Production de protéines recombinantes par des plantes carnivores génétiquement transformées : application à Drosera rotundifolia et transfert de la technologie à Nepenthes alata

The present work focuses on the development of a new innovating technology, called PAT Friday®, aiming at producing recombinant proteins into the extra-foliar fluid of modified carnivorous plants. Two objectives were assigned to this work : 1- to realize a proof of concept of the technology on the experimental model Drosera rotundifolia, transformed with marker and human genes, to confirm the occurence of the recombinant proteins into glu ; and 2 - to evaluate and develop, the technology on the model Nepenthes alata, more adapted to industrial scaling-up. The results indicate the presence of two marker proteins GUS and GFP inside the tissues and into the glu of modified Drosera rotundifolia plants. The same plant species has also been transformed with human gamma interferon and intrinsic factor genes. The corresponding human recombinant proteins have been detected into the plant tissues. Potential industrial scaling-up has been studied with the species Nepenthes alata. The results show a potential productivity of 10 to 15 kg of total proteins per hectare per year, thanks to non-destructive repeated harvests, and possibility to efficiently control the natural proteinase activity. The elaboration of a regeneration protocol has been undertaken through indirect organogenesis and somatic embryogenesis, with a view to transform genetically this plant. PAT Friday® technology, with simplified extraction and purification methods of the proteins of interest targeted into the liquid secretions, opens new perspectives in the field of therapeutical proteins produced in plantsLe travail présenté porte sur le développement d?une nouvelle technologie innovante, nommée PAT Friday®, visant à produire des protéines recombinantes au sein des sécrétions extracellulaires de plantes carnivores génétiquement modifiées. Deux objectifs ont été fixés : Réaliser la preuve de concept de la technologie sur le modèle expérimental Drosera rotundifolia, en transformant la plante avec des gènes marqueurs et humains afin de mettre en évidence la présence des protéines recombinantes dans la glu ; et développer, après évaluation, la technologie sur un modèle potentiellement industrialisable, Nepenthes alata. Les résultats ont indiqué la présence des deux protéines marqueurs GFP et GUS dans les tissus et dans la glu de Drosera rotundifolia transformées. Les plantes ont également été transformées génétiquement avec les gènes humains de l?interféron gamma et du facteur intrinsèque. Les protéines recombinantes humaines ont été mises en évidence au sein des tissus végétaux. Le potentiel industriel du modèle Nepenthes alata a ensuite été étudié : 10 à 15 kg de protéines totales par hectare et par an peuvent être produits, grâce notamment à des récoltes successives non destructrices, et la possibilité de contrôler l?activité des protéases digestives naturelles. L?élaboration d?un protocole de régénération de la plante a été entreprise par embryogénèse somatique et organogénèse indirecte, en vue de sa transformation génétique. La technologie PAT Friday®, avec des étapes simplifiées d?extraction et de purification des protéines d?intérêt produites dans le liquide digestif, offre de nouvelles perspectives dans le domaine des protéines thérapeutiques produites à partir de plante

Production of recombinant proteins by genetically modified carnivorous plants : application to Drosera rotundifolia and technology transfer to Nepenthes alata

Le travail présenté porte sur le développement d’une nouvelle technologie innovante, nommée PAT Friday®, visant à produire des protéines recombinantes au sein des sécrétions extracellulaires de plantes carnivores génétiquement modifiées. Deux objectifs ont été fixés : Réaliser la preuve de concept de la technologie sur le modèle expérimental Drosera rotundifolia, en transformant la plante avec des gènes marqueurs et humains afin de mettre en évidence la présence des protéines recombinantes dans la glu ; et développer, après évaluation, la technologie sur un modèle potentiellement industrialisable, Nepenthes alata. Les résultats ont indiqué la présence des deux protéines marqueurs GFP et GUS dans les tissus et dans la glu de Drosera rotundifolia transformées. Les plantes ont également été transformées génétiquement avec les gènes humains de l’interféron gamma et du facteur intrinsèque. Les protéines recombinantes humaines ont été mises en évidence au sein des tissus végétaux. Le potentiel industriel du modèle Nepenthes alata a ensuite été étudié : 10 à 15 kg de protéines totales par hectare et par an peuvent être produits, grâce notamment à des récoltes successives non destructrices, et la possibilité de contrôler l’activité des protéases digestives naturelles. L’élaboration d’un protocole de régénération de la plante a été entreprise par embryogénèse somatique et organogénèse indirecte, en vue de sa transformation génétique. La technologie PAT Friday®, avec des étapes simplifiées d’extraction et de purification des protéines d’intérêt produites dans le liquide digestif, offre de nouvelles perspectives dans le domaine des protéines thérapeutiques produites à partir de plantesThe present work focuses on the development of a new innovating technology, called PAT Friday®, aiming at producing recombinant proteins into the extra-foliar fluid of modified carnivorous plants. Two objectives were assigned to this work : 1- to realize a proof of concept of the technology on the experimental model Drosera rotundifolia, transformed with marker and human genes, to confirm the occurence of the recombinant proteins into glu ; and 2 - to evaluate and develop, the technology on the model Nepenthes alata, more adapted to industrial scaling-up. The results indicate the presence of two marker proteins GUS and GFP inside the tissues and into the glu of modified Drosera rotundifolia plants. The same plant species has also been transformed with human gamma interferon and intrinsic factor genes. The corresponding human recombinant proteins have been detected into the plant tissues. Potential industrial scaling-up has been studied with the species Nepenthes alata. The results show a potential productivity of 10 to 15 kg of total proteins per hectare per year, thanks to non-destructive repeated harvests, and possibility to efficiently control the natural proteinase activity. The elaboration of a regeneration protocol has been undertaken through indirect organogenesis and somatic embryogenesis, with a view to transform genetically this plant. PAT Friday® technology, with simplified extraction and purification methods of the proteins of interest targeted into the liquid secretions, opens new perspectives in the field of therapeutical proteins produced in plant

A Rapid and Efficient Method for Isolating High Quality DNA from Leaves of Carnivorous Plants from the Drosera Genus

International audienceDrosera rotundifolia, Drosera capensis, and Drosera regia are carnivorous plants of the sundew family, characterized by the presence of stalked and sticky glands on the upper leaf surface, to attract, trap, and digest insects. These plants contain exceptionally high amounts of polysaccharides, polyphenols, and other secondary metabolites that interfere with DNA isolation and subsequent enzymatic reactions such as PCR amplification. We present here a protocol for quick isolation of Drosera DNA with high yield and a high level of purity, by combining a borate extraction buffer with a commercial DNA extraction kit, and a proteinase K treatment during extraction. The yield of genomic DNA is from 13.36 μg/g of fresh weight to 35.29 μg/g depending of the species of Drosera, with a A₂₆₀/A₂₈₀ ratio of 1.43-1.92. Moreover, the procedure is quick and can be completed in 2.5 h

Assessing Carnivorous Plants for the Production of Recombinant Proteins

The recovery of recombinant proteins from plant tissues is an expensive and time-consuming process involving plant harvesting, tissue extraction, and subsequent protein purification. The downstream process costs can represent up to 80% of the total cost of production. Secretion-based systems of carnivorous plants might help circumvent this problem. Drosera and Nepenthes can produce and excrete out of their tissues a digestive fluid containing up to 200 mg. L-1 of natural proteins. Based on the properties of these natural bioreactors, we have evaluated the possibility to use carnivorous plants for the production of recombinant proteins. In this context, we have set up original protocols of stable and transient genetic transformation for both Drosera and Nepenthes sp. The two major drawbacks concerning the proteases naturally present in the secretions and a polysaccharidic network composing the Drosera glue were overcome by modulating the pH of the plant secretions. At alkaline pH, digestive enzymes are inactive and the interactions between the polysaccharidic network and proteins in the case of Drosera are subdued allowing the release of the recombinant proteins. For D. capensis, a concentration of 25 μg of GFP/ml of secretion (2% of the total soluble proteins from the glue) was obtained for stable transformants. For N. alata, a concentration of 0.5 ng of GFP/ml secretions (0.5% of total soluble proteins from secretions) was reached, corresponding to 12 ng in one pitcher after 14 days for transiently transformed plants. This plant-based expression system shows the potentiality of biomimetic approaches leading to an original production of recombinant proteins, although the yields obtained here were low and did not allow to qualify these plants for an industrial platform project

A simple SDS-Page protein pattern from pitcher secretions as a new tool to distinguish Nepenthes species (Nepenthaceae)

International audiencePremise of the study - Carnivorous plants have always fascinated scientists because these plants are able to attract, capture and digest animal prey using their remarkable traps that contain digestive secretions. Nepenthes is one of the largest genera of carnivorous plants, with 120 species described thus far. Despite an outstanding diversity of trap designs, many species are often confused with each other and remain difficult to classify because they resemble pitchers or of the occurrence of interspecific hybrids. Methods - Here, we propose a new method to easily distinguish Nepenthes species based on a 1D SDS PAGE protein pattern analysis of their pitcher secretions. Intraspecific comparisons were performed between specimens growing in different environmental conditions to ascertain the robustness of this method. Key results - Our results show that, at the juvenile stage and in the absence of prey in the pitcher, an examined species is characterized by a specific and stable profile, whatever the environmental conditions. Conclusions - The method we describe here can be used as a reliable tool to easily distinguish between Nepenthes species and to help with potential identification based on the species-specific protein pattern of their pitcher secretions, which is complementary to the monograph informatio

Proteome analysis of digestive fluids in Nepenthes pitchers

International audienceBackground and Aims: Carnivorous plants have developed strategies to enable growth in nutrient-poor soils. For the genus Nepenthes, this strategy represents producing pitcher-modified leaves that can trap and digest various prey. These pitchers produce a digestive fluid composed of proteins, including hydrolytic enzymes. The focus of this study was on the identification of these proteins.Methods: In order to better characterize and have an overview of these proteins, digestive fluid was sampled from pitchers at different stages of maturity from five species of Nepenthes (N. mirabilis, N. alata, N. sanguinea, N. bicalcarata and N. albomarginata) that vary in their ecological niches and grew under different conditions. Three complementary approaches based on transcriptomic resources, mass spectrometry and in silico analysis were used.Key Results: This study permitted the identification of 29 proteins excreted in the pitchers. Twenty of these proteins were never reported in Nepenthes previously and included serine carboxypeptidases, α- and β-galactosidases, lipid transfer proteins and esterases/lipases. These 20 proteins display sequence signals allowing their secretion into the pitcher fluid.Conclusions:Nepenthes pitcher plants have evolved an arsenal of enzymes to digest prey caught in their traps. The panel of new proteins identified in this study provides new insights into the digestive process of these carnivorous plants

Datura innoxia plants hydroponically-inoculated with Agrobacterium rhizogenes display an enhanced growth and alkaloid metabolism

International audienceBackground: The production of secondary metabolites through the culture of entire plants is of great interest. Soilless culture, such as hydroponics, enables the control of plant growth and metabolism. Specific environmental conditions must be developed to maximize the productivity of medicinal plants used as efficient natural bioreactors. Methods: The nutrient solution of newly established hydroponic cultures ofDatura innoxia Mill. were inoculated with Agrobacterium rhizogenes (A.r.) wild strains (TR7, TR107, 11325 or 15834). Growth and the alkaloid contents of roots and aerial parts were analyzed. Axenic cultures were also performed with modified TR7 strains containing the egfp or gus reporter gene. In vitro isolated root cultures enabled the phenological and molecular demonstration of gene transfer. Results: A.r.TR 7 led to a greater improvement in plant secondary metabolism and growth. Positive expression of the reporter genes occurred. Isolation and subculture of some of the roots of these plants showed a hairy root phenotype; molecular tests proved the transfer of bacterial genes into the roots isolated from the plants. Conclusions: Hyoscyamine and scopolamine productivity is enhanced after A.r. inoculation in the nutrient solution of hydroponic plants. Transformation events occur in the original roots of the plants. This leads to chimeric plants with a part of their roots harboring a hairy root phenotype. Such semi-composite plants could be used for successful specialized metabolite bioproduction in greenhouses

Beet western yellows virus infects the carnivorous plant Nepenthes mirabilis

Although poleroviruses are known to infect a broad range of higher plants, carnivorous plants have not yet been reported as hosts. Here, we describe the first polerovirus naturally infecting the pitcher plant Nepenthes mirabilis. The virus was identified through bioinformatic analysis of NGS transcriptome data. The complete viral genome sequence was assembled from overlapping PCR fragments and shown to share 91.1 % nucleotide sequence identity with the US isolate of beet western yellows virus (BWYV). Further analysis of other N. mirabilis plants revealed the presence of additional BWYV isolates differing by several insertion/deletion mutations in ORF5