Violation of the Equivalence Principle in Modified Theories of Gravity

Resistance to QoI fungicides in Pyrenophora teres (Dreschsler) and P. tritici-repentis (Died.) Dreschsler was detected in 2003 in France and in Sweden and Denmark respectively. Molecular analysis revealed the presence of the F129L mutation in resistant isolates of both pathogens. In 2004, the frequency of the F129L mutation in populations of both pathogens further increased. The G143A mutation was also detected in a few isolates of P. tritici-repentis from Denmark and Germany. In 2005, the F129L mutation in P. teres increased in frequency and geographical distribution in France and the UK but remained below 2% in Germany, Switzerland, Belgium and Ireland. In P. tritici-repentis, both mutations were found in a significant proportion of the isolates from Sweden, Denmark and Germany. The G143A mutation conferred a significantly higher level of resistance (higher EC50 values) to Qo inhibitors (QoIs) than did the F129L mutation. In greenhouse trials, resistant isolates with G143A were not well controlled on plants sprayed with recommended field rates, whereas satisfactory control of isolates with F129L was achieved. For the F129L mutation, three different single nucleotide polymorphisms (SNPs), TTA, TTG and CTC, can code for L (leucine) in P. teres, whereas only the CTC codon was detected in P. tritici-repentis isolates. In two out of 250 isolates of P. tritici-repentis from 2005, a mutation at position 137 (G137R) was detected at very low frequency. This mutation conferred similar resistance levels to F129L. The structure of the cytochrome b gene of P. tritici-repentis is significantly different from that of P. teres: an intron directly after amino acid position 143 was detected in P. teres which is not present in P. tritici-repentis. This gene structure suggests that resistance based on the G143A mutation may not occur in P. teres because it is lethal. No G143A isolates were found in any P. teres populations. Although different mutations may evolve in P. tritici-repentis, the G143A mutation will have the strongest impact on field performance of QoI fungicides.

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A dispensable paralog of succinate dehydrogenase subunit C mediates standing resistance towards a subclass of SDHI fungicides in Zymoseptoria tritici

Steinhauer

Salat

Frey

et al. 2019

PLoS Pathog

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A dispensable paralog of succinate dehydrogenase subunit C mediates standing resistance towards a subclass of SDHI fungicides inZymoseptoria tritici

Steinhauer

Salat

Frey

et al. 2019

Preprint

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34Succinate dehydrogenase inhibitor (SDHI) fungicides are widely used for the control of a 35 broad range of fungal diseases. This has been the most rapidly expanding fungicide group in 36 terms of new molecules discovered and introduced for agricultural use over the past fifteen 37 years. A particular pattern of differential sensitivity (resistance) to a subclass of chemically-38 related SDHIs (SHA-SDHIs) was observed in naïve Zymoseptoria tritici populations. Class 39 specific SHA-SDHI resistance was confirmed at the enzyme level but did not correlate with 40 the genotypes of the succinate dehydrogenase (SDH) encoding genes. Mapping and 41 characterization of the genetic factor responsible for standing SHA-SDHI resistance in natural 42 field isolates identified a gene (alt-SDHC) encoding a paralog of the C subunit of succinate 43 dehydrogenase. This paralog was not present within our sensitive reference isolates and found 44 at variable frequencies within Z. tritici populations. Using reverse genetics, we showed that 45 alt-SDHC associates with the three other SDH subunits leading to a fully functional enzyme 46 and that a unique Qp-site residue within the alt-SDHC protein confers SHA-SDHI resistance. 47 Enzymatic assays, computational modelling and docking simulations for the two types of 48 SQR enzymes (alt-SDHC, SDHC) enabled us to describe protein-inhibitor interactions at an 49 atomistic level and to propose rational explanations for differential potency and resistance 50 across SHA-SDHIs. European Z. tritici populations displayed a presence (20-30%) / absence 51 polymorphism of alt-SDHC, as well as differences in alt-SDHC expression levels and splicing 52 efficiency. These polymorphisms have a strong impact on SHA-SDHI resistance phenotypes. 53Characterization of the alt-SDHC promoter in European Z. tritici populations suggest that 54 transposon insertions are associated with the strongest resistance phenotypes. These results 55 establish that a dispensable paralogous gene determines SHA-SDHIs fungicide resistance in 56 natural populations of Z. tritici. This study paves the way to an increased awareness of the 3 57 role of fungicidal target paralogs in resistance to fungicides and demonstrates the paramount 58 importance of population genomics in fungicide discovery. 59 Author Summary 60Zymoseptoria tritici is the causal agent of Septoria tritici leaf blotch (STB) of wheat, the most 61 devastating disease for cereal production in Europe. Multiple succinate dehydrogenase 62 inhibitor (SDHI) fungicides have been developed and introduced for the control of STB. We 63 report the discovery and detailed characterization of a paralog of the C subunit of the SDH 64 enzyme conferring standing resistance towards a particular chemical subclass of the SDHIs. 65The resistance gene is characterized by its presence/absence, expression and splicing 66 polymorphisms which in turn affect resistance levels. The identified mechanism influenced 67 the chemical optimization phase which led to the discovery of pydiflu...

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Regula Frey

Cytochrome b gene sequence and structure of Pyrenophora teres and P. tritici‐repentis and implications for QoI resistance

A dispensable paralog of succinate dehydrogenase subunit C mediates standing resistance towards a subclass of SDHI fungicides in Zymoseptoria tritici

A dispensable paralog of succinate dehydrogenase subunit C mediates standing resistance towards a subclass of SDHI fungicides inZymoseptoria tritici

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