Mutations in sdh genes in field isolates of Zymoseptoria tritici and impact on the sensitivity to various succinate dehydrogenase inhibitors

Zymoseptoria tritici is the causal agent of septoria tritici blotch (STB), a foliar wheat disease important worldwide. Succinate dehydrogenase inhibitors (SDHIs) have been used in cereals for effective control of STB for several years, but resistance towards SDHIs has been reported in several phytopathogenic fungi. Resistance mechanisms are target‐site mutations in the genes coding for subunits B, C and D of the succinate dehydrogenase (SDH) enzyme. Previous monitoring data in Europe indicated the presence of single isolates of Z. tritici with reduced SDHI sensitivity. These isolates carried mutations leading to amino acid exchanges: C‐T79N, C‐W80S in 2012; C‐N86S in 2013; B‐N225T and C‐T79N in 2014; and C‐V166M, B‐T268I, C‐N86S, C‐T79N and C‐H152R in 2015. The current study provides results from microtitre and greenhouse experiments to give an insight into the impact of different mutations in field isolates on various SDHIs. In microtitre tests, the highest EC₅₀ values for all tested SDHIs were obtained with mutants carrying C‐H152R. Curative greenhouse tests with various SDHIs confirmed the findings of microtitre tests that isolates with C‐H152R are, in general, controlled with lower efficacy than isolates carrying B‐T268I, C‐T79N and C‐N86S. SDHI‐resistant isolates of Z. tritici found in the field were shown to have cross‐resistance towards all SDHIs tested. So far, SDHI‐resistant isolates of Z. tritici have been found in low frequencies in Europe. Therefore, FRAC recommendations for resistance management in cereals, including a limited number of applications, alternation and combination with other MOAs, should be followed to prolong SDHI field efficacy.     

琥珀酸脱氢酶抑制剂类杀菌剂抗性研究进展

作用于琥珀酸脱氢酶复合体的新型杀菌剂-琥珀酸脱氢酶抑制剂 (succinate dehydrogenase inhibitors, SDHIs) 已逐步成为继Qo位点呼吸抑制剂类 (QoIs) 和麦角甾醇生物合成抑制剂类(EBIs)杀菌剂之后的世界第3大类杀菌剂。近年来,SDHIs杀菌剂的市场占有份额逐年增加,新品种不断涌现,在植物病害化学防治中发挥着重要作用。然而,由于该类杀菌剂作用位点单一,抗药性已成为制约该类杀菌剂创制发展与科学应用的重要科学问题。本综述归纳了琥珀酸脱氢酶抑制剂类杀菌剂的开发、品种、抗性发生发展、抗性分子机制与应用现状,并结合作者研究团队的最新研究成果对其靶标生物学及应用技术研究进行了总结,以期为更高活性的SDHIs杀菌剂创制和应用提供参考。     

Non‐target site SDHI resistance is present as standing genetic variation in field populations of Zymoseptoria tritici

BACKGROUND

A new generation of more active succinate dehydrogenase (Sdh) inhibitors (SDHIs) is currently widely used to control Septoria leaf blotch in northwest Europe. Detailed studies were conducted on Zymoseptoria tritici field isolates with reduced sensitivity to fluopyram and isofetamid; SDHIs which have only just or not been introduced for cereal disease control, respectively.

RESULTS

Strong cross‐resistance between fluopyram and isofetamid, but not with other SDHIs, was confirmed through sensitivity tests using laboratory mutants and field isolates with and without Sdh mutations. The sensitivity profiles of most field isolates resistant to fluopyram and isofetamid were very similar to a lab mutant carrying SdhC‐A84V, but no alterations were found in SdhB, C and D. Inhibition of mitochondrial Sdh enzyme activity and control efficacy in planta for those isolates was severely impaired by fluopyram and isofetamid, but not by bixafen. Isolates with similar phenotypes were not only detected in northwest Europe but also in New Zealand before the widely use of SDHIs.

CONCLUSION

This is the first report of SDHI‐specific non‐target site resistance in Z. tritici. Monitoring studies show that this resistance mechanism is present and can be selected from standing genetic variation in field populations. © 2017 The Authors. Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.     

A reassessment of the risk of rust fungi developing resistance to fungicides

Rust fungi are major pathogens of many annual and perennial crops. Crop protection is largely based on genetic and chemical control. Fungicide resistance is a significant issue that has affected many crop pathogens. Some pathogens have rapidly developed resistance and hence are regarded as high‐risk species. Rust fungi have been classified as being low risk, in spite of sharing many relevant features with high‐risk pathogens. An examination of the evidence suggests that rust fungi may be wrongly classified as low risk. Of the nine classes of fungicide to which resistance has developed, six are inactive against rusts. The three remaining classes are quinone outside inhibitors (QoIs), demethylation inhibitors (DMIs) and succinate dehydrogenase inhibitors (SDHIs). QoIs have been protected by a recently discovered intron that renders resistant mutants unviable. Low levels of resistance have developed to DMIs, but with limited field significance. Older SDHI fungicides were inactive against rusts. Some of the SDHIs introduced since 2003 are active against rusts, so it may be that insufficient time has elapsed for resistance to develop, especially as SDHIs are generally sold in mixtures with other actives. It would therefore seem prudent to increase the level of vigilance for possible cases of resistance to established and new fungicides in rusts. © 2014 Society of Chemical Industry     

Foliar application of benzovindiflupyr shows non‐fungicidal effects in wheat plants

BACKGROUND

The fungicide benzovindiflupyr belongs to the class of succinate dehydrogenase inhibitors (SDHIs). Certain SDHIs have shown plant physiological effects, so‐called secondary effects, that appeared to be related to the plant water status. Therefore, the effect of benzovindiflupyr on transpiration of leaves and whole wheat plants was studied under controlled conditions. Furthermore, wheat yield trials under controlled and natural drought stress in the field were conducted.

RESULTS

Transpiration of detached wheat leaves was reduced by benzovindiflupyr in a dose‐dependent manner. Similarly, whole‐plant transpiration decreased for several days following application of this fungicide. In 16 field trials under drought stress conditions that were classified as disease‐free, treatment of wheat plants at the flag leaf stage or at heading with benzovindiflupyr showed a grain yield increase (+5.2%; P ≤ 0.01) that was partially attributed to an increased thousand‐grain weight.

CONCLUSIONS

Water saving during pre‐anthesis as a result of benzovindiflupyr application may be associated with better seed setting and filling under dry field conditions in wheat. The results of this research provide new insights into secondary effects of SDHIs that lead directly to yield improvements. © 2017 The Authors. Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.     

Amino acid substitutions responsible for different QoI and SDHI sensitivity patterns in Puccinia horiana,the causal agent of chrysanthemum white rust

Quinone outside inhibitors (QoIs) and succinate dehydrogenase inhibitors (SDHIs) are major groups of agricultural fungicides. However, resistance to some of these fungicides has been reported in a Japanese population of Puccinia horiana, the causal agent of chrysanthemum white rust disease. Because their mechanisms are not well understood, we investigated the existence of mutations in QoI and SDHI target protein-encoding genes. Eight out of nine isolates from cultivated chrysanthemum carried L275F and L299F amino acid substitutions in cytochrome b, the target protein of QoIs. These isolates showed 23- and 17-fold higher EC₅₀ values for the QoI fungicides azoxystrobin and kresoxim-methyl, respectively, in basidiospore germination inhibitory tests, while they were hypersensitive to another QoI, famoxadone. All nine isolates were resistant to SDHI oxycarboxin and carried the I88F substitution in SdhC. This substitution was orthologous to the SdhC-I86F substitution found in some Brazilian isolates of the soybean rust fungus, Phakopsora pachyrhizi, showing reduced sensitivity to some SDHIs. Although the rarity of wild-type sensitive isolates, the subsequent limited number of comparisons between wild types and mutants, and a difficulty in applying reverse genetic analysis to this obligate parasite, are obstacles in making definitive conclusions, L275F and L299F in cytochrome b and SdhC-I88F are suspected to be responsible for the different patterns of sensitivity to QoI and for oxycarboxin-resistance in P. horiana, respectively.     

Fungicide resistance status in French populations of the wheat eyespot fungi Oculimacula acuformis and Oculimacula yallundae

Eyespot, caused by Oculimacula acuformis and Oculimacula yallundae, is the major foot disease of winter wheat in several European countries, including France. It can be controlled by chemical treatment between tillering and the second node stage. The fungicides used include antimicrotubule toxicants (benzimidazoles), inhibitors of sterol 14α‐demethylation (DMIs) or of succinate dehydrogenase (SDHIs), the anilinopyrimidines cyprodinil and the benzophenone metrafenone. Since the early 1980s, a long‐term survey has been set up in France to monitor changes in the sensitivity of eyespot populations to fungicides. Resistance to benzimidazoles has become generalised since the early 1990s, in spite of the withdrawal of this class of fungicides. In the DMI group, resistance to triazoles is generalised, whereas no resistance to the triazolinethione prothioconazole has yet developed. Resistance to the imidazole prochloraz evolved successively in O. acuformis and O. yallundae and is now well established. Specific resistance to cyprodinil has also been detected, but its frequency has generally remained low. Finally, since the early 2000s, a few strains of O. yallundae displaying multidrug resistance (MDR) have been detected. These strains display low levels of resistance to prothioconazole and SDHIs, such as boscalid. Knowledge of the spatiotemporal distribution in France of O. acuformis and O. yallundae field strains resistant to fungicides allows resistance management strategies for eyespot fungi in winter wheat to be proposed.© 2012 Society of Chemical Industry     

Molecular characterization of boscalid- and penthiopyrad-resistant isolates of Didymella bryoniae and assessment of their sensitivity to fluopyram

BACKGROUND: Didymella bryoniae has a history of developing resistance to single‐site fungicides. A recent example is with the succinate‐dehydrogenase‐inhibiting fungicide (SDHI) boscalid. In laboratory assays, out of 103 isolates of this fungus, 82 and seven were found to be very highly resistant (B^VHR) and highly resistant (B^HR) to boscalid respectively. Cross‐resistance studies with the new SDHI penthiopyrad showed that the B^VHR isolates were only highly resistant to penthiopyrad (B^VHR‐P^HR), while the B^HR isolates appeared sensitive to penthiopyrad (B^HR‐P^S). In this study, the molecular mechanism of resistance in these two phenotypes (B^VHR‐P^HR and B^HR‐P^S) was elucidated, and their sensitivity to the new SDHI fluopyram was assessed. RESULTS: A 456 bp cDNA amplified fragment of the succinate dehydrogenase iron sulfur gene (DbSDHB) was initially cloned and sequenced from two sensitive (B^S‐P^S), two B^VHR‐P^HR and one B^HR‐P^S isolate of D. bryoniae. Comparative analysis of the DbSDHB protein revealed that a highly conserved histidine residue involved in the binding of SDHIs and present in wild‐type isolates was replaced by tyrosine (H277Y) or arginine (H277R) in the B^VHR‐P^HR and B^HR‐P^S variants respectively. Further examination of the role and extent of these alterations showed that the H/Y and H/R substitutions were present in the remaining B^VHR‐P^HR and B^HR‐P^S variants respectively. Analysis of the sensitivity to fluopyram of representative isolates showed that both SDHB mutants were sensitive to this fungicide as the wild‐type isolates. CONCLUSION: The genotype‐specific cross‐resistance relationships between the SDHIs boscalid and penthiopyrad and the lack of cross‐resistance between these fungicides and fluopyram should be taken into account when selecting SDHIs for gummy stem blight management. Copyright © 2011 Society of Chemical Industry     

樱桃褐腐病菌对啶酰菌胺的敏感性及其对4种琥珀酸脱氢酶抑制剂的交互抗性

采用菌丝生长速率法测定了樱桃褐腐病菌Monilinia fructicola对啶酰菌胺的敏感性,同时研究了不同敏感性菌株的生物学性状,探究了琥珀酸脱氢酶B亚基的氨基酸突变与其对啶酰菌胺产生抗性的相关性,并分析了樱桃褐腐病菌对啶酰菌胺与其他3种琥珀酸脱氢酶抑制剂(SDHIs)氯苯醚酰胺、氟唑菌苯胺和氟吡菌酰胺之间的交互抗...     

Lack of cross-resistance to a novel succinate dehydrogenase inhibitor, fluopyram, in highly boscalid-resistant isolates of Corynespora cassiicola and Podosphaera xanthii

BACKGROUND: Recently in Japan, isolates resistant to boscalid, a succinate dehydrogenase inhibitor (SDHI), have been detected in Corynespora cassiicola (Burk. & Curt.) Wei and Podosphaera xanthii (Castaggne) Braun & Shishkoff, the pathogens causing Corynespora leaf spot and powdery mildew disease on cucumber, respectively. Resistant isolates of C. cassiicola are widely distributed and represent a serious problem in disease control at present. Novel SDHI fungicides, including fluopyram, are now under development. RESULTS: The growth of very highly boscalid‐resistant, highly resistant and sensitive isolates of C. cassiicola was strongly suppressed on fluopyram‐amended YBA agar medium. Although boscalid and another SDHI, penthiopyrad, hardly controlled Corynespora leaf spot and powdery mildew on cucumber plants when very highly or highly boscalid‐resistant isolates were employed for inoculation, fluopyram still exhibited excellent control efficacy against these resistant isolates as well as sensitive isolates of C. cassiicola and P. xanthii. CONCLUSION: Differential sensitivity to boscalid, penthiopyrad and fluopyram, clearly found in these two important pathogens of cucumber, may indicate involvement of a slightly distinct site of action for fluopyram from the two other SDHIs. This finding may lead to the discovery of unique SDHIs in the future. Copyright © 2011 Society of Chemical Industry     

琥珀酸脱氢酶抑制剂类杀菌剂水生生态毒理学研究进展

作为当前杀菌剂市场的主要种类之一,琥珀酸脱氢酶抑制剂类 (SDHIs) 杀菌剂的广泛应用导致其易进入水体环境,威胁水生生物的安全。大量研究表明,该类药剂中大部分品种对水生生物的急性毒性较高,部分甚至达到剧毒级,并且在较低浓度下即可对水生生物产生毒性效应,不同程度影响水生生物的生长、发育和繁殖,进而导致水生生态系统的失衡。文章综述了SDHIs杀菌剂对水体环境的污染状况及其对水生生物的毒性效应及作用机制的研究进展,展望了该类杀菌剂的水生生态毒理学研究重点和未来发展方向,旨在为减少SDHIs杀菌剂对水生生态系统的影响提供理论依据。     

Biological and molecular characterization of field isolates of <Emphasis Type="Italic">Alternaria alternata</Emphasis> with single or double resistance to respiratory complex II and III inhibitors

Field isolates of Alternaria alternata collected from tomato processors were characterized for sensitivity to respiration inhibitors using in vitro mycelial growth assays. Pyraclostrobin (QoI), boscalid, fluopyram and isopyrazam (SDHIs) mean EC₅₀ values were 0.32, 1.43, 2.21, and 3.53 μg/ml respectively. Of the 42 isolates, 36 were sensitive to all respiration inhibiting fungicides tested whereas three isolates were less sensitive to boscalid, one to pyraclostrobin and two were simultaneously resistant to both inhibitors and isopyrazam. Correlation analysis between fungicide sensitivities revealed a positive cross-resistance between pyraclostrobin and tebuconazole, and between cyprodinil and mancozeb. There was no cross-resistance between QoIs, SHDIs or any other mode of action. Sequencing of the QoI and SDHI targets revealed the G143A cytochrome b resistance mutation in all pyraclostrobin-resistant isolates while analysis of the succinate dehydrogenase coding gene revealed point mutations in two of three of the gene subunits analyzed in boscalid-resistant isolates. Specifically, two isolates carried the H277Y and three the H133Q resistance mutations located in the sdhB and sdhD subunits of the respiration complex II, respectively. Isolates bearing the H277Y mutation also carried the G143A cytochrome b resistance mutation. Boscalid and pyraclostrobin-resistant isolates exhibited greater pathogenicity and sporulation compared to sensitive isolates, respectively. Isolates with cross-resistance exhibited greater pathogenicity and sporulation but slower mycelial growth compared to sensitive isolates. This is the first report of field isolates of A. alternata with single or double resistance to QoIs and SDHIs in Greece and should be considered in planning and implementing effective anti-resistance strategies.     

Fungicide resistance status and chemical control options for the brassica pathogen Pyrenopeziza brassicae

Pyrenopeziza brassicae causes leaf spot disease of Brassicaceae in Europe/Oceania (lineage 1) and North America (lineage 2). In Europe, fungicides currently used for disease management are sterol 14α-demethylase (CYP51) inhibitors (azoles), quinone outside inhibitors (QoIs), and succinate dehydrogenase inhibitors (SDHIs); methyl benzimidazole carbamates (MBCs) are no longer applied. In this study, in vitro screening revealed European populations (collected 2018–2020) had shifted towards decreased azole sensitivity, but the North American population (2014–2016) was highly sensitive. Genotyping revealed CYP51 substitutions G460S or S508T were prevalent in European populations, often with a CYP51 promoter insert. Compared to wildtype CYP51 isolates, those with G460S plus an insert (44/46/151/210/302 bp) were c.25–32-fold and c.50-fold less sensitive to tebuconazole and prochloraz, respectively; those with S508T plus an insert (44/46/151/233 bp) were c.9–15-fold and c.25–40-fold less sensitive to tebuconazole and prochloraz, respectively. Selection for G460S (quantified via pyrosequencing) under different fungicide regimes was investigated in UK field trials, but G460S levels were high (c.76%) before treatment, so further selection during the trials was unclear. Despite the high G460S frequency and low disease pressure, yield data indicated measurable benefit for both azole- and non-azole-based programmes. In vitro screening against the MBC carbendazim showed European populations were predominantly moderately resistant/resistant; the North American population was sensitive. European and North American populations were sensitive to QoI (pyraclostrobin) and SDHI (penthiopyrad) fungicides. Results support an azole plus QoI/SDHI mixing partner for robust disease control and decreased risk of resistance, with continued sensitivity monitoring to ensure optimal strategies are deployed.     

贵州省烟草赤星病菌对啶酰菌胺的敏感性基线

对2014—2015年采自贵州省田间未使用过琥珀酸脱氢酶抑制剂 (SDHIs) 的烟草赤星病病样进行了病原菌分离和鉴定,并采用菌丝生长速率法建立了烟草赤星病菌群体对啶酰菌胺的敏感性基线。结果表明:虽然烟草赤星病菌不同菌株在菌落、孢子形态和致病性上有较大差异,但均属于交链格孢Alternaria alternata。啶酰菌胺抑制赤星病菌群体 (n = 102) 菌丝生长的EC₅₀值在0.186~5.818 μg/mL之间,平均EC₅₀值为 (2.157 ± 1.112) μg/mL,不同敏感性菌株频率分布为连续的单峰曲线,该平均EC₅₀值可以作为烟草赤星病菌对啶酰菌胺的敏感性基线。进一步研究表明,贵州省烟草赤星病菌的Sdh B基因在第209位、277位和224位等密码子存在核苷酸多样性,但未发现这种多样性与烟草赤星病菌对啶酰菌胺的敏感性之间存在关联。     

Biological activity of the succinate dehydrogenase inhibitor fluopyram against Botrytis cinerea and fungal baseline sensitivity

BACKGROUND: Succinate dehydrogenase inhibitors (SDHIs) constitute a fungicide class with increasing relevance in crop protection. These fungicides could play a crucial role in successful management of grey mould disease. In the present study the effect of fluopyram, a novel SDHI fungicide, on several developmental stages of Botrytis cinerea was determined in vitro, and the protective and curative activity against the pathogen was determined on strawberry fruit. Furthermore, fungal baseline sensitivity was determined in a set of 192 pathogen isolates. RESULTS: Inhibition of germ tube elongation was found to be the most sensitive growth stage affected by fluopyram, while mycelial growth was found to be the least sensitive growth stage. Fluopyram provided excellent protective activity against B. cinerea when applied at 100 µg mL^?1 96, 48 or 24 h before the artificial inoculation of the strawberry fruit. Similarly, fluopyram showed a high curative activity when it was applied at 100 µg mL^?1 24 h post‐inoculation, but, when applications were conducted 48 or 96 h post‐inoculation, disease control efficacy was modest or low. The measurement of baseline sensitivity showed that it was unimodal in all the populations tested. The individual EC₅₀ values for fluopyram ranged from 0.03 to 0.29 µg mL^?1. In addition, no correlation was found between sensitivity to fluopyram and sensitivity to other fungicides, including cyprodinil, fenhexamid, fludioxonil, iprodione, boscalid and pyraclostrobin. CONCLUSIONS: The obtained biological activity, baseline sensitivity and cross‐resistance relationship data suggest that fluopyram could play a key role in grey mould management in the near future and encourage its introduction into spray programmes. Copyright © 2011 Society of Chemical Industry     

Mode of action of new diethylamines in lycopene cyclase inhibition and in photosystem II turnover

The new bleaching herbicidal compound N,N‐diethyl‐N‐(2‐undecynyl)amine (NDUA) is identified here as an inhibitor of lycopene cyclase and is compared with the known cyclase inhibitors N,N‐diethyl‐N‐[2‐(4‐chlorophenylthio)ethyl]amine (CPTA) and N,N‐diethyl‐N‐[2‐(4‐methylphenoxy)ethyl]amine (MTPA). HPLC separation of chloroplast pigments shows lycopene accumulation in NDUA treated tissue. Variation in chain length of the undecynylamine moeity of NDUA from 7 to 21 C atoms reveals an optimum of 11 to 14 C atoms for herbicidal activity. A series of seven further analogues of NDUA and CPTA reveals the structural elements necessary for inhibition of lycopene cyclase. The effect of NDUA derivatives on photosynthesis has been studied in Chlamydomonas reinhardtii. Photosynthesis is highly sensitive, particularly towards the C14 and longer chain length analogues at nanomolar concentrations. It is shown that the breakdown of photosynthesis by NDUA is due to interference with the turnover of the D1 protein of the photosystem II reaction centre that requires the continous biosynthesis of the two reaction‐centre β‐carotene moieties in the reassembly phase. The D1 protein disappearance is most marked under strong light conditions. The depletion of photosystem II occurs before total pigment bleaching. This newly recognized mechanism in herbicidal activity is also the basis for the mode of action of other lycopene cyclase inhibitors as well as phytoene desaturase inhibitors. © 2001 Society of Chemical Industry     

Multiple resistance of Papaver rhoeas L. to 2,4‐D and acetolactate synthase inhibitors in four European countries

The issue of cross‐ or multiple resistance to acetolactate synthase (ALS) inhibitors and the auxinic herbicide 2,4‐D was investigated in Papaver rhoeas L., a common and troublesome weed in winter cereals, in a broad‐scale study across four European countries. A combination of herbicide sensitivity bioassays and molecular assays targeting mutations involved in resistance was conducted on 27 populations of P. rhoeas originating from Greece (9), Italy (5), France (10) and Spain (3). Plants resistant to the field rate of 2,4‐D were observed in 25 of the 27 populations assayed, in frequencies ranging from 5% to 85%. Plants resistant to ALS‐inhibiting herbicides (sulfonylureas) were present in 24 of the 27 populations, in frequencies ranging from 4% to 100%. Plants resistant to 2,4‐D co‐occurred with plants resistant to sulfonylureas in 23 populations. In four of these, the probability of presence of plants with cross‐ or multiple resistance to 2,4‐D and sulfonylureas was higher than 0.5. ALS genotyping of plants from the field populations or of their progenies, identified ALS alleles carrying a mutation at codon Pro197 or Trp574 in 2,4‐D‐sensitive and in 2,4‐D‐resistant plants. The latter case confirmed multiple resistance to 2,4‐D and ALS inhibitors at the level of individual plants in all four countries investigated. This study is the first to identify individual plants with multiple resistance in P. rhoeas, an attribute rarely assessed in other weed species, but one with significant implications in designing chemical control strategies.     

Effects of selective cutting and timing of herbicide application on growth and development of Cirsium arvense in spring barley

Recently, a new implement for controlling weeds in cereals (CombCut) has been developed. It cuts weeds in growing cereals without damaging them by using the physical differences (in height, stem thickness, straw stiffness and branching pattern) between crops and weeds. To evaluate and compare the effects of selective cutting with different timings of herbicide application on Cirsium arvense in spring barley, a randomised block experiment was conducted in Sweden in 2015–2017, in a field with a naturally occurring C. arvense population. Treatments consisted of control (C), herbicide application at 4–5‐leaf stage of C. arvense (H1), herbicide application at 8–10‐leaf stage (H2) and selective cutting at 10‐leaf stage (S). The treatments were performed in 2015 and repeated in 2016 in the same plots, and a final evaluation was performed in 2017. Compared to the control, S, H1 and H2 were equally efficient in reducing above‐ground biomass production of C. arvense and increasing spring barley grain yield per unit area. The number of C. arvense shoots per area was, however, higher in S compared to H1 and H2. No differences in control effects on shoot number were observed between H1 and H2. Our study indicates that (i) selective cutting (S) reduces C. arvense equally efficient as herbicide application and (ii) early herbicide spraying is as efficient as spraying later in the season.     

Structure-Activity Relationships for the Action of Dihydropyrazole Insecticides on Mouse Brain Sodium Channels

Assays of radiosodium uptake into mouse brain vesicles and the binding of [³H]batrachotoxinin A 20-α-benzoate (BTX-B) were used to compare the actions of six dihydropyrazole (3-aryl-1-arylcarbamoyl-2-pyrazoline) insecticides on mouse brain sodium channels. The relative potencies of the six dihydropyrazoles as inhibitors of either pumiliotoxin B-stimulated sodium uptake measured in the presence of scorpion (Leiurus quinquestriatus) venom or veratridine-stimulated sodium uptake were closely correlated with the relative potencies of these compounds as inhibitors of the binding of BTX-B to mouse brain sodium channels. A comparison of the enantiomers of the most potent dihydropyrazole, RH 3421, as inhibitors of radiosodium uptake showed that the (−) enantiomer of RH 3421 was approximately six-fold more potent than the (+) enantiomer. The potencies of these dihydropyrazoles in these assays and the stereoselectivity observed in the action of enantiomers of RH 3421 are in good agreement with available information on insecticidal activity in this group of compounds. Assays of the combined effects of RH 3421 and dibucaine as inhibitors of BTX-B binding revealed mutually competitive interactions between these compounds. This finding is consistent with the existence of a common site of action for dihydropyrazoles and local anesthetics on the sodium channel. The results of these studies provide further evidence for the toxicological relevance of the effects of dihydropyrazoles on sodium channels.     

Inhibitors of shikimate dehydrogenase as potential herbicides

Shikimate dehydrogenase (E.C. 1.1.1.25) is found in plants but not in animals and is therefore an attractive target for a new herbicide. A series of 1,6-dihydroxy-2-oxoisonicotinic acid derivatives was prepared and shown to inhibit the enzyme reversibly. Weak active-site directed irreversible inhibitors based on these compounds were also synthesised but none was herbicidal.