The effects of foliar fungicides on beneficial arthropods in wheat fields

Large scale replicated field trials were carried out over a 2 year period to quantify the insecticidal properties of 3 foliar fungicides commonly used in wheat fields. Pyrazophos significantly reduced the numbers of many groups of the natural enemies of cereal aphids and the insects known to be vital in the diet of gamebird chicks for up to 4 weeks after spraying. No such reductions were found after the use of either triadimefon or propiconazole. Aphid numbers on plots sprayed with pyrazophos were twice the numbers found on unsprayed plots either 6 weeks after spraying in 1985 or on unsprayed plots and plots sprayed with the other fungicides 20 days after treatment in 1984. In 1985, this necessitated the additional use of an aphicide only on those plots previously sprayed with pyrazophos. The removal of chick food insects following the use of pyrazophos was considered to be sufficient to reduce survival rates of wild gamebird chicks.      

The microflora of ripening barley grain and the effects of pre harvest fungicide application

Newly-emerged ears of barley soon became colonised by micro-organisms with numbers increasing to 5·8 × 10⁵ viable propagules/g dry weight by harvest. Bacteria were numerically predominant throughout. Yeasts and yeast-like fungi were also numerous during the early stages of grain development but were exceeded by propagules of filamentous fungi during ripening, with Cladosporium spp., Alternaria alternata, Epicoccum purpurascens and Verticillium lecanii most abundant. Numbers of most micro-organisms were greatest in a wet season but Alternaria was equally abundant in hot dry weather. Application of fungicides at or after anthesis modified the grain microflora. Captafol was most effective overall in decreasing numbers of fungi. However, benomyl decreased Cladosporium inoculum more than catpafol but was ineffective against Alternaria which became more numerous on benomyl-treated grain than on untreated. Yield increases of up to 4% were obtained by late fungicide treatment, least in a hot, dry year. Germination was also increased by some treatments by up to 5%.     

Effects of aphids on foliar foraging by Argentine ants and the resulting effects on other arthropods

Abstract.  1. Although interactions between ants and honeydew-producing insects have received considerable study, relatively little is known about how these interactions alter the behaviour of ants in ways that affect other arthropods. In this study, field and greenhouse experiments were performed that examined how the presence of aphids ( Aphis fabae solanella ) on Solanum nigrum influenced the foraging behaviour of Argentine ants ( Linepithema humile ) and, in turn, modified the extent to which ants deter larval lacewings ( Chrysoperla rufilabris ), which are known aphid predators.
2. A field experiment demonstrated that the level of foliar foraging by ants increased linearly with aphid abundance, whereas no relationship existed between the level of ground foraging by ants and aphid abundance.
3. In the greenhouse, as in the field, foliar foraging by ants greatly increased when aphids were present. Higher levels of foliar foraging led to a twofold increase in the likelihood that ants contacted aphid predators. As a result of these increased encounters with ants, lacewing larvae were twice as likely to be removed from plants with aphids compared with plants without aphids. Once contact was made, however, the behaviour of ants towards lacewing larvae appeared similar between the two experimental groups.
4. Argentine ants drive away or prey upon a diversity of arthropod predators and parasitoids, but they also exhibit aggression towards certain herbivores. Future work should attempt to quantify how the ecological effects that result from interactions between honeydew-producing insects and invasive ants, such as L. humile , differ from those that result from interactions between honeydew-producing insects and native ants.     

Augmentation of beneficial arthropods by strip-management

The effect of strip-management on surface activity, movements and activity density of abundant carabid beetles during two vegetation periods in a cereal field was investigated using mark-recapture techniques. Significantly higher recapture rates, indicating higher activity, were found in the strip-managed area than in the control area, especially in Poecilus cupreus and also in Carabus granulatus and Pterostichus melanarius. Several observations led to the conclusion that this higher activity is generally due to a prolongation of the reproductive period in the strip-managed area. Significantly higher activity densities were found for P. cupreus, Pterostichus anthracinus, C. granulatus and Pt. melanarius in the strip-managed area than in a bordering control area. P. cupreus is greatly attracted to the strips during its migrations, as can be deduced from the high percentage of movements that contact the strips. Also, significantly more marked individuals moved from the control to the strip-managed area than vice versa. Pt. melanarius and Pt. anthracinus show less preference for the strips in their movements than P. cupreus. However, significantly more individuals of Pt. melanarius also moved from the control to the strip-managed area. C. granulatus, on the other hand, kept mainly to the cereal areas. After harvest only Pterostichus niger and Harpalus rufipes distinctly preferred the strips. The generally marked degree of attraction exercised by strip-management on carabid beetles is discussed.     

Augmentation of beneficial arthropods by strip-management

Summary A 5-year-field experiment was performed in a meadow to test the effect of strip-management (small unmown strips alternating with broad mown strips, Fig. 1) on the abundance and composition of arthropods. The species number and density of most predator groups increased from year to year. The succession (parallel to the development of the unmown strips) favoured more specialized species, so that the initial pioneer species become less abundant in consecutive years. In spiders, this succession leads from a dominance of Linyphiidae to a dominance of Lycosidae; the spider biomass increases and probably predator pressure by spiders is augmented. The stability of the predator community (measured as the variance of their frequency in successive years) is higher than that of the phytophagous groups. Under strip-managed conditions the abundance (activity density) of most arthropod groups decreases by an average of ca. 12%. The trophic levels, however, are affected to different extents and strong species-specific preferences were found as well. These combined effects lead to constant increase in the ratio of predacious and parasitic to phytophagous insects in the strip-managed area and probably lead also to an increase of the predator pressure facing phytophagous insects. Strip-management is discussed as an important technique among integrated methods for the biological control of pests.     

The impact of dimethoate on the spatial distribution of beneficial arthropods in winter wheat

The within‐field spatial distribution of beneficial arthropods was assessed using two‐dimensional grids of pitfall traps and suction sampling across two winter wheat fields of 4 and 16 ha, before and after an application of dimethoate. An unsprayed 6 m wide buffer zone was left around half the edge of the larger field. Arthropod numbers fluctuated to varying extents prior to spraying. Two species of Carabidae (Pterostichus madidus and P. melanarius), Linyphiidae, Lycosidae and Aphidius spp. (Braconidae) all showed their greatest reduction after spraying. For five carabid taxa, Tachyporus spp. (Staphylinidae) and Collembola the decline in numbers following spraying was no greater than any reduction found during the pre‐spraying period. Within field spatial distributions of three arthropod groups were analysed using SADIE. P. madidus, present in patches across the centre of both fields prior to spraying, was removed by dimethoate and by 34 days after spraying had recovered most at the field edges. Linyphiidae were evenly distributed across both fields prior to spraying. Their numbers were reduced considerably by dimethoate and they did not recover to pre‐spray levels. However, where recovery occurred this was across the centre of both fields indicating their potential to reinvade whole fields. Aphidius species were also evenly distributed across both fields prior to spraying, but did not recover after spraying. Some, but not all arthropods survived within the unsprayed buffer zone and there was some indication that reinvasion of the mid‐field was more extensive where this was present. The importance of field margins with respect to insecticide treatments is discussed.     

Some effects of high electrical fields on barley growth

Growth rate studies were conducted on barley plantings exposed to vertical electrical fields of 50–400 kV/m and also to plantings exposed to the gaseous by-products dispersed from such high field exposures. In general, direct exposure to fields below about 200 kV/m produced enhanced growth while higher fields inhibited growth. For all fields up to 750 kV/m gaseous by-products carried to an adjacent planting resulted in increased initial growth, this gain eventually being lost as total growth dropped back to normal after about 150 hours.

---

Zusammenfassung Studien der Wachstumsrate wurden ausgeführt mit Gerstensetzlingen, die vertikalen elektrischen Feldern von 50–400 kV/m und den gasförmigen Nebenprodukten derartig hoher elektrischer Feldbelastung ausgesetzt waren. Die direkte Feldbelastung unter 200 kV/m bewirkte im allgemeinen ein verstärktes Wachstum während bei höheren Feldstärken das Wachstum gehemmt war. In allen Feldern bis 750 kV/m führten die gasförmigen Nebenprodukte zu einem anfänglich gesteigerten Wachstum. Dieser Gewinn ging später verloren, indem das Gesamtwachstum nach 150 Stunden auf Normalwerte zurückfiel.

---

Resume On a étudié le taux de croissance de jeunes plantes d'orge exposées à des champs électriques verticaux de 50 à 400 kV/m, ainsi que de germes exposés aux émanations gazeuses provenant de tels champs électriques à haute intensité. En général, l'exposition directe à des champs de moins de 200 kV/m à peu près provoque une augmentation de la vitesse de croissance, alors que des champs supérieurs ont un effet inhibiteur sur cette même croissance. Dans tous les champs électriques jusqu'à 750 kV/m, les produits gazeux accessoires ont eu pour conséquence au début, une croissance supérieure. Pourtant, ce gain s'est perdu par la suite, du fait que la croissance totale est retombée à des valeurs normales après 150 heures.

     

The effects of some commonly-used foliar fungicides on Collembola in winter barley: laboratory and field studies

Four commonly-used cereal foliar fungicides were screened for their laboratory toxicity against the symphypleone collembolan, Sminthurinus aureus. A proportional hazards analysis of time-survival curves following the fungicide treatments showed that carbendazim, propiconazole, pyrazophos and triadimenol significantly increased the laboratory mortality of S. aureus. The organophosphorus fungicide pyrazophos caused high levels of mortality of S. aureus in the laboratory so a field evaluation of the effects of this fungicide on a wider range of Collembola was undertaken in winter barley. Comparison of the effects of pyrazophos with those of the broad-spectrum insecticide dimethoate in the field revealed both compounds to have similar activity against some Collembola. Of the 11 species caught only the four symphypleone species exhibited these effects but the numbers of three symphypleone species were reduced to zero 4 wk after treatment with pyrazophos. The effects of pyrazophos and dimethoate were, however, not detectable in individual species after 11 wk.     

Insect-resistant biotech crops and their impacts on beneficial arthropods

With a projected population of 10 billion by 2050, an immediate priority for agriculture is to achieve increased crop yields in a sustainable and cost-effective way. The concept of using a transgenic approach was realized in the mid-1990s with the commercial introduction of genetically modified (GM) crops. By 2010, the global value of the seed alone was US $11.2 billion, with commercial biotech maize, soya bean grain and cotton valued at approximately US $150 billion. In recent years, it has become evident that insect-resistant crops expressing δ-endotoxin genes from Bacillus thuringiensis have made a significant beneficial impact on global agriculture, not least in terms of pest reduction and improved quality. However, because of the potential for pest populations to evolve resistance, and owing to lack of effective control of homopteran pests, alternative strategies are being developed. Some of these are based on Bacillus spp. or other insect pathogens, while others are based on the use of plant- and animal-derived genes. However, if such approaches are to play a useful role in crop protection, it is desirable that they do not have a negative impact on beneficial organisms at higher trophic levels thus affecting the functioning of the agro-ecosystem. This widely held concern over the ecological impacts of GM crops has led to the extensive examination of the potential effects of a range of transgene proteins on non-target and beneficial insects. The findings to date with respect to both commercial and experimental GM crops expressing anti-insect genes are discussed here, with particular emphasis on insect predators and parasitoids.     

Nontarget effects of foliar fungicide application on the rhizosphere: diversity of nifH gene and nodulation in chickpea field

Aims: This study explores nontarget effects of fungicide application on field‐grown chickpea. Methods and Results: Molecular methods were used to test the effects of foliar application of fungicide on the diversity and distribution of nifH genes associated with two chickpea cultivars and their nodulation. Treatments were replicated four times in a split‐plot design in the field, in 2008 and 2009. Chemical disease control did not change the richness of the nifH genes associated with chickpea, but selected different dominant nifH gene sequences in 2008, as revealed by correspondence analysis. Disease control strategies had no significant effect on disease severity or nifH gene distribution in 2009. Dry weather conditions rather than disease restricted plant growth that year, suggesting that reduced infection rather than the fungicide is the factor modifying the distribution of nifH gene in chickpea rhizosphere. Reduced nodule size and enhanced N₂‐fixation in protected plants indicate that disease control affects plant physiology, which may in turn influence rhizosphere bacteria. The genotypes of chickpea also affected the diversity of the nifH gene in the rhizosphere, illustrating the importance of plant selective effects on bacterial communities. Conclusions: We conclude that the chemical disease control affects nodulation and the diversity of nifH gene in chickpea rhizosphere, by modifying host plant physiology. A direct effect of fungicide on the bacteria cannot be ruled out, however, as residual amounts of fungicide were found to accumulate in the rhizosphere soil of protected plants. Significance and Impact of the Study: Systemic nontarget effect of phytoprotection on nifH gene diversity in chickpea rhizosphere is reported for the first time. This result suggests the possibility of manipulating associative biological nitrogen fixation in the field.     

Side effects of the sterol biosynthesis inhibitor fungicide, propiconazole, on a beneficial arbuscular mycorrhizal fungus

The Sterol Biosynthesis Inhibitor (SBI) fungicide, propiconazole, is extensively used in modern agriculture to control fungal diseases. Unfortunately, little is known about its potential side effects on non-target plant-beneficial soil organisms such as arbuscular mycorrhizal fungi (AMF). The direct impact of increasing propiconazole concentrations (0.02; 0.2 and 2 mg x L(-1)) on the lipid metabolism of the AMF Glomus irregulare in relation with its development, was studied by using axenic cultures. The propiconazole impact on G. irregulare was investigated, firstly, through sterol (the target-metabolism of SBI fungicides), phospholipids (PL) and their associated fatty acids (PLFA) analysis (the main membrane components) and secondly by measuring malondialdehyde (MDA) (a biomarker of lipid peroxidation) formation. Finally, the storage lipid quantity, triacylglycerol (TAG), was quantified. Our results demonstrated that the drastic reduction of G. irregulare development (germination, germ tube elongation, colonization, extraradical hyphae growth and sporulation) could be explained not only by the decreases of the total sterol end-products (24-methylcholesterol and 24-ethylcholesterol) and by 24-methylene dihydrolanosterol (a sterol precursor) accumulation, suggesting an inhibition of a key enzyme in sterol biosynthesis pathway (14alpha-demethylase), but also by the increases in phosphatidylcholine (PC) and PLFA (C16:0; C18:0 and C18:3) quantities as well as by MDA accumulation. Moreover, TAG quantity was found to be reduced in the presence of propiconazole, suggesting their use by G. irregulare in a response to propiconazole toxicity. In conclusion, taken together, the findings of the current study highlighted a relationship between the SBI fungicide toxicity against the beneficial AMF G. irregulare and (1) the disturbance in the sterol metabolism, (2) the membrane alteration (PC decrease, lipid peroxidation) as well as (3) the reduction in storage lipids, TAG. More generally, this work could contribute to investigate the toxicity of agricultural chemicals on AMF and underlined the emergency of using sustainable alternative method to control plant diseases. Furthermore, these data can provide a useful approach in soil ecotoxicology studies and risk assessment.     

Interactions between fungicide, plant growth regulator, nitrogen fertiliser applications, foliar disease and yield of winter barley

Leaf size and foliar disease in winter barley increased with increasing total amounts of nitrogen applied to the crop: flag leaf areas increased at an average of 10% per 35 kg N ha^-1 Nitrogen top dressing applied in mid-March (G.S. 31) resulted in larger leaves, more foliar disease, more straw, delayed ear emergence, fewer grains ear^-1 and less grain yield than nitrogen applied in mid-April (G.S. 31). Application of chlormequat at G.S. 30 gave a variable response, but overall it increased fertile stems m-² and crop yield and decreased crop height but had no significant effect on straw yield. Fungicide treatments suppressed foliar disease and improved yield. Yield responses were greater when plant growth regulator and mid-March nitrogen had been applied at sites where more disease prevailed than with April-applied nitrogen. In one of the field experiments, on cv. Sonja, delaying the main nitrogen application until April, without fungicide treatment, gave a similar yield to that provided by nitrogen in March with two or three fungicide sprays.     

化学杀虫剂对菜田节肢动物多样性的影响

分析了化学杀虫剂对菜田节肢动物结构组成、多样性变化等的影响,结果表明化学杀虫剂对菜田节肢动物的影响主要表现在物种组成、多样性指数及物种分布的均匀性等方面,尤其是对害虫类、捕食性天敌和蜘蛛类的影响尤为明显。停止化学杀虫剂使用后,菜田优势害虫种群趋势指数降低,天敌的控制作用明显增强,节肢动物多样性指数增大。因此,限制和停止化学杀虫剂的使用,恢复由于杀虫剂使用而破坏了的菜田环境,逐步增强天敌对优势害虫的控制能力,这在菜田害虫生态控制中具有重要作用。     

Changes in foliar proline concentration of osmotically stressed barley

The amino acid proline is accumulated in plant tissues in response to a variety of stresses. The existence of two routes for its biosynthesis is well documented. However, little is known about the contribution of each pathway to the accumulation of free proline under stress conditions. In the present study young barley plants were subjected to osmotic stress by treating their roots with 25% polyethylene glycol. Prior to stress imposition roots were incubated for 24 h in nutrient solution containing proline or one of its metabolic precursors: glutamate and ornithine. Free proline quantity in the leaves was measured before and after stress. Relative water content (RWC) was used as a measure of the plant water status. Foliar proline levels showed a significant increase in ornithine- and proline-pretreated plants compared to the control. Nevertheless, no considerable changes in leaf RWC were observed. It was shown that before stress application only ornithine but not glutamate was immediately metabolized to proline. Under stress conditions, however, both precursors were converted into proline. The possible role of this amino acid in the processes of post stress recovery is discussed.     

Effects of fungicide timing on control of Rhynchosporium secalis in barley plants

Sprays of captafol, carbendazim, carbendazim + tridemorph + maneb, diclobutrazol, triadimefon or triadimefon + carbendazim all completely protected barley plants in a glasshouse against R. secalis for at least 30 days. However, their effectiveness in preventing disease development when applied after inoculation differed: triadimefon, traidimefon + carbendazim, or diclobutrazol were the most effective, completely preventing symptom development when applied up to 5 days after inoculation to plants grown above 16 °C, and up to 8 days below 8 °C. All the fungicides decreased the number of viable conidia produced by leaf blotch lesions, and when applied to infected plants at G. S. 30, greatly decreased the upward spread of the disease under simulated rain conditions; the most effective fungicides in these respects were triadimefon and triadimefon + carbendazim. The above fungicides and fungicide mixtures, together with the recently introduced materials fenpropimorph and propiconazole were applied to diseased winter barley crops in winter or in spring. All treatments decreased leaf blotch development and increased yields. In most cases, a winter application was more effective than spring applications, particularly if applied in mid-November. The most effective fungicides were triadimefon and propiconazole. The field trials data fitted well with the predictions of performance indicated by the glasshouse investigations.     

Pesticides selectivity list to beneficial arthropods in four field vegetable crops

Selectivity of pesticides to beneficial arthropods is a key data for the implementation of IPM program. In the context of field vegetables crop, a set of 16 fungicides, 17 herbicides and 14 insecticides commonly used in Belgium were tested on 5 indicator species: the parasitic hymenoptera Aphidius rhopalosiphi (De Stefani-Perez) (Hym., Aphidiidae), the aphid foliage dwelling predators Adalia bipunctata (L.) (Col., Coccinellidae) and Episyrphus balteatus (Dipt., Syrphidae) and the ground-dwelling predators Aleochara bilineata (Col., Staphyllinidae) and Bembidion lampros (Col., Carabidae). Pesticides were tested according a testing scheme including a first assessment on inert substrate (glass plates for adults of A. rhopalosiphi, larvae of A. bipunctata and E. balteatus, sand on adults of A. bilineata and B. lampros) and, for product that were toxic, a second assessment on natural substrate (barley seedlings for A. rhopalosiphi, french bean plants for A. bipunctato and E. balteatus and two type of soil for 8. lampros and A. bilineato). The effects of the product were assessed on basis on mortality, except for A. bilineata (Onion fly pupae parasitism). According to the final results obtained at the end of this testing scheme, the product were listed in toxicity class: green list if effect < or =30%, yellow list 30% < effect < 60% and orange list 60% < effect < or =80%. Products with toxicity higher than 80% on plants or on soils, or that reduce parasitism more than 80% on soil were put in red list and are not recommended for IPM. Results showed that all fungicides and herbicides were included in the green list except tebuconazole and boscalid + pyraclostrobin that were labeled as yellow for A. bipunctata. In opposite, no foliar insecticide was totally selective for all beneficial tested. However some products are in green list for one or several species. Soil insecticides were all are very toxic for ground dwelling arthropods and classed in red list. All results obtained during this study and further upgrade will be available on www.cra.wallonie.be/selectivite. In conclusions, fungicides and herbicides tested are compatible with IPM programs. For foliar insecticides, some treatments can be used carefully according to the selectivity. But for soil insecticide treatments, their toxicity raise the question of their use in IPM programs in vegetables and the need of new compounds or development of alternative pest control programs.     

Effects of weed harrowing frequency on beneficial arthropods,plants and crop yield

相似文献