Data_Sheet_1_A Short-Term Response of Soil Microbial Communities to Cadmium and Organic Substrate Amendment in Long-Term Contaminated Soil by Toxic Elements.PDF Pavla Madrova Tomas Vetrovsky Marek Omelka Michal Grunt Yvona Smutna Daria Rapoport Marek Vach Petr Baldrian Jan Kopecky Marketa Sagova-Mareckova 10.3389/fmicb.2018.02807.s001 https://frontiersin.figshare.com/articles/dataset/Data_Sheet_1_A_Short-Term_Response_of_Soil_Microbial_Communities_to_Cadmium_and_Organic_Substrate_Amendment_in_Long-Term_Contaminated_Soil_by_Toxic_Elements_PDF/7362230 <p>Two long-term contaminated soils differing in contents of Pb, Zn, As, Cd were compared in a microcosm experiment for changes in microbial community structure and respiration after various treatments. We observed that the extent of long-term contamination (over 200 years) by toxic elements did not change the total numbers and diversity of bacteria but influenced their community composition. Namely, numbers of Actinobacteria determined by phylum specific qPCR increased and also the proportion of Actinobacteria and Chloroflexi increased in Illumina sequence libraries in the more contaminated soil. In the experiment, secondary disturbance by supplemented cadmium (doses from double to 100-fold the concentration in the original soil) and organic substrates (cellobiose or straw) increased bacterial diversity in the less contaminated soil and decreased it in the more contaminated soil. Respiration in the experiment was higher in the more contaminated soil in all treatments and correlated with bacterial numbers. Considering the most significant changes in bacterial community, it seemed that particularly Actinobacteria withstand contamination by toxic elements. The results proved higher resistance to secondary disturbance in terms of both, respiration and bacterial community structure in the less contaminated soil.</p> 2018-11-20 05:00:39 respiration diversity actinobacteria straw cellobiose