Characterization of fludioxonil-resistant and pyrimethanil-resistant phenotypes of Penicillium expansum from apple

Penicillium expansum is the primary cause of blue mold, a major postharvest disease of apple. Fludioxonil and pyrimethanil are two newly registered postharvest fungicides for pome fruit in the United States. To evaluate the potential risk of resistance development in P. expansum to the new postharvest fungicides, one isolate of each of thiabendazole-resistant (TBZ-R) and -sensitive (TBZ-S) P. expansum was exposed to UV radiation to generate fungicide-resistant mutants. Four fludioxonil highly-resistant mutants (EC(50) > 1,000 microg/ml) and four pyrimethanil-resistant mutants (EC(50) > 10 microg/ml) were tested for sensitivities to thiabendazole, fludioxonil, and pyrimethanil, and fitness parameters including mycelial growth, sporulation on potato dextrose agar (PDA), sensitivity to osmotic stress, and pathogenicity and sporulation on apple fruit. The stability of resistance of the mutants was tested on PDA and apple fruit. Efficacy of the three fungicides to control blue mold incited by the mutants was evaluated on apple fruit. Six fungicide-resistant phenotypes were identified among the parental wild-type isolates and their mutants based upon their resistance levels. All four fludioxonil highly-resistant mutants were sensitive to pyrimethanil and retained the same phenotypes of resistance to TBZ as the parental isolates. All four pyrimethanil-resistant mutants had a low level of resistance to fludioxonil with a resistance factor >15. The two pyrimethanil-resistant mutants derived from a TBZ-S isolate became resistant to TBZ at 5 microg/ml. After 20 successive generations on PDA and four generations on apple fruit, the mutants retained the same phenotypes as the original generations. All mutants were pathogenic on apple fruit at both 0 and 20 degrees C, but fludioxonil highly-resistant mutants were less virulent and produced fewer conidia on apple fruit than pyrimethanil-resistant mutants and their parental wild-type isolates. Compared with the parental isolates, all four fludioxonil highly-resistant mutants had an increased sensitivity to osmotic stress on PDA amended with NaCl, while the pyrimethanil-resistant mutants did not. Pyrimethanil was effective against blue mold caused by fludioxonil-resistant mutants at both 0 and 20 degrees C. Pyrimethanil and fludioxonil reduced blue mold incited by pyrimethanil-resistant mutants during 12-week storage at 0 degrees C but were not effective at 20 degrees C. TBZ was not effective against pyrimethanil-resistant mutants derived from TBZ-S wild-type isolates at room temperature but provided some control at 0 degrees C. The results indicate that: (i) a fitness cost was associated with fludioxonil highly resistant mutants of P. expansum in both saprophytic and pathogenic phases of the pathogen but not pyrimethanil-resistant mutants; (ii) pyrimethanil possessed a higher risk than fludioxonil in the development of resistance in P. expansum; and (iii) triple resistance to the three apple-postharvest fungicides could emerge and become a practical problem if resistance to pyrimethanil develops in P. expansum populations.     

Molecular characterization and a multiplex allele-specific PCR method for detection of thiabendazole resistance in Penicillium expansum from apple

Thiabendazole (TBZ) is commonly used as a postharvest treatment for control of blue mold in apples caused by Penicillium expansum. Different point mutations in the β-tubulin gene conferring benzimidazole resistance have been reported in plant pathogens, but molecular mechanisms of TBZ resistance in P. expansum from apple in Washington State are unknown. Determination of TBZ resistance level showed that all 102 TBZ-resistant (TBZ-R) isolates were highly resistant. Sequencing of the majority of the β-tubulin gene showed that 76 TBZ-R isolates harboured the E198V mutation and 26 harboured the F167Y mutation, and all the sensitive isolates did not possess any of the mutations, indicating that these two point mutations in the β-tubulin gene were correlated with TBZ resistance in P. expansum from apple in Washington State. There was no association between levels of TBZ resistance and types of point mutations (E198V or F167Y) in the β-tubulin gene. A multiplex allele-specific PCR assay was developed to detect these two mutations simultaneously. Microsatellite-primed PCR derived presence-absence matrix used to assess the genetic relationship among 56 isolates suggested that the resistance mutations originated several times independently and that there was no correlation between the types of point mutation and the genetic background of the isolates.     

Stability and fitness of pyraclostrobin- and boscalid-resistant phenotypes in field isolates of Botrytis cinerea from apple

Phenotype stability, fitness, and competitive ability of pyraclostrobin- and boscalid-resistant isolates of Botrytis cinerea from apple were investigated. Stability of resistance was determined after consecutive transfers on potato dextrose agar (PDA) or being cycled on apple fruit. In vitro fitness components mycelial growth, osmotic sensitivity, conidial germination, and sporulation were evaluated on agar media. Pathogenicity, virulence and sporulation on apple fruit were evaluated at both 20 and 0°C. Competition between fungicide-resistant and -sensitive isolates on apple fruit also was evaluated. Resistance to the two fungicides was retained at levels similar to that of the initial generation after 20 and 10 transfers on PDA and five and three disease cycles on apple fruit at 20 and 0°C, respectively. Great variability in individual fitness components tested was observed among isolates within the same phenotype groups either sensitive or resistant to the fungicides but, when compared as phenotype groups, there were no significant differences in the mean values of these fitness components between resistant and sensitive phenotypes except that the phenotype resistant only to boscalid produced fewer conidia in vitro than sensitive isolates. Resistant isolates were as pathogenic and virulent on apple fruit as sensitive isolates. There was no significant correlation between the values of individual fitness components tested and the level of resistance to pyraclostrobin or boscalid, except that virulence at 20°C positively correlated with the level of resistance to the two fungicides. The final frequency of pyraclostrobin-resistant individuals in the populations was significantly decreased compared with the initial generation and no boscalid-resistant individuals were detected after four disease cycles on apple fruit inoculated with a pair mixture of a dual-sensitive isolate and one isolate each of the three phenotypes resistant to pyraclostrobin, boscalid, or both. The results suggest that resistance of B. cinerea to pyraclostrobin and boscalid was stable in the absence of the fungicides and that resistance to the two fungicides did not significantly impair individual fitness components tested. However, both pyraclostrobin- and boscalid-resistant isolates exhibited competitive disadvantage over the dual-sensitive isolate on apple fruit.     

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.

     

Resistance to thiabendazole in isolates of Polyscytalum pustulans (skin spot) and Fusarium solani var. coeruleum (dry rot) in Scotland

Between 1988 and 1991, isolates of Polyscytalum pustulans were obtained from potato tubers grown in Scotland and tested for sensitivity to thiabendazole (TBZ) on agar. Sensitive isolates did not grow at 1 mg TBZ/1, whereas growth of resistant isolates was unaffected at 1 mg and reduced by 10–30% at 10 mg/1. Resistant isolates were present on all classes of seed potatoes, and were also recovered from the air of stores during grading. Isolates from a stock of seed tubers from Northern Ireland were resistant. All 44 isolates of Fusarium solani var. coeruleum collected in 1991 were sensitive to TBZ.     

Stability and fitness of anilinopyrimidine-resistant strains of Botrytis cinerea

The fitness of anilinopyrimidine-resistant isolates of Botrytis cinerea compared with that of sensitive isolates, collected from vegetable crops in Greece during 2005, was investigated. Stability of resistance to anilinopyrimidine fungicides was determined after consecutive transfers of the fungal isolates on fungicide-free potato dextrose agar for 16 culture cycles or on fungicide-untreated cucumber seedlings for eight disease cycles. Results showed that after the consecutive transfers of the isolates either in vitro or in vivo sensitivity to cyprodinil was not changed significantly compared to the initial sensitivity in all the isolates tested, suggesting a stable genetically controlled trait. Fitness parameters measured were mycelial growth, spore production in vitro, osmotic sensitivity, virulence, spore production in vivo, percentage of spore germination, and competitive ability of the resistant isolates in four pairs with sensitive isolates both on artificial nutrient medium or on cucumber seedling plants. The measurements of the fitness components in individual isolates showed high variability within both sensitivity groups in all, except virulence, fitness components tested. As a group, resistant isolates showed significantly lower (P < 0.05) mycelial growth and virulence, while they were more osmotically sensitive than the sensitive isolates. In addition the resistant isolates showed higher (P < 0.05) spore production in vivo but there was no difference (P > 0.05) between the two sensitivity groups in spore production in vitro and in the percentage of spore germination. However, the correlation to test if there is any relationship between the values of each fitness component tested and the level of cyprodinil sensitivity of each isolate was for all, except the spore production in vivo, fitness components not significant (P > 0.05). This absence of significant correlation coefficient values suggests that the development of resistance to anilinopyrimidine fungicides did not affect the fitness of the resistant isolates. Competition of the resistant versus sensitive isolates was isolates-dependent, since in two of the isolate pairs the resistance frequency decreased significantly after five culture or disease cycles, while in the remaining two pairs resistance frequency increased significantly after five disease cycles or remained stable for one pair after five culture cycles on artificial nutrient media.     

灰葡萄孢多药抗性菌株的筛选和鉴定

从浙江杭州市售草莓上分离得到83个灰葡萄孢菌株,测定了这些菌株对苯醚菌酯、多菌灵和异菌脲的敏感性,筛选出对这3种药剂同时产生了抗性的两个菌株HZ021和HZ054,其在马铃薯葡萄糖琼脂(PDA)平板上的菌丝生长和产孢量与敏感菌株相比无显著差异,在黄瓜叶片上均表现出很强的致病力。结果表明,HZ021和HZ 054有很高的适合度。通过对抗性菌株中细胞色素b (CYT b)、双组份组氨酸激酶(OS-1)和β-微管蛋白(TUB 2)基因序列进行分析发现,HZ021和HZ054对多种药剂的抗性是由于其药剂靶标基因上的点突变所致。     

Adaptation to fungicides in Monilinia fructicola isolates with different fungicide resistance phenotypes

The ability to develop fungicide resistance was assessed in Monilinia fructicola isolates with different fungicide sensitivity phenotypes by adapting mycelium and conidia to increasing concentrations of selective fungicides and UV mutagenesis. Results showed that adaptation to Quinone outside inhibitor (QoI) fungicide azoxystrobin and sterol demethylation inhibitor (DMI) fungicide propiconazole was more effective in conidial-transfer experiments compared to mycelial-transfer experiments. DMI-resistant (DMI-R) isolates adapted to significantly higher doses of azoxystrobin in both, mycelial- and conidial-transfer experiments compared to benzimidazole-resistant (BZI-R) and sensitive (S) isolates. Adaptation to propiconazole in conidial-transfer experiments was accelerated in BZI-R isolates when a stable, nonlethal dose of 50 microg/ml thiophanate-methyl was added to the selection medium. One of two azoxystrobin-resistant mutants from DMI-R isolates did not show any fitness penalties; the other isolate expired before further tests could be carried out. The viable mutant caused larger lesions on detached peach fruit sprayed with azoxystrobin compared to the parental isolate. The azoxystrobin sensitivity of the viable mutant returned to baseline levels after the mutant was transferred to unamended medium. However, azoxystrobin resistance recovered quicker in the mutant compared to the corresponding parental isolate after renewed subculturing on medium amended with 0.2 and 1 microg/ml azoxystrobin; only the mutant but not the parental isolate was able to adapt to 5 microg/ml azoxystrobin. In UV mutagenesis experiments, the DMI-R isolates produced significantly more mutants compared to S isolates. All of the UV-induced mutants showed stable fungicide resistance with little fitness penalty. This study indicates the potential for QoI fungicide resistance development in M. fructicola in the absence of a mutagen and provides evidence for increased mutability and predisposition to accelerated adaptation to azoxystrobin in M. fructicola isolates resistant to DMI fungicides.     

Identification of a novel point mutation in the <Emphasis Type="Italic">β</Emphasis>-tubulin gene of <Emphasis Type="Italic">Botrytis cinerea</Emphasis> and detection of benzimidazole resistance by a diagnostic PCR-RFLP assay

The molecular basis of resistance to benzimidazole fungicides with laboratory and field mutant isolates of Botrytis cinerea was investigated. After chemical mutagenesis with N-methyl-N-nitrosogouanidine (NMNG) two different benzimidazole-resistant phenotypes were isolated on media containing carbendazim or a mixture of carbendazim and diethofencarb. The mutant isolates from the fungicide-mixture-containing medium were moderately resistant to carbendazim with wild-type tolerance to diethofencarb while mutant isolates from carbendazim-containing medium were highly resistant to carbendazim but sensitive to diethofencarb. The studied field isolates were highly resistant to benzimidazoles and sensitive to diethofencarb. Study of fitness characteristics of benzimidazole highly-resistant isolates showed that the resistance mutation(s) had no apparent effect on fitness-determining parameters. Contrary to this, the moderately benzimidazole-resistant strains, with no increased diethofencarb sensitivity, had a significant reduction in certain ecological fitness-determining characteristics. Analysis of the sequence of the β-tubulin gene revealed two amino acid replacements in the highly benzimidazole-resistant mutants compared to that of the wild-type parent strain. One was the glutamic acid (GAG) to alanine (GCG) change at position 198 (E198A), identified in both laboratory and field highly benzimidazole-resistant isolates, a mutation previously implicated in benzimidazole resistance. The second was a novel benzimidazole resistance mutation of glutamic acid (GAG) to glycine (GGG) substitution at the same position 198 (E198G), identified in a highly benzimidazole-resistant laboratory mutant strain. Molecular analysis of the moderately benzimidazole-resistant strains revealed no mutations at the β-tubulin gene. A novel diagnostic PCR-RFLP assay utilising a BsaI restriction site present in the benzimidazole-sensitive (E198) but absent in both resistant genotypes (E198G and E198A) was developed for the detection of both amino acid replacements at the β-tubulin gene.     

Effect of Phenylpyrrole-resistance Mutations on Ecological Fitness of <Emphasis Type="Italic">Botrytis cinerea</Emphasis> and their Genetical Basis in <Emphasis Type="Italic">Ustilago maydis</Emphasis>

Mutants of Botrytis cinerea and Ustilago maydis highly resistant to fludioxonil were isolated at a high frequency, after nitrosoguanidine or UV mutagenesis, respectively, and selection on media containing fludioxonil. Tests on the response of mutant strains to high osmotic pressure resulted in the identification of two fludioxonil-resistant phenotypes (FLD_osm/s and FLD_osm/r), regarding the sensitivity to high osmolarity. Approximately 95% of fludioxonil-resistant mutants were found to be more sensitive to high osmotic pressure than the wild-type parent strains. Genetic analysis of phenylpyrrole-resistance in the phytopathogenic basidiomycete U. maydis, showed that fludioxonil-resistance was coded by three unlinked chromosomal loci (U/fld-1, U/fld-2 and U/fld-3), from which only the U/fld-1 mutation coded an osmotic sensitivity similar to that of the wild-types. Cross-resistance studies with fungicides from other chemical groups showed that the mutations for resistance to phenylpyrroles affect the sensitivity of mutant strains to the aromatic hydrocarbon and dicarboximide fungicides, but not to the benzimidazoles, anilinopyrimidines, phenylpyridinamines, hydroxyanilides or the sterol biosynthesis inhibiting fungicides. A study of fitness parameters in the wild-type and fludioxonil-resistant mutants of B. cinerea, showed that all osmotic sensitive (B/FLD_osm/s) isolates had significant reductions in the characteristics determining saprophytic fitness such as mycelial growth, sporulation, conidial germination and sclerotial production. Contrary to that, with the exception of mycelial growth, the fitness parameters were unaffected or only slightly affected in most of the osmotic resistant (B/FLD_osm/r) isolates. Tests on cucumber seedlings showed that the osmotic-sensitive strains were significantly less pathogenic compared with the wild-type and B/FLD_osm/r strains of B. cinerea. Preventative applications of the commercial products Saphire 50 WP (fludioxonil) and Rovral 50 WP (iprodione) were effective against lesion development on cotyledons by the wild-type and the mutant strains of B. cinerea that were resistant to the anilinopyrimidine cyprodinil (B/CPL-27) and to the hydroxyanilide fenhexamid (B/FNH-21), but ineffective, even at high concentrations, against disease caused by the fludioxonil-resistant isolates (B/FLD) and a mutant strain resistant to the dicarboximide iprodione (B/IPR-1). Experiments on the stability of the fludioxonil-resistant phenotype showed a reduction of resistance, mainly in osmotic-sensitive isolates, when the mutants were grown on inhibitor-free medium. A rapid recovery of the high resistance was observed after mutants were returned to the selection medium. Studies on the competitive ability of mutant isolates against the wild-type parent strain of B. cinerea, by applications of a mixed conidial population, showed that, in vitro, all mutants were less competitive than the wild-type strain. However, the competitive ability of osmotic-resistant mutants was higher than the osmotic-sensitive ones. Furthermore, competition tests, in planta, showed a significant reduction of the frequency of both phenylpyrrole-resistant phenotypes, with a respective increase in the population of the wild-type strain of the pathogen.     

Characterization and fitness of carbendazim-resistant strains of Fusarium graminearum (wheat scab)

BACKGROUND: Carbendazim (MBC) has failed to control wheat scab, caused by Fusarium graminearum Schwabe, on the eastern coast of China in recent years after about 30 years of application. RESULTS: MBC resistance was found to be common in pathogen populations on the eastern coast and along areas of the Yangtze River. EC(50) and minimum inhibitive concentration (MIC) values of MBC inhibiting mycelium growth of wild-type isolates were less than 0.9 and 1.4 microg mL(-1) respectively, while EC(50) values of resistant collections averaged 7.02 +/- 11.86 microg mL(-1). The slope of the MBC dosage-response curve (DRC) for resistant isolates of F. graminearum was flat: 1 < b < 2.8 for resistant isolates and 3.5 < b < 11 for sensitive isolates). Both field resistant and sensitive MBC strains shared similar temperature sensitivity, fitness and virulence on ears. Field resistant strains and UV-induced mutants showed positive cross-resistance to other benzimidazole derivatives and were mainly at intermediate MBC resistance level. Highly resistant field MBC strains rarely appeared, but only some of the highly resistant MBC UV mutants were insensitive to N-phenylaminecarbamates. No mutation in beta-tubulin was found in F. graminearum, in contrast to mutation in this tubulin which has led to MBC resistance in other plant pathogens. CONCLUSION: MBC(R) isolates have high fitness and competition in field, conferred by a novel molecular mechanism.     

Molecular characterization of benzimidazole-resistant B. cinerea field isolates with reduced or enhanced sensitivity to zoxamide and diethofencarb

Sensitivity profiles of Botrytis cinerea field isolates to zoxamide and the molecular basis of the resistance mechanism involved in cross-resistance relationships between benzamides, benzimidazoles and N-phenylcarbamates were investigated. B. cinerea isolates collected from southern, central and northern Greece were characterized based on their sensitivity to zoxamide, the benzimidazole carbendazim and the N-phenylcarbamate diethofencarb. Isolates exhibiting baseline sensitivity to carbendazim and zoxamide but no sensitivity to diethofencarb were considered wild type (S phenotype) and accounted for 44% of the total strains sampled. Thirty-three percent of the isolates had increased sensitivity (HS phenotype) to zoxamide and diethofencarb and were highly resistant to carbendazim compared to S isolates. Eight percent of the sample was highly resistant (HR phenotype) to all anti-tubulin agents studied. The rest of the isolates were moderately resistant to zoxamide (MR phenotype) and equally sensitive to benzimidazoles and N-phenylcarbamates compared to isolates of the S phenotype. Fungitoxicity tests with botrycides belonging to other chemical classes revealed no cross-resistance relationships between zoxamide and the phenylpyrrole fludioxonil, the dicarboximide iprodione, the hydroxyanilide fenhexamid, the anilinopyrimidine cyprodinil, the carboxamide boscalid and the strobilurin-type fungicide pyraclostrobin. Study of fitness characteristics did not show any significant difference between zoxamide resistant and sensitive isolates with respect to the parameters tested. PCR-RFLP analysis of a part of the β-tubulin gene sequence detected mutations in position 198 for both HS and HR zoxamide-sensitivity phenotypes. DNA sequence analysis of the B. cinerea β-tubulin gene revealed two previously described benzimidazole-resistance-conferring mutations. The first one was the glutamic acid (GAG) to alanine (GCG) change at position 198 (E198A), which was identified in all HS isolates. The second mutation (E198K) was a GAG-to-AAG substitution resulting in the replacement of glutamic acid with lysine present in all B. cinerea isolates highly resistant to all three anti-tubulin classes of fungicides. A number of mutations in other positions of the β-tubulin gene were detected in the moderately zoxamide-resistance phenotype.     

Resistance mechanisms and associated mutations in acetylcholinesterase genes in Sitobion avenae (Fabricius)

Wheat aphid, Sitobion avenae (fabricius), is one of the most important wheat pests and has been reported to be resistant to commonly used insecticides in China. To determine the resistance mechanism, the resistant and susceptible strains were developed in laboratory and comparably studied. A bioassay revealed that the resistant strain showed high resistance to pirimicarb (RR: 161.8), moderate reistance to omethoate (32.5) and monocrotophos (33.5), and low resistance to deltamethrin (6.3) and thiodicarb (5.5). A biochemistry analysis showed that both strains had similar glutathione-S-transferase (GST) activity, but the resistant strain had 3.8-fold higher esterase activity, and its AChE was insensitive to this treatment. The I₅₀ increased by 25.8-, 10.7-, and 10.4-folds for pirimicarb, omethoate, and monocrotophos, respectively, demonstrating that GST had not been involved in the resistance of S. avenae. The enhanced esterase contributed to low level resistance to all the insecticides tested, whereas higher resistance to pirimicarb, omethoate, and monocrotophos mainly depended on AChE insensitivity. However, the AChE of the resistant strain was still sensitive to thiodicarb (1.7-fold). Thus, thiodicarb could be used as substitute for control of the resistant S. avenae in this case. Furthermore, the two different AChE genes cloned from different resistant and susceptible individuals were also compared. Two mutations, L436(336)S in Sa.Ace1 and W516(435)R in Sa.Ace2, were found consistently associated with the insensitivity of AChE. They were thought to be the possible resistance mutations, but further work is needed to confirm this hypothesis.     

Biological and molecular characterization of laboratory mutants of Cercospora beticola resistant to Qo inhibitors

The resistance to strobilurin-related fungicides and its molecular basis in laboratory mutant isolates of Cercospora beticola was investigated. After ultraviolet mutagenesis, mutants with high, moderate or low resistance levels to pyraclostrobin were isolated from a wild-type strain of C. beticola. Fungitoxicity tests on the response of resistant isolates on medium containing pyraclostrobin and salicylhydroxamate (SHAM), a specific inhibitor of cyanide-resistant (alternative) respiration, indicated that the biochemical mechanism of alternative oxidase was not responsible for the reduced sensitivity to pyraclostrobin for half of the mutants. Cross-resistance studies with other inhibitors of the cytochrome bc ₁ complex of the mitochondrial respiratory chain showed that the mutation(s) for resistance to pyraclostrobin also reduced the sensitivity of mutant strains to other Qo inhibitors such as azoxystrobin and fenamidone, but not to the Qi inhibitor cyazofamid. No effect of pyraclostrobin-resistant mutation(s) on fungitoxicity of the carboxamide boscalid, the triazoles epoxiconazole and flutriafol and to the benzimidazole benomyl, which affect other cellular pathways or other steps of the respiratory chain, was observed. Study of fitness parameters showed that most mutants had a significant reduction in sporulation and pathogenicity compared to the wild-type parental isolate. However, experiments on the stability of the resistant phenotype did not show a significant reduction of the resistance for half of the mutants when grown for at least four generations on pyraclostrobin-free medium. Molecular analysis of cytochrome b cDNA, isolated from the wild-type and the pyraclostrobin-resistant mutant isolates, revealed two novel amino acid replacements at positions involved in Qo resistance in other species. The glycine (GGT) to serine (AGT) replacement at position 143 (G143S) was found in the isolate with the highly resistant phenotype. The second amino acid change was the replacement of phenylalanine (TTC) by valine (GTC) at position 129 (F129V), which was found in a mutant strain with the moderately resistant phenotype. Four additional mutations located in conserved regions of the mitochondrial cytochrome b gene (I154L, N250D, E256G and V261D) were detected in some mutant isolates of C. beticola but their possible role in Qo-resistance needs further investigation. This is the first study reporting C. beticola strains resistant to Qo inhibitor fungicides due to the biochemical mechanism of target-site modification, resulting from amino acid changes in the mitochondrial cytochrome b␣gene.     

烟草黑胫病菌抗甲霜灵突变体的诱导及其适合度研究

室内离体条件下采用药剂诱导法,获得了11个烟草黑胫病菌抗甲霜灵突变体;检测了所有抗药突变体的抗药稳定性及抗性水平;比较了3个低抗和1个高抗突变体的适合度。结果表明:在2~20 μg/mL范围内,抗药突变体的发生频率随甲霜灵诱导浓度的增加而提高;所有抗药突变体的抗药性都能稳定遗传;11个抗药突变体中,10个为低抗突变体(抗性水平3.55~13.9倍,平均8.60倍),1个为高抗突变体(抗性水平510倍);低抗菌株20M-001、10M-003、10M-006和高抗菌株10M-004的适合度指数分别为0.56、0.38、0.38和0.87;抗药突变体的适合度指数与抗性水平不相关。     

Further studies of the inheritance of benomyl resistance in Venturia pirina isolated from pear orchards in Israel

Fourteen single-spore cultures of benomyl-resistant Venturia pirina were isolated from pear scab lesions at four sites in Israel. According to the ability of the isolates to germinate and grow at varying benomyl concentrations, four levels of resistance were determined in vitro : three isolates with low resistance (LR) grew at 0.5 but not at 5 μg/ml benomyl: five moderately resistant (MR) isolates grew at 5 but not at 50 μg/ml benomyl: five highly resistant (HR) isolates grew at 50 μg/ml but their hyphae were curled: and one isolate with very high resistance (VHR) grew unaffected at 50 μg/ml benomyl. The difference between the HR and the VHR phenotypes was clearly shown on medium amended with N -(3.5-dichlorophenyl) carbamate (MDPC): only the VHR isolate showed negative cross-resistance to 1 μ g/ml MDPC. whereas HR isolates grew unaffected. Crosses between resistant isolates and sensitive wild types, as well as between different resistant isolates, showed that the various levels of resistance are conferred by four allelic mutations that constitute a polymorphic series at a single locus.     

A High Multi-drug Resistance to Chemically Unrelated Oomycete Fungicides in Phytophthora infestans

Mutants of Phytophthora infestans with high resistance to the amidocarbamates iprovalicarb and benthiavalicarb and to the cyanoimidazole cyazofamid were isolated after UV-mutagenesis and selection on media containing one of the above fungicides. In vitro fungitoxicity tests showed that all resistant strains presented a highly reduced sensitivity to both cyazofamid and to the amidocarbamates. Cross-resistance studies with other oomycete fungicides from different chemical groups showed that the mutation(s) for resistance to iprovalicarb (IPV), benthiavalicarb (BVC) and cyazofamid (CZF) also greatly reduced the sensitivity of mutant strains to the phenylamide metalaxyl, acetamide cymoxanil, morpholine dimethomorph, benzamide zoxamide and to chlorothalonil. A lower reduction of sensitivity of mutant strains to the strobilurins azoxystrobin, kresoxim-methyl, pyraclostrobin and trifloxystrobin, azolones famoxadone and fenamidone and to antimycin A was observed. A resistance correlation was not apparent for the dithiocarbamate propineb and phenylpyridinamine fluazinam. Studies of fitness parameters in the wild-type and mutant strains of P. infestans showed that most resistant isolates had significantly reduced sporulation and sporangial germination, but not in the differentiation of sporangia into zoospores. Pathogenicity tests on tomato seedlings showed that most resistant isolates were significantly less pathogenic compared to the wild-type parent strain. However, experiments on the stability of the resistant phenotypes did not show a reduction in resistance when the mutants were grown for more than eleven generations on inhibitor-free medium. This is believed to be the first report of high level multi-drug resistance in fungal pathogens to chemically unrelated fungicides inhibiting different sites of cellular pathway.     

Effect of null mutations in the AbNIK1 gene on saprophytic and parasitic fitness of Alternaria brassicicola isolates highly resistant to dicarboximide fungicides

Alternaria brassicicola field isolates highly resistant to dicarboximide fungicides (DCF) and carrying non‐sense codons or micro‐deletions in the AbNIK1 gene encoding a group III histidine kinase were characterized at the protein level using specific antibodies. These isolates, as well as laboratory mutants expressing the same resistant phenotype, were shown to correspond to null mutants. The fitness of these isolates was compared to that of wild‐type isolates by measuring i) mycelial growth, ii) sporulation and iii) conidial germination under standard conditions. None of these factors were affected in the resistant isolates. Mycelial growth was also measured under stress conditions. Unlike suboptimal incubation temperatures or exposure to the superoxide ion generator menadione, osmotic stress generated by high sorbitol concentrations in the culture medium significantly affected the growth of AbNIK1‐null mutants compared to wild‐types. The effects of these mutations on parasitic fitness were estimated under both controlled and field conditions after inoculation of radish with individual isolates, to measure their aggressiveness, or with mixed conidial suspensions, to measure their competitive ability against wild‐type isolates. These tests on radish seedlings revealed that DCF‐resistant isolates were still aggressive. Despite this, the data obtained in the competition experiments showed that the loss of the ability to synthesize AbNIK1p in A. brassicicola DCF‐resistant mutants was linked to a severe decrease in their competitiveness.     

对噻枯唑具有抗性的水稻白叶枯病菌菌株的性质

对田间和室内分别筛选的抗噻枯唑的水稻白叶枯病菌菌株性质研究发现:室内筛选的抗药菌株在水稻上失去致病性,而田间抗药菌株在离体下则不表现抗药性;抗噻枯唑的菌株对敌枯唑表现交互抗性,对叶枯净不表现交互抗性;抗性菌株与敏感菌株混合接种于无药水稻上发现,抗性菌株的竞争力稍低于敏感菌株;供试的抗性菌株在无药平板上转移6代后,抗性仍很稳定,但在无药的水稻上反复接种、分离4代后,抗性水平有所下降。