371-6 Natural Disease Suppression of Rhizoctonia By a Network of Fungal Players: Evidence of Direct Competition and Competitive Exclusion.

See more from this Division: SSSA Division: Soil Biology & Biochemistry
See more from this Session: Linking Soil Macrofaunal and Microbial Communities with Crop Dynamics Including Diseases

Wednesday, November 18, 2015: 1:30 PM
Minneapolis Convention Center, 101 J

Christopher Ryan Penton, 6073 S Backus Mall, Arizona State University, Mesa, AZ, VVSR Gupta, Australian Commonwealth Scientific and Industrial Research Organization, Glen Osmond, Australia, James M. Tiedje, Dept. Plant, Soil & Microbial Sciences, Michigan State University, East Lansing, MI, Stephen Neate, Department of Agriculture, Fisheries and Forestry, Toowoomba, Australia, Kathy Ophel-Keller, South Australian Research and Development Institute, Glen Osmond, SA, Australia, Michael Gillings, Department of Biological Sciences, Macquarie University, Sydney, Australia, Paul Harvey, Ecosystem Sciences, Commonwealth Scientific and Industrial Research Organisation (CSIRO), Glen Osmond, SA, Australia and David Roget, Sustainable Ecosystems, Commonwealth Scientific and Industrial Research Organisation (CSIRO), Glen Osmond, SA, Australia
Abstract:
Evidence of antagonism by naturally-occurring fungal and bacterial species towards Rhizoctonia bare patch disease has been demonstrated in historically disease-suppressive cropping fields in Australia. However, there is little data regarding bacterial-fungal interactions in these systems nor is there an understanding of the temporal variability or stability of these communities. While the presence of putative suppressive taxa has been indicated to drive suppression in some agricultural systems, the process would require interactions among multiple taxa in order to achieve temporal stability. Here we present a two-year study focusing on both soil bacterial and fungal communities in Rhizoctonia disease conducive and suppressive soils by targeted phylogenetic marker Illumina sequencing. Approximately 450,000 sequences from 105 samples were generated for both the fungal 28S and bacterial 16S rRNA markers. Temporal variability was evidenced by larger changes in fungal communities over annual and sowing/in-crop samples, though suppression status remained the primary driving component.  Molecular Ecological Network analysis suggested that suppressive soils are characterized by a higher functional redundancy with “small-world” interactions. In all, the data suggest that suppression of Rhizoctonia solani AG8 is due a combination of direct antagonism by soil taxa and endophytic competition for root infection sites (competitive exclusion). Thus, stable disease suppression in these cropping soils appears more complex than due to the mere presence of a few characterized suppressive taxa.

See more from this Division: SSSA Division: Soil Biology & Biochemistry
See more from this Session: Linking Soil Macrofaunal and Microbial Communities with Crop Dynamics Including Diseases