expression of GUS in the outermost cell layers of maize endosperm in both a tissue-specific and a developmentally determined manner.     

The endoplasmic reticulum stress induced by highly expressed OsrAAT reduces seed size via pre-mature programmed cell death

The high accumulation of a recombinant protein in rice endosperm causes endoplasmic reticulum (ER) stress and in turn dramatically affects endogenous storage protein expression, protein body morphology and seed phenotype. To elucidate the molecular mechanisms underlying these changes in transgenic rice seeds, we analyzed the expression profiles of endogenous storage proteins, ER stress-related and programmed cell death (PCD)-related genes in transgenic lines with different levels of Oryza sativa recombinant alpha antitrypsin (OsrAAT) expression. The results indicated that OsrAAT expression induced the ER stress and that the strength of the ER stress was dependent on OsrAAT expression levels. It in turn induced upregulation of the expression of the ER stress response genes and downregulation of the expression of the endogenous storage protein genes in rice endosperm. Further experiments showed that the ER stress response upregulated the expression of PCD-related genes to disturb the rice endosperm development and induced pre-mature PCD. As consequence, it resulted in decrease of grain weight and size. The mechanisms for the detriment seed phenotype in transgenic lines with high accumulation of the recombinant protein were elucidated.     

Increased lysine content in rice grains by over-accumulation of BiP in the endosperm

Over-accumulation of lysine-rich binding protein (BiP) in the rice endosperm caused strong endoplasmic reticulum (ER) stress and reduced seed storage proteins, resulting in a relative increase in nutritionally balanced non-seed storage proteins. We show that transgenic rice with over-accumulated BiP was a high-lysine rice germplasm and that the over-accumulation of BiP in the endosperm offered a unique strategy to improve the lysine content of cereal grains.