Effects of Wetland Utilization Change on Spatial Distribution of Soil Nematodes in Heihe River Basin, Northwest China

ZHU Hongqiang; MAO Zhixia; LONG Zhangwei; WANG Yan; SU Yongzhong; WANG Xuefeng

doi:10.1007/s11769-016-0813-2

Volume 26 Issue 3

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Article Navigation > Chinese Geographical Science > 2016 > 26(3): 339-351

ZHU Hongqiang, MAO Zhixia, LONG Zhangwei, WANG Yan, SU Yongzhong, WANG Xuefeng. Effects of Wetland Utilization Change on Spatial Distribution of Soil Nematodes in Heihe River Basin, Northwest China[J]. Chinese Geographical Science, 2016, 26(3): 339-351. doi: 10.1007/s11769-016-0813-2

Citation:

ZHU Hongqiang, MAO Zhixia, LONG Zhangwei, WANG Yan, SU Yongzhong, WANG Xuefeng. Effects of Wetland Utilization Change on Spatial Distribution of Soil Nematodes in Heihe River Basin, Northwest China[J]. Chinese Geographical Science, 2016, 26(3): 339-351. doi: 10.1007/s11769-016-0813-2

Effects of Wetland Utilization Change on Spatial Distribution of Soil Nematodes in Heihe River Basin, Northwest China

doi: 10.1007/s11769-016-0813-2

1.
Chinese Medicinal Material College, Jilin Agricultural University, Changchun 130118, China;
2.
Northeast Institute of Geography and Agroecology, Chinese Academy of Sciences, Changchun 130102, China;
3.
Linze Inland River Basin Research Station, Key Laboratory of Eco-Hydrology in Heihe River Basin, Cold and Arid Regions Environmental and Engineering Research Institute, Chinese Academy of Sciences, Lanzhou 730000, China

Funds: Under the auspices of Major State Basic Research Development Program of China (No. 2009CB421302), National Natural Science Foundation of China (No. 30670375, 41201245)

More Information

Corresponding author: WANG Xuefeng
Received Date: 2015-12-18
Rev Recd Date: 2016-02-17
Publish Date: 2016-06-27

Abstract

The first account of the effects of wetland reclamation on soil nematode assemblages were provided, three sites in Heihe River Basin of Northwest China, that is grass wetland (GW), Tamarix chinensis wetland (TW) and crop wetland (CW) treatments, were compared. Results showed that the majority of soil nematodes were presented in the 0-20 cm soil layers in CW treatments, followed by in the 20-40 cm and 40-60 cm layers in GW treatments. Plant-feeding nametodes were the most abundant trophic groups in each treatment, where GW (91.0%) > TW (88.1%) > CW (53.5%). Generic richness (GR) was lower in the TW (16) than that in GW (23) and CW (25). The combination of enrichment index (EI) and structure index (SI) showed that the soil food web in GW was more structured, and those in TW was stressed, while the enrichment soil food web was presented in the CW treatment. Several ecological indices which reflected soil community structure, diversity, Shannon-Weaver diversity (H'), Evenness (J'), Richness (GR) and modified maturity index (MMI) were found to be effective for assessing the response of soil namatode communities to soil of saline wetland reclamation. Furthermore, saline wetland reclamation also exerted great influence on the soil physical and chemical properties (pH, Electric conductivity (EC), Total organic carbon (TOC), Total nitrogen (Total-N) and Nitrate Nitrogen (N-NO₃^-)). These results indicated that the wetland reclamation had significantly effects on soil nematode community structure and soil properties in this study.
- soil nematode,
- spatial distribution,
- community structure,
- ecological index,
- wetland exploration

References

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[6]	Bongers T, Ferris H, 1999. Nematode community structure as a bioindicator in environmental monitoring. Trends in Ecology & Evolution, 14(6): 224-228. doi: 10.1016/S0169-5347(98) 01583-3
[7]	Coulson S J, Hodkinson I D, Strathdee A T et al., 1995. Thermal environments of arctic soil organisms during winter. Arctic & Alpine Research, 27(4): 364-370. doi: 10.2307/1552029
[8]	Ekschmitt K, Bakonyi G, Bongers M et al., 2001. Nematode community structure as indicator of soil functioning in European grassland soils. European Journal of Soil Biology, 37(4): 263-268. doi: 10.1016/S1164-5563(01)01095-0
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[11]	Ferris H, Matute M M, 2003. Structural and functional succession in the nematode fauna of a soil food web. Applied Soil Ecology, 23(2): 93-110. doi: 10.1016/S0929-1393(03)00044-1
[12]	Ferris H, Venette R C, Lau S S, 1996. Dynamics of nematode communities in tomatoes grown in conventional and organic farming systems, and their impact on soil fertility. Applied Soil Ecology, 3(2): 161-175. doi: 10.1016/0929-1393(95)00071-2
[13]	Forge T, Simard S, 2001. Structure of nematode communities in forest soils of southern British Columbia: relationship to nitrogen mineralization and effects of clearcut harvesting and fertilization. Biology & Fertility of Soils, 34(3): 170-178. doi: 10.1007/s003740100390
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[21]	Kennish M J, 2002. Environmental threats and environmental future of estuaries. Environmental. Conservation, 29(1): 78-107. doi: 10.1017/S0376892902000061
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[23]	Liang W J, Li Q, Jiang Y et al., 2005. Nematode faunal analysis in an aquic brown soil fertilised with slow-release urea, Northeast China. Applied Soil Ecology, 29(2): 185-192. doi: 10.1016/j.apsoil.2004.10.004
[24]	Liang W J, Lou Y L, Li Q et al., 2009. Nematode faunal response to long-term application of nitrogen fertilizer and organic manure in Northeast China. Soil Biology and Biochemistry, 41(5): 883-890. doi: 10.1016/j.soilbio.2008.06.018
[25]	Liang W J, Zhong S, Hua J F et al., 2007. Nematode faunal response to grassland degradation in Horqin Sandy Land. Pedosphere, 17(5): 611-618. doi: 10.1016/S1002-0160(07) 60072-1
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[28]	Montemayor M B, Price J S, Rochefort L et al., 2008. Temporal variations and spatial patterns in saline and waterlogged peat fields. Environmental and Experimental Botany, 62(3): 333-342. doi: 10.1016/j.envexpbot.2007.10.004
[29]	Mulvaney R L, 1996. Nitrogen-inorganic. In: Sparks D L (Ed.). Methods of soil Analysis. Part 3. Book Series 5. Madison: Soil Science Society of America.
[30]	Neher D A, Barbercheck M E, Anas O, 2001. Nematodes in wetland soils of North Carolina. Phytopathology, 91(6s): S139.
[31]	Nico E, Tomasz D, Simone C et al., 2013. Plant diversity effects on soil food webs are stronger than those of elevated CO₂ and N deposition in a long-term grassland experiment. Proceedings of the National Academy of Sciences, 110(17): 6689-6694. doi: 10.1073/pnas.1217382110
[32]	Okada H, Ferris H, 2001. Temperature effects on growth and nitrogen mineralization of fungi and fungal-feeding nematodes. Plant and Soil, 234(2): 253-262. doi: 10.1023/A: 1017957929476
[33]	Oostenbrink M, 1960. Estimating nematode populations by some selected methods. In: Sasser J N et al. (Eds.). Nematology. Chapel Hill: University of North Carolina Press.
[34]	Ou W, Liang W J, Jiang Y et al., 2005. Vertical distribution of soil nematodes under different land use types in an aquic brown soil. Pedobiologia, 49(2): 139-148. doi: 10.1016/j.pedobi. 2004.10.001
[35]	Porazinska D L, Duncan L W, McSorley R et al., 1999. Nematode communities as indicators of status and processes of a soil ecosystem influenced by agricultural management practices. Applied Soil Ecology, 13(1): 69-86.
[36]	Rey A, Pegoraro E, Tedeschi V et al., 2008. Annual variation in soil respiration and its components in a coppice oak forest in Central Italy. Global Change Biology, 32(4): 387-392. doi: 10.1046/j.1365-2486.2002.00521.x
[37]	Sainju U M, Singh B P, Whitehead W F et al., 2007. Accumulation and crop uptake of soil mineral nitrogen as influenced by tillage, cover crops, and nitrogen fertilization. Agronomy Journal, 99(3): 682-691.
[38]	Stanislav P, Ginetta B, Yosef S, 2008. Effect of desert plant ecophysiological adaptation on soil nematode communities. European Journal of Soil Biology, 44(3): 298-308. doi: 10.1016/j.ejsobi.2008.03.005
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Effects of Wetland Utilization Change on Spatial Distribution of Soil Nematodes in Heihe River Basin, Northwest China

1. Chinese Medicinal Material College, Jilin Agricultural University, Changchun 130118, China;

2. Northeast Institute of Geography and Agroecology, Chinese Academy of Sciences, Changchun 130102, China;

3. Linze Inland River Basin Research Station, Key Laboratory of Eco-Hydrology in Heihe River Basin, Cold and Arid Regions Environmental and Engineering Research Institute, Chinese Academy of Sciences, Lanzhou 730000, China

Funds: Under the auspices of Major State Basic Research Development Program of China (No. 2009CB421302), National Natural Science Foundation of China (No. 30670375, 41201245)

Corresponding author: WANG Xuefeng

Received Date: 2015-12-18

Rev Recd Date: 2016-02-17

Publish Date: 2016-06-27

Key words:

Abstract: The first account of the effects of wetland reclamation on soil nematode assemblages were provided, three sites in Heihe River Basin of Northwest China, that is grass wetland (GW), Tamarix chinensis wetland (TW) and crop wetland (CW) treatments, were compared. Results showed that the majority of soil nematodes were presented in the 0-20 cm soil layers in CW treatments, followed by in the 20-40 cm and 40-60 cm layers in GW treatments. Plant-feeding nametodes were the most abundant trophic groups in each treatment, where GW (91.0%) > TW (88.1%) > CW (53.5%). Generic richness (GR) was lower in the TW (16) than that in GW (23) and CW (25). The combination of enrichment index (EI) and structure index (SI) showed that the soil food web in GW was more structured, and those in TW was stressed, while the enrichment soil food web was presented in the CW treatment. Several ecological indices which reflected soil community structure, diversity, Shannon-Weaver diversity (H'), Evenness (J'), Richness (GR) and modified maturity index (MMI) were found to be effective for assessing the response of soil namatode communities to soil of saline wetland reclamation. Furthermore, saline wetland reclamation also exerted great influence on the soil physical and chemical properties (pH, Electric conductivity (EC), Total organic carbon (TOC), Total nitrogen (Total-N) and Nitrate Nitrogen (N-NO₃^-)). These results indicated that the wetland reclamation had significantly effects on soil nematode community structure and soil properties in this study.

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Reference (57)

[1]	Berkelmans R, Ferris H, Tenuta M et al., 2003. Effects of long-term crop management on nematode trophic levels other than plant feeders disappear after 1 year of disruptive soil management. Applied Soil Ecology, 23(3): 223-235. doi: 10. 1016/S0929-1393(03)00047-7
[2]	Bird A F, 1959. The attractiveness of roots to the plant parasitic nematodes, Meloidogyne javanica and M. hapla. Nematologica, 4(4): 322-335.
[3]	Bloemers G F, Hodda M, Lambshead P J D et al., 1997. The effects of forest disturbance on diversity of tropical soil nematodes. Oecologia, 111(4): 575-582. doi: 10.1007/s00442 0050274
[4]	Bongers T, 1990. The maturity index: an ecological measure of environmental disturbance based on nematode species composition. Oecologia, 83(1): 14-19. doi: 10.1007/BF0032 4627
[5]	Bongers T, Bongers M, 1998. Functional diversity of nematodes., Applied Soil Ecology, 10(3): 239-251. doi: 10.1016/S0929-1393(98)00123-1
[6]	Bongers T, Ferris H, 1999. Nematode community structure as a bioindicator in environmental monitoring. Trends in Ecology & Evolution, 14(6): 224-228. doi: 10.1016/S0169-5347(98) 01583-3
[7]	Coulson S J, Hodkinson I D, Strathdee A T et al., 1995. Thermal environments of arctic soil organisms during winter. Arctic & Alpine Research, 27(4): 364-370. doi: 10.2307/1552029
[8]	Ekschmitt K, Bakonyi G, Bongers M et al., 2001. Nematode community structure as indicator of soil functioning in European grassland soils. European Journal of Soil Biology, 37(4): 263-268. doi: 10.1016/S1164-5563(01)01095-0
[9]	Ettema C H, Bongers T, 1993. Characterization of nematode colonization and succession in disturbed soils using the Maturity Index. Biology & Fertility of Soils, 16(2): 79-85. doi: 10.1007/BF00369407
[10]	Ferris H, Bongers T, de Goede R G M, 2001. A framework for soil food web diagnostics: extension of the nematode faunal analysis concept. Applied Soil Ecology, 18(1): 13-29. doi: 10.1016/S0929-1393(01)00152-4
[11]	Ferris H, Matute M M, 2003. Structural and functional succession in the nematode fauna of a soil food web. Applied Soil Ecology, 23(2): 93-110. doi: 10.1016/S0929-1393(03)00044-1
[12]	Ferris H, Venette R C, Lau S S, 1996. Dynamics of nematode communities in tomatoes grown in conventional and organic farming systems, and their impact on soil fertility. Applied Soil Ecology, 3(2): 161-175. doi: 10.1016/0929-1393(95)00071-2
[13]	Forge T, Simard S, 2001. Structure of nematode communities in forest soils of southern British Columbia: relationship to nitrogen mineralization and effects of clearcut harvesting and fertilization. Biology & Fertility of Soils, 34(3): 170-178. doi: 10.1007/s003740100390
[14]	Freckman D W, 1978. Ecology of anhydrobiotic nematodes. In: Crowe J H et al. (Eds). Dried Biological Systems. New York: Academic Press, 345-357.
[15]	Fu S L, Coleman D C, Hendrix P F et al., 2000. Responses of trophic groups of soil nematodes to residue application under conventional tillage and no-till regimes. Soil Biology and Biochemistry, 32(11-12): 1731-1741. doi: 10.1016/S0038-0717(00)00091-2
[16]	Geraert E, 1965. The genus Paratylenchus. Nematologica, 11(3): 301-334. doi: 10.1163/187529265X00221
[17]	Gordon D C, 1994. Intertidal ecology and potential power impacts, Bay of Fundy. Biological Journal of the Linnean Society, 51(1-2): 17-23. doi: 10.1006/bijl.1994.1003
[18]	Hodson A K, Ferris H, Hollander A D et al., 2014. Nematode food webs associated with native perennial plant species and soil nutrient pools in California riparian oak woodlands. Geoderma, 228(5): 182-191. doi: 10.1016/j.geoderma.2013.07. 021
[19]	Jiang D M, Li Q, Liu F M et al., 2007. Vertical distribution of soil nematodes in an age sequence of Caragana microphylla plantations in the Horqin Sandy Land, Northeast China. Ecology Research, 22(1): 49-56. doi: 10.1007/s11284-006-0187-5
[20]	Kandji S T, Ogol C K P O, Albrecht A, 2001. Diversity of plant-parasitic nematodes and their relationships with some soil physico-chemical characteristics in improved fallows in western Kenya. Applied Soil Ecology, 18(2): 143-157. doi: 10.1016/S0929-1393(01)00157-3
[21]	Kennish M J, 2002. Environmental threats and environmental future of estuaries. Environmental. Conservation, 29(1): 78-107. doi: 10.1017/S0376892902000061
[22]	Li Q, Xu C G, Liang W J et al., 2009. Residue incorporation and N fertilization affect the response of soil nematodes to the elevated CO₂ in a Chinese wheat field. Soil Biology and Biochemistry, 41(7): 1497-1503. doi: 10.1016/j.soilbio.2009. 04.006
[23]	Liang W J, Li Q, Jiang Y et al., 2005. Nematode faunal analysis in an aquic brown soil fertilised with slow-release urea, Northeast China. Applied Soil Ecology, 29(2): 185-192. doi: 10.1016/j.apsoil.2004.10.004
[24]	Liang W J, Lou Y L, Li Q et al., 2009. Nematode faunal response to long-term application of nitrogen fertilizer and organic manure in Northeast China. Soil Biology and Biochemistry, 41(5): 883-890. doi: 10.1016/j.soilbio.2008.06.018
[25]	Liang W J, Zhong S, Hua J F et al., 2007. Nematode faunal response to grassland degradation in Horqin Sandy Land. Pedosphere, 17(5): 611-618. doi: 10.1016/S1002-0160(07) 60072-1
[26]	Mai W F, Harrison M B, 1959. The golden nematode. Cornell Extension Bulletin, 49(sup.): S870.
[27]	Malhi S S, Lemke R, Wang Z H et al., 2006. Tillage, nitrogen and crop residue effects on crop yield, nutrient uptake, soil quality, and greenhouse gas emissions. Soil and Tillage Research, 90(1-2): 171-183. doi: 10.1016/j.still.2005.09.001
[28]	Montemayor M B, Price J S, Rochefort L et al., 2008. Temporal variations and spatial patterns in saline and waterlogged peat fields. Environmental and Experimental Botany, 62(3): 333-342. doi: 10.1016/j.envexpbot.2007.10.004
[29]	Mulvaney R L, 1996. Nitrogen-inorganic. In: Sparks D L (Ed.). Methods of soil Analysis. Part 3. Book Series 5. Madison: Soil Science Society of America.
[30]	Neher D A, Barbercheck M E, Anas O, 2001. Nematodes in wetland soils of North Carolina. Phytopathology, 91(6s): S139.
[31]	Nico E, Tomasz D, Simone C et al., 2013. Plant diversity effects on soil food webs are stronger than those of elevated CO₂ and N deposition in a long-term grassland experiment. Proceedings of the National Academy of Sciences, 110(17): 6689-6694. doi: 10.1073/pnas.1217382110
[32]	Okada H, Ferris H, 2001. Temperature effects on growth and nitrogen mineralization of fungi and fungal-feeding nematodes. Plant and Soil, 234(2): 253-262. doi: 10.1023/A: 1017957929476
[33]	Oostenbrink M, 1960. Estimating nematode populations by some selected methods. In: Sasser J N et al. (Eds.). Nematology. Chapel Hill: University of North Carolina Press.
[34]	Ou W, Liang W J, Jiang Y et al., 2005. Vertical distribution of soil nematodes under different land use types in an aquic brown soil. Pedobiologia, 49(2): 139-148. doi: 10.1016/j.pedobi. 2004.10.001
[35]	Porazinska D L, Duncan L W, McSorley R et al., 1999. Nematode communities as indicators of status and processes of a soil ecosystem influenced by agricultural management practices. Applied Soil Ecology, 13(1): 69-86.
[36]	Rey A, Pegoraro E, Tedeschi V et al., 2008. Annual variation in soil respiration and its components in a coppice oak forest in Central Italy. Global Change Biology, 32(4): 387-392. doi: 10.1046/j.1365-2486.2002.00521.x
[37]	Sainju U M, Singh B P, Whitehead W F et al., 2007. Accumulation and crop uptake of soil mineral nitrogen as influenced by tillage, cover crops, and nitrogen fertilization. Agronomy Journal, 99(3): 682-691.
[38]	Stanislav P, Ginetta B, Yosef S, 2008. Effect of desert plant ecophysiological adaptation on soil nematode communities. European Journal of Soil Biology, 44(3): 298-308. doi: 10.1016/j.ejsobi.2008.03.005
[39]	Sun G, Wu N, Luo P, 2005. Soil N pools and transformation rates under different land uses in a subalpine forest-grassland ecotone. Pedosphere, 15(1): 52-58.
[40]	Townshend J L, 1963. A modification and evaluation of the apparatus for the Oostenbrink direct cottonwool filter extraction method. Nematologica, 7(3): 106-110. doi: 10. 1163/18752 9263X00205
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Effects of Wetland Utilization Change on Spatial Distribution of Soil Nematodes in Heihe River Basin, Northwest China

doi: 10.1007/s11769-016-0813-2

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