Production of recombinant proteins in plant root exudates.

The large-scale production of recombinant proteins in plants is limited by relatively low yields and difficulties in extraction and purification. These problems were addressed by engineering tobacco plants to continuously secrete recombinant proteins from their roots into a simple hydroponic medium. Three heterologous proteins of diverse origins (green fluorescent protein of jellyfish, human placental alkaline phosphatase [SEAP], and bacterial xylanase) were produced using the root secretion method (rhizosecretion). Protein secretion was dependent on the presence of the endoplasmic reticulum signal peptide fused to the recombinant protein sequence. All three secreted proteins retained their biological activity and, as shown for SEAP, accumulated in much higher amounts in the medium than in the root tissue.

Tobacco ribosomal DNA spacer element stimulates amplification and expression of heterologous genes.

Here we show that the cis-acting genetic element aps (amplification-promoting sequence), isolated from the nontranscribed spacer region of tobacco ribosomal DNA (rDNA), increases the level of expression of recombinant proteins. Transgenic tobacco plants, transformed with expression cassettes containing the herbicide-resistant acetolactate synthase (hr-ALS) gene or the green fluorescent protein (GFP) gene fused to the aps sequence, had greater levels of corresponding messenger RNAs (mRNAs) and proteins compared to transformants lacking aps. Analysis of transgenic plants showed that aps increased the copy number and transcription of the adjacent heterologous genes and, in the case of hr-ALS, enhanced the herbicide resistance phenotype. Both the increased transgene copy number and enhanced expression were stably inherited. These data provide the first evidence that the aps sequence can be used for gene amplification in transgenic plants and possibly other multicellular organisms.

Seed development and differentiation: a role for metabolic regulation.

During seed growth, the filial organs, Vicia embryos and barley endosperm, differentiate into highly specialized storage tissues. Differentiation is evident on structural and morphological levels and is reflected by the spatial distribution of metabolites. In Vicia embryos, glucose is spatially correlated to mitotic activity whereas elongating and starch accumulating cells contain high levels of sucrose. Seed development is also regulated by phytohormones. In pea seeds, GA-deficiency stops seed growth before maturation. In Arabidopsis seeds, ABA regulates differentiation and inhibits cell division activity. The ABA pathway, in turn, is linked to sugar responses. In young Vicia embryos, invertases in maternal tissues control both concentration and composition of sugars. Embryonic and endospermal transfer cell formation represents an early differentiation step. Establishing an epidermis-localised sucrose uptake system renders the embryo independent from maternal control. cDNA array analysis in barley seeds revealed a massive transcriptional re-programming of gene expression during the transition stage, when gene clusters related to transport and energy metabolism are highly transcribed. Sucrose represents a signal for differentiation and up-regulates storage-associated gene expression. Sucrose signalling involves protein phosphorylation. Sucrose non-fermenting-1-related protein kinases are apparently induced in response to high cellular sucrose, and could act as mediators of sucrose-specific signals. Energy metabolism changes during seed development. In Vicia embryos metabolic responses upon hypoxia and low energy charge levels are characteristic for young undifferentiated stages when energy demand and respiration are high. During the transition stage, the embryo becomes adapted to low energy availability and metabolism becomes energetically more economic and tightly controlled. These adaptations are embedded in the embryo's differentiation program and coupled with photoheterotrophic metabolism. In Vicia cotyledons, ATP content increases in a development-dependent pattern and is associated with the greening process. The main role of seed photosynthesis is to increase internal O2 contents and to control biosynthetic fluxes by improving energy supply.

Glucan phosphorylases in Vicia faba L.: cloning, structural analysis and expression patterns of cytosolic and plastidic forms in relation to starch.

We have isolated and characterised cDNA sequences from a Vicia faba cotyledonary library encoding a plastidic isoform (VfPho1) and a cytosolic isoform (VfPho2) of an alpha-1,4-glucan phosphorylase (EC 2.4.1.1; Commission on Plant Gene Nomenclature 1994). The Pho1 isoform is characterized by the presence of a plastidial transit peptide and an 81-residue stretch of additional amino acids in the middle of the polypeptide which are not found in the Pho2 isoform. We define the position of this so-called insertion sequence differently from previous authors. The Pho1 transcripts were found predominantly in the early seed coat and in cotyledons, and accumulated until the late desiccation phase, whereas Pho2 transcripts were about equally abundant in all investigated tissues. Activity patterns of both enzymes in cotyledons roughly followed mRNA accumulation patterns, with the exception of the late desiccation phases when mRNAs were degraded but enzyme activities remained at high level, even in long-stored seeds. The distinct Pho1 and Pho2 gene expression patterns in seed coats coincided with the transient accumulation pattern of starch. Similarly, in-situ hybridisation revealed a relationship between Pho1 gene expression and starch granule formation in developing cotyledons. Expression data and enzyme activity patterns were associated with starch formation during seed development, and could simply reflect a continuous accumulation of enzyme protein, ensuring immediate participation in starch degradation during germination.

Comparison of nuclear ribosomal RNA genes among Solanum species and other Solanaceae.

The organization of the nuclear-encoded 18S, 5.8S, and 25S ribosomal RNA genes (ribosomal DNA; rDNA) of 21 New World species from different sections of the genus Solanum, of two Old World Solanum species, and of representatives of other Solanaceae (Nicotiana, Atropa, Datura, Physalis, and Capsicum) was analyzed by restriction enzyme mapping using different rDNA specific hybridization probes. All Solanum species investigated exhibited rDNA repeats between 8.7 and 9.3 kb in length; the only exception was S. neorossii with a repeat length of 10.3 kb. Sequence heterogeneity was observed mostly in the intergenic spacer (IGS) region. Restriction sites for EcoRI and DraI in the spacer sequences were found to be characteristic for the New World species of the genus Solanum and for Lycopersicon esculentum. An additional XbaI site was detected in the spacer region of two nontuber-bearing species, S. brevidens and S. etuberosum (subsection Estolonifera Hawkes; series Etuberosa), as well as in the primitive tuber-bearing species of the series Pinnatisecta and Polyadenia (subsection Potatoe G. Don), thus demonstrating that these Mexican species are separated from the other tuber-bearing species but are closely linked to the nontuber-bearing Estolonifera group. Two EcoRI sites mapped at the 3' end of the 25S rRNA coding region seem to be characteristic for members of the Solanaceae; the first EcoRI site is apparently methylated in approximately 50% of the rDNA repeats. Southern hybridization with an IGS fragment of Solanum tuberosum as hybridization probe and nucleotide sequence analysis of the phylogenetically informative 3' end of the 25S rDNA support the assumption that the New World species of the genus Solanum are closely related to Lycopersicon (tomato) in contrast with other Solanaceae investigated, Nicotiana, Atropa, Datura, Physalis, and Capsicum.(ABSTRACT TRUNCATED AT 250 WORDS)

Cell-type specific, coordinate expression of two ADP-glucose pyrophosphorylase genes in relation to starch biosynthesis during seed development of Vicia faba L.

Several cDNA clones encoding two different ADP-glucose pyrophosphorylase (AGPase, EC 2.7.7.27) polypeptides denoted VfAGPC and VfAGPP were isolated from a cotyledonary library of Vicia faba L. Both sequences are closely related to AGPase small-subunit sequences from other plants. Whereas mRNA levels of VfAGPP were equally high in developing cotyledons and leaves, the mRNA of VfAGPC was present in considerable amounts only in cotyledons. During development of cotyledons, both mRNAs accumulated until the beginning of the desiccation phase and disappeared afterwards. The increase of AGPase activity in cotyledons during the phase of storage-product synthesis was closely followed by the accumulation of starch. The AGPase activity in crude extracts of cotyledons was insensitive to 3-phosphoglycerate whereas the activity from leaves could be activated more than five-fold. Inorganic phosphate inhibited the enzyme from both tissues but was slightly more effective on the leaf enzyme. There was a correlation at the cellular level between the distribution of VfAGPP and VfAGPC mRNAs and the accumulation of starch, as studied by in-situ hybridisation and by histochemical staining in parallel tissue sections of developing seeds, respectively. During the early phase of seed development (12-15 days after fertilization) VfAGPase mRNA and accumulation of starch were detected transiently in the hypodermal, chlorenchymal and outer parenchymal cell layers of the seed coat but not in the embryo. At 25 days after fertilization both synthesis of VfAGPase mR-NA and biosynthesis of starch had started in parenchyma cells of the inner adaxial zone of the cotyledons. During later stages, the expression of VfAGPase and synthesis of starch extended over most of the cotyledons but were absent from peripheral cells of the abaxial zone, provascular and procalyptral cells.

Sucrose metabolism during cotyledon development of Vicia faba L. is controlled by the concerted action of both sucrose-phosphate synthase and sucrose synthase: expression patterns, metabolic regulation and implications for seed development.

The roles of sucrose-phosphate synthase (Sps) and sucrose synthase (Sus) in developing embryos of Vicia faba have been characterized. In the cotyledons the expression of both Sps and Sus is initiated in cells differentiating into storage tissue. This stage is characterized by a switch in the carbohydrate state from a high to a low hexoses to sucrose ratio. The carbohydrate state was found earlier to be controlled by seed coat-associated invertase. During cotyledon development the Sps-enzyme undergoes a cycle of deactivation and reactivation: the activated state is associated with the prestorage phase, desiccation and germination and the deactivated state with the storage phase. Sus activity is associated with the storage phase. Sps and Sus are differentially influenced by free sugars. Feeding hexoses to storage phase cotyledons increases levels of Sps-mRNA but not Sus-mRNA, Sps activity and Sps activation state and impairs storage functions evidenced by an increased sucrose to starch ratio and a downregulation of storage protein legumin B-mRNA. Sus enzyme activity is inhibited by free hexoses in vitro. It is proposed that the changing carbohydrate state during cotyledon development controls the ratio of Sps to Sus. Sps may have some significance for the initiation of the storage process possibly decreasing hexoses and/or increasing sucrose. The relevance of the changing carbohydrate state with respect to development and storage processes is discussed.

Molecular analysis of highly repeated genome fractions in Solanum and their use as markers for the characterization of species and cultivars.

Highly repeated DNA of potato (Solanum sp.) was characterized by cloning various major repeated elements of the nuclear genome. The percentage of the nuclear genome of the specific fractions and the restriction enzyme patterns were determined in order to show the distribution and organization of the respective repeats in the genome of Solanum tuberosum cultivars, dihaploid breeding lines and in wild species of Solanum. Several of the clones obtained were represented in a high copy number but showed no informative RFLP patterns. More information was gained from 'restriction satellite' repeats. The clone pR1T320 was found to contain satellite repeats (360 bp in length) that are proportionally present in the genome of all Solanum species at frequencies, between 0.5% and 2.6% and which are differently organized. This repeat was also found in the genera Lycopersicon, Datura and Nicotiana. With various restriction enzymes characteristic RFLP patterns were detected. A more or less genus-specific element for Solanum was the 183-bp repeat (clone pSA287; between 0.2-0.4% of the nuclear genome) that was present in the majority of the Solanum species analyzed except S. kurtzianum, S. bulbocastanum and S. pinnatisectum. In a few wild species (prominently in S. kurtzianum, S. demissum and S. acaule) a specific repeat type was detected (clone pSDT382; repeat length approximately 370 bp) that could be used to trace the wild species introduced into S. tuberosum cultivars. The repeats analyzed together with the 18S, 5.8S and 25S ribosomal DNA (1.9-5.2%, corresponding to 1800-5500 rDNA copies) comprised approximately 4-7% of the Solanum genome.

Seed coat-associated invertases of fava bean control both unloading and storage functions: cloning of cDNAs and cell type-specific expression.

We have studied the molecular physiology of photosynthate unloading and partitioning during seed development of fava bean (Vicia faba). During the prestorage phase, high levels of hexoses in the cotyledons and the apoplastic endospermal space are correlated with activity of cell wall-bound invertase in the seed coat. Three cDNAs were cloned. Sequence comparison revealed genes putatively encoding one soluble and two cell wall-bound isoforms of invertase. Expression was studied in different organs and tissues of developing seeds by RNA gel analysis, in situ hybridization, enzyme assay, and enzyme activity staining. One extracellular invertase gene is expressed during the prestorage phase in the thin-walled parenchyma of the seed coat, a region known to be the site of photoassimilate unloading. We propose a model for an invertase-mediated unloading process during early seed development and the regulation of cotyledonary sucrose metabolism. After unloading from the seed coat, sucrose is hydrolyzed by cell wall-bound invertases. Thus, invertase contributes to establish sink strength in young seeds. The resultant hexoses are loaded into the cotyledons and control carbohydrate partitioning via an influence on the sucrose synthase/sucrose-phosphate synthase pathway. The developmentally regulated degradation of the thin-walled parenchyma expressing the invertase apparently initiates the storage phase. This is characterized by a switch to a low sucrose/hexoses ratio. Feeding hexoses to storage-phase cotyledons in vitro increases the sucrose-phosphate synthase/sucrose synthase ratio and changes carbohydrate partitioning in favor of sucrose. Concomitantly, the transcript level of the major storage product legumin B is downregulated.

A role for sugar transporters during seed development: molecular characterization of a hexose and a sucrose carrier in fava bean seeds.

To analyze sugar transport processes during seed development of fava bean, we cloned cDNAs encoding one sucrose and one hexose transporter, designated VfSUT1 and VfSTP1, respectively. sugar uptake activity was confirmed after heterologous expression in yeast. Gene expression was studied in relation to seed development. Transcripts were detected in both vegetative and seed tissues. In the embryo, VfSUT1 and VfSTP1 mRNAs were detected only in epidermal cells, but in a different temporal and spatial pattern. VfSTP1 mRNA accumulates during the midcotyledon stage in epidermal cells covering the mitotically active parenchyma, whereas the VfSUT1 transcript was specific to outer epidermal cells showing transfer cell morphology and covering the storage parenchyma. Transfer cells developed at the contact area of the cotyledonary epidermis and the seed coat, starting first at the early cotyledon stage and subsequently spreading to the abaxial region at the late cotyledon stage. Feeding high concentrations of sugars suppressed both VfSUT1 expression and transfer cell differentiation in vitro, suggesting a control by carbohydrate availability.

Expression of a yeast-derived invertase in developing cotyledons of Vicia narbonensis alters the carbohydrate state and affects storage functions.

In plants the carbohydrate state provides signals to adjust metabolism to specific physiological conditions. Storage-active sink organs like seeds often contain high levels of sucrose. In order to change the sugar status during seed development a yeast-derived invertase gene was expressed in Vicia narbonensis under control of the LeguminB4 promoter. A signal sequence targeted the invertase to the apoplast in maturing embryos. In the cotyledons, sucrose was decreased whereas hexoses strongly accumulated. There was a major reduction of starch whereas proteins were less affected. Vacuoles of cotyledon cells were enlarged and dry seeds wrinkled. Transcripts and enzyme activity of sucrose synthase, the small and large subunit of ADP-glucose pyrophosphorylase as well as vicilin were downregulated. Sucrose phosphate synthase and legumin-mRNAs were not affected. Analysing single seeds with different sucrose levels revealed a positive correlation of sucrose concentration to mRNA levels of sucrose synthase and most pronounced to ADP-glucose pyrophosphorylase-mRNA levels as well as to starch content. Glucose on the other hand did not show any correlation. After feeding 14C-sucrose in vitro, the invertase-expressing cotyledons partitioned less carbon into starch compared to the wild-type. In the transgenic cotyledons, a relatively higher amount was directed into proteins compared to starch. We conclude that starch accumulation in developing cotyledons could be a function of sucrose concentration. Our results are consistent with a possible sucrose-mediated induction of storage-associated differentiation indicated by upregulation of specific genes of the starch synthesis pathway.

Calreticulin expression in plant cells: developmental regulation, tissue specificity and intracellular distribution.

The tissue-specific expression pattern and the intracellular distribution of the Ca(2+)-binding protein calreticulin at the mRNA and protein levels have been studied during somatic and zygotic embryogenesis of Nicotiana plumbaginifolia Viv. A full-length cDNA sequence encoding calreticulin was isolated from a lembda Zap cDNA library from early developmental stages of somatic embryogenesis. The deduced amino acid sequence of the calreticulin from N. plumbaginifolia shows high homology to the corresponding proteins of tobacco (98.2% identity), maize (80%) and barley (76.5%), and more than 55% homology to animal calreticulins, and the sequence motifs with established functions found in calreticulins of other species were quite conserved. Northern experiments revealed a developmental regulation of the calreticulin transcript with a maximum during the early stages of somatic embryogenesis and an auxin dependence during in-vitro cell culture. alpha-Naphthaleneacetic acid stimulated calreticulin expression whereas 2,4-dichlorophenoxyacetic acid reduced it. Immunohistological analysis of calreticulin distribution in the ovaries during zygotic embryogenesis showed that calreticulin biosynthesis started tissue specifically, with a high abundance in the endothelium of the integument in the ovules, followed by calreticulin accumulation in the embryo proper and in the associated endosperm at the late globular stage of embryogenesis. Using immunogold labeling, calreticulin was intracellularly localized with a high abundance to the Golgi compartment and to patches on the surface of dividing protoplasts. Smaller amounts were found in the endoplasmic reticulum and plasma membranes. The functional role of calreticulin in posttranslational processing and translocation processes, apart from its postulated function in cellular Ca2+ homeostasis, is discussed.

Amino acid permeases in developing seeds of Vicia faba L.: expression precedes storage protein synthesis and is regulated by amino acid supply.

Full length cDNAs encoding three amino acid permeases were isolated from seed-specific libraries of Vicia faba. The predicted proteins VfAAP1, VfAAP3 and VfAAP4 share up to 66% identity among themselves. Functional characterization of VfAAP1 and VfAAP3 in a yeast mutant showed that these permeases transport a broad range of amino acids. However, VfAAP1 had a preference for cysteine and VfAAP3 for lysine and arginine. VfAAP1 was highly expressed in cotyledons at early developmental stages and moderately in other sink tissues. Its peak of expression in cotyledons corresponded to the appearance of storage protein transcripts, suggesting that this transporter fulfills an important role in providing amino acids for storage protein biosynthesis. VfAAP3 was expressed most abundantly in maternal tissues, that is in roots, stems, gynoecia, pods and seed coats at different developmental stages. VfAAP4 transcripts could not be detected by northern hybridization. In situ hybridization showed that VfAAP1 mRNA is distributed throughout cotyledon storage parenchyma cells, but could not be detected in the abaxial epidermal cell layer. It also accumulate in the chlorenchyma and thin-walled parenchyma cells of seed coats. VfAAP1 mRNA levels were lower in cotyledons cultured in the presence of glutamine, whereas expression of a vicilin storage protein gene was up-regulated under similar conditions. Cysteine repressed the expression of the GUS reporter gene under control of the VfAAP1 promoter, suggesting that this transporter is modulated at the transcriptional level. Regulation of amino acid transport in relation to storage protein accumulation is discussed.

Production of recombinant proteins in tobacco guttation fluid.

Guttation, the loss of water and dissolved materials from uninjured plant organs, is a common phenomenon in higher plants. By using endoplasmic reticulum signal peptides fused to the recombinant protein sequences, we have generated transgenic tobacco (Nicotiana tabacum L. cv Wisconsin) plants that secrete three heterologous proteins of different genetic backgrounds (bacterial xylanase, green fluorescent protein of jellyfish [Aequorea victoria], and human placental alkaline phosphatase) through the leaf intercellular space into tobacco guttation fluid. Production rates of 1.1 microg/g of leaf dry weight per day were achieved for alkaline phosphatase with this protein comprising almost 3% of total soluble protein in the guttation fluid. Guttation fluid can be collected throughout a plant's life, thus providing a continuous and nondestructive system for recombinant protein production. Guttation fluid has the potential of increasing the efficiency of recombinant protein production technology by increasing yield, abolishing extraction, and simplifying its downstream processing.

Expression patterns and subcellular localization of a 52 kDa sucrose-binding protein homologue of Vicia faba (VfSBPL) suggest different functions during development.

A cDNA coding for a 54 kDa signal sequence containing protein has been isolated from a faba bean cotyledonary library and characterized. The deduced protein is designated Vicia faba SBP-like protein (VfSBPL) since it shares 58% homology to a 62 kDa soybean (Glycine max) protein (GmSBP) which has been described as a sucrose-binding and sucrose-transporting protein (SBP). VfSBPL as well as GmSBP are outgroup members of the large vicilin storage protein family. We were unable to measure any sucrose transport activity in mutant yeast cells expressing VfSBPL. During seed maturation in late (stage VII) cotyledons mRNA was localized by in situ hybridization in the storage parenchyma cells. At the subcellular level, immunolocalization studies proved VfSBPL accumulation in storage protein vacuoles. However, mRNA localization in stage VI cotyledons during the prestorage/storage transition phase was untypical for a storage protein in that, in addition to storage parenchyma cell labelling, strong labelling was found over seed coat vascular strands and the embryo epidermal transfer cell layer reminiscent of sucrose transporter localization. The VfSBPL gene is composed of 6 exons and 5 introns with introns located at the same sites as in a Vicia faba 50 kDa vicilin storage protein gene. The time pattern of expression as revealed by northern blotting and the GUS accumulation pattern caused by a VfSBPL-promoter/GUS construct in transgenic tobacco seeds was similar to a seed protein gene with increasing expression during seed maturation. Our data suggest different functions of VfSBPL during seed development.

Use of plant roots for phytoremediation and molecular farming.

Alternative agriculture, which expands the uses of plants well beyond food and fiber, is beginning to change plant biology. Two plant-based biotechnologies were recently developed that take advantage of the ability of plant roots to absorb or secrete various substances. They are (i) phytoextraction, the use of plants to remove pollutants from the environment and (ii) rhizosecretion, a subset of molecular farming, designed to produce and secrete valuable natural products and recombinant proteins from roots. Here we discuss recent advances in these technologies and assess their potential in soil remediation, drug discovery, and molecular farming.