Effects of conventional and reduced N inputs on nematode communities and plant yield under intensive vegetable production

► Intensive vegetable greenhouse production caused poor soil nematode community. ► Reduced N fertilization reduced the abundance of root knot nematodes. ► Reduced N fertilization improved soil nematode community. ► Reduced N fertilization decreased soil mineral nitrogen content. ► Reduced N fertiliz...

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Published in:Applied soil ecology : a section of Agriculture, ecosystems & environment ecosystems & environment, 2013-04, Vol.66, p.48-55
Main Authors: Ruan, Wei-Bin, Ren, Tao, Chen, Qing, Zhu, Xiang, Wang, Jing-Guo
Format: Article
Language:English
Subjects:
Agronomy. Soil science and plant productions
Biological and medical sciences
Chemical, physicochemical, biochemical and biological properties
correlation
crop yield
Degradation
field experimentation
Fundamental and applied biological sciences. Psychology
greenhouse soils
greenhouses
intensive farming
Maturity index
nitrates
nitrogen
nitrogen content
nitrogen fertilizers
Physics, chemistry, biochemistry and biology of agricultural and forest soils
plant age
Plant parasite index
production technology
Root knot nematodes
soil analysis
soil fauna
soil food webs
Soil mineral nitrogen
Soil science
soil treatment
surveys
vegetable growing
vegetables
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Summary:► Intensive vegetable greenhouse production caused poor soil nematode community. ► Reduced N fertilization reduced the abundance of root knot nematodes. ► Reduced N fertilization improved soil nematode community. ► Reduced N fertilization decreased soil mineral nitrogen content. ► Reduced N fertilization had no adverse effects on crop yield loss. As the largest group of soil mesofauna, nematodes occupy all consumer trophic levels in soil food webs, and may serve as a proxy for soil food web structure and composition. The present study was conducted in an intensively managed, solar greenhouse vegetable-production system to investigate the effects of nitrogen management on soil nematode communities. We conducted two experimental trials. The first trial was a field survey in vegetable greenhouses with various cultivation histories (1, 2 and ≥5 years) and open grain fields. The second trial was a series of nematode community analyses over four years from a long-term N management experiment with three treatments: NN (no nitrogen input), RN (reduced N fertilization) and CN (conventional N application). In the field survey, we found that soil total N significantly increased with planting age. After one year of cultivation, greenhouse soil had a significantly lower Shannon–Wiener diversity index (H) (1.55) and a higher abundance of root knot nematodes (RKNs) (292 nematodes per 100g dry soil) compared to the soil in the open fields. With increasing time of cultivation, there were further decreases in H and increases in RKNs with H reaching 1.03 and RKNs 1254 after five or more years of vegetable planting. Analyses of soil nematode community in the N management experiment indicated that the abundance of RKNs significantly decreased by 55.9% to 770 per 100g dry soil in the RN treatment compared to 1745 per 100g dry soil in the CN treatment. The maturity index of the soil nematode community was negatively correlated with the amount of N input and soil total N. Further, tomato fruit yield was not affected by reduced N input in the RN treatment in contrast to the CN treatment. Our results clearly demonstrate that reduced N input had two benefits; (1) reducing the risk of nitrate pollution associated with excessive N input, (2) decreasing the abundance of RKNs and improving the soil nematode community for vegetable production systems.
ISSN:0929-1393
1873-0272
DOI:10.1016/j.apsoil.2013.01.004