One of the most important challenges in agriculture is to determine the effectiveness and environmental impact of certain farming practices. The aim of present study was to determine and compare the taxonomic composition of the microbiomes established in soil following long-term exposure (14 years) to a conventional and organic farming systems (CFS and OFS accordingly). Soil from unclared forest next to the fields was used as a control. The analysis was based on RT-PCR and pyrosequencing of 16S rRNA genes of bacteria and archaea. The number of bacteria was significantly lower in CFS than in OFS and woodland. The highest amount of archaea was detected in woodland, whereas the amounts in CFS and OFS were lower and similar. The most common phyla in the soil microbial communities analyzed were Proteobacteria (57.9%), Acidobacteria (16.1%), Actinobacteria (7.9%), Verrucomicrobia (2.0%), Bacteroidetes (2.7%) and Firmicutes (4.8%). Woodland soil differed from croplands in the taxonomic composition of microbial phyla. Croplands were enriched with Proteobacteria (mainly the genus Pseudomonas), while Acidobacteria were detected almost exclusively in woodland soil. The most pronounced differences between the CFS and OFS microbiomes were found within the genus Pseudomonas, which significantly (p<0,05) increased its number in CFS soil compared to OFS. Other differences in microbiomes of cropping systems concerned minor taxa. A higher relative abundance of bacteria belonging to the families Oxalobacteriaceae, Koribacteriaceae, Nakamurellaceae and genera Ralstonia, Paenibacillus and Pedobacter was found in CFS as compared with OFS. On the other hand, microbiomes of OFS were enriched with proteobacteria of the family Comamonadaceae (genera Hylemonella) and Hyphomicrobiaceae, actinobacteria from the family Micrococcaceae, and bacteria of the genera Geobacter, Methylotenera, Rhizobium (mainly Rhizobium leguminosarum) and Clostridium. Thus, the fields under OFS and CFS did not differ greatly for the composition of the microbiome. These results, which were also confirmed by cluster analysis, indicated that microbial communities in the field soil do not necessarily differ largely between conventional and organic farming systems.
Agricultural microbiology is presented as a synthetic research field responsible for knowledge transfer from general microbiology and microbial ecology to the agricultural biotechnologies. The major goal of agricultural microbiology is a comprehensive analysis of symbiotic micro-organisms (bacteria, fungi) interacting with agriculturally important plants and animals: here we have focussed on plants. In plants, interactions with micro-organisms are diverse, ranging from two-partite symbioses (e.g. legume-rhizobia N 2 -fixing nodular symbioses or arbuscular mycorrhiza) to multipartite endophytic and epiphytic (root-associated, phyllosphere) communities. Two-partite symbioses provide the clearest models for addressing genetic cooperation between partners, resulting in the formation of super-organism genetic systems, which are responsible for host productivity. Analysis of these systems has now been extended considerably by using the approaches of metagenomics, which allow the dissection of taxonomic/population structures and the metabolic/ecological functions of microbial communities, which have resulted from the adaptation of free-living, soil microflora in the endosymbiotic niches. Both beneficial (nutritional, defensive, regulatory) and antagonistic (biocontrol) functions expressed by symbiotic microbes towards their hosts are the potential subjects of effective agronomic use. A fundamental knowledge of the genetics, molecular biology, ecology and evolution of symbiotic interactions could enable the development of microbe-based sustainable agriculture. This could achieve: (a) an improvement of major adaptive functions and productivity in crop plants by manipulating their microbial cohabitants; (b) partial or even full substitution of ecologically hazardous agrochemicals (mineral fertilizers, pesticides) by microbial preparations; (c) a decrease in the cost and an improvement of the quality of agricultural products.Ann Appl Biol 159 (2011) 155-168
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