Multiple resistance to sulfonylureas and imidazolinones conferred by an acetohydroxyacid synthase gene with separate mutations for selective resistance

Summary The acetohydroxyacid synthase (AHAS) gene from the Arabidopsis thaliana mutant line GH90 carrying the imidazolinone resistance allele imr1 was cloned. Expression of the AHAS gene under the control of the CaMV 35S promoter in transgenic tobacco resulted in selective imidazolinone resistance, confirming that the single base-pair change found near the 3 end of the coding region of this gene is responsible for imidazolinone resistance. A chimeric AHAS gene containing both the imr1 mutation and the csr1 mutation, responsible for selective resistance to sulfonylurea herbicides, was constructed. It conferred on transgenic tobacco plants resistance to both sulfonylurea and imidazolinone herbicides. The data illustrate that a multiple-resistance phenotype can be achieved in an AHAS gene through combinations of separate mutations, each of which individually confers resistance to only one class of herbicides.     

Acetohydroxyacid synthase mutations conferring resistance to imidazolinone or sulfonylurea herbicides in sunflower

Wild biotypes of cultivated sunflower (Helianthus annuus L.) are weeds in corn (Zea mays L.), soybean (Glycine max L.), and other crops in North America, and are commonly controlled by applying acetohydroxyacid synthase (AHAS)-inhibiting herbicides. Biotypes resistant to two classes of AHAS-inhibiting herbicides—imidazolinones (IMIs) or sulfonylureas (SUs)—have been discovered in wild sunflower populations (ANN-PUR and ANN-KAN) treated with imazethapyr or chlorsulfuron, respectively. The goals of the present study were to isolate AHAS genes from sunflower, identify mutations in AHAS genes conferring herbicide resistance in ANN-PUR and ANN-KAN, and develop tools for marker-assisted selection (MAS) of herbicide resistance genes in sunflower. Three AHAS genes (AHAS1, AHAS2, and AHAS3) were identified, cloned, and sequenced from herbicide-resistant (mutant) and -susceptible (wild type) genotypes. We identified 48 single-nucleotide polymorphisms (SNPs) in AHAS1, a single six-base pair insertion-deletion in AHAS2, and a single SNP in AHAS3. No DNA polymorphisms were found in AHAS2 among elite inbred lines. AHAS1 from imazethapyr-resistant inbreds harbored a C-to-T mutation in codon 205 (Arabidopsis thaliana codon nomenclature), conferring resistance to IMI herbicides, whereas AHAS1 from chlorsulfuron-resistant inbreds harbored a C-to-T mutation in codon 197, conferring resistance to SU herbicides. SNP and single-strand conformational polymorphism markers for AHAS1, AHAS2, and AHAS3 were developed and genetically mapped. AHAS1, AHAS2, and AHAS3 mapped to linkage groups 2 (AHAS3), 6 (AHAS2), and 9 (AHAS1). The C/T SNP in codon 205 of AHAS1 cosegregated with a partially dominant gene for resistance to IMI herbicides in two mutant × wild-type populations. The molecular breeding tools described herein create the basis for rapidly identifying new mutations in AHAS and performing MAS for herbicide resistance genes in sunflower.     

Molecular characterization of Als1, an acetohydroxyacid synthase mutation conferring resistance to sulfonylurea herbicides in soybean

Key message

The AHAS gene family in soybean was characterized. The locus Als1 for sulfonylurea resistance was mapped and the resistant allele was characterized at the molecular level.

Abstract

Sulfonylurea (SU) resistance in soybean is controlled by Als1, a semi-dominant allele obtained by EMS mutagenesis over the cultivar Williams 82. The overall objective of this research was to map Als1 in the soybean genome and to determine the nucleotidic changes conferring resistance to SU. Four nucleotide sequences (GmAhas1–4) showing high homology with the Arabidopsis thaliana acetohydroxyacid synthase (AHAS, EC 4.1.3.18) gene sequence were identified by in silico analysis, PCR-amplified from the SU-resistant line BTK323STS and sequenced. Expression analysis showed that GmAhas1, located on chromosome 4 by in silico analysis, is the most expressed sequence in true leaves. F_2:3 families derived from the cross between susceptible and resistant lines were evaluated for SU resistance. Mapping results indicate that the locus als1 is located on chromosome 4. Sequence comparison of GmAhas1 between BTK323STS and Williams 82 showed a single nucleotide change from cytosine to thymine at position 532. This transversion generates an amino acid change from proline to serine at position 197 (A. thaliana nomenclature) of the AHAS catalytic subunit. An allele-specific marker developed for the GmAhas1 mutant sequence cosegregated with SU resistance in the F₂ population. Taking together, the mapping, expression and sequencing results indicate that the GmAhas1 sequence corresponds to the Als1 gene sequence controlling SU resistance in soybean. The molecular breeding tools described herein create the basis to speed up the identification of new mutations in soybean AHAS leading to enhanced levels of resistance to SU or to other families of AHAS inhibitor herbicides.     

A mutation at the Ala122 position of acetohydroxyacid synthase (AHAS) located on chromosome 6D of wheat: improved resistance to imidazolinone and a faster assay for marker assisted selection

A new mutation at the acetohydroxyacid synthase (AHAS) locus on chromosome 6D of wheat was analyzed in detail because it conferred an improved resistance to the imidazolinone group of herbicides. Sequence analysis showed that the mutation was at the Ala122 position (A122T), a position in AHAS which has not to date been identified in imidazolinone resistant wheat lines even though the position has been identified in other plants and is associated with resistance. An allele-specific assay for the mutation (in the wheat line Brookton-8) was developed and used in a genetic analysis. Two mapping populations were analysed and the doubled haploid progeny from the cross Brookton-8 × Clearfield STL proved to be most informative. The AHAS^Ala122 mutation (A122T) was allelic to the AHAS^Ser653 mutation (S653N) in Clearfield STL (Imi1, on chromosome 6D) and hence was assigned to the chromosome 6D locus. The analysis of the doubled haploid lines in the mapping population demonstrated the greater resistance conferred by the A122T mutation because lines from the same cross and carrying either the A122T or S653N mutations could be directly compared. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Mapping and identification of a Cicer arietinum NSP2 gene involved in nodulation pathway

Key message

For the first time the putative NSP2 gene in chickpea has been identified using pairs of NILs differing for the Rn1 / rn1 nodulation gene that was located in LG5 of chickpea genetic map.

Abstract

An intraspecific cross between the mutant non-nodulating genotype PM233, carrying the recessive gene rn1, and the wild-type CA2139 was used to develop two pairs of near-isogenic lines (NILs) for nodulation in chickpea. These pairs of NILs were characterized using sequence tagged microsatellite site (STMS) markers distributed across different linkage groups (LGs) of the chickpea genetic map leading to the detection of polymorphic markers located in LG5. Using this information, together with the genome annotation in Medicago truncatula, a candidate gene (NSP2) known to be involved in nodulation pathway was selected for mapping in chickpea. The full length sequence obtained in chickpea wild-type (CaNSP2) was 1,503 bp. Linkage analysis in an F₃ population of 118 plants derived from the cross between the pair of NILS NIL7-2A (nod) × NIL7-2B (non-nod) revealed a co-localization between CaNSP2 and Rn1 gene. These data implicate the CaNSP2 gene as a candidate for identity to Rn1, and suggest that it could act in the nodulation signaling transduction pathway similarly to that in other legumes species.     

Development of transgenic imazapyr-tolerant cowpea (Vigna unguiculata)

Key message

Here we present the development of cowpea lines tolerant to a herbicide from imidazoline class (imazapyr). Plants presented tolerance to fourfold the commercial recommended dose for weed control.

Abstract

Cowpea is one of the most important and widely cultivated legumes in many parts of the world. Its cultivation is drastically affected by weeds, causing damages during growth and development of plants, competing for light, nutrients and water. Consequently, weed control is critical, especially using no-tillage farming systems. In tropical regions, no-till farming is much easier with the use of herbicides to control weeds. This study was conducted to evaluate the possibility of obtaining transgenic cowpea plants resistant to imidazolinone, which would facilitate weed control during the summer season. The biolistic process was used to insert a mutated acetohydroxyacid synthase coding gene (Atahas) which confers tolerance to imazapyr. The transgene integration was confirmed by Southern blot analysis. Out of ten lines tested for tolerance to 100 g ha^?1 imazapyr, eight presented some tolerance. One line (named 59) revealed high herbicide tolerance and developmental growth comparable to non-transgenic plants. This line was further tested for tolerance to higher herbicide concentrations and presented tolerance to 400 g ha^?1 imazapyr (fourfold the commercial recommended dose) with no visible symptoms. Line 59 will be the foundation for generating imidazolinone-tolerant cowpea varieties, which will facilitate cultivation of this crop in large areas.     

Mutations in corn (Zea mays L.) conferring resistance to imidazolinone herbicides

Summary Three corn (Zea mays L.) lines resistant to imidazolinone herbicides were developed by in vitro selection and plant regeneration. For all three lines, resistance is inherited as a single semidominant allele. The resistance alleles from resistant lines XA17, XI12, and QJ22 have been crossed into the inbred line B73, and in each case homozygotes are tolerant of commercial use rates of imidazolinone herbicides. All resistant selections have herbicide-resistant forms of acetohydroxyacid synthase (AHAS), the known site of action of imidazolinone herbicides. The herbicide-resistant phenotypes displayed at the whole plant level correlate directly with herbicide insensitivity of the AHAS activities of the selections. The AHAS activities from all three selections have normal feedback regulation by valine and leucine, and plants containing the mutations display a normal phenotype.     

Resistance mechanism to acetyl coenzyme A carboxylase inhibiting herbicides in Phalaris paradoxa collected in Mexican wheat fields

Background and aims

In this study, we describe the molecular, physiological and agronomic aspects involved in the resistance to acetyl coenzyme A carboxylase inhibiting herbicides (ACCase) observed in one biotype of Phalaris paradoxa from Mexico.

Methods

Dose–response Assays: The herbicide rate inhibiting plant growth of each biotype by 50% with respect to the untreated control, ED₅₀. Enzyme purification and ACCase assays to determine herbicide rate inhibiting the enzyme of each biotype by 50% with respect to the untreated control, I₅₀. Absorption and Translocation Assays with [¹⁴C]diclofop-methyl. Metabolism of diclofop-methyl and its metabolites were identified by thin-layer chromatography. Study of target site resistance mechanism at enzyme and molecular levels.

Results

In this work, it has been studied the whole-plant response of Phalaris paradoxa biotypes from Mexico resistant (R) and susceptible (S) to ACCase-inhibiting herbicides: aryloxyphenoxypropionate (APP), cyclohexanedione (CHD) and phenylpyrazoline (PPZ), and the mechanism behind their resistance were studied. To analyse the resistance mechanism, the enzyme ACCase activity was investigated. Results from biochemical assays indicated a target-site resistance as the cause of reduced susceptibility to ACCase inhibitors. The absorption, translocation and metabolism were similar between R and S biotypes. A point mutation never described before was detected within the triplet of glycine at the amino acid position 2096 (referring to EMBL accession no. AJ310767) and resulted in the triplet of serine. This new mutation could explain the loss of affinity for the ACCase-inhibiting herbicides.

Conclusions

We found a new mutation, which had never been described before. This mutation was detected within the triplet of glycine at the amino acid position 2096. This new mutation confers cross-resistance to three different chemical groups of ACCase-inhibiting herbicides.     

Structure and mechanism of inhibition of plant acetohydroxyacid synthase

Plants and microorganisms synthesize valine, leucine and isoleucine via a common pathway in which the first reaction is catalysed by acetohydroxyacid synthase (AHAS, EC 2.2.1.6). This enzyme is of substantial importance because it is the target of several herbicides, including all members of the popular sulfonylurea and imidazolinone families. However, the emergence of resistant weeds due to mutations that interfere with the inhibition of AHAS is now a worldwide problem. Here we summarize recent ideas on the way in which these herbicides inhibit the enzyme, based on the 3D structure of Arabidopsis thaliana AHAS. This structure also reveals important clues for understanding how various mutations can lead to herbicide resistance.     

A novel selection system for potato transformation using a mutated AHAS gene

Acetohydroxyacid synthase (AHAS) is the target enzyme for a number of herbicides. A S653N mutation in the AHAS gene results in an increased tolerance to imidazolinone herbicides. We have investigated the use of the mutated gene as selection gene for potato transformation. This resulted in a transformation system with a very high transformation frequency and low rate of escapes. The mutated AHAS gene was introduced into transformed potato together with a -glucuronidase (GUS) gene. Selection on 0.5 M Imazamox yielded GUS expression in 93–100% of regenerated shoots. Furthermore the mutated AHAS gene was used as selection gene for production of high-amylopectin potato lines. The high transformation frequency was verified and potato lines with the desirable starch quality were obtained.Abbreviations ABA Abscisic acid - AHAS Acetohydroxyacid synthase - BAP 6-Benzylaminopurine - 2,4-D 2, 4-Dichlorophenoxyacetic acid - GA₃ Gibberellic acid - GBSS Granule bound starch synthase - GUS -Glucuronidase - MS medium Murashige and Skoog medium - NAA -Naphthaleneacetic acid - nos Nopaline synthase - OCS Octopine synthase - PCR Polymerase chain reaction - X-gluc 5-Bromo-4-chloro-3-indolyl-beta-d-glucuronic acid - YEB Yeast extract brothCommunicated by R. Schmidt     

Herbicide-resistant Acala and Coker cottons transformed with a native gene encoding mutant forms of acetohydroxyacid synthase

Herbicide-resistant transgenic cotton (Gossypium hirsutum L.) plants carrying mutant forms of a native acetohydroxyacid synthase (AHAS) gene have been obtained by Agrobacterium and biolistic transformation. The native gene, A19, was mutated in vitro to create amino acid substitutions at residue 563 or residue 642 of the precursor polypeptide. Transformation with the mutated forms of the A19 gene produced resistance to imidazolinone and sulfonylurea herbicides (563 substitution), or imidazolinones only (642 substitution). The herbicide-resistant phenotype of transformants was also manifested in their in vitro AHAS activity. Seedling explants of both Coker and Acala cotton varieties were transformed with the mutated forms of the A19 gene using Agrobacterium. In these experiments, hundreds of transformation events were obtained with the Coker varieties, while the Acala varieties were transformed with an efficiency about one-tenth that of Coker. Herbicide-resistant Coker and Acala plants were regenerated from a subset of transformation events. Embryonic cell suspension cultures of both Coker and Acala varieties were biolistically transformed at high frequencies using cloned cotton DNA fragments carrying the mutated forms of the A19 gene. In these transformation experiments the mutated A19 gene served as the selectable marker, and the efficiency of selection was comparable to that obtained with the NPT II gene marker of vector Bin 19. Using this method, transgenic Acala plants resistant to imidazolinone herbicides were obtained. Southern blot analyses indicated the presence of two copies of the mutated A19 transgene in one of the biolistically transformed R₀ plants, and a single copy in one of the R₀ plants transformed with Agrobacterium. As expected. progeny seedlings derived from outcrosses involving the R₀ plant transformed with Agrobacterium segregated in a 1:1 ratio with respect to herbicide resistance. The resistant progeny grew normally after irrigation with 175 g/l of the imidazolinone herbicide imazaquin, which is five times the field application rate. In contrast, untransformed sibling plants were severely stunted.Abbreviations AHAS acetohydroxyacid synthase - CaMV cauliflower mosaic virus - ELISA enzyme linked immunosorbent assay - FW fresh weight - GUS -glucuronidase - IC₅₀ herbicide concentration that produces a 50% reduction in the fresh weight growth of cells - NAA -naphthaleneacetic acid - NPT II neomycin phosphotransferase II - MS Murashige and Skoog (1962)     

Characterization and molecular mechanism of a naturally occurring metsulfuron-methyl resistant strain of Pseudomonas aeruginosa

Strain L36, naturally resistant to the herbicide metsulfuron-methyl (SM), was isolated and characterized with respect to the molecular mechanism of resistance. The isolate was identified as Pseudomonas aeruginosa based on bacterial morphology, physiology, cellular fatty acid, and 16S rRNA gene sequence. Minimal inhibitory concentrations of metsulfuron-methyl against the growth of L36 and wild type isolate PAO1 were 6.03 and 1.33 mM, respectively. L36 carried a nucleotide base change in the acetolactate synthase (ALS) gene that coded for a single amino acid mutation (Ala29 → Val29). The mutated ilvIH gene was functionally expressed, purified, and the kinetic properties of the purified ALS were tested. The mutant enzyme had K _m for pyruvate fourfold higher than the wild type enzyme, and K _i ^app for sulfonylureas some 30-fold higher. The A29 V mutation in the ALS resulted in the resistance of P. aeruginosa to sulfonylurea herbicides but not to imidazolinone herbicides.     

A Mutation Causing Imidazolinone Resistance Maps to the Csr1 Locus of Arabidopsis thaliana

A mutant of Arabidopsis thaliana, two hundred times more resistant to the imidazolinone herbicide imazapyr than wild-type plants, was isolated by direct selection of seedlings from a mutagenized population. Genetic analysis showed that resistance is due to a single dominant nuclear mutation that could not be separated by recombination from a mutation in the CSR1 gene encoding acetohydroxy acid synthase. Acetohydroxy acid synthase activity in extracts isolated from the mutant was 1000-fold more resistant to inhibition by imazapyr than that of the wild type. The resistant enzyme activity cosegregated with whole plant resistance. These data strongly suggest that the mutation is an allele of CSR1 encoding an imazapyr-resistant AHAS.     

An acetohydroxy acid synthase mutant reveals a single site involved in multiple herbicide resistance

Acetohydroxy acid synthase (AHAS) is an essential enzyme for many organisms as it catalyzes the first step in the biosynthesis of the branched-chain amino acids valine, isoleucine, and leucine. The enzyme is under allosteric control by these amino acids. It is also inhibited by several classes of herbicides, such as the sulfonylureas, imidazolinones and triazolopyrimidines, that are believed to bind to a relic quinone-binding site. In this study, a mutant allele of AHAS3 responsible for sulfonylurea resistance in a Brassica napus cell line was isolated. Sequence analyses predicted a single amino acid change (557 TrpLeu) within a conserved region of AHAS. Expression in transgenic plants conferred strong resistance to the three classes of herbicides, revealing a single site essential for the binding of all the herbicide classes. The mutation did not appear to affect feedback inhibition by the branched-chain amino acids in plants.     

Molecular basis of sulfonylurea herbicide inhibition of acetohydroxyacid synthase

Acetohydroxyacid synthase (AHAS) (acetolactate synthase, EC ) catalyzes the first step in branched-chain amino acid biosynthesis and is the target for sulfonylurea and imidazolinone herbicides. These compounds are potent and selective inhibitors, but their binding site on AHAS has not been elucidated. Here we report the 2.8 A resolution crystal structure of yeast AHAS in complex with a sulfonylurea herbicide, chlorimuron ethyl. The inhibitor, which has a K(i) of 3.3 nm, blocks access to the active site and contacts multiple residues where mutation results in herbicide resistance. The structure provides a starting point for the rational design of further herbicidal compounds.     

Multiple allelic forms of acetohydroxyacid synthase are responsible for herbicide resistance in <Emphasis Type="Italic">Setaria viridis</Emphasis>

In weed species, resistance to herbicides inhibiting acetohydroxyacid synthase (AHAS) is often conferred by genetic mutations at one of six codons in the AHAS gene. These mutations provide plants with various levels of resistance to different chemical classes of AHAS inhibitors. Five green foxtail [Setaria viridis (L.) Beauv.] populations were reported in Ontario with potential resistance to the AHAS-inhibiting herbicide imazethapyr. The objectives of this study were to confirm resistance, establish the resistance spectrum for each of the five populations, and determine its genetic basis. Dose response curves were generated for whole plant growth and enzyme activity, and the AHAS gene was sequenced. Resistance was confirmed by determining the resistance factor to imazethapyr in the five resistant green foxtail populations for whole plant dose response experiments (21- to 182-fold) and enzyme assays (15- to 260-fold). All five imazethapyr-resistant populations showed cross-resistance to nicosulfuron and flucarbazone while only three populations had cross-resistance to pyrithiobac. Sequence analyses revealed single base-pair mutations in the resistant populations of green foxtail. These mutations were coded for Thr, Asn, or Ile substitution at Ser₆₅₃. In addition, a new mutation was found in one population that coded for an Asp substitution at Gly₆₅₄. There is an agreement between the spectra of resistance observed and the type of resistance known to be conferred by these substitutions. Moreover, it indicates that, under similar selection pressure (imazethapyr), a variety of mutations can be selected for different populations, making the resistance pattern difficult to predict from herbicide exposure history.