Introduction

Botrytis cinerea (teleomorph Botryotinia fuckeliana) is a common airborne plant pathogen that causes serious pre- and post-harvest losses on at least 200 crops worldwide1. During the last 30 years, gray mold control in China has mainly depended on the application of systemic fungicides with single-site modes of action. These systemic fungicides (which include the benzimidazole fungicide carbendazim, the quinone outside inhibitor azoxystrobin and the sterol biosynthesis inhibitors tebuconazole and prochloraz) are often mixed with the protective fungicides thiram, chlorothalonil, procymidone and pyrimethanil2,3,4,5. Because of the high genetic variability of B. cinerea, its abundant sporulation and polycyclic nature1, together with the intensive sprays required for gray mold, fungicide-resistant strains in B. cinerea have developed against many classes of fungicides in China and many other countries as well2,3,4,5,6,7,8.

Zoxamide is a commercial benzamide fungicide with great promise against oomycete plant pathogens as well as against some true fungi such as B. cinerea, Cercospora beticola, Venturia inaequalis, Monilinia fructicola and Mycosphaerella fijiensis9. Zoxamide has the same mode of action as benzimidazoles, which inhibits tubulin polymerization and arrests nuclear division by binding to the β-subunit of microtubules10. Benzimidazoles are a group of fungicides with a long usage history. Representatives include carbendazim, thiophanate-methyl, etc. However, unlike zoxamide, benzimidazoles are only active against true fungi but not oomycetes. In addition, the resistance to benzimidazoles developed rapidly after their introduction11,12; by contrast, resistance or reduced sensitivity to zoxamide has been rarely reported since it was commercialized in 200113,14,15,16. Attempts to obtain isolates resistant to zoxamide in Phytophthora capsici and P. infestans with the use of chemical mutagenesis, UV irradiation, or adaptation have been largely unsuccessful15. Thus far, there are just two reported cases of zoxamide-induced resistance in oomycete pathogens. One is acquired resistance in P. capsici by treating either mycelial cultures or zoospores with UV irradiation and selection with zoxamide, but the frequency was low13; the other has been achieved in Pythium sylvaticum via repeated exposure to zoxamide17. For true fungi, some benzimidazole-resistant field isolates of B. cinerea and V. inaequalis exhibiting a cross-resistance to zoxamide have been detected14,18; and in 2011, it was reported that some moderately zoxamide-resistant isolates of B. cinerea with wild-type sensitivity to benzimidazoles was detected in field14.

In most cases, amino acid substitutions in the β-tubulin explain the resistance to benzimidazoles in various pathogens (B. cinerea, Neurospora crassa, Aspergillus nidulans, Penicillium expansum, V. inaequalis, M. fructicola, Tapesia yallundae and Tapesia acuformis)18,19,20,21,22,23,24,25. The most commonly reported mutations are at codon 198 and 200. A replacement of glutamic acid with alanine at position 198 (E198A) makes isolates with high resistance to carbendazim much more sensitive to zoxamide14. The frequency of E198K is also relatively high in field isolates, but it leads to simultaneous resistance to benzimidazoles and zoxamide14. Taking together, it is suggested that codon 198 is the overlapping target site of these two fungicides. F200Y is another reported reason for the high resistance to benzimidazoles26,27. Although six different amino acid substitutions in conserved regions of β-tubulin were found in moderately zoxamide-resistant isolates with wild-type sensitivity to benzimidazoles, their contributions to the occurrence and development of zoxamide resistance have still been unclear14. In addition, one of the moderately zoxamide-resistant isolates was found with no mutations in the β-tubulin gene14. It is supposed that the reported six amino acid substitutions in β-tubulin are possibly not the cause of zoxamide resistance in ZoxRCarS phenotype isolates.

Zoxamide is still undergoing registration for application on potato, tomato, pepper and cucumber in China (CCM International Ltd., Guangzhou, China website). In this study, the risk of developing resistance in B. cinerea to zoxamide in China was assessed in order to support the registration progress and to guide application with the goal of preventing resistance. The objectives of the study were to: i) determine the baseline sensitivity of B. cinerea to zoxamide; ii) generate zoxamide-resistant mutants with wild-type sensitivity to carbendazim and characterize their fitness components; iii) investigate the molecular mechanism of zoxamide resistance in B. cinerea and clarify how the point mutations might affect the binding of zoxamide and carbendazim by constructing docking models; iv) develop a rapid and reliable method for detection of zoxamide-resistant isolates in populations of B. cinerea.

Materials and methods

B. cinerea isolates and culture conditions

B. cinerea was isolated from diseased tomato leaves or fruits. Diseased samples were collected in 2011 from various cities and provinces in northern, central and southern China where there was no history of zoxamide usage; sampling locations included Fujian, Shanghai, Liaoning and Inner Mongolia. Tomato leaves with lesions were cut into 0.5-cm-diameter pieces, decontaminated in 75% (vol/vol) ethanol for 1 min, rinsed three times by shaking in sterile water and then plated on yeast glucose agar medium (YG; 5 g of yeast extract powder, 18 g of dextrose and 15 g of agar, distilled water to 1 liter) amended with streptomycin sulfate (50 μg/ml; 100% a.i., Tuoyingfang Biotech Co., Ltd., Beijing). For isolation from diseased tomato fruits, a small quantity of mycelium or conidia was transferred to a Petri plate containing YG. After 2–3 days at 20 °C in the dark, small mycelium plugs from the edge of the cultures were transferred to new YG plates. In total, 161 B. cinerea isolates were obtained (Table 1). For long-term storage, the isolates were maintained on potato dextrose agar (PDA; 200 g of boiled potato tubers, 18 g of dextrose and 14 g of agar, distilled water to 1 liter) slants that were covered with sterile mineral oil and stored at 12 °C.

Fungicides

The fungicides used in this study are listed in Table S1. They were dissolved individually in dimethyl sulfoxide (DMSO) to make stock solutions, which were stored at 4 °C in the dark.

Sensitivities of 161 field isolates of B. cinerea to zoxamide and carbendazim

Radial growth was used to determine the sensitivities of the 161 B. cinerea isolates to zoxamide and carbendazim. For each isolate, a plug (5 mm in diameter) was taken from the edge of a 3-day-old B. cinerea colony on PDA and transferred to a PDA plate containing a range of concentrations of zoxamide or carbendazim (see below). The final concentration of DMSO was limited to 0.1% (vol/vol) and the same concentration of the solvent was used as a control throughout this study. Each combination of isolate, fungicide and concentration was represented by four replicate plates. The effect of the fungicide on radial growth was determined by measuring colony diameters after incubation at 20 °C in the dark for 3 days. A linear regression equation was derived by regressing the probit of percentage of inhibition of average radial growth (colony diameters minus 5 mm) on the log10 of fungicide concentration as described previously13. The effective concentration for 50% inhibition (EC50) was calculated from the dose response curves.

The concentrations of zoxamide in the PDA were 0, 0.4, 0.6, 0.8, 1, 2, 4 and 5 μg/ml. If the EC50 was determined to be >5 μg/ml, a concentration which can completely inhibit the growth of all the tested sensitive isolates14, the isolate was designated as resistant and the isolate was retested with 3, 5, 10, 25 and 50 μg of zoxamide/ml. A distribution histogram of zoxamide EC50 values for all zoxamide-sensitive isolates was established and the shape, mean and range of frequency distribution was assessed.

The single discriminatory concentration of 5 μg/ml, which completely inhibit carbendazim-sensitive strains but allows the growth of resistant strains, was used to measure the sensitivity to carbendazim. For sensitive isolates, the following eight concentrations of carbendazim were used to obtain dose-response curves: 0.04, 0.05, 0.06, 0.07, 0.08, 0.09, 0.1 and 0.2 μg/ml.

For each zoxamide-resistant field isolate, a resistance level was estimated by calculating an RF value, which was the ratio of the EC50 for the resistant isolate to the EC50 of the corresponding parent isolate. According to the sensitivity to both fungicides, isolates were divided into four phenotypes: ZoxSCarS (sensitive to zoxamide and carbendazim), ZoxSCarR (sensitive to zoxamide and resistant to carbendazim), ZoxRCarR (resistant to zoxamide and carbendazim) and ZoxRCarS (resistant to zoxamide and sensitive to carbendazim).

Baseline sensitivity of B. cinerea field isolates to zoxamide

A distribution histogram of zoxamide EC50 values for zoxamide-sensitive isolates was developed and the shape, mean, variance and range of the frequency distribution were assessed.

Generation of zoxamide-resistant mutants of B. cinerea

Eight wild-type ZoxSCarS isolates (NJ11, NJ2, NJ3, SX1, S6, P10, T2-6 and T1-1) were randomly selected to generate zoxamide-resistant mutants. Mycelial agar plugs (5 mm in diameter) cut from 3-day-old colonies were placed (with the mycelium side down) on PDA plates containing zoxamide at 4 μg/ml (the EC90 of most ZoxSCarS isolates). After incubation at 20 °C in the dark for 15-30 days, cultures growing from the plugs were transferred to new PDA plates amended with the same concentration. This “domestication step” of low-dose exposure was repeated several times. Then the survivors of the final transfer were transferred to a series of PDA plates amended with increasing concentrations of zoxamide (10, 20, 30, 50 and 100 μg/ml) for high-dose induction. Before an isolate was transferred to a higher dose, the exposure to the lower dose was repeated several times until most plugs survived. Finally, the resistance of potential mutants was confirmed on PDA containing 5 μg/ml of zoxamide. Only two zoxamide-resistant mutants were obtained: RZ-BC14 and RZ-BC16. The EC50 values of the two zoxamide-resistant mutants were estimated by measuring mycelial growth on PDA containing 3, 5, 10, 25 and 50 μg of zoxamide/ml. The RF value of each mutant was calculated as the EC50 of the mutant/EC50 of its sensitive parent.

Phenotypic characteristics of mutants and isolates

As described in the following sections, a number of phenotypic characteristics were determined for the two zoxamide-resistant mutants (RZ-BC14 and RZ-BC16), their sensitive parent isolate NJ11 and eight field isolates (two of ZoxSCarS, three of ZoxSCarR and three of ZoxRCarR); the field isolates were randomly selected from each phenotype. The phenotypic characteristics included resistance stability, mycelial growth as affected by temperature, sporulation, germination, virulence and sclerotium production.

Resistance stability

For determination of resistance stability, the nine field isolates and two mutants were subjected to 10 successive transfers on fungicide-free medium. At each transfer, the mycelial plugs excised from the edge of 5-day-old colonies were placed on a new fungicide-free PDA medium (one plug per plate), with three replicate plates per isolate. The EC50 values of the culture obtained with the 1st and 10th transfer were determined. The change in EC50 value was expressed as the EC50 value obtained with the 10th transfer divided by that obtained with the 1st transfer. This experiment was conducted three times for each selected isolate.

Mycelial growth as affected by temperature

Responses to a range of temperatures were determined by incubating the isolates and mutants on PDA plates at 4, 12, 20, 25, 28 and 37 °C in darkness. After 5 days, the colony diameter was measured. Each combination of isolate or mutant and temperature was represented by three replicate plates and the experiment was performed twice. The same methods were used to compare growth rates at 20 °C.

Sporulation in vitro

To induce conidia production, mycelial plugs (5 mm) excised from the margin of a 3-day-old PDA colony were placed upside-down on carrot agar medium (CA; 200 g of carrot, 15 g of agar and distilled water to 1 liter). The CA plates were incubated at 20 °C in darkness for 5 days before they were moved to 25 °C under near-UV light (365 nm) for another 5 days. Then, the conidia were harvested by rinsing the sporulating colony in each plate with 10 ml of distilled water. Conidia in the suspension were counted with a hemacytometer and a microscope and conidia production was expressed as the number of conidia per cm2 of colony surface. Each isolate or mutant was represented by three replicate plates. This experiment was conducted twice.

Conidia germination

For measurement of conidia germination, conidia produced in vitro were incubated on 1.5% water agar in Petri dishes at 20 °C in darkness. After 12 h, 100 conidia on each of three replicate plates were examined at 200× magnification; if the germ tube was longer than the conidium, the conidium was scored as germinated. Germination was expressed as a percentage (number of germinated conidia divided by the total number of conidia examined times 100). The conidia germination experiment was conducted twice. Germination could not be determined for the mutants because these mutants did not produce conidia.

Virulence and sporulation in vivo

Virulence was determined on detached fruits of “BeiBei” (a common tomato cultivar in China). Fruits of the same age and size were rinsed three times with sterile-distilled water. A 5-mm-diameter mycelial plug taken from the margin of a 3-day-old colony on PDA was placed on a single puncture that was formed on each fruit with a sterile needle. Virulence was also determined by inoculating a puncture on fruit with a suspension containing 2 × 106 conidia/ml, but this was not done with the mutants because the mutants did not produce any conidia. Controls consisted of fruit that were punctured and then inoculated with a sterile agar plug or distilled water. For each inoculation method, three fruits per isolate or mutant were placed in a 20-mm-diameter Petri dish with wet filter paper at the bottom. After 5 days at 20 °C with 12 h of light and 12 h of darkness, the lesion area on each fruit was measured. The virulence experiments were performed twice.

Conidia production in vivo was measured by inoculating fruits as described in the previous paragraph. After the inoculated fruit were incubated at 20 °C with 12 h of light and 12 h of darkness for 3 days and then at 25 °C with 12 h of light and 12 h of darkness for another 5 days, the number of conidia per cm2 of lesion area was determined. The in vivo sporulation experiments were performed twice.

Sclerotia production in vitro

For comparison of sclerotia production, an agar plug cut from the edge of a 3-day-old colony on PDA was placed in the center of a 9-cm-diameter Petri dish. After 15 days at 20 °C in darkness, sclerotia were removed from the cultures and dried to a constant weight at 80 °C for 12 h. Sclerotia production was expressed as sclerotia dry mass per Petri dish. Each isolate or mutant was represented by three replicate Petri dishes.

Cross resistance

EC50 values, based on the radial growth of B. cinerea isolates on PDA, were used to evaluate cross resistance among zoxamide, carbendazim and 10 frequently used fungicides belonging to other chemical groups. The experiment used seven randomly selected ZoxSCarS isolates, six randomly selected ZoxSCarR isolates, five randomly selected ZoxRCarR isolates and the two ZoxRCarS mutants. The fungicides and concentrations are listed Table S2. Each combination of isolate or mutant and fungicide and concentration was represented by three replicate plates and the experiment was conducted twice.

Molecular characterization of the β-tubulin gene in isolates of B. cinerea with different phenotypes

Genomic DNA was extracted from same B. cinerea isolates and mutants used for the determination of cross resistance. The isolates were grown for 3 days in PDA medium at 20 °C and the extraction method was the same as described previously28. Based on the sequence U27198.1 published in GenBank, three pairs of primers were designed for amplification of the full-length β-tubulin gene in B. cinerea (Table S3). These and all other primers used in this study were synthesized by Beijing Sunbiotech Co. (Beijing, China). The 50-μl PCR reaction volume included 1 μl of genomic DNA (50-100 ng), 1 μl of each primer (10 μM), 4 μl of dNTP mixture (2.5 μM each dNTP), 5 μl of 10× Easy Taq DNA Polymerase Buffer and 1 μl of 2.5 U EasyTaq DNA Polymerase (TransGen Biotech, Beijing, China). All PCRs were performed in a MyCyclerTM Thermal Cycler (Bio-Rad) with the following parameters: 94 °C for 5 min; followed by 35 cycles of 94 °C for 30 s, 60 °C for 30 s and 72 °C for 90 s; and a final extension at 72 °C for 10 min. The PCR products of the expected size were separated and purified in a 1.5% agarose gel and submitted to Beijing Sunbiotech Co. for sequencing. Sequences of the fragments amplified from the three pairs of primers were pieced together to form a total of 3136-bp β-tubulin gene by DNAMAN software. The amino acid sequences predicted were referred to the reported amino acid sequence (AAB60307.1) of β-tubulin in B. cinerea.

Molecular docking analysis

Bioinformatic analysis was used to investigate the molecular docking of zoxamide and carbendazim with β-tubulin protein. The crystal structure 3N2G retrieved from the Protein Data Bank (PDB ID: 3N2G) was applied in the current study. 3N2G is a complex crystal of microtubules with a carbamate compound named G2N which is a low molecular weight inhibitor of tubulin and has a carbamate structure similar to both zoxamide and carbendazim (Fig. S1). Furthermore, the binding pocket of G2N in the crystal structure overlaps with the reported resistance sites of benzimidazoles (Fig. S2). The alignment of the β-tubulin amino acid sequence of B. cinerea and the D chain of 3N2G (Ovis aries) was performed using DNAMAN software. The results indicated that the two sequences shared 82.33% sequence identity (Fig. S3), which confirmed that the crystal structure of 3N2G was a suitable template to study the binding conformation of zoxamide and carbendazim with β-tubulin.

The 3D conformations of zoxamide and carbendazim were retrieved from PubChem Database (http://pubchem.ncbi.nlm.nih.gov/) and compared to the binding pocket ligand G2N by assessing the energy minimization of each complex using the MMFF94 force field with MMFF94 charges29. The docking experiments were conducted using the Surflex-Dock (SFXC) function from the Sybyl X2.0 software package. The G2N ligand was first docked into the binding pocket to reproduce the complex X-ray structure of 3N2G and the best ligand pose was selected on the basis of the top Surflex-Dock energy score and the suitable parameters were then used to evaluate the docking of zoxamide and carbendazim within the same binding pocket30. The Biopolymer-Replace Sequence subset from the Sybyl X2.0 software package was used to produce site-directed mutations of the “3N2G” binding pocket at residues E198 (E198V, E198K) or M233 (M233I) with the energy minimization being performed using the Tripos force field with Gasteiger-Marsili charges. Zoxamide and carbendazim were then docked into the mutated binding pockets, respectively and the relationship between the mutation site and fungicide affinity was analyzed based on the energy score and the binding mode.

Allele-specific PCR (AS-PCR) detection of the mutation in the β-tubulin gene resulting in zoxamide resistance in B. cinerea

Based on the single mutation in the β-tubulin gene of ZoxRCarS isolates, four pairs of allele-specific primers were designed with the artificial introduction of a mismatched base at the last nucleotide of the 3′-end of the forward primers (Table S3). To test the specificity, all of the primer pairs were used for gradient PCR using the DNA templates from the ZoxRCarS isolates RZ-BC14 and RZ-BC16, the ZoxSCarS isolate NJ11, the ZoxSCarR isolate SQ15 and the ZoxRCarR isolate FJX3. PCR amplifications were performed in a MyCyclerTM Thermal Cycler (Bio-Rad) with the following parameters: 94 °C for 5 min; followed by 30 cycles of 94 °C for 30 s, 50–68 °C for 30 s and 72 °C for 30 s; and a final extension at 72 °C for 10 min. PCR products were analyzed by electrophoresis using a 2% agarose gel in TAE buffer.

Results

Response of field isolates to zoxamide and carbendazim

Based on a colony growth assay on PDA containing different concentrations of zoxamide or carbendazim, three phenotypes were detected among 161 B. cinerea field isolates obtained from 26 locations in China (Table 2). In order of abundance (from most to least), these phenotypes were ZoxSCarR (sensitive to zoxamide and resistant to carbendazim), ZoxRCarR (resistant to both the fungicides) and ZoxSCarS (sensitive to both the fungicides). Isolates that were resistant to zoxamide and sensitive to carbendazim (ZoxRCarS) were not detected. In total, 84% of the isolates were carbendazim resistant (Table 2), indicating that carbendazim resistance is a severe problem in China, especially in Liaoning and Inner Mongolia where all detected isolates were carbendazim-resistant (ZoxS/RCarR). Although zoxamide had not been used in China before isolates were collected, resistance to this fungicide was detected, likely because of cross resistance in some carbendazim-resistant isolates.

Altogether, 71% of 161 B. cinerea isolates were sensitive to zoxamide (ZoxSCarS/R). The EC50 values for these 114 isolates ranged from 0.05 to 1.95 μg/ml with a mean and standard error of 0.76 ± 0.03 μg/ml. The frequency showed a skewed unimodal distribution (Fig. 1).

Two zoxamide-resistant mutants were obtained

As noted earlier, the phenotype ZoxRCarS was not detected in the field. In this study, two mutants, designated as RZ-BC14 and RZ-BC16, were obtained (with a frequency below 10−9) from the ZoxSCarS isolate NJ11 by mycelial adaptation on zoxamide-amended medium. No mutants were derived from NJ2, NJ3, SX1, S6, P10, T2-6, or T1-1. The zoxamide EC50 values of the two mutants were >10 μg/ml (Table 3) and the initial RFs were 13.28 and 20.43. The two mutants showed wild-type sensitivity to carbendazim (Table 3).

Resistance stability of zoximide-resistant mutants and of representative isolates of the different phenotypes

The stability of zoximide resistance of the mutants RZ-BC14 and RZ-BC16 was tested and compared with that of their parent isolate NJ11 and also with that of eight randomly selected field isolates. For the six zoxamide-sensitive isolates (including NJ11) that were zoxamide-sensitive, initial EC50 values ranged from 0.49 to 1.18 μg/ml (Table 3). For the three field isolates and two mutants that were zoxamide-resistant, initial EC50 values ranged from 11.47 to 29.53 μg/ml and all RF values were >12 (Table 3). After 10 successive transfers on a fungicide-free medium, the change in EC50 (EC50 at 1st transfer/EC50 at 10th transfer) for most isolates was close to 1, regardless of phenotype. RZ-BC14 was an exception because its EC50 doubled after 10 transfers (Table 3). In general, the sensitivity to zoxamide was relatively stable regardless of phenotype.

Colony growth as affected by temperature

The four phenotypes of B. cinerea had nearly the same response to different temperatures. Growth was fastest at 20 °C except for isolate FJX3, whose optimum growth temperature was 25 °C and growth for all phenotypes was very slow at 4 °C and 37 °C (Fig. 2).

In comparisons of colony growth rate at 20 °C among the mutants and the parent isolate, the growth rate was highest for NJ11, intermediate for RZ-BC14 and very low for RZ-BC16 (P < 0.05) (Table 4). In comparisons among the four phenotypes, the average growth rate of the ZoxSCarS phenotype was not significantly different from that of the ZoxSCarR and ZoxRCarR phenotypes but was significantly higher than that of the ZoxRCarS phenotype (P < 0.05) (Table 4).

Sporulation in vitro and in vivo and conidia germination

The zoxamide-resistant mutants (ZoxRCarS) produced no conidia in vitro or in vivo and conidia production did not significantly differ among the other three wild-type phenotypes (P < 0.05) (Table 4).

Conidia germination was ≥98% for ZoxSCarS, ZoxSCarR and ZoxRCarR. Germination could not be determined for ZoxRCarS because the mutants did not produce conidia.

Virulence

Based on the lesions generated by mycelial plugs, virulence was significantly lower in the two ZoxRCarS mutants than in the parent isolate NJ11 (P < 0.05) (Table 4). The average of lesion sizes generated by mycelial plugs did not significantly differ among the four phenotypes but tended to lower in the ZoxRCarS phenotype (P < 0.05) (Table 4). Based on lesions generated when conidia suspension was used as inoculum, virulence did not significantly differ among ZoxSCarS, ZoxSCarR and ZoxRCarR phenotypes (P < 0.05). Virulence based on conidia could not be evaluated for ZoxRCarS (i.e. RZ-BC14 and RZ-BC16) because the mutants failed to sporulate (Table 4).

Sclerotium production in vitro

Sclerotium production on PDA did not significantly differ among ZoxSCarS, ZoxSCarR and ZoxRCarR phenotypes (P < 0.05) (Table 4). However, for NJ11, micro-sclerotia were observed at the bottom of the petri dish, but were too small to measure; while for the two ZoxRCarS mutants RZ-BC14 and RZ-BC16, neither normal nor micro sclerotia were produced (Fig. S4).

Cross resistance

Ten commonly used fungicides belonging to different chemical classes than zoxamide and carbendazim were tested for cross resistance with zoxamide and carbendazim; this was done using two to seven representatives of each phenotype. For the protective fungicide thiram, EC50 values were generally low for all four phenotypes; one ZoxSCarR isolate, however, had an EC50 value of 48.68 μg/ml (Table 5). For procymidone, the EC50 values were >1.3 μg/ml for all carbendazim-resistant isolates (ZoxS/RCarR) but were <0.25 μg/ml for the sensitive isolates (ZoxS/RCarS); this five-fold difference in sensitivity suggests double-resistance to carbendazim and procymidone. Azoxystrobin-resistant isolates were detected in all phenotypes, including NJ11, RZ-BC14 and RZ-BC16. Based on the reported EC50 values of pyrimethanil-sensitive isolates of B. cinerea (<0.3 μg/ml)4,31,32, only two ZoxSCarS isolates were determined to be pyrimethanil-sensitive. All the tested isolates and mutants had wild-type sensitivity to chlorothalonil, myclobutanil, iprodione, prochloraz, tebuconazole and fluazinam (Table 5).

Molecular characterization of the β-tubulin gene in different phenotypes

Comparison of the deduced amino acid sequence between isolates from phenotypes differing in zoxamide and carbendazim response revealed a number of mutations in the β-tubulin gene (Table 6). E198V was found in all tested ZoxSCarR isolates. For ZoxRCarR, a glutamic acid (GAG)-to-lysine (AAG) replacement at the same amino acid position 198 (E198K) was identified. An ATG-to-ATA substitution resulted in the replacement of methionine with isoleucine (M233I) in the two laboratory-induced zoxamide-resistant mutants (ZoxRCarS).

Effect of amino acid changes on the binding affinity of carbendazim and zoxamide to β-tubulin

The sequence alignment showed that there was a tyrosine (Y) at codon 200 in the β-tubulin of Ovis aries (Fig. S3) which just corresponds to the mutation site responsible for moderate resistance to carbendazim (CarMR)27 and resistance to zoxamide in B. cinerea. The substitution of tyrosine (Y) for phenylalanine (F), as occurs in the tubulin of wild type B. cinerea, was found to strengthen the hydrogen bonding force between the β-tubulin and the side-chain of carbendazim from one hydrogen bond (2.38 Å) to two stronger hydrogen bonds (2.09 Å and 2.20 Å) (Fig. 3F,G) and resulted in the docking score increased from 4.90 to 6.16 (Table 7). For zoxamide, the hydrogen bond interaction with the F200 (1.98 Å) was much stronger than that with Y200 (2.40 Å) (Fig. 3A,B).

Although there was a new weak hydrogen bond (2.27 Å) and a weak Pi-Pi (4.51 Å) interaction formed between carbendazim and β-tubulin (Fig. 3F,I), the substitution of glutamate for the valine at position 198 (E198V) eliminated the two strong hydrogen bonds (2.09 Å and 2.20 Å) between carbendazim with E198, which resulted in the docking score decreased from 6.16 to 3.94 for carbendazim (Table 7). However, for zoxamide, although the mutation E198V made the H bond (1.98 Å) between zoxamide and F200 disappear, two H bonds were newly formed between zoxamide with V236 (1.81 Å) and T237 (2.13 Å) (Fig. 3A,D). As a result, there was little change in the docking score (5.36 for E198 and 5.30 for V198, Table 7). The changes in the docking score corroborated the results of the fungicide sensitivity assays in which the mutation E198V caused resistance to carbendazim, but not to zoxamide (Table 6). The E198K mutation was found to alter the binding pocket for both zoxamide and carbendazim. The H bond (1.98 Å) between zoxamide and F200 was replaced by a weaker H bond (2.42 Å) with C239; the two H bonds (2.09 Å and 2.20 Å) between carbendazim with E198 were reduced to one weak H bond with K198 (2.38 Å) (Fig. 3C,H). These results also validated the data from the sensitivity assays and explain why the E198K substitution results in resistance to both zoxamide and carbendazim. The M233I mutation was found to have no effect on hydrogen bonding force between the E198 and the side-chain of carbendazim, but caused the loss of the hydrogen bond interaction (1.98 Å) between F200 and zoxamide (Fig. 3E,J), which explains why this mutation only results in resistance to zoxamide.

AS-PCR for rapid detection of zoxamide-resistant isolates of B. cinerea

DNA templates from one ZoxRCarS mutant and from one isolate of each of the other three phenotypes were used for AS-PCR. With the primer pair RZBCR1-RZBC233T, a 365-bp fragment was amplified at annealing temperatures of 50.0–56.7 °C, regardless of the origin of the template DNA; as the annealing temperature was increased to 61.0 °C, however, the amplicon was obtained only from the ZoxRCarS DNA template. When primers with an artificially mismatched base (A, C, G) at the last nucleotide of the 3′-end were used, no amplicon was amplified from the ZoxSCarS, ZoxSCarR or ZoxRCarR template regardless of how low the annealing temperature was (Fig. 4A). This indicated that the artificial introduction of a mismatch in the primers could increase the specificity at various annealing temperatures. With primers RZBCR1-RZBC233C, the 365-bp fragment was amplified at 56.0 °C from RZ-BC14 and RZ-BC16 but not from the isolates of the other three phenotypes (Fig. 4B).

Discussion

Microtubule inhibitors which have been used as fungicides include benzimidazole and thiophanate fungicides such as carbendazim and thiophanate-methyl33. Zoxamide is the sole commercial anti-tubulin agent in benzamide chemical group. Unlike carbendazim, which only has a great efficiency against true fungi but not oomycetes, zoxamide exhibits fungitoxic activity toward a broad range of organisms, including both oomycete and non-oomycete fungi9. In contrast with the high resistance risk of benzimidazoles, which is a severe problem for many plant pathogens worldwide4,12,14,22,25, the resistance risk developing to zoxamide is defined as low33, according to the uncommon appearance of resistant isolates in field and the low mutagenesis frequency in lab. To date, there have been only a few reports of cross-resistance to zoxamide in benzimidazole resistant strains of true fungi, like in B. cinerea and V. inaequalis14,18; in oomycete pathogens, no resistance or reduced sensitivity to zoxamide has been reported in field since it was commercialized in 2001. The lab-induced resistance to zoxamide in oomycetes is also rarely achieved, except in P. capsici and Pythium sylvaticum although with a low mutagenesis frequency13,17. Although zoxamide and benzimidazoles have the similar mode of action, the resistance risk of zoxamide contrasts sharply with the severe resistance problems in benzimidazoles. An important difference between the two compounds is that zoxamide is mainly used against diploid oomycetes while carbendazim is mainly used against haploid stages of true fungi. The inheritance of resistance in oomycete pathogens to zoxamide is thought to be recessive, which means that the allele of the mutants must be homozygous for the resistance to be fully expressed16. However, in the current study, only one out of eight B. cinerea isolates with ZoxSCarS phenotype was mutated after many transfers on zoxamide-amended medium and only two stable ZoxRCarS mutants were obtained but with fitness penalty. According to the results, the risk that B. cinerea develops resistance to zoxamide is suggested to be low as well, without consideration of the nature cross-resistance with benzimidazoles. Taking together, the resistance risk of zoxamide is low, regardless in oomycetes or non-oomycetes. A likely explanation for the low resistance risk of zoxamide should be the particular target sites of zoxamide acting on β-tubulin which would make a distinction from benzimidazoles.

In order to assess the risk of resistance to zoxamide in B. cinerea, the sensitivity profile of B. cinerea field isolates was evaluated and phenotypes were characterized according to their sensitivities to zoxamide and carbendazim. In our study, 84% of 161 B. cinerea isolates were resistant to carbendazim, which demonstrates that benzimidazole resistance is a serious problem in China, especially in Liaoning and Inner Mongolia where all isolates were carbendazim-resistant (ZoxS/RCarR). It follows that fungicide application strategies should be changed. In addition, the apparent cross resistance between zoxamide and carbendazim indicates that there is some risk in using zoxamide in areas that have experienced frequent, large-scale and long-term applications of benzimidazoles. Multi-drug resistance was detected for procymidone, pyrimethanil, azoxystrobin, carbendazim and zoxamide, while drug resistance was not detected for chlorothalonil, myclobutanil, iprodione, prochloraz, tebuconazole or fluazinam. Therefore, mixing the latter fungicides with zoxamide should provide control of the approximately 29% of the field isolates in China with the ZoxRCarR phenotype. At the same time, applications of carbendazim, azoxystrobin, pyrimethanil and procymidone must be avoided or reduced for the control of gray mold caused by B. cinerea in China.

Except for the mechanism underlying the cross resistance of zoxamide with carbendazim, the molecular mechanism of zoxamide resistance has not been previously reported15,16,33. The glutamic acid at position 198 of the β-tubulin protein seems to be one of the key sites for zoxamide and carbendazim binding. The results of the molecular docking analysis indicate that there was two strong hydrogen bonds (2.09 Å and 2.20 Å) between E198 and the side-chain of carbendazim (Fig. 3F). Previous studies14,20,22,23,25 showed that the substitution of glutamic acid with other amino acids at this position, including alanine, valine, glycine or lysine (E198A/V/G/K), is associated with high levels of resistance to carbendazim indicating that these two hydrogen bonds could play a major role in the binding of carbendazim to the β-tubulin protein. Similar studies have also shown that zoxamide sensitivity can be affected by changes at E198, for example it was found that the mutation E198A increased sensitivity to zoxamide in both B. cinerea and V. inaequalis14,18, but the mutation E198V had no effect on the sensitivity to zoxamide. The results of the molecular docking analysis in the current study showed that although E198 was a component of the binding pocket of zoxamide in β-tubulin, the fungicide did not form a direct interaction with it (Fig. 3A) which could explain why mutations at this position do not affect sensitivity to zoxamide as much as carbendazim. The amino acid substitution at position 200 is another common mutation associated with resistance to carbendazim26,27. The data from the molecular docking analysis confirmed that the F200Y mutation altered the binding pocket of carbendazim and resulted in a weakening of two hydrogen bonds (2.09 Å and 2.20 Å) formed with E198, which was replaced with one hydrogen bond formed (2.38 Å) with Y200. This result seems consistent with the resistance observed in isolates containing this mutation27. The hydrogen bond interaction between zoxamide and F200 (1.98 Å) was much stronger than that between zoxamide and Y200 (2.40 Å) (Fig. 3A,B), which is consistent with the resistance observed in isolates carrying this mutation.

In the current study, we demonstrated that the M233I mutation only resulted in resistance to zoxamide and not to carbendazim, which is not surprising given the differences in binding pocket of zoxamide and carbendazim with β-tubulin. Indeed, the results of the molecular docking analysis confirmed that although the M233I had no effect on the binding of carbendazim, it resulted in the loss of the hydrogen bond interaction (1.98 Å) between F200 and zoxamide (Fig. 3E,J). Taking together, the results in the study have shown that the conserved M233 in β-tubulin is a crucial target site for zoxamide against B. cinerea, which is probably the main reason for the difference of resistance risk between the two fungicides.

Molecular detection methods such as AS-PCR, PCR-RFLP and RAPD-PCR have been developed for detecting isolates with mutations associated with fungicide resistance. Malandrakis et al.14 and Ziogas et al.34 developed a PCR-RFLP method that can rapidly detect benzimidazole-resistant isolates with mutations at codon 198 (E198A/K/V/G) of β-tubulin in B. cinerea populations. The current study shows that another mutation in the β-tubulin protein, M233I, is responsible for resistance to zoxamide. Previous reports indicated that the introduction of a mismatch at the last second nucleotide of the 3′-end can increase the specificity of the allele-specific primer. In our study, the mismatch was introduced at the 3′-end and the resulting AS-PCR primers were found to be highly specific. These AS-PCR primers will be useful for detecting zoxamide resistance in field populations of B. cinerea.

Additional Information

How to cite this article: Cai, M. et al. M233I Mutation in the β-Tubulin of Botrytis cinerea Confers Resistance to Zoxamide. Sci. Rep. 5, 16881; doi: 10.1038/srep16881 (2015).