Transgenic tobacco plants regenerated from leaf disks can be periclinal chimeras

Amongst rolC transgenic tobacco plants regenerated from leaf disks 6.5% are periclinal chimeras, i.e. plants with genetically different cell populations in different cell layers. The expression of the rolC gene of Agrobacterium rhizogenes causes a reduction in pigment content in leaves. The chimeric composition of the regenerated plants becomes thus apparent as light green leaf tissue in the transgenic region, tissue flanked by dark green wild-type sectors. Southern and northern blot analysis confirmed the chimeric nature of such plants. Investigation of selfed progeny of chimeric plants on selective media indicates that layer invasion in reproductive tissues can occur in tobacco early during the formation of the flower buds. The results show (1) that tobacco plants regenerated from leaf disks and grown on selective media have not necessarily the same clonal origin and (2) that they can give rise to non-transgenic offspring. The chimeric plants provide insight on the effect of rolC gene expression on microsporogenesis.     

Cytosolic localization in transgenic plants of therolC peptide fromAgrobacterium rhizogenes

TherolC gene ofAgrobacterium rhizogenes codes for a peptide with an apparent molecular weight of approximately 20 kDa. Immunolocalization of therolC peptide, in leaves of transgenic plants which are genetic mosaics for the expression of therolC gene, is restricted to the phenotypically altered sectors. Subcellular fractionation of homogenates from 35S-rolC transgenic leaves shows the cytosolic localization of therolC peptide.     

Promotion of flowering and morphological alterations in Atropa belladonna transformed with a CaMV 35S-rolC chimeric gene of the Ri plasmid

Summary Kanamycin-resistant plants of belladonna (Atropa belladonna) were obtained after Agrobacterium mediated transformation. When a rolC gene, which is one of the loci located on Ri plasmid of Agrobacterium rhizogenes, was co-introduced with a kanamycin resistant (NPT II) gene under control of a cauliflower mosaic virus 35S promoter, the rolC gene was expressed strongly in leaves, flowers, stems and roots. The transformed plants exhibited dramatic promotion of flowering, reduced apical dominance, pale and lanceolated leaves and smaller flowers. On the other hand, when native rolC gene was co-introduced with NPT II, the transgenic plants obtained did not exhibit the altered phenotypes observed in 35S-rolC transformants, and the expression level of the rolC gene was much lower than in 35S-rolC transformants. These results suggest that the morphological changes in transgenic Atropa belladonna were related to the degree of expression of the rolC gene.Abbreviations native rolC rolC gene under control of its own promoter - 35S-rolC rolC gene under control of a cauliflower mosaic viras 35S promoter     

Promoter of the rolC gene of Agrobacterium rhizogenes can be strongly regulated in glandular cell of transgenic tobacco

A 577-bp promoter segment of Agrobacterium rhizogenes rolC, previously known as the phloem-specific gene expression promoter, was fused to the 5′ end of a reporter gene, β-glucuronidase (GUS), uidA. This rolC-promoter-driven expression of the GUS gene was found to be significantly strong in glandular cells in transgenic tobacco plants. Analysis of this segment of the promoter sequence revealed a myb response element.     

The pleiotropic effects induced by therolC gene in transgenic plants are caused by expression restricted to protophloem and companion cells

Expression of therolC gene fromAgrobacterium rhizogenes causes morphological and developmental alterations in transgenic plants. The histological alterations underlying the macroscopic changes and the cellular localization of the site of expression of therolC gene have shown that: (i) the expression of therolC gene is developmentally regulated, (ii) in vegetative transgenic plants, the expression of therolC gene under the control of its own promoter is restricted to companion and protophloem cells, (iii) the site of action of the product(s) of the activity of the rolC enzyme is distinct from its site of expression, (iv) precise localization of the rolC peptide has been achieved by immunocytochemistry but not by the histochemical GUS assay. These results imply that the sites of action and expression of therolC gene in trangenic plants are physically separated. Thus the product(s) of the activity of the rolC enzyme must be a factor capable of being transported. Current models forrolC gene action are discussed taking into account the reported results.     

FLP/FRT-mediated restoration of normal phenotypes and clonal sectors formation in rolC transgenic tobacco

Site-specific recombination systems have been shown to excise transgene DNA sequences positioned between their cognate target sites, and thus be used to generate clonal sectors in transgenic plants. Here we characterized clonal sectors derived from genetic reversion of rolC (A. rhizogenes) – induced vegetative and reproductive phenotypes, mediated by FLP recombinase from S. cerevisiae, in tobacco. The constitutive expression of rolC induces pleiotropic effects including reduced apical dominance and plant height, lanceolate and pale green leaves and small, male-sterile flowers. Two transgenic male-sterile tobacco lines (N. tabacum, Samsun NN) expressing a 35sP-rolC gene construct flanked by two FRT (FLP recombinase target) sites, were cross-pollinated with pollen from a constitutive 35sP-FLP expressing line. Three main phenotypes were generated in result of recombinase-mediated excision of the 35sP-rolC locus in the F₁ (FLP×FRT-35sP-rolC-FRT) hybrid progenies: (a) restoration of male fertility, associated with reversion to normal leaf phenotypes prior to flower bud formation, (b) development of normal and fertile lateral shoot sectors on the background of rolC-type plants, (c) restoration of partially fertile flowers, associated with display of peripheral normal leaf sectors surrounding rolC-type inner-leaf tissues, consistent with periclinal chimeras. These results, supported by DNA molecular analysis, indicate that site-specific recombination might be used as a relatively efficient tool for generation of transgenic periclinal chimeric plants.     

Nucleotide substitutions in <Emphasis Type="Italic">rolC</Emphasis> and <Emphasis Type="Italic">nptII</Emphasis> gene sequences during long-term cultivation of <Emphasis Type="Italic">Panax ginseng</Emphasis> cell cultures

It has been shown previously that the rolC gene from Agrobacterium tumefaciens gene was stably and highly expressed in 15-year-old Panax ginseng transgenic cell cultures. In the present report, we analyze in detail the nucleotide composition of the rolC and nptII (neomycin phosphotransferase) genes, which is the selective marker used for transgenic cell cultures of P. ginseng. It has been established that the nucleotide sequences of the rolC and nptII genes underwent mutagenesis during cultivation. Particularly, 1–4 nucleotide substitutions were found per sequence in the 540 and 798 bp segments of the complete rolC and nptII genes, respectively. Approximately half of these nucleotide substitutions caused changes in the structure of the predicted gene product. In addition, we attempted to determine the rate of accumulation of these changes by comparison of DNA extracted from P. ginseng cell cultures from 1995 to 2007. It was observed that the frequency of nucleotide substitutions for the rolC and nptII genes in 1995 was 1.21 ± 0.02 per 1,000 nucleotides analyzed, while in 2007, the nucleotide substitutions significantly increased (1.37 ± 0.07 per 1,000 nucleotides analyzed). Analyzing the nucleotide substitutions, we found that substitution to G or to C nucleotides significantly increased (in 1.9 times) in the rolC and nptII genes compared with P. ginseng actin gene. Finally, the level of nucleotide substitutions in the rolC gene was 1.1-fold higher when compared with the nptII gene. Thus, for the first time, we have experimentally demonstrated the level of nucleotide substitutions in transferred genes in transgenic plant cell cultures.     

ROLC strawberry plant adaptability, productivity, and tolerance to soil-borne disease and mycorrhizal interactions

The potential to improve strawberry cultivation was assessed regarding the use the rolC genes from Agrobacterium rhizogenes that can confer higher levels of free cytokinins. Strawberry (cv. Calypso) rolC lines were produced by genetic transformation of Agrobacterium tumefaciens. Yield and fruit quality of the control and transgenic lines were measured under open-field conditions. The effects of the transgenic rolC lines depended on gene copy number: rolC lines with one (Line A) or two gene (Line B) copies showed 30% greater yields than controls, due to 20% more fruit per plant and an increased fruit weight. Line A also differed in terms of the highest fruit quality, due to 10.5% increased soluble solids and 12.7% higher acidity. Moreover, cv. Calypso rolC lines A and B had increased tolerance to greenhouse infection by Phytophthora cactorum. Conversely, for all of these characters, Line F (five rolC copies) was not significantly different from the control line. The same lines were also used to examine their symbiosis with root arbuscular mycorrhizal fungi (AMF) using vital and non-vital staining of roots collected at different stages of plant growth. Control and rolC plants showed similar intensities of AMF infection according to plant phenology and/or physiology. Furthermore, possible horizontal gene transfer of the rolC gene was tested for the AMF spores by PCR, with all AMF samples negative using rolC primers. The use of the rolC gene should be considered for the improvements provided in productivity, fruit quality and disease resistance of cultivated strawberry that show no effects on soil microorganisms.     

Sequence of the cellular T-DNA in the untransformed genome of Nicotiana glauca that is homologous to ORFs 13 and 14 of the Ri plasmid and analysis of its expression in genetic tumors of N. glauca x N. langsdorffii

A region homologous to the TL-DNA of Agrobacterium rhizogenes was previously detected in the genome of untransformed Nicotiana glauca and designated cellular T-DNA (cT-DNA). Subsequently, part of this region was sequenced and two genes, which corresponded to rolB and rolC and were named NgrolB and NgrolC, were found. We have now sequenced a region of the cT-DNA other than the region that includes NgrolB and C and we have found two other open reading frames (ORFs), NgORF13 and NgORF14. These ORFs correspond to ORFs 13 and 14 of the TL-DNA of A. rhizogenes and exhibit a high degree of homology to these ORFs, without having a nonsense codon. We have not found any sequence homologous to rolD (ORF15). The two genes, NgORF13 and 14, as well as the NgrolB and C genes, are expressed in genetic tumors of hybrids between N. glauca and N. langsdorffii but not in leaf tissues of the hybrid.     

Molecular characterization of rgp2, a gene encoding a small GTP-binding protein from rice

Summary We previously reported the isolation of rgp1, a gene from rice, which encodes a ras-related GTP-binding protein, and subsequently showed that the gene induces specific morphological changes in transgenic tobacco plants. Here, we report the isolation and characterization of an rgp1 homologue, rgp2, from rice. The deduced rgp2 protein sequence shows 53% identity with the rice rgp1 protein, but 63% identity with both the marine ray ora3 protein, which is closely associated with synaptic vesicles of neuronal tissue, and the mammalian rab11 protein. Conservation of particular amino acid sequence motifs places rgp2 in the rab/ypt subfamily, which has been implicated in vesicular transport. Northern blot analysis of rgp1 and rgp2 suggests that both genes show relatively high, but differential, levels of expression in leaves, stems and panicles, but low levels in roots. In addition, whereas rgp1 shows maximal expression at a particular stage of plantlet growth, rgp2 is constitutively expressed during the same period. Southern blot analysis suggests that, in addition to rgp1 and rgp2, several other homologues exist in rice and these may constitute a small multigene family.     

Expression of a stilbene synthase gene in Nicotiana tabacum results in synthesis of the phytoalexin resveratrol

A gene from groundnut (Arachis hypogaea) coding for stilbene synthase was transferred together with a chimaeric kanamycin resistance gene. It was found to be rapidly expressed after induction with UV light and elicitor in tobacco cells (Nicotiana tabacum). Comparative studies of stilbene synthase mRNA synthesis in groudnut and transgenic tobacco suspension cultures revealed the same kinetics of gene expression. Stilbene synthase specific mRNA was detectable 30 minutes after elicitor induction and 10 minutes after UV irradiation. The maximum of mRNA accumulation was between 2 and 8 hours post induction. 24 hours after induction stilbene synthase mRNA accumulation ceased. Furthermore, in transgenic tobacco plants, the gene was found to be inducible in sterile roots, stems and leaves. Stilbene synthase was demonstrated in crude protein extracts from transgenic tobacco cell cultures using specific antibodies. Resveratrol, the product of stilbene synthase, was identified by HPLC and antisera raised against resveratrol.     

Genetic transformation through the use of hyperhydric tobacco meristems

Exposed shoot meristems from normal and hyperhydric (vitrified) tobacco, Nicotiana tabacum, were bombarded with gold particles either coated with plasmid DNA containing neomycin phosphotransferase (NPTII), rolC and -glucuronidase (GUS) genes (plasmid pGA-GUSGFrolC) or left uncoated. Meristems bombarded with uncoated particles were co-cultivated with Agrobacterium tumefaciens strain EHA 101 harboring the binary vector pGA-GUSGFrolC. Whole-plant transformants were produced from 4 of 40 hyperhydric meristems bombarded with uncoated particles followed by co-cultivation with A. tumefaciens. One transgenic plant was obtained from 40 normal, non-hyperhydric meristems treated. Transformation was verified by growth on kanamycin-containing medium, GUS assays, PCR, and Southern analysis. The plants tested through Southern analysis appeared to have 2 or more copies of the transgene insert. Seeds obtained from self-pollination of these transgenic plants segregated 3:1 or 15:1 (kanamycin resistant:sensitive) when germinated on medium containing 100 mg/l kanamycin, indicating transfer of foreign genes through the sexual cycle. Whole-plant transformants were not produced from 50 normal tobacco meristems bombarded with plasmid-coated gold particles and not exposed to engineered A. tumefaciens, but 1 plant of 60 bombarded hyperhydric meristems produced transgenic roots, the result of a chimera. We suggest that hyperhydric meristems are more readily transformed.     

Characterization of hairy root-phenotype in transgenic <Emphasis Type="Italic">Hypericum perforatum</Emphasis> L. clones

Hairy root-regenerated clones of Hypericum perforatum L. grown in vitro similarly to those successfully adapted to ex vitro conditions showed phenotype features typical for plants transformed with Agrobacterium rhizogenes T-DNA. These included reduced apical dominance, increased branching, dwarfing and reduced fertility. Transgenic clones differed in ability to develop root system as a necessary condition for transfer to the soil. One of the profiling characters, capability of hypericin biosynthesis was altered as well. Dark glands as the sites of hypericin accumulation and/or synthesis exhibited significantly higher densities on both, leaves and petals of transgenic clones comparing to controls. In the genome of transgenic clones, rolABC genes were detected. Both clones harboured similar copy number of individual rol genes. However, copy numbers descended from rolA to rolC gene in both clones.     

Resveratrol content and expression of phenylalanine ammonia-lyase and stilbene synthase genes in rolC transgenic cell cultures of Vitis amurensis

Resveratrol, a naturally occurring polyphenol, has been reported to exhibit a wide range of valuable biological and pharmacological properties. In the present investigation, we show that transformation of Vitis amurensis Rupr. with the oncogene rolC of Agrobacterium rhizogenes increased resveratrol production in the two transformed callus cultures 3.7 and 11.9 times. The rolC-transformed calli were capable of producing 0.099% and 0.144% dry weight of resveratrol. We characterized phenylalanine ammonia-lyase (PAL) and stilbene synthase (STS) gene expression in the two rolC transgenic callus cultures of V. amurensis. In the rolC transgenic culture with higher resveratrol content, expression of VaPAL3, VaSTS3, VaSTS4, VaSTS5, VaSTS6, VaSTS8, VaSTS9, and VaSTS10 was increased; while in the rolC culture with lower resveratrol content, expression of VaPAL3 and VaSTS9 was increased. We suggest that transformation of V. amurensis calli with the rolС gene induced resveratrol accumulation via selective enhancement of expression of individual PAL and STS genes involved in resveratrol biosynthesis. We compared the data on PAL and STS gene expression in rolC transgenic calli with the previously obtained results for rolB transgenic calli of V. amurensis. We propose that the transformation of V. amurensis with the rolC and rolB genes of A. rhizogenes increased resveratrol accumulation through different regulatory pathways.     

Inhibitory effect of the Agrobacterium rhizogenes rolC gene on rabdosiin and rosmarinic acid production in Eritrichium sericeum and Lithospermum erythrorhizon transformed cell cultures

Rabdosiin and related caffeic acid metabolites have been proposed as active pharmacological agents demonstrating potent anti-HIV and antiallergic activities. We transformed Eritrichium sericeum and Lithospermum erythrorhizon seedlings by the rolC gene, which has been recently described as an activator of plant secondary metabolism. Surprisingly, the rolC-transformed cell cultures of both plants yielded two- to threefold less levels of rabdosiin and rosmarinic acid (RA) than respective control cultures. This result establishes an interesting precedent when the secondary metabolites are differently regulated by a single gene. We show that the rolC gene affects production of rabdosiin and RA irrespective of the methyl jasmonate (MeJA)-mediated and the Ca²⁺-dependent NADPH oxidase pathways. Cantharidin, an inhibitor of serine/threonine phosphatases, partly diminishes the rolC-gene inhibitory effect that indicates involvement of the rolC-gene-mediated signal in plant regulatory controls, mediated by protein phosphatases. We also show that the control MeJA-stimulated E. sericeum root culture produces (–)-rabdosiin up to 3.41% dry weight, representing the highest level of this substance for plant cell cultures reported so far.