Effects of terbinafine on growth, squalene, and steryl ester content of a celery cell suspension culture

The allylamine terbinafine inhibited growth of a celery (Apium graveolens) cell suspension culture (I₅₀ = 90 μM) and blocked the action of squalene epoxidase, resulting in an accumulation of squalene and a decrease in the sterol content of the cells. Celery cells were tolerant to squalene accumulation; inhibition of growth of cultures was associated with a fall in the free sterol content below about 1 μg sterol/mg dry wt of cells. At Day 14, untreated celery cells contained about 60% of the total sterol in the esterified form. However, the steryl ester pool was considerably lower in terbinafine-treated cells which may reflect an attempt to maintain the free sterol content above a threshold value. The composition of free sterols of terbinafine-treated cells was different from control cultures, suggesting that terbinafine has a second site of inhibition on the pathway to major sterols in plants.     

Effects of triazole fungicides on sterol biosynthesis during spore germination of Botrytis cinerea,Venturia inaequalis and Puccinia graminis f. sp. tritici

With three plant pathogens,Botrytis cinerea, Venturia inaequalis and Puccinia graminis f. sp.tritici, the time course of sterol biosynthesis during spore germination was examined by labeling experiments along with the question whether this pathway could be inhibited by triazole fungicides. Conidia ofB. cinerea andV. inaequalis are able to synthesize sterols immediately after the beginning of the germination process when the germ tubes have not yet emerged. On the contrary uredospores ofP. graminis start sterol biosynthesis after 6 to 8 h germination time almost at the end of the germ tube phase, indicating that sterol reserves of the spores are likely to be used for the germ tube growth.The sterol C-14 demethylation appeared to be the rate limiting step within the sterol biosynthetic pathway: the half life of 24-methylenedihydrolanosterol was less than 1 h forB. cinerea. It was more than 1 h forV. inaequalis and 3 h forP. graminis. Independent of these differences in the time course of sterol biosynthesis and in the C-14 demethylation rate, the synthesis of sterols in germinating spores was strongly inhibited by triazole fungicides in all three pathogens examined. In contrast toP. graminis, this inhibition could be demonstrated withB. cinerea andV. inaequalis even in ungerminated conidia, indicating that the fungicides were rapidly taken up and reached their target within 1 or 2 h. These results are discussed along with the question whether spore germination can be used as a bioassay for the estimation of sensitivities of triazole fungicides.     

Sterol content and other characteristics of pimaricin-resistant mutants of Aspergillus nidulans

Pimaricin-resistant mutants of Aspergillus nidulans were selected on a medium containing the polyene-antibiotic. Some resistant mutants contained markedly reduced amounts of ergosterol, but others contained almost normal levels of this sterol. Most resistant mutants which lacked ergosterol had a biochemical lesion in sterol C-22 desaturation. Analysis of sterols in one of these isolates showed the presence of 5,7-ergostadienol, 5,7,24(28)-ergostatrienol, and 5,8-ergostadienol. The sterol C-14 demethylation inhibitor, fenarimol, was more toxic to this mutant than to the wild type. On the other hand, mutants inactive in sterol C-22 desaturation were resistant to oligomycin but showed wild type sensitivity to carboxin. Attempts to select sterol C-14-demethylation-deficient mutants of Aspergillus nidulans, Monilinia fructicola, and Pyricularia oryzae on polyene-containing media were unsuccessful. Apparently C-14-methyl sterols do not support growth of these filamentous fungi.     

Inhibition of ergosterol biosynthesis by triadimenol in Ustilago avenae

In Ustilago avenae sporidia, following the first doubling period of about 4 h, triadimenol (2 μg ml^?1) affected sporidial multiplication more severely than other growth processes; daughter cells failed to separate from the parent sporidia resulting in chains of interconnected cells. Triadimenol incubated with the fungus for 8 h interfered neither with respiration nor with protein and nucleic acid synthesis but after 6 h the toxicant had induced a higher content of free fatty acids. Triadimenol markedly altered, both quantitatively and qualitatively, the sterols in sporidia of U. avenae. Incorporation of [¹⁴C]acetate (in the form of sodium acetate) into lipid fractions for a period of 2 h revealed that the toxicant powerfully inhibited the synthesis of the 4-demethyl sterol fraction (predominantly ergosterol), whilst the 4,4-dimethyl sterol fraction rapidly accumulated. This was confirmed by g.1.c. analysis of the sterols after 6 and 8 h incubation which showed that the amount of ergosterol, the major sterol in untreated sporidia, was diminished while simultaneously 4,4-dimethyl, 4-methyl and 14-methyl sterols increased. The accumulation of 14-methyl sterols suggests that triadimenol acts as a potent inhibitor of one of the metabolic steps involved in the demethylation at the 14-position during ergosterol biosynthesis.     

The lipid compositions of two isolates of Cladosporium cucumerinum do not explain their differences in sensitivity to fungicides which inhibit sterol biosynthesis

Isolate 840905 of Cladosporium cucumerinum, when grown on agar or in liqiud medium, was sensitive to triadimenol, HWG 1608 (tebuconazole), fenpropimorph and pimaricin but relatively resistant to terbinafine. Conversely, isolate 49628 was sensitive to terbinafine but relatively resistant to the other fungicides. Changes in sterol composition following treatment with the fungicides reflected the known modes of action of each fungicide. When individual enantiomers of triadimenol were tested against isolate 840905 the order of activity in reducing mycelial growth was 1 S, 2R > 1R, 2R > 1R, 2S ≈? 1S, 2S, and this was paralleled by the depletion of ergosterol and the appearance of 14α-methyl sterols. Isolate 49628 had a greater saturated:unsaturated fatty acid ratio than did isolate 840905 but no major changes in fatty acid composition of either isolate were induced by fungicide treatment. There appears to be no obvious explanation for the differences in fungicide sensitivity of the isolates in terms of their lipid compositions.     

Effects of sterol biosynthesis inhibitor fungicides in the phytopathogenic fungus,Nectria haematococca: ergosterol depletion versus precursor or abnormal sterol accumulation as the mechanism of fungitoxicity

The relative importance of the depletion of ergosterol versus the accumulation of precursor or abnormal sterols in the mechanism of fungal growth inhibition by sterol biosynthesis inhibitor fungicides is incompletely understood. In order to investigate this problem further, the degree of inhibition of the growth of Nectria haematococca by fungicides with different enzymatic targets in the sterol biosynthetic pathway was determined and compared with their effects on the sterol profile. The sensitivity of N. haematococca was highest towards fenpropimorph, followed by tebuconazole, terbinafine, fenpropidin and tridemorph. Terbinafine, a squalene epoxidase inhibitor, induced a very large accumulation of squalene without very significant inhibition of ergosterol biosynthesis and growth. The fungus appeared able to tolerate large amounts of squalene. In the case of tebuconazole, a sterol 14α-demethylase inhibitor, it seemed that the accumulation of C4 mono- and dimethyl sterols was responsible for fungitoxicity. Fenpropimorph and fenpropidin seemed to be good inhibitors of both sterol Δ¹⁴-reductase and Δ⁸→Δ⁷-isomerase, whereas tridemorph was a better inhibitor of Δ⁸→Δ⁷-isomerase than of the Δ¹⁴-reductase. Large accumulations of Δ^8,14- or Δ⁸-sterols and correspondingly large decreases in the ergosterol content are both implicated in the fungitoxicity of these compounds in N. haematococca. © 1998 Society of Chemical Industry     

Resistance to Sterol Demethylation Inhibitors in Ustilago maydis. III. Cross-Resistance Patterns and Sterol Analyses

Two spontaneous triadimefon-resistant mutants of Ustilago maydis, 151ar/1 and 151ar/3, were investigated with regard to their extent of cross-resistance and their sterol composition to elicit indications about the specificity of the present resistance mechanisms. Testing resistance to various sterol biosynthesis inhibitors and toxicants with different modes of action, it could be demonstrated that, in the mutant 151ar/1, cross-resistance was limited to the sterol demethylation inhibitors (DMIs), whereas, in strain 151ar/3, resistance included most sterol biosynthesis inhibitors studied (DMIs, morpholines, piperidines, allylamines) as well as the unrelated compounds vinclozolin and cycloheximide. Sterol analyses showed that both mutants contained ergosterol as the main sterol component. In comparison with the sensitive reference strain, the mutant 151ar/1 had a slightly elevated content of C-14 methyl sterols, whereas in strain 151ar/3 the amount of ergosterol was increased. Triadimefon caused an accumulation of C-14 methyl sterols and a decrease in ergosterol content in the sensitive strain and the mutant 151ar/1, whereas the other strain 151ar/3 remained unaffected. The results indicate that several resistance mechanisms are probably operating in the two mutants.     

Antifungal mode of action of triforine

Rapidly growing mycelia of Aspergillus fumigatus treated with 10 μg/ml triforine (N,N′-bis-(1-formamido-2,2,2-trichloroethyl)-piperazine) showed little or no inhibition in dry weight increase prior to 2 h. By 2.5–3 h, triforine inhibited dry weight increase by 85%. The effects of triforine on protein, DNA, and RNA syntheses corresponded to the effect on dry weight increase both in time of onset and magnitude. Neither glucose nor acetate oxidation were inhibited by triforine.Ergosterol synthesis was almost completely inhibited by triforine even in the first hour after treatment. Inhibition of ergosterol synthesis was accompanied by an accumulation of the ergosterol precursors 24-methylenedihydrolanosterol, obtusifoliol, and 14α-methyl-Δ^{8, 24 (28)}-ergostadienol. Mycelia treated with 5 μg/ml of triarimol (α-(2,4-dichlorophenyl)-α-phenyl-5-pyrimidinemethanol) also accumulated the same sterols as well as a fourth sterol believed to be Δ^{5, 7}-ergostadienol.Identification of 4,4-dimethyl-Δ^{8, 24 (28)}-ergostadienol in untreated mycelia indicates that the C-14 methyl group is the first methyl group removed in the biosynthesis of ergosterol by A. fumigatus. The lack of detectable quantities of 4,4-dimethyl-Δ^{8, 24 (28)}-ergostadienol in triforine or triarimol-treated mycelia and the accumulation of C-14 methylated sterols in treated mycelia suggests that both fungicides inhibit sterol C-14 demethylation. The accumulation of Δ^{5, 7}-ergostadienol in triarimol-treated mycelia further implies that triarimol also inhibits the introduction of the sterol C-22(23) double bond.Two strains of Cladosporium cucumerinum tolerant to triforine and triarimol were also tolerant to the fungicide S-1358 (N-3-pyridyl-S-n-butyl-S′-p-t-butylbenzyl imidodithiocarbonate).     

Effects of imazalil on sterol composition of sensitive and DMI-resistant isolates of Penicillium italicum

Imazalil differentially inhibited dry weight increase of 10-hour-old germlings of wild-type and DMI-resistant isolates ofPenicillium italicum in liquid malt cultures. EC₅₀ values ranged from 0.005 to 0.27 μg ml^?1. In all isolates ergosterol constituted the major sterol (over 95% of total sterols) in the absence of the fungicide. Therefore, DMI-resistance cannot be associated to a deficiency of the C-14 demethylation enzyme in the ergosterol biosynthetic pathway. Imazalil treatment at concentrations around EC₅₀ values for inhibition of mycelial growth resulted in a decrease in ergosterol content and a simultaneous increase in 24-methylene-24,25-dihydrolanosterol content in all isolates. A correlation existed between the imazalil concentration necessary to induce such changes in sterol composition and the EC₅₀ values for inhibition of mycelial growth of the different isolates. The reason for the differential effects of imazalil on sterol composition in the variousP. italicum isolates may be due to decreased accumulation of the fungicide in the mycelium and to other yet non-identified mechanisms of resistance.     

Action of fungicidal triazoles of the diclobutrazol series on ustilago maydis

Diclobutrazol [(2RS, 3RS)-1-(2, 4-dichlorophenyl)-4, 4-dimethyl-2-(1,2, 4-triazol-1-yl)pentan-3-ol] decreased the rate of growth of Ustilago maydis during the log phase. Marked changes in sterol composition were observed with a decrease in ergosterol and an increase in methyl-sterols, indicating a block in the removal of the 14-methyl group. The inhibition was of rapid onset (<4 h). Changes in other lipid constituents were minor and there was no build up of unsaturated fatty acids. The fungicidal activity resides in the (2R, 3R)-isomer, which is known to be more potent in blocking a yeast 14-demethylase enzyme than the (2S, 3S)-isomer. This relationship held in the 4-chlorophenyl homologues, which as a group were less fungicidal and less potent inhibitors than the 2, 4-dichlorophenyl compounds. The evidence presented indicates that the primary lesion caused by the fungicide was a build up of membrane sterols containing extra methyl groups; this, in combination with a loss of ergosterol, is believed to prevent proper membrane ordering and thus to cause a loss of membrane function.     

A mutant of Ustilago maydis deficient in sterol C-14 demethylation: Characteristics and sensitivity to inhibitors of ergosterol biosynthesis

An ergosterol-deficient mutant of Ustilago maydis was compared to the wild type in regard to morphology, growth rate, lipid content, and sensitivity to ergosterol biosynthetic inhibitors. Morphology of mutant sporidia is abnormal and resembles that of fenarimol-treated wild-type sporidia. Doubling time of mutant sporidia is 6.3 hr compared to 2.5 hr for the wild type. The mutant produces 24-methylenedihydrolanosterol, obtusifoliol, and 14α-methylfecosterol; ergosterol is absent. The sterols of the mutant are the same as those which accumulate in wild-type sporidia treated with the sterol C-14 demethylation inhibitors fenarimol, etaconazole, and miconazole. The level of free fatty acids is higher in the mutant than in wild-type cells. Growth of mutant sporidia is not inhibited by fenarimol, etaconazole, and miconazole, or by the sterol Δ¹⁴-reductase inhibitor azasterol A25822B at low concentrations which inhibit growth of wild-type sporidia. The residual growth rate of wild-type sporidia treated with low concentrations of the sterol C-14 demethylation inhibitors is about the same as that of untreated mutant sporidia. Therefore, the mutant would not be recognized as resistant in a wild-type population. The mutant is deficient in sterol C-14 demethylation and is similar in all properties studied to wild-type sporidia treated with sterol C-14 demethylation inhibitors. These findings support the contention that inhibition of sterol C-14 demethylation in U. maydis is the primary mode of toxicity of fenarimol, etaconazole, and miconazole. A secondary mode of toxicity is evident for miconazole and etaconazole at higher concentrations but is doubtful for fenarimol.     

Fungitoxicity and growth regulation involving aspects of lipid biosynthesis

Triarimol and triforine inhibit ergosterol biosynthesis in fungi and cause accumulation of free fatty acids, 24-methylenedihydrolanosterol, obtusifoliol and 14α-methyl-δ^8,24(28)-ergostadienol. Triparanol also inhibits ergosterol synthesis and causes accumulation of free fatty acids, but not of the latter 3 sterols. Triparanol appears to inhibit prior to lanosterol in the sterol biosynthetic pathway of Ustilago maydis and at unidentified sites subsequent to lanosterol which lead to the accumulation of a sterol which migrates with desmethylsterols on TLC plates. Quantitative abnormalities in sterols and free fatty acids in U. maydis are not produced by the fungicides carbendazim, chloroneb, carboxin and cycloheximide. A deficiency in nitrogen leads to a marked increase in triglycerides, but a normal distribution pattern for other lipids.Inhibition of oxidative demethylation of the sterol 14α-methyl group is probably the prime mechanism of inhibition of ergosterol biosynthesis by triarimol. Rates of formation of obtusifoliol and 14α-methyl-δ^8,24(28)-ergostadienol in triarimol-treated U. maydis cells suggest that C-4 demethylation occurs along an abnormal pathway which operates effectively only at high substrate concentrations. The growth retardant action of triarimol and ancymidol in higher plants most likely results from inhibition of a reaction in the gibberellin biosynthetic pathway analogous to sterol C-14 demethylation.Free fatty acid accumulation in U. maydis cells treated with inhibitors of sterol synthesis are derived mainly from polar lipid degradation and from de novo synthesis as a consequence of the disproportionality between fatty acid synthesis and utilization. The free fatty acids may play a significant role in the lethality of these inhibitors in this organism.     

Sterol metabolism in wheat treated by N-substituted morpholines

Wheat caryopses were treated with racemic fenpropimorph. As shown previously in other plant species, 9(β,19-cyclopropyl sterols were found to accumulate markedly. A distinctive feature was a remarkable accumulation of 31 -norcyclobranol, a very rare sterol in nature. A⁸-sterols were also identified. The ratio A⁸-sterols: cyclopropyl sterols was shown to depend greatly on the configuration of the methyl substituent in position 2 of fenpropimorph. Whereas cyclopropyl sterols predominated in the case of seedlings treated with the (2S)-2-methyl enantiomer, A⁸-sterols were shown to be very abundant in plants treated with the (2R)-2-methyl enantiomer. A⁸-sterols were shown also to be more abundant in leaves than in roots. Experiments were conducted to find out whether the phytotoxic response of plants to fenpropimorph could be ascribed to its action on sterol biosynthesis. From the results obtained it appears that this is not the case and thus the phytotoxic effect is probably related to a cellular target other than sterol biosynthesis.     

Effects of sterol biosynthesis-inhibiting fungicides and plant growth regulators on the sterol composition of barley plants

A number of sterol biosynthesis-inhibiting (SBI) fungicides and plant growth regulator analogs were applied as root drenches to barley seedlings and their effect on the total sterol composition of the roots and shoots was measured by gas-liquid chromatography. Prochloraz was found to be inactive in this system, probably because of poor uptake, while the other compounds could be divided into two groups according to their mode of action as assessed by sterol profiling. The morpholines tridemorph and fenpropimorph inhibited the enzyme cycloeucalenol—obtusifoliol isomerase whereas triadimenol, nuarimol, paclobutrazol, and triapenthenol (RSW 0411) inhibited the enzyme responsible for the removal of the C-14 methyl group. Effects of individual diastereo-isomers and enantiomers of some compounds on sterol profiles were compared with their known fungicidal and anti-gibberellin properties. Shoot growth was reduced by all the compounds tested, paclobutrazol, nuarimol, and triapenthenol being the most effective. As well as inducing accumulation of abnormal sterols, SBI fungicide treatment changed the ratio of campesterol to stigmasterol and sitosterol. It is hypothesized that this may reflect changes in membrane architecture and may offer an explanation for the increased frost hardiness sometimes observed with SBI fungicide-treated plants.     

Effects of imazalil on sterol composition of sensitive and DMI-resistant isolates of Penicillium italicum

Imazalil differentially inhibited dry weight increase of 10-hour-old germlings of wild-type and DMI-resistant isolates ofPenicillium italicum in liquid malt cultures. EC₅₀ values ranged from 0.005 to 0.27 g ml^–1. In all isolates ergosterol constituted the major sterol (over 95% of total sterols) in the absence of the fungicide. Therefore, DMI-resistance cannot be associated to a deficiency of the C-14 demethylation enzyme in the ergosterol biosynthetic pathway. Imazalil treatment at concentrations around EC₅₀ values for inhibition of mycelial growth resulted in a decrease in ergosterol content and a simultaneous increase in 24-methylene-24,25-dihydrolanosterol content in all isolates. A correlation existed between the imazalil concentration necessary to induce such changes in sterol composition and the EC₅₀ values for inhibition of mycelial growth of the different isolates. The reason for the differential effects of imazalil on sterol composition in the variousP. italicum isolates may be due to decreased accumulation of the fungicide in the mycelium and to other yet non-identified mechanisms of resistance.Imazalil remt differentieel de toename in drooggewicht van 10-uur-oude gekiemde sporen van wild-type en DMI-resistente isolaten vanPenicillium italicum in vloeistofcultures van moutextract. De EC₅₀ waarden voor groei van de verschillende isolaten lopen uiteen van 0,005 tot 0,27 g ml^–1. In afwezigheid van het fungicide is in alle isolaten ergosterol het belangrijkste sterol (meer dan 95% van het totaal). DMI-resistentie kan daarom niet in verband staan met deficiëntie van het C-14 demethyleringsenzym in de ergosterol biosynthese. Imazalilbehandeling van mycelium bij concentraties rond de EC₅₀ waarde voor groeiremming, resulteerde bij alle isolaten in een afname van het ergosterolgehalte en een gelijktijdige toename van het gehalte aan 24-methyleen-24,25-dihydrolanosterol. Er bestaat dus een nauwe correlatie tussen de imazalilconcentratie die noodzakelijk is om vergelijkbare veranderingen in sterolsamenstelling te induceren en de EC₅₀ waarde voor remming van myceliumgroei van de verschillende isolaten. De differentiële effecten van imazalil op de sterolsamenstelling van de verschillendeP. italicum isolaten kunnen worden veroorzaakt door verminderde accumulatie van het fungicide in het mycelium en door andere, nog niet geïdentificeerde resistentiemechanismen.     

Germination response of Orobanche seeds subjected to conditioning temperature, water potential and growth regulator treatments

Broomrapes (Orobanche spp.) are parasitic weeds that cause significant losses of crop yield. Experiments were conducted to investigate the seed response to the artificial germination stimulant GR₂₄ in three species of Orobanche subjected to preconditioning under various temperatures, water potentials and with plant growth regulators. The highest germination percentages were observed in Orobanche ramosa, Orobanche aegyptiaca and Orobanche minor seeds conditioned at 18°C for 7 days followed by germination stimulation at 18°C. With the increase of the conditioning period (7, 14, 21 and 28 days), the germination percentage of O. ramosa and O. aegyptiaca progressively decreased. When conditioned at −2 MPa, the germination percentage was lower than at 0 and −1 MPa, especially at 13 and 28°C. Orobanche minor seeds could retain relatively high germination if conditioned at 18, 23 or 28°C, even after significantly extended conditioning periods (up to 84 days). GA₃ (30–100 mg L⁻¹), norflurazon and fluridone (10–100 mg L⁻¹), and brassinolide (0.5–1.0 mg L⁻¹) increased seed germination, while 0.01 mg L⁻¹ uniconazole significantly reduced germination rates of all three Orobanche spp. The promotional effects of GA₃ and norflurazon and the inhibitory effect of uniconazole were evident, even when they were treated for 3 days. Germination of Orobanche seeds was much lower when the unconditioned seeds were directly exposed to GR₂₄ at 10⁻⁶ m . This early GR₂₄-induced inhibition was however alleviated or even eliminated by the inclusion of GA₃ or norflurazon (10–50 mg L⁻¹) in the conditioning medium. On the contrary, the inclusion of uniconazole increased the inhibitory effect of GR₂₄, particularly in the case of O. ramosa.     

Relationship between chemical structure and biological activity of triazole fungicides against Botrytis cinerea

The inhibitory activity of commercial and experimental triazole fungicides on the target enzyme, sterol 14α-demethylase (P450_14DM), was studied in a cell-free sterol synthesis assay of Botrytis cinerea Pers. ex Fr. In order to assess structure-activity relationships, the inhibitory activities of the compounds on radial growth of the fungus were tested as well. The EC₅₀ values (concentrations of fungicide inhibiting radial growth of B. cinerea on PDA by 50%) of all triazoles tested ranged between 10^?8 and 10^?5 m. IC₅₀ values (concentrations of fungicide inhibiting incorporation of [2-¹⁴C]mevalonate into C4-desmethyl sterols by 50%) generally ranged between 10^?9 and 10^?7 M and correlated with inhibition of radial mycelial growth. However, differences in IC₅₀ values did not reflect quantitatively the observed differences in EC₅₀ values, since the ratio between EC₅₀ and IC₅₀ increased with decreasing fungitoxicity. For a limited number of compounds the correlation between intrinsic inhibitory activity and fungitoxicity was low. Both in-vitro tests were used to investigate structure-activity relationships for stereoisomers of cyproconazole, SSF-109 and tebucona-zole. Fungitoxicity and the potency to inhibit cell-free C4-desmethyl sterol synthesis correlated for all stereoisomers tested. Mixtures of isomers of tebucona-zole or cyproconazole were slightly less active than the most potent isomer. The high activity of several commercial triazoles in both experiments implies that poor field performance of triazole fungicides against B. cinerea is due neither to insensitivity of the P450_14DM nor to low in-vitro sensitivity of the fungus.     

Development of a cell-free assay from Botrytis cinerea as a biochemical screen for sterol biosynthesis inhibitors

An assay for measuring ergosterol synthesis in cell-free extracts of the filamentous plant pathogen Botrytis cinerea is described. The extracts capable of synthesizing C4-desmethyl sterols from [2- 14 C]mevalonate were derived by mechanical disruption of young conidial germlings in a Bead-Beater apparatus. The C4-desmethyl sterol fraction consisted of three distinct compounds and totalled 39% of the non-saponifiable lipids formed. Ergosterol accounted for 63% of the C4-desmethyl sterols. Only small amounts of C4-monomethyl sterols were synthesized, while C4, 4-dimethyl sterols made up 29% of the non-saponifiable lipids. The latter fraction mainly consisted of lanosterol (54%) and eburicol (28%). The cell-free system had a narrow pH optimum for synthesis of C4-desmethyl sterols of pH 7.3–7.4. Cell-free synthesis of C4-desmethyl sterols was inhibited by the imidazole fungicide imazalil, concomitant with an accumulation of eburicol. The IC₅₀ value (concentration of fungicide which inhibited cell-free synthesis of C4-desmethyl sterols by 50%) was 9.1 × 10 ?9 M. These results are consistent with the hypothesis that imazalil is a potent inhibitor of the cytochrome P450-dependent sterol 14x-demethylase of B. cinerea. The method described may be used to screen compounds biochemically for inhibition of sterol synthesis in an agriculturally important plant pathogen.     

Propanil‐resistant barnyardgrass [Echinochloa crus‐galli (L.) Beauv.] in Sri Lanka: Seedling growth under different temperatures and control

Experiments were conducted to (i) evaluate the efficacy of propanil formulations available in Sri Lanka in controlling Echinochloa crus‐galli; (ii) study the seedling growth of propanil‐resistant (R) and ‐susceptible (S) biotypes of the weed under different temperatures; (iii) quantify the level of resistance in R biotypes and; (iv) to suggest alternative control measures for R biotypes. Field studies showed that retail propanil formulations (36% a.i., EC) applied at 2.7 kg a.i. ha^?1 gave less than 30% control of E. crus‐galli collected from several locations of the north dry zone of Sri Lanka. Chemical analysis revealed that there was no adulteration of propanil formulations at the retailer level. Growth studies conducted in controlled environments indicated that per cent germination and seedling growth of R and S biotypes were similar at the day/night temperature regimes imposed. However, per cent germination for plants grown under a 34/31°C (day/night) regime was 27–29% higher compared to those grown at 28/24°C. At the higher temperature regime, R and S biotypes reached the 2–3 leaf stage five days earlier, and the 4–5 leaf stage seven days earlier. The ED₅₀ values from the dose–response experiments indicated that the R biotype was four times more resistant to propanil than susceptible ones. The resistance index (RI) did not vary significantly under different temperature regimes. Quinclorac (25% a.i., SC) applied at 200 g a.i. ha^?1 and bispyribac‐sodium (10% a.i., SC) applied at 30 g a.i. ha^?1 (recommended dosages) successfully controlled propanil‐resistant biotypes of E. crus‐galli. Conversely, oxadiazon and propanil (8% and 23% a.i., EC, respectively) applied at 280 + 805 g a.i. ha^?1 did not result in satisfactory control.