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.     

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     

Transgene Expression in the Vegetative Tissues of Apple Driven by the Vascular-specific rolC and CoYMV Promoters

The ability of the heterologous promoters, rolCP and CoYMVP, to drive expression of the gusA reporter gene in the vegetative tissues of apple (Malus pumila Mill.) has been studied using transgenic plants produced by Agrobacterium-mediated transformation. Replicate plants of each transgenic clone were propagated in soil to a uniform size and samples of leaf, petiole, stem, and root were taken for the measurement of -glucuronidase (GUS) activity by fluorometric assay. The levels of expression were compared with those in tissues of a representative clone containing the CaMV 35S promoter. These quantitative GUS data were related to the copy number of transgene loci assessed by Southern blotting. The CoYMV promoter was slightly more active than the rolC promoter, although both expressed gusA at a lower level than the CaMV 35S promoter. In clones containing the rolC promoter with multiple transgene loci, expression values were generally among the highest or lowest in the range. The precise location of GUS activity in each tissue was identified by staining of whole leaves and tissue sections with a chromogenic substrate. This analysis demonstrated that with both the rolC and CoYMV promoters the reporter gene activity was primarily localised to vascular tissues, particularly the phloem. Our results indicate that both promoters would be suitable to drive the expression of transgenes to combat pests and diseases of apple that are dependent on interaction with the phloem.     

The Agrobacterium rhizogenes rolB and rolC promoters are expressed in pericycle cells competent to serve as root initials in transgenic hybrid aspen

Expression of the Agrobacterium rhizogenes rolB and rolC promoters was studied in transgenic hybrid aspen ( Populus tremula L. × P. tremuloides Michx.) lines containing a chimeric fusion of either the rolB or the rolC promoter and the reporter gene uidA . The resultant GUS activity was monitored by histochemical analysis in aerial tissues as well as in developing roots. Both the rolC and rolB promoters were shown to be expressed in the phloem and in the root tips, which is similar to the expression pattern previously described for annual plants. However, a strong expression of the rolB promoter in the rays of the phloem and the cambial zone of the stem, and of the rolC promoter in groups of pericycle cells prior to and during lateral root initiation was unique for hybrid aspen. In both stem and root tissues, the expression of the rolB and rolC promoters was localised primarily in a subset of cells competent to form adventitious or lateral roots, suggesting that these cells might serve as the target for A. rhizogencs infection. The biological significance of the cell-specific rol gene expression in establishing the hairy root disease is discussed.     

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.     

Surrogate transformation of perennial ryegrass, Lolium perenne, using genetically modified Acremonium endophyte.

Summary Conditions have been developed for transforming protoplasts of the perennial ryegrass endophyteAcremonium strain 187BB. Unlike most other ryegrass endophytes, this strain does not produce the lolitrem B neurotoxin and is therefore suitable as a host for surrogate introduction of foreign genes into grasses. Transformation frequencies of 700–800 transformants/g DNA were obtained for both linear and circular forms of pAN7-1, a hygromycin (hph) resistant plasmid. Up to 80% of the linear transformants were stable on further culturing but only 25% of the circular transformants retained hygromycin resistance. Integration of pAN7-1 into the genome was confirmed by Southern blotting and probing of genomic digests of transformant DNA. Both single and tandemly repeated copies of the plasmid were found in the genome and both the number and sites of integration varied among the transformants. At least 13 chromosomes were identified in 187BB using contour-clamped homogeneous electric field (CHEF) gel electrophoresis. Probing of Southern blots of these gels confirmed that pAN7-1 had integrated into different chromosomes. The -glucuronidase (GUS) gene,uidA, was also introduced into 187BB by co-transformation of pNOM-2 with pAN7-1. GUS activity was detected by growing the transformants on plates containing 5-bromo-4-chloro-3-indolyl -D-glucuronic acid and by enzyme assays of mycelial extracts. Severalhph- anduidA-containing transformants were reintroduced into ryegrass seedlings and expression of GUS visualized in vivo, demonstrating that 187BB can be used as a surrogate host to introduce foreign genes into perennial ryegrass. Molecular analysis of fungal isolates from the leaf sheath confirmed that the pattern of pAN7-1 and pNOM-2 hybridizing fragments was identical to that observed in the fungus used as inoculum.     

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 Brassica napus extA promoter: a novel alternative promoter to CaMV 35S for directing transgene expression to young stem tissues and load bearing regions of transgenic apple trees (Malus pumila Mill.)

The Brassica napus extensin A gene is highly expressed in root tissue of oilseed rape. In an attempt to identify an effective root-specific promoter for biotechnological applications, we have examined the ability of the –940 extA promoter to drive expression of the gusA reporter gene in the vegetative tissues of apple (Malus pumila Mill cv. Greensleeves). Transgenic apple lines were produced by Agrobacterium tumefaciens-mediated transformation and GUS activity was analysed both quantitatively and qualitatively. The extA promoter was active in all tissues of young plants in all 15 clones examined. However Southern blot data suggested that only a proportion of the population contained the entire promoter and that others had suffered deletions of unknown length. This may have contributed to the variation seen in the quantitative and qualitative expression of GUS. Specific GUS activity was highest in the stems where it approached, and in some clones, exceeded that using the constitutive CaMV 35S promoter. Histochemical analysis confirmed that GUS was localised to tissues involved in structural support of the stem. Staining was particularly intense at nodal junctions where high tensile stress is exerted on the tissues. Maturing phloem tissues showed localisation of expression to the phloem parenchyma cells and phloem fibres. Transverse sections of the root revealed staining of primary procambial tissues including the young endodermis but no staining was seen in the cortex. Although the –940 extA promoter is clearly not root-specific in apple, it is likely to have useful biotechnological applications in tree species.     

Effect of an enhanced CaMV 35S promoter and a fruit-specific promoter on uida gene expression in transgenic tomato plants

Summary Two different promoters, a cauliflower mosaic virus (CaMV) 35S promoter with a 5′-untranslated leader sequence from alfalfa mosaic virus RNA4 (designated as CaMV 35S/AMV) and an E-8 fruit-ripening-specific promoter, were compared to evaluate their effects on expression of the uidA reporter gene in transgenic tomato plants. In order to generate sufficient numbers of transgenic tomato plants, both a reliable regeneration system and an efficient Agrobacterium transformation protocol were developed using 8-d-old cotyledons of tomato (Lycopersicon ecsulentum Mill. cv. Swifty Belle). Two sets of constructs, both derivatives of the binary vector pBI121, were used in transformation of tomato whereby the uidA gene was driven either by the CaMV 35S/AMV or the E-8 fruit-ripening-specific promoter. Southern blot hybridization confirmed the stable integration of the chimeric uidA gene into the tomato genome. Fruit and leaf tissues were collected from T₀ and T₁ plants, and assayed for β-glucuronidase (GUS) enzyme activity. As expected, both vegetative and fruit tissues of transgenic plants carrying the uidA gene under the control of CaMV 35S/AMV showed varying levels of GUS activity, while no expression was observed in vegetative tissues of transgenic plants carrying the uidA gene driven by the E-8 promoter. All fruits from transgenic plants produced with both sets of constructs displayed expression of the uidA gene. However, when this reporter gene was driven by the CaMV 35S/AMV, GUS activity levels were significantly higher than when it was driven by the E-8 fruit-specific promoter. The presence/absence of the uidA gene in T₁ plants segregated in a 3∶1 Mendelian ratio.     

Activity of a maize ubiquitin promoter in transgenic rice

We have used the maize ubiquitin 1 promoter, first exon and first intron (UBI) for rice (Oryza sativa L. cv. Taipei 309) transformation experiments and studied its expression in transgenic calli and plants. UBI directed significantly higher levels of transient gene expression than other promoter/intron combinations used for rice transformation. We exploited these high levels of expression to identify stable transformants obtained from callus-derived protoplasts co-transfected with two chimeric genes. The genes consisted of UBI fused to the coding regions of the uidA and bar marker genes (UBI:GUS and UBI:BAR). UBI:GUS expression increased in response to thermal stress in both transfected protoplasts and transgenic rice calli. Histochemical localization of GUS activity revealed that UBI was most active in rapidly dividing cells. This promoter is expressed in many, but not all, rice tissues and undergoes important changes in activity during the development of transgenic rice plants.     

Antisense inhibition of the sucrose transporter in potato: effects on amount and activity

The sucrose proton-cotransporter gene from potato (StSUT1) is mainly expressed in the phloem of mature, exporting leaves. To study the in vivo role of the protein, potato plants were transformed with antisense constructs of the sucrose transporter cDNA under control of the CaMV35S and the rolC promoters, respectively. Both types of transgenic plant develop symptoms characteristic of an inhibition of phloem loading. To determine the level of inhibition, immunological and transport studies were performed. Purified antibodies directed against a peptide from the central loop of SUT1 recognized a transporter with an apparent molecular mass of 47 kDa in leaf plasma membrane vesicles. Antisense repression under control of the non-specific CaMV35S promoter led to a strong reduction in SUT1 protein, whereas no such reduction could be detected when the companion cell-specific rolC promoter was used. Similarily. sucrose uptake in plasma membrane vesicles was reduced by 50–75% in CaMV35S but not in rolC plants. These data suggest that, unlike the rolC promoter, the sucrose transporter is expressed not only in the companion cells but also in other leaf cells. However, inhibition of the transporter by rolC-controlled antisense repression is sufficient to impair phloem loading.     

A simple and efficient gene transfer system of trifoliate orange (Poncirus trifoliata Raf.)

Summary A simple and efficient gene transfer system of trifoliate orange (Poncirus trifoliata Raf.) was developed using epicotyl segments. The segments were infected with Agrobacterium harboring the binary vector pBI121 or pBI101-O12-p1. Both vectors contained the neomycin phosphotransferase II (NPTII) and the -glucuronidase (GUS) genes. In the plasmid pBI101-O12-p1, the GUS gene was directed to the promoter region of ORF12 (rolC) of the Ri plasmid. On a selection medium containing 100 or 200 g/ml kanamycin, adventitious shoots were formed from 21.7–44.6% of the segments. Histochemical GUS assay showed that 55.4–87.7% of the shoots expressed the GUS gene. The stable integration of this gene was also confirmed by polymerase chain reaction (PCR) analysis and by Southern blot analysis. When the pBI101-O12-p1 plasmid was used, the GUS activity was found to be located in phloem cells of leaf, stem and root. More than 100 transformed plants were obtained using this method within 2–3 months.     

Evaluation in tobacco of the organ specificity and strength of therolD promoter,domain A of the 35S promoter and the 35S2 promoter

In order to study the expression in plants of therolD promoter ofAgrobacterium rhizogenes, we have constructed chimaeric genes placing the coding region of thegusA (uidA) marker gene under control of tworolD promoter fragments of different length. Similar results were obtained with both genes. Expression studies were carried out in transformed R₁ progeny plants. In mature transformed tobacco plants, therolD-gus genes were expressed strongly in roots, and to much lower levels in stems and leaves. This pattern of expression was transmitted to progeny, though the ratio of the level of expression in roots relative to that in leaves was much lower in young seedlings. The degree of root specificity inrolD-gus transformants was less than that of a gene constructed with domain A of the CaMV 35S promoter,domA-gus, but the level of root expression was much higher than with the latter gene. However, the level of expression of therolD-gus genes was less than that of agus gene with a 35S promoter with doubled domain B, 35S²-gus. TherolD-gus genes had a distinctive pattern of expression in roots, compared to that of the two other genes, with the strongest GUS activity observed in the root elongation zone and in vascular tissue, and much less in the root apex.     

The seasonal activity and the effect of mechanical bending and wounding on the PtCOMT promoter in Betula pendula Roth

In this study, 900-bp (signed as p including nucleotides –1 to –886) and partly deleted (signed as dp including nucleotides –1 to –414) COMT (caffeate/5-hydroxyferulate O-methyltransferase) promoters from Populus tremuloides Michx. were fused to the GUS reporter gene, and the tissue-specific expression patterns of the promoters were determined in Betula pendula Roth along the growing season, and as a response to mechanical bending and wounding. The main activity of the PtCOMTp- and PtCOMTdp-promoters, determined by the histochemical GUS assay, was found in the developing xylem of stems during the 8th–13th week and in the developing xylem of roots in the 13th week of the growing season. The GUS expression patterns did not differ among the xylem cell types. The PtCOMT promoter-induced GUS expression observed in phloem fibres suggests a need for PtCOMT expression and thus syringyl (S) lignin synthesis in fibre lignification. However, the PtCOMTdp-promoter induced GUS expression in stem trichomes, which may contribute to the biosynthesis of phenylpropanoid pathway-derived compounds other than lignin. Finally, a strong GUS expression was induced by the PtCOMT promoters in response to mechanical stem bending but not to wounding. The lack of major differences between the PtCOMTp- and PtCOMTdp-promoters suggests that the deleted promoter sequence (including nucleotides −415 to −886) did not contain a significant regulatory element contributing to the GUS expression in young B. pendula trees.     

Transgene expression in strawberries driven by a heterologous phloem-specific promoter

Strawberry is susceptible to diseases caused by phytoplasmas, mycoplasma-like prokaryotes restricted to sieve elements in the phloem tissue of infected plants. One strategy to improve strawberry resistance to phytoplasmas involves transgenic expression of anti-microbial peptide genes in phloem. For targeted phloem-specific expression, we constructed a binary vector with an expression cassette bearing the -glucuronidase (GUS) reporter gene (uidA) under control of the Arabidopsis sucrose-H⁺ symporter gene (AtSUC2) promoter. Transgenic strawberry lines were generated with high efficiencies by a modified transformation protocol, which combines the adoption of a 3-day pre-selection period following transformation, and the addition of 10-M thidiazuron to the regeneration medium. Histological GUS activity indicated that the reporter gene was expressed specifically in phloem of leaves, petioles, and roots of transgenic plants. The results suggest that the transformation protocol and the AtSUC2 promoter may be useful for engineering phytoplasma-resistant transgenic strawberries.     

The transformation of pea (<Emphasis Type="Italic">Pisum sativum</Emphasis> L.): applicable methods of <Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis>-mediated gene transfer

Three methods of transformation of pea (Pisum sativum ssp. sativum L. var. medullare) were tested. The most efficient Agrobacterium tumefaciens-mediated T-DNA transfer was obtained using embryonic segments from mature pea seeds as initial explants. The transformation procedure was based on the transfer of the T-DNA region with the reporter gene uidA and selection gene bar. The expression of β-glucuronidase (GUS) in the regenerated shoots was tested using the histochemical method and the shoots were selected on a medium containing phosphinothricin (PPT). The shoots of putative transformants were rooted and transferred to non-sterile conditions. Transient expression of the uidA gene in the tissues after co-cultivation and in the course of short-term shoot cultivation (confirmed by histochemical analysis of GUS and by RT-PCR of mRNA) was achieved; however, we have not yet succeeded in proving stable incorporation of the transgene in the analysed plants.