Yves Chupeau

CO-SUPPRESSION OF NITRATE REDUCTASE HOST GENES AND TRANSGENES IN TRANSGENIC TOBACCO PLANTS

Constructs carrying the entire or part of the tobacco nitrate reductase cDNA (NIA) cloned between the promoter and terminator sequences of the 35S RNA of the cauliflower mosaic virus were introduced into tobacco, in an attempt to improve nitrate assimilation. Several transgenic plants that had elevated NIA mRNA and nitrate reductase (NR) activity were obtained. In addition, a few plants that exhibited a chlorotic phenotype characteristic of NR-deficient mutants were also obtained. One of these plants contained no NIA mRNA, no NR activity and accumulated nitrate. This phenotype was therefore assumed to result from co-suppression of 35S-NIA transgenes and host NIA genes. NR-deficient plants were also found among the progeny of transformants overexpressing NIA mRNA. Genetic analyses indicated that these NR-deficient plants were homozygous for the 35S-NIA transgene, although not all homozygous plants were deficient for NR. The ratio of normal to NR-deficient plants in the progeny of homozygous plants remained constant at each generation, irrespective of the state of expression of the NIA genes (active or inactive) in the previous generation. This ratio also remained unchanged when field trials were performed in two areas of France: Versailles and Bergerac. The analysis of homozygous plants revealed that co-suppression was reversible at some stage of sexual reproduction. Indeed, host genes and transgenes reactivated at each generation, and co-suppression always appeared after a lag period of normal growth, suggesting that the phenomenon is developmentaly regulated. We observed that the triggering of cosuppression was delayed when plants were initially grown under limited light and/or watered with limited nitrate supply (light and nitrate both being required for the expression of the host NIA genes). However, this delay did not affect the final ratio between normal and NR-deficient plants after transfer to nitrate-fertilized fields. Independent transformants exhibited either different co-suppression ratios or no co-suppression at all, irrespective of the transgene copy number, suggesting that genomic sequences surrounding the transgene might play a role in determining co-suppression.

Isolation and culture of sunflower protoplasts (Helianthus annuus L.): Factors influencing the viability of cell colonies derived from protoplasts

Abstract Sunflower protoplasts from various sources (mesophyll, stems, cotyledons anhypocotyls) have been tested for their capacity to divide in culture. Only hypocotyl protoplasts divided in our media at a high and repeatable percentage (60%). Culture at low density in a medium containing glutamine or ammonium succinate as sole sources of nitrogen and a reduced amount of naphthalene acetic acid (NAA) (0.1 mg/l) were the most important conditions for obtaining calli from sunflower protoplasts. On such media, 6% of the initially plated protoplasts reached the stage of calli.

Characterization of the Early Events Leading to Totipotency in an Arabidopsis Protoplast Liquid Culture by Temporal Transcript Profiling

An efficient liquid medium gave high plating efficiencies of protoplasts. Transcription profiles of plantlets and protoplast-derived cells during the first week of culture were used to track major molecular processes of the reentry in the cell cycle as the plant cells transitioned toward a totipotent state. Candidate genes for plant cell reprogramming are highlighted. The molecular mechanisms underlying plant cell totipotency are largely unknown. Here, we present a protocol for the efficient regeneration of plants from Arabidopsis thaliana protoplasts. The specific liquid medium used in our study leads to a high rate of reentry into the cell cycle of most cell types, providing a powerful system to study dedifferentiation/regeneration processes in independent somatic cells. To identify the early events in the establishment of totipotency, we monitored the genome-wide transcript profiles of plantlets and protoplast-derived cells (PdCs) during the first week of culture. Plant cells rapidly dedifferentiated. Then, we observed the reinitiation and reorientation of protein synthesis, accompanied by the reinitiation of cell division and de novo cell wall synthesis. Marked changes in the expression of chromatin-associated genes, especially of those in the histone variant family, were observed during protoplast culture. Surprisingly, the epigenetic status of PdCs and well-established cell cultures differed, with PdCs exhibiting rare reactivated transposons and epigenetic changes. The differentially expressed genes identified in this study are interesting candidates for investigating the molecular mechanisms underlying plant cell plasticity and totipotency. One of these genes, the plant-specific transcription factor ABERRANT LATERAL ROOT FORMATION4, is required for the initiation of protoplast division.

Sexual and somatic hybridization in the genus Lactuca

Various genes for disease resistance identified in wild Lactuca are difficult, even impossible to exploit in lettuce breeding, due to sexual incompatibility between L. sativa and wild Lactuca sp. We adapted two cellular biology techniques to overcome these interspecific barriers: in vitro embryo rescue and protoplast fusion. In vitro rescue of immature embryos was used successfully for sexual hybridization between L. sativa and L. virosa. Vigorous hybrid plants were produced between L. sativa and seven accessions of L. virosa. Protoplast fusion permitted the regeneration of somatic hybrids between L. sativa and either L. tatarica or L. perennis. Hybrids between L. sativa and L. tatarica were backcrossed to L. sativa.

Somatic hybrids of plants by fusion of protoplasts

SummaryFusions of protoplasts from Nicotiana langsdorffii and Nicotiana glauca were induced using polyethylene glycol. Parasexual hybrid colonies were selected for their ability to grow without growth substances. Hybrid plants, regenerated after grafting, were all tumorous and exhibited morphological and chromosome number variations. Out of 48 colonies selected in vitro only 6 regenerated flowering plants. Two of these plants had 42 chromosomes and were morphologically identical to the sexual amphidiploid Nicotiana glaucaxlangsdorffii.

Successful Gene Tagging in Lettuce Using the Tnt1 Retrotransposon from Tobacco

The tobacco (Nicotiana tabacum) element Tnt1 is one of the few identified active retrotransposons in plants. These elements possess unique properties that make them ideal genetic tools for gene tagging. Here, we demonstrate the feasibility of gene tagging using the retrotransposon Tnt1 in lettuce (Lactuca sativa), which is the largest genome tested for retrotransposon mutagenesis so far. Of 10 different transgenic bushes carrying a complete Tnt1 containing T-DNA, eight contained multiple transposed copies of Tnt1. The number of transposed copies of the element per plant was particularly high, the smallest number being 28. Tnt1 transposition in lettuce can be induced by a very simple in vitro culture protocol. Tnt1 insertions were stable in the progeny of the primary transformants and could be segregated genetically. Characterization of the sequences flanking some insertion sites revealed that Tnt1 often inserted into genes. The progeny of some primary transformants showed phenotypic alterations due to recessive mutations. One of these mutations was due to Tnt1 insertion in the gibberellin 3β-hydroxylase gene. Taken together, these results indicate that Tnt1 is a powerful tool for insertion mutagenesis especially in plants with a large genome.

The Isolation and Culture of Leaf Protoplasts of Cichorium intybus and Their Regeneration into Plants

Summary Enzymatically prepared protoplasts from leaves of various greenhouse grown Cichorium intybus cultivars did not show sustained divisions in a Murashige and Skoog salts-based medium. Replacement of ammonium and nitrate by glutamine as the sole nitrogen source improved plating efficiency and cell colony survival. Early transfer, before the second week of culture, to a low auxin medium was essential for development of microcalli. Plant regeneration from protoplast-derived calli was achieved through shoot formation.

Improved flax regeneration from hypocotyls using thidiazuron as a cytokinin source

SummaryThe effects of thidiazuron, benzyladenine and zeatin were tested with respect to bud regeneration of different flax explants from hypocotyls, cotyledons and apices of two fibre varieties (Ariane, Viking) and one linseed variety (Antarès). These three cytokinins were tested either alone or in combination with naphthalene acetic acid, indole acetic acid or 2,4-dichlorophenoxyacetic acid.Hypocotyls were the most responsive explants. Thidiazuron was significantly the most effective followed by benzyladenine, and then zeatin, in inducing organogenesis from hypocotyl segments. The optimal thidiazuron concentration for bud regeneration from hypocotyls was 0.1–0.3 μM in combination with 0.01 μM of naphthalene acetic acid. Six days after plating, shoot initials began to appear on hypocotyl sections compared with ten to fifteen days when using benzyladenine or zeatin.

Coat protein gene-mediated protection in Lactuca sativa against lettuce mosaic potyvirus strains.

Lettuce mosaic potyvirus (LMV) can be very destructive on lettuce crops worldwide. The LMV strain 0 (LMV-0) coat protein (CP) gene was engineered for expression in plants. It was introduced into three susceptible cultivars of Lactuca sativa using an improved procedure for transformation and regeneration of lettuce, by co-cultivation of leaf explants with Agrobacterium tumefaciens. Several transformants accumulated detectable levels of LMV CP. The R1 progeny of twelve R0 transformants (four plants per cultivar) with T-DNA integration at one single locus, was studied for protection against LMV. The progeny from five R0 transformants showed resistance to LMV-0, with the effectiveness of resistance depending on the development stage of the plants at the time of inoculation. The R1 and R2 progeny from one of these R0 transformants, Cocarde-9a, were more extensively analysed. The homozygous but not the hemizygous R1 plants displayed protection to LMV-0. The R2 progeny from one homozygous R1 plant were shown to be resistant to infection by LMV-0 and other LMV strains. As previously observed in other cases of potyvirus sequence-mediated protection, a phenomenon of recovery was observed in some plants, as well as complete resistance. However, this recovery phenotype was not always maintained, as opposed to the previous described cases, leading to a late progression of viral infection.

Ingested plant miRNAs regulate gene expression in animals.

The incidence of genetic material or epigenetic information transferred from one organism to another is an important biological question. A recent study demonstrated that plant small RNAs acquired orally through food intake directly influence gene expression in animals after migration through the plasma and delivery to specific organs.