Aluminum borate whisker-mediated production of transgenic tobacco plants

An aluminum borate whiskers-mediated transformation system for calluses of tobacco (Nicotiana tabacum, cv. SR-1) has been developed. A total of 50 small pieces of calluses were vigorously agitated in a liquid medium containing aluminum borate whiskers, pBI221 plasmid carrying the -glucuronidase (GUS) gene, and pBI222 plasmid carrying the hygromycin phosphotransferase (HPT) gene. After treatment, calluses were cultured to select for hygromycin resistance, and three resistant calluses were obtained. Adventitious shoots were produced from each hygromycin-resistant callus and were transferred to rooting medium. A total of three plantlets obtained from each hygromycin-resistant callus were acclimatized and established in soil. Polymerase chain reaction analysis revealed that all the plantlets were cotransformed with both the GUS and HPT genes. Detached leaves of transgenic individuals showed clear hygromycin resistance when cultured in liquid medium. Histochemical assay for GUS revealed that one of these transgenic plants expressed the GUS gene, indicating coexpression of foreign genes.     

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.     

High level of GUS gene expression driven by pollen-specific promoters in electroporated lily pollen protoplasts

Gene constructs that contained the -glucuronidase (GUS) gene under the control of a pollen-specific Zm13 promoter from maize and a LAT52 promoter from tomato were introduced by electroporation into pollen protoplasts isolated from bicellular pollen grains of Lilium longiflorum. After 20 h in culture, the pollen protoplasts exhibited the apparent expression of GUS in a fluorometric assay. The GUS activity induced under the control of the Zm13 promoter was over 10 000 times higher than activity in the control (with no DNA or without electroporation). By contrast, the GUS gene was nearly silent in the lily microspore protoplasts and generative cell protoplasts. The GUS activity driven by the Zm13 and LAT52 promoters was also detected by a cytochemical assay. The frequency of blue-staining pollen protoplasts was about 70% in the case of the Zm13 promoter. The efficiency of gene transfer by electroporation was much higher than by particle bombardment. This protoplast-specific electroporation system is suitable for rapid and reliable examination of pollen-specific promoters, being as good as the particle bombardment system.     

Cotton α-Globulin Promoter: Isolation and Functional Characterization in Transgenic Cotton,Arabidopsis, and Tobacco

Globulins are the most abundant seed storage proteins in cotton and, therefore, their regulatory sequences could potentially provide a good source of seed-specific promoters. We isolated the putative promoter region of cotton -globulin B gene by gene walking using the primers designed from a cotton staged embryo cDNA clone. PCR amplified fragment of 1108 bp upstream sequences was fused to gusA gene in the binary vector pBI101.3 to create the test construct. This was used to study the expression pattern of the putative promoter region in transgenic cotton, Arabidopsis, and tobacco. Histochemical GUS analysis revealed that the promoter began to express during the torpedo stage of seed development in tobacco and Arabidopsis, and during cotyledon expansion stage in cotton. The activity quickly increased until embryo maturation in all three species. Fluorometric GUS analysis showed that the promoter expression started at 12 and 15 dpa in tobacco and cotton, respectively, and increased through seed maturation. The strength of the promoter expression, as reflected by average GUS activity in the seeds from primary transgenic plants, was vastly different amongst the three species tested. In Arabidopsis, the activity was 16.7% and in tobacco it was less than 1% of the levels detected in cotton seeds. In germinating seedlings of tobacco and Arabidopsis, GUS activity diminished until it was completely absent 10 days post imbibition. In addition, absence of detectable level of GUS expression in stem, leaf, root, pollen, and floral bud of transgenic cotton confirmed that the promoter is highly seed-specific. Analysis of GUS activity at individual seed level in cotton showed a gene dose effect reflecting their homozygous or hemizygous status. Our results show that this promoter is highly tissue-specific and it can be used to control transgene expression in dicot seeds.     

Evidence for non-proteinaceous inhibitor(s) of β-glucuronidase in wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis>L.) leaf and root tissues

The GUS gene of E. coli, encoding -glucuronidase, has been widely used as a reporter gene in plant transformation. However, -glucuronidase activity in transgenic wheat leaf or root tissue is rarely observed or reported. To address this question, we investigated three wheat lines transformed with the GUS reporter gene. We found all three lines expressed GUS mRNA as well as -glucuronidase protein in their leaf and root tissues as detected by RNA gel blot, ELISA, and immunoblot analyses. However, -glucuronidase enzyme activity was only detected in pollen grains from the transgenic plants. Fluorometric and histochemical assays performed in the presence of wheat tissue extracts indicated that wheat leaf and root tissues contain inhibitor(s) of -glucuronidase activity, but pollen grains contain much lower concentrations. Further characterizations indicated that the inhibitor(s) is of low molecular weight (<10 kDa) and is non-proteinaceous.     

Gene transfer by electroporation in betulaceae protoplasts: Alnus incana

The Escherichia coli -glucuronidase gene (GUS) was introduced into Alnus incana (L.) Moench protoplasts by electroporation. Level of GUS transient gene expression was increased by increasing DNA concentrations of pBI 221 plasmid and was affected by the amplitude and duration of the applied electric pulse as well as by the presence of polyethylene glycol (PEG) in the electroporation medium. An optimal level of GUS activity was obtained after electroporation with a capacitive discharge of 500 V/cm and 71 ms-duration. This transformation procedure is simple and efficient. These results motivated us to investigate this method as a possible way of achieving the stable transformation of actinorhizal alder.Abbreviations CaMV cauliflower mosaic virus - CPW salts, Cocking-Power-White salts - kb kilobase(s) - MU 4-methyl umbelliferyl - MUG 4-methyl umbelliferyl glucuronide - F microfarad(s) - NOS nopaline synthase     

Pollen viability and transgene expression following storage in honey

Transgenic plants of tobacco andArabidopsis that produce genetically marked pollen, expressing the reporter geneuidA (gusA), were generated to determine whether pollen proteins can be expressed and stable in honey, a potential route by which foreign proteins might enter the wider environment. Hydrated tobacco pollen was found to lose viability rapidly in honey, while pollen in the natural dehydrated form remained viable for at least several days and in some cases several weeks, as determined by FDA staining activity and germinability. Dehydrated pollen was found to be capable of transient foreign gene expression, following microprojectile bombardment, after incubation in honey for at least 120 h. PCR amplification of transgene sequences in pollen of transgenic plants revealed that pollen DNA can remain relatively intact after 7 weeks in honey. GUS enzyme activity analysis and SDS-PAGE of pollen proteins revealed that foreign and native pollen proteins are stable in pollen incubated in honey for at least 6 weeks. We conclude that pollen may represent an ecologically important vector for transgenic protein products.     

Activity of a chimeric promoter with the doubled CaMV 35S enhancer element in protoplast-derived cells and transgenic plants in maize

A reproducible and efficient transformation system has been developed for maize that is based on direct DNA uptake into embryogenic protoplasts and regeneration of fertile plants from protoplast-derived transgenic callus tissues. Plasmid DNA, containing the -glucuronidase (GUS) gene, under the control of the doubled enhancer element (the –208 to –46 bp upstream fragment) from CaMV 35S promoter, linked to the truncated (up to –389 bp from ATG) promoter of wheat, -amylase gene was introduced into protoplasts from suspension culture of HE/89 genotype. The constructed transformation vectors carried either the neomycin phosphotransferase (NPTII) or phosphinothricin acetyltransferase (PAT) gene as selective marker. The applied DNA uptake protocol has resulted at least in 10–20 resistant calli, or GUS-expressing colonies after treatment of 10⁶ protoplasts. Vital GUS staining of microcalli has made possible the shoot regeneration from the GUS-stained tissues. 80–90% of kanamycin or PPT resistant calli showed GUS activity, and transgenic plants were regenerated from more than 140 clones. Both Southern hybridization and PCR analysis showed the presence of introduced foreign genes in the genomic DNA of the transformants. The chimeric promoter, composed of a tissue specific monocot promoter, and the viral enhancer element specified similar expression pattern in maize plants, as it was determined by the full CaMV 35S promoter in dicot and other monocot plants. The highest GUS specific activity was found in older leaves with progressively less activity in young leaves, stem and root. Histochemical localization of GUS revealed promoter function in leaf epidermis, mesophyll and vascular bundles, in the cortex and vascular cylinder of the root. In roots, the meristematic tip region and vascular tissues stained intensively. Selected transformants were grown up to maturity, and second-generation seedlings with segregation for GUS activity were obtained after outcrossing. The GUS-expressing segregants carried also the NPTII gene as shown by Southern hybridization.     

Semi-constitutive expression of an Arabidopsis thaliana α-tubulin gene

In Arabidopsis tissues, the pool of tubulin protein is provided by the expression of multiple -tubulin and -tubulin genes. Previous evidence suggested that the TUA2 -tubulin gene was expressed in all organs of mature plants. We now report a more detailed analysis of TUA2 expression during plant development. Chimeric genes containing TUA2 5-flanking DNA fused to the -glucuronidase (GUS) coding region were used to create transgenic Arabidopsis plants. Second-generation progeny of regenerated plants were analyzed by histochemical assay to localize GUS expression. GUS activity was seen throughout plant development and in nearly all tissues. The blue product of GUS activity accumulated to the highest levels in tissues with actively dividing and elongating cells. GUS activity was not detected in a few plant tissues, suggesting that, though widely expressed, the TUA2 promoter is not constitutively active.     

Agrobacterium-mediated transient transformation of annatto (Bixa orellana) hypocotyls with the GUS reporter gene

Hypocotyls from annatto seedlings, were inoculated with Agrobacterium tumefaciens harboring a binary vector, pBI.121 or pCAMBIA2301, containing the -glucuronidase (gus) gene. Histochemical GUS assay of infected hypocotyls from two annatto varieties showed transient gus gene expression between 3 and 12 days after inoculation.These authors contributed equally to this work.)     

Optimization of delivery of foreign DNA into higher-plant chloroplasts

We report here an efficient and highly reproducible delivery system, using an improved biolistic transformation device, that facilitates transient expression of -glucuronidase (GUS) in chloroplasts of cultured tobacco suspension cells. Cultured tobacco cells collected on filter papers were bombarded with tungsten particles coated with pUC118 or pBI101.3 (negative controls), pBI505 (positive nuclear control) or a chloroplast expression vector (pHD203-GUS), and were assayed for GUS activity. No GUS activity was detected in cells bombarded with pUC118 or pBI101.3. Cells bombarded with pBI505 showed high levels of expression with blue color being distributed evenly throughout the whole cytosol of the transformants. pHD203-GUS was expressed exclusively in chloroplasts. We base this conclusion on: i) the procaryotic nature of the promoter used in the chloroplast expression vector; ii) delayed GUS staining; iii) localization of blue color within subcellular compartments corresponding to plastids in both shape and size; and iv) confirmation of organelle-specific expression of pHD203-GUS using PEG-mediated protoplast transformation. Chloroplast transformation efficiencies increased dramatically (about 200-fold) using an improved helium-driven biolistic device, as compared to the more commonly used gun powder charge-driven device. Using GUS as a reporter gene and the improved biolistic device, optimal bombardment conditions were established, consistently producing several hundred transient chloroplast transformants per Petri plate. Chloroplast transformation efficiency was found to be increased further (20-fold) with supplemental osmoticum (0.55 M sorbitol and 0.55 M mannitol) in the bombardment and incubation medium. This system provides a highly effective mechanism for introducing and expressing plasmid DNA within higher-plant chloroplasts, and the fact that GUS functions as an effective marker gene now makes many genetic studies possible which were not possible before.     

Timing of Transposition of Ac Mobile Element in Potato

The timing of excision of maize transposable element Ac was studied using visual histochemical assay based on Ac excision restoring activity of -glucuronidase (GUS). The Solanum tuberosum L. cv. Bintje was used for Agrobacterium-mediated transformation with pTT230 plasmid harbouring Ac-interrupted gus A gene and npt II gene as a selectable marker gene. Twenty-eight out of 72 kanamycin resistant calli did not express any GUS activity, 31 calli showed partial GUS expression and 13 out of assayed calli revealed strong expression of gus A gene. Plants were regenerated from calli without and/or with partial expression of gus A gene. The regenerated transformants which did not express GUS during the callus phase often contained many small GUS expressing spots on leaves. A phenotypic selection assay for excision of Ac has been also used. This non-detectable excision of Ac in callus tissue could be followed by a "late" timing excision during leaf development. After transformation with pTT224 plasmid harbouring Ac-interrupted hpt II gene and npt II gene transgenic calli containing Ac within the hygromycin resistance gene were derived and hygromycin sensitive plants were regenerated from them. Protoplasts isolated from leaves of transgenic regenerated plants were selected on hygromycin. Hygromycin resistant minicalli showed to harbour multiple copies of Ac and mark out low uniqueness of integration sites.     

Visual characterization of recombination at FRT-gusA loci in transgenic tobacco mediated by constitutive expression of the native FLP recombinase

FLP/FRT-mediated site-specific recombination was studied with a recombination-reporter gene system which allows visualization of -glucuronidase (GUS) expression after site-specific excisional activation of a silent gusA gene. This system was used for characterization of the functional activity of the Saccharomyces cerevisiae native FLP recombinase driven by the cauliflower mosaic virus (CaMV) 35s promoter [linked to the tobacco mosaic virus (TMV) omega translational leader] in mediating site-specific recombination of chromosomal FRT sites in tobacco FLP x FRT-reporter hybrids. Six hybrids were generated from crosses of lines containing either a stably integrated recombination-reporter or a FLP-expression construct. The activated gusA phenotype was specific to hybrid progenies and was not observed in either parental plants or their selfed progenies. Recombination efficiency in whole seedlings was estimated by the percent of radioactivity on a Southern blot which was incorporated into the recombined DNA product. Estimated efficiency mean values for the six crosses ranged from 5.2 to 52.0%. Histochemical analysis in hybrid plants visualized GUS activity with variable chimeric patterns and intensities. Recombination efficiency and GUS expression varied both among and within crosses, while higher recombination efficiency coincided with larger and more intense patterns of GUS activity. These data suggest that recombination is induced randomly during somatic developmental stages and that the pattern and intensity generated in a given plant are affected by factors imposing varibility not only between but also within crosses. Additionally, while recombination in a population of FLP/FRT hybrids may occur in all plants, recombination efficiency may still be low in any given plant. The activity of the native, as compared to a modified, FLP (Kilby et al. 1995) in the activation of transgenic traits in tobacco is discussed.     

Review: Biosafety of E. coli β-glucuronidase (GUS) in plants

The -glucuronidase (GUS) gene is to date the most frequently used reporter gene in plants. Marketing of crops containing this gene requires prior evaluation of their biosafety. To aid such evaluations of the GUS gene, irrespective of the plant into which the gene has been introduced, the ecological and toxicological aspects of the gene and gene product have been examined. GUS activity is found in many bacterial species, is common in all tissues of vertebrates and is also present in organisms of various invertebrate taxa. The transgenic GUS originates from the enterobacterial species Escherichia coli that is widespread in the vertebrate intestine, and in soil and water ecosystems. Any GUS activity added to the ecosystem through genetically modified plants will be of no or minor influence. Selective advantages to genetically modified plants that posses and express the E. coli GUS transgene are unlikely. No increase of weediness of E. coli GUS expressing crop plants, or wild relatives that might have received the transgene through outcrossing, is expected. Since E. coli GUS naturally occurs ubiquitously in the digestive tract of consumers, its presence in food and feed from genetically modified plants is unlikely to cause any harm. E. coli GUS in genetically modified plants and their products can be regarded as safe for the environment and consumers     

Molecular and biochemical characterization of three aromatic polyketide synthase genes from Rubus idaeus

To play an essential role in C₄ photosynthesis, the maize C₄ phosphoenolpyruvate carboxylase gene (PPCZm1) acquired many new expression features, such as leaf specificity, mesophyll specificity, light inducibility and high activity, that distinguish the unique C₄ PPC from numerous non-C₄ PPC genes in maize. We present here the first investigation of the developmental, cell-specific, light and metabolic regulation of the homologous C₄ PPCZm1 promoter in stable transgenic maize plants. We demonstrate that the 1.7 kb of the 5-flanking region of the PPCZm1 gene is sufficient to direct the C₄-specific expression patterns of -glucuronidase (GUS) activity, as a reporter, in stable transformed maize plants. In light-grown shoots, GUS expression was strongest in all developing and mature mesophyll cells in the leaf, collar and sheath. GUS activity was also detected in mesophyll cells in the outer husks of ear shoots and in the outer glumes of staminate spikelets. We did not observe histological localization of GUS activity in light- or dark-grown callus, roots, silk, developing or mature kernels, the shoot apex, prop roots, or pollen. In addition, we used the stable expressing transformants to conduct and quantify physiological induction studies. Our results indicate that the expression of the C₄ PPCZm1-GUS fusion gene is mesophyll-specific and influenced by development, light, glucose, acetate and chloroplast biogenesis in transgenic maize plants. These studies suggest that the adoption of DNA regulatory elements for C₄-specific gene expression is a crucial step in C₄ gene evolution.     

Transgenic haploid plants ofNicotiana rustica produced by bombardment-mediated transformation of pollen

Immature pollen fromNicotiana rustica was bombarded with gold particles coated with plasmid DNA encoding neomycin phosphotransferase II (NPTII) and -glucuronidase (GUS) genes which, respectively, are under the control of the cauliflower mosaic virus (CaMV) 35S promoter and nopaline synthase (NOS) terminator in the plasmid. Kanamycin-resistant pollen embryoids were selected from the bombarded pollen cells and two independent lines of transgenic plants were regenerated. Enzyme assays showed that one has both NPTII and GUS activities and the other only weak NPTII activity. Southern blot analyses indicated that the former has a DNA fragment corresponding to the intact expression cassettes for both genes in its genome; whereas the latter lacks intact expression cassettes for both genes and has only the intactnptII coding sequence in its genome. The transgenic plants of both lines have 24 chromosomes, confirming haploidy, and they are infertile. These results indicate that transgenic haploid plants can be produced directly by the bombardment-mediated transformation of immature pollen.     

Xylem-specific expression of a GRP1.8 promoter::4CL gene construct in transgenic tobacco

Lignin is a complex aromatic polymer of vascular plants that provides mechanical strength to the stem and protects cellulose fibres from chemical and biological degradation. 4-Coumarate:CoA ligases (EC 6.2.1.12) are key enzymes for the biosynthetic pathway of monolignols which is an important complex aromatic polymer for lignin biosynthesis and tree growth. Recently, 4-coumarate:CoA ligase has been used as exogenous gene in transgenic plants to genetically modify the lignin biosynthesis pathway. Since most lignin is produced in the vascular cells, a tissue-specific-expressed promoter in the vascular cell would be important and useful to change and modify the content of lignin. Here we report the existence of a promoter of GRP1.8 (the glycine-rich protein 1.8) in Sopho japonica L. (GenBank accession number AF250149) and studies on its function in transgenic tobacco. The promoter activity was analyzed in transgenic tobacco plants by histochemical staining of GUS gene expression driven by a 613-bp sjGRP1.8p promoter sequence. In sjGRP1.8p-GUS transgenic plants, intense GUS staining was detected in the xylem of the stem. To further investigate the regulation of the tissue-specific expression of the 4CL1 gene, we analyzed the activity of the 4CL1 gene which is sense orientated with the sjGRP1.8p promoter in transgenic tobacco. The Pto4CL1 gene was expressed in the stem of transgenic tobacco. The activity of the 4CL1 enzyme was increased 1–2-fold in the stem but not increased in the leaves of transgenic tobacco. In comparison with the control plants, the content of lignin was increased 25% in the stem but there was no increase in the leaves of transgenic tobacco.     

Expression pattern of diacylglycerol acyltransferase-1, an enzyme involved in triacylglycerol biosynthesis,in Arabidopsis thaliana

Triacylglycerol (TAG) is the major carbon storage reserve in oilseeds such as Arabidopsis. Acyl-CoA:diacylglycerol acyltransferase (DGAT) catalyses the final step of the TAG synthesis pathway. Although TAG is mainly accumulated during seed development, and DGAT has presumably the highest activity in developing seeds, we show here that TAG synthesis is also actively taking place during germination and seedling development in Arabidopsis. The expression pattern of the DGAT1 gene was studied in transgenic plants containing the reporter gene -glucuronidase (GUS) fused with DNA sequences flanking the DGAT1coding region. GUS activity was not only detected in developing seeds and pollen, which normally accumulate storage TAG, but also in germinating seeds and seedlings. Western blots showed that DGAT1 protein is present in several tissues, though is most abundant in developing seeds. In seedlings, DGAT1 is expressed in shoot and root apical regions, correlating with rapid cell division and growth. The expression of GUS in seedlings was consistent with the results of RNA gel blot analyses, precursor feeding and DGAT assay. In addition, DGAT1gene expression is up-regulated by glucose and associated with glucose-induced changes in seedling development.     

Successful expression in pollen of various plant species of in vitro synthesized mRNA introduced by particle bombardment

Gold particles coated with -glucuronidase (GUS) mRNA with a 5 cap structure that had been synthesized in vitro were introduced, by use of a pneumatic particle gun, into pollen grains of lily (Lilium longiflorum), freesia (Freesia refracta) and tulip (Tulipa gesneriana). A fluorometric assay for the GUS activity indicated that in vitro synthesized GUS mRNA introduced into these pollen cells by particle bombardment was successfully expressed. GUS activity in extracts of the bombarded lily pollen became detectable fluorometrically within 30 min after bombardment, peaked at 6 h, then gradually decreased. This activity changed as a function of the developmental stage of the pollen cell of lily.