Four populations of Sclerotinia sclerotiorum in North America were inferred previously, based on analyses of both rapidly evolving markers (DNA fingerprint and mycelial compatiblity), and multilocus DNA sequence spanning the range between fast and slow evolution. Each population was defined as an interbreeding unit of conspecific individuals sharing a common recent ancestor and arising in a unique evolutionary event. The present study applies this standard to extend characterization of S. sclerotiorum populations to the Western United States. Isolates of S. sclerotiorum (N = 294) were determined to represent three genetically differentiated populations: California (CA, lettuce), Washington (WA, pea/lentil), and Ontario (ON, lettuce). CA was the most diverse population yet sampled in North America. Clonality was detected in ON and WA. No DNA fingerprints were common among the populations. The index of association (I(A)), based on fingerprint, was closer to zero (0) for CA than it was for the other populations. High diversity and lack of association of markers in California are consistent either with genetic exchange and recombination, or with large population size and high standing genetic variation. Intra- and interlocus conflict among three DNA sequence loci was consistent with recombination. The coalescent IGS genealogy confirmed subdivision and showed CA to be older than WA or ON. The Nearest Neighbor statistic on combined data confirmed subdivision among all present and previously defined populations. All isolates had both MAT1-1 and MAT1-2, consistent with uniform homothallism.
With the increasing awareness of the significance of mycorrhizas, research is focusing on studies to elucidate the contribution of the symbiosis to ecosystem dynamics. In this sense, molecular biology has acquired great significance. PCR/RFLP techniques were adapted to characterize ectomycorrhizal fungi associated with Eucalyptus grandis. The ITS region of the fungal rDNA from pure cultures and from of mycorrhizas synthesized in vitro was amplified. Primers NSA3/NLC2 were used followed by a nested reaction with primers ITS1F/NLB3. Amplicons were then digested with the enzymes MboI, HinfI and TaqI. Amplification resulted in a 1,000-bp fragment for basidiomycetes and a 1,500 bp fragment for Cenococcum geophillum (an ascomycete). There was no amplification of the plant DNA. The enzymes MboI and HinfI were more effective than TaqI, resulting in patterns of two to five fragments allowing the identification of the isolates both in culture and in mycorrhizas. HinfI allowed greater differentiation among the isolates and a higher number of polymorphisms. Restriction with TaqI resulted in too many fragments. Amplification efficiency for the fungal DNA was 64% in culture and 87% in mycorrhizas. The modified methodology represents a valuable tool to complement traditional approaches in ecosystem studies.
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