Soybean seed protein storage vacuoles for expression of recombinant molecules.

Soybean is one of the most important protein sources for human consumption and livestock feed. Soy production also allows the biosynthesis of edible oils, biodiesel, and biofertilizers. With the advent of modern agricultural biotechnology, soybean plants have also converted into bioreactors of therapeutic proteins and industrial enzymes. Soybean's characteristics, such as protein storage vacuoles (PSVs) and other unique organelles, allow the plant to be exploited as an accumulator of heterologous proteins under high stability and scalability conditions, and that maintains its basic functions. This review reports the main aspects of heterologous protein accumulation in soybean PSVs.

Protein families, natural history and biotechnological aspects of spider silk.

Spiders are exceptionally diverse and abundant organisms in terrestrial ecosystems and their evolutionary success is certainly related to their capacity to produce different types of silks during their life cycle, making a specialized use on each of them. Presenting particularly tandemly arranged amino acid repeats, silk proteins (spidroins) have mechanical properties superior to most synthetic or natural high-performance fibers, which makes them very promising for biotechnology industry, with putative applications in the production of new biomaterials. During the evolution of spider species, complex behaviors of web production and usage have been coupled with anatomical specialization of spinning glands. Spiders retaining ancestral characters, such as the ones belonging to the Mygalomorph group, present simpler sorts of webs used mainly to build burrows and egg sacs, and their silks are produced by globular undifferentiated spinning glands. In contrast, Araneomorphae spiders have a complex spinning apparatus, presenting up to seven morphologically distinct glands, capable to produce a more complex set of silk polymers with different degrees of rigidness and elasticity associated with distinct behaviors. Aiming to provide a discussion involving a number of spider silks' biological aspects, in this review we present descriptions of members from each family of spidroin identified from five spider species of the Brazilian biodiversity, and an evolutionary study of them in correlation with the anatomical specialization of glands and spider's spinning behaviors. Due to the biotechnological importance of spider silks for the production of new biomaterials, we also discuss about the new possible technical and biomedical applications of spider silks and the current status of it.

A minimal DNA cassette as a vector for genetic transformation of soybean (Glycine max).

Currently, the market demands products committed to protecting human health and the environment, known as clean products. We developed a protocol using DNA fragments containing only the gene sequence of interest, to replace the circular vectors containing genes for antibiotic resistance and other undesirable sequences, for obtaining transgenic soybeans for microparticle bombardment. Vector pAC321 was digested with the restriction enzyme PvuII to produce the 6159 bp ahas fragment, which contains the mutated ahas gene from Arabidopsis thaliana (Brassicaceae), under the control of its own promoter and terminator. This gene confers resistance against imazapyr, a herbicidal molecule of the imidazolinone class, capable of systemically translocating and concentrating in the apical meristematic region of the plant, the same region used for the introduction of the transgenes. This fragment was used to generate 10 putative transgenic soybean lines.

Soybeans as bioreactors for biopharmaceuticals and industrial proteins.

Plants present various advantages for the production of biomolecules, including low risk of contamination with prions, viruses and other pathogens, scalability, low production costs, and available agronomical systems. Plants are also versatile vehicles for the production of recombinant molecules because they allow protein expression in various organs, such as tubers and seeds, which naturally accumulate large amounts of protein. Among crop plants, soybean is an excellent protein producer. Soybean plants are also a good source of abundant and cheap biomass and can be cultivated under controlled greenhouse conditions. Under containment, the plant cycle can be manipulated and the final seed yield can be maximized for large-scale protein production within a small and controlled area. Exploitation of specific regulatory sequences capable of directing and accumulating recombinant proteins in protein storage vacuoles in soybean seeds, associated with recently developed biological research tools and purification systems, has great potential to accelerate preliminary characterization of plant-derived biopharmaceuticals and industrial macromolecules. This is an important step in the development of genetically engineered products that are inexpensive and safe for medicinal, food and other uses.

Correct targeting of proinsulin in protein storage vacuoles of transgenic soybean seeds.

Soybean plants are promising bioreactors for the expression of biochemically complex proteins that cannot be produced in a safe and/or economically viable way in microorganisms, eukaryotic culture cells or secreted by transgenic animal glands. Soybeans present many desirable agronomic characteristics for high scale protein production, such as high productivity, short reproductive cycle, photoperiod sensitivity, and natural organs destined for protein accumulation in the seeds. The significant similarities between plant and human cells in terms of protein synthesis processes, folding, assembly, and post-translational processing are important for efficient accumulation of recombinant proteins. We obtained two transgenic lines using biolystics, incorporating the human proinsulin gene under control of the monocot tissue-specific promoter from sorghum gamma-kafirin seed storage protein gene and the alpha-coixin cotyledonary vacuolar signal peptide from Coix lacryma-jobi (Poaceae). Transgenic plants expressed the proinsulin gene and accumulated the polypeptide in mature seeds. Protein targeting to cotyledonary protein storage vacuoles was successfully achieved and confirmed with immunocytochemistry assays. The combination of different regulatory sequences was apparently responsible for high stability in protein accumulation, since human proinsulin was detected after seven years under room temperature storage conditions.

Spidroins from the Brazilian spider Nephilengys cruentata (Araneae: Nephilidae).

Spiders produce up to six different kinds of silk, each one for a specific biological function. Spider silks are also known for their unique mechanical properties. The possibility of producing new materials with similar properties motivated research on these silk proteins (spidroins). Using expression sequence tags, we identified four spidroins produced by major ampullate, minor ampullate, flagelliform and tubuliform silk glands from the Brazilian spider Nephilengys cruentata (Araneae: Nephilidae). The new protein sequences showed substantial similarity to other spidroins previously described, with high content of alanine and glycine due to the presence of the highly repetitive motifs (polyAla, (GA)n, (GGX)n, (GPGGX)n). Similarities among sequences were also observed between the different spidroins with the exception of tubuliform spidroin, which presents a unique complex amino acid sequence with high amounts of serine and low amounts of glycine.

Gene flow from transgenic to nontransgenic soybean plants in the Cerrado region of Brazil.

Evaluation of transgenic crops under field conditions is a fundamental step for the production of genetically engineered varieties. In order to determine if there is pollen dispersal from transgenic to nontransgenic soybean plants, a field release experiment was conducted in the Cerrado region of Brazil. Nontransgenic plants were cultivated in plots surrounding Roundup Ready transgenic plants carrying the cp4 epsps gene, which confers herbicide tolerance against glyphosate herbicide, and pollen dispersal was evaluated by checking for the dominant gene. The percentage of cross-pollination was calculated as a fraction of herbicide-tolerant and -nontolerant plants. The greatest amount of transgenic pollen dispersion was observed in the first row, located at one meter from the central (transgenic) plot, with a 0.52% average frequency. The frequency of pollen dispersion decreased to 0.12% in row 2, reaching 0% when the plants were up to 10 m distance from the central plot. Under these conditions pollen flow was higher for a short distance. This fact suggests that the management necessary to avoid cross-pollination from transgenic to nontransgenic plants in the seed production fields should be similar to the procedures currently utilized to produce commercial seeds.

Inheritance of a recessive transgene-associated character controlling albinism in transgenic bean (Phaseolus vulgaris L.).

We identified a transgenic line exhibiting albinism during our work to introduce genes through genetic engineering in dry bean (Phaseolus vulgaris). The transgenic mother plant (R0) presented a normal phenotype and generated albino and normal green plants in the first generation (R1). The segregation ratio of the albino character in the R1 and R2 generations fitted the expected ratio for a character controlled by a single recessive gene linked to a foreign gus gene, suggesting that albinism could be a consequence of insertional mutation caused by introduction of the exogenous gene. Analysis by electron microscope revealed that the albino cells possessed no chloroplasts and a greater number of mitochondria when compared to normal green plants. This transgenic bean line may be used in understanding the genetic control of chloroplast genesis, for acquiring additional knowledge of genomic structure or in physiological studies. This is the first described transgene-associated mutant bean plant.

Biolistic-mediated gene transfer using the bovine herpesvirus-1 glycoprotein D is an effective delivery system to induce neutralizing antibodies in its natural host.

A genetic vaccine consisting of the bovine herpesvirus-1 (BHV-1) glycoprotein D (gD) gene was constructed and administered to cattle using the biolistic (gene-gun) process. Results were compared to standard intramuscular injection of an inactivated whole BHV-1 commercial vaccine. Cattle genetically immunized by the gene-gun-delivered gD subunit vaccine developed high titers of IgG antibodies specific to gD demonstrating that this immunization method is a potent humoral response inducer. Further, gene-gun vaccinated cattle produced high neutralizing antibody titers to BHV-1 similar to levels induced in the commercial vaccine immunized animals. Additionally, cellular immunity was measured by an increased level of IFN-gamma mRNA detected in PBMC of cattle immunized with the gD gene or with the commercial vaccine, whereas augmented levels of IL-4 were not detected following vaccination. Because of its simplicity and effectiveness in inducing an immune response in cattle similar to a commercial vaccine, gene-gun delivery of a subunit BHV-1 gD vaccine would be a viable alternative to current immunization protocols.

Methods of gene transfer and analysis in higher plants.

The rapid development of tissue culture and recombinant-DNA technology in recent years has enabled plants of many species to be regenerated from cultured cells and their genetic information to be manipulated in various ways. Gene transfer has already resulted in the production of a wide range of transgenic dicotyledons, particularly in the Solanaceue. Although success with monocotyledons is more limited, transgenic rye (1), maize (2), and rice (3) plants have been reported.

Transient expression of GUS and the 2S albumin gene from Brazil nut in peanut (Arachis hypogaea L.) seed explants using particle bombardment.

The effect of parameters involved in the transformation efficiency of peanut (Arachis hypogaea L.) seed tissues by direct gene transfer using a helium inflow particle bombardment device was evaluated. Transient gene expression was affected by both particle and DNA amounts, and was positively correlated with gene copy number, as determined byß-glucuronidase (GUS) activity assays. No influence of plasmid size on GUS gene expression was observed. Transcriptional control of GUS by either the CaMV 35S or the 2S promoter from Brazil nut 2S albumin gene varied with the developmental stage of the seed and was approximately tenfold greater under the influence of the 35S promoter than under the 2S promoter. The gene products of both the Brazil nut methionine-rich 2S albumin and GUS genes under the transcriptional control of the 35S promoter were detected by ELISA assays.

Biolistic-mediated gene expression in guinea pigs and cattle tissue in vivo.

Foreign genes were introduced and expressed in vivo in guinea pigs and cattle utilizing a new hand-held device based on high-pressure helium gas to accelerate DNA-coated microparticles. Guinea pigs were used to evaluate the physical parameters to introduce and express the exogenous DNA. The best conditions were applied to conduct bombardments in cattle. The results showed a high frequency of gene expression in all the bombarded cattle. This procedure could be used to study the immune responses in cattle and in a wide variety of animals through genetic immunization.

The role of T cell subsets and cytokines in the regulation of intracellular bacterial infection.

Cellular immune responses are a critical part of the host's defense against intracellular bacterial infections. Immunity to Brucella abortus crucially depends on antigen-specific T cell-mediated activation of macrophages, which are the major effectors of cell-mediated killing of this organism. T lymphocytes that proliferate in response to B. abortus were characterized for phenotype and cytokine activity. Human, murine, and bovine T lymphocytes exhibited a type 1 cytokine profile, suggesting an analogous immune response in these different hosts. In vivo protection afforded by a particular cell type is dependent on the antigen presented and the mechanism of antigen presentation. Studies using MHC class I and class II knockout mice infected with B. abortus have demonstrated that protective immunity to brucellosis is especially dependent on CD8+ T cells. To target MHC class I presentation we transfected ex vivo a murine macrophage cell line with B. abortus genes and adoptively transferred them to BALB/c mice. These transgenic macrophage clones induced partial protection in mice against experimental brucellosis. Knowing the cells required for protection, vaccines can be designed to activate the protective T cell subset. Lastly, as a new strategy for priming a specific class I-restricted T cell response in vivo, we used genetic immunization by particle bombardment-mediated gene transfer.

A biolistic process for in vitro gene transfer into chicken embryos.

Chicken embryos kept in culture medium were bombarded using a high helium gas pressure biolistic device. To optimize the factors that affect transformation efficiency, the lacZ gene under control of the human cytomegalovirus immediate early enhancer/promoter was used as a reporter gene. There was an inverse relationship between survival rate and transformation efficiency. The best conditions obtained for high embryo survival and high transformation efficiency were achieved with 800 psi helium gas pressure, 500 mmHg vacuum, gold particles, an 8 cm DNA-coated microparticle flying distance to the embryo and embryo placement 0.5 cm from the center of the particle dispersion cone. Under these conditions, transformation efficiency was 100%, survival rate 25% and the number of expression units in the embryo body cells ranged from 100 to 1,000. Expression of green fluorescent protein was also detected in embryos bombarded under optimal conditions. Based on the results obtained, the biolistic process can be considered an efficient method for the transformation of chicken embryos and therefore can be used as a model system to study transient gene expression and tissue-specific promoters.

Immunological properties of gene vaccines delivered by different routes.

Gene vaccines represent a new and promising approach to control infectious diseases, inducing a protective immune response in the appropriate host. Several routes and methods of genetic immunization have been shown to induce antibody production as well as T helper (Th) cell and cytotoxic T lymphocyte activation. However, few studies have compared the nature of the immune responses generated by different gene vaccination delivery systems. In the present study we reviewed some aspects of immunity induced by gene immunization and compared the immune responses produced by intramuscular (i.m.) DNA injection to gene gun-mediated DNA transfer into the skin of BALB/c mice. Using a reporter gene coding for beta-galactosidase, we have demonstrated that i.m. injection raised a predominantly Th1 response with mostly IgG2a anti-beta gal produced, while gene gun immunization induced a mixed Th1/Th2 profile with a balanced production of IgG2a and IgG1 subclasses. Distinct types of immune responses were generated by different methods of gene delivery. These findings have important implications for genetic vaccine design. Firstly, a combination between these two systems may create optimal conditions for the induction of a broad-based immune response. Alternatively, a particular gene vaccine delivery method might be used according to the immune response required for host protection. Here, we describe the characteristics of the immune response induced by gene vaccination and the properties of DNA involved in this process.

Tissue culture propagation of Mentha spp. by the use of axillary buds.

A method is described for rapid multiplication from axillary buds of six Mentha species. Nodal segments from one-year old plants were grown on Murashige and Skoog medium (BMS), supplemented with BAP (1.0; 2.0 mg/l) and KIN (1.0 mg/l) and kept at 28 ± 1°C under fluorescent light for 30 days. After this period, several shoots (15-20 shoots per explant) with roots were produced which were placed in soil for further growth.

Direct DNA transfer to plant cells.

A range of somatic cell and molecular techniques are now available to supplement conventional plant breeding. The introduction and expression of foreign DNA has been used to modify basic aspects of physiology and development, to introduce commercially important characteristics such as herbicide and insect resistance into plants and to insert genes suitable as dominant selectable markers for somatic hybridisation. Several techniques for direct DNA delivery are available, ranging from uptake of DNA into isolated protoplasts mediated by chemical procedures or electroporation, to injection and the use of high-velocity particles to introduce DNA into intact tissues. Direct DNA uptake is applicable to both stable and transient gene expression studies and utilises a range of vectors, including those employed for gene cloning. Although the frequency of stable transformation is low, direct DNA uptake is applicable to those plants not amenable to Agrobacterium transformation, particularly monocotyledons.

Long-term effect of electroporation on enhancement of growth and plant regeneration of colt cherry (Prunus avium × pseudocerasus) protoplasts.

Electric pulses applied to Colt cherry protoplasts enhanced the long-term growth and plant regeneration of protoplast-derived tissues. Protoplasts isolated from long-term cultured tissues derived from electroporated protoplasts retained the ability to enter division in culture earlier and with a higher frequency of plant regeneration than untreated cell suspension protoplasts.

Particle bombardment-mediated transient expression of a Brazil nut methionine-rich albumin in bean (Phaseolus vulgaris L.).

Bean (Phaseolus vulgaris L.) mature embryos were transformed using biolistic methods with a plasmid containing 2S albumin and beta-glucuronidase structural sequences, both under the control of the 35S CaMV promoter. We have shown that chimaeric tissues could be obtained and that both structural sequences were expressed to similar levels.

Somatic hybridization of sexually incompatible top-fruit tree rootstocks, wild pear (Pyrus communis var. pyraster L.) and Colt cherry (Prunus avium x pseudocerasus).

Mesophyll protoplasts of wild pear (Pyrus communis var. pyraster L., Pomoideae) were chemically fused with cell suspension protoplasts of cherry rootstock Colt (Prunus avium x pseudocerasus, Prunoideae), following an electroporation treatment of the separate parental protoplast systems. Fusion-treated protoplasts were cultured, on modified K8P medium, where it had been previously established that neither parental protoplasts were capable of division. Somatic hybrid calli were recovered and, following caulogenesis on MS medium with zeatin and after rooting of regenerated shoots, complete trees were obtained and grown in vivo. Hybridity of these trees was confirmed based on morphological characters, chromosome complement and isozyme analysis. Two separate cloned lines of this intersubfamilial rootstock somatic hybrid (wild pear (+) Colt cherry) were produced. This is the first report of the production of somatic hybrid plants of two woody species, of agronomic value, within the order Rosales.