A greenhouse experiment was conducted to evaluate effects of monoculture and mixed planting of three tree species on microbial diversity and nitrogen (N) availability in rhizosphere and bulk soils. Six treatments with poplar, willow, and alder mono-or mixed seedlings were grown in the rhizoboxes and both rhizosphere and bulk soils were sampled and analysed after eight-month growth. Microbial diversity in rhizosphere soil was significantly higher than in bulk soils based on denatured gradient gel electrophoresis (DGGE) fingerprinting of 16S-or 18S-rRNA gene fragments of soil microbial community. Tree species composition significantly influenced microbial diversity index and nitrogen contents in the rhizosphere soil, with the highest values of genotypic richness, Shannon diversity index and inorganic nitrogen contents were observed in rhizosphere soils of poplar-alder mixture. Shannon diversity indices of bacteria and fungi in the rhizosphere soils were positively and significantly correlated with nitrogen contents. Alder addition significantly improved genotypic richness, microbial diversity index and nitrogen availability in the rhizosphere soils, suggesting that adding N-fixing alder into poplar plantations is a good option in the practice. 438Vol. 61, 2015, No. 10: 438-443 Plant Soil Environ.doi: 10.17221/94/2015-PSE Poplar is one of the most promising short rotation plantation forest species and at present, the area of poplar plantation in China has reached about 8.5 million ha. However, monoculture plantations lead to declines in soil fertility and plant biomass productivity over successive rotations (Mao et al. 2010). Therefore, mixed plantations have been recommended to combat soil degradation and maintain productivity of poplar plantations. In this study, a greenhouse experiment was conducted to evaluate the effect of monoculture and mixed plantations of three tree species on rhizosphere microbial diversity and nitrogen (N) availability. We hypothesized that rhizosphere effects on soil microbial diversity and nitrogen availability would vary with tree species and their compositions due to differences in intrinsic biological characteristics and complementarities of species traits (especially ecological characteristics). The specific objectives were to: (1) assess effects of tree species compositions on diversity of bacteria and fungi and nitrogen availability in rhizospheric and non-rhizospheric soils, and (2) discuss the relationships between soil microbial diversity and nitrogen availability. MATERIAL AND METHODS Rhizobox design and the planting experiment.The rhizoboxes were made of two top-open black Plexiglas compartments separated by a polyamide membrane with 30 µm pore-diameters and 75 µm thick (Fang et al. 2013). The plant-root compartment was 250 mm wide and had an internal volume of 22.5 L. The sampling compartment, where rhizosperic and bulk soils were sampled, was 50 mm wide and had an internal volume of 4.5 L. The soil used in the rhizoboxes had pH 7.2 and content of organic carbon ...
Plant roots strongly influence C and N availability in the rhizosphere via rhizodeposition and uptake of nutrients. An in situ rhizobox approach was used to compare rhizosphere effects of different tree species and clones on N cycling under seasonally flooded soil. We examined N mineralization and nitrification rates, inorganic N, and microbial biomass C (MBC) and N (MBN) in rhizosphere and bulk soils of three poplar clones, alder, and willow plantations in southeast China. Significant differences in soil pH, total N, soil organic C, MBC, MBN, and MBC/MBN were found between bulk and rhizosphere soils except alder. Compared to bulk soil, the net N mineralization and nitrification rates in rhizosphere soil across all tree species and clones increased by 124-228% and 108-216%, respectively. However, NO 3 --N was depleted in the rhizosphere soil mainly owing to the root uptake and rhizosphere microbial immobilization. The magnitude of rhizosphere effects on N transformations was considerably different among the tree species studied. Of the tested ones, alder had the greatest rhizosphere effect on N transformation, indicating different capacities of tree species to facilitate N turnover in the rhizosphere.
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