Transgenic pea seeds as bioreactors for the production of a single-chain Fv fragment (scFV) antibody used in cancer diagnosis and therapy

Field pea (Pisum sativum L.) appears well suited for the production of high-value molecules such as recombinant antibodies, with well-established agricultural practices world-wide and seeds that are easily stored and distributed. In order to evaluate the suitability of this grain legume for the production of biologically active antibodies, we transformed peas with a cDNA encoding the single-chain Fv fragment scFvT84.66. This scFv is derived from the monoclonal antibody T84.66, which recognises the well-characterised tumour-associated carcinoembryonic antigen. The antibody is useful for in vitro immunodiagnosis and in vivo imaging of human cancers. We expressed scFvT84.66 cDNA under the control of the seed-specific legumin A promoter. We targeted the antibody to the endoplasmic reticulum for better stability and high accumulation. Transgenic plants produced up to 9 g per gram fresh weight of functional scFvT84.66 in their seeds. The transgene was stably inherited and expressed in the progeny, and the antibody remained active after storage in dried transgenic seeds for two months at room temperature. Our results demonstrate the suitability of grain legume seeds to produce biologically active recombinant antibodies, and the utility of field pea seeds as production vehicles for recombinant pharmaceutical macromolecules.     

Rice cell culture as an alternative production system for functional diagnostic and therapeutic antibodies

We investigated the suitability of transformed rice cell lines as a system for the production of therapeutic recombinant antibodies. Expression constructs encoding a single-chain Fv fragment (scFvT84.66, specific for CEA, the carcinoembryonic antigen present on many human tumours) were introduced into rice tissue by particle bombardment. We compared antibody production levels when antibodies were either secreted to the apoplast or retained in the endoplasmic reticulum (ER) using a KDEL retention signal. Production levels were up to 14 times higher when antibodies were retained in the ER. Additionally, we compared constructs encoding different leader peptides (plant codon optimised murine immunoglobulin heavy and light chain leader peptides) and carrying alternative 5 untranslated regions (the petunia chalcone synthase gene 5 UTR and the tobacco mosaic virus omega sequence). We observed no significant differences in antibody production levels among cell lines transformed with these constructs. The highest level of antibody production we measured was 3.8gg^–1 callus (fresh weight). Immunological analysis of transgenic rice callus confirmed the presence of functional scFvT84.66. We discuss the potential merits of cell culture for the production of recombinant antibodies and other valuable macromolecules.     

Expression of wheat puroindoline genes in transgenic rice enhances grain softness

The puroindoline genes (pinA and pinB) are believed to play critical roles in wheat (Triticum aestivum L.) grain texture. Mutations in either gene are associated with hard wheat. No direct evidence exists for the ability of puroindolines to modify cereal grain texture. Interestingly, puroindolines appear to be absent in cereal species outside of the tribe Triticeae, in which the dominant form of grain texture is hard. To assess the ability of the puroindolines to modify cereal grain texture, the puroindolines were introduced into rice (Oryzae sativa L.) under the control of the maize ubiquitin promoter. Textural analysis of transgenic rice seeds indicated that expression of PINA and/or PINB reduced rice grain hardness. After milling, flour prepared from these softer seeds had reduced starch damage and an increased percentage of fine flour particles. Our data support the hypothesis that puroindolines play important roles in controlling wheat grain texture and may be useful in modifying grain texture of other cereals.     

Metabolic redesign of vitamin E biosynthesis in plants for tocotrienol production and increased antioxidant content

Tocotrienols are the primary form of vitamin E in seeds of most monocot plants, including cereals such as rice and wheat. As potent antioxidants, tocotrienols contribute to the nutritive value of cereal grains in human and livestock diets. cDNAs encoding homogentisic acid geranylgeranyl transferase (HGGT), which catalyzes the committed step of tocotrienol biosynthesis, were isolated from barley, wheat and rice seeds. Transgenic expression of the barley HGGT in Arabidopsis thaliana leaves resulted in accumulation of tocotrienols, which were absent from leaves of nontransformed plants, and a 10- to 15-fold increase in total vitamin E antioxidants (tocotrienols plus tocopherols). Overexpression of the barley HGGT in corn seeds resulted in an increase in tocotrienol and tocopherol content of as much as six-fold. These results provide insight into the genetic basis for tocotrienol biosynthesis in plants and demonstrate the ability to enhance the antioxidant content of crops by introduction of an enzyme that redirects metabolic flux.     

Construction and analysis of a BAC library in the grass<Emphasis Type="Italic"> Brachypodium sylvaticum</Emphasis>: its use as a tool to bridge the gap between rice and wheat in elucidating gene content

A BAC library of 30,228 clones with an average insert size of 102 kb was constructed in the grass Brachypodium sylvaticum. Brachypodium has a simple genome, similar in size and repetitive DNA content to that of rice, and is more closely related than rice both to the major temperate cereals wheat and barley, and to the forage grasses. The library represents 6.6 genome equivalents, implying a 99.9% probability of recovering any specific sequence. The library was arrayed onto two high-density colony filters, which were screened with heterologous DNA probes from rice chromosome nine and from syntenous regions of wheat, barley, maize and oat. The construction of Brachypodium BAC contigs revealed that synteny between rice, wheat and Brachypodium was largely maintained over several regions of rice chromosome nine. This suggests that Brachypodium will be a useful tool in the elucidation of gene content in agronomically important cereal crops, complementing rice as a grass genome model.     

Cloning and characterization of microRNAs from wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

Background  

MicroRNAs (miRNAs) are a class of small, non-coding regulatory RNAs that regulate gene expression by guiding target mRNA cleavage or translational inhibition. So far, identification of miRNAs has been limited to a few model plant species, such as Arabidopsis, rice and Populus, whose genomes have been sequenced. Wheat is one of the most important cereal crops worldwide. To date, only a few conserved miRNAs have been predicted in wheat and the computational identification of wheat miRNAs requires the genome sequence, which is unknown.     

Oral immunogenicity and protective efficacy in mice of transgenic rice plants producing a vaccine candidate antigen (As16) of Ascaris suum fused with cholera toxin B subunit

Cereal crops such as maize and rice are considered attractive for vaccine production and oral delivery. Here, we evaluated the rice Oryza sativa for production of As16—an antigen protective against the roundworm Ascaris suum. The antigen was produced as a chimeric protein fused with cholera toxin B subunit (CTB), and its expression level in the endosperm reached 50 μg/g seed. Feeding the transgenic (Tg) rice seeds to mice elicited an As16-specific serum antibody response when administered in combination with cholera toxin (CT) as the mucosal adjuvant. Although omitting the adjuvant from the vaccine formulation resulted in failure to develop the specific immune response, subcutaneous booster immunization with bacterially expressed As16 induced the antibody response, indicating priming capability of the Tg rice. Tg rice/CT-fed mice orally administered A. suum eggs had a lower lung worm burden than control mice. This suggests that the rice-delivered antigen functions as a prophylactic edible vaccine for controlling parasitic infection in animals.     

Responses to Light Intensity in a Genome-Scale Model of Rice Metabolism

We describe the construction and analysis of a genome-scale metabolic model representing a developing leaf cell of rice (Oryza sativa) primarily derived from the annotations in the RiceCyc database. We used flux balance analysis to determine that the model represents a network capable of producing biomass precursors (amino acids, nucleotides, lipid, starch, cellulose, and lignin) in experimentally reported proportions, using carbon dioxide as the sole carbon source. We then repeated the analysis over a range of photon flux values to examine responses in the solutions. The resulting flux distributions show that (1) redox shuttles between the chloroplast, cytosol, and mitochondrion may play a significant role at low light levels, (2) photorespiration can act to dissipate excess energy at high light levels, and (3) the role of mitochondrial metabolism is likely to vary considerably according to the balance between energy demand and availability. It is notable that these organelle interactions, consistent with many experimental observations, arise solely as a result of the need for mass and energy balancing without any explicit assumptions concerning kinetic or other regulatory mechanisms.Rice (Oryza sativa) makes up nearly 20% of the total caloric intake for the human population as a whole; the income of more than 100 million households in developing countries depends on rice cultivation. Although rice yield has increased, though gradually more slowly, during the last four decades, the world population continues to grow, while the land and water resources for cultivation are declining, leading to a need for high-yielding, stress-tolerant, nutrient-rich rice cultivars (Nguyen and Ferrero, 2006).Researchers are trying to meet the challenges of improving production in different ways. Some of the efforts include (1) identifying the stress-tolerant rice varieties and stress-responsive genes (Xiang et al., 2007), (2) producing a “Green Super Rice” combining, in a single plant, many different favorable characteristics from the large number of available strains and cultivars, guided by molecular marker-based selection (Zhang, 2007), (3) introducing the genes of C₄ plant to change the leaf anatomy of rice and hence improving the photosynthesis (Kajala et al., 2011), and (4) producing vitamin A-enriched golden rice (Al-Babili and Beyer, 2005). In addition, current research on the genetic basis of signaling between nitrogen-fixing soil bacteria and legumes (Xie et al., 2012) has the potential to allow the engineering of nodule formation in cereal crops such as rice and wheat (Triticum aestivum).Here, we present a genome-scale model of rice metabolism and examine its responses to changing light availability. Because rice is also a model organism for other cereal crops, such as wheat, this effort should help researchers to understand the biochemistry of a photosynthetic crop plant as well as to compare it with other plants. In addition, the metabolic model of rice, which is the second metabolic model of a crop plant, can be used as a template for comparing the metabolism of different varieties of rice that are pathogen tolerant, drought tolerant, lower or higher yield, etc., and thus, it may also help in identifying characteristics of individual varieties that may assist rice biotechnologists to breed the desired rice crop.     

The importance of initial seed size in wheat plant response to salinity

Large initial seed size frequently confers distinct advantages on cereal crops in terms of seedling vigor, hardiness, improved stand establishment, and higher productivity. This study was conducted to determine if these advantages inherent in the plants grown from large seeds persist when the crop is subjected to salinity stress. Two hard red spring wheat cultivars, Yecora Rojo and Anza were grown in greenhouse sand cultures from seed of two size classes that differed in weight by a factor of 2. The cultures were irrigated four times daily with complete nutrient solutions to which NaCl and CaCl₂ (2:1 molar ratio) were added to achieve osmotic potentials of –0.05. –0.55, and –0.70 MPa with electrical conductivities of 1.8, 12.8, and 15.8 dS m^-1, respectively. In response to both salinity and small initial seed size, the following plant characteristics decreased: leaf appearance rate, blade area, tillers per plant, spikelets per spike and seeds per spike. Plants grown from large seeds out-yielded those from small seeds by 8, 37, and 27% for Yecora Rojo and by 15, 30, and 23% for Anza at osmotic potentials of –0.05, –0.55 and –0.70 MPa, respectively. Compared to the corresponding nonsaline controls, the yield of Yecora Rojo grown at –0.55 MPa was 51% for the plants from large seed and 35% from the small seeds. For Anza salinized at –0.55 MPa, these values were 49 and 40%, respectively. Exploitation of the benefits derived from large initial seed size may be a cost-effective management strategy for improving wheat productivity in salt-affected areas.     

Symbiosome-like intracellular colonization of cereals and other crop plants by nitrogen-fixing bacteria for reduced inputs of synthetic nitrogen fertilizers

It has been forecast that the challenge of meeting increased food demand and protecting environmental quality will be won or lost in maize, rice and wheat cropping systems, and that the problem of environmental nitrogen enrichment is most likely to be solved by substituting synthetic nitrogen fertilizers by the creation of cereal crops that are able to fix nitrogen symbiotically as legumes do. In legumes, rhizobia present intracellularly in membrane-bound vesicular compartments in the cytoplasm of nodule cells fix nitrogen endosymbiotically. Within these symbiosomes, membrane-bound vesicular compartments, rhizobia are supplied with energy derived from plant photosynthates and in return supply the plant with biologically fixed nitrogen, usually as ammonia. This minimizes or eliminates the need for inputs of synthetic nitrogen fertilizers. Recently we have demonstrated, using novel inoculation conditions with very low numbers of bacteria, that cells of root meristems of maize, rice, wheat and other major non-legume crops, such as oilseed rape and tomato, can be intracellularly colonized by the non-rhizobial, non-nodulating, nitrogen fixing bacterium,Gluconacetobacter diazotrophicus that naturally occurs in sugarcane.G. diazotrophicus expressing nitrogen fixing (nifH) genes is present in symbiosome-like compartments in the cytoplasm of cells of the root meristems of the target cereals and non-legume crop species, somewhat similar to the intracellular symbiosome colonization of legume nodule cells by rhizobia. To obtain an indication of the likelihood of adequate growth and yield, of maize for example, with reduced inputs of synthetic nitrogen fertilizers, we are currently determining the extent to which nitrogen fixation, as assessed using various methods, is correlated with the extent of systemic intracellular colonization byG. diazotrophicus, with minimal or zero inputs.     

绿色荧光蛋白基因作为报告基因在水稻基因转化中的应用研究

本研究中 ,构建了含有编码绿色荧光蛋白的改进型基因质粒pJPM5。用基因枪法分别把pJPM5和另一带有绿色荧光蛋白基因的质粒pSBG70 0转入水稻TNG6 7愈伤组织。用South ern杂交法证实了转基因的存在 ,而且表明多数转基因植株含有 1到 8个拷贝的转基因。取 2个月的转基因植株上的叶片用于分析绿色荧光蛋白基因表达。用SLM - 80 0 0荧光分析仪定量测定绿色荧光蛋白。多数转基因植株具有很高的绿色荧光蛋白信号。虽然水稻植株有少量自发荧光 ,但是绿色荧光蛋白基因表达出的绿色荧光蛋白信号比植株的自发荧光强得多 ,其测定不会受自发荧光的太大影响。在荧光显微镜下观察到了绿色荧光蛋白基因的表达。借助观察分析绿色荧光蛋白基因的瞬时表达 ,本研究还发现基因枪法转化中 ,如果两枪的气压为90 0psi& 135 0psi,比两枪的气压都为 90 0psi或者 135 0psi更好 ,因其能使质粒进入更多的细胞。研究结果表明 ,绿色荧光蛋白基因可以作为水稻 (甚至小麦、玉米 )转基因研究中的报告基因。研究还显示 ,MAR序列能明显增强绿色荧光蛋白基因的表达能力 (这一结果在另文讨论 ) .     

N-glycosylation potential of maize: the human lactoferrin used as a model

In order to determine the N-glycosylation potential of maize, a monocotyledon expression system for the production of recombinant glycoproteins, human lactoferrin was used as a model. The human lactoferrin coding sequence was inserted into the pUC18 plasmid under control of the wheat glutenin promoter. Maize was stably transformed and recombinant lactoferrin was purified from the fourth generation seeds. Glycosylation was analysed by gas chromatography, lectin detection, glycosidase digestions and mass spectrometry. The results indicated that both N-glycosylation sites of recombinant lactoferrin are mainly substituted by typical plant paucimannose-type glycans, with 1,2-xylose and 1,3-linked fucose at the proximal N-acetylglucosamine, and that complex-type glycans with Lewis^a determinants are not present in maize recombinant lactoferrin.     

Biological nitrogen fixation in non-leguminous field crops: Facilitating the evolution of an effective association between Azospirillum and wheat

Recent advances towards achieving significant nitrogen fixation by diazotrophs in symbioses with cereals are reviewed, referring to the literature on the evolution of effective symbioses involving rhizobia and Frankia as microsymbionts. Data indicating that strains of Acetobacter and Herbaspirillum colonizing specific cultivars of sugarcane as endophytes make a significant contribution to the nitrogen economy of this crop improves the prospects that similar associative systems may be developed for other gramineous species such as rice and wheat. By contrast, the transfer of nodulation genes similar to those in legumes or Parasponia to achieve nodulation in crops like rice and wheat is considered to be a more ambitious and distant goal. Progress in developing an effective associative system for cereals has been materially assisted by the development of genetic tools based on the application of lacZ and gusA fusions with the promoters of genes associated with nitrogen fixation. These reporter genes have provided clear evidence that crack-entry at the points of emergence of lateral roots or of 2,4-D induced para-nodules is the most significant route of endophytic colonization. Furthermore, using the laboratory model of para-nodulated wheat, there is now evidence that the ability of azospirilla and other nitrogen fixing bacteria to colonize extensively as endophytes can be genetically controlled. The most successful strain of Azospirillum brasilense (Sp7-S) for endophytic colonization and nitrogen fixation in wheat seedlings is a mutant with reduced exopolysaccharide production. Most other strains of azospirilla do not colonize as endophytes and it is concluded that though these are poorly adapted to providing nitrogen for the host plant, they are well adapted for survival and persistence in soil. A research program combining the study of endophytic colonization by azospirilla with an examination of the factors controlling the effectiveness of association (oxygen tolerance and nitrogen transfer) is now being pursued. It is proposed that a process of facilitated evolution of para-nodulated wheat involving the stepwise genetic improvement of both the prospective microsymbionts and the cereal host will eventually lead to effective nitrogen-fixing associations. In the attempt to achieve this goal, continued study of the endophytes occurring naturally in sugar cane and other grasses (e.g. Azoarcus sp.) should be of assistance.     

Physiological and genetic characterization of rice nitrogen fixer PGPR isolated from rhizosphere soils of different crops

Aims

We aimed to identify plant growth-promoting rhizobacteria that could be used to develop a biofertilizer for rice.

Methods

To obtain plant growth-promoting rhizobacteria, rhizosphere soils from different crops (rice, wheat, oats, crabgrass, maize, ryegrass, and sweet potato) were inoculated to rice plants. In total, 166 different bacteria were isolated and their plant growth-promoting traits were evaluated in terms of colony morphology, indole-3-acetic acid production, acetylene reduction activity, and phosphate solubilization activity. Moreover, genetic analysis was carried out to evaluate their phylogenetic relationships based on 16S rRNA sequence data.

Results

Strains of Bacillus altitudinis, Pseudomonas monteilii, and Pseudomonas mandelii formed associations with rice plants and fixed nitrogen. A strain of Rhizobium daejeonense showed nitrogen fixation activity in an in vitro assay and in vivo. Strains of B. altitudinis and R. daejeonense derived from rice rhizosphere soil, strains of P. monteilii and Enterobacter cloacae derived from wheat rhizosphere soil, and a strain of Bacillus pumilus derived from maize rhizosphere soil significantly promoted rice plant growth.

Conclusions

These methods are effective to identify candidate species that could be developed as biofertilizers for target crops.     

Accumulation of Japanese cedar pollen allergen,Cry j 1, in the protein body I of transgenic rice seeds using the promoter and signal sequence of glutelin GluB-1 gene

Recombinant Cry j 1, a Japanese cedar pollen allergen, was produced in rice seeds for potential use for oral immunotherapy. Cry j 1 cDNA was divided into two parts, an N-terminal half and a C-terminal half, and each was fused downstream to glutelin GluB-1 gene containing sequences of the promoter, 5 untranslated region and signal peptide. A gene for green fluorescent protein was also fused to the 3 end of the Cry j 1 fragment. Recombinant Cry j 1 of up to 16.6 g per mg total protein of the seeds was expressed in transgenic rice seeds. Although the recombinant Cry j 1 was expected to be accumulated in protein body II because of the employment of glutelin signal peptide, it was demonstrated to be accumulated exclusively in protein body I. The recombinant Cry j 1 was not shown to react with IgE of allergic patients, indicating the reduction of the risk of anaphylactic reaction. These results demonstrate that the transgenic rice seeds with the recombinant Cry j 1 would be useful for the study of oral immunotherapy.