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[1]李欢,魏雅丽,闫帮国,等.干热河谷土壤酶活性和车轴草生长对氮磷添加的响应[J].水土保持研究,2022,29(04):89-94.
　LI Huan,WEI Yali,YAN Bangguo,et al.Response of Soil Enzyme Activities and Trifolium repens L. Growth to Nitrogen and Phosphorus Addition in Dry and Hot Valley[J].Research of Soil and Water Conservation,2022,29(04):89-94.

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干热河谷土壤酶活性和车轴草生长对氮磷添加的响应

《水土保持研究》[ISSN:1005-3409/CN:61-1272/P] 卷: 29 期数: 2022年04期页码: 89-94 栏目: 出版日期: 2022-06-20

Title:: Response of Soil Enzyme Activities and Trifolium repens L. Growth to Nitrogen and Phosphorus Addition in Dry and Hot Valley

文章编号:: 1005-3409(2022)04-0089-06

作者:: 李欢^1,2, 魏雅丽¹, 闫帮国², 孙毅², 和润莲², 李义林², 方海东²; (1.四川农业大学资源学院, 成都 611130; 2.云南省农业科学院热区生态农业研究所, 云南元谋 651300)

Author(s):: LI Huan^1,2, WEI Yali¹, YAN Bangguo², SUN Yi², HE Runlian², LI Yilin², FANG Haidong²; (1.College of Resources, Sichuan Agricultural University, Chengdu 611130, China; 2.Institute of Tropical Eco-agriculture, Yunan Academy of Agricultural Sciences, Yuanmou, Yunnan 651300, China)

关键词:: 干热河谷; 土地利用类型; 氮磷养分限制; 土壤酶活性; 车轴草

Keywords:: dry hot valley; land use types; limitation of nitrogen and phosphorus; soil enzyme activities; Trifolium repens L.

分类号:: S154

文献标志码:: A

摘要:: 为了探讨干热河谷地区不同土地利用类型下土壤酶活性和植物生长对氮磷添加的响应以及二者之间的联系,采集了元谋干热河谷6种不同土地利用类型土壤,包括灌丛、草地、森林、新开垦农田(新农)、常年耕作农田(常农)、侵蚀裸地(裸地),并利用盆栽探索了土壤酶活性和车轴草(Trifolium repens L.)生长对氮(N)、磷(P)、氮磷(N+P)处理的响应特征。结果表明:(1)植物生物量受土地利用类型和处理双重因素影响,两者的交互作用对植物生物量具有显著作用。(2)除农田土壤(新农和常农)外,其他土地利用类型的土壤上植物生长受到养分添加的显著影响,其中添加P处理的生物量显著高于对照; 而N+P处理又显著高于单一的P添加; 而新农和常农不同养分处理间植物生物量差异不显著。(3)土壤酶活性受土地利用类型显著影响,但是不同养分添加处理之间土壤酶活性差异不显著; 土壤酶活性与植物生物量无显著相关性。综上,干热河谷土壤中植物生长的限制养分主要为磷,然而土壤酶活性则不受氮磷养分的限制,其活性主要与土地利用类型有关。

Abstract:: This study aims to explore the effects of nitrogen and phosphorus addition on soil enzyme activities and plant growth under different land use types in dry and hot valleys, and the association between soil enzyme activities and plant growth. Soils in 6 different land-use types including shrubs, grasslands, forests, new farming, permanent farming, eroded bare land in Yuanmou dry-hot valley were collected. Pot experiment was used to explore the response characteristics of soil enzyme activities and Trifolium repens L. growth to treatments of nitrogen(N), phosphorus(P), and nitrogen and phosphorus(N+P). The results show that:(1)plant biomass was affected by both land use types and fertilizer treatments as well as their interactions;(2)there were significant differences in plant growth of nutrient addition in land use types except for soils from farmlands(new farming and permanent farming); the plant biomass of P treatment was significantly higher than that of CK; the plant biomass of N+P treatment was significant higher than that of single application of P fertilizer; however, the differences in plant biomass among different treatments for soils from new farming and permanent farmland were not significant;(3)soil enzyme activities were significantly affected by land use types, but there were no significant differences in soil enzyme activities among different nutrient addition treatments; there was no significant correlation between those soil enzyme activities and plant biomass. In conclusion, plant growth was primarily limited by phosphorus on soils in this dry and hot valley. However, soil enzyme activities were not limited by phosphorus or nitrogen, but mainly affected by land use types.

参考文献/References:

[1] Elser J J, Acharya K, Kyle M, et al. Growth rate-stoichiometry couplings in diverse biota[J]. Ecology Letters, 2003,6(10):936-943.
[2] 卢同平,张文翔,武梦娟,等.干湿度梯度及植物生活型对土壤氮磷空间特征的影响[J].土壤,2017,49(2):364-370.
[3] Galloway J N, Townsend A R, Erisman J W, et al. Transformation of the nitrogen cycle: recent trends, questions, and potential solutions[J]. Science, 2008,320(5878):889-892.
[4] Liu X, Zhang Y, Han W, et al. Enhanced nitrogen deposition over China[J]. Nature, 2013,494(7438):459-462.
[5] Craine J M, Morrow C, Stock W D. Nutrient concentration ratios and co-limitation in South African grasslands[J]. New Phytologist, 2008,179(3):829-836.
[6] Hedwall P O, Bergh J, Brunet J. Phosphorus and nitrogen co-limitation of forest ground vegetation under elevated anthropogenic nitrogen deposition[J]. Oecologia, 2017,185(2):317-326.
[7] 闵凯凯,何向阳,吴倩怡,等.参与碳氮磷转化的水解酶对不同施肥响应的差异[J].土壤,2020,52(4):718-727.
[8] 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.
[9] Sinsabaugh R L, Antibus R K, Linkins A E. An enzymic approach to the analysis of microbial activity during plant litter decomposition[J]. Agriculture, Ecosystems & Environment, 1991,34(1):43-54.
[10] Sinsabaugh R L, Follstad Shah J J. Ecoenzymatic stoichiometry and ecological theory[J]. Annual Review of Ecology, Evolution, and Systematics, 2012,43(1):313-343.
[11] 勒佳佳,苏原,彭庆文,等.氮添加对天山高寒草原土壤酶活性和酶化学计量特征的影响[J].干旱区研究,2020,37(2):111-118.
[12] 李欢,魏雅丽,闫帮国,等.元谋干热河谷沟蚀地区植被恢复对土壤养分和酶活性的影响[J].土壤通报,2020,51(5):1118-1126.
[13] 樊博,史亮涛,潘志贤,等.干热河谷土壤酶活性对碳氮添加的响应[J].生态学报,2018,38(23):341-348.
[14] 曾泉鑫,张秋芳,林开淼,等.酶化学计量揭示5年氮添加加剧毛竹林土壤微生物碳磷限制[J].应用生态学报,2021,32(2):521-528.
[15] Marklein A R, Houlton B Z. Nitrogen inputs accelerate phosphorus cycling rates across a wide variety of terrestrial ecosystems[J]. New Phytologist, 2012,193(3):696-704.
[16] mineau M M, Fatemi F R, Fernandez I J, et al. Microbial enzyme activity at the watershed scale: response to chronic nitrogen deposition and acute phosphorus enrichment[J]. Biogeochemistry, 2014,117(1):131-142.
[17] 王杰,李刚,修伟明,等.氮素和水分对贝加尔针茅草原土壤酶活性和微生物量碳氮的影响[J].农业资源与环境学报,2014,31(3):237-245.
[18] Elser J J, Bracken M E S, Cleland E E, et al. Global analysis of nitrogen and phosphorus limitation of primary producers in freshwater, marine and terrestrial ecosystems[J]. Ecology Letters, 2007,10(12):1135-1142.
[19] Refsgaard K, Bjarnholt N, Møller B L, et al. Dissipation of cyanogenic glucosides and cyanide in soil amended with white clover(Trifolium repens L.)[J]. Soil Biology and Biochemistry, 2010,42(7):1108-1113.
[20] D'Annibale A, Sechi V, Larsen T, et al. Does introduction of clover in an agricultural grassland affect the food base and functional diversity of Collembola[J]. Soil Biology and Biochemistry, 2017,112:165-176.
[21] Weatherburn M W. Phenol-hypochlorite reaction for determination of ammonia[J]. Analytical Chemistry, 1967,39(8):971-974.
[22] Doane T A, Horwáth W R. Spectrophotometric determination of nitrate with a single reagent[J].Analytical Letters, 2003,36(12):2713-2722.
[23] 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.
[24] Turner B L. Variation in pH optima of hydrolytic enzyme activities in tropical rain forest soils[J]. Applied and Environmental Microbiology, 2010,19(76):6485-6493.
[25] Dick R P, Dick L K, Deng S, et al. Cross-laboratory comparison of fluorimetric microplate and colorimetric bench-scale soil enzyme assays[J]. Soil Biology and Biochemistry, 2018,121:240-248.
[26] Cordero I, Snell H, Bardgett R D. High throughput method for measuring urease activity in soil[J]. Soil Biology and Biochemistry, 2019,134:72-77.
[27] 卢广超,邵怡若,薛立.氮沉降对凋落物分解的影响研究进展[J].世界林业研究,2014,27(1):35-42.
[28] 范爱连,张礼宏,陈廷廷,等.常绿阔叶林外生、内生菌根树种细根化学计量学性状对N添加的响应[J].生态学报,2020,40(14):4966-4974.
[29] Bucci S, Scholz F, Goldstein G, et al. Nutrient availability constrains the hydraulic architecture and water relations of savanna trees[J]. Plant, Cell & Environment, 2007,29(12):2153-2167.
[30] Liu L, Gundersen P, Zhang W, et al. Effects of nitrogen and phosphorus additions on soil microbial biomass and community structure in two reforested tropical forests[J]. Scientific Reports, 2015,5:14378.
[31] Turner B L, Joseph Wright S. The response of microbial biomass and hydrolytic enzymes to a decade of nitrogen, phosphorus, and potassium addition in a lowland tropical rain forest[J]. Biogeochemistry, 2014,117(1):115-130.
[32] 郑斯元.氮磷添加对羊草-土壤-根际微生物化学计量特征的影响[D].长春:东北师范大学,2020.
[33] Malcolm R E. Assessment of phosphatase activity in soils[J]. Soil Biology and Biochemistry, 1983,15(4):403-408.
[34] Allison S D, Vitousek P M. Responses of extracellular enzymes to simple and complex nutrient inputs[J]. Soil Biology and Biochemistry, 2004,37(5):937-944.

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备注/Memo

收稿日期:2021-05-25 修回日期:2021-06-15
资助项目:云南省重点研发计划“云南典型生态功能区生态保护和修复技术研究与应用示范”(2019BC001)
第一作者:李欢(1995—),女,四川遂宁人,在读硕士研究生,研究方向为土地资源利用与生态修复。E-mail:1350960103@qq.com
通信作者:方海东(1979—),男,黑龙江海伦人,硕士,研究员,主要从事干热河谷生态系统退化的原因、退化生态系统恢复与重建的技术和方法及其生态学过程和机理研究。E-mail:fhd@yaas.org.cn

更新日期/Last Update: 2022-06-20