Synchrotron FTIR and Raman spectroscopy provide unique spectral fingerprints for Arabidopsis floral stem vascular tissues.

Cell walls are highly complex structures that are modified during plant growth and development. For example, the development of phloem and xylem vascular cells, which participate in the transport of sugars and water as well as providing support, can be influenced by cell-specific wall composition. Here, we used synchrotron radiation-based Fourier-transform infrared (SR-FTIR) and Raman spectroscopy to analyse the cell wall composition of floral stem vascular tissues of wild-type Arabidopsis and the double-mutant sweet11-1 sweet12-1, which has impaired sugar transport. The SR-FTIR spectra showed that in addition to modified xylem cell wall composition, phloem cell walls in the double-mutant line were characterized by modified hemicellulose composition. Combining Raman spectroscopy with a classification and regression tree (CART) method identified combinations of Raman shifts that could distinguish xylem vessels and fibers. In addition, the disruption of the SWEET11 and SWEET12 genes impacted on xylem wall composition in a cell-specific manner, with changes in hemicelluloses and cellulose observed at the xylem vessel interface. These results suggest that the facilitated transport of sugars by transporters that exist between vascular parenchyma cells and conducting cells is important in ensuring correct phloem and xylem cell wall composition.

Wuschel overexpression promotes somatic embryogenesis and induces organogenesis in cotton (Gossypium hirsutum L.) tissues cultured in vitro.

KEY MESSAGE: This work shows that overexpression of the WUS gene from Arabidopsis enhanced the expression of embryogenic competence and triggered organogenesis from some cells of the regenerated embryo-like structures. Agrobacterium-mediated genetic transformation of cotton was described in the late 1980s, but is still time consuming and largely genotype dependant due to poor regeneration. To help solve this bottleneck, we over-expressed the WUSCHEL (WUS) gene, a homeobox transcription factor cloned in Arabidopsis thaliana, known to stimulate organogenesis and/or somatic embryogenesis in Arabidopsis tissues cultured in vitro. The AtWUS gene alone, and AtWUS gene fused to the GFP marker were compared to the GFP gene alone and to an empty construct used as a control. Somatic embryogenesis was improved in WUS expressed calli, as the percentage of explants giving rise to embryogenic tissues was significantly higher (×3) when WUS gene was over-expressed than in the control. An interesting result was that WUS embryogenic lines evolved in green embryo-like structures giving rise to ectopic organogenesis never observed in any of our previous transformation experiments. Using our standard in vitro culture protocol, the overexpression of AtWUS in tissues of a recalcitrant variety did not result in the production of regenerated plants. This achievement will still require the optimization of other non-genetic factors, such as the balance of exogenous phytohormones. However, our results suggest that targeted expression of the WUS gene is a promising strategy to improve gene transfer in recalcitrant cotton cultivars.

Towards deciphering phloem: a transcriptome analysis of the phloem of Apium graveolens.

Events occurring in the phloem tissue are key to understanding a wide range of developmental and physiological processes in vascular plants. While a considerable amount of molecular information on phloem proteins has emerged in the past decade, a unified picture of the molecular mechanisms involved in phloem differentiation and function is still lacking. New models to increase our understanding of this complex tissue can be created by the development of global approaches such as genomic analysis. In order to obtain a comprehensive overview of the molecular biology of the phloem tissue, we developed a genomic approach using Apium graveolens as a model. cDNA libraries were constructed from mRNAs extracted from isolated phloem of petioles. Expression data obtained from the analysis of 989 expressed sequence tags (ESTs) and the transcript profile deduced from a cDNA macroarray of 1326 clones were combined to identify genes showing distinct expression patterns in the vascular tissues. Comparisons of expression profiles obtained from the phloem, xylem and storage parenchyma tissues uncovered tissue-specific differential expression patterns for given sets of genes. The major classes of mRNAs predominantly found in the phloem encode proteins related to phloem structure, metal homeostasis or distribution, stress responses and degradation or turnover of proteins. Of great interest for future studies are the genes we found to be specifically expressed in the phloem but for which the function is still unknown, and also those genes described in previous reports to be up or downregulated by specific interactions. From a broader prospective, our results also clearly demonstrate that cDNA macroarray technology can be used to identify the key genes involved in various physiological and developmental processes in the phloem.

Modified development in transgenic tobacco plants expressing a rolA::GUS translational fusion and subcellular localization of the fusion protein.

The rolA gene is transferred naturally by Agrobacterium rhizogenes to the genome of host plants, where it induces dramatic changes in development of transformed plants, including dwarfism and leaf wrinkling. The predicted translation product of the rolA gene is a small (11.4 kDa), basic (pI = 11.2) protein, which has no clearly significant similarity to sequences in the data bases. We have introduced into the tobacco genome a gene encoding a rolA::GUS fusion protein. Expression of this gene led to synthesis of an RNA and a protein of expected size, and the transformed plants exhibited the dwarfism and leaf wrinkling typical of rolA plants, but to a lesser degree than plants transformed with the wild-type rolA gene. The distribution of beta-glucuronidase (GUS) activity was compared in subcellular fractions of leaf extracts from plants expressing either the rolA::gus gene or a control gus construct. As expected, in the control plants, GUS activity was essentially cytosolic. In contrast, in plants expressing the rolA::gus gene the highest specific activity was associated with the plasmalemma fraction.

Synthesis of full-length potyvirus cDNA copies suitable for the analysis of genome polymorphism.

New methods facilitating the synthesis and amplification of full-length cDNA copies of single-stranded viral RNA genomes have been developed. A method is described for the efficient purification of potyviral RNA and total RNA from infected plants and it is shown that they can serve as templates for the efficient synthesis of a full-length, 10 kb long, genomic cDNA. Two different reverse transcriptases were used (AMV-RT and MMLV-RT); only the first reverse transcriptase produced a good quality, full-length cDNA using viral RNA as a template. Surprisingly, MMLV-RT allowed for the full-length cDNA synthesis on virions rather than viral RNA. The PVY cDNA, synthesized using either RNA or virions, can be amplified successfully by PCR with high yields of full-length products. Such products are good substrates for the study by RFLP of the total genome polymorphism of virus isolates.

Cell-free cloning and biolistic inoculation of an infectious cDNA of potato virus Y.

Potato virus Y (PVY) full-length cDNA has been found to be refractory to cloning in Escherichia coli cells. A full-length 9.7 kb PVY cDNA was obtained by reverse transcription polymerase chain reaction (RT-PCR) from the RNA of PVY (tuber necrotic strain, PVYNTN). Double-stranded DNA fragments were used as primers (ds megaprimers), to include signals for transcription in vivo (a cauliflower mosaic virus 35S RNA promoter and a nopaline synthase terminator) in the final PCR product. Biolistic bombardment with a helium particle gun was used to inoculate the amplified product to detached tobacco leaves. Inoculation of tobacco plants with ground inoculated leaves followed by northern blot, ELISA and immuno-electron microscopy demonstrated that the DNA was highly infectious with up to 90% of bombarded leaves containing the virus. This methodology will allow the use of reverse genetics in the study of PVY-plant interactions and will also be useful for obtaining infectious cDNA from other viruses with large RNA genomes.

Tissue-specific expression of the rolA gene mediates morphological changes in transgenic tobacco.

The spatial and temporal activity of the entire and individual promoter domains of the rolA gene of Agrobacterium rhizogenes was investigated and correlated with the distinctive features of the phenotypes of transgenic tobacco plants. The GUS assay was performed in the presence of an oxidative catalyst during the development of transgenic plants expressing chimeric genes containing the beta-glucuronidase coding sequence under the control of the different promoter domains. In situ hybridization was also used on transgenic plants harbouring rolA under the control of the entire or deleted promoter. This paper demonstrates for the first time that the entire rolA promoter, composed of domains, A, B and C, is silent in seeds, then activated at the onset of germination in the cotyledons and in the elongation zone of the radicle and is finally expressed throughout the vegetative and floral phases. Domains B + C, which were sufficient to induce wrinkled leaves and short internodes, were active in all the stem tissues, but only in the companion cells of the phloem strands of the leaves. Domain C, which specified a dwarf phenotype with normal leaves, was weakly expressed in the stem vascular bundles and in the leaf internal phloem. These results indicate that the vascular bundles are the primary targets for the generation of the short internode phenotype. Furthermore, the local expression of rolA in the stem vascular bundles induced a size reduction of the surrounding parenchyma cells, suggesting the existence of some diffusible factor(s) associated with the expression of the rolA gene.

Differential expression of the rolA plant oncogene and its effect on tobacco development.

The rolA gene not only provokes the abnormal traits of wrinkled leaves, shortened internodes, and deficient root growth in tobacco, but also induction of roots in leaf disks in hormone-free medium. The rolA mRNA is most abundant in the stem of transgenic tobacco, accumulating at fivefold and 50-fold lower levels in the leaf and the root, respectively. Promoter deletion mutants were constructed and the rolA-induced abnormal traits were exploited to identify promoter regulatory regions. The removal of specific promoter domains provokes the appearance of new patterns of rolA transcripts in leaves, stems and roots. These new patterns are correlated with the disappearance of specific abnormal trait, thereby identifying three functional domains. Domain A includes a mosaic motif composed of a putative GT-2 binding site and DUE-NDE elements. This domain positively regulates rolA gene expression in the leaf and negatively regulates it in the stem and root. Domains B and C, which contain sequences homologous to the OCS enhancer and to ASF-1 binding sites, respectively, generally activate the rolA gene expression in all tissues. The possible function of these elements on the regulation of the rolA gene is discussed.

Inhibition of tobacco nitrite reductase activity by expression of antisense RNA.

A tobacco nitrite reductase (NiR) cDNA and its corresponding gene were isolated from cDNA and genomic libraries. An NiR antisense mRNA was expressed in transgenic tobacco under the control of a double 35S promoter. Transformants were obtained on a medium containing ammonium as the sole source of nitrogen. One plant growing normally on ammonium but displaying drastically reduced development and chlorotic leaves when grown on nitrate as the sole source of nitrogen was studied further. This plant accumulated nitrite fivefold over wild-type level and showed reduced amounts of ammonium (11% wild-type level), glutamine (19%), and total protein (8%). NiR mRNA and activity were below detectable levels. Under these conditions, nitrate reductase (NR) activity and mRNA were overexpressed, suggesting that N-metabolites resulting from nitrate reduction are responsible for the repression of the expression of the NR gene, independently from the presence or absence of a functional NR protein.

rol A modulates the sensitivity to auxin of the proton translocation catalyzed by the plasma membrane H(+)-ATPase in transformed tobacco.

In order to investigate the effect of the rol A gene product on the plasma membrane response to auxin, a clone of rol A-transformed tobacco was prepared. Auxin sensitivity was measured by the auxin concentration which induced the highest stimulation of H(+)-ATPase-mediated proton translocation on isolated plasma membrane vesicles. Both transformed and control plants exhibited identical auxin-sensitivity changes during vegetative and induction to flowering periods. However the sensitivity of flowering-transformed plants was 100-times higher than that of control plants. Consistent observations were also made when using rol A+B+C-transformed plants. These results suggest that the rol A gene product could either participate in or affect the reception/transduction pathway of auxin signal at the plasma membrane.

Expression vectors based on the Agrobacterium rhizogenes Ri plasmid transformation system.

This article describes several new expression vectors that capitalize on the ability of Agrobacterium rhizogenes to transfer DNA from its Ri plasmid to the plant nuclear genome. The intermediate vectors described include an expression cassette based on one of the three following promoters: the nopaline synthase promoter, or the cauliflower mosaic virus (CaMV) promoters responsible for transcription of either the 19S or 35S CaMV RNA. The termination and polyadenylation signals are either from the nopaline synthase gene or from CaMV. The expression micro-Ri plasmid described bears a selectable marker gene and an expression cassette cloned between the borders of the TL-region of the Ri plasmid of A. rhizogenes A4. Different strategies for using these vectors to introduce chimeric genes into plants are described, and the advantages and disadvantages of the two types of vectors are discussed.

A new vector derived from Agrobacterium rhizogenes plasmids: a micro-Ri plasmid and its use to construct a mini-Ri plasmid.

A new binary vector system has been constructed, based on agropine-type root-inducing plasmid (pRi) left transferred-region border sequences cloned in a plasmid containing the replication origin of another A. rhizogenes plasmid (pArA4a). This micro-pRi has been used to introduce a chimeric kanamycin resistance gene into tobacco plants, vir functions being provided by either octopine or nopaline tumor-inducing plasmids deleted of their own transferred regions. In addition, we show that cloning of pRi EcoRI fragment 15, which contains three open reading frames (which may correspond to loci rolA, B and C), in the micro-Ri vector generates a mini-pRi capable of inducing the proliferation of transformed roots.

A DNA sequence from Dictyostelium discoideum complements ura3 and ura5 mutations of Saccharomyces cerevisiae.

A 3.7 kilobase fragment of Dictyostelium discoideum genomic DNA has been cloned by its ability to complement a yeast ura3 mutation affecting the activity of orotidine-5'-phosphate carboxy-lyase (EC 4.1.1.23). This fragment also complements a yeast ura5 mutation that leads to a defect in orotate phosphoribosyl transferase (EC 2.4.2.10). The orotidine-5'-phosphate carboxy-lyase and the orotate phosphoribosyl transferase activities that result from Dictyostelium gene expression in yeast have been detected. The size of the DNA required for both complementations has been localised to a segment of less than 2 kb. A unique Dictyostelium RNA species of 1,600 base pairs hybridizes to this fragment. In vitro deletions in this fragment lead to the simultaneous loss of the two activities. The two enzymatic activities coelute as a protein of 120,000 daltons during gel filtration of a Dictyostelium extract. These results favour the existence, on the cloned Dictyostelium DNA fragment, of a unique structural gene which codes for a bifunctional enzyme carrying the two activities, orotidine-5'-phosphate carboxy-lyase and orotate phosphoribosyl transferase.