Transgenic hybrid aspen overexpressing the Atwbc19 gene encoding an ATP-binding cassette transporter confers resistance to four aminoglycoside antibiotics

Antibiotic-resistance genes of bacterial origin are invaluable markers for plant genetic engineering. However, these genes are feared to pose possible risk to human health by horizontal gene transfer from transgenic plants to bacteria, potentially resulting in antibiotic-resistant pathogenic bacteria; this is a considerable regulatory concern in some countries. The Atwbc19 gene, encoding an Arabidopsis thaliana ATP-binding cassette transporter, has been reported to confer resistance to kanamycin specifically as an alternative to bacterial antibiotic-resistance genes. In this report, we transformed hybrid aspen (Populus canescens × P. grandidentata) with the Atwbc19 gene. Unlike Atwbc19-transgenic tobacco that was only resistant to kanamycin, the transgenic Populus plants also showed resistance to three other aminoglycoside antibiotics (neomycin, geneticin, and paromomycin) at comparable levels to plants containing a CaMV35S-nptII cassette. Although it is unknown why the transgenic Populus with the Atwbc19 gene is resistant to all aminoglycoside antibiotics tested, the broad utility of the Atwbc19 gene as a reporter gene is confirmed here in a second dicot species. Because the Atwbc19 gene is plant-ubiquitous, it might serve as an alternative selectable marker to current bacterial antibiotic-resistance marker genes and alleviate the potential risk for horizontal transfer of bacterial-resistance genes in transgenic plants.     

Overexpression of an Arabidopsis thaliana ABC transporter confers kanamycin resistance to transgenic plants

Selectable markers of bacterial origin such as the neomycin phosphotransferase type II gene, which can confer kanamycin resistance to transgenic plants, represent an invaluable tool for plant engineering. However, since all currently used antibiotic-resistance genes are of bacterial origin, there have been concerns about horizontal gene transfer from transgenic plants back to bacteria, which may result in antibiotic resistance. Here we characterize a plant gene, Atwbc19, the gene that encodes an Arabidopsis thaliana ATP binding cassette (ABC) transporter and confers antibiotic resistance to transgenic plants. The mechanism of resistance is novel, and the levels of resistance achieved are comparable to those attained through expression of bacterial antibiotic-resistance genes in transgenic tobacco using the CaMV 35S promoter. Because ABC transporters are endogenous to plants, the use of Atwbc19 as a selectable marker in transgenic plants may provide a practical alternative to current bacterial marker genes in terms of the risk for horizontal transfer of resistance genes.     

Detection of nptII (kanamycin resistance) genes in genomes of transgenic plants by marker-rescue transformation

We have developed a novel system for the sensitive detection of nptII genes (kanamycin resistance determinants) including those present in transgenic plant genomes. The assay is based on the recombinational repair of an nptII gene with an internal 10-bp deletion located on a plasmid downstream of a bacterial promoter. Uptake of an nptII gene by transformation restores kanamycin resistance. In Escherichia coli, promoterless nptII genes provided by electroporation were rescued with high efficiency in a RecA-dependent recombinational process. For the rescue of nptII genes present in chromosomal plant DNA, the system was adapted to natural transformation, which favours the uptake of linear DNA. When competent Acinetobacter sp. BD413 (formerly A. calcoaceticus) cells containing the mutant nptII gene on a plasmid were transformed with DNA from various transgenic plants carrying nptII as a marker gene (Solanum tuberosum, Nicotiana tabacum, Beta vulgaris, Brassica napus, Lycopersicon esculentum), kanamycin-resistant transformants were obtained roughly in proportion to the concentration of nptII genes in the plant DNA. The rescue of nptII genes occurred in the presence of a more than 6 × 10⁶-fold excess of plant DNA. Only 18 ng of potato DNA (2.5 × 10³ genome equivalents, each with one copy of nptII) was required to produce one kanamycin-resistant transformant. These experiments and others employing DNA isolated from soil samples demonstrate that the system allows reliable and highly sensitive monitoring of nptII genes in transgenic plant DNA and in DNA from environmental sources, such as soil, without the need for prior DNA amplification (e.g. by PCR). Received: 20 May 1997 / Accepted: 17 October 1997     

Detection of nptII (kanamycin resistance) genes in genomes of transgenic plants by marker-rescue transformation

We have developed a novel system for the sensitive detection of nptII genes (kanamycin resistance determinants) including those present in transgenic plant genomes. The assay is based on the recombinational repair of an nptII gene with an internal 10-bp deletion located on a plasmid downstream of a bacterial promoter. Uptake of an nptII gene by transformation restores kanamycin resistance. In Escherichia coli, promoterless nptII genes provided by electroporation were rescued with high efficiency in a RecA-dependent recombinational process. For the rescue of nptII genes present in chromosomal plant DNA, the system was adapted to natural transformation, which favours the uptake of linear DNA. When competent Acinetobacter sp. BD413 (formerly A. calcoaceticus) cells containing the mutant nptII gene on a plasmid were transformed with DNA from various transgenic plants carrying nptII as a marker gene (Solanum tuberosum, Nicotiana tabacum, Beta vulgaris, Brassica napus, Lycopersicon esculentum), kanamycin-resistant transformants were obtained roughly in proportion to the concentration of nptII genes in the plant DNA. The rescue of nptII genes occurred in the presence of a more than 6?×?10⁶-fold excess of plant DNA. Only 18 ng of potato DNA (2.5?×?10³ genome equivalents, each with one copy of nptII) was required to produce one kanamycin-resistant transformant. These experiments and others employing DNA isolated from soil samples demonstrate that the system allows reliable and highly sensitive monitoring of nptII genes in transgenic plant DNA and in DNA from environmental sources, such as soil, without the need for prior DNA amplification (e.g. by PCR).     

The improvement of resistance to bacterial speck in transgenic tomato plants by <Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis> mediated transformation

The pto gene, responsible for resistance to Pseudomonas syringae pv. tomato, was transferred to tomato genotype Urfa-2 by the LBA4404 strain of A. tumefaciens harboring the plasmid pPTC8. The presence of nptII and pto genes in transgenic plants was proved by PCR analysis. Insertion of the pto gene into the genome of transgenic plants and expression of the gene were confirmed by southern and northern hybridizations, respectively. The pathogen P. syringae pv. tomato was applied to all leaves of transgenic and control plants. While typical bacterial speck symptoms developed on the leaves of control plants, the transgenic plants did not display any typical symptoms of bacterial speck upon inoculation with strains 1 and 0. Some of these transgenic plants had thicker leaves than the control plants and produced abnormal flowers. The pollen of transgenic plants was used for crossing with control plants to produce F1 transgenic lines. Fruits from crossed transgenic and control plants were obtained, and F1 seeds germinated on Murashige and Skoog medium in the presence of kanamycin have developed F1 seedlings. Published in Russian in Fiziologiya Rastenii, 2007, Vol. 54, No. 1, pp. 102–110. The text was submitted by the authors in English.     

Unsuccessful search for DNA transfer from transgenic plants to bacteria in the intestine of the tobacco horn worm, <Emphasis Type="Italic">Manduca sexta</Emphasis>

DNA transfer from transgenic plants to native intestinal bacteria and introduced Acinetobacter BD413 was assessed in the gut of the tobacco horn worm (Manduca sexta). The marker was kanamycin resistance gene (nptII), and tobacco carrying the nptII gene in the chloroplasts served as the donor. We detected neither whole gene transfer to native bacteria, nor transfer of fragments of nptII to Acinetobacter, using a marker exchange assay. This negative result was attributed to a heat-labile activity that degraded DNA in the feces, probably DNAase. Nevertheless, a few intact leaf cells survived transit through the gut, and DNA extracted from feces did transform Acinetobacter, albeit at lower frequencies than DNA extracted from leaves.     

Kanamycin resistance in plants: an unexpected trait controlled by a potentially multifaceted gene

Ayalew Mentewab and C. Neal Stewart Jr recently showed that an Arabidopsis kanamycin resistance gene encodes an ATP binding cassette (ABC) transporter. This Atwbc19 protein is hypothesized to prevent ribosome inactivation by translocating kanamycin into the vacuole. Because ABC transporters often recognize multiple exogenous substrates, overexpression of Atwbc19 can result in the accumulation of unexpected compounds in transgenic plants. Another potential safety issue associated with this gene is horizontal gene transfer. Thus, commercial applications are likely to be limited to methods that allow removal of the selectable marker from the transgenic plant genome.     

Transformation of the tropane alkaloid-producing medicinal plant Hyoscyamus muticus by particle bombardment

We report an efficient whole plant transformation system for Hyoscyamus muticus, an important medicinal plant of the Solanaceous family. We developed a system using a plasmid carrying the nptII and gusA genes, which was delivered into leaf explants by particle bombardment. Ten percent of bombarded leaf explants formed kanamycin-resistant callus, from which putative transgenic plants were recovered. The nptII gene conferring kanamycin resistance was found to be incorporated into the genome of all transgenic plants screened. Over 50% of the kanamycin resistant plants showed strong expression of the non-selected gusA gene. The majority of transgenic plants reached maturity, could be self pollinated, and produced fertile seed. A simple and efficient whole plant transformation system for this medicinal plant is an important step in furthering our understanding of tropane alkaloid production in plants.     

Transformation of Acinetobacter sp. Strain BD413(pFG4ΔnptII) with Transgenic Plant DNA in Soil Microcosms and Effects of Kanamycin on Selection of Transformants

Here we show that horizontal transfer of DNA, extracted from transgenic sugar beets, to bacteria, based on homologous recombination, can occur in soil. Restoration of a 317-bp-deleted nptII gene in Acinetobacter sp. strain BD413(pFG4) cells incubated in sterile soil microcosms was detected after addition of nutrients and transgenic plant DNA encoding a functional nptII gene conferring bacterial kanamycin resistance. Selective effects of the addition of kanamycin on the population dynamics of Acinetobacter sp. cells in soil were found, and high concentrations of kanamycin reduced the CFU of Acinetobacter sp. cells from 10⁹ CFU/g of soil to below detection. In contrast to a chromosomal nptII-encoded kanamycin resistance, the pFG4-generated resistance was found to be unstable over a 31-day incubation period in vitro.     

Chlorophyll fluorescence assay for kanamycin resistance screening in transgenic plants

The applicability of a chlorophyll fluorescence assay for kanamycin (Km) resistance screening in transgenic tobacco (Nicotiana tabacum) and Arabidopsis thaliana plants was investigated. In wild-type leaves incubated in the presence of 200 mg/l Km, a decrease in maximum variable fluorescence ((Fv)m) and a significant increase in constant fluorescence (Fo) were observed. Using (Fv)m/Fo as a screening parameter, we were able to distinguish Km-treated samples from untreated samples within 4 days. This parameter was applied to Km resistance screening using tobacco plants transformed with the nptII gene via Agrobacterium. Among 74 shoots selected on medium containing 200 mg/l Km, 37 plants were scored as Km sensitive by the chlorophyll fluorescence assay. These 74 scorings proved to be accurate, as reconfirmed by (1) polymerase chain reaction amplification of the transgene, (2) enzymatic assay of neomycin phosphotransferase and (3) leaf disc assay. Using the chlorophyll fluorescence assay, we could also screen 3-week old Arabidopsis plants carrying the nptII gene. These results clearly demonstrate the reliability and efficiency of this nondestructive assay for Km resistance screening of transgenic plants. Received: 27 November 1995 / Revision received: 18 April 1997 / Accepted: 28 July 1997     

A novel strategy for obtaining kanamycin resistance in Arabidopsis thaliana by silencing an endogenous gene encoding a putative chloroplast transporter

The use of bacterial antibiotic resistance markers in transgenic plants raises concerns about horizontal gene transfer to soil bacteria. We report here that kanamycin resistance in Arabidopsis thaliana can be achieved by silencing an endogenous gene encoding a putative chloroplast transporter, which presumably imports kanamycin into chloroplasts to interfere with ribosomal RNA. Homologs of the transporter exist in other plant species, suggesting this strategy may be generally useful for selecting transformed plant cells.     

Kanamycin resistance of germinating pollen of transgenic plants

The influence of kanamycin on the percentage of pollen germination and on tube growth of pollen from non-transformed and transformed plants of various species containing a chimaeric kanamycin resistance gene (NPTII) was investigated. Pollen grains isolated from kanamycin resistant plants expressed resistance when germinating in vitro, whereas kanamycin impaired tube growth of pollen from non-transformed plants. Pollen grains from transgenic plants were less sensitive and produced significantly longer tubes. mRNAs of the chimaeric gene are probably presynthesized concurrently with the other mRNAs during microsporogenesis, and kanamycin resistance is expressed by mRNA translation during pollen tube elongation. Received: 24 August 1999 / Revision accepted: 20 October 1999     

<Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation of flax with a mutant tubulin gene responsible for resistance to dinitroaniline herbicides

Agrobacterium tumefaciens was used to transform fiber flax with the pBITUBA8 plasmid carrying the mutant α-tubulin gene imparting resistance to dinitroaniline herbicides and the nptII selective marker gene imparting resistance to kanamycin. The transformants were selected in parallel on media containing kanamycin and trifluralin (a dinitroaniline herbicide). The transgenic nature of the resultant regenerants resistant to dinitroaniline herbicides was confirmed by means of Southern blotting and polymerase chain reaction (PCR) analysis using specific probes for the ntpII gene and the gene of α-tubulin.     

Transformation of Brassica napus with Agrobacterium tumefaciens based vectors

A reproducible system to produce transgenic Brassica napus plants has been developed using stem segments. Stem segments from 6–7 week old plants were inoculated with an Agrobacterium tumefaciens strain containing a disarmed tumor-inducing plasmid pTiT37-SE carrying a chimeric bacterial gene encoding kanamycin resistance (pMON200). Stem explants were cocultured for 2 days before transfer to kanamycin selection medium. Shoots regenerated directly from the explant in 3–6 weeks and were excised, dipped in Rootone®, and rooted in soil. Transformation was confirmed by opine production, kanamycin resistance, and DNA blot hybridization in the primary transformants. Final proof of transformation was demonstrated by the co-transfer of opine production and kanamycin resistance to progeny in a Mendelian fashion. Over 200 transgenic Brassica napus plants have been produced using this system.Abbreviations BA 6-benzyladenine - NAA -naphthalene-acetic acid - T-DNA transferred DNA into plants - IBA indole butyric acid - IAA indole acetic acid - TXD Tobacco Xanthi diploid suspension cells     

Agrobacterium tumefaciens-mediated transgenic plant production via direct shoot bud organogenesis from pre-plasmolyzed leaf explants of Catharanthus roseus

Production of Agrobacterium tumefaciens-mediated transgenic plants, via direct shoot bud organogenesis from leaves of Catharanthus roseus, is reported. A. tumefaciens harbouring the plasmid pBI121 with GUS gene uidA and kanamycin resistance gene nptII was used. Highest transformation efficiency of 1.4 transgenic shoots/responded explant was obtained when pre-plasmolysed leaves, pre-incubated on shoot bud induction medium for 10 days, were subjected to sonication for 30 s prior to transformation. Using a selection medium containing 50 mg kanamycin l⁻¹, transformants grew into micro-shoots and formed roots on a hormone-free half strength MS medium. The transgenic nature of the regenerated plants was confirmed by PCR amplification of uidA gene and GUS histochemical assay.     

Examining the behavior of crop-derived antibiotic resistance genes in anaerobic sludge batch reactors under thermophilic conditions

The consumption of transgenic crops and their by-products has become increasingly common in the United States. Yet, uncertainty remains regarding the fate and behavior of DNA within food matrices once it exits the digestive track and enters into wastewater treatment plants (WWTPs). Because many transgenic crops have historically contained antibiotic resistance genes as selection markers, understanding the behavior and uptake of these transgenes by environmental microbes is of critical importance. To investigate the behavior of free transgenic crop DNA, thermophilic anaerobic batch reactors were amended with varying concentrations of transgenic crop genes (i.e., LUG, nptII, and bla) and the persistence of those genes was monitored over 60 days using quantitative PCR. Significant levels of nptII and bla were detected in extracellular DNA (eDNA). Furthermore, LUG maize marker genes were also detected in the control reactors, suggesting that other crop-derived transgenes contained within digested transgenic foods may also enter WWTPs. Possible bacterial transformation events were detected within the highest dose treatments at Days 30 and 60 of incubation. These findings suggest that within the average conventional digester residence times in the United States (30 days), there is a potential for bacterial transformation events to occur with crop-derived transgenes found in eDNA.     

Selection for kanamycin resistance in transformed petunia cells leads to the co-amplification of a linked gene

A cell suspension culture was established from a transgenic petunia (Petunia hybrida L.) plant which carried genes encoding neomycin phosphotransferase II (nptII) and -glucuronidase (uidA, GUS). Two selection experiments were performed to obtain cell lines with increased resistance to kanamycin. In the first, two independently selected cell lines grown in the presence of 350 g/ml kanamycin were eight to ten-fold more resistant to kanamycin than unselected cells. Increased resistance was correlated with amplification of the nptII gene and an increase in nptII mRNA levels. Selection for kanamycin resistance also produced amplification of the linked GUS gene, resulting in increased GUS mRNA levels and enzyme activity. Selected cells grown in the absence of kanamycin for twelve growth cycles maintained increased copy numbers of both genes, and GUS enzyme activity was also stably overexpressed. In a second selection experiment, a cell line grown continuously in medium containing 100 g/ml kanamycin exhibited higher nptII and GUS gene copy numbers and an increase in GUS enzyme activity after eleven growth cycles. In this cell line, amplification of the two genes was accompanied by DNA rearrangement.     

Agrobacterium tumefaciens-mediated transformation of the aromatic shrub Lavandula latifolia

Transgenic plants of the aromatic shrub Lavandula latifolia (Lamiaceae) were produced using Agrobacterium tumefaciens-mediated gene transfer. Leaf and hypocotyl explants from 35–40-day old lavender seedlings were inoculated with the EHA105 strain carrying the nptII gene, as selectable marker, and the reporter gusA gene with an intron. Some of the factors influencing T-DNA transfer to L. latifolia explants were assessed. Optimal transformation rates (6.0 ± 1.6% in three different experiments) were obtained when leaf explants precultured for 1 day on regeneration medium were subcultured on selection medium after a 24 h co-cultivation with Agrobacterium. Evidence for stable integration was obtained by GUS assay, PCR and Southern hybridisation. More than 250 transgenic plants were obtained from 37 independent transformation events. Twenty-four transgenic plants from 7 of those events were successfully established in soil. -glucuronidase activity and kanamycin resistance assays in greenhouse-grown plants from two independent transgenic lines confirmed the stable expression of both gusA and nptII genes two years after the initial transformation. Evidence from PCR data, GUS assays and regeneration in the presence of kanamycin demonstrated a 1:15 Mendelian segregation of both transgenes among seedlings of the T1 progeny of two plants from one transgenic L. latifolia line.     

Spread of Recombinant DNA by Roots and Pollen of Transgenic Potato Plants, Identified by Highly Specific Biomonitoring Using Natural Transformation of an Acinetobacter sp.

Transgenic potato plants with the nptII gene coding for neomycin phosphotransferase (kanamycin resistance) as a selection marker were examined for the spread of recombinant DNA into the environment. We used the recombinant fusion of nptII with the tg4 terminator for a novel biomonitoring technique. This depended on natural transformation of Acinetobacter sp. strain BD413 cells having in their genomes a terminally truncated nptII gene (nptII′; kanamycin sensitivity) followed by the tg4 terminator. Integration of the recombinant fusion DNA by homologous recombination in nptII′ and tg4 restored nptII, leading to kanamycin-resistant transformants. DNA of the transgenic potato was detectable with high sensitivity, while no transformants were obtained with the DNA of other transgenic plants harboring nptII in different genetic contexts. The recombinant DNA was frequently found in rhizosphere extracts of transgenic potato plants from field plots. In a series of field plot and greenhouse experiments we identified two sources of this DNA: spread by roots during plant growth and by pollen during flowering. Both sources also contributed to the spread of the transgene into the rhizospheres of nontransgenic plants in the vicinity. The longest persistence of transforming DNA in field soil was observed with soil from a potato field in 1997 sampled in the following year in April and then stored moist at 4°C in the dark for 4 years prior to extract preparation and transformation. In this study natural transformation is used as a reliable laboratory technique to detect recombinant DNA but is not used for monitoring horizontal gene transfer in the environment.     

Evaluation of possible horizontal gene transfer from transgenic plants to the soil bacterium Acinetobacter calcoaceticus BD413

 The use of genetically engineered crop plants has raised concerns about the transfer of their engineered DNA to indigenous microbes in soil. We have evaluated possible horizontal gene transfer from transgenic plants by natural transformation to the soil bacterium Acinetobacter calcoaceticus BD413. The transformation frequencies with DNA from two sources of transgenic plant DNA and different forms of plasmid DNA with an inserted kanamycin resistance gene, nptII, were measured. Clear effects of homology were seen on transformation frequencies, and no transformants were ever detected after using transgenic plant DNA. This implied a transformation frequency of less than 10^-13 (transformants per recipient) under optimised conditions, which is expected to drop even further to a minimum of 10^-16 due to soil conditions and a lowered concentration of DNA available to cells. Previous studies have shown that chromosomal DNA released to soil is only available to A. calcoaceticus for limited period of time and that A. calcoaceticus does not maintain detectable competence in soil. Taken together, these results suggest that A. calcoaceticus does not take up non-homologous plant DNA at appreciable frequencies under natural conditions. Received: 1 November 1996 / Accepted: 18 April 1997