Browsing by Author "Johnson, D.A."

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    Genetic and phenotypic diversity and random association of DNA markers of isolates of the fungal plant pathogen Sclerotinia sclerotiorum from soil on a fine geographic scale
    (Soil Biology and Biochemistry, 2012) Chen, W.; Johnson, D.A.; Porter, L.; Attanayake, R.N.
    Sclerotia of the soil-borne plant pathogen Sclerotinia sclerotiorum were collected from 1 m2 area of the top 1.27 cm layer of soil in an alfalfa field in southeastern Washington state of the US. Out of 272 sclerotia collected, 40 were randomly selected and analyzed for genetic diversity in terms of microsatellite loci, mycelial compatibility groups (MCGs) and phenotypic diversity using five phenotypic traits (fungicide sensitivity, oxalic acid production, growth rate, colony color and virulence). Sixteen microsatellite haplotypes and 15 MCGs were found among the 40 isolates. The isolates showed three colony colors (beige, dark and white) on Difco PDA and exhibited significant differences in growth rate, oxalic acid production, and sensitivity to three fungicides, benomyl, fluazinam and iprodione. However, these isolates did not show differences in their ability to colonize detached pea leaves. No apparent relationship among the neutral genetic markers and the phenotypic traits was detected. Two of the haplotypes accounted 40% of the isolates, suggesting isolates of these haplotypes might be better adapted to the environmental conditions in this alfalfa field. Several lines of evidence indicated high levels of genetic diversity and potential outcrossing within the population of S. sclerotiorum: 1) high likelihood of five genetic populations based on Bayesian probability and the presence of admixed isolates; 2) random association of alleles in every pair-wise linkage disequilibrium test among eight independent microsatellite loci; 3) discordances between microsatellite haplotypes and MCGs and 4) lack of correspondence among the genetic markers and phenotypic traits. Multilocus Index of Association test suggested that outcrossing occurs only within interbreeding subpopulations of S. sclerotiorum.
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    Inferring outcrossing in the homothallic fungus Sclerotinia sclerotiorum using linkage disequilibrium decay
    (Heredity, 2014) Attanayake, R.N.; Tennekoon, V.; Johnson, D.A.; Porter, L.D.; del Río-Mendoza, L.; Jiang, D.; Chen, W.
    The occurrence and frequency of outcrossing in homothallic fungal species in nature is an unresolved question. Here we report detection of frequent outcrossing in the homothallic fungus Sclerotinia sclerotiorum. In using multilocus linkage disequilibrium (LD) to infer recombination among microsatellite alleles, high mutation rates confound the estimates of recombination. To distinguish high mutation rates from recombination to infer outcrossing, 8 population samples comprising 268 S. sclerotiorum isolates from widely distributed agricultural fields were genotyped for 12 microsatellite markers, resulting in multiple polymorphic markers on three chromosomes. Each isolate was homokaryotic for the 12 loci. Pairwise LD was estimated using three methods: Fisher?s exact test, index of association (IA) and Hedrick?s D?. For most of the populations, pairwise LD decayed with increasing physical distance between loci in two of the three chromosomes. Therefore, the observed recombination of alleles cannot be simply attributed to mutation alone. Different recombination rates in various DNA regions (recombination hot/cold spots) and different evolutionary histories of the populations could explain the observed differences in rates of LD decay among the chromosomes and among populations. The majority of the isolates exhibited mycelial incompatibility, minimizing the possibility of heterokaryon formation and mitotic recombination. Thus, the observed high intrachromosomal recombination is due to meiotic recombination, suggesting frequent outcrossing in these populations, supporting the view that homothallism favors universal compatibility of gametes instead of traditionally believed haploid selfing in S. sclerotiorum. Frequent outcrossing facilitates emergence and spread of new traits such as fungicide resistance, increasing difficulties in managing Sclerotinia diseases.