The absorption, translocation and distribution of the herbicide glyphosate in maize expressing the CP-4 transgene

Maize (Zea mays L. var. Bonnie) transformed with a gene encoding a 5-enolpyruvylshikimate 3-phosphate synthase with altered sensitivity showed over 100-fold greater resistance to the herbicide glyphosate (N-[phosphonomethyl]glycine) in comparison with its non-transformed progenitor (parental control) at the third-leaf stage. Studies with [¹⁴C]-glyphosate at a dosage lethal to the parental control, but sublethal to the transgenic, revealed that a maximum of 45-65% of the applied dose was absorbed, with greater absorption occurring in transgenic plants. Translocation of glyphosate was closely related to its absorption (r value 0.956) with approximately 15% more of the applied dose being mobilized in transgenic plants than the parental controls. Analysis of electronic autoradiograms along the treated leaf lamina found discrete internal regions of glyphosate accumulation closely associated with the site of application. These regions contained lower amounts of glyphosate present in the treated leaf lamina was almost completely translocated in transgenic plants, while in the parental controls more remained and the leaf became necrotic. In both types of maize there was a small accumulation of herbicide in the tip region of the leaf which was not mobilized. Younger shoot tissues and roots were major sinks for translocated glyphosate accumulating approximately 25-40% of the applied dose depending upon treatment. In the parental control, equal amounts of glyphosate were found distributed between young shoot tissues and roots; while in transgenic plants, the young shoot tissue accumulated around three times more glyphosate than the roots. In both plant types, glyphosate was localized in the meristems and young, actively growing leaves. Specific glyphosate activity (the amount of glyphosate per unit dry weight of tissue) in the major sinks of the transgenic declined towards the end of the treatment period but remained relatively constant in the parental control. In conclusion, enhancing glyphosate resistance by genetic transformation influenced the absorption, translocation and distribution of this herbicide in whole plants.Keywords: Zea mays, glyphosate (N-[phosphonomethyl]-glycine), transgenic, absorption, translocation, source-sink.      

Effect of Glutamine Synthetase Gene Overexpression in Birch (<Emphasis Type="Italic">Betula pubescens</Emphasis>) Plants on Auxin Content and Rooting in vitro

The effects of transformation of downy birch (Betula pubescens Ehrh.) with the GS1 gene encoding the cytosolic form of glutamine synthetase on the rooting of plants in vitro was studied. The transgenic plants had an elevated content of glutamine as well as glutamic and aspartic acids and rooted more rapidly than the control plants. Rooting on a medium containing the glutamine synthetase inhibitor phosphinothricin prevented the accumulation of auxin in birch plants carrying the GS1 gene, indicating the involvement of this enzyme in raising the level of auxins in the transgenic plants. The correlation between the increase in the auxin levels in the transgenic plants carrying the glutamine synthetase gene and the increase in the rooting rate is shown for the first time.     

Biochemical and molecular characterization of transgenic<Emphasis Type="Italic"> Lotus japonicus</Emphasis> plants constitutively over-expressing a cytosolic glutamine synthetase gene

Higher plants assimilate nitrogen in the form of ammonia through the concerted activity of glutamine synthetase (GS) and glutamate synthase (GOGAT). The GS enzyme is either located in the cytoplasm (GS₁) or in the chloroplast (GS₂). To understand how modulation of GS activity affects plant performance, Lotus japonicus L. plants were transformed with an alfalfa GS₁ gene driven by the CaMV 35S promoter. The transformants showed increased GS activity and an increase in GS₁ polypeptide level in all the organs tested. GS was analyzed by non-denaturing gel electrophoresis and ion-exchange chromatography. The results showed the presence of multiple GS isoenzymes in the different organs and the presence of a novel isoform in the transgenic plants. The distribution of GS in the different organs was analyzed by immunohistochemical localization. GS was localized in the mesophyll cells of the leaves and in the vasculature of the stem and roots of the transformants. Our results consistently showed higher soluble protein concentration, higher chlorophyll content and a higher biomass accumulation in the transgenic plants. The total amino acid content in the leaves and stems of the transgenic plants was 22–24% more than in the tissues of the non-transformed plants. The relative abundance of individual amino acid was similar except for aspartate/asparagine and proline, which were higher in the transformants.Abbreviations GS Glutamine synthetase - UTR Untranslated region     

Production of phosphinothricin-tolerant rice (Oryza sativa L.) through the application of phosphinothricin as growth regulator

 A novel procedure has been developed to produce rice (Oryza sativa L.) tolerant to the herbicide phosphinothricin (PPT) by means of in vitro selection. First, sublethal and lethal concentrations of PPT on 7-day-old seedlings were determined and morphogenetic events in response to the PPT treatment evaluated. Differentiation of 6–30 microshoots on 5–40% of the treated plant material was observed on a hormone-free culture medium supplemented with a sublethal concentration of PPT. We proved that PPT is morphogenetically active, similar to the action of many other herbicides, showing cytokinin-like effects in rice tissue culture. Fertile plants were grown from those microshoots having PPT tolerance under greenhouse conditions. To the best of our knowledge, this is the first report on the production of rice plants tolerant to this herbicide without genetic transformation. Since PPT is a competitive inhibitor of glutamine synthetase (GS), total GS activity in PPT-tolerant and PPT-sensitive plants was examined comprehensively in order to decide whether this enzyme has any role in PPT tolerance. An elevated GS activity was detected in PPT-tolerant plant material which could result in an elevated PPT tolerance at unchanged concentrations of the herbicide. Received: 20 February 2000 / Accepted: 19 June 2000     

The two paralogue phoN (phosphinothricin acetyl transferase) genes of Pseudomonas putida encode functionally different proteins

Phosphinothricin (PPT) is a non‐specific inhibitor of glutamine synthetase that has been employed as herbicide for selection of transgenic plants expressing cognate resistance genes. While the soil bacterium Pseudomonas putida KT2440 has been generally considered PPT‐sensitive, inspection of its genome sequence reveals the presence of two highly similar open reading frames (PP_1924 and PP_4846) encoding acetylases with a potential to cause tolerance to the herbicide. To explore this possibility, each of these genes (named phoN1 and phoN2) was separately cloned and their activities examined in vivo and in vitro. Genetic and biochemical evidence indicated that phoN1 encodes a bona fide PPT‐acetyl transferase, the expression of which suffices to make P. putida tolerant to high concentrations of the herbicide. In contrast, PhoN2 does not act on PPT but displays instead activity against methionine sulfoximine (MetSox), another glutamine synthetase inhibitor. When the geometry of the substrate‐binding site of PhoN1 was grafted with the equivalent residues of the predicted PhoN2 structure, the resulting protein increased significantly MetSox resistance of the expression host concomitantly with the loss of activity on PPT. These observations uncover intricate biochemical and genetic interactions among soil microorganisms and how they can be perturbed by exposure to generic herbicides in soil.     

Vegetative and generative dispersal capacity of field released transgenic aspen trees

Transfer of genes by pollen or wind-dispersed seed is considered a main potential risk when field release experiments with transgenic trees are initiated. In Germany, the first release experiment with genetically transformed trees was initiated in 1996. To ensure that the transgenic trees remained in the vegetative phase, the duration of the experiment was limited to 5 years. In total, 457 1-year-old trees including eight transgenic aspen lines carrying either the 35S- rolC or the rbcS- rolC gene construct, and three control clones were transferred to the field. In 1998 and 2000, 12 plants of transgenic lines all carrying the 35S- rolC gene construct formed female flower buds. Furthermore, one young aspen plant identified as a root sucker was observed in 1999 followed by an increasing number of root suckers derived from transgenic and non-transgenic trees in 2000 and 2001. In 2001, the last year of the field trial, 15 root suckers were detected outside the field. In total, 234 root suckers were harvested in 2000 and 2001 and analysed for their transgenic status. More than half of the roots suckers investigated showed the presence of the rbcS- rolC gene construct. We concluded that in addition to the widely accepted generative propagation, vegetative dispersal capacity of transgenic perennial plants is also important and must be included in risk assessment studies.     

Response of transgenic poplar overexpressing cytosolic glutamine synthetase to phosphinothricin

Glutamine synthetase (GS) is the main enzyme involved in ammonia assimilation in plants and is the target of phosphinothricin (PPT), an herbicide commonly used for weed control in agriculture. As a result of the inhibition of GS, PPT also blocks photorespiration, resulting in the depletion of leaf amino acid pools leading to the plant death. Hybrid transgenic poplar (Populus tremula x P. alba INRA clone 7171-B4) overexpressing cytosolic GS is characterized by enhanced vegetative growth [Gallardo, F., Fu, J., Cantón, F.R., García-Gutiérrez, A., Cánovas, F.M., Kirby, E.G., 1999. Expression of a conifer glutamine synthetase gene in transgenic poplar. Planta 210, 19-26; Fu, J., Sampalo, R., Gallardo, F., Cánovas, F.M., Kirby, E.G., 2003. Assembly of a cytosolic pine glutamine synthetase holoenzyme in leaves of transgenic poplar leads to enhanced vegetative growth in young plants. Plant Cell Environ. 26, 411-418; Jing, Z.P., Gallardo, F., Pascual, M.B., Sampalo, R., Romero, J., Torres de Navarra, A., Cánovas, F.M., 2004. Improved growth in a field trial of transgenic hybrid poplar overexpressing glutamine synthetase. New Phytol. 164, 137-145], increased photosynthetic and photorespiratory capacities [El-Khatib, R.T., Hamerlynck, E.P., Gallardo, F., Kirby, E.G., 2004. Transgenic poplar characterized by ectopic expression of a pine cytosolic glutamine synthetase gene exhibits enhanced tolerance to water stress. Tree Physiol. 24, 729-736], enhanced tolerance to water stress (El-Khatib et al., 2004), and enhanced nitrogen use efficiency [Man, H.-M., Boriel, R., El-Khatib, R.T., Kirby, E.G., 2005. Characterization of transgenic poplar with ectopic expression of pine cytosolic glutamine synthetase under conditions of varying nitrogen availability. New Phytol. 167, 31-39]. In vitro plantlets of GS transgenic poplar exhibited enhanced resistance to PPT when compared with non-transgenic controls. After 30 days exposure to PPT at an equivalent dose of 275 g ha(-1), growth of GS transgenic poplar plantlets was 5-fold greater than controls. The response of young leaves to PPT treatment depends on physiological state as indicated by GS and Rubisco (LSU) levels. Young leaves from control plants, typically in a low differentiation state, respond to the herbicide showing up-regulation of GS and LSU. In contrast, young leaves from transgenic lines, with higher initial GS and LSU levels compared to control, display up-regulation of NADP(+)-isocitrate dehydrogenase. Differences between control and GS transgenics in their response to PPT are discussed in relation to their differences in photosynthetic and photorespiratory capacities (El-Khatib et al., 2004).     

Enhanced salt stress tolerance in transgenic potato plants (<Emphasis Type="Italic">Solanum tuberosum</Emphasis> L.) expressing a bacterial <Emphasis Type="Italic">mtl</Emphasis>D gene

Bacterial mannitol 1-phosphate dehydrogenase (mtlD) gene was introduced into potato (Solanum tuberosum L.) by Agrobacterium tumefaciens-mediated transformation. Transgenic plants were selected on a medium containing 100 mg l⁻¹ kanamycin and confirmed by polymerase chain reaction (PCR), Southern blotting, and RT-PCR analyses. All of the selected transformants accumulated mannitol, a sugar alcohol that is not found in wildtype potato. Experiments designed for testing salt tolerance revealed that there was enhanced NaCl tolerance of the transgenic lines both in vitro and in hydroponic culture. Compared to 0 mM NaCl, the shoot fresh weight of wildtype plants was reduced by 76.5% at 100 mM NaCl under hydroponic conditions. However, under the same condition, the shoot fresh weight of transgenic plants was reduced only by 17.3%, compared to 0 mM NaCl treatment. The improved tolerance of this transgenic line may be attributed to the induction and progressive accumulation of mannitol in the roots and shoots of the plants. In contrast to in vitro experiments, the mannitol content in the transgenic roots and shoots increased at 50 mM NaCl and decreased slightly at 75 and 100 mM NaCl, respectively. Overall, the amount of accumulated mannitol in the transgenic lines was too small to act as an osmolyte; thus, it might act as an osmoprotectant. However, the results demonstrated that mannitol had more contribution to osmotic adjustment in the roots (but not in shoots). Finally, we concluded that mtlD expression in transgenic potato plants can significantly increase the mannitol accumulation that contributes to the enhanced tolerance to NaCl stress. Furthermore, although this enhanced tolerance resulted mainly from an osmoprotectant action, an osmoregulatory effect could not be ruled out.     

Overproduction of alfalfa glutamine synthetase in transgenic tobacco plants

Summary We have obtained transgenic tobacco plants overexpressing the enzyme glutamine synthetase (GS) by fusing an alfalfa GS gene to the cauliflower mosaic virus 35S promotor and integrating it intoNicotiana tabacum var. W38 plants byAgrobacterium tumefaciens mediated gene transfer. The amount of RNA specific to alfalfa GS was about 10 times higher in transgenic tobacco plants than in alfalfa. The alfalfa GS produced by these transgenic plants was identified by Western blotting and represented 5% of total soluble protein in the transformed plants, amounting to a 5-fold increase in specific GS activity and in a 20-fold increase in resistance to the GS inhibitorl-phosphinothricin in vitro. Tissue from GS overproducing plants showed a sevenfold lower amount of free NH₃. The amino acid composition of the plant tissue was not altered significantly by GS overproduction. GS overproducing plants were fertile and grew normally. These data show that a high level of expression of a key metabolic enzyme such as glutamine synthetase does not interfere with growth and fertility of plants.     

Antifungal activity of stilbenes in in vitro bioassays and in transgenic<Emphasis Type="Italic"> Populus</Emphasis> expressing a gene encoding pinosylvin synthase

The effect of two stilbene compounds, pinosylvin and resveratrol, on the growth of several fungi was evaluated in plate tests. Wood decay tests were carried out with birch and aspen samples impregnated with the two stilbenes. In plate experiments, resveratrol had an enhancing effect on growth at concentrations where pinosylvin was already enough to prevent the growth of most fungi studied. Pinosylvin impregnated at 0.2% (w/w) concentration significantly reduced the decay caused by all fungi except Phellinus tremulae. In contrast, a resveratrol content of 0.8%, did not protect the wood from decay. A pinosylvin-synthase-encoding gene from Pinus sylvestris was transferred into aspen (Populus tremula) and two hybrid aspen clones (Populus tremula×tremuloides) by Agrobacterium tumefaciens-mediated transformation. Transgenic plants accumulated pinosylvin synthase-specific mRNA and showed stilbene synthase enzyme activity in vitro. Transgenic aspen line H4 showed increased resistance to Phellinus tremulae, while two hybrid aspen transformants decayed faster than the control trees. However, we were unable to detect the accumulation of stilbenes in the transgenic plantlets.Communicated by P. Debergh     

Expression of the bacterial gdhA gene encoding a NADPH glutamate dehydrogenase in tobacco affects plant growth and development

We investigated the effects of genetic modification of nitrogen metabolism via the bacterial glutamate dehydrogenase (GDH) on plant growth and metabolism. The gdhA gene from Escherichia coli encoding a NADPH-GDH was expressed in tobacco plants under the control of the 35 S promoter. The specific activity of GDH in gdhA plants was 8-fold of that in E. coli. Damage caused by spray application of 1.35 mM of phosphinothricin (PPT) herbicide, a glutamine synthetase (GS) inhibitor, was less pronounced in gdhA plants as compared with the control plants which suggests that the introduced GDH can assimilate some of the excess ammonium, at least during GS inhibition. However, gdhA plants were susceptible to 2.7 mM PPT. Biomass production was consistently increased in gdhA transgenic plants grown under controlled conditions and in the field. Total free amino acids and total carbohydrates were increased in gdhA plants grown in the greenhouse suggesting that both nitrogen and carbon metabolism were altered. We conclude that the modifications in transgenic plants may result from both increased nitrogen efficiency and altered gene expression and metabolism. This revised version was published online in June 2006 with corrections to the Cover Date.     

Rapid attainment of a doubled haploid line from transgenic maize (<Emphasis Type="Italic">Zea mays</Emphasis> L.) plants by means of anther culture

Summary We present a strategy for establishing a transgenic doubled haploid maize line from heterozygous transgenic material by means of anther culture. Compared to conventional inbreeding, the in vitro androgenesis technique enables a faster generation of virtually fully homozygous lines. Since the androgenic response is highly genotype-dependent, we crossed transgenic, non-androgenic plants carrying a herbicide resistance marker gene (pat, encoding for phosphinothricin acetyl transferase) with a highly androgenic genotype. The transgenic progenies were used as donor plants for anther culture. One transgenic and three non-transgenic doubled haploid lines have been established within approximately 1 yr. The homozygosity of all four doubled haploid lines was tested by analysis of simple sequence repeat (SSR) markers at 19 different loci. Polymorphisms were found between the lines but not within the lines indicating the homozygous nature of the entire plant genome gained by anther culture. Southern blot analysis revealed that the transgenic donor plants and their doubled haploid progeny exhibited the same integration pattern of the pat gene. No segregation of the herbicide resistance trait has been observed among the progeny of the transgenic doubled haploid line.     

Salinity stress response of non-transformed and AtCKX transgenic centaury (Centaurium erythraea Rafn.) shoots and roots grown in vitro

Common centaury (Centaurium erythraea Rafn.) is a plant species that can inhabit saline soils. It is known as a plant with high spontaneous regeneration potential in vitro. In the present work we evaluated shoots and roots salinity tolerance of non-transformed and three AtCKX transgenic centaury lines to graded NaCl concentrations (0, 50, 100, 150, 200 mM) in vitro. Overexpression of AtCKX genes in transgenic centaury plants resulted in an altered cytokinins (CKs) profile leading to a decline of bioactive CK levels and, at the same time, increased contents of storage CK forms, inactive CK forms and/or CK nucleotides. Significant increment of fresh shoot weight was obtained in shoots of non-transformed and AtCKX1 transgenic line only on medium supplemented with 50 mM NaCl. However two analysed AtCKX2 transgenic lines reduced shoot growth at all NaCl concentrations. In general, centaury roots showed higher tolerance to salinity than shoots. Non-transformed and AtCKX1 transgenic lines tolerated up to 100 mM NaCl without change in frequency of regeneration and number of regenerated plants. Roots of two analysed AtCKX2 transgenic lines showed different regeneration potential under salt stress. Regeneration of transgenic AtCKX2-26 shoots even at 200 mM NaCl was recorded. Salinity stress response of centaury shoots and roots was also evaluated at biochemical level. Free proline, malondialdehyde and hydrogen peroxide content as well as antioxidative enzymes activities were investigated in shoots and roots after 1, 2, 4 and 8 weeks. In general, adition of NaCl in culture medium elevated all biochemical parameters in centaury shoots and in roots. Considering that all analysed AtCKX transgenic centaury lines showed altered salt tolerance to graded NaCl concentrations in vitro it can be assumed that CKs might be involved in plant defence to salt stress conditions.     

<Emphasis Type="Italic">Rol</Emphasis> (root loci) gene as a positive selection marker to produce marker-free <Emphasis Type="Italic">Petunia hybrida</Emphasis>

The presence of marker genes conferring antibiotic or herbicide resistance in transgenic plants has been a serious problem for their public acceptance and commercialization. MAT (multi-auto-transformation) vector system has been one of the strategies to excise the selection marker gene from transgenic plants. Agrobacterium tumefaciens strain EHA105 harboring a rol-type MAT vector, pMAT101, was used to produce morphologically normal transgenic Petunia hybrida ‘Dainty Lady’ employing rol gene as the selection marker gene. LacZ gene was used as a model gene of interest. Infected explants were cultured on plant growth regulator (PGR)- and antibiotic-free half-strength MS medium. Sixty-five percent of the infected explants produced hairy roots. The hairy roots were separated and proliferated on 1/2 MS hormone-free medium. Shoots produced from the hairy roots on 1/2 MS medium supplemented with benzylaminopurine (BA) and naphthalene acetic acid (NAA) exhibited hairy root syndrome (Ri syndrome) such as dwarfed, reduced apical dominance, short internodes and increased rooting, but subsequently produced normal-looking marker-free shoots. Molecular analysis of DNA from the hairy roots, shoots with Ri syndrome and morphologically normal shoots revealed that the normal shoots had only LacZ gene, and the removable cassette consisting of rol, R (recombinase) and GUS genes was excised. From this study it can be concluded that the chimeric rol genes can be used as a selection marker for Agrobacterinum-mediated transformation of Petunia hybrida and that the production of marker-free normal transgenic plants is possible without using selective chemical agents employing rol-type MAT vector.     

Effects of aerobic versus anoxic conditions on glutamine synthetase activity in eelgrass (Zostera marina L.) roots: regulation of ammonium assimilation potential

Root glutamine synthetase (GS; EC 6.3.1.2) activity was measured daily (0 to 4 days) for eelgrass (Zostera marina L.) plants held under continuous darkness rooted in sediments, continuous darkness without sediments, continuous light without sediments, and control light/dark cycle (Control L/D). Roots experiencing prolonged aerobiosis exhibited lower activity in vitro than controls, whereas roots experiencing prolonged anoxia exhibited increased activity. Plants held in darkness without sediments had activity intermediate between controls and anoxic roots. One-hour pretreatment of root extracts with ATP slightly reduced in vitro glutamine synthetase activity, whereas pretreatment with ADP and AMP increased activity ≈50%. While glutamine synthetase activity increased with higher adenylate energy charge (AEC) in the reaction mixture, pretreatment of enzyme extracts at high adenylate energy charges decreased subsequent activity relative to pretreatment at lower energy charges. One-hour pretreatment with l-alanine (Ala) had little effect on enzyme activity. Pretreatment with l-glutamine (Gln), l-glutamate (Glu), and γ-amino butyric acid (GABA) increased activity ≈75%. Incubation of excised roots under anoxic conditions for 24 h nearly doubled enzyme activity. However, addition of cycloheximide to anoxic root incubations lessened or prevented the increase in activity. It appears that enhanced glutamine synthetase activity following periods of root anoxia results from interactions with metabolites that fluctuate between aerobic and anoxic conditions, particularly adenylates, and from de novo synthesis of glutamine synthetase or some other protein synthesis-dependent process.     

Tobacco isoenzyme 1 of NAD(H)-dependent glutamate dehydrogenase catabolizes glutamate in vivo

Glutamate (Glu) dehydrogenase (GDH, EC 1.4.1.2-1.4.1.4) catalyzes in vitro the reversible amination of 2-oxoglutarate to Glu. The in vivo direction(s) of the GDH reaction in higher plants and hence the role(s) of this enzyme is unclear, a situation confounded by the existence of isoenzymes comprised totally of either GDH beta- (isoenzyme 1) or alpha- (isoenzyme 7) subunits, as well as another five alpha-beta isoenzyme permutations. To clarify the in vivo direction of the reaction catalyzed by GDH isoenzyme 1, [(15)N]Glu was supplied to roots of two independent transgenic tobacco (Nicotiana tabacum) lines with increased isoenzyme 1 levels (S4-H and S49-H). The [(15)N]ammonium (NH(4)(+)) accumulation rate in these lines was elevated approximately 65% compared with a null segregant control line, indicating that isoenzyme 1 catabolizes Glu in roots. Leaf glutamine synthetase (GS) was inhibited with a GS-specific herbicide to quantify any contribution by GDH toward photorespiratory NH(4)(+) reassimilation. Transgenic line S49-H did not show enhanced resistance to the herbicide, indicating that the large pool of isoenzyme 1 in S49-H leaves was unable to compensate for GS and suggesting that isoenzyme 1 does not assimilate NH(4)(+) in vivo.     

Bar-expressing peppermint (Mentha × Piperita L. var. Black Mitcham) plants are highly resistant to the glufosinate herbicide Liberty

Weed control is a substantial economic input for production of mint oils, the most commercially important of which are obtained from peppermint. The objective of this research is to obtain peppermint plants resistant to the broad-spectrum herbicide glufosinate, which can be used for development of economically efficacious weed control strategies and, perhaps, serve as a paradigm in perennial crops. The bar gene, which encodes phosphinothricin acetyltransferase (PAT) which inactivates glufosinate-ammonium or phosphinothricin (PPT), was constructed into Agrobacterium tumefaciens binary vectors under the nopaline synthase (NOS) or a chimeric promoter containing a trimer of the OCS-upstream-activating sequence (UAS) to a MAS promoter/activator region[(OCS) ₃ MAS]. A total of 142 independent transgenic peppermint (cv. Black Mitcham) plants were obtained (107 and 35 were obtained with pGPTV (and pCAS1) and pATC940 vectors, respectively) and evaluated for herbicide resistance in the greenhouse after foliar application of glufosinate herbicide Liberty as the commercial product. All transgenic plants exhibited substantially less herbicide symptom development than non-transgenic Black Mitcham or untransformed tissue cultured-derived plants, albeit variation for herbicide resistance occurred amongst the transformed lines. Plants from 35 of the 142 lines were selected at random and all were PCR-positive for the presence of bar. Five lines, that were least affected, exhibited no injury symptoms to Liberty concentrations that are 4 times the standard level for control of weeds in peppermint fields. The most resistant transgenic plants had the greatest steady-state PAT mRNA levels and PAT activities. No experimental difference in herbicide resistance was evident between plant populations obtained with pGPTV (pCAS1)-bar or pATC940-bar vector. However, 4 of 35 lines transformed with (ocs) ₃ MAS-bar exhibited maximal resistance while only 1 of 107 NOS-bar lines has comparable resistance. These herbicide resistant peppermint plants will facilitate development of post-emergent herbicide control strategies that use newer generation herbicides, like glufosinate, which have reduced environmental and product residual because of metabolism by microbes and the transgenic plants.     

Impact of low pH and aluminium on nitrogen uptake and metabolism in roots of <Emphasis Type="Italic">Lotus japonicus</Emphasis>

The effect of low pH and aluminum on nitrogen uptake and metabolism was studied in roots of Lotus japonicus grown in hydroponic cultures. The low pH slightly suppressed root elongation, and this effect was accompanied by the suppression of nitrate and ammonia uptake, as well as the nitrate reductase activity. In spite of high resistance of young Lotus plants to short-term Al application, the one-day treatment of Al strongly reduced nitrate uptake and also the activity of nitrate reductase (NRA) in the apical parts of roots. The glutamine synthetase activity was also suppressed by Al treatment, but in lower extent. On the other hand, the ammonium uptake and nitrite reductase activity stayed unchanged by Al treatment and the values were practically the same as in control plants. These results support the view that nitrate uptake and nitrate reduction might be the main processes responsible for Al induced growth retardation in Lotus plants grown in mineral acid soils.