Lilya Kopertekh

Agroinfiltration as a tool for transient expression of cre recombinase in vivo.

Agroinfiltration was used to express transiently cre recombinase from bacteriophage P1 in planta. Activation of gfp expression after cre-mediated excision of a bar intervening sequence served as a marker to monitor site-specific recombination events in lox-target N. benthamiana plants. Gfp expressing regenerants from A. tumefaciens infiltrated leaves were obtained with an efficiency of about 34%. In 20% of the regenerants bar gene excision was due to the expression of stably integrated cre gene, whereas in 14% of plants site-specific recombination was a consequence of transient cre expression. Phenotypic and molecular data indicated that the recombined state has been transferred to the T1 generation. These results demonstrate the suitability of agroinfiltration for the expression of cre recombinase in vivo.

Tuber‐specific cphA expression to enhance cyanophycin production in potatoes

The production of biodegradable polymers that can be used to substitute petrochemical compounds in commercial products in transgenic plants is an important challenge for plant biotechnology. Nevertheless, it is often accompanied by reduced plant fitness. To decrease the phenotypic abnormalities of the sprout and to increase polymer production, we restricted cyanophycin accumulation to the potato tubers by using the cyanophycin synthetase gene (cphA(Te)) from Thermosynechococcus elongatus BP-1, which is under the control of the tuber-specific class 1 promoter (B33). Tuber-specific cytosolic (pB33-cphA(Te)) as well as tuber-specific plastidic (pB33-PsbY-cphA(Te)) expression resulted in significant polymer accumulation solely in the tubers. In plants transformed with pB33-cphA(Te), both cyanophycin synthetase and cyanophycin were detected in the cytoplasm leading to an increase up to 2.3% cyanophycin of dry weight and resulting in small and deformed tubers. In B33-PsbY-cphA(Te) tubers, cyanophycin synthetase and cyanophycin were exclusively found in amyloplasts leading to a cyanophycin accumulation up to 7.5% of dry weight. These tubers were normal in size, some clones showed reduced tuber yield and sometimes exhibited brown sunken staining starting at tubers navel. During a storage period over of 32 weeks of one selected clone, the cyanophycin content was stable in B33-PsbY-cphA(Te) tubers but the stress symptoms increased. However, all tubers were able to germinate. Nitrogen fertilization in the greenhouse led not to an increased cyanophycin yield, slightly reduced protein content, decreased starch content, and changes in the amounts of bound and free arginine and aspartate, as compared with control tubers were observed.

Alternatives to Antibiotic Resistance Marker Genes for In Vitro Selection of Genetically Modified Plants – Scientific Developments, Current Use, Operational Access and Biosafety Considerations

Genes conferring resistance to antibiotics have been widely used as markers for the selection of transformed cells in the development of genetically modified (GM) plants. Their presence in GM plants released in the environment or used as food or feed has raised concerns over the past years regarding possible risks for human health and the environment. Although these concerns have not been supported so far by scientific evidence, the implementation of selection approaches avoiding the presence of antibiotic resistance marker genes (ARMGs) in the final GM plant is increasingly considered by GM plant developers, not only to alleviate the above-mentioned concerns, but also to circumvent technical limitations associated with the use of ARMGs. In the current paper, we present the results of a three-step analysis of selectable markers and reporter genes as well as methods aiming at developing marker-free GM plants. First, based on a comprehensive review of the scientific literature, technical developments in this domain are presented. Second, a state-of-the-art of the current use of selection approaches is provided based on publicly available information on GM plants tested in the field or authorized for commercialization. Third, in order to get more insight in the underlying practical, scientific and/or regulatory arguments supporting the choice of selection approaches, we present the results of a survey directed at relevant developers and users of GM plants. The applicability, efficiency, operational access and biosafety of the various selection approaches is discussed and considered in light of their current use, and in perspective to the long history of use of ARMGs in plant biotechnology.

Possible role of the Nt-4/1 protein in macromolecular transport in vascular tissue.

The Arabidopsis thaliana 4/1 (At-4/1) protein has a highly α-helical structure with potential to interact both with itself and other protein ligands, including the movement proteins of some plant viruses; the Nicotiana tabacum ortholog (Nt-4/1) has similar structure. Here we describe localization of GUS expression in transgenic N. tabacum seedlings under control of the Nt-4/1 promoter, which indicates that transcription is associated with the veins at certain developmental stages, and especially in the hypocotyl. Viroid accumulation and movement was altered in plants in which 4/1 expression was reduced by virus-induced gene silencing. These localization studies support a role of 4/1 in signaling in the vasculature, including mobility of pathogen-related and cellular RNAs.

Subcellular localization and self-interaction of plant-specific Nt-4/1 protein

The Nicotiana tabacum Nt-4/1 protein is a plant-specific protein of unknown function. Analysis of bacterially expressed Nt-4/1 protein in vitro revealed that the protein secondary structure is mostly alpha-helical and suggested that it could consist of three structural domains. Earlier studies of At-4/1, the Arabidopsis thaliana-encoded ortholog of Nt-4/1, demonstrated that GFP-fused At-4/1 was capable of polar localization in plant cells, association with plasmodesmata, and cell-to-cell transport. Together with the At-4/1 ability to interact with a plant virus movement protein, these data supported the hypothesis of the At-4/1 protein involvement in viral transport through plasmodesmata. Studies of the Nt-4/1-GFP fusion protein reported in this paper revealed that the protein was localized to cytoplasmic bodies, which were co-aligned with actin filaments and capable of actin-dependent intracellular movement. The Nt-4/1-GFP bodies, being non-membrane structures, were found in association with the plasma membrane, the tubular endoplasmic reticulum and endosome-like structures. Bimolecular fluorescence complementation experiments and inhibition of nuclear export showed that the Nt-4/1 protein was capable of nuclear-cytoplasmic transport. The nuclear export signal (NES) was identified in the Nt-4/1 protein by site-directed mutagenesis. The Nt-4/1 NES mutant was localized to the nucleoplasm forming spherical bodies. Immunogold labeling and electron microscopy of cytoplasmic Nt-4/1-containing bodies and nuclear structures containing the Nt-4/1 NES mutant revealed differences in their fine structure. In mammalian cells, Nt-4/1-GFP formed cytoplasmic spherical bodies similar to those found for the Nt-4/1 NES mutant in plant cell nuclei. Using dynamic laser light scattering and electron microscopy, the Nt-4/1 protein was found to form multimeric complexes in vitro.

Plant 4/1 protein: potential player in intracellular, cell-to-cell and long-distance signaling

Originally isolated as a result of its ability to interact with the movement protein of Tomato spotted wilt virus in a yeast two-hybrid system, the 4/1 protein is proving to be an excellent tool for studying intracellular protein trafficking and intercellular communication. Expression of 4/1 in vivo is tightly regulated, first appearing in the veins of the cotyledon and later in the vasculature of the leaf and stem in association with the xylem parenchyma and phloem parenchyma. Structural studies indicate that 4/1 proteins contain as many as five coiled–coil (CC) domains; indeed, the highest level of sequence identity among 4/1 proteins involves their C-terminal CC domains, suggesting that protein–protein interaction is important for biological function. Recent data predict that the tertiary structure of this C-terminal CC domain is strikingly similar to that of yeast protein She2p; furthermore, like She2p, 4/1 protein exhibits RNA-binding activity, and mutational analysis has shown that the C-terminal CC domain is responsible for RNA binding. The 4/1 protein contains a nuclear export signal. Additional microscopy studies involving leptomycin and computer prediction suggest the presence of a nuclear localization signal as well.

Transient Production of Recombinant Pharmaceutical Proteins in Plants: Evolution and Perspectives

During the last two decades, the production of pharmaceutical proteins in plants evolved from proof of concept to established technology adopted by several biotechnological companies. This progress is particularly based on intensive research starting stable genetic transformation and moving to transient expression. Due to its advantages in yield and speed of protein production transient expression platforms became the leading plant-based manufacturing technology. Current transient expression methods rely on Agrobacteriummediated delivery of expression vectors into plant cells. In recent years, great advances have been made in the improvement of expression vectors, host cell engineering as well as in the development of commercial manufacturing processes. Several GMP-certified large-scale production facilities exist around the world to utilize agroinfiltration method. A number of pharmaceutical proteins produced by transient expression are currently in clinical development. The great potential of transient expression platform in respect to rapid response to emerging pandemics was demonstrated by the production of experimental ZMapp antibodies against Ebola virus as well as influenza vaccines. This review is focused on current design, status and future perspectives of plant transient expression system for the production of biopharmaceutical proteins.

Utilization of PVX-Cre expression vector in potato

Trait genes are usually introduced into the plant genome together with a marker gene. The last one becomes unnecessary after transgene selection and characterization. One of the strategies to produce transgenic plants free from the selectable marker is based on site-specific recombination. The present study employed the transient Cre-lox system to remove the nptII marker gene from potato. Transient marker gene excision involves introduction of Cre protein in lox-target plants by PVX virus vector followed by plant regeneration. Using optimized experimental conditions, such as particle bombardment infection method and application of P19 silencing suppressor protein, 20–27% of regenerated plants were identified by PCR analysis as marker-free. Based on our comparison of the recombination frequencies observed in this study to the efficiency of other methods to avoid or eliminate marker genes in potato, we suggest that PVX-Cre mediated site-specific excisional recombination is a useful tool to generate potato plants without superfluous transgenic sequences.

Elimination of Transgenic Sequences in Plants by Cre Gene Expression

The ability to insert foreign DNA into plant cells opened plenty opportunities for the development of new cell lines and improved varieties for agronomic and industrial purposes. Despite the great advances reached there are still some limitations in plant biotechnology based on genetic transformation. In most cases precise engineering of target genomic loci is difficult. Random DNA integration and multi-copy transgene insertions might result in unpredictable expression or gene silencing. Furthermore, commercial application of plant biotechnology products rises numerous regulatory and biosafety concerns about possible spread of the transgenes into the environment or the presence of selectable marker genes. One of the molecular tools that can help to overcome these limitations is site-specific recombination. Several site-specific recombination systems have been shown to be functional in plant cells: the Cre-lox system from bactreiophage P1 (Dale and Ow, 1990; Odell et al., 1990, Bayley et al., 1992), the FLP-FRT system from Saccharomyces cerevisiae (Lyznik et al., 1993; Lloyd and Davis, 1994; Kilby et al., 1995), the R-RS system from Zygosaccharomyces rouxii (Onouchi et al., 1991), the Gin-gix system from bacteriophage Mu (Maeser and Kahmann, 1991), the CinH-RS2 system from Acetinetobacter (Moon et al., 2011), the ParA system from a plasmid operon parCBA (Thomson et al., 2009) and the Streptomyces phage phiC31 system (Kittiwongwattana et al., 2007, Rubtsova et al., 2008). Currently, Crelox has become the most commonly employed site-specific recombination system. Although both types of recombination catalyzed by the Cre protein, site-specific integration and excision, found practical application (Ow, 2002; Gilbertson, 2003; Lyznik et al., 2003; Gidoni et al., 2008; Wang et al., 2011), the removal of lox-flanked sequences is the most widely used applications of Cre recombinase. The following technologies are based on excisional recombination: (i) regulation of gene expression, (ii) resolution of complex insertion sites to single copy structures, (iii) biological confinement, and (iv) elimination of selectable marker genes. Here we review the progress in the employment of Cre-mediated site-specific excisional recombination for applied plant biology and discuss in detail the advantages, limitations and potential improvements of technologies utilizing the Cre-lox system.

A developmentally regulated Cre-lox system to generate marker-free transgenic Brassica napus plants.

In this chapter, a strategy for engineering marker-free Brassica napus plants is described. It is based on the Cre-lox site-specific recombination system and includes three essential steps. At first, the binary vector pLH-nap-lx-cre-35S-bar-lx-vst has been designed. In this vector, the cre gene and the bar expression cassette are flanked by two lox sites in direct orientation. The lox-flanked sequence is placed between a seed-specific napin promoter and a coding region for the vstI gene. At the second step, the cre-bar vector was transferred into B. napus hypocotyl explants by Agrobacterium tumefaciens-mediated transformation. Finally, T1 progeny was tested for excision of the marker gene at phenotypic and molecular levels. PCR, sequencing, and Southern blot analysis confirmed complete and precise deletion of the lox-flanked DNA region. This developmentally regulated Cre-lox system can be applied to remove undesirable DNA in transgenic plants propagated by seeds.