Identification of a tractable model system and oxalic acid-dependent symptom development of the dollar spot pathogen Clarireedia jacksonii

Clarireedia jacksonii causes dollar spot disease of cool-season turfgrasses in the United States and produces the phytotoxin oxalic acid. The role of oxalic acid in host–pathogen interactions of C. jacksonii is unknown and there are multiple challenges to studying these interactions in natural turfgrass hosts. Consequently, identification of model plants to study C. jacksonii–host interactions and the role of oxalic acid in pathogenesis is necessary. Controlled environment inoculation assays were used to evaluate pathogenesis of C. jacksonii in various model plants and investigate the role of oxalic acid in symptom development. Observations at microscopic and macroscopic levels demonstrated that infection progressed similarly in all monocots tested (creeping bentgrass, wheat, barley, rice, Brachypodium distachyon) but not in the dicot Arabidopsis thaliana. Plant oxalic acid content increased from near zero to around 0.2–0.4 mM following inoculation with C. jacksonii in creeping bentgrass, barley, and wheat. Conversely, oxalic acid content remained near zero in A. thaliana and was not well correlated with inoculation in rice and B. distachyon, both of which had higher endogenous oxalic acid levels than other monocots. Time-course oxalic acid quantification experiments with creeping bentgrass and B. distachyon further supported a link between symptom development and in planta oxalic acid content and identified 48 hr postinoculation as a critical time-point for investigating the role of oxalic acid in C. jacksonii pathogenesis. These studies demonstrate that various monocots can serve as tractable model systems for studying C. jacksonii–host interactions and that increases in oxalic acid content are associated with C. jacksonii symptom development.     

Phosphite-mediated enhancement of defence responses in Agrostis stolonifera and Poa annua infected by Microdochium nivale

The ascomycete fungus Microdochium nivale is one of the most damaging pathogens of cool season turfgrass. Prevention of and recovery from infection is costly to many sports facilities each year. In recent years, use of many chemical plant protectants has been restricted and turfgrass managers have increasingly sought alternative measures for disease control. The use of phosphite has been shown to be effective in reducing M. nivale disease symptoms in Agrostis stolonifera and Poa annua. The aim of this research was to assess initial defence responses in M. nivale-infected turfgrass, specifically total phenolic content and hydrogen peroxide generation, to determine the effect phosphite treatment has on these responses and on suppression of symptoms. Phenolic compounds and H₂O₂ are shown to be components of host responses. Phosphite treatment led to enhanced accumulations of total phenolic content, and when applied sequentially or singly to greenhouse plants, it led to significant reductions in M. nivale disease symptoms compared to phosphate-treated plants or controls. H₂O₂ extractions indicated that while phosphite treatment increased H₂O₂ generation compared to controls, the effect was no different to the responses in phosphate-treated plants.     

Snow cover has variable effects on persistence of fungicides and their suppression of microdochium patch on amenity turfgrass

Fungicides applied to turfgrass in temperate climates prior to snowfall are expected to suppress fungal diseases such as microdochium patch (Microdochium nivale) until infection conditions become unfavourable the following spring. However, mild winters with inconsistent snow cover may alter fungicide persistence and render the turf more susceptible to fungal infection. This study was conducted to determine the effect of snow cover on the persistence of the fungicides chlorothalonil and iprodione applied to creeping bentgrass (Agrostis stolonifera), maintained as a golf course fairway. The fungicides were applied 1 day prior to the first accumulating snowfall in Madison, Wisconsin, for four consecutive winters, beginning in 2009/10. Fungicide treatments were kept under continuous snow cover or maintained free of snow cover the entire winter to determine the effect of snow cover on fungicide persistence (2010/11 to 2012/13) and microdochium patch development in a controlled environment chamber (2009/10 to 2012/13). Iprodione concentration was not impacted by snow cover in 2010/11 but was reduced under snow cover relative to bare turf in 2011/12 and 2012/13. Chlorothalonil concentration was not impacted by snow cover in 2011/12 but was greater under snow cover in 2012/13. Microdochium patch severity in the controlled environment chamber was not impacted by snow cover with either fungicide in 2009/10 or 2011/12 but was slightly reduced under snow cover with both fungicides during 2010/11 and 2012/13. The majority of fungicide depletion occurred shortly after rainfall or snowmelt events, except in 2010/11 when both fungicides rapidly depleted during a warming trend without rainfall.     

Winter annual grassy weeds increase over‐winter mortality in autumn‐sown wheat

Over‐winter mortality, that is, winterkill, reduces cereal crop competitive ability and yield. While management and environmental variables are known to affect winterkill, the extent to which weeds contribute to increased winterkill is largely unknown. Winter annual weeds may increase winterkill through resource competition and by increasing incidence of and damage from plant pathogens that cause winterkill. We evaluated the impact of summer annual (Avena fatua) and winter annual (Bromus tectorum) weeds on the over‐winter survival rate of winter wheat over three winters, during which plots were covered with snow. Pink snow mould (Microdochium nivale), a winterkill pathogen known to infect B. tectorum and winter wheat, was common in wheat stands. In weed‐free treatments, mortality rates were initially near zero, but increased by nearly 45% in each subsequent winter, presumably due to an increase in snow mould disease in continuously cropped winter wheat. Whereas A. fatua infestation had no impact on crop survival rates, winter wheat survival in B. tectorum‐infested plots was 50% less than the weed‐free control in the second and third years of this study. Among B. tectorum‐infested plots, winter wheat over‐winter survival declined with increasing weed seed produced in the previous summer. Overall, this study demonstrated that winter annual weed infestations can reduce crop stand densities below replanting thresholds by reducing fall‐sown cereal winter survival. The effects of winter annual weeds on winter wheat may be meditated by increased proliferation of snow mould disease.     

ABA level, proline and phenolic concentration, and PAL activity induced during cold acclimation in androgenic Festulolium forms with contrasting resistance to frost and pink snow mould (Microdochium nivale)

The metabolic changes in foliar abscisic acid, proline and phenolic concentration, and PAL activity induced during cold acclimation in androgenic forms of Festulolium contrasting in terms of their resistance to frost and Microdochium nivale were studied. The frost-resistant and snow mould-resistant (cross-tolerant) genotype (561) was characterized by a higher ABA amount and higher PAL activity compared to those of the frost and snow mould-susceptible genotype (621) during cold acclimation. The obtained results suggest that both these parameters are involved in a cross-tolerance mechanism relating to frost and snow mould resistance.     

Suppression of Dollar Spot by Hypovirulent Isolates of Sclerotinia homoeocarpa

ABSTRACT Selected hypovirulent isolates of Sclerotinia homoeocarpa were evaluated for efficacy in suppressing dollar spot of turfgrass under growth room and field conditions. Under growth room conditions, hypovirulent isolates Sh12B, Sh09B, or Sh08D of S. homoeocarpa caused 3.4 to 30.4% diseased turf in comparison to virulent isolates Sh48B and Sh14D, which caused 80.2 to 90.2% disease. In treatments that received both virulent and hypovirulent isolates, only hypovirulent isolate Sh12B significantly reduced disease as compared with the control with virulent isolates alone. In a field experiment in 1993 on swards of creeping bentgrass artificially inoculated with a virulent isolate of the pathogen, all treatments containing hypovirulent isolate Sh12B applied as a mycelial suspension, granular mix, or alginate pellets developed significantly less disease (6.3 to 20.8% diseased turf) compared with their respective formulation controls (23.8 to 31.2%). Suppression of dollar spot by treatment with mycelial suspensions of isolate Sh12B was evident up to 45 days postinoculation, and disease suppression was still significant 1 year after application when compared with the water control. Applications of hypovirulent isolate Sh09B did not reduce dollar spot in any treatments. Significant suppression of dollar spot by isolate Sh12B was also observed in the experiment conducted in 1994. In addition, suppression of dollar spot by hypovirulent isolate Sh12B was evaluated on swards with naturally occurring inoculum during 1994. Treatments with a mycelial suspension and alginate pellets of hypovirulent isolate Sh12B significantly reduced dollar spot compared with their respective formulation controls. With few exceptions, there was no statistical difference between treatments with hypovirulent isolate Sh12B and the fungicide chlorothalonil (Daconil 2787). Multiple applications of the hypovirulent isolate did not result in greater suppression of dollar spot as compared with a single application. The results indicate that hypovirulence has potential as an effective strategy for the management of dollar spot.     

Differential Control of Head Blight Pathogens of Wheat by Fungicides and Consequences for Mycotoxin Contamination of Grain

Fusarium head blight of wheat is caused by a disease complex comprised of toxigenic pathogens, predominantly Fusarium spp., and a non-toxigenic pathogen Microdochium nivale, which causes symptoms visually indistinguishable from Fusarium and is often included as a causal agent of Fusarium head blight. Four field trials are reported here, including both naturally and artificially inoculated trials in which the effect of fungicide treatments were noted on colonisation by Fusarium and Microdochium, and on the production of deoxynivalenol (DON) mycotoxin. The pathogen populations were analysed with quantitative PCR and samples were tested for the presence of the mycotoxin DON. Application of fungicides to reduce Fusarium head blight gave a differential control of these fungi. Tebuconazole selectively controlled F. culmorum and F. avenaceum and reduced levels of DON, but showed little control of M. nivale. Application of azoxystrobin, however, selectively controlled M. nivale and allowed greater colonisation by toxigenic Fusarium species. This treatment also lead to increased levels of DON detected. nobreak Azoxystrobin application two days post-inoculation increased the production of DON mycotoxin per unit of pathogen in an artificially inoculated field trial. This result indicates the potential risk of increased DON contamination of grain following treatment with azoxystrobin to control head blight in susceptible wheat cultivars. This is the first study to show differential fungicidal control of mixed natural pathogen populations and artificial inoculations in field trials.     

Control of post‐harvest decay of apples by pre‐harvest and post‐harvest application of ammonium molybdate

Ammonium molybdate was tested as a potential fungicide for use in apples (cv Golden Delicious) against blue and grey mould, important post‐harvest diseases of pome fruits. In tests in vivo at 20 °C, ammonium molybdate (15 mM ) reduced lesion diameters of Penicillium expansum, Botrytis cinerea and Rhizopus stolonifer by 84%, 88% and 100% respectively. When apples treated with ammonium molybdate were stored at 1 °C for three months, a significant reduction in severity and incidence of P expansum and B cinerea was observed in both years of study (1998 and 1999). In the second year of the experiment the reduction in disease severity was greater than 88% for both pathogens, and the level of control was similar to, or greater than, that observed with the fungicide imazalil. When ammonium molybdate was applied as a pre‐harvest treatment, a significant reduction in blue mould decay was observed after three months in cold storage. In vitro, ammonium molybdate greatly inhibited spore germination of P expansum and B cinerea, although better inhibition was obtained against grey mould. Ammonium dimolybdate, sodium molybdate and potassium molybdate were also tested in vitro in comparison with ammonium molybdate as inhibitors of spore germination, but only ammonium molybdate inhibited spore germination by more than 50%. © 2001 Society of Chemical Industry     

6-戊基-2H-吡喃-2-酮对草坪币斑病菌的抑菌活性及其对病害的防治效果

由Clarireedia spp.引起的草坪币斑病是对草坪最具有破坏性的病害之一,6-戊基-2H-吡喃(6-pentyl-2H-pyran-2-one, 6PP)是木霉菌属(Trichoderma spp.)重要的抗菌次生代谢产物。为探究6PP对草坪币斑病菌的抑菌活性、防治效果以及草坪币斑病菌对6PP的生理响应,本研究采用菌丝生长速率法测定了6PP对草坪币斑病菌的抑制活性,分别采用室内离体叶片和盆栽试验测定了6PP对草坪币斑病的预防和治疗作用,并分析了在6PP影响下草坪币斑病菌菌丝结构及抗逆相关酶活性的变化。结果显示,6PP对两种草坪币斑病菌C. jacksonii和C. monteithiana均具有高抑制活性,其中对C. monteithiana的平均有效抑制中浓度(EC₅₀)为0.37 μg/mL,对C. jacksonii的EC₅₀值为0.04 μg/mL;经6PP处理后,C. jacksonii和C. monteithiana菌丝生长异常,细胞膜通透性增加,相对电导率上升,细胞膜脂过氧化,细胞膜受损;C. jacksonii过氧化物酶(POD)的活性显著上升,但pH值不变,而C. monteithiana超氧化物歧化酶(SOD)活性、pH值和胞外多糖(EPS)显著上升。1 μg/mL的6PP在离体条件下对币斑病的预防效果为91.14%;盆栽条件下,防治效果为72.21%。6PP对草坪币斑病菌抑制作用显著,且在离体和盆栽条件下对病害均有良好的防治效果,具备开发成生态友好型杀菌剂的潜力。     

First application of PCR-Luminex system for molecular diagnosis of fungicide resistance and species identification of fungal pathogens

Fungicide resistance in plant pathogens is often caused by a single point mutation in a gene encoding fungicide target proteins. Such is the case for resistance to MBI-D (inhibitors of scytalone dehydratase in melanin biosynthesis) fungicides in rice blast fungus (Magnaporthe oryzae), which is caused by a mutation in the scytalone dehydratase gene that results in a replacement of valine with methionine at codon 75 of the fungicide target protein. PCR-Luminex, a novel system developed for high-throughput analysis of single nucleotide polymorphisms (SNPs) was successfully introduced to diagnose MBI-D resistance using specific oligonucleotide probes coupled with fluorescent beads. The PCR-Luminex system was further tested for its potential in identifying species causing Fusarium head blight on wheat. Four major pathogens, Fusarium graminearum (=F. asiaticum), F. culmorum, F. avenaceum, and Microdochium nivale, known to cause the disease, were tested, and the species were identified using the PCR-Luminex method. So far, this report is the first on the application of the DNA-based PCR-Luminex system in the area of crop protection and/or agricultural sciences.     

Suppression of the in vitro growth and development of Microdochium nivale by phosphite

The ascomycete fungus Microdochium nivale is a major pathogen of many species of the gramineae. Control measures rely heavily on chemical fungicides, making alternative means of disease reduction desirable. Phosphite (PO₃^3?), has proven efficacy in reducing susceptibility of different species of gramineae to oomycetes, and has adverse effects on the in vitro growth of numerous other pathogens. The effect of phosphorous acid (H₃PO₃), phosphoric acid (H₃PO₄), dihydrogen potassium phosphite (KH₂PO₃), dihydrogen potassium phosphate (KH₂PO₄) and potassium hydroxide (KOH) on the in vitro mycelial growth and development of M. nivale was determined. Radial growth on amended potato dextrose agar (PDA) was used to calculate mean daily growth and percentage inhibition. PO₃^3? had a significant inhibitory effect on mycelial growth, with EC₅₀ values ranging between 35.9 and 40.99 μg mL^?1, whilst PO₄^3? and KOH had no significant inhibitory effect. Microscopic examination of mycelia showed morphological deformities in hyphae growing on PO₃^3? amended PDA, whilst hyphal growth was normal on PO₄^3? and KOH amended PDA. Conidial germination of M. nivale was significantly reduced following immersion in solutions of 50, 100 and 250 μg mL^?1 of PO₃^3?, while PO₄^3? and KOH at the same concentrations induced no inhibitory affect. These results show that PO₃^3? is a significant inhibitor of the growth of M. nivale and may have the potential to be used as a chemical control agent in the field.     

Aminopyrifen,a novel 2-aminonicotinate fungicide with a unique effect and broad-spectrum activity against plant pathogenic fungi

Aminopyrifen is a novel 2-aminonicotinate fungicide with unique chemistry and a novel mode of action. The fungicide showed high antifungal activity mainly against Ascomycetes and its related anamorphic fungi under in vitro and pot conditions (EC₅₀ values: 0.0039–0.23 mg/L and 1.2–12 mg/L, respectively). The active ingredient strongly inhibited germ-tube elongation of Botrytis cinerea below 0.1 mg/L and invasion into a plant. The compound exhibited no cross-resistance to commercial fungicides in B. cinerea. The antifungal agent showed high preventive efficacy and translaminar action. In the field, aminopyrifen controlled gray mold and powdery mildew at 150 mg/L. Our findings suggest that aminopyrifen is useful for protecting crops from various plant pathogens.     

Yield Reduction in Wheat in Relation to Leaf Disease From Yellow (tan) Spot and Septoria Nodorum Blotch

Yellow or tan spot (caused by Pyrenophora tritici-repentis) and septoria nodorum blotch (caused by Phaeosphaeria nodorum) occur together and are a constraint to wheat yields in Australia. Recently, higher crop yields and lower fungicide costs have made fungicides an attractive management tool against these diseases. Yield-loss under different rates of progress of yellow spot and septoria nodorum blotch was examined in four experiments over three years to define the relationship between disease severity and yield. In these experiments, differences in disease were first promoted by inoculations either with P. tritici-repentis-infected stubble or aqueous spore suspensions of P. nodorum. Disease progress was further manipulated with foliar application of fungicide. The pattern of disease development varied in each year under the influence of different rainfall patterns. The inoculation and fungicide treatments produced differences in disease levels after flag leaf emergence. The infection of yellow spot or septoria nodorum blotch caused similar losses in grain yield, ranging from 18% to 31%. The infection by either disease on the flag or penultimate leaf provided a good indication of yield-loss. Disease severity on flag leaves during the milk stage of the crop or an integration of disease as area under the disease progress curve on the flag leaves based on thermal time explained more than 80% variance in yield in a simple regression model. The data provided information towards the development of disease management strategies for the control of septoria nodorum blotch and yellow spot.     

Can a chitin‐synthesis‐inhibiting turfgrass fungicide enhance black cutworm susceptibility to a baculovirus?

BACKGROUND: Developmental resistance, i.e. reduced virulence and speed of kill of late instars, is a limiting factor in the use of baculoviruses for caterpillar control. Agrotis ipsilon multicapsid nucleopolyhedrovirus (AgipMNPV) is highly infective to young black cutworms, Agrotis ipsilon, but too slow‐acting against late instars for effective curative control on golf courses or sports fields. Chitin‐synthesis‐inhibiting fungicides containing the active ingredient polyoxin‐d are used to control fungal diseases in turfgrass, and similar compounds have been shown in the laboratory to synergize baculoviruses by disrupting peritrophic membrane function. This study tested whether applying the virus together with such a fungicide can synergize AgipMNPV activity against A. ipsilon in turfgrass. RESULTS: The addition of a chitin synthesis inhibitor failed to increase AgipMNPV infectivity to A. ipsilon in the field. Rather, delayed and slightly reduced mortality from viral infection was seen when larvae fed on fungicide/virus‐treated grasses as opposed to virus‐only treatments. Choice tests revealed the fungicide residues to be a mild feeding deterrent. CONCLUSION: Because polyoxin‐d does not deactivate AgipMNPV, the two substances are compatible. However, combination applications of polyoxin‐d and Agip MNPV on turfgrass might interfere with larval ingestion of a lethal virus dose, resulting in prolonged larval feeding in the field. Copyright © 2011 Society of Chemical Industry     

Control of light leaf spot and clubroot in brassica crops using defence elicitors

Plant defence elicitors are compounds that can induce host defence responses against plant pathogens and offer a novel strategy for disease management. Disease control by elicitors can be inconsistent and is often dependent on the crop, the variety and the environment. The use of foliar application of defence elicitors to control light leaf spot (LLS) disease caused by Pyrenopeziza brassicae in the brassica crops winter oilseed rape (WOSR) and Brussel sprouts was evaluated in field trials across multiple years. Elicitor responses in WOSR varied between years. Yield benefits were also inconsistent and did not reflect the level of disease control. Results with Brussel sprouts were more consistent although variation between variety, trial site and year were observed. In particular the salicylic acid analog Acibenzolar-S-Methyl, in the commercial product Bion®, demonstrated good disease control across the field trial sites in the early maturing Brussel sprout variety Cobus. Levels of LLS were consistently reduced when Bion® was alternated within a standard fungicide programme, applied as an individual spray or in combination with other defence elicitors. When applied as a root drench or seed soak Bion® also reduced symptom development of the soil-borne brassica disease clubroot, caused by Plasmodiophora brassicae, in WOSR. These results indicate that defence elicitors such as Bion® can be used as an additional disease management tool alongside host resistance and standard fungicide programmes to protect brassica crops.     

Structure–biological activity relationships in triterpenic saponins: the relative activity of protobassic acid and its derivatives against plant pathogenic fungi

BACKGROUND: Triterpenic saponins from Sapindus mukorossi Gaertn. and Diploknema butyracea JF Gmelin were evaluated for in vitro antifungal activity against four phytopathogenic fungi. The study of the structure–antifungal activity relationships of protobassic acid saponins was widened by including semi‐synthetic derivatives. RESULTS: Diploknema butyracea saponins exhibited significant antifungal activity against three fungi (ED₅₀ 230–455 µg mL^?1), whereas S. mukorossi saponin was effective against two fungi (ED₅₀ 181–407 µg mL^?1). The n‐butanol extract after preparative HPLC separation provided two saponins from D. butyracea saponin mixture: 3‐O‐[β‐D ‐glucopyarnosyl‐β‐D ‐glucopyranosyl]‐16‐α‐hydroxyprotobassic acid‐28‐O‐[arabinopyranosyl‐glucopyranosyl‐xylopyranosyl]‐arabinopyranoside (MI‐I), and 3‐O‐β‐D ‐glucopyranosyl‐glucopyranosyl‐glucopyranosyl‐16‐α‐hydroxyprotobassic acid‐28‐O‐[arabinopyranosyl‐xylopyranosyl‐arabinopyranosyl]‐apiofuranoside (MI‐III). The single saponin extracted from S. mukorossi saponin mixture was identified as 3‐O‐[O‐acetyl‐β‐D ‐xylopyranosyl‐β‐D ‐arabinopyranosyl‐β‐D ‐rhamnopyranosyl] hederagenin‐28‐O[β‐D ‐glucopyranosyl‐β‐D ‐glucopyranosyl‐β‐D ‐rhamnopyranosyl] ester (SM‐I). Monodesmosides resulting from the partial degradation of hederagenin and hydroxyprotobassic acid bisdesmosides exhibited significant reduction in antifungal effect. Further removal of sugar moiety yielded complete loss in activity. The antifungal activity of the triterpenic saponins was associated with their aglycone moieties, and esterification of the hydroxyl group led to change in antifungal activity. CONCLUSION: Sapindus mukorossi saponin, which is effective against Rhizoctonia bataticola (Taub.) Briton Jones and Sclerotium rolfsii Sacc., can be exploited for the development of a natural fungicide. A sugar moiety is a prerequisite for the antifungal activity of triterpenic saponin. Copyright © 2010 Society of Chemical Industry     

Effect of benomyl on soil fungi associated with rye. 1. Effect on the incidence of sharp eyespot caused by Rhizoctonia cerealis

Effects of benomyl on incidence of pathogens affecting the culm base of rye were studied in field trials and growth chamber experiments. Spraying of the crop with the fungicide at a high dosage (2.4 kg.ha^–1) resulted in a tenfold increase of sharp eyespot caused byRhizoctonia cerealis and reduced foot rot symptoms caused by fusaria by 50%. In a field trial at a low dosage (0.24 kg.ha^–1) a slight increase of sharp eyespot was observed. In one year, probably because of wet conditions during the infection period, sharp eyespot did not occur in either benomyl-treated or untreated plots, but eyespot caused byPseudocercosporella herpotrichoides was abundant. Its occurrence was reduced from 74% affected culm bases in untreated plots to 8% and 1% in plots that received 0.24 and 2.4 kg.ha^–1 of the fungicide, respectively.In growth chambers seedlings were grown in two sandy soils inoculated withR. cerealis. The soil was kept dry at about 35% of the moisture holding capacity. In plots with benomyl (1 mg.kg^–1; moisture content 11% of fresh weight), fewer seedlings emerged than in plots without the fungicide. This result was highly significant (P<0.01) for one soil but not for the other. The number of seedlings that remained free of disease symptoms was higher (P<0.01) in untreated than in fungicide-treated plots of both soils.Isolates of pathogens obtained from diseased culms were tested for their sensitivity to benomyl. Growth of all of them includingR. cerealis was inhibited, although not always completely suppressed, at 10 g.ml^–1 on potato-dextrose agar. ED₅₀ values of most isolates ofR. cerealis were between 2.2 and 3.1 g.ml^–1. The fungus was slightly but consistently less sensitive thanF. culmorum. Mycelial growth ofF. nivale was appreciably more sensitive than that of the otherFusarium spp. from cereals.P. herpotrichoides andF. nivale were the most sensitive pathogens tested with ED₅₀ values of <1 g.ml^–1. Accordingly,F. nivale was absent on culms from treated plots. In a growth chamber experiment, seedlings were protected from infection by supplying the fungicide (1 mg.kg^–1) to previously inoculated soil.In a laboratory assay the effect of benomyl on microbial antagonism toR. cerealis was estimated for rhizosphere soil. Enhanced incidence of sharp eyespot in treated crops was associated with adverese effects of the fungicide on microbial antagonism. There is presumptive evidence thatR. cerealis is suppressed by bacteria after wet periods during the vegetation period of the crop and by fungi after dry periods. Only fungal antagonism, which may be less effective, is affected by benomyl. The response to benomyl of the microflora in different soils varied. Reasons for this inconsistency are suggested.Samenvatting In veldproeven en in een klimaatkamer werd de invloed van benomyl op het optreden van voetziekten in rogge onderzocht. In veldjes die bespoten waren met een hoge dosis van het fungicide (in totaal 2.4 kg.ha^–1) bleken tienmaal zoveel halmen met scherpe oogvlekken, veroorzaakt doorRhizoctonia cerealis, voor te komen dan in onbespoten veldjes. Daarentegen was voetrot veroorzaakt doorFusarium-soorten met 50% verminderd. In een volgende veldproef, waarbij een voor de praktijk geadviseerde dosis (0.24 kg.ha^–1) was toegepast, werd een lichte toename van scherpe oogvlekken waargenomen.In een ander jaar trad scherpe oogvlekkenziekte in het geheel niet op, ook niet in met benomyl behandelde veldjes. De vochtige omstandigheden tijdens de infectieperiode zijn daarvan waarschijnlijk de oorzaak. Daarentegen werd de oogvlekkenziekte, welke doorPseudocercosporella herpotrichoides werd veroorzaakt, veel aangetroffen. In de onbehandelde veldjes waren 74% van de halmen aangetast tegen 8 en 1% in de veldjes die met het fungicide waren behandeld in doseringen van 0.24 en 2.4 kg.ha^–1.De invloed van het fungicide op de aantasting van kiemplanten werd in klimaatkamerproeven onderzocht. Daartoe werden twee zandgronden metR. cerealis geënt. De grond werd droog gehouden (op 35% van het waterhoudend vermogen). In grond met fungicide (1 mg.kg^–1) was de opkomst minder dan in grond zonder fungicide. Dit was zeer significant (P<0.01) voor één van de beide zandgronden, maar niet voor de andere. Het aantal gezonde kiemplanten was in beide gevallen duidelijk hoger (P<0.01) voor de onbehandelde grond.De isolaten van ziekteverwekkers uit aangetaste halmen werden op hun gevoeligheid voor het fungicide getoetst. Op aardappel-glucoseagar werden alle isolaten in hun groei geremd bij een benomyl-concentratie van 10 g.ml^–1.R. cerealis was iets minder gevoelig danF. culmorum. Voor het overgrote deel van de isolaten vanR. cerealis lag de ED₅₀ waarde tussen 2,2 en 3,1 g.ml^–1. De myceliumgroei vanF. nivale werd meer geremd dan die van de andereFusarium-soorten.P. herpotrichoides enF. nivale waren met een ED₅₀ waarde van <1 g.m.^–1 de gevoeligste pathogenen die uit de halmvoeten werden geïsoleerd. Dat de populatie vanF. nivale in benomylhoudende grond wordt onderdrukt, blijkt uit (1) het feit dat de schimmel niet voorkwam op halmen uit behandelde veldjes en (2) de bescherming tegen infectie van kiemplanten als aan de besmette grond fungicide (1 mg.kg^–1) was toegevoegd.In laboratoriumproeven werd de invloed van benomyl op het microbiële antagonisme in rhizosfeergrond tegenR. cerealis bepaald. Een toename in het optreden van scherpe oogvlekkenziekte in behandelde gewassen bleek gepaard te gaan met een remming van het antagonisme tegen de ziekteverwekker. Er zijn sterke aanwijzingen datR. cerealis na vochtige perioden tijdens de vegetatieperiode door bacteriën wordt onderdrukt en na droge perioden door schimmels. Het antagonisme van de laatste groep lijkt minder effectief te zijn en alleen dit antagonisme wordt door benomyl verlaagd. Tenslotte wordt een mogelijke oorzaak aangegeven voor de ongelijke respons op het fungicide van het microbieel antagonisme in verschillende gronden.     

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     

Integration of partial resistance,plant density and use of fungicide for management of white mould in common bean

In-row plant densities have not been studied for common beans with type II growth habit and contrasting reactions to white mould. Advanced breeding lines with partial resistance or susceptibility to white mould were combined with 4, 7, 10 or 13 plants m⁻¹ and with or without fungicide at a constant between-row spacing of 0.5 m in five sprinkler-irrigated field trials conducted during the autumn–winter season in Brazil. White mould pressures in the trials covered the whole range from zero to moderate/high (46–60% of white mould severity index). In all trials, means of white mould incidence, severity and yield did not vary significantly between 7 and 13 plants m⁻¹ for the partially resistant line, regardless of the fungicide levels. For the susceptible line, 13 plants m⁻¹ increased white mould incidence and severity under moderate disease, regardless of the fungicide levels, and decreased yield compared with 10 plants m⁻¹ when fungicide was applied twice under moderate/high disease pressure. For the susceptible line, 7 or 10 plants m⁻¹ maximized yield in all trials, with or without fungicide applications. The results suggest that the current recommendation of 11–13 plants m⁻¹ could be used for type II beans with partial resistance to white mould in either a conventional or organic system. For susceptible genotypes, 7–10 plants m⁻¹ seems to be the most appropriate in-row plant density. This study may improve the recommendation of in-row plant density for type II beans cultivated under white mould pressure.