Assembly and transport of seed storage proteins.

Plant seeds store nitrogen by accumulating storage proteins in protein bodies within various compartments of the endomembrane system. The prolamin storage proteins of some cereal species are normally retained and assembled into protein bodies within the ER. Yet, these proteins lack a C-terminal KDEL/HDEL signal, suggesting that their retention is regulated by novel mechanisms. Furthermore, in other cereal species, such protein bodies formed within the ER may be subsequently internalized into vacuoles by a special route that does not utilize the Golgi complex. Thus, studies of the routing of seed storage proteins are revealing novel mechanisms of protein assembly and transport in the endomembrane system.

Evidence for a novel route of wheat storage proteins to vacuoles.

Wheat seed storage proteins are deposited in protein bodies (PB) inside vacuoles, but their subcellular site of aggregation and their route to vacuoles are still controversial. In the present work, an ultra structural analysis of developing wheat endosperm at early to mid maturation was performed to address these issues. Golgi complexes were rarely detected, indicating that their role in wheat storage protein transport is limited. In contrast, a considerable amount of PB was detected in the cytoplasm. Many of these PB were surrounded by RER membranes and were enlarged by fusion of smaller PB. Small, electron lucent vesicles were detected around the surfaces of the PB in the cytoplasm, or attached to them, suggesting that such attachments and subsequent fusion of the vesicles with each other lead to the formation of small vacuoles containing PB inclusions. Immunogold labeling with serum raised against yeast-BiP, an ER-localized protein, demonstrated that the wheat BiP homolog was present within the PB in the cytoplasm as well as inside vacuoles. This confirmed that the PB were formed within the RER and that the Golgi complex was not involved in their transport to vacuoles. It is concluded that a considerable part of the wheat storage proteins aggregate into PB within the RER and are then transported as intact PB to the vacuoles by a novel route that does not utilize the Golgi complex.

Aggregation of lysine-containing zeins into protein bodies in Xenopus oocytes.

Zeins, the storage proteins of maize, are totally lacking in the essential amino acids lysine and tryptophan. Lysine codons and lysine- and tryptophan-encoding oligonucleotides were introduced at several positions into a 19-kilodalton zein complementary DNA by oligonucleotide-mediated mutagenesis. A 450-base pair open reading frame from a simian virus 40 (SV40) coat protein was also engineered into the zein coding region. Messenger RNAs for the modified zeins were synthesized in vitro with an SP6 RNA polymerase system and injected into Xenopus laevis oocytes. The modifications did not affect the translation, signal peptide cleavage, or stability of the zeins. The ability of the modified zeins to assemble into structures similar to maize protein bodies was assayed by two criteria: assembly into membrane-bound vesicles resistant to exogenously added protease, and ability to self-aggregate into dense structures. All of the modified zeins were membrane-bound; only the one containing a 17-kilodalton SV40 protein fragment was unable to aggregate. These findings suggest that it may be possible to create high-lysine corn by genetic engineering.

Two Closely Related Wheat Storage Proteins Follow a Markedly Different Subcellular Route in Xenopus laevis Oocytes.

[alpha]-Gliadins and [gamma]-gliadins are two closely related wheat storage proteins that evolved from a common ancestral gene. However, synthesis of [alpha]-gliadins and [gamma]-gliadins in Xenopus laevis oocytes revealed striking differences in their subcellular routing. The major portion of [alpha]-gliadin accumulated inside the oocyte, whereas most of the [gamma]-gliadin was secreted. Disruption of the Golgi apparatus by monensin revealed that the major part of secretion of [gamma]-gliadin is Golgi mediated. The difference in the subcellular route between [alpha]-gliadin and [gamma]-gliadin may be attributed to differential transport from the endoplasmic reticulum to the Golgi apparatus, a process that is generally the rate-limiting step in protein secretion. Coinjection of the two mRNAs had no effect on their routing, indicating no interaction between them. Our results support the hypothesis that subcellular transport of gliadins in wheat endosperm occurs in two separate routes; one is Golgi mediated, and the other is not. We also show that the subcellular transport may be markedly affected by small structural variations within closely related storage proteins.

Translational regulation of human beta interferon mRNA: association of the 3' AU-rich sequence with the poly(A) tail reduces translation efficiency in vitro.

The 3' AU-rich region of human beta-1 interferon (hu-IFN beta) mRNA was found to act as a translational inhibitory element. The translational regulation of this 3' AU-rich sequence and the effect of its association with the poly(A) tail were studied in cell-free rabbit reticulocyte lysate. A poly(A)-rich hu-IFN beta mRNA (110 A residues) served as an inefficient template for protein synthesis. However, translational efficiency was considerably improved when the poly(A) tract was shortened (11 A residues) or when the 3' AU-rich sequence was deleted, indicating that interaction between these two regions was responsible for the reduced translation of the poly(A)-rich hu-IFN beta mRNA. Differences in translational efficiency of the various hu-IFN beta mRNAs correlated well with their polysomal distribution. The poly(A)-rich hu-IFN beta mRNA failed to form large polysomes, while its counterpart bearing a short poly(A) tail was recruited more efficiently into large polysomes. The AU-rich sequence-binding activity was reduced when the RNA probe contained both the 3' AU-rich sequence and long poly(A) tail, supporting a physical association between these two regions. Further evidence for this interaction was achieved by RNase H protection assay. We suggest that the 3' AU-rich sequence may regulate the translation of hu-IFN beta mRNA by interacting with the poly(A) tail.

Lysine catabolism: a stress and development super-regulated metabolic pathway.

Lysine is a nutritionally important essential amino acid whose level in plants is largely regulated by the rate of its synthesis. In some plant tissues and under some stress conditions, however, lysine is also efficiently catabolized into glutamate and several other stress-related metabolites by novel mechanisms of metabolic regulation. Lysine catabolism is important for mammalian brain function; it is possible that the generation of glutamate regulates nerve transmission signals via glutamate receptors. Plants also possess homologues of animal glutamate receptors. It is thus likely that lysine catabolism also regulates various plant processes via these receptors.

Expression of an Aspartate Kinase Homoserine Dehydrogenase Gene Is Subject to Specific Spatial and Temporal Regulation in Vegetative Tissues, Flowers, and Developing Seeds.

Although the regulation of amino acid synthesis has been studied extensively at the biochemical level, it is still not known how genes encoding amino acid biosynthesis enzymes are regulated during plant development. In the present report, we have used the [beta]-glucuronidase (GUS) reporter gene to study the regulation of expression of an Arabidopsis thaliana aspartate kinase-homoserine dehydrogenase (AK/HSD) gene in transgenic tobacco plants. The polypeptide encoded by the AK/HSD gene comprises two linked key enzymes in the biosynthesis of aspartate-family amino acids. AK/HSD-GUS gene expression was highly stimulated in apical and lateral meristems, lateral buds, young leaves, trichomes, vascular and cortical tissues of growing stems, tapetum and other tissues of anthers, pollen grains, various parts of the developing gynoecium, developing seeds, and, in some transgenic plants, also in stem and leaf epidermal trichomes. AK/HSD-GUS gene expression gradually dimished upon maturation of leaves, stems, floral tissues, and embryos. GUS expression was relatively low in roots. During seed development, expression of the AK/HSD gene in the embryo was coordinated with the initiation and onset of storage protein synthesis, whereas in the endosperm it was coordinated with the onset of seed desiccation. Upon germination, AK/HSD-GUS gene expression in the hypocotyl and the cotyledons was significantly affected by light. The expression pattern of the A. thaliana AK/HSD-GUS reporter gene positively correlated with the levels of aspartate-family amino acids and was also very similar to the expression pattern of the endogenous tobacco AK/HSD mRNA as determined by in situ hybridization.

Expression of an arabidopsis aspartate Kinase/Homoserine dehydrogenase gene is metabolically regulated by photosynthesis-related signals but not by nitrogenous compounds

Although the control of carbon fixation and nitrogen assimilation has been studied in detail, relatively little is known about the regulation of carbon and nitrogen flow into amino acids. In this paper we report our study of the metabolic regulation of expression of an Arabidopsis aspartate kinase/homoserine dehydrogenase (AK/HSD) gene, which encodes two linked key enzymes in the biosynthetic pathway of aspartate family amino acids. Northern blot analyses, as well as expression of chimeric AK/HSD-beta-glucuronidase constructs, have shown that the expression of this gene is regulated by the photosynthesis-related metabolites sucrose and phosphate but not by nitrogenous compounds. In addition, analysis of AK/HSD promoter deletions suggested that a CTTGACTCTA sequence, resembling the binding site for the yeast GCN4 transcription factor, is likely to play a functional role in the expression of this gene. Nevertheless, longer promoter fragments, lacking the GCN4-like element, were still able to confer sugar inducibility, implying that the metabolic regulation of this gene is apparently obtained by multiple and redundant promoter sequences. The present and previous studies suggest that the conversion of aspartate into either the storage amino acid asparagine or aspartate family amino acids is subject to a coordinated, reciprocal metabolic control, and this biochemical branch point is a part of a larger, coordinated regulatory mechanism of nitrogen and carbon storage and utilization.

Wheat (Triticum aestivum L.) [gamma]-Gliadin Accumulates in Dense Protein Bodies within the Endoplasmic Reticulum of Yeast.

Following their sequestration into the endoplasmic reticulum (ER), wheat storage proteins may either be retained and packaged into protein bodies within this organelle or transported via the Golgi to vacuoles. We attempted to study the processes of transport and packaging of wheat storage proteins using the heterologous expression system of yeast. A wild-type wheat [gamma]-gliadin, expressed in the yeast cells, accumulated mostly within the ER and was deposited in protein bodies with similar density to natural protein bodies from wheat endosperm. This suggested that wheat storage proteins contain sufficient information to initiate the formation of protein bodies in the ER of a heterologous system. Only a small amount of the [gamma]-gliadin was transported to the yeast vacuoles. When a deletion mutant of the [gamma]-gliadin, lacking the entire N-terminal repetitive region, was expressed in the yeast cells, the mutant was unable to initiate the formation of protein bodies within the ER and was completely transported to the yeast vacuole. This strongly indicated that the information for packaging into dense protein bodies within the ER resides in the N-terminal repetitive region of the [gamma]-gliadin. The advantage of using yeast to identify the signals and mechanisms controlling the transport of wheat storage proteins and their deposition in protein bodies is discussed.

Suppression of tobacco basic chitinase gene expression in response to colonization by the arbuscular mycorrhizal fungus Glomus intraradices.

A differentially displayed cDNA clone (MD17) was isolated from tobacco roots (nicotiana tabacum cv. Xanthi-nc) infected with the arbuscular mycorrhizal (AM) fungus Glomus intraradices. The isolated DNA fragment exhibited a reduced level of expression in response to AM establishment and 90% identity with the 3' noncoding sequence of two basic chitinases (EC 3.2.1.14) from N. tabacum. Northern (RNA) blots and Western blots (immunoblots), probed with tobacco basic chitinase gene-specific probe and polyclonal antibodies raised against the chitinase enzyme, yielded hybridization patterns similar to those of MD17. Moreover, the up-regulation of the 32-kDa basic chitinase gene expression in tobacco roots by (1,2,3)-thiadiazole-7-carbothioic acid S-methyl ester (BTH) was less effective in mycorrhizal roots than in nonmycorrhizal controls. Suppression of endogenous basic chitinase (32-kDa) expression was also observed in transgenic mycorrhizal plants that constitutively express the 34-kDa basic chitinase A isoform. When plants were grown with an increased phosphate supply, no suppression of the 32-kDa basic chitinase was obtained. These findings indicate that during the colonization and establishment of G. intraradices in tobacco roots, expression of the basic chitinase gene is down-regulated at the mRNA level.

Induction of cytoplasmic factors that bind to the 3' AU-rich region of human interferon beta mRNA during early development of Xenopus laevis.

Certain endogenous Xenopus mRNAs, carrying a destabilizing 3' AU-rich sequence, are unusually very stable in oocytes and become unstable only after fertilization. In addition, heterologous short lived mRNA, containing 3' AU-rich sequences, appear to be very stable when injected into Xenopus oocytes. In the present study, a human interferon beta (hu-IFN beta) mRNA, carrying the destabilizing 3' AU-rich element, was used as a probe to identify Xenopus proteins that specifically bind to the 3' AU-rich element as well as to study their relative levels during early embryonic development. While three major proteins that specifically bind to the 3' AU-rich element were detected in human SV80 cells, that naturally express hu-IFN beta (proteins termed AU-F1, F2 and F3), only two proteins, migrating similarly to the SV80 AU-F1 and AU-F3, were detected in cytoplasmic extracts from Xenopus oocytes or eggs. Following fertilization, the intensity of the Xenopus AU-F1 and AU-F3 proteins increased considerably and a new protein, corresponding to SV80 AU-F2, was also detected. Cyclohexamide applied either at the morula or at the early blastula stages reduced the intensity of the AU-binding factors, while actinomycin D did not, indicating that the levels of these factors during these stages are regulated posttranscriptionally. In contrast, application of each of these metabolic inhibitors at the late blastula stage increased the intensity of the AU-binding proteins. The possible function of these AU-binding factors in regulating the expression and half life of AU-rich mRNAs is discussed.

Cloning, sequence analysis and expression in Escherichia coli of the cDNA encoding a precursor of peanut agglutinin.

The cDNA coding for pre-peanut agglutinin (PNA) was isolated from a bacterial expression library. It codes for a polypeptide of 273 amino acids composed of a hydrophobic signal peptide of 23 amino acids and a mature protein of 250 amino acids. The sequence of the latter is identical to that of native PNA, determined very recently by conventional methods, except that it contains 14 additional amino acids at the C-terminus. Bacterial cells harboring a plasmid with the prePNA-cDNA, produced two PNA cross-reacting proteins: one migrated on SDS-PAGE identically with the native lectin (apparent mol. wt. 31 kDa); the other, at 35 kDa, was a beta-galactosidase pre-PNA fusion protein. The former protein possessed an N-terminal sequence identical to that of the mature, native PNA, suggesting that it was processed from the 35 kDa prePNA precursor. Only the 31 kDa protein was exported into the bacterial periplasmic space, and had the ability to bind to galactose-Sepharose. The isolated processed protein had the same hemagglutinating activity as the native lectin, when assayed with sialidase-treated human erythrocytes. Like the native lectin, it did not agglutinate the untreated cells, was not inhibited by N-acetylgalactosamine, and was inhibited by Gal beta 1----3GalNAc 30-times more strongly than by galactose.

Alliin lyase (Alliinase) from garlic (Allium sativum). Biochemical characterization and cDNA cloning.

The garlic plant (Allium sativum) alliinase (EC 4.4.1.4), which catalyzes the synthesis of allicin, was purified to homogeneity from bulbs using various steps, including hydrophobic chromatography. Molecular and biochemical studies showed that the enzyme is a dimer of two subunits of MW 51.5 kDa each. Its Km using synthetic S-allylcysteine sulfoxide (+ isomer) as substrate was 1.1 mM, its pH optimum 6.5, and its isoelectric point 6.35. The enzyme is a glycoprotein containing 6% carbohydrate. N-terminal sequences of the intact polypeptide chain as well as of a number of peptides obtained after cyanogen bromide cleavage were obtained. Cloning of the cDNAs encoding alliinase was performed by a two-step strategy. In the first, a cDNA fragment (pAli-1-450 bp) was obtained by PCR using a mixed oligonucleotide primer synthesized according to a 6-amino acid segment near the N-terminal of the intact polypeptide. The second step involved screening of garlic lambda gt11 and lambda ZAPII cDNA libraries with pAli-1, which yielded two clones; one was nearly full length and the second was full length. These clones exhibited some degree of DNA sequence divergence, especially in their 3' noncoding regions, suggesting that they were encoded by separate genes. The nearly full length cDNA was fused in frame to a DNA encoding a signal peptide from alpha wheat gliadin, and expressed in Xenopus oocytes. This yielded a 50 kDa protein that interacted with the antibodies against natural bulb alliinase. Northern and Western blot analyses showed that the bulb alliinase was highly expressed in bulbs, whereas a lower expression level was found in leaves, and no expression was detected in roots. Strikingly, the roots exhibited an abundant alliinase activity, suggesting that this tissue expressed a distinct alliinase isozyme with very low homology to the bulb enzyme.

Lysine catabolism, an effective versatile regulator of lysine level in plants.

Lysine is a nutritionally important essential amino acid, whose synthesis in plants is strongly regulated by the rate of its synthesis. Yet, lysine level in plants is also finely controlled by a super-regulated catabolic pathway that catabolizes lysine into glutamate and acetyl Co-A. The first two enzymes of lysine catabolism are synthesized from a single LKR/SDH gene. Expression of this gene is subject to compound developmental, hormonal and stress-associated regulation. Moreover, the LKR/SDH gene of different plant species encodes up to three distinct polypeptides: (i) a bifunctional enzyme containing the linked lysine-ketoglutarate (LKR) and saccharopine dehydrogenase (SDH) whose LKR activity is regulated by its linked SDH enzyme; (ii) a monofunctional SDH encoded by an internal promoter, which is a part of the coding DNA region of the LKR/SDH gene; and (iii) a monofunctional, highly potent LKR that is formed by polyadenylation within an intron. LKR activity in the bifunctional LKR/SDH polypeptide is also post-translationally regulated by phosphorylation by casein kinase-2 (CK2), but the consequence of this regulation is still unknown. Why is lysine metabolism super-regulated by synthesis and catabolism? A hypothesis addressing this important question is presented, suggesting that lysine may serve as a regulator of plant growth and interaction with the environment.

Regulation of lysine catabolism in Arabidopsis through concertedly regulated synthesis of the two distinct gene products of the composite AtLKR/SDH locus.

Lysine catabolism in plants is initiated by a bifunctional LKR/SDH (lysine-ketoglutarate reductase/saccharopine dehydrogenase) enzyme encoded by a single LKR/SDH gene. Yet, the AtLKR/SDH gene of Arabidopsis also encodes a second gene product, namely a monofunctional SDH. To elucidate the regulation of lysine catabolism in Arabidopsis through these two gene products of the AtLKR/SDH gene, an analysis was carried out on the effects of the hormones, abscisic acid and jasmonate, as well as various metabolic and stress signals, including lysine itself, on their mRNA and protein levels. The response of the two gene products to the various treatments was only partially co-ordinated, but the levels of the monofunctional SDH mRNA and protein were always in excess over their bifunctional LKR/SDH counterparts. These results suggest that lysine catabolism is regulated primarily by the first enzyme LKR, while the excess level of SDH enables efficient flux of lysine catabolism following the LKR step. Analysis of transgenic plants expressing beta-glucoronidase fusion constructs with the AtLKR/SDH and monofunctional AtSDH promoters demonstrated that transcriptional regulation contributes to the modulation of expression of the bifunctional LKR/SDH and monofunctional SDH gene products in response to hormonal and metabolic signals. To test whether the enhanced expression of the LKR/SDH gene under various hormonal and metabolic signals is correlated with enhanced lysine catabolism, wild-type Arabidopsis and a knockout mutant lacking lysine catabolism were exposed to abscisic acid and sugar starvation. Free lysine accumulated to significantly higher levels in this knockout mutant than in the wild-type plants.

Heterologous expression of a wheat high molecular weight glutenin gene in Escherichia coli.

An engineered DNA fragment containing a DNA sequence encoding a wheat high molecular weight glutenin subunit was cloned into a bacterial expression vector that is based on bacteriophage T7 RNA polymerase. The resulting plasmid directed the synthesis of large amounts of the mature form of the wheat high molecular weight glutenin subunit in Escherichia coli. This protein comigrated in SDS/PAGE with a native high molecular weight glutenin subunit extracted from wheat endosperm and cross-reacted with antibodies raised against purified wheat high molecular weight glutenins. The wheat subunit synthesized in E. coli also exhibited pI and solubility characteristics identical to those of native wheat subunits. Moreover, the wheat glutenin subunit produced in E. coli cells self-assembled into oligomers linked by intermolecular disulfide bonds, a process that plays an important role in the assembly of native glutenins during gluten formation. The large amounts of a purified wheat subunit obtained from E. coli will enable investigators to analyze the three-dimensional structure of that protein and to identify protein sequences that affect the bread-making quality of wheat dough.

Role of conserved cysteines of a wheat gliadin in its transport and assembly into protein bodies in Xenopus oocytes.

Following sequestration into the endoplasmic reticulum, wheat gliadin storage proteins may either be retained and packaged into protein bodies inside the organelle or be transported via the Golgi apparatus to vacuoles and condense into protein bodies at a post-endoplasmic reticulum location. To unravel the mechanism of this complex process of deposition, we expressed wild-type and mutant forms of two closely related gamma and aggregated gliadins in Xenopus oocytes. Although a considerable amount of the gamma-gliadin was secreted to the medium, its closely related aggregated gliadin was entirely retained within the oocytes. This differential secretion was largely due to structural variations in the C-terminal regions of the proteins. Retention of the wild-type aggregated and gamma-gliadins within the endoplasmic reticulum could not be explained by rapid assembly into insoluble deposits inasmuch as both proteins could diffuse rather efficiently within the organelle for several hours. To address more closely the role of the C-terminal region in the transport and assembly of the gamma-gliadin within the endoplasmic reticulum, 3 cysteine codons in this region were mutated, one at a time, to serine codons. The cysteine-replacement mutants improperly aggregated within the endoplasmic reticulum forming denser deposits compared with the wild-type protein.

Concerted regulation of lysine and threonine synthesis in tobacco plants expressing bacterial feedback-insensitive aspartate kinase and dihydrodipicolinate synthase.

The essential amino acids lysine and threonine are synthesized in higher plants by two separate branches of a common pathway. This pathway is primarily regulated by three key enzymes, namely aspartate kinase (AK), dihydrodipicolinate synthase (DHPS) and homoserine dehydrogenase (HSD), but how these enzymes operate in concert is as yet unknown. Addressing this issue, we have expressed in transgenic tobacco plants high levels of bacterial AK and DHPS, which are much less sensitive to feedback inhibition by lysine and threonine than their plant counterparts. Such expression of the bacterial DHPS by itself resulted in a substantial overproduction of lysine, whereas plants expressing only the bacterial AK overproduced threonine. When both bacterial enzymes were expressed in the same plant, the level of free lysine exceeded by far the level obtained by the bacterial DHPS alone. This increase, however, was accompanied by a significant reduction in threonine accumulation compared to plants expressing the bacterial AK alone. Our results suggested that in tobacco plants the synthesis of both lysine and threonine is under a concerted regulation exerted by AK, DHPS, and possibly also by HSD. We propose that the balance between lysine and threonine synthesis is determined by competition between DHPS and HSD on limiting amounts of their common substrate 3-aspartic semialdehyde, whose level, in turn, is determined primarily by the activity of AK. The potential of this molecular approach to increase the nutritional quality of plants is discussed.

Characterization of HSP-70 cognate proteins from wheat.

Animal and plant cells contain a family of constitutively expressed HSP-70 cognate proteins that are localized in different subcellular locations and are presumed to play a role in protein folding and transport. Utilizing antibodies raised against the yeast endoplasmicreticulum-localized HSP-70 cognate termed BiP/GRP-78, as well as antibodies raised against the Escherichia coli HSP-70 protein DnaK, we have identified and characterized a large family of closely related proteins in wheat. One protein band of 78 kDa that is apparently closely related to yeast BiP was localized in the endoplasmic reticulum. This band cross-reacted with the yeast BiP but not with the DnaK-specific antibodies. The yeast BiP antibodies also recognized a cytoplasmic protein of 70 kDa that is probably related to the HSC-70 cognate proteins. These two proteins were further confirmed as HSP-70 cognates by their ability to bind to an ATP-agarose column. Probing of proteins from purified wheat mitochondrial preparations with the yeast BiP and DnaK-specific antibodies showed that this organelle contained a family of HSP-70-related proteins. The yeast BiP antibodies recognized two mitochondrial proteins of 60 and 58 kDa, but failed to detect any protein in the size rang of 70 to 80 kDa. However, the presence of immunologically distinct proteins of 90 and 78 kDa, as well as of lower molecular weight from this family in the mitochondria, was shown by probing with the DnaK-specific antibodies. A new protein of 30 kDa, cross-reacting with anti-yeast BiP antibodies, was detected only in developing seeds, close to their maturity. The evolution of HSP-70 cognate proteins in wheat as shown in this study is discussed.