Imazaquin and chlorsulfuron resistance and cross resistance in mutants of Chlamydomonas reinhardtii

Summary Chlorsulfuron and/or imazaquin resistant mutants of Chlamydomonas reinhardtii strain CW15 have been obtained and shown to have actolactate synthase (ALS) with altered sensitivity to one or both of these herbicides. Herbicide resistance in the three mutants described is allelic, and resistance appears to result from a dominant or semidominant mutation in a single, nuclear gene. Imazaquin and chlorsulfuron resistant ALS from imazaquin and chlorsulfuron resistant mutants, together with single-gene Mendelian inheritance of these phenotypes, suggests that ALS is the sole site of action of the two herbicides in Chlamydomonas. A high degree of cross resistance between the two herbicides was found in only one mutant. This mutant (IM-13) was selected for resistance to imazaquin and has a high level of in vitro resistance to both imazaquin (270-fold increased I₅₀) and chlorsulfuron (900-fold increased I₅₀). In another mutant selected for resistance to imazaquin (IMR-2), hyper-sensitivity to chlorsulfuron was found. A mutant selected for resistance to chlorsulfuron (CSR-5), had a substantial degree of resistance of chlorsulfuron (80-fold increased I₅₀), but not to imazaquin (7-fold increased I₅₀).     

Establishment of an enhancer trap system with<Emphasis Type="Italic"> Ds</Emphasis> and GUS for functional genomics in rice

To develop an efficient means of enhancer trapping, a two-element system employing Ds and an Ac transposase (AcTPase) gene was tested in rice. We generated 263 transgenic rice plants, each of which harboured the maize transposable element Ds together with a GUS coding sequence under the control of a minimal promoter ( Ds-GUS), and a gene that confers resistance to the herbicide chlorsulfuron. Among the 263 lines generated, 42 were shown to have a single copy of the Ds-GUS element. Four single-copy lines were crossed with each of six transgenic plants that carried the AcTPase gene. Excision of the Ds-GUS in leaves of F₁ plants was detected in eight combinations out of seventeen examined. The frequency of transposition of Ds-GUS in germ cells in the F₁ plants was examined using 10,524 F₂ plants, and 675 (6%) were judged to be transposants. Their frequencies differed among F₁ plants depending on the AcTPase x Ds-GUS cross considered, and also among panicles on the same F₁ plant. This suggests that Ds-GUS tends to transpose during panicle development. Southern analysis with a GUS probe showed different band patterns among transposants derived from different panicles. Therefore, the transposants derived from different panicles must have arisen independently. Transposants showing tissue-specific GUS activities were obtained, and enhancers thus trapped by the Ds-GUS element were identified. These results demonstrate that the system is suitable for the isolation of large numbers of independent Ds-GUS transposants, and for the identification of various tissue-specific enhancers. The Ds-GUS lines generated in this study offer a potentially powerful tool for studies on the functional genomics of rice.Communicated by M.-A. Grandbastien     

Generation of chlorsulfuron-resistant transgenic garlic plants (Allium sativum L.) by particle bombardment

We established an effective biolistic transformation procedure fortransferring foreign genes into garlic (Allium sativumL.),which we demonstrated by generating transgenic plants resistant tochlorsulfuron, a sulfonylurea herbicide. We subcultured callus tissue from theapical meristem of garlic cloves and repeatedly selected calli with brittle,non-mucilaginous surfaces for over six months, to increase transformationefficiency. We then constructed recombinant DNA that contained the acetolactatesynthase (ALS) gene from a chlorsulfuron-resistantArabidopsis mutant, the cauliflower mosaic virus 35Spromoter, the -glucuronidase (GUS) reporter gene, and the hygromycinphosphotransferase (HPT) selectable marker gene. The garlic calli werebombarded twice with tungsten particles coated with the DNA constructs. Transformed calliwere efficiently selected by embedding them in solid agar medium containing 50mg l^–1 hygromycin B. Selected propagules wereregenerated into 12 independent plants. We confirmed that the transgenes wereintegrated and expressed in the plants using PCR-Southern and Northern blotanalyses and by -glucuronidase expression assay forGUS. The regenerated plants survived in the presence of 3mg l^–1 chlorsulfuron, demonstrating that theirALS was insensitive to this herbicide. These results illustrate the successfultransformation of foreign genes into garlic plants. The set of proceduresdeveloped in this study is applicable to the generation of transgenic garlicplants with other agronomically beneficial traits. These authors contributed equally to this work     

Characterization of transgenic sulfonylurea-resistant flax (Linum usitatissimum)

Summary Fourteen transgenic flax (Linum usitatissimum) lines, carrying a mutant Arabidopsis acetolactate synthase (ALS) gene selected for resistance to chlorsulfuron, were characterized for resistance to two sulfonylurea herbicides. Progeny of 10 of the 14 lines segregated in a ratio of 3 resistant to 1 susceptible, indicating a single insertion. Progeny of 1 line segregated in a 151 ratio, indicating two insertions of the ALS gene at independent loci. Progeny from 3 lines did not segregate in a Mendelian fashion and were likely the products of chimeric shoots. Resistance to chlorsulfuron was stably inherited in all lines. At the enzyme level, the transgenic lines were 2.5 to more than 60 times more resistant to chlorsulfuron than the parental lines. The transgenic lines were 25–260 times more resistant to chlorsulfuron than the parental lines in root growth experiments and demonstrated resistance when grown in soil treated with 20 g ha^-1 chlorsulfuron. The lines demonstrated less resistance to metsulfuron methyl; in root growth experiments, the transgenic lines were only 1.6–4.8 times more resistant to metsulfuron methyl than the parental lines. Resistance was demonstrated in the field at half (2.25 g ha^-1) and full (4.5 g ha^-1) rates of metsulfuron methyl.     

Response to auxin by cells ofRiella helicophylla during reversible arrest in different cell-cycle phases

When cells of the unistratose meristem ofRiella helicophylla (Bory et Mont.) Mont. are reversibly arrested at G1/S transition by treatment with the inhibitor of thymidylate synthase 5-fluorodeoxyuridine, with the inhibitor of DNA polymerase , aphidicolin, or with an inhibitor of late DNA synthesis, 5-aminouracil, they continue to expand. Simultaneous supply of auxin enhances cell expansion, while simultaneous addition of the auxin antagonistp-chlorophenoxyisobutyric acid prevents cell enlargement. When the meristematic cells are reversibly arrested during G1 phase by treatment with chlorsulfuron, an inhibitor of acetolactate synthase, cell size remains unchanged, but it increases when auxin is supplied simultaneously. Simultaneous application of chlorsulfuron during treatment with 5-fluorodeoxyuridine, aphidicolin or 5-aminouracil, prevents cell expansion. After recovery from 5-fluorodeoxyuridine, aphidicolin or 5-aminouracil treatment, the cellular pattern of the meristem is severely disturbed, while in combination withp-chlorophenoxyisobutyric acid or chlorsulfuron, meristem differentiation is almost unaffected. During reactivation of divisional functions in mature cells induced by isolation of tissue fragments, blockage of DNA synthesis by aphidicolin causes an augmentation of rhizoid initials which are characterized by enhanced RNA synthesis. Exogenous supply of auxin is required for outgrowth of these rhizoid initials, while, in untreated fragments, auxin for rhizoid growth is provided probably by the dividing cells. When reactivation of divisional functions in tissue fragments is reversibly inhibited by chlorsulfuron, no changes in the cells are discernible and application of auxin has no effect; after release from blockage the cells regenerate like those in untreated fragments. The results suggest that the phases of the cell cycle differ with regard to auxin synthesis and competence to respond to auxin. Probably, during cycle inhibition at G1/S or S a rising auxin level causes disintegration of cell-cycle events.Abbreviations APH aphidicolin - 5-AU 5-aminouracil - CS chlorsulfuron - 5-FdUrd 5-fluorodeoxyuridine - PCIB p-chloro-phenoxyisobutyric acid Part of doctoral thesis, University of Kassel, GermanyI thank Professor Luise Stange (this Institute) for her suggestions and many stimulating discussions. This research was supported by a scholarship of the Otto-Braun-Fonds and by a grant of the Deutsche Forschungsgemeinschaft to Professor Stange.     

Differential effects of the sulfonylurea herbicides chlorsulfuron and sulfometuron methyl on microorganisms

The sulfonylurea herbicides exert their effects on cells via their inhibition of the acetohydroxy acid synthase (AHS) enzymes. Although chlorsulfuron and sulfometuron methyl often affected microbial growth differently their effects on the AHS activities of toluenised cells were similar. Sulfometuron methyl was always a more potent inhibitor than chlorsulfuron. We have postulated that sulfometuron methyl penetrated into microbial cells more readily then did chlorsulfuron. The effect of the herbicides on microbial growth was altered by the composition of the medium and in particular by valine or valine plus isoleucine. Different microorganisms had different complements of AHS isoenzymes which together with differences in permeability were the most likely explanations for the different responses observed. It was pointed out that application of these sulfonylurea herbicides would have significant effects on the microbial ecological balance of soil, and particularly so in alkaline soils. The consequences would be most evident in agricultural situations where the microbial population played an important role in maximising the productivity of crops.     

Metabonomics classifies pathways affected by bioactive compounds. Artificial neural network classification of NMR spectra of plant extracts

The biochemical mode-of-action (MOA) for herbicides and other bioactive compounds can be rapidly and simultaneously classified by automated pattern recognition of the metabonome that is embodied in the 1H NMR spectrum of a crude plant extract. The ca. 300 herbicides that are used in agriculture today affect less than 30 different biochemical pathways. In this report, 19 of the most interesting MOAs were automatically classified. Corn (Zea mays) plants were treated with various herbicides such as imazethapyr, glyphosate, sethoxydim, and diuron, which represent various biochemical modes-of-action such as inhibition of specific enzymes (acetohydroxy acid synthase [AHAS], protoporphyrin IX oxidase [PROTOX], 5-enolpyruvylshikimate-3-phosphate synthase [EPSPS], acetyl CoA carboxylase [ACC-ase], etc.), or protein complexes (photosystems I and II), or major biological process such as oxidative phosphorylation, auxin transport, microtubule growth, and mitosis. Crude isolates from the treated plants were subjected to 1H NMR spectroscopy, and the spectra were classified by artificial neural network analysis to discriminate the herbicide modes-of-action. We demonstrate the use and refinement of the method, and present cross-validated assignments for the metabolite NMR profiles of over 400 plant isolates. The MOA screen also recognizes when a new mode-of-action is present, which is considered extremely important for the herbicide discovery process, and can be used to study deviations in the metabolism of compounds from a chemical synthesis program. The combination of NMR metabolite profiling and neural network classification is expected to be similarly relevant to other metabonomic profiling applications, such as in drug discovery.