See more from this Session: Symposium--Do -Omics Hold Promise for Greater Understanding of Soil Microbial Ecology
Monday, November 1, 2010: 11:50 AM
Long Beach Convention Center, Room 104B, First Floor
Metaproteomics has the potential to transform the study of microbial community functioning in soil. To test this potential, experiments were conducted to characterize the microbial community proteome in toluene amended (1.) soil and (2.) soil microbial inoculated cultures. A glucose-amended soil was also used as a contrast to the effects of toluene. A total of 47 proteins were identified at a 95% confidence-interval. The toluene-amended communities shared many proteins and showed a high degree of similarity to previous studies of toluene impacted bacteria. For example, the microbial communities in the toluene amended soil and cultures but not the glucose impacted microbial communities, showed the presence of glutamine synthetase (Gln), ABC-transporters (e.g. Glt1), extracellular solute binding proteins, and outer membrane proteins (Omp). These proteins may be upregulated for the purpose of removing toluene from bacterial cells. Toluene amended cultures also showed the presence of arginine deiminase (ArcA), and cold-shock protein (Csp), while microbial protein from toluene amended soil showed the presence of the stress proteins superoxide dismutase (SodB) and chaperonin (GroEL). Fatty acid methyl ester analysis indicated that toluene exposed microorganisms increased the rigidity of their membranes through a 3 to 12 X increase in the ratio of saturated to monounsaturated fatty acids. Moreover, the 16S rRNA gene analysis of bacterial communities in the toluene amended soil showed a high degree of dominance, whereby ~80% of the OTU’s were described by representatives most closely related to genus Bacillus, This research has shown that proteomic studies can be used to provide useful descriptions of microbial function in soil.
See more from this Division: S03 Soil Biology & BiochemistrySee more from this Session: Symposium--Do -Omics Hold Promise for Greater Understanding of Soil Microbial Ecology