Author:
Gutierrez Vazquez Yaiza,Adams Ian P.,McGreig Sam,Walshaw John,van den Berg Femke,Sanderson Roy,Pufal Hollie,Conyers Chris,Langton David,Broadhead Ruth,Harrison Catherine,Boonham Neil
Abstract
Zymoseptoria tritici is the causal agent of Septoria tritici blotch, the most important disease affecting wheat crops and responsible for up to 50% loss in yield. Azoles and SDHIs are the main groups of fungicides used to control the disease. The efficacy of these fungicides has decreased in recent years due to resistance development. Fungicide resistance can be a result of mutations in the target genes, mutations in upstream regulatory elements that result in over-expression of target proteins and the overexpression of transporters that remove toxic compounds from cells. In the current study nanopore sequencing was used to analyse isolates, mock communities and field samples to determine the pathogen population composition related to azole resistance. Despite the presence of sequencing errors, the method was able to effectively differentiate the sequences of different haplotypes present in both mock and field populations for haplotypes that were relatively common in the overall population. However, haplotypes present at a frequency lower than 5% of the total population, could not be accurately distinguished from haplotypes generated through background sequencing errors. The nanopore protocols are rapid and inexpensive, enabling the routine profiling of haplotypes within pathogen populations at the start of the season or between sprays, facilitating the selection of the most appropriate fungicide to control them, yet limit further selection for azole resistance.
Subject
Plant Science,Soil Science,Agricultural and Biological Sciences (miscellaneous),Agronomy and Crop Science