Mode of action of triadimefon in Ustilago avenae

Triadimefon [1-(4-chlorophenoxy)-3,3-dimethyl-(1,2,4-triazol-1-yl)-2-butanone], 1.5–2.0 μ/ml, inhibited the multiplication of sporidia of Ustilago avenae more strongly than it did the increase of dry weight. The treated sporidia appeared swollen, multicellular, and branched. At concentrations of 1.5–100 μg of triadimefon/ml, the oxidation of glucose was not affected. Increase in dry weight and synthesis of protein, RNA, and DNA were inhibited slightly, whereas cell division was acutely arrested. After an incubation period of 9.5 hr, microscopic studies revealed that daughter cells of the treated sporidia also contained one nucleus. In sporidia treated for 6 hr with triadimefon, both the total lipid content and its composition of fatty acids were not appreciably altered. The treated cells, however, differed from control cells by a higher content of free fatty acids. Triadimefon markedly interfered in sterol biosynthesis in Ustilago avenae. Gas chromatographic (glc) analysis and [¹⁴C]acetate incorporation studies indicated that ergosterol biosynthesis was almost completely inhibited by triadimefon; on the other hand, sterol compounds representing precursors of ergosterol (probably 4,4-dimethyl and C-4-methyl sterols) accumulated in treated sporidia. As the results indicate, the inhibition of conversion of immediate sterol precursors to ergosterol may be regarded as the primary target for the action of triadimefon in Ustilago avenae.     

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.     

Mode of action of triarimol in Ustilago maydis

Triarimol (2 μg/ml) strongly inhibited multiplication of Ustilago maydis sporidia after one doubling, but growth continued and sporidia became abnormally large, branched and multicellular. Oxidation of glucose or acetate was not affected, and only slight limitations occurred in DNA, RNA and protein syntheses. The toxicant did not inhibit triglyceride synthesis but markedly increased the quantity and altered the quality of free fatty acids. Incorporation of [¹⁴C]acetate into ergosterol and an unidentified sterol was inhibited more than 90%, but incorporation into two other unidentified sterols was almost unaffected. Inhibition in the sterol biosynthetic pathway at a point preceeding ergosterol is regarded as a primary site of triarimol action in U. maydis.     

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.     

Specific effects of tridemorph on sterol biosynthesis in Ustilago maydis

In an attempt to indicate the site of action of tridemorph in ergosterol biosynthesis by Ustilago maydis the nature of the sterol intermediates accumulating in treated cells was studied. At low growth-inhibiting concentrations of the toxicant (10 and 15 μg/ml) decline of ergosterol content during 6 hr of incubation was accompanied by an accumulation of various sterol intermediates of which ergosta-8,14-dien-3β-ol appeared to be the major sterol. After isolation of this intermediate its identity was further confirmed by direct comparisonof its ultraviolet, glc, and mass spectrum with those of an authentic synthesized sample of ergosta-8,14-dien-3β-ol (ignosterol). Results indicate that toxicity of tridemorph is caused by a specific inhibitive effect on the enzyme Δ¹⁴-reductase which is responsible for $\text{14}\text{15}$ double-bond reduction in sterol biosynthesis.     

Effects of sterol biosynthesis-inhibiting (SBI) fungicides on cytochrome P-450 oxygenations in fungi

The fungicides miconazole, fenarimol, and etaconazole block ergosterol biosynthesis in fungi by inhibiting sterol 14α-demethylation, which is mediated by a cytochrome P-450 enzyme. The sensitivity of cytochrome P-450-dependent hydroxylation or demethylation of several substrates to these fungicides and similar compounds was compared to that of fungal growth and sterol 14α-demethylation. Demethylation of p-chloro-N-methylaniline (PCMA) by sporidia of Ustilago maydis and 11α-hydroxylation of progesterone by Aspergillus nidulans were relatively insensitive to these compounds and to metyrapone. The ability of a sterol 14α-demethylation-deficient mutant to demethylate PCMA indicates that this substrate is not demethylated by the sterol 14α-demethylation system of U. maydis. The 14α-hydroxylation of progesterone by cells of Curvularia lunata was quite sensitive to the three fungicides, and also to metyrapone and isopropylphenylimidazole. This system was less sensitive to the three fungicides than sterol 14α-demethylation, but was appreciably more sensitive than PCMA demethylation. A study of progesterone 14α-hydroxylation in cell-free preparations of C. lunata showed the reaction to be inhibited by CO, and to be competitively inhibited by low concentrations of miconazole. These data suggest that the primary action of sterol biosynthesis-inhibiting (SBI) fungicides is competitive inhibition of sterol/steroid-type cytochrome P-450 enzymes rather than interference with the function of sterol carrier proteins or enzyme-modulating phospholipids.     

Effects of Sterol Biosynthesis Inhibitor Fungicides on Growth and Sterol Composition of Ustilago maydis,Botrytis cinerea and Pyrenophora teres

The effects of the sterol biosynthesis inhibitor (SBI) fungicides fenarimol, fenpropimorph, imazalil, prochloraz, propiconazole and triadimenol on growth and sterol composition of Ustilago maydis, Botrytis cinerea and Pyrenophora teres, grown from spores or sporidia in liquid culture, were determined. Growth of U. maydis was only slightly inhibited by SBI fungicides at concentrations which caused considerable changes in both sterol content and composition. Conversely, in B. cinerea and P. teres, growth was strongly inhibited under conditions where ergosterol was still the predominant sterol, suggesting that, in these two fungi, growth may be more sensitive to SBI fungicides than overall sterol production. Demethylase inhibitor fungicides behaved as a homogeneous group in their effects on growth and on sterol profiles of the three fungi studied.     

Benomyl and methyl-2-benzimidazolecarbamate (MBC): Biochemical,cytological and chemical aspects of toxicity to Ustilago maydis and Saccharomyces cerevesiae

Action of methyl-2-benzimidazolecarbamate (MBC), a breakdown product of benomyl, was studied in synchronous cultures of Ustilago maydis and Saccharomyces cerevesiae. Cells treated with MBC developed similarly to control cells until the two portions of the doublets (joined mother and daughter “cells”) were morphologically equivalent. At this point development of the treated cells ceased but control doublets separated to form two new cells. The compound did not prevent DNA synthesis during the first cell cycle of synchronized S. cerevesiae cells but did prevent completion of cell division, as it did also in synchronized U. maydis sporidia which already contained the DNA complement needed for completion of the first division. Mitosis did not go to completion in MBC-treated cells so the doublets formed contained only a single compact nucleus. The effect of MBC markedly resembles mitotic arrest caused by colchicine and isopropyl N-phenylcarbamate in higher plants and griseofulvin in the fungus Aspergillus nidulans. Inhibition of DNA synthesis in U. maydis and inhibition of cytokinesis in both organisms studied are secondary effects attributable to mitotic failure.A volatile compound toxic to U. maydis and S. cerevesiae was demonstrated in air over moistened benomyl. Hexane, through which such air samples were passed, or hexane extracts of aqueous suspensions of benomyl contained a substance having the same ir spectrum and retention time in two gas chromatographic systems as butyl isocyanate (BIC).BIC inhibited respiration of U. maydis and S. cerevesiae in a manner similar to benomyl. Benomyl partially inhibited respiration of subcellular particles from both organisms. MBC had essentially no effect on whole cell or subcellular particle respiration of either organism. Toxicity of benomyl preparations is not attributed to “benomyl” as such, but to two breakdown products, MBC and BIC. Therefore, differential effects of benomyl preparations and of MBC on growth and metabolism in fungi should be ascribed to BIC.     

Resistance to fungicides which inhibit ergosterol biosynthesis in laboratory strains of Botrytis cinerea and Ustilago maydis

The strains of Botrytis cinerea or Ustilago maydis selected on fenarimol, triarimol, or triadimefon were also resistant to the other inhibitors of sterol C-14 demethylation; the sterol composition of the strains was normal. Among the isolates of U. maydis resistant to dodemorph, fenpropidin, fenpropimorph and tridemorph, some were resistant to the 15-azasteroid A 25822B and did not contain ergosterol. The other strains remained sensitive to A 25822B and had a normal sterol composition. All the resistant isolates and the wild-type were inhibited to the same extent by nystatin and pimaricin.     

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.     

Inhibition of ergosterol biosynthesis in Ustilago maydis by the fungicide 1-[2-(2, 4-dichlorophenyl)-4-ethyl-1, 3-dioxolan-2-ylmethyl]-1H-1, 2, 4-triazole

Inhibition of sporidial multiplication in cultures of Ustilago maydis by 1-[2-(2, 4-dichlorophenyl)-4-ethyl-1, 3-dioxolan-2-ylmethyl]-1H-1, 2, 4-triazole^a (CGA-64251), at concentrations of 0.1, 1.0 and 5.0 μg ml^?1, increased from about 15% during the first 4 h, to 58–70% during the subsequent 4 to 12-h period. Sporidia became swollen and highly branched in the presence of the fungicide. Total lipid content as a percentage of the dry weight was not affected after exposure of the sporidia to the fungicide at 0.1 or 5 μg ml^?1 for 4 h, but synthesis of ergosterol and other demethyl-sterols was inhibited by 87–92%. Large quantities of methyl-sterol precursors of ergosterol and of free fatty acids accumulated in the treated sporidia. Fungitoxicity of CGA-64251 is attributed to inhibition of ergosterol biosynthesis at the stage of sterol C-14 demethylation.     

Action of the fungicide tridemorph on the glucose,lactate and succinate dehydrogenase activities of some tridemorph-sensitive and -resistant bacteria

The systemic morpholine fungicide tridemorph, which is known to exert its antifungal action through inhibition of ergosterol biosynthesis, can also inhibit the growth of organisms which are incapable of sterol biosynthesis. It was found to inhibit strongly glucose and lactate dehydrogenase activities in cultures of four Gram( +) bacteria, Rhodococcus sp. AK 1, Bacillus cereus Frankland & Frankland, Bacillus subtilis (Ehrenberg) Cohn, Nocardia asteroides and a Gram(?) bacterium, Rhizobium leguminosarum. Growth of these bacteria was inhibited by tridemorph at concentrations between 7 and 60 mg litre^?1. In contrast, similar dehydrogenase activities in other Gram(?) organisms, Escherichia coli Cast. & Chalm. and Azotobacter vinelandii, which showed no growth inhibition at 200 mg litre ^?1 tridemorph, were either not inhibited or inhibited only slightly. Similarly, succinate dehydrogenase activity in Rhodococcus sp. AK 1 was more strongly inhibited by tridemorph than that in E. coli. In cell-free extracts of Rhodococcus sp. AK1 and E. coli, lactate dehydrogenase activity was also inhibited by tridemorph to a much greater extent in the sensitive strain (63%) than in the resistant ones (8%).     

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.     

Sensitivity of Ustilago maydis to pyrazophos and one of its conversion products,and failure to induce resistance with UV-treatment

2-Hydroxy-5-methyl-6-ethoxycarbonylpyrazolo(1,5-a)pyrimidine (PP), a conversion product of pyrazophos, shows considerable toxicity toUstilago maydis, when administered to this fungus in a solution at pH<5. Evidence was obtained thatU. maydis may convert pyrazophos in to PP, and that the latter compound is the toxic principle responsible for the action of pyrazophos. By UV-irradiation of sporidia no PP-resistant mutants were obtained. This does not support the hypothesis that this toxicant acts by specific inhibition of one enzyme system.     

Uptake by roots and translocation to shoots of two morpholine fungicides in barley

Despite being lipophilic, morpholine fungicides are systemic in plants. Such transport may be explicable by their protonation (pKa∽7·5) at the pH of plant compartments to yield the more polar cation. This behaviour might be a useful attribute to be incorporated into other classes of lipophilic pesticides. To understand quantitatively the behaviour of the morpholine fungicides, the uptake by roots and transport to shoots in barley of two such ¹⁴C-labelled compounds, dodemorph and tridemorph, were investigated using bathing solutions of differing pH. At pH 5, uptake and transport were small, but increased by approximately two orders of magnitude at pH 8. Tridemorph, the more lipophilic of the two compounds, was highly accumulated by roots at pH 8 and moderately translocated to shoots. In contrast, dodemorph was translocated to shoots at pH 8 with remarkable efficiency, moving into the xylem across the endodermis at 23 times the efficiency of water, though accumulation in roots was less than that of tridemorph. Behaviour at 24 h was largely similar to that at 48 h for both compounds, indicating that uptake and translocation are equilibrium processes maintained over time. Transport to shoots for each compound was directly proportional to the concentrations accumulated in the roots, except at low pH where partitioning into root solids became proportionately more important with such material not being directly available for transport to the xylem across the endodermis. Uptake and transport of these basic fungicides are explained in terms of their partitioning and of their accumulation in acidic plant compartments by ion trapping as the protonated form; this behaviour is discussed in relation to the pKa and lipophilicity of these compounds. © 1998 Society of Chemical Industry     

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     

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.     

Distribution of tridemorph and its metabolites in barley plants grown to maturity

The distribution of tridemorph residues in previously treated mature barley plants has been determined using a specific g.l.c. method. Tridemorph residues were found in grain, awns, leaves, rachis and stems, the amount of residue in the grain appearing to be variety-specific.     

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.     

Genetic control of resistance to tridemorph inustilago maydis

Mutants ofUstilago maydis with low resistance to tridemorph isolated in a mutation frequency of 7x 10^-6 after UV-irradiation and selection on media containing 25 μg ml^-1 tridemorph. Genetic analysis with nine such mutant isolates resulted in the identification of two unlinked chromosomal loci,U/tdm- 1 andU/tdm- 2. TheU/tdm mutations are responsible for low resistance levels to tridemorph (resistance factor, Rf, of 3 or 5 based on effective concentration causing a 50% reduction in the growth rate (EC₅₀) or minimal inhibitory concentration (MIC) values, respectively) and low to moderate level of resistance to fenpropimorph (Rf 10 or 16 based on MIC or EC₅₀, respectively) and fenpropidin (Rf 5 or 11 based on MIC or EC₅₀, respectively). Haploid strains carrying bothU/tdm mutations exhibit higher levels of resistance to the above fungicides, indicating interallelic interaction between nonallelic genes. Crosses between mutants carrying theU/tdm- genes with compatible isolates carrying theU/fpm- 1 orU/fpm- 2 mutations, which were found in previous work to carry fenpropimorph resistance, yielded in all cases a large number of recombinants with wild-type sensitivity, indicating that the mutant genes involved were not allelic. Cross-resistance studies with the inhibitors of C-14 demethylase showed that. the U/tdm-mutations were responsible for increased sensitivity to the triazoles triadimefon, triadimenol, propiconazole and flusilazole, and to the pyridine pyrifenox. Study of gene effect on the fitness ofU. maydis showed thatU/tdm-mutations appeared to be pleiotropic, having more or less adverse effects on growth rate in liquid culture and pathogenicity on young corn plants.