Systemic Agrobacterium tumefaciens-mediated transfection of viral replicons for efficient transient expression in plants

Plant biotechnology relies on two approaches for delivery and expression of heterologous genes in plants: stable genetic transformation and transient expression using viral vectors. Although much faster, the transient route is limited by low infectivity of viral vectors carrying average-sized or large genes. We have developed constructs for the efficient delivery of RNA viral vectors as DNA precursors and show here that Agrobacterium-mediated delivery of these constructs results in gene amplification in all mature leaves of a plant simultaneously (systemic transfection). This process, called "magnifection", can be performed on a large scale and with different plant species. This technology combines advantages of three biological systems (the transfection efficiency of A. tumefaciens, the high expression yield obtained with viral vectors, and the post-translational capabilities of a plant), does not require genetic modification of plants and is faster than other existing methods.     

Plant virus expression systems for transient production of recombinant allergens in Nicotiana benthamiana

In recent years, several studies have demonstrated the use of autonomously replicating plant viruses as vehicles to express a variety of therapeutic molecules of pharmaceutical interest. Plant virus vectors for expression of heterologous proteins in plants represent an attractive biotechnological tool to complement the conventional production of recombinant proteins in bacterial, fungal, or mammalian cells. Virus vectors are advantageous when high levels of gene expression are desired within a short time, although the instability of the foreign genes in the viral genome may present problems. Similar levels of foreign protein production in transgenic plants often are unattainable, in some cases because of the toxicity of the foreign protein. Now virus-based vectors are for the first time investigated as a means of producing recombinant allergens in plants. Several plant virus vectors have been developed for the expression of foreign proteins. Here, we describe the utilization of tobacco mosaic virus- and potato virus X-based vectors for the transient expression of plant allergens in Nicotiana benthamiana plants. One approach involves the inoculation of tobacco plants with infectious RNA transcribed in vitro from a cDNA copy of the recombinant viral genome. Another approach utilizes the transfection of whole plants from wounds inoculated with Agrobacterium tumefaciens containing cDNA copies of recombinant plus-sense RNA viruses.     

PSITE vectors for stable integration or transient expression of autofluorescent protein fusions in plants: probing Nicotiana benthamiana-virus interactions

Plant functional proteomics research is increasingly dependent upon vectors that facilitate high-throughput gene cloning and expression of fusions to autofluorescent proteins. Here, we describe the pSITE family of plasmids, a new set of Agrobacterium binary vectors, suitable for the stable integration or transient expression of various autofluorescent protein fusions in plant cells. The pSITE vectors permit single-step Gateway-mediated recombination cloning for construction of binary vectors that can be used directly in transient expression studies or for the selection of transgenic plants on media containing kanamycin. These vectors can be used to express native proteins or fusions to monmeric red fluorescent protein or the enhanced green fluorescent protein and its cyan and yellow-shifted spectral variants. We have validated the vectors for use in transient expression assays and for the generation of transgenic plants. Additionally, we have generated markers for fluorescent highlighting of actin filaments, chromatin, endoplasmic reticulum, and nucleoli. Finally, we show that pSITE vectors can be used for targeted gene expression in virus-infected cells, which should facilitate high-throughput characterization of protein dynamics in host-virus interactions.     

Development of a new tobamovirus-based viral vector for protein expression in plants

Plants are becoming an interesting alternative system for the heterologous production of pharmaceutical proteins, providing a more scalable, cost-effective, and biologically safer option than the current expression systems. The development of plant virus expression vectors has allowed rapid and high-level transient expression of recombinant genes, and, in turn, provided an attractive plant-based production platform. Here we report the development of vectors based on the tobamovirus Pepper mild mottle virus (PMMoV) to be used in transient expression of foreign genes. In this PMMoV vector, a middle part of the viral coat protein gene was replaced by the green fluorescent protein (GFP) gene, and this recombinant genome was assembled in a binary vector suitable for plant agroinoculation. The accumulation of GFP was evaluated by observation of green fluorescent signals under UV light and by western blotting. Furthermore, by using this vector, the multiepitope gene for chikungunya virus was successfully expressed and confirmed by western blotting. This PMMoV-based vector represents an alternative system for a high-level production of heterologous protein in plants.

     

Expression of heterologous genes in plant systems: New possibilities

The basic methods used in current practice for stable and transient expression of heterologous genes in plants are presented and compared. The key areas of research in the heterologous expression of genes in plants have been identified by analyzing literature and experimental data: modeling of metabolic pathways; creation of marker-free transgenic plants; the search for new regulatory elements and plant genes influencing the efficiency of expression of heterologous genes in plants; development of new methods for analyzing of transgenic plants and new approaches to the expression of heterologous genes in plants.     

Heterologous activation of the Porphyra tenera HSP70 promoter in Bangiophycean algal cells

Porphyra has attracted great attention for its biological and industrial importance. However, establishment of a stable nuclear transformation has not yet been achieved in these organisms, which impedes the molecular biological study and the development of a molecular breeding method for them. Toward establishing the stable transformation, we have recently developed an efficient transient gene expression system in Bangiophycean algae, in which the HSP70 promoter from P. tenera (PtHSP70 promoter) was activated heterologously in P. yezoensis cells. Since heterologous promoters are required for homologous recombination-based stable transformation, the identification of heterologously activated promoters is important in establishing a stable transformation system in individual Bangiophycean alga. We here examined the activation of the PtHSP70 promoter using the GC-rich PyGUS reporter system in additional Porphyra and Bangia species. The results indicated that this promoter drove expression of the PyGUS gene efficiently in all examined algae, whereas there was quite low expression of PyGUS by the cauliflower mosaic virus 35S promoter that is widely used as a heterologous promoter in the transformation of green land plants. Therefore, heterologous activation of the PtHSP70 promoter could promote the establishment of the stable transformation system in various kinds of Bangiophycean algae.     

Baculovirus vectors for efficient gene delivery and expression in mammalian cells

Baculovirus expression vectors are extensively used for the delivery of foreign genes and expression of recombinant proteins in insect and mammalian cells. Modified baculoviruses containing mammalian promoter elements (BacMam viruses) for an efficient transient and stable transduction of diverse mammalian cells ensure a high level of heterologous protein expression both in vitro and in vivo. Recombinant baculovirus vectors containing mammalian expression cassette with cytomegalovirus promoter, green or red fluorescent protein gene, SV40pA polyadenylation signal, and polylinker MCS were constructed for the delivery of genes encoding hepatitis C virus structural proteins into mammalian cells. In HEK293T and Huh7 cells, formation of glycoprotein complexes and HCV4ike particles was observed. A high efficiency of the baculovirus-medi-ated gene transfer and expression of the virus envelope proteins in mammalian cells was demonstrated using fluorescence, flow cytometry, and immunoblot techniques.     

Use of viral replicons for the expression of genes in plants

Autonomously replicating virus-based vectors have been investigated as a means of introducing heterologous genes into plants. This approach has a number of potential advantages over stable genetic transformation, particularly in terms of speed and levels of expression that can be obtained. Several groups of plant viruses, with genomes consisting of both DNA and RNA, have been investigated as possible gene vectors. In the case of DNA viruses, it has generally been possible to identify nonessential regions of the genome that can be replaced by foreign sequences. However, there appear to be limitations on the size of insert which can be tolerated. In the case of RNA viruses, replacement of viral sequences usually has a drastic effect on the viability. However, in several cases it has proved possible to substantially increase the size of the viral genome by the direct insertion of additional sequences while still retaining the ability of the viruses to multiply and spread in plants. These RNA virus-based systems appear to have the greatest potential as gene vectors.     

Transformation of peanut with a soybean vspB promoter‐uidA chimeric gene. I. Optimization of a transformation system and analysis of GUS expression in primary transgenic tissues and plants

Direct DNA delivery via microprojectile bombardment has become an established approach for gene transfer into peanut ( Arachis hypogaea L.). To optimize our transformation protocol and to simultaneously explore the function of a heterologous promoter whose activity is developmentally regulated, embryogenic cultures from three peanut cultivars were bombarded with two plasmid constructs containing a uidA gene controlled by either a soybean vegetative storage protein gene promoter or a cauliflower mosaic virus 35S promoter. We found that GUS transient expression was useful to predict stable transformation and confirmed that image analysis could provide a quick and efficient method for semi‐quantitation of transient expression. One hundred and sixty hygromycin‐resistant cell lines were recovered from and maintained on selective medium, and those tested by Southern blot analysis showed integration of the foreign gene. Over 200 transgenic plants were regenerated from 38 cell lines. More than 100 plants from 32 cell lines flowered and 79 plants from 19 cell lines produced pods. Over 1000 R₁ seeds were harvested. Analysis of expression in primary transgenic plants showed that GUS expression driven by the vspB promoter was modulated by chemical and positional information.     

Development of a simple transient assay for Ac/Ds activity in cells of intact barley tissue

The development of a barley ( Hordeurn vulgare L.) transformation system made it possible to consider the use of maize Activator/Dissociation ( Ac/Ds ) transposable elements for gene tagging in transgenic barley plants. However, barley transformation is time-consuming, and therefore a simple transient assay for Ac/Ds activity in intact barley tissues was developed to test the components of a proposed gene tagging system, prior to their stable introduction into plants. In this assay, barley scutellar tissue is co-transformed with constructs containing the maize Ac transposase gene and an Escherichia coli uid A reporter gene ( Gus ), the expression of which is interrupted by a maize Ds element. In transformed barley scutellar cells, Ac transposase-mediated excision of the Ds element generates a functional Gus gene, leading to histochemically detectable GUS activity. Characterization of the excision products showed that they had a pattern of nucleotide deletions and/or transversions similar to that found in maize and other heterologous plant systems. In addition, although contrary to the situation observed in heterologous dicot systems, efficient Ds excision in barley, a heterologous monocot system, appears to be inversely associated with Ac copy number, a finding similar to the Ac dosage effects observed in maize. The transient assay was used to demonstrate functional transposase activity in barley callus lines stably transformed with an Ac transposase gene.     

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.     

A Series of TA-Based and Zero-Background Vectors for Plant Functional Genomics

With the sequencing of genomes from many organisms now complete and the development of high-throughput sequencing, life science research has entered the functional post-genome era. Therefore, deciphering the function of genes and how they interact is in greater demand. To study an unknown gene, the basic methods are either overexpression or gene knockout by creating transgenic plants, and gene construction is usually the first step. Although traditional cloning techniques using restriction enzymes or a site-specific recombination system (Gateway or Clontech cloning technology) are highly useful for efficiently transferring DNA fragments into destination plasmids, the process is time consuming and expensive. To facilitate the procedure of gene construction, we designed a TA-based cloning system in which only one step was needed to subclone a DNA fragment into vectors. Such a cloning system was developed from the pGreen binary vector, which has a minimal size and facilitates construction manipulation, combined with the negative selection marker gene ccdB, which has the advantages of eliminating the self-ligation background and directly enabling high-efficiency TA cloning technology. We previously developed a set of transient and stable transformation vectors for constitutive gene expression, gene silencing, protein tagging, subcellular localization analysis and promoter activity detection. Our results show that such a system is highly efficient and serves as a high-throughput platform for transient or stable transformation in plants for functional genome research.     

TRBO: a high-efficiency tobacco mosaic virus RNA-based overexpression vector

Transient expression is a rapid, useful approach for producing proteins of interest in plants. Tobacco mosaic virus (TMV)-based transient expression vectors can express very high levels of foreign proteins in plants. However, TMV vectors are, in general, not efficiently delivered to plant cells by agroinfection. It was determined that agroinfection was very efficient with a 35S promoter-driven TMV replicon that lacked the TMV coat protein gene sequence. This coat protein deletion vector had several useful features as a transient expression system, including improved ease of use, higher protein expression rates, and improved biocontainment. Using this TMV expression vector, some foreign proteins were expressed at levels of 3 to 5 mg/g fresh weight of plant tissue. It is proposed that this new transient expression vector will be a useful tool for expressing recombinant proteins in plants for either research or production purposes.     

Transient expression assays in grapevine: a step towards genetic improvement

In the past few years, the usefulness of transient expression assays has continuously increased for the characterization of unknown gene function and metabolic pathways. In grapevine (Vitis vinifera L.), one of the most economically important fruit crops in the world, recent systematic sequencing projects produced many gene data sets that require detailed analysis. Due to their rapid nature, transient expression assays are well suited for large‐scale genetic studies. Although genes and metabolic pathways of any species can be analysed by transient expression in model plants, a need for homologous systems has emerged to avoid the misinterpretation of results due to a foreign genetic background. Over the last 10 years, various protocols have thus been developed to apply this powerful technology to grapevine. Using cell suspension cultures, somatic embryos, leaves or whole plantlets, transient expression assays enabled the study of the function, regulation and subcellular localization of genes involved in specific metabolic pathways such as the biosynthesis of phenylpropanoids. Disease resistance genes that could be used for marker‐assisted selection in conventional breeding or for stable transformation of elite cultivars have also been characterized. Additionally, transient expression assays have proved useful for shaping new tools for grapevine genetic improvement: synthetic promoters, silencing constructs, minimal linear cassettes or viral vectors. This review provides an update on the different tools (DNA constructs, reporter genes, vectors) and methods (Agrobacterium‐mediated and direct gene transfer methods) available for transient gene expression in grapevine. The most representative results published thus far are then described.     

125 years of virology and ascent of biotechnologies based on viral expressio

The study of viruses lasts for more than a century since their discovery in 1892. In recent decades, viruses are also being actively exploited as a biotechnological tool. Plant-virus-driven transient expression of heterologous proteins is an actively developing production platform; it is the basis of several industrial processes that are currently being used for the production of multiple recombinant proteins. Viral vectors have also become useful tools for research. Viral vectors delivered by Agrobacterium (magnifection) provide for high protein yield, rapid scale up and fast manufacturing. In this review, we explore modern approaches for biotechnological production of recombinant proteins in plants using viral vectors.     

Comparison of Expression Vectors for Transient Expression of Recombinant Proteins in Plants

Production of recombinant proteins in plants is of increasing importance for practical applications. However, the production of stable transformed transgenic plants is a lengthy procedure. Transient expression, on the other hand, can deliver recombinant proteins within a week, and many viral vectors have been constructed for that purpose. Each of them is reported to be highly efficient, robust and cost-effective. Here, a variety of expression vectors which were designed for transient and stable plant transformation, including pPZP3425, pPZP5025, pPZPTRBO, pJLTRBO, pEAQ-HT and pBY030-2R, was compared for the expression of green fluorescent protein and β-glucuronidase in Nicotiana benthamiana by Agrobacterium-mediated transient expression. Our results show that pPZPTRBO, pJLTRBO and pEAQ-HT had comparable expression levels without co-infiltration of a RNA-silencing inhibitor. The other vectors, including the non-viral vectors pPZP5025 and pPZP3425, needed co-infiltration of the RNA-silencing inhibitor P19 to give good expression levels.     

A single plasmid transfection that offers a significant advantage associated with puromycin selection in Drosophila Schneider S2 cells expressing heterologous proteins

The Drosophila Schneider S2 (S2) Expression System enables expression of recombinant proteins constitutively, as well as inductively. This system can establish both transient and stable transformants with various selection markers. The generation of stable cell lines for increased expression or large scale expression of the desired protein is currently accomplished by cotransfection of both the expression and selection vectors. The selection vectors, pCoHYGRO and pCoBLAST, are commercially available using hygromycin-B and blasticidin S, respectively. Recently, we generated a plasmid, pCoPURO, for selection of transfected S2 cells using puromycin, which allows significant acceleration of the selection time. Although co-transfection of the selection marker with the plasmid for heterologous protein expression is functional in stable expression at short culture periods, the expression levels of stable transformants are continuously decreased during long culture times. To overcome this limitation, we generated pMT-PURO, a new plasmid that contains both the expression cassette and puromycin selection marker in a single plasmid. This system allows rapid selection and maintenance of the transformed S2 lines for extended culture periods.