[1]ZHANG Peng,WANG Guoliang.Changes of Soil Enzyme in Robinia pseudoacacia Forest Along Environmental Gradient on the Loess Plateau[J].Research of Soil and Water Conservation,2020,27(01):161-167.
Copy
Changes of Soil Enzyme in Robinia pseudoacacia Forest Along Environmental Gradient on the Loess Plateau
Research of Soil and Water Conservation[ISSN 1005-3409/CN 61-1272/P] Volume:
27
Number of periods:
2020 01
Page number:
161-167
Column:
Public date:
2020-02-20
- Title:
- Changes of Soil Enzyme in Robinia pseudoacacia Forest Along Environmental Gradient on the Loess Plateau
- CLC:
- S718.5
- DOI:
- -
- Abstract:
- Soil enzymes play an important role in the material cycling, information exchange and energy flow of underground ecosystems, and are one of the hotspots of current ecology research. However, the mechanism of soil enzymes change along environmental gradient is still unclear. Therefore, Robinia pseudoacacia Forests in four areas(Chunhua, Ansai, Suide and Shenmu)from the north to the south of the Loess Plateau were selected as the research samples. Soil nutrients, microbial biomass and enzyme activities were measured, and the relationship between enzyme activity and its stoichiometry, climate, soil nutrients and microbial biomass were analyzed. The results showed that:(1)from north to south, the activities of beta-1,4-glucosidase(BG), beta-N-acetylglucosaminidase(NAG), leucine aminopeptidase(LAP)and alkaline phosphatase(AP)were 28.72~110.66, 1.60~3.32, 6.84~10.25 and 14.17~32.60 nmol/(g·h), respectively; LAP showed an increasing trend; BG, NAG and AP increased at first, then decreased and then increased;(2)microbial biomass carbon(MBC), microbial biomass nitrogen(MBN)and microbial biomass phosphorus(MBP)ranged between 23.08~95.04 mg/kg, 2.86~7.95 mg/kg and 0.53~0.92 mg/kg, respectively;(3)BG/(LAP+NAG), BG/AP,(LAP+NAG)/AP were between 3.15~6.46, 1.5~2.96 and 0.41~0.70, respectively; BG/(LAP+NAG)decreased at first, then increased, which was the highest in Chunhua; BG/AP decreased at first, then increased, which was the highest in Shenmu; and(LAP+NAG)/AP showed a continuous decreasing trend;(4)through redundancy analysis, the total explanatory rate of environmental factors to soil enzymes and microbial biomass reached up to 57.36%; among them, the annual average rainfall and N/P had the greatest influence and positive correlation, explaining rates were 36.60% and 14.80%, respectively; the total explanatory rate of environmental factors to soil enzymes and microbial quantification was 72.18%, soil available phosphorus had the greatest impact on soil total nitrogen, and had a positive correlation, the interpretation rates were 30.5% and 19.1%, respectively; microbial community is relatively stable, and there is no significant relationship between microbial quantification and soil nutrient differentiation, soil enzymatic stoichiometric ratio is not stable along the environmental gradient and depends on the stoichiometric ratio of available nutrients and soil nutrient differentiation.
- References:
-
[1] Li G, Kim S, Han S H, et al. Precipitation affects soil microbial and extracellular enzymatic responses to warming[J]. Soil Biology and Biochemistry, 2018,120:212-221.
[2] Allison S D, Weintraub M N, Gartner T B, et al. Evolutionary-economic principles as regulators of soil enzyme production and ecosystem function[J]. Soil Enzymology, 2010,22:229-243.
[3] Paul K, Melissa A C, Courtney E C, et al. Soil ecosystem functioning under climate change: plant species and community effects[J]. Ecology, 2010,91(3):767-781.
[4] 王理德,王方琳,郭春秀,等.土壤酶学硏究进展[J].土壤,2016,48(1):12-21.
[5] Wenxuan H, Jingyun F, Dali G, et al. Leaf nitrogen and phosphorus stoichiometry across 753 terrestrial plant species in China[J]. The New Phytologist, 2005,168(2):377-385.
[6] 曾冬萍,蒋利玲,曾从盛,等.生态化学计量学特征及其应用研究进展[J].生态学报,2013,33(18):5484-5492.
[7] Jonathan W L, Stuart E J, Suzanne M P, et al. Consistent responses of soil microbial communities to elevated nutrient inputs in grasslands across the globe[J]. Proceedings of the National Academy of Sciences of the United States of America, 2015,112(35):10967-10972.
[8] Sinsabaugh R L, Lauber C L, Weintraub M N, et al. Stoichiometry of soil enzyme activity at global scale[J]. Ecology Letters, 2008,11(11):1252-1264.
[9] Peng X, Wang W. Stoichiometry of soil extracellular enzyme activity along a climatic transect in temperate grasslands of northern China[J]. Soil Biology and Biochemistry, 2016,98:74-84.
[10] Zhang W, Xu Y, Gao D, et al. Ecoenzymatic stoichiometry and nutrient dynamics along a revegetation chronosequence in the soils of abandoned land and Robinia pseudoacacia plantation on the Loess Plateau, China[J]. Soil Biology and Biochemistry, 2019,134:1-14.
[11] Brockett B F T, Prescott C E, Grayston S J. Soil moisture is the major factor influencing microbial community structure and enzyme activities across seven biogeoclimatic zones in western Canada[J]. Soil Biology and Biochemistry, 2012,44(1):9-20.
[12] Seneviratne G. Signal transduction in edaphic ecosystems governs sustainability[J]. Agriculture Ecosystems & Environment, 2015,210(30):47-49.
[13] Singh J S, Gupta V K. Soil microbial biomass: A key soil driver in management of ecosystem functioning[J]. Science of the Total Environment, 2018,634:497-500.
[14] Thakur M P, Milcu A, Manning P, et al. Plant diversity drives soil microbial biomass carbon in grasslands irrespective of global environmental change factors[J]. Glob Chang Biol, 2015,21(11):4076-4085.
[15] Schindler D E. Ecological Stoichiometry: The Biology of elements from molecules to the biosphere[J]. Quarterly Review of Biology, 2003,78(4):501.
[16] Lu N, Liski J, Chang R Y, et al. Soil organic carbon dynamics of black locust plantations in the middle Loess Plateau area of China[J]. Biogeosciences, 2013,10(11):7053-7063.
[17] Soriano A U, Martins L F, Santos De Assump??o Ventura E, et al. Microbiological aspects of biodiesel and biodiesel/diesel blends biodeterioration[J]. International Biodeterioration & Biodegradation, 2015,99:102-114.
[18] Saiya-Cork K R, Sinsabaugh R L, Zak D R. The effects of long term nitrogen deposition on extracellular enzyme activity in an Acer saccharum forest soil[J]. Soil Biology and Biochemistry, 2002,34(9):1309-1315.
[19] Zhang W, Xu Y, Gao D, et al. Ecoenzymatic stoichiometry and nutrient dynamics along a revegetation chronosequence in the soils of abandoned land and Robinia pseudoacacia plantation on the Loess Plateau, China[J]. Soil Biology and Biochemistry, 2019,134:1-14.
[20] Du Y, Niu W, Zhang Q, et al. Effects of nitrogen on soil microbial abundance, enzyme activity, and nitrogen use efficiency in greenhouse celery under aerated irrigation[J]. Soil Science Society of America Journal, 2018,82(3):606-613.
[21] Waring B G, Weintraub S R, Sinsabaugh R L. Ecoenzymatic stoichiometry of microbial nutrient acquisition in tropical soils[J]. Biogeochemistry, 2014,117(1):101-113.
[22] Kivlin S N, Treseder K K. Soil extracellular enzyme activities correspond with abiotic factors more than fungal community composition[J]. Biogeochemistry, 2014,117(1):23-37.
[23] 许淼平,任成杰,张伟,等.土壤微生物生物量碳氮磷与土壤酶化学计量对气候变化的响应机制[J].应用生态学报,2018,29(7):2445-2454.
[24] Burns R G, DeForest J L, Marxsen J, et al. Soil enzymes in a changing environment: Current knowledge and future directions[J]. Soil Biology and Biochemistry, 2013,58:216-234.
[25] Luo L, Meng H, Gu J. Microbial extracellular enzymes in biogeochemical cycling of ecosystems[J]. Journal of Environmental Management, 2017,197:539-549.
[26] Xiao W, Chen X, Jing X, et al. A meta-analysis of soil extracellular enzyme activities in response to global change[J]. Soil Biology and Biochemistry, 2018,123:21-32.
- Similar References:
Memo
-
Last Update:
2020-02-25