Effects of soil fauna on leaf litter decomposition under different land uses in eastern coast of China

Baoling Yang , Wenwen Zhang , Hanmei Xu , Shaojun Wang , Xia Xu , Huan Fan , Han Y. H. Chen , Honghua Ruan

Journal of Forestry Research ›› 2017, Vol. 29 ›› Issue (4) : 973 -982.

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Journal of Forestry Research ›› 2017, Vol. 29 ›› Issue (4) : 973 -982. DOI: 10.1007/s11676-017-0521-5
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Effects of soil fauna on leaf litter decomposition under different land uses in eastern coast of China

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Abstract

Soil fauna decompose litter, whereas land use changes may significantly alter the composition and structure of soil fauna assemblages. However, little is known of the effects of land-use on the contribution of soil fauna to litter decomposition. We studied the impacts of soil fauna on the decomposition of litter from poplar trees under three different land uses (i.e. poplar-crop integrated system, poplar plantation, and cropland), from December 2013 to December 2014, in a coastal area of Northern Jiangsu Province. We collected litter samples in litterbags with three mesh sizes (5, 1 and 0. 01 mm, respectively) to quantify the contribution of various soil fauna to the decomposition of poplar leaf litter. Litter decomposition rates differed significantly by land use and were highest in the cropland, intermediate in the poplar-crop integrated system, and lowest in the poplar plantation. Soil fauna in the poplar-crop integrated system was characterized by the highest numbers of taxa and individuals, and highest Margalef’s diversity, which suggested that agro-forestry ecosystems may support a greater quantity, distribution, and biodiversity of soil fauna than can single-species agriculture or plantation forestry. The individuals and groups of soil fauna in the macro-mesh litterbags were higher than in the meso-mesh litterbags under the same land use types. The average contribution rate of meso- and micro-fauna to litter decomposition was 18.46%, which was higher than the contribution rate of macro-fauna (3.31%). The percentage of remaining litter mass was inversely related to the density of the soil fauna (P < 0.05) in poplar plantations; however, was unrelated in the poplar-crop integrated system and cropland. This may have been the result of anthropogenic interference in poplar-crop integrated systems and croplands. Our study suggested that when land-use change alters vegetation types, it can affect species composition and the structure of soil fauna assemblages, which, in turn, affects litter decomposition.

Keywords

Mesh sizes / Poplar / Leaf litter / Soil fauna / Litter decomposition

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Baoling Yang, Wenwen Zhang, Hanmei Xu, Shaojun Wang, Xia Xu, Huan Fan, Han Y. H. Chen, Honghua Ruan. Effects of soil fauna on leaf litter decomposition under different land uses in eastern coast of China. Journal of Forestry Research, 2017, 29(4): 973-982 DOI:10.1007/s11676-017-0521-5

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Ammer S, Weber K, Abs C, Ammer C, Prietzel J. Factors influencing the distribution and abundance of earthworm communities in pure and converted Scots pine stands. Appl Soil Ecol, 2006, 33: 10-21.

[2]

Bao J, Yin X, Li X. Study on the contribution of soil fauna to litter decomposition of Rhododendron chrysanthum in the Changbai Mountains. Acta Ecol Sin, 2015, 35: 1-12.
[3]

Bokhorst S, Wardle DA. Microclimate within litter bags of different mesh size: implications for the ‘arthropod effect’ on litter decomposition. Soil Biol Biochem, 2013, 58: 147-152.

[4]

Bradford MA, Tordoff GT, Jones TH, Newington JE. Microbiota, fauna, and mesh size interactions in litter decomposition. Oikos, 2002, 99: 317-323.

[5]

Cao Z. Soil ecology, 2007, Beijing: Chemical Industry Press.
[6]

Chauvel A, Grimaldi M, Barros E, Blanchart E, Desjardins T, Sarrazin M, Lavelle P. Pasture damage by an Amazonian earthworm. Nature, 1999, 398: 32-33.

[7]

Chen XL, Ju Q, Lin KL. Development status, issues and countermeasures of China's plantation. World For Res, 2014, 27: 54-59.
[8]

Cutzpool LQ, Palaciosvargas JG, CastañOmeneses G, GarcíAcalderón NE. Edaphic Collembola from two agroecosystems with contrasting irrigation type in Hidalgo State, Mexico. Appl Soil Ecol, 2007, 36: 46-52.

[9]

David T, Peter BR, Forest I. Biodiversity impacts ecosystem productivity as much as resources, disturbance or herbivory. Proc Natl Acad Sci, 2012, 109: 10394-10397.

[10]

De Deyn GB, Raaijmakers CE, Zoomer HR, Berg MP, de Ruiter PC, Verhoef HA, Martijn BT, Van der Putten WH. Soil invertebrate fauna enhances grassland succession and diversity. Nature, 2003, 422: 711-713.

[11]

Deng X, Zou S, Fu X, Yao T, Sheng C, Bai Z. The impacts of land use practices on the communities of soil fauna in the Xishuangbanna rain forest, Yunnan, China. Acta Ecol Sin, 2003, 23: 130-138.
[12]

Ekschmitta K, Liu M, Vettera S, Foxa O, Woltersa V. Strategies used by soil biota to overcome soil organic matter stability—why is dead organic matter left over in the soil?. Geoderma, 2005, 128: 167-176.

[13]

Emmerling C. Long-term effects of inundation dynamics and agricultural land-use on the distribution of soil macrofauna in fluvisols. Biol Fertil Soils, 1995, 20: 130-136.

[14]

Fan H, Wang S, Ruan H, Tan Y, Zheng A, Xu Y, Xu K, Cao G. Effects of soil fauna on litter decomposition and its community structure under different land use patterns in coastal region of northern Jiangsu province. J Nanjing For Univ (Natl Sci Ed), 2014, 38: 1-7.
[15]

Franklin E, Magnusson WE, Luizão FJ. Relative effects of biotic and abiotic factors on the composition of soil invertebrate communities in an Amazonian savanna. Appl Soil Ecol, 2005, 29: 259-273.

[16]

Galizzi MC, Zilli F, Marchese M. Diet and functional feeding groups of Chironomidae (Diptera) in the Middle Paraná River floodplain (Argentina). Iheringia Série Zoologia, 2012, 102: 117-121.

[17]

Ge B, Zhang D, Zhang H, Li Z, Liu Z, Zhou C, Tang B. Community structure and functional groups of soil macrofauna in urban green spaces of Yancheng city, Jiangsu province in spring. Chin J Ecol, 2012, 31: 87-92.
[18]

Geissen V, Peña-Peña K, Huerta E. Effects of different land use on soil chemical properties, decomposition rate and earthworm communities in tropical Mexico. Pedobiologia, 2009, 53: 75-86.

[19]

Hati KM, Swarup A, Dwivedi AK, Misra AK, Bandyopadhyay KK. Changes in soil physical properties and organic carbon status at the topsoil horizon of a vertisol of central India after 28 years of continuous cropping, fertilization and manuring. Agric Ecosyst Environ, 2007, 119: 127-134.

[20]

He R, Chen Y, Deng C, Yang W, Zhang J, Liu Y. Seasonal responses of the soil meso- and microfauna to litter decomposition in alpine meadow of western Sichuan. Chin J Appl Environ Biol, 2015, 21: 350-357.
[21]

He R, Chen Y, Deng C, Yang W, Zhang J, Liu Y. Litter decomposition and soil faunal diversity of two understory plant debris in the alpine timberline ecotone of western Sichuan in a snow cover season. Chin J Appl Ecol, 2015, 26: 723-731.
[22]

Hunter MD, Adl S, Pringle CM, Coleman DC. Relative effects of macroinvertebrates and habitat on the chemistry of litter during decomposition. Pedobiologia, 2003, 47: 101-115.

[23]

Illig J, Norton RA, Scheu S, Maraun M. Density and community structure of soil- and bark-dwelling microarthropods along an altitudinal gradient in a tropical montane rainforest. Exp Appl Acarol, 2010, 52: 49-62.

[24]

Irmler U. Changes in the fauna and its contribution to mass loss and N release during leaf litter decomposition in two deciduous forests. Pedobiologia, 2000, 44: 105-118.

[25]

Jaccard P. Nouvelles recherches sur la distribution florale. Bulletin De La Societe Vaudoise Des Sciences Naturelles, 1908, 44: 223-270.
[26]

Joo SJ, Yim MH, Nakane K. Contribution of microarthropods to the decomposition of needle litter in a Japanese cedar (Cryptomeria japonica D. Don) plantation. For Ecol Manage, 2006, 234: 192-198.

[27]

Koehler H, Born H. The influence of vegetation structure on the development of soil mesofauna. Agric Ecosyst Environ, 1989, 27: 253-269.

[28]

Lavelle P. Functional domains in soils. Ecol Res, 2002, 17: 441-450.

[29]

Li J, Zhang W, Liao C, Yang Y, Fu S. Responses of earthworms to organic matter at different stages of decomposition. Pedosphere, 2009, 19: 382-388.

[30]

Li Y, Luo C, Yang W, Hu J, Wu F. Decomposition of eucalyptus-alder mixed litters and dynamics of soil faunal community. Chin J Appl Ecol, 2011, 22: 851-856.
[31]

Liang W, Lou Y, Li Q, Zhong S, Zhang X, Wang J. Nematode faunal response to long-term application of nitrogen fertilizer and organic manure in Northeast China. Soil Biol Biochem, 2009, 41: 883-890.

[32]

Lin B, Liu Q, Wu Y, He H. Advances in the studies of forest litter. Chin J Ecol, 2004, 23: 60-64.
[33]

Lin Y, Zhang F, Liu H, Su H. Fluctuation of soil fauna community in Baiwangshen during paper Mulberry leaf litter decomposition. Chin J Zool, 2005, 40: 60-66.
[34]

Lin G, Zhao F, Chen G, Chen S, Su J, Zhang T. Effects of different land-use types on larger-size soil animal communities in the northern region of Qinghai Lake. Acta Prataculturae Sin, 2012, 21: 180-186.
[35]

Liu Q, Yin H, Cheng X, Lin B, Hu R, Zhao C, Yin C. Problems and strategies of sustainable regeneration of plantation ecosystem in China. World For Res, 2010, 23: 71-75.
[36]

Liu Y, Zhang A, Yan Y, Li K, Fang Y. Diversity of soil animal community under different land-use types in Chongming Island. J Fudan Univy (Natl Sci), 2011, 50: 288-295.
[37]

Liu R, Li W, Yang W, Tan B, Wang W, Xu Z, Wu F. Contributions of soil fauna to litter decomposition in alpine/subalpine forests. Chin J Appl Ecol, 2013, 24: 3354-3360.
[38]

Mando A, Ouattara B, Sédogo M, Stroosnijder L, Ouattara K, Brussaard L, Vanlauwe B. Long-term effect of tillage and manure application on soil organic fractions and crop performance under Sudano-Sahelian conditions. Soil Tillage Res, 2005, 80: 95-101.

[39]

Maraun M, Scheu S. Changes in microbial biomass, respiration and nutrient status of beech (Fagus sylvatica) leaf litter processed by millipedes (Glomeris marginata). Oecologia, 1996, 107: 131-140.

[40]

Margalef DR. Information theory in ecology. Gen Syst, 1958, 3: 36-71.
[41]

Moore JC, Berlow EL, Coleman DC, Ruiter PCD, Dong Q, Alan H, Collins JN, Mccann KS, Kim M, Morin PJ. Detritus, trophic dynamics and biodiversity. Ecol Lett, 2004, 7: 584-600.

[42]

Pielou EC. The measurement of diversity in different types of biological collection. J Theor Biol, 1967, 15: 131-144.

[43]

Read DJ, Perez-Moreno J. Mycorrhizas and nutrient cycling in ecosystems—A journey towards relevance?. New Phytol, 2003, 157: 475-492.

[44]

Ruan H, Li Y, Zou X. Soil communities and plant litter decomposition as influenced by forest debris: variation across tropical riparian and upland sites. Pedobiologia, 2005, 49: 529-538.

[45]

Seastedt TR. The role of microarthropods in decomposition and mineralization processes. Annu Rev Entomol, 1984, 29: 25-46.

[46]

Shannon CE. A mathematical theory of communication. Bell Syst Tech J, 1948, 27: 379-423.

[47]

Simpson EH. Measurement of diversity. Nature, 1949, 163: 688.

[48]

Swift MJ, Heal OW, Anderson JM. Decomposition in terrestial ecosystems. Decompos Terr Ecosyst, 1979, 5: 607-612.
[49]

Wall DH, Bradford MA, John MGS, Trofymow JA, Behan-Pelletier V, Bignell DE, Dangerfield JM, Parton WJ, Rusek J, Voigt W. Global decomposition experiment shows soil animal impacts on decomposition are climate-dependent. Glob Change Biol, 2008, 14: 2661-2677.
[50]

Wang G, Wang Y, Han L, Zhang M, Li B. Soil animal communities of variously utilized in the Dongting Lake region. Acta Ecol Sin, 2005, 25: 2629-2636.
[51]

Wang S, Ruan H, Wang B. Effects of soil microarthropods on plant litter decomposition across an elevation gradient in the Wuyi Mountains. Soil Biol Biochem, 2009, 41: 891-897.

[52]

Wang S, Ruan H, Han Y. Effects of microclimate, litter type, and mesh size on leaf litter decomposition along an elevation gradient in the Wuyi Mountains, China. Ecol Res, 2010, 25: 1113-1120.

[53]

Wang X, Yin X, Song B, Xin W, Li B, Ma H. Main species litter decomposition and function of soil fauna in Leymus chinensis grassland. Acta Prataculturae Sin, 2011, 20: 143-149.
[54]

Wang W, Yang W, Tan B, Liu R, Wu F. Effects of soil fauna to nitrogen and phosphorus releases during litter decomposition at different phenological stages in the subtropical evergreen broad-leaved forest in Sichuan Basin. Scientia Silvae Sinicae, 2015, 51: 1-11.
[55]

Wei X, Hao M, Shao M, Gale WJ. Changes in soil properties and the availability of soil micronutrients after 18 years of cropping and fertilization. Soil Tillage Res, 2006, 91: 120-130.

[56]

Wood CT, Schlindwein CCD, Soares GLG, Araujo PB. Feeding rates of Balloniscus sellowii (Crustacea, Isopoda, Oniscidea): the effect of leaf litter decomposition and its relation to the phenolic and flavonoid content. Zookeys, 2012, 24: 231-245.

[57]

Wu T. Effects of global change on soil fauna diversity: a review. Chin J Appl Ecol, 2013, 24: 581-588.
[58]

Wu D, Zhang B, Chen P. Community structure and composition of soil macrofauna under different land use in Changchun City. Acta Zool Sin, 2006, 52: 279-287.
[59]

Wu Y, Cai Q, Lin C, Huang J, Cheng X. Effects of terrace hedgerows on soil macrofauna diversity. Acta Ecol Sin, 2009, 29: 5320-5329.

[60]

Wu F, Yang W, Zhang J, Deng R. Litter decomposition in two subalpine forests during the freeze–thaw season. Acta Oecol, 2010, 36: 135-140.

[61]

Xia L, Wu F, Yang W, Tan B. Contribution of soil fauna to the mass loss of Betula albosinensis leaf litter at early decomposition stage of subalpine forest litter in western Sichuan. Chin J Appl Ecol, 2012, 23: 301-306.
[62]

Xu G, Kuster TM, Günthardt-Goerg MS, Matthias D, Li M. Seasonal exposure to drought and air warming affects soil Collembola and mites. PLoS ONE, 2012, 7: 1-9.

[63]

Xuluc-Tolosa FJ, Vester HFM, Ramĺrez-Marcial N, Castellanos-Albores J, Lawrence D. Leaf litter decomposition of tree species in three successional phases of tropical dry secondary forest in Campeche, Mexico. For Ecol Manag, 2003, 174: 401-412.

[64]

Yang X, Zou X. Soil Fauna and leaf litter decomposition in tropical rain forest in XiShuangBanNa, SW China: effects of Mesh Size of Litterbags. J Plant Ecol, 2006, 30: 791-801.

[65]

Yang X, Chen J. Plant litter quality influences the contribution of soil fauna to litter decomposition in humid tropical forests, southwestern China. Soil Biol Biochem, 2009, 41: 910-918.

[66]

Yin W, Hu S, Shen Y. Pictorial keys to soil animals of China, 1998, Beijing: Science Press.
[67]

Yin X, Zhong W, Wang H, Chen P. Decomposition of forest defoliation and role of soil animals in Xiao Hinggan Mountains. Geogr Res, 2002, 21: 689-699.
[68]

Yin X, Song B, Dong W, Xin W, Wang Y. A review on the eco-geography of soil fauna in China. J Geogr Sci, 2010, 20: 333-346.

[69]

Yu Q, Wu J, Liang D, Zhang J, Li Z, Zhang S. Effects of flooding condition and mesh size on leaf litter decomposition of the dominant species, Carex atrofusca, in an alpine swamp meadow in Tibetan Plateau. Chin J Ecol, 2015, 34: 2785-2791.
[70]

Zhang J, Qin Z, Li Q. Clustering and ordination of soil animal community under different land-use types. Chin J Ecol, 2011, 30: 2849-2856.
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