Non‐target site SDHI resistance is present as standing genetic variation in field populations of Zymoseptoria tritici

Abstract BACKGROUND A new generation of more active succinate dehydrogenase (Sdh) inhibitors (SDHIs) is currently widely used to control Septoria leaf blotch in northwest Europe. Detailed studies were conducted on Zymoseptoria tritici field isolates with reduced sensitivity to fluopyram and isofetamid; SDHIs which have only just or not been introduced for cereal disease control, respectively. RESULTS Strong cross‐resistance between fluopyram and isofetamid, but not with other SDHIs, was confirmed through sensitivity tests using laboratory mutants and field isolates with and without Sdh mutations. The sensitivity profiles of most field isolates resistant to fluopyram and isofetamid were very similar to a lab mutant carrying SdhC‐A84V, but no alterations were found in SdhB, C and D. Inhibition of mitochondrial Sdh enzyme activity and control efficacy in planta for those isolates was severely impaired by fluopyram and isofetamid, but not by bixafen. Isolates with similar phenotypes were not only detected in northwest Europe but also in New Zealand before the widely use of SDHIs. CONCLUSION This is the first report of SDHI‐specific non‐target site resistance in Z. tritici. Monitoring studies show that this resistance mechanism is present and can be selected from standing genetic variation in field populations. © 2017 The Authors. Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.


INTRODUCTION
Fungicides are widely used in crop protection to achieve quality and a high yield of produce. Septoria leaf blotch, caused by Zymoseptoria tritici (synonym: Mycosphaerella graminicola), is one of the most important diseases affecting wheat production in northwest Europe. Owing to a lack of resistant varieties, programmed application of fungicides has been key to controlling this pathogen. 1 Methyl benzimidazole carbamates, sterol demethylation inhibitors and quinone outside inhibitors (QoIs) have been introduced sequentially to the market and have provided growers with excellent control of Septoria leaf blotch. However, their efficacy has been lost or substantially eroded over time due to the emergence and further spread of resistant strains in Z. tritici field populations. [2][3][4] Carboxamide fungicides, representing an old class of chemistry originating from the late 1960s, have been shown to inhibit succinate dehydrogenase (Sdh), an important component of the mitochondrial respiratory chain (complex II). Succinate dehydrogenase inhibitors (SDHIs) impact electron transport by blocking the quinone-binding site of Sdh formed by subunits B, C and D. [5][6][7][8] In contrast to the narrow spectrum of early-generation SDHIs, the latest generation of SDHIs have shown broad-spectrum control of Ascomycota, including Z. tritici. 9,10 Following the 2003 introduction of boscalid, the first of the new generation of SDHIs with strong eyespot activity, 9 other SDHIs, such as bixafen, fluxapyroxad, isopyrazam, penthiopyrad and benzovindiflupyr, that are very effective in controlling Septoria leaf blotch have also been registered in Europe since 2010. To delay resistance, SDHIs should be used in a mixture with other fungicides having different modes of action, such as azoles, and/or multiple sites, and the maximum number of sprays per season has been restricted.
Several laboratory ultraviolet (UV)-mutagenesis studies have shown that SDHI resistance can develop easily in different fungal species, 11,12 including Z. tritici, for which a range of mutations in the SdhB, SdhC and SdhD genes have been detected. [13][14][15] Prior to the emergence of SDHI resistance in Z. tritici field strains in 2012, 16 SDHI resistance-conferring mutations underlying single amino acid substitutions in Sdh subunits B, C or D were reported for field strains of other plant pathogens. [17][18][19] Lack of a cross-resistance relationship between boscalid and fluopyram has been found in several cases. Substitution of histidine by tyrosine at codon position 272 in SdhB (B-H272Y) of Botrytis cinerea and an equivalent substitution in Corynespora cassiicola led to very high resistance to boscalid, although sensitivity to fluopyram remained. 20 Furthermore, the new SDHI isofetamid had a sensitivity profile similar to that of fluopyram when a B-H272Y mutant of B. cinerea was tested. 21,22 Low levels of SDHI resistance in Z. tritici strains carrying Sdh mutations C-T79 N and C-W80S were reported in 2012, followed by C-N86S (2013), B-N225 T (2014) and B-T268I (2015). 16 High levels of resistance due to strains carrying Sdh mutation C-H152R were recently reported in Ireland and the UK. 16,23,24 Field isolates with different levels of sensitivity to fluopyram have also been found in Ireland but not discussed further. 23 Metabolic degradation or altered expression of efflux pumps encoded by ATP-binding cassette (ABC) transporters and/or major facilitator superfamily (MFS) transporters can also reduce sensitivity against various xenobiotics, including fungicides with different modes of action. [25][26][27][28] In Z. tritici, upregulation of MgMFS1 by a 519-bp insertion in the promoter region led to a decrease in sensitivity to various fungicides, including QoI, SDHI and azole fungicides, although other transporters might also contribute to fungicide resistance. 28 Generally, this type of reduced sensitivity, known as multidrug resistance (MDR), can be easily distinguished from target-site resistance by low-moderate resistance to unrelated chemicals such as cycloheximide, rhodamine and fentin chloride, which are antifungal but also substrates of efflux pumps. Antimycotic drugs inhibiting squalene epoxidase such as terbinafine and tolnaftate have been reported as useful indicators to identify both Z. tritici and B. cinerea strains with the MDR phenotype because a high level of resistance for MDR strains was observed, especially with tolnaftate. [28][29][30] Our aim of this study is: (i) to confirm a cross-resistance relationship between SDHIs with similar chemical structures, (ii) to check the distribution of resistance against fluopyram and isofetamid in a population collected at different locations and over time, and (iii) to investigate the resistance mechanism. Here, we report further studies on the detection and characterization of fluopyramand isofetamid-resistant Z. tritici field strains isolated from different countries. Isofetamid is not commercialized as a cereal diseases control agent, but fluopyram has just been introduced in the UK in a mixture with bixafen and prothioconazole to enhance and obtain a wider spectrum of disease control. We observed a positive cross-resistance relationship between fluopyram and isofetamid. Sequencing analysis of the SDHI binding pocket (SdhB, SdhC and SdhD) and mitochondrial Sdh enzyme activity assays revealed that the inhibitory effects of both fluopyram and isofetamid were severely impaired in the absence of any target-site alterations in resistant strains. Further studies are needed to elucidate the underlying resistance mechanism(s) in these strains.

Isolation and storage of Z. tritici strains
For cross-resistance studies, reference strain IPO323-derived laboratory mutants and field isolates, for which the Sdh genotypes had been analysed previously, 14,16,24 were tested. For additional field population monitoring studies, sampling and isolation of Z. tritici strains from infected wheat leaves were performed as described previously. 31 Septoria leaf blotch-infected leaves were randomly collected from wheat fields located near Lyon (fungicide untreated plots) and Orleans (fungicide untreated and treated plots) in France and at Rothamsted Research (Harpenden, UK) from an untreated field in 2015. Additional populations were sampled from untreated fields near Carlow (Ireland) and at Rothamsted in 2017. Conidial suspensions were streaked onto yeast extract peptone dextrose agar (YPD agar; For Medium, Norwich, UK) amended with penicillin G sodium salt and streptomycin sulphate at 100 mg mL −1 respectively, and incubated for 7 days at 15 ∘ C. Single yeast-like forming colonies were propagated by transferring these to fresh YPD agar plates. Propagated spores were stored in 80% (v/v) glycerol at −80 ∘ C. The SDHI-sensitive reference strain MM20, 14 carrying SdhC-N33 T and C-N34 T, isolated from a fungicide-untreated field in Spain in 2006, and NT321.17, a SDHI-resistant MgMFS1 overexpressing strain 28 without Sdh alterations, isolated from a SDHI-treated plot in Hampshire (UK) in 2013, were included as additional reference strains in this study. NT321.17 showed the highest resistance to SDHIs among MgMFS1 overexpressing strains in the authors' collection. In addition, strains representing field populations from the UK, Ireland and New Zealand, sampled previously and stored in the same way, were also tested.

Fungicide sensitivity testing
Sensitivity tests were conducted according to Fraaije et al. 14  and 50 mg L −1 for resistant strains. Spore suspensions of Z. tritici were prepared at the final concentration of 2.5 × 10 4 spores mL −1 from cultures grown for 7 days on YPD agar at 15 ∘ C. Aliquots of 100 L of these spore suspensions were added to each well. Plates were incubated in the dark at 21 ∘ C for 4 days, and growth was measured at 630 nm using a FLUOstar OPTIMA microplate reader (BMG Labtech, Offenburg, Germany) in well-scanning mode with a 2 × 2 matrix of scanning points within a 3-mm diameter. Fungicide sensitivities were determined as the 50% effective concentration to inhibit growth (EC 50 in mg mL −1 ) using a dose-response relationship curve function of the OPTIMA software. No adverse effect of DMSO up to 500 mg mL −1 was observed.

Isolation of genomic DNA, PCR detection of MgMFS1
promoter inserts and sequencing of sdhA, B, C and D genes Genomic DNA was extracted from strains grown on YPD plates at 15 ∘ C in the dark for 7 days and quantified according Rudd et al. 32 PCRs using primers listed in Table 1 were carried out on a Biometra T3000 thermocycler (Göttingen, Germany) in a final volume of 25 L containing 20 ng of fungal template DNA. PCRs Creek, TX, USA). Amplification conditions were 95 ∘ C for 2 min, followed by 40 cycles at 95 ∘ C for 10 s, 57 ∘ C (MgMFS1) or 62 ∘ C (SdhA) for 20 s and 72 ∘ C for 1 min with a final DNA extension at 72 ∘ C for 5 min. PCR products were sequenced by MWG Eurofins Genomics GmbH (Ebersberg, Germany) using both PCR primers for each reaction and two additional primers, SdhAF2 (TCTTTGCCATTGATCTCATCATG) and SdhAR2 (GCTCCGTAGATACCAGTTGGGT) were used for SdhA sequencing. Sequences were assembled and aligned with Geneious version 6.1.4 software (Biomatters Ltd., Auckland, New Zealand), and amino acid substitutions deduced after sequence analysis.

Mitochondrial isolation and succinate dehydrogenase enzyme activity assays
Mitochondrial extraction was performed using the method by Scalliet et al. with minor modification. 15 Frozen spores were homogenized in liquid nitrogen and crushed to a fine powder using a pestle and mortar; 20% w/v of the powder was re-suspended in mitochondrial extraction buffer (1 M sorbitol, 50 mM sodium citrate buffer, pH 5.8) containing 1 mM dithiothreitol. The suspension was centrifuged at 700 g for 5 min once and supernatant was transferred to new tubes. The supernatant was then centrifuged and mitochondria were pelleted at 17000 g for 20 min. A pink-red pellet was re-suspended in assay buffer (0.25 M sucrose, 0.1 mM EDTA, 3 mM Tris-HCl, pH 7.4) and washed by centrifugation. After measuring the protein content using the Bradford protein assay, 33 isolated mitochondria samples were adjusted to a final concentration of 5 g protein L −1 and immediately used in enzyme assays. Colorimetric assay using microplate reader was adapted to measure succinate: ubiquinone/dichlorophenolindophenol (DCIP) activity. Briefly, 2 g protein samples of isolated mitochondria were added to 100 L of assay buffer containing 200 M 2,3-decyl ubiquinone (dUQ) and SDHI solution at different concentrations (0, 0.002, 0.008, 0.031, 0.125, 0.5, 2, 8 and 32 M). Then, 100 L of reaction buffer (assay buffer containing 100 M DCIP, 10 mM succinate and 1 M antimycin A) was added to initiate the enzyme reaction and the reduction in DCIP was monitored at 600 nm using a iMark microplate reader (Bio-Rad Laboratories, Hercules, CA, USA).

2.6
In planta Septoria efficacy testing using different SDHIs Wheat cultivar, Consort, was sown on commercial nursery soil. Four-week-old seedlings, four per pot, in triplicate, were sprayed with fungicide solution prepared with an in-house emulsifiable concentrate (EC) formulation containing surfactant and organic solvent, dried for several hours and inoculated with a spore suspension of Z. tritici at a concentration of 2 × 10 6 spores mL −1 . Because IPO323 was not able to infect cv Consort, strain MM20 was used as reference for efficacy tests. 14 After 48 h at 100% relative humidity (RH) in dark incubation boxes, seedlings were moved to the greenhouse and incubated for ∼ 18 days at >80% RH and ambient temperature. Disease symptoms were assessed visually using the following keys: 0, no symptoms; 1, ∼ 10%; 2, 10-25%; 3, 25-50%; 4, 50-80%; and 5, > 80% of leaf area covered with pycnidia. Control efficacy was calculated using the following formula: Control efficacy (%) = 100 × (1 -average of key values in fungicide-treated plot/ average of key values in untreated plot).
Final data sets were based on the average of each test performed three times independently.

Statistical analysis
All statistical analysis was performed by SAS (SAS Institute Inc., Cary, NC, USA). For cross-resistance between SDHIs, Spearman's correlation analysis was applied to EC 50 values of SDHIs against each Sdh mutants. The Shapiro-Wilk test was used to assess normality for field population collected in 2015.

SDHI cross-resistance patterns in resistant lab mutants and field strains
In total, six different SDHIs belonging to four chemical groups were tested (Fig. 1). To assess SDHI cross-resistance patterns, a range of laboratory-generated UV mutants and two 2015 UK field isolates carrying C-T79 N and C-I161S, which have been reported previously, were tested ( Table 2). 14 − 16,24 The number of data points (n = 21) was not enough; however, a positive cross-resistance relationship was observed between the pyridine (boscalid) and pyrazole carboxamides (bixafen, fluxapyroxad and penthiopyrad), with values of r s > 0.778 (Fig. 2). The pyridinyl-ethyl-benzamide fluopyram and the phenyl-oxo-ethyl thiophene amide isofetamid had slightly higher fungicidal activity against the B-H267Y mutants (18 − 11 and M36) compared with reference strain IPO323, and showed a high level of cross-resistance (r s = 0.851), whereas weaker correlations between the other four SDHIs were observed with r s values ranging from 0.250 to 0.499 for fluopyram and −0.056 to 0.185 for isofetamid, respectively. Fungicidal activities of both fluopyram and isofetamid were less impaired by mutants for whom the other four SDHIs were severely affected, such as B-T268I and C-T79I. However, in comparison with the other SDHIs, the C-A84V mutant was much less sensitive to isofetamid and fluopyram with resistance factors (RF) of >174 and >18, respectively. wileyonlinelibrary.com/journal/ps

SDHI sensitivity testing and SdhB, C and D sequence analysis of Z. tritici strains isolated in France and the UK in 2015
The bixafen, fluopyram and isofetamid sensitivity profiles of 113 single-spore isolates collected from untreated plots in France (strains from Lyon and Orleans; n = 65) and the UK (strains from Harpenden; n = 48) were measured ( Fig. 3 and Table 3 Table 2 (n = 22). Sensitivity data measured as EC 50 (mg L −1 ) values were expressed with log 10 scale. P < 0.05 means the correlation was statistically significant.
sequence analysis (Table 4). Sensitivity testing confirmed the high levels of resistance to isofetamid in the resistant strains with RF > 174 in comparison with reference strain IPO323. The level of fluopyram sensitivity varied in the isofetamid-resistant strains, with RF ranging from 1.2 to 38.6, but high values (RF > 10) were measured for six of the 10 strains tested. Furthermore, none of these strains was able to grow in the presence of 10 mg L −1 tolnaftate and no or a low level of resistance (RF < 10) was measured for all compounds tested, including the SDHIs fluxapyroxad and bixafen. The sensitivity levels of the three isofetamid sensitive strains, Orleans 40, Lyon 31 and Lyon 16, were as expected; no or low levels of sensitivity to all compounds with exception of strain Lyon 16, in which low levels of resistance were measured for all SDHIs and fentin chloride, together with a high level of resistance to tolnaftate (RF > 58). A similar pattern, albeit with higher RF values, was found for the efflux pump MgMFS1 overexpressing reference strain NT321.17. PCR confirmed the presence of a 519-bp insert in the MgMFS1 promoter region of strain Lyon 16 and reference strain NT321.17, but not in the other strains tested (Fig. 4). All strains tested, including the reference strains, were sensitive to the multisite inhibitor chlorothalonil. SdhB, C and D sequencing analysis of all selected strains showed the presence of three different Sdh amino acid substitutions. Six of the 13 isolates tested showed two SdhC amino acid substitutions, C-N33 T and C-N34 T, simultaneously, but the presence of these alterations was not linked with SDHI resistance because Lyon 31 carrying those two mutations was sensitive to four SDHIs tested (Table 4). An additional substitution, D-V106 L, was found in strain R15-46, but this alteration is not known to affect SDHI binding, 14,15 and the bixafen sensitivity of this strain was like the other tolnaftate-sensitive strains carrying both C-N33 T and C-N34 T.

Mitochondrial succinate dehydrogenase activity assays
Extracted mitochondria from isolates sensitive and less-sensitive to fluopyram and isofetamid were subjected to Sdh enzyme activity assays ( Table 5). The mitochondrial Sdh activity of reference strain IPO323 was severely affected with IC 50 values wileyonlinelibrary.com/journal/ps

In planta disease control of SDHI resistant Z. tritici strains
The SDHI-sensitive reference strain MM20 and four field isolates, moderate (Lyon 14) or highly resistant to fluopyram and isofetamid (Lyon 35, Orleans 26 and R15-46) were tested in the greenhouse ( Table 6). After being inoculated on wheat seedlings, sprayed preventatively with three SDHIs to evaluate pathogenicity and in planta disease control, all five strains produced pycnidia on unsprayed and inoculated leaves 18 days after inoculation. MM20 was well controlled (efficacy >80%) by both fluopyram and isofetamid at dose rates of ≥10 mg L −1 . By contrast, the three highly resistant isolates, Lyon 35, Orleans 26 and R15-46, were not controlled by fluopyram and isofetamid even at the highest application rate of 100 mg L −1 . The moderate resistant strain Lyon 14 was not controlled using isofetamid but fluopyram provided control at rates ≥30 mg L −1 . Bixafen showed a high control efficacy at 1 mg L −1 for MM20 (91 %) and the other strains were well controlled at either 3 (Orleans 26) or 10 mg L −1 (Lyon 14, Lyon 35 and R15-46).

Distribution of fluopyram and isofetamid resistant strains in Z. tritici populations sampled at different locations and over time
Population sensitivity profiles to three SDHIs, bixafen, fluopyram and isofetamid, were determined for 12 different field populations sampled in the UK (6), Ireland (2), France (2) and New Zealand (2) ( Table 7). The frequencies of isolates with low and high resistance to fluopyram, isofetamid and bixafen in each population were determined. Highly isofetamid-resistant strains (EC 50 > 5.0 mg L −1 ) were detected in each population, with frequencies between 2.6% and 33.3%. Highly fluopyram-resistant strains (EC 50 > 5.0 mg L −1 ) were detected only at low frequencies, between 2.2% and 11. wileyonlinelibrary.com/journal/ps   34 , were shown to be less sensitive to both pyridine-(boscalid) and pyrazole-carboxamides (e.g. bixafen, fluxapyroxad and penthiopyrad), whereas their sensitivity to fluopyram was equal to or higher than wild-type isolates. 15,18,20,35 The fungicidal activity of isofetamid was also higher for a B-H272Y mutant of B. cinerea. 22 Homology modelling and docking studies have suggested that the histidine residue at codon 267 of SdhB in Z. tritici is supposed to interact with the hetero atom, such as N and O, of the heterocyclic acid part of SDHIs via hydrogen bonding. 14,36,37 The enhanced or high isofetamid and fluopyram sensitivity of two Z. tritici mutants carrying B-H267Y in this study can be explained by greater hydrophobic interaction between tyrosine and these two SDHIs. An opposite trend was observed for the Z. tritici mutant carrying C-A84V, in which only the fungicidal activity of fluopyram and isofetamid was impaired. Docking studies showed that C-A84 is positioned near the aliphatic linker of fluopyram, 15 and substitution of alanine with bulky valine might, in comparison with other SDHIs, have the greatest impact on isofetamid binding, to which its carbonyl group was introduced in its aliphatic spacer (Fig. 1). Considering the SDHI sensitivity profiles and similarity between chemical 3D structures, a similar mode of binding can be expected between fluopyram and isofetamid.

Z. tritici strains with reduced sensitivity to fluopyram and isofetamid
Field isolates with reduced sensitivity to SDHIs commonly used in cereals, such as bixafen, isopyrazam, penthiopyrad and fluxapyroxad, have recently been identified. Most field isolates carry single key amino acid substitutions in at least one Sdh subunit, sometimes in combination with other alterations that do not form part of the binding pocket and can also be detected in resistant strains. For example, C-T79 N can be found alone or in combination with C-I29V or with both C-N33 T and C-N34 T (Fraaije, unpublished). Strains carrying C-N33 T and C-N34 T, including reference strain MM20, are sensitive to SDHIs and have been reported previously. 23,38 Multiple key target-site alterations have been found in lab mutants 14 and in two field strains isolated in 2015 (Fraaije, unpublished results), but this might carry a greater fitness penalty. Fluopyram-resistant field strains of Z. tritici have been detected previously, but have not been characterized further. 23 In this study, we found a high number of field strains resistant to fluopyram and isofetamid, but no key SdhB, SdhC or SdhD alterations were detected (Table 4). Additional SdhA sequencing of a fluopyram-and isofetamid-resistant strain Lyon wileyonlinelibrary.com/journal/ps   100  100  13  71  0  100  30  100  0  0  0  100  10  98  0  0  0  22  3  6 6  0  0  0  0  1  3 5  0  0  0  0  Isofetamid  100  100  42  0  0  47  30  100  35  0  0  0  10  87  29  0  0  0  3  6 8  0  0  0  0  1  3 1  0  0  0  0  Bixafen  10  100  97  100  100  100  3  100  51  96  8  77  1  9  35 also revealed no mutations in comparison with the sensitive reference strain IPO323 (see NCBI XM_003857126.1). No common mutations found in 4 Sdh subunits among fluopyram-and isofetamid-resistant strains led us to evaluate other possible mechanisms in fungicide resistance. Target-site overexpression has also been reported as a resistance mechanism in several fungi. Different evolutionary pathways, such as gene duplication 39 and genetic alterations of transcription factors 40 or promoter regions, 41 resulting in constitutively or inducible CYP51 overexpression have been linked with azole resistance. However, overexpression of Sdh genes as a resistance mechanism is unlikely because this would affect all SDHIs to some extent, and not only the fluopyram and isofetamid sensitivity.
ABC and MFS transporters are also involved in fungicide resistance. Upregulated MgMFS1 by 519-bp insertion in the promoter region of Z. tritici resulted in low to moderate resistance against chemically unrelated antifungal compounds. 28 The presence of the 519-bp MgMFS1 promoter insert in strains Lyon 16 and NT321.17 correlated with resistance to both tolnaftate and fentin chloride, but the RF values for fluopyram and isofetamid were relatively low in these strains. The presence of highly fluopyramand isofetamid-resistant strains, tolnaftate sensitive and lacking the MgMFS1 519-bp promoter insert, suggest that MgMFS1 overexpression is not the driver for strongly reduced fluopyram and isofetamid sensitivity. Interestingly, fluopyram and isofetamid resistance was also observed in mitochondrial extracts of the corresponding fluopyram-and isofetamid-resistant strains (Table 5). Some ABC transporters are located within mitochondria 42 and further studies are needed to study their potential role in fluopyram and isofetamid resistance.

Evolution and practical impact of resistance against fluopyram and isofetamid
Under laboratory conditions, artificial mutagenesis is considered to be a powerful tool to detect possible mutations and predict the future evolution of resistance in fields. 43 Mutagenesis studies of Z. tritici under selection by different SDHIs have shown that some mutations can confer different levels of resistance to different SDHIs, although some mutations conferred high resistance levels to all SDHIs tested. 14 wileyonlinelibrary.com/journal/ps M Yamashita, B Fraaije to fluopyram, and in particular isofetamid, in multiple locations as early as 2003 (Table 7), before the widespread introduction of a newer generation of SDHIs into the cereal market in 2010, indicates pre-existing non-target site resistance. We have also seen that European Z. tritici populations have developed acquired resistance only through a range of different Sdh target-site mutations since 2012. 16 In addition, strains with altered efflux pump activity, including MgMFS1-overexpressing strains have recently spread in Europe as a response to selection by QoI, azole and SDHI fungicides. Highly isofetamid-resistant strains (EC 50 > 5.0 mg L −1 ) seem to be accumulating in populations sampled at Rothamsted over time. This accumulation is not due to the selection of strains carrying Sdh mutations because only a few strains with Sdh mutations were detected in 2016 (C-T79 N, n = 1) and 2017 (C-T79 N, n = 2 and C-R151M, n = 1), and all field Sdh variants reported to date are sensitive or slightly resistant to isofetamid (EC 50 < 5.0 mg L −1 ). Highly isofetamid-resistant strains might be selected indirectly through in planta breakdown products of SDHIs caused by metabolic activity of the host plant and/or the fungus itself. The high frequency of low isofetamid-and bixafen-resistance strains in the 2017 Irish population can be explained in a sharp increase in frequency of efflux pump-overexpressing strains and C-T79 N strains after 2015. 44 This study shows that non-target site SDHI resistance pre-exists in Z. tritici populations and should be considered for the development of new molecules and rational design of resistance management strategies.