Rhizosphere and bulk soil enzyme activities in a Nothotsuga longibracteata forest in the Tianbaoyan National Nature Reserve, Fujian Province, China

Shihong Xiao; Huiming You; Weibin You; Jinshan Liu; Changtang Cai; Jianqin Wu; Zhirong Ji; Shihua Zhan; Zhesen Hu; Zhongrui Zhang; Dongjin He

doi:10.1007/s11676-016-0334-y

Journal of Forestry Research ›› 2016, Vol. 28 ›› Issue (3) : 521 -528. DOI: 10.1007/s11676-016-0334-y

Original Paper

Rhizosphere and bulk soil enzyme activities in a Nothotsuga longibracteata forest in the Tianbaoyan National Nature Reserve, Fujian Province, China

Author information +

History +

PDF

Abstract

The rhizosphere, distinct from bulk soil, is defined as the volume of soil around living roots and influenced by root activities. We investigated protease, invertase, cellulase, urease, and acid phosphatase activities in rhizosphere and bulk soils of six Nothotsuga longibracteata forest communities within Tianbaoyan National Nature Reserve, including N. longibracteata + either Phyllostachys pubescens, Schima superba, Rhododendron simiarum, Cunninghamia lanceolata, or Cyclobalanopsis glauca, and N. longibracteata pure forest. Rhizosphere soils possessed higher protease, invertase, cellulase, urease, and acid phosphatase activities than bulk soils. The highest invertase, urease, and acid phosphatase activities were observed in rhizosphere samples of N. longibracteata + S. superba. Protease was highest in the N. longibracteata + R. simiarum rhizosphere, while cellulase was highest in the pure N. longibracteata forest rhizosphere. All samples exhibited obvious rhizosphere effects on enzyme activities with a significant linear correlation between acid phosphatase and cellulase activities (p < 0.05) in rhizosphere soils and between protease and acid phosphatase activities (p < 0.05) in bulk soils. A principal component analysis, correlating 13 soil chemical properties indices relevant to enzyme activities, showed that protease, invertase, acid phosphatase, total N, and cellulase were the most important variables impacting rhizosphere soil quality.

Keywords

Bulk soil / Enzyme activities / Rhizosphere soil / Tianbaoyan National Nature Reserve / Nothotsuga longibracteata

Cite this article

Download citation ▾

Shihong Xiao, Huiming You, Weibin You, Jinshan Liu, Changtang Cai, Jianqin Wu, Zhirong Ji, Shihua Zhan, Zhesen Hu, Zhongrui Zhang, Dongjin He. Rhizosphere and bulk soil enzyme activities in a Nothotsuga longibracteata forest in the Tianbaoyan National Nature Reserve, Fujian Province, China. Journal of Forestry Research, 2016, 28(3): 521-528 DOI:10.1007/s11676-016-0334-y

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Albiach R, Canet R, Pomares F, Ingelmo F. Microbial biomass content and enzymatic activities after the application of organic amendments to a horticultural soil. Bioresour Technol, 2000, 75(1): 43-48.

[2]	Alvarez S, Guerrero MC. Enzymatic activities associated with decomposition of particulate organic matter in two shallow ponds. Soil Biol Biochem, 2000, 32(13): 1941-1951.

[3]	Aon MA, Colaneri AC. Temporal and spatial evolution of enzymatic activities and physico-chemical properties in an agricultural soil. Appl Soil Ecol, 2001, 18(3): 255-270.

[4]	Aon MA, Cabello MN, Sarena DE, Colaneria AC, Francoa MG, Burgosa JL, Cortassa S. I. Spatio-temporal patterns of soil microbial and enzymatic activities in an agricultural soil. Appl Soil Ecol, 2001, 18(3): 239-254.

[5]	Bastida F, Moreno JL, Hernández T, García C. Microbiological degradation index of soils in a semiarid climate. Soil Biol Biochem, 2006, 38(12): 3463-3473.

[6]	Bell C, Carrillo Y, Boot CM, Rocca JD, Pendall E, Wallenstein MD. Rhizosphere stoichiometry: are C:N:P ratios of plants, soils, and enzymes conserved at the plant species-level?. New Phytol, 2014, 201(2): 505-517.

[7]	Böhme L, Langer U, Böhme F. Microbial biomass, enzyme activities and microbial community structure in two European long-term field experiments. Agr Ecosyst Environ, 2005, 109(1–2): 141-152.

[8]	Buée M, Boer WD, Martin F, van Overbeek L, Jurkevitch E. The rhizosphere zoo: an overview of plant-associated communities of microorganisms, including phages, bacteria, archaea, and fungi, and of some of their structuring factors. Plant Soil, 2009, 321(1–2): 189-212.

[9]	Burke DJ, Smemo KA, López-Gutiérrez JC, Hewins CR. Soil enzyme activity in an old-growth northern hardwood forest: interactions between soil environment, ectomycorrhizal fungi and plant distribution. Pedobiologia, 2012, 55(6): 357-364.

[10]	De Graaff M, Classen AT, Castro HF, Schadt CW. Labile soil carbon inputs mediate the soil microbial community composition and plant residue decomposition rates. New Phytol, 2010, 188(4): 1055-1064.

[11]	Fioretto A, Papa S, Sorrentino G, Fuggi A. Decomposition of Cistus incanus leaf litter in a Mediterranean maquis ecosystem: mass loss, microbial enzyme activities and nutrient changes. Soil Biol Biochem, 2001, 33(3): 311-321.

[12]	Garcia C, Roldan A, Hernandez T. Ability of different plant species to promote microbiological processes in semiarid soil. Geoderma, 2005, 124(1–2): 193-202.

[13]	Ge Y, Zhang CB, Jiang YP, Yue CL, Jiang QS, Min H, Fan HT, Zeng Q, Chang J. Soil microbial abundances and enzyme activities in different rhizospheres in an integrated vertical flow constructed Wetland. CLEAN Soil Air Water, 2011, 39(3): 206-211.

[14]	Imamura A, Yumoto T, Yanai J. Urease activity in soil as a factor affecting the succession of ammonia fungi. J For Res, 2006, 11(2): 131-135.

[15]	Jin K, Sleutel S, Buchan D, De Neve S, Cai DX, Gabriels D, Jin JY. Changes of soil enzyme activities under different tillage practices in the Chinese loess plateau. Soil Till Res, 2009, 104(1): 115-120.

[16]	Johansson E, Krantz-Rülcker C, Zhang BX, Öberg G. Chlorination and biodegradation of lignin. Soil Biol Biochem, 2000, 32(7): 1029-1032.

[17]

Kaiser C, Koranda M, Kitzler B, FuchsluegerL Schnecker J, Schweiger P, Rasche F, Zechmeister-Boltenstern S, Sessitsch A, Richter A. Belowground carbon allocation by trees drives seasonal patterns of extracellular enzyme activities by altering microbial community composition in a beech forest soil. New Phytol, 2010, 187(3): 843-858.

[18]	Kardol P, Campany CE, Souza L, Norby RJ, Weltzin JF, Classen AT. Climate change effects on plant biomass alter dominance patterns and community evenness in an experimental old-field ecosystem. Glob Change Biol, 2010, 16(10): 2676-2687.

[19]	Marschner P, Grierson PF, Rengel Z. Microbial community composition and functioning in the rhizosphere of three Banksia species in native woodland in Western Australia. Appl Soil Ecol, 2005, 28(3): 191-201.

[20]	Monreal CM, Bergstrom DW. Soil enzymatic factors expressing the influence of land use, tillage system and texture on soil biochemical quality. Can J Soil Sci, 2000, 80(3): 419-428.

[21]	Nausch M, Nausch G. Stimulation of peptidase activity in nutrient gradients in the Baltic Sea. Soil Biol Biochem, 2000, 32(13): 1973-1983.

[22]	Orwin KH, Buckland SM, Johnson D, Turner BL, Smart S, Oakley S, Bardgett RD. Linkages of plant traits to soil properties and the functioning of temperate grassland. J Ecol, 2010, 98(5): 1074-1083.

[23]	Phillips RP, Fahey TJ. The influence of soil fertility on rhizosphere effects in northern hardwood forest soils. Soil Sci Soc Am J, 2008, 72(2): 453-461.

[24]	Puglisi E, Del Re AAM, Rao MA, Gianfreda L. Development and validation of numerical indexes integrating enzyme activities of soils. Soil Biol Biochem, 2006, 38(7): 1673-1681.

[25]	Qiu YJ, Liu YF, Kang M, Yi GM, Huang HW. Spatial and temporal population genetic variation and structure of Nothotsuga longibracteata (Pinaceae), a relic conifer species endemic to subtropical China. Genet Mol Biol, 2013, 36(4): 598-607.

[26]	Sanaullah M, Blagodatskaya E, Chabbi A, Rumpel C, Kuzyakov Y. Drought effects on microbial biomass and enzyme activities in the rhizosphere of grasses depend on plant community composition. Appl Soil Ecol, 2011, 48(1): 38-44.

[27]	Sinsabaugh RL, Hill BH, Follstad Shah JJ. Ecoenzymatic stoichiometry of microbial organic nutrient acquisition in soil and sediment. Nature, 2009, 462(10): 795-798.

[28]	Tscherko D, Hammesfahr U, Marx MC, Kandeler E. Shifts in rhizosphere microbial communities and enzyme activity of Poa alpina across an alpine chronosequence. Soil Biol Biochem, 2004, 36(10): 1685-1698.

[29]	Wang AS, Angle JS, Chaney RL, Delorme TA, Mcintosh M. Changes in soil biological activities under reduced soil pH during Thlaspi caerulescens phytoextraction. Soil Biol Biochem, 2006, 38(6): 1451-1461.

[30]	Xiao SH, He DJ, You HM, Liu JS, Cai CT. Storage of coarse woody debris in three typical forests in Tianbaoyan National Nature Reserve, Fujian Province of eastern China. J Beijing For Univ, 2012, 34(5): 64-68. (In Chinese)

[31]	You HM, He DJ, Cai CT, Liu JS, Hong W, You WB, Wang L, Xiao SH, Hu J, Zheng XY. Assessment on effect of fallen woods on soil fertility in Tsuga longibracteata forest in Tianbaoyan National Nature Reserve. Chin J Appl Environ Biol, 2013, 19(1): 168-174. In Chinese)

[32]	You HM, He DJ, Liu JS, Cai CT, You WB, Xiao SH. Effect of covering with fallen logs on soil physicochemical property of Tsuga longibracteata forest in Tianbaoyan National Nature Reserve. J Plant Resour Environ, 2013, 22(3): 18-24. (In Chinese)

[33]	You HM, He DJ, You WB, Liu JS, Cai CT. Effect of environmental gradients on the quantity and quality of fallen logs in Tsuga longibracteata forest in Tianbaoyan National Nature Reserve, Fujian province, China. J Mount Sci, 2013, 10(6): 1118-1124.

[34]	Yuan L, Huang JG, Yu SQ. Responses of nitrogen and related enzyme activities to fertilization in rhizosphere of wheat. Pedosphere, 1997, 7(2): 141-148.

[35]	Zhang YM, Wu N, Zhou GY, Bao WK. Changes in enzyme activities of spruce (Picea balfouriana) forest soil as related to burning in the eastern Qinghai-Tibetan Plateau. Appl Soil Ecol, 2005, 30(3): 215-225.

[36]	Zhang C, Liu GB, Xue S, Song ZL. Rhizosphere soil microbial activity under different vegetation types on the Loess Plateau, China. Geoderma, 2011, 161(3–4): 115-125.

[37]	Zhang C, Liu GB, Xue S, Zhang CS. Rhizosphere soil microbial properties on abandoned croplands in the Loess Plateau, China during vegetation succession. Eur J Soil Biol, 2012, 50: 127-136.

[38]	Zhang L, Song L, Shao H, Shao H, Shao C, Li M, Liu M, Brestic M, Xu G. Spatio-temporal variation of rhizosphere soil microbial abundance and enzyme activities under different vegetation types in the coastal zone, Shandong, china. Plant Biosyst, 2013, 148(3): 403-409.