Resistance in mutagen-induced mutants of Ustilago maydis to fungicides which inhibit ergosterol biosynthesis

Resistance to a number of inhibitors of sterol C-14 demethylation, (clotrimazole, imazalil, miconazole, fenarimol, nuarimol and triadimefon), as well as resistance to inhibitors of sterol C-14(15) double bond reduction, (tridemorph and fenpropi-morph), was readily induced in Ustilago maydis. Resistant mutants were obtained after mutagenic treatment by ultraviolet irradiation, or by treatment with 1-methyl-3-nitro-1-nitrosoguanidine, of sporidia of the wild-type strain, followed by selection in the presence of the toxicant. The level of resistance of these mutants varied appreciably. Although not always reciprocal, cross-resistance to fungicides which inhibit ergosterol biosynthesis (EBIs) appeared to be present in most cases. Several of the U. maydis mutants which were resistant to inhibitors of sterol C-14 demethylation lacked cross-resistance to tridemorph and fenpropimorph, or displayed increased sensitivity to fenpropimorph (negatively correlated cross-resistance). Cross-resistance between EBIs and the antimicrobial agents climbazole and lombazole was also established. It is suggested that fungal mutants that possess a resistance mechanism based on a deficiency in sterol C-14 demethylation or sterol C-14(15) double bond reduction, have a greatly reduced chance of survival.     

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.     

Resistance to inhibitors of sterol biosynthesis in field isolates or laboratory strains of the eyespot pathogen Pseudocercosporella herpotrichoides

Strains of Pseudocercosporella herpotrichoides collected in France on winter wheat give either fast-growing mycelial colonies with regular margins or slow-growing mycelial colonies with irregular margins. Most of the fastgrowing isolates were sensitive to triadimenol (EC₅₀ below 2mg litre^?1), but some of them were resistant to this inhibitor of sterol C-14 demethylation. In contrast, all the slow-growing strains were highly resistant to triadimenol (EC₅₀ greater than 100 mg litre^?1). This resistance was also expressed in inhibition of germ-tube elongation. Positive cross-resistance was observed between most of the inhibitors of sterol C-14 demethylation, with the exception of some imidazole derivatives (clotrimazole, prochloraz). All the fast-growing strains were tolerant to fenpropimorph and fenpropidin whereas the slow-growing ones were susceptible; the reverse was true with piperalin and tridemorph. All the field isolates were inhibited to the same extent by the inhibitors of squalene-epoxidase, nafifine and terbinafine. Two types of mutant resistant to triadimenol have been induced under laboratory conditions from sensitive fast-growing strains. The most common mutants were resistant to all the inhibitors of sterol C–14 demethylation and also in some conditions to fenpropimorph, tridemorph and the inhibitors of squalene-epoxidase. The other mutants were characterised by a reduced spectrum of cross-resistance between triadimenol and the other inhibitors of sterol biosynthesis. The field isolates and laboratory mutants resistant to triadimenol and propiconazole were also resistant to each of the four enantiomers of these two fungicides.     

New Cases of Negative Cross-resistance between Fungicides,Including Sterol Biosynthesis Inhibitors

A survey of fungicide resistance in Mycosphaerella graminicola and Tapesia acuformis, two major pathogens of winter wheat in France, respectively responsible for speckled leaf blotch and eyespot, led to the characterization of two types of resistant strains to sterol 14α-demethylation inhibitors (DMIs). Most of the strains of M. graminicola collected in France in 1997–1998 were resistant to all DMIs, and only in a few strains was the resistance to several triazoles associated with increased susceptibility to pyrimidine derivatives (i.e., fenarimol, nuarimol) and triflumizole. On the other hand, in T. acuformis the most prevalent strains were those which exhibited negative-cross resistance between DMIs. In both fungi such a phenomenon could be related to changes in cytochrome P450 sterol 14α-demethylase, the target site of these fungicides. For Botryotinia fuckeliana, the causal agent of grey mould, the extensive monitoring conducted in French vineyards before the marketing of fenhexamid revealed the presence of highly resistant strains to this promising botryticide (only in tests involving mycelial growth measurements). Negative cross-resistance to edifenphos and several sterol biosynthesis inhibitors, such as prochloraz and fenpropimorph, was observed in fenhexamid resistant strains. Synergism of the antifungal action of fenhexamid by cytochrome P450 inhibitors, such as the DMI fungicides, was only recorded in fenhexamid resistant strains. These data and those previously obtained with edifenphos resistant strains of Magnaporthe grisea (rice blast pathogen) suggest that in fenhexamid resistant strains of B. fuckeliana the same cytochrome P450 monooxygenase could be involved in detoxification of fenhexamid and activation of edifenphos. Received 6 September 1999/ Accepted in revised form 13 September 1999     

Effect of the fungicide pyrifenox on sterol biosynthesis in Ustilago maydis

Pyrifenox, a new pyridine derivative, proved to be an inhibitor of ergosterol biosynthesis, blocking the pathway at the C-14 demethylation step in Ustilago maydis (CD.) Cor da. In treated sporidia the incorporation of [1-¹⁴C]acetic acid into ergosterol and squalene was reduced and the incorporation into sterols which retain the C-14 methyl group, mainly 24-methylenedihydrolanosterol and obtusifoliol, was increased. In addition, treatment with pyrifenox markedly reduced the incorporation into sterol esters. It is possible that the methylated sterols may be unsuitable substrates for the esterification enzyme.     

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.     

Mutations in the CYP51 gene correlated with changes in sensitivity to sterol 14 alpha-demethylation inhibitors in field isolates of Mycosphaerella graminicola

In France, as in many other European countries, Mycosphaerella graminicola (Fuckel) Schr?ter in Cohn (anamorph Septoria tritici), the causal agent of wheat leaf blotch, is controlled by foliar applications of fungicides. With the recent generalization of resistance to strobilurins (QoIs), reliable control is mainly dependent upon inhibitors of sterol 14 alpha-demethylation (DMIs). To date, strains with reduced sensitivity to DMIs are widespread, but disease control using members of this class of sterol biosynthesis inhibitors has not been compromised. In this study, sensitivity assays based on in vitro effects of fungicides towards germ-tube elongation allowed the characterization of seven DMI-resistant phenotypes. In four of them, cross-resistance was not observed between all tested DMIs; this characteristic concerned prochloraz, triflumizole, fluquinconazole and tebuconazole. Moreover, the highest resistant factors to most DMIs were found only in recent isolates; according to their response towards prochloraz, they were classified into two categories. Molecular studies showed that DMI resistance was associated with mutations in the CYP51 gene encoding the sterol 14 alpha-demethylase. Alterations at codons 459, 460 and 461 were related to low resistance levels, whereas, at position 381, a valine instead of an isoleucine, in combination with the previous changes, determined the highest resistance levels to all DMIs except prochloraz. Mutations in codons 316 and 317 were also found in some isolates exhibiting low resistance factors towards most DMIs.     

Cross-Resistance Patterns Among Sterol Biosynthesis Inhibiting Fungicides (SBIs) in Cercospora beticola

Thirty single-spore isolates of Cercospora beticola, collected from several fields in northern Greece, representing a broad spectrum sensitivity to the sterol demethylation-inhibiting (DMIs) fungicide flutriafol, were tested for sensitivity to eleven other sterol biosynthesis-inhibiting (SBI) fungicides and to the guanidine fungicide dodine. Sensitivity was measured as EC₅₀ values for each fungicide and log-transformed EC₅₀ values to each fungicide were pairwise correlated and the correlation coefficient estimated. These pairwise comparisons showed high correlation coefficients between the DMIs suggesting a cross-resistance relationship between these fungicides. However, the degree of cross-resistance between DMIs varied greatly. Conversely, low correlation coefficients were obtained for the pair-wise comparisons with the morpholine fungicide fenpropimorph suggesting a lack of cross-resistance between morpholines and DMIs in C. beticola. Similarly, there was no correlation between the sensitivity (EC₅₀ values) to dodine and all the other fungicides tested, indicating that there was no negative cross-resistance relationship between dodine and SBIs in C. beticola. Based on these results, combinations or alternations of fungicides which show no cross-resistance relationship should be used to control the disease in areas where reduced sensitivity to DMIs has been already observed.     

Impact of fludioxonil resistance on fitness and cross-resistance profiles of Altrenaria solani laboratory mutants

Sensitivity and inherent resistance risk of Alternaria solani to fludioxonil, cross-resistance profiles and the potential implications of resistance mutations on fitness parameters were investigated. Fludioxonil was highly effective against a wild type A. solani field strain both in vitro (EC₅₀?=?0.05 μg/mL) and in preventive applications on artificially inoculated tomato fruit. Mutants with low [Resistance factor (Rf): 15 based on EC₅₀], medium (Rf: 150–300) and high (Rf: > 1000) levels of phenylpyrrole resistance were isolated from the wild type strain at high frequencies following mutagenesis with UV irradiation and selection on fludioxonil containing medium. Resistant isolates retained their resistance levels even after 9 subcultures on fungicide-free growth medium while they could express their resistant phenotypes in planta. Investigation of cross-resistance relationships showed that fludioxonil resistance mutations also reduce the sensitivity of mutant strains to the aromatic hydrocarbon fungicide quintozene as well as the dicarboximides iprodione and vinclozolin. No cross-resistance was observed between fludioxonil and fungicides with different modes of action such as the sterol biosynthesis inhibitors (DMIs) imazalil and flusilazole and the carboxamide boscalid. All fludioxonil resistant isolates were more sensitive to the anilinopyrimidine pyrimethanil, while only two isolates were less sensitive to the QoI pyraclostrobin compared to the wild-type strain. Study of fitness determining parameters showed that resistance mutation(s) had no adverse effects on mycelial growth, conidial germination and sensitivity to osmotic stress while they had a pleiotropic effect on virulence and conidia production in resistant mutants. Results of the present study indicate that fludioxonil is a highly effective fungicide against A. solani, while the risk of resistance development to this fungicide is considered to be medium making fludioxonil an ideal alternative to high risk fungicides such as boscalid and pyraclostrobin whose performance against early blight has already been compromised by resistance development.

     

植物病原真菌对甾醇脱甲基抑制剂类杀菌剂抗性分子机制研究进展

甾醇脱甲基抑制剂 (DMI) 可通过抑制病原真菌的14α-去甲基化酶(CYP51)而干扰或阻断细胞膜麦角甾醇的生物合成,造成有毒甾醇积累,从而影响细胞膜的结构及功能,进而发挥抗菌作用。随着DMI类杀菌剂的广泛应用,病原菌对其的抗性问题日益严重。本文从抗药性分子机制出发,总结出病原菌对DMI类杀菌剂产生抗性的主要原因为:CYP51氨基酸突变引起其与杀菌剂间的亲和力下降;启动子区域基因片段的插入引起CYP51基因过表达;转录因子激活突变或启动子区域基因片段插入导致外排蛋白基因过表达。本文基于杀菌剂的作用方式及病原菌抗性机制研究展开综述,可为杀菌化合物的结构修饰与优化、新靶点改进和研发以及病原真菌的抗药性治理提供参考。     

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).     

Analogy in the mode of action of fluotrimazole and clotrimazole in Ustilago avenae

Fluotrimazole [BUE 0620; 1-(3-trifluoromethyltriphenyl) 1,2,4-triazole] (20 μg/ml of nutrient solution) and clotrimazole [Bay b 5097; bisphenyl(2-chlorophenyl)-1-imidazolyl methane] (5 μg/ml) did not inhibit dry weight increase and only slightly reduced multiplication of sporidia of Ustilago avenae during the first doubling period (about 4 hr). After 8 hr, both fluotrimazole and clotrimazole more strongly inhibited sporidia multiplication than dry weight increase. As a consequence of treatment with both fungicides the usually single-celled sporidia appear swollen, multicellular, and branched. Both chemicals at a concentration range of 5–100 μg/ml did not affect oxidation of glucose. The effect of fluotrimazole and clotrimazole on protein, DNA, and RNA synthesis was similar to that on dry weight. Following a 6-hr incubation period total lipid synthesis was quantitatively unaffected by both chemicals. As the analysis of major fatty acids of total lipids revealed fluotrimazole substantially induced the synthesis of 20:4 carbon fatty acids, while in clotrimazole-treated sporidia the pattern of fatty acids did not differ from that of control sporidia. Fluotrimazole and clotrimazole produced a higher quantity of free fatty acids in sporidia of U. avenae. Gas-liquid chromatographic analysis of sterol fractions in treated and control sporidia (6 hr) indicated that both fluotrimazole and clotrimazole seriously inhibited ergosterol biosynthesis and concomitantly caused an accumulation of immediate ergosterol precursors which represent C-4-methyl and 4,4-dimethyl sterols. Incorporation of [¹⁴C]acetate for 2 hr into various lipid fractions of sporidia of U. avenae also revealed that radioactivity in C-4-desmethyl sterols in both fluotrimazole- and clotrimazole-treated sporidia was drastically reduced, while the radioactivity of C-4-methyl and 4,4-dimethyl sterols distinctly increased. The data suggest that fluotrimazole and clotrimazole are specific inhibitors of the oxidative demethylation of the C-14-methyl group during ergosterol biosynthesis in U. avenae.     

Detection and Quantification of Resistance of Venturia inaequalis Populations to Sterol Demethylation Inhibitors

ABSTRACT Monoconidial isolates of Venturia inaequalis were collected in 1990 and 1991 from orchards in New York, Michigan, and Nova Scotia that had never or only sporadically been treated with fungicides acting as sterol demethylation inhibitors (DMIs). Sensitivities of isolates to two representative DMIs (fenarimol and myclobutanil) were determined by a sensitivity test based on the relative growth (RG) of mycelial colonies at one discriminatory dose. Mean isolate sensitivities were not significantly different (P > 0.2) for the majority of the populations tested, and all sensitivity data obtained from these sites were combined to provide a baseline distribution of isolate sensitivities for both fenarimol and myclobutanil. The baseline distributions were compared with isolate sensitivities determined for an experimental orchard in Nova Scotia with a documented case of DMI resistance and for a commercial orchard in Michigan with a long history of DMI use and first evidence of practical DMI resistance. For both DMIs tested and in both treated orchards, frequencies of isolates with RG values <80 had decreased or only slightly increased compared to the baseline population. In contrast, frequencies of isolates with RG values >80 had increased more than 20-fold over baseline levels. Thus, isolates with RG values >80 were rated DMI resistant. The validity of a qualitative isolate classification was tested in controlled infection studies. At doses of fenarimol and myclobutanil recommended for commercial control of apple scab, reproduction of a typical sensitive isolate on treated apple leaves was suppressed completely. Lesions caused by a resistant isolate continued to expand and produced abundant conidia. Statistical analysis of orchard sensitivities revealed that the analysis of isolate counts grouped into the categories DMI sensitive or resistant was most indicative in comparisons of orchard sensitivities aimed at detection of practical DMI resistance. A high degree of cross-resistance between fenarimol and myclobutanil indicated that sensitivity tests with one of the DMIs employed as the diagnostic tool in this study can serve as a test for other DMIs.     

Ultrastructure and sterol composition of laboratory strains of Ustilago avenae resistant to triazole fungicides

The fine structure and sterol composition of wild-type and triazole-resistant laboratory strains of Ustilago avenae was investigated by electron microscopic and biochemical methods. The growth rate of the mutants was only slightly affected by a fungicide (triadimefon) concentration of about 0.1 mg/ml, whereas the wild-type cells were completely inhibited. Biochemically the sterol composition of wild-type and triazole-resistant strains did not differ. In freeze-fracture electron microscopy no ultrastructural differences were observed between the different untreated strains (wild and resistant). Filipin labeling allowed the localization of ergosterol in the plasmalemma (PF and EF). Generally, wild-type samples and mutants exhibited a clear pattern of filipin-sterol (FS-) complexes. These results are in accord with the biochemical experiments. Neither a modification of the sterol composition nor an altered localization of sterols seemed to be the prime cause of resistance in U. avenae mutants. Alternative explanations for the resistance mechanism are discussed.     

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.     

Characterization of fenarimol-resistant mutants of Aspergillus nidulans

The fitness of twelve fenarimol-resistant mutants of Aspergillus nidulans was tested with respect to spore germination, germ tube elongation, hyphal growth and sporulation. Half of the strains tested were isolated on triarimolcontaining media. The other strains were selected on imazalil-or cycloheximide-containing media (Van Tuyl, 1977).A number of mutant strains produced spores with unimpaired viability on synthetic medium. In other strains a reduction in spore viability was noticed. The rate of germ tube elongation of all resistant mutants was significantly lower than that of the wild-type strain. Mutant strains with a low degree of resistance always had an almost normal mycelial growth rate, whereas growth of some of the strains with a relatively high degree of resistance was significantly slower. Spore production on malt agar was highest in the wild-type strain and was found to be lower in fenarimol-resistant mutants. In most of the mutant strains tested a high degree of cross-resistance between fenarimol, imazalil and triadimefon was established; in some of them cross-resistance to these chemicals was low or even absent.Possible implications of the results described for the chance of development of resistance in phytopathogenic fungi to sterol biosynthesis-inhibiting fungicides are discussed.     

Biochemical aspects of the fungitoxic and growth regulatory action of fenarimol and other pyrimidin-5-ylmethanols

The C-14 demethylation of the sterols, dependent on cytochrome P-450, and the C-22(23) desaturation of sterols are reactions in the ergosterol biosynthesis pathway that are regarded as primary target sites in the toxicity of fungicides of the pyrimidin-5-ylmethanol type. Currently, there is no evidence for target sites in other pathways of comparable sensitivity, although the failure of added ergosterol to reverse the fungitoxicity suggests the existence of such sites. The mitochondrial respiratory systems in Ustilago maydis and Aspergillus nidulans are insensitive to this type of fungicide and are not regarded as primary targets of fungitoxicity in these organisms. Appreciable evidence indicates that the primary targets in higher plant growth regulation are reactions, dependent on cytochrome P-450, that assist in the conversion of kaurene to kaurenoic acid in the gibberellin (GA) biosynthesis pathway. Growth retardation by high concentrations of pyrimidin-5-ylmethanols, which is not reversable by GA, apparently involves action at sites outside the GA biosynthesis pathway. The data derived from various studies of the mechanisms of fungitoxicity and growth regulation suggest that any undetected primary targets of the pyrimidin-5-ylmethanols are likely to be haem enzymes, similar to the cytochrome P-450 involved in sterol C-14 demethylation.     

Acquisition of Resistance to Sterol Demethylation Inhibitors by Populations of Venturia inaequalis

ABSTRACT Acquisition of resistance to sterol demethylation inhibitors (DMIs) by populations of Venturia inaequalis was investigated using a microscopical method developed by C. Siebels and K. Mendgen. Microscopical analysis of conidiophore formation enabled the earlier detection of resistance and a clearer distinction between DMI-resistant and DMI-sensitive populations than other in vivo methods commonly used to analyze inhibitory effects of fungicides. In addition, because observations were made on the level of individuals, quantitative measures of the composition of conidial populations were obtained. The development of DMI sensitivity was followed over a period of 3 years in control apple orchards that had never been treated with fungicides and in orchards with DMI history. The 50% effective dose values determined by microscopical evaluation of conidio-phore development for untreated populations revealed the baseline sensitivities of 0.3, 0.96, 0.09, 1.22, and 1.92 mg/liter for flusilazole, fenarimol, difenoconazole, tebuconazole, and pyrifenox, respectively. As compared with the baseline sensitivity, all populations with DMI history showed significant resistance to flusilazole. A strong nonlinear correlation (R = 0.96) was found between the resistance factors and the sum of all DMI treatments of the 3 years before taking the sample. According to this correlation, resistance can be expected in all apple orchards of the fruit-growing area along Lake Constance, Germany, in which more than two DMI treatments per season have been applied. Due to cross-resistance, the recently introduced DMI fungicides difenoconazole, tebuconazole, and pyrifenox did not allow the control of V. inaequalis populations resistant to flusilazole.