Within-Season Shift in Fungicide Resistance Profiles of Botrytis cinerea in California Strawberry Fields.

Sensitivity of Botrytis cinerea to seven fungicide chemical classes was determined for 888 isolates collected in 2016 from 47 California strawberry fields. Isolates were collected early season (minimum fungicide exposure) and late season (maximum fungicide exposure) from the same planting block in each field. Resistance was determined using a mycelial growth assay, and variable frequencies of resistance were observed to each fungicide at both sampling times (early season %, late season %): boscalid (12, 35), cyprodinil (12, 46), fenhexamid (53, 91), fludioxonil (1, 4), fluopyram (2, 7), iprodione (25, 8), isofetamid (0, 1), penthiopyrad (8, 25), pyraclostrobin (77, 98), and thiophanate-methyl (81, 96). Analysis of number of chemical class resistances (CCRs) revealed an increasing shift in CCR from the early to late season. Phenotypes of 40 isolates that were resistant or sensitive to different chemical classes were associated with presence or absence of mutations in target genes. Fungicide-resistance phenotypes determined in the mycelial growth assay closely matched (93.8%) the genotype observed. Previously described resistance-conferring mutations were found for each gene. A survey of fungicide use from 32 of the sampled fields revealed an average of 15 applications of gray mold-labeled fungicides per season at an average interval of 12 days. The most frequently applied fungicides (average number of applications during the 2016 season) were captan (7.3), pyraclostrobin (2.5), cyprodinil (2.3), fludioxonil (2.3), boscalid (1.8), and fenhexamid (1.4). Multifungicide resistance is widespread in California. Resistance management tactics that reduce selection pressure by limiting fungicide use, rotating among Fungicide Resistance Action Committee codes, and mixing/rotating site-specific fungicides with multisite fungicides need to be improved and implemented.

Effect of Fungicide Applications on Monilinia fructicola Population Diversity and Transposon Movement.

In this study, we investigated whether fungicide-induced mutagenesis previously reported in Monilinia fructicola could accelerate genetic changes in field populations. Azoxystrobin and propiconazole were applied to nectarine trees at weekly intervals for approximately 3 months between bloom and harvest in both 2013 and 2014. Fungicides were applied at half-label rate to allow recovery of isolates and to increase chances of sublethal dose exposure. One block was left unsprayed as a control. In total, 608 single-spore isolates were obtained from blighted blossoms, cankers, and fruit to investigate phenotypic (fungicide resistance) and genotypic (simple-sequence repeat [SSR] loci and gene region) changes. In both years, populations from fungicide-treated and untreated fruit were not statistically different in haploid gene diversity (P = 0.775 for 2013 and P = 0.938 for 2014), allele number (P = 0.876 for 2013 and P = 0.406 for 2014), and effective allele number (P = 0.861 for 2013 and P = 0.814 for 2014). Isolates from blossoms and corresponding cankers of fungicide treatments revealed no changes in SSR analysis or evidence for induced Mftc1 transposon translocation. No indirect evidence for increased genetic diversity in the form of emergence of reduced sensitivity to azoxystrobin, propiconazole, iprodione, and cyprodinil was detected. High levels of population diversity in all treatments provided evidence for sexual recombination of this pathogen in the field, despite apparent absence of apothecia in the orchard. Our results indicate that fungicide-induced, genetic changes may not occur or not occur as readily in field populations as they do under continuous exposure to sublethal doses in vitro.

An intron in the cytochrome b gene of Monilinia fructicola mitigates the risk of resistance development to QoI fungicides.

BACKGROUND: The cytochrome b (Cyt b) gene is a key genetic determinant for quinone outside inhibitor (QoI) fungicide resistance in plant pathogenic fungi. A mutation at amino acid position G143 can cause qualitative resistance unless it is part of the recognition site for a self-splicing intron. The objective of this study was to clone and sequence the Cyt b gene from Monilinia fructicola (Wint.) Honey, the causal agent of brown rot of stone fruits, and to assess the risk for the development of a mutation at position 143. RESULTS: The Cyt b gene of M. fructicola was 11 927 bp in size and contained seven introns located at cDNA positions (5'-3') 204, 395, 430, 491, 507, 780 and 812 with sizes of 1592, 1318, 1166, 1252, 1065, 2131 and 2227 bp respectively. Sequence analysis revealed that the above-mentioned 1166 bp intron, a self-splicing group I intron, was located just downstream of the G143 codon. The Cyt b gene region covering the G143 location and the adjacent 1166 bp intron was PCR amplified and sequenced from Chinese and US isolates, indicating that the intron may be omnipresent in M. fructicola. CONCLUSION: This is the first complete Cyt b gene sequence published for M. fructicola or any other Monilinia species, forming the basis for molecular analysis of QoI fungicide resistance. Sequence analysis revealed that the G143A mutation responsible for high levels of QoI fungicide resistance in many plant pathogenic fungi may not develop in M. fructicola unless genotypes emerge that lack the 1166 bp intron.

Identification and characterization of Armillaria tabescens from the southeastern United States.

In the southeastern USA, Armillaria root rot disease on peach (Prunus persica) is caused by Armillaria tabescens, and to a lesser degree by A. mellea. Recent attempts to genetically characterize A. tabescens isolates using rDNA indicated the existence of heterozygosity in diploid isolates. In order to clarify this heterozygosity, DNA from stipe and single spore cultures of A. tabescens isolate SC.MF-1.01 was characterized using RFLP and sequence analysis. Direct sequencing of rDNA amplicons from diploid stipe tissue indicated heterozygosity in the IGS1 and ITS2 regions. IGS1 copies A and B, and ITS copies A and B segregated in a 1:1 ratio in single spore progeny, whereby IGS1 copy A always segregated with ITS copy A and IGS1 copy B always segregated with ITS copy B. The results indicate the existence of divergent haplotypes in the two nuclei of SC.MF-1.01 diploid mycelium and a single locus for rDNA tandem repeats. Additional IGS1 copies, designated IGS1 copy C, D, and E, with variable AluI restriction sites were cloned from SC.MF-1.01 diploid mycelium indicating polymorphism within ribosomal tandem repeats in A. tabescens. IGS1 copies C, D, and E were found once each in 100 clones analyzed, and therefore seemed to be rare compared to copies A (44 clones) and B (53 clones). RFLP and sequence analysis of the ribosomal IGS1 and ITS1 regions in North American A. tabescens isolates indicated that heterozygosity is common in A. tabescens diploid mycelium. A PCR-based molecular technique was developed to distinguish A. tabescens from many other North American Armillaria species, including A. mellea.