| 500 | 24 | 36 |
| 下载次数 | 被引频次 | 阅读次数 |
以福建省三明市格氏栲自然保护区米槠(Castanopsis carlesii)天然林土壤和杉木(Cunninghamia lanceolata)人工林土壤为研究对象,通过不同梯度(对照CT-0 g·kg-1、低磷LP-0.1 g·kg-1、高磷HP-0.6 g·kg-1)磷添加室内培养实验,采用磷脂脂肪酸(PLFA)分析法,研究磷添加对中亚热带米槠天然林和杉木人工林土壤微生物生物量和群落组成的影响,结果表明:1)施磷除显著提高总磷和有效磷含量外,亦显著增加土壤pH和可溶性有机碳的含量;2)土壤微生物生物量和群落组成对磷添加的响应因施磷量和森林类型不同而不同,其中高磷处理显著增加杉木人工林和米槠天然林土壤微生物PLFA,杉木人工林增幅大于米槠天然林。低磷处理仅显著增加杉木人工林土壤微生物PLFA,对米槠天然林土壤微生物生物量影响不显著;磷添加显著增加杉木人工林土壤革兰氏阳性菌与革兰氏阴性菌的比值(GP/GN),对2种森林土壤真菌与细菌比(F/B)影响不显著。该研究表明米槠天然林转变成杉木人工林后,养分流失,加剧了磷限制。因此适当施磷有利于杉木人工林可持续经营。
Abstract:We investigated the responses of soil microbial biomass,community composition and soil physicochemical properties to phosphorus(P) addition at level of 0(CT),0. 1(LP),and 0. 6(HP)g·kg-1 in natural Castanopsis carlesii forest and Cunninghamia lanceolata plantation in Geshikao Nature Reserve in Fujian Province of China.(1) After four months of P addition,the result demonstrated that P addition not only significantly increased total phosphorus and available phosphorus content,but also significantly increased soil pH and dissolved organic carbon content.(2) The specific influences of P addition on soil microbial community composition base on types of forest soils and the level of P.The abundance of soil total phospholipid fatty acid(PLFA),bacterial PLFA,fungal PLFA,gram-posi-tive bacterial PLFA,gram-negative bacterial PLFA and actinomycetes PLFA in two forest soil increased in the HP treatment. Low P addition only significant increased soil microbial PLFA and the ratio of gram-positive bacteria to gram-negative bacteria(GP/GN) in C. lanceolata plantation. The ratio of fungi to bacteria(F/B) was not significant changed with P addition in two forest soil. This finding indicates that P availability is maybe not the limiting factor for microbial growth in C. carlesii forest soil.However,the soil microorganisms may be limited by phosphorus nutrient due to nutrient loss after conversion from C. carlesii forest to C. lanceolata plantation. Therefore,proper phosphorus application is beneficial to sustainable management of C. lanceolata plantation.
[1]ALLISON S D,TRESEDER K K.Warming and drying suppress microbial activity and carbon cycling in boreal forest soils[J].Global Change Biology,2008,14(12):2898-2909.
[2]CRUZ A F,HAMEL C,HANSON K,et al.Thirty-seven years of soil nitrogen and phosphorus fertility management shapes the structure and function of the soil microbial community in a Brown Chernozem[J].Plant&Soil,2009,315(2):173-184.
[3]ESBREG C,TOIT B D,OLSSON R,et al.Microbial responses to P addition in six South African forest soils[J].Plant&Soil,2010,329(1/2):209-225.
[4]LIU L,GUNDERSEN P,ZHANG T,et al.Effects of phosphorus addition on soil microbial biomass and community composition in three forest types in tropical China[J].Soil Biology&Biochemistry,2012,44(1):31-38.
[5]GROFFMAN P M,FISK M C.Phosphate additions have no effect on microbial biomass and activity in a northern hardwood forest[J].Soil Biology&Biochemistry,2011,43(12):2441-2449.
[6]THIRUKKUMARAN C M,PARKINSON D.Microbial activity,nutrient dynamics and litter decomposition in a Canadian Rocky Mountain pine forest as affected by N and P fertilizers[J].Forest Ecology&Management,2002,159(3):187-201.
[7]LI J,LI Z,WANG F,et al.Effects of nitrogen and phosphorus addition on soil microbial community in a secondary tropical forest of China[J].Biology&Fertility of Soils,2015,51(2):207-215.
[8]DENG H,ZHANG B,RUI Y,et al.Long-term effect of re-vegetation on the microbial community of a severely eroded soil in sub-tropical China[J].Plant&Soil,2010,328(1/2):447-458.
[9]RORGUEZ-LOINAZ G,ONAINDIA M,AMEZAGA I,et al.Relationship between vegetation diversity and soil functional diversity in native mixed-oak forests[J].Soil Biology&Biochemistry,2008,40(1):49-60.
[10]PHILLIPS O L,GRACE J.Changes in the carbon balance of tropical forests:Evidence from long-term plots[J].Science,1998,282(5388):439.
[11]刘小飞,杨智杰,谢锦升,等.中亚热带森林转换对地表CH4氧化的影响[J].林业科学,2012,48(1):7-12.
[12]VITOUSEK P M,PORDER S,HOULTON B Z,et al.Terrestrial phosphorus limitation:Mechanisms,implications,and nitrogen-phosphorus interactions[J].Ecological Applications A Publication of the Ecological Society of America,2010,20(1):5.
[13]CLEVELAN C C,TOWNSEND A R,TAYLOR P,et al.Relationships among net primary productivity,nutrients and climate in tropical rain forest:A pan-tropical analysis[J].Ecology Letters,2011,14(9):939.
[14]FISK M,SANTANGELO S,MINICK K.Carbon mineralization is promoted by phosphorus and reduced by nitrogen addition in the organic horizon of northern hardwood forests[J].Soil Biology&Biochemistry,2015,81(81):212-218.
[15]CURTIN D,WRIGHT C E,BRARE M H,et al.Hot water-extractable nitrogen as an indicator of soil nitrogen availability[J].Soil Science Society of America Journal,2006,70(5):1512-1521.
[16]KOVAR J L,PIERZYNSKI G M.Methods of phosphorus analysis for soils,sediments,residuals,and waters second edition[M]//Methods of Phosphorus Analysis for Soils.Raleigh,USA:North Carolina State University,2009.
[17]BARDGETT R D,HOBBS P J,FROSTEGRD.Changes in soil fungal:bacterial biomass ratios following reductions in the intensity of management of an upland grassland[J].Biology&Fertility of Soils,1996,22(3):261-264.
[18]周丽霞,丁明懋.土壤微生物学特性对土壤健康的指示作用[J].生物多样性,2007,15(2):162-171.
[19]DILLY O,MUNCH J C.Ratios between estimates of microbial biomass content and microbial activity in soils[J].Biology&Fertility of Soils,1998,27(4):374-379.
[20]KOURTEV P S,EHRENFELD J G,Hggblom M.Exotic plant species alter the microbial community structure and function in the soil[J].Ecology,2002,83(11):3152-3166.
[21]CLEVELAND C C,TOWNSEND A R,SCHMIDT S K.Phosphorus limitation of microbial processes in moist tropical forests:evidence from short-term laboratory incubations and field studies[J].Ecosystems,2002,5(7):680-691.
[22]HUANG J,HU B,QI K,et al.Effects of phosphorus addition on soil microbial biomass and community composition in a subalpine spruce plantation[J].European Journal of Soil Biology,2016,72:35-41.
[23]BLAGODATSKAYA E,YUYUKINA T,BLAGODATSKY S,et al.Turnover of soil organic matter and of microbial biomass under C3-C4vegetation change:Consideration of13C fractionation and preferential substrate utilization[J].Soil Biology&Biochemistry,2011,43(1):159-166.
[24]MORALES A,D E AGUDELO M M R,HERNANDEZ F.Adsorption mechanism of phosphorus on alumina[J].Applied Catalysis,1988,41:261-271.
[25]RAMIREZ K S,CRAINE J M,FIERER N.Consistent effects of nitrogen amendments on soil microbial communities and processes across biomes[J].Global Change Biology,2012,18(6):1918-1927.
[26]BTH E,ANDERSON T H.Comparison of soil fungal/bacterial ratios in a p H gradient using physiological and PLFA-based techniques[J].Soil Biology&Biochemistry,2003,35(7):955-963.
[27]NILSSON L O,BTH E,FALKENGRENGRERUP U,et al.Growth of ectomycorrhizal mycelia and composition of soil microbial communities in oak forest soils along a nitrogen deposition gradient[J].Oecologia,2007,153(2):375-384.
[28]WU Y,MA B,LING Z,et al.Changes in the soil microbial community structure with latitude in eastern China,based on phospholipid fatty acid analysis[J].Applied Soil Ecology,2009,43(2/3):234-240.
[29]MICHAELS S,JOHANNES R.Considering fungal:bacterial dominance in soils—Methods,controls,and ecosystem implications[J].Soil Biology&Biochemistry,2010,42(9):1385-1395.
[30]FIERER N,SCHIMEL J P,HOLDEN P A.Variations in microbial community composition through two soil depth profiles[J].Soil Biology&Biochemistry,2003,35(1):167-176.
基本信息:
DOI:10.19687/j.cnki.1673-7105.2018.01.002
中图分类号:S714.3
引用信息:
[1]郑宪志,杨柳明,陈忠,等.磷添加对中亚热带2种森林类型土壤微生物群落组成的影响[J].亚热带资源与环境学报,2018,13(01):9-16.DOI:10.19687/j.cnki.1673-7105.2018.01.002.
基金信息:
国家自然科学基金项目(31300523;31600433)
2018-03-15
2018-03-15