Abstract
We conducted a field experiment in two alpine meadows to investigate the short-term effects of nitrogen enrichment and plant litter biomass on plant species richness, the percent cover of functional groups, soil microbial biomass, and enzyme activity in two alpine meadow communities. The addition of nitrogen fertilizer to experimental plots over two growing seasons increased plant production, as indicated by increases in both the living plant biomass and litter biomass in the Kobresia humilis meadow community. In contrast, fertilization had no significant effect on the amounts of living biomass and litter biomass in the K. tibetica meadow. The litter treatment results indicate that litter removal significantly increased the living biomass and decreased the litter biomass in the K. humilis meadow; however, litter-removal and litter-intact treatments had no impact on the amounts of living biomass and litter biomass in the K. tibetica meadow. Litter production depended on the degree of grass cover and was also influenced by nitrogen enrichment. The increase in plant biomass reflects a strong positive effect of nitrogen enrichment and litter removal on grasses in the K. humilis meadow. Neither fertilization nor litter removal had any impact on the grass biomass in the K. tibetica meadow. Sedge biomass was not significantly affected by either nutrient enrichment or litter removal in either alpine meadow community. The plant species richness decreased in the K. humilis meadow following nitrogen addition. In the K. humilis meadow, microbial biomass C increased significantly in response to the nitrogen enrichment and litter removal treatments. Enzyme activities differed depending on the enzyme and the different alpine meadow communities; in general, enzyme activities were higher in the upper soil layers (0–10 cm and 10–20 cm) than in the lower soil layers (20–40 cm). The amounts of living plant biomass and plant litter biomass in response to the different treatments of the two alpine meadow communities affected the soil microbial biomass C, soil organic C, and soil fertility. These results suggest that the original soil conditions, plant community composition, and community productivity are very important in regulating plant community productivity and microbial biomass and activity.
This is a preview of subscription content, access via your institution.
References
Abrams PA (1995) Monotonic or unimodal diversity-productivity gradients: what does competition theory predict? Ecology 76:2019–2027
Acosta-Martinez V, Acosta-Mercado D, Sotomayor-Ramrez D, Cruz-Rodrguez L (2008) Microbial communities and activities under different management in semiarid soils. Soil Biol Biochem 38:249–260
Aerts R, Berendse F (1988) The effect of increased nutrient availability on vegetation dynamics in heathlands. Vegetation 63:63–69
Baldrian P, Trögl J, Valàšková V, Merhautvá V, Cajthaml T, Herinková J (2008) Enzyme activities and microbial biomass in topsoil layer during spontaneous succesion in spoil heaps after brown coal mining. Soil Biol Biochem 40:2107–2115
Barbhuiya AR, Arunachalam A, Pandey HN, Arunachalam K, Khan ML, Nath PC (2004) Dynamics of soil microbial biomass C, N and P in disturbed and undisturbed stands of a tropical wet-evergreen forest. Eur J Soil Biol 40:113–121
Bardgett RD, Mawdsley JL, Edwards S, Hobbs PJ, Rodwell JS, Davies WJ (1999) Plant species effects on soil biological properties of temperate upland grasslands. Funct Ecol 13:650–660
Bever JD (2002) Host-specificity of AM fungal population growth rates can generate feed-back on plant growth. Plant Soil 244:281–290
Bowman WD, Conant RT (1994) Shoot growth dynamics and photosynthetic response to increased nitrogen availability in the alpine willow Salix glauca. Oecologia 97:93–99
Bowman WD, Theodose TA, Schardt JC, Conant RT (1993) Constraints of nutrient availability on primary production in two alpine communities. Ecology 74:2085–2097
China vegetation edit commission (1980) China vegetations. Science, Beijing, pp 10–68
Descheemaeker D, Muys B, Nyssen J, Poesen J, Raes D, Haile M, Deckers J (2006) Litter production and organic matter accumulation in exclosures of the Tigray highlands, Ethiopia. Forest Ecol Manag 233:21–35
Facelli JM, Pickett STA (1991) Plant litter: its dynamics and effects on plant community structure. Bot Rev 57:1–31
Foster BL, Gross KL (1998) Species richness in successional grassland: effects of nitrogen enrichment and plant litter. Ecology 79:2593–2602
Fox JE (1992) Responses of diversity and growth form dominance to fertility in Alaskan tundra ellfield communities. Arct Ant Arct Alp Res 24:233–237
Guan SY (1986) Research methods on soil enzymes. China Agricultural, Beijing, pp 182–266
Hobbie SE (1992) Effects of plant species on nutrient cycling. Trends Ecol Evol 7:336–339
Huston MA, DeAngelis DL (1994) Competition and coexistence: the effects of resource transport and supply rates. Am Nat 144:954–977
Jonasson S (1992) Plant responses to fertilization and species removal in tundra related to community structure and clonality. Oikos 63:420–429
Jonasson S, Bryant JP, Chapin FS, Anderson M (1986) Plant phenols and nutrients in relation to variations in climate and rodent grazing. Am Nat 128:394–408
Jutila HM, Grace JB (2002) Effects of disturbance on germination and seedling establishment in a coastal prairie grassland: a test of the competitive release hypothesis. J Ecol 90:291–302
Korner C (1991) Some often overlooked plant characteristics as determinants of plant growth: a reconsideration. Funct Ecol 5:162–173
Kourtev PS, Ehrenfeld JG, Haggblom M (2002) Exotic plant species alter the microbial community structure and function in the soil. Ecology 83:3152–3166
Li YS, Wu LH, Lu XH, Zhao LM, Fan QL, Zhang FS (2006) Soil microbial biomass as affected by non-flooded plastic mulching cultivation in rice. Biol Fertil Soils 1:107–111
Li YS, Li FM, Rengel Z, Zhan ZY, Singh B (2007) Soil physical properties and their relations to organic carbon pools as affected by land use in an alpine pastureland. Geoderma 139:98–105
May DE, Webber PJ (1982) Spatial and temporal variation of vegetation and its productivity on Niwot Ridge, Colorado. In: Hakfpenny J (ed) Ecological studies in the Colorado alpine, a Festschrift for John W. Marr. Occasional Paper Number 37. Institute of Arctic and Alpine Research, University of Colorado, Boulder, Colorado, pp 35–62
Pielou EC (1969) An introduction to mathematical ecology. Wiley, New York
Pysek P, Leps J (1991) Response of a weed community to nitrogen fertilization: a multivariate analysis. J Veg Sci 2:237–244
Sugden A, Stone R, Ash C (2004) Ecology in the underworld. Science 304:1616
Theodose TA (1995) Interspecific plant competition in alpine tundra. Dissertation. University of Colorado, Boulder, Colorado
Tilman D (1982) Resource competition and community structure. Monographs in population biology. Princeton University Press, Princeton
Tilman D (1984) Plant dominance along an experimental nutrient gradient. Ecology 56:1445–1453
Tilman D (1987) Secondary succession and the pattern of plant dominance along experimental nitrogen gradients. Ecol Monogr 57:189–214
Tilman D (1993) Species richness of experimental productivity gradients: how important is colonization limitation? Ecology 74:2179–2191
Vance ED, Brooks PC, Jenkinson DS (1987) An extraction method for measure soil microbial biomass C. Soil Biol Biochem 19:703–707
Vinton MA, Burke IC (1997) Contingent effects of plant species on soils along a regional moisture gradient in the Great Plains. Oecologia 110:393–402
Wang QJ, Zhou XM, Zhang YQ, Shen ZX (1995) Community structure and biomass dynamic of the Kobresia pygmaea steppe meadow. Acta Phytoecol Sini 19:225–235
Wang CT, Cao GM, Wang QL, Jing ZC, Ding LM, Long RJ (2008a) Effects of altitude on plant-species diversity and productivity in an alpine meadow, Qinghai-Tibetan plateau. Sci China Ser C 51:86–94
Wang CT, Long RJ, Wang QL, Jing ZC, Du YG DLM, Cao GM (2008b) Effects of soil resources on species composition, plant diversity, and plant biomass in an alpine meadow, Qinghai-Tibetan plateau. Isr J Ecol Evol 53:205–222
Wedin DA, Tilman D (1990) Species effects on nitrogen cycling: a test with perennial grasses. Oecologia 84:433–441
Wilson SD, Tilman D (1991) Interactive effects of fertilization and disturbance on community structure and resource availability in an old-field community. Oecologia 88:61–71
Xiong S, Nilsson C, Johansson ME, Jansson R (2001) Responses of riparian plants to accumulations of silt and plant litter: the importance of plant litter. J Veg Sci 12:481–490
Zhou XM (2001) Kobresia meadow in China. Science Press, Beijing, pp 131–162
Acknowledgements
The authors would like to thank those colleagues who helped with the fieldwork for this study. This research was performed under the auspices of the Hundred Talents Program of the Chinese Academy of Sciences and the Project 30730069 of the National Natural Science Important Foundation of China.
Author information
Authors and Affiliations
Corresponding author
Additional information
Responsible Editor: Wim van der Putten.
Appendix
Appendix
Soil enzyme activities of samples collected at different depths in two alpine meadow communities.
K. humilis meadow | K. tibetica meadow | |||||||
|---|---|---|---|---|---|---|---|---|
Depth-cm | Depth-cm | |||||||
Treatment | 0–10 | 10–20 | 20–40 | 0–40 | 0–10 | 10–20 | 20–40 | 0–40 |
Nitrogen (A) | 0.43a (0.03) | 0.20a (0.03) | 0.18a (0.01) | 0.27a (0.02) | 0.51a (0.03) | 0.08a (0.01) | 0.03a (0.00) | 0.21a (0.01) |
No nitrogen (A) | 0.23b (0.01) | 0.12b (0.01) | 0.11b (0.01) | 0.15b (0.00) | 0.49a (0.03) | 0.09a (0.01) | 0.03a (0.00) | 0.18a (0.01) |
Litter intact (A) | 0.42a (0.02) | 0.16b (0.02) | 0.12b (0.01) | 0.24a (0.02) | 0.44a (0.03) | 0.09a (0.01) | 0.03a (0.01) | 0.19a (0.01) |
Litter removal (A) | 0.21b (0.02) | 0.20a (0.02) | 0.17a (0.01) | 0.20b (0.00) | 0.46a (0.04) | 0.08a (0.01) | 0.03a (0.00) | 0.19a (0.01) |
Nitrogen (B) | 7.49a (0.52) | 5.43a (0.26) | 5.81a (0.14) | 6.24a (0.28) | 1.11a (0.03) | 0.82a (0.04) | 0.75a (0.05) | 0.89a (0.04) |
No nitrogen (B) | 5.91b (0.53) | 3.90b (0.12) | 3.01b (0.25) | 4.27b (0.19) | 1.08a (0.01) | 0.90a (0.01) | 0.78a (0.02) | 0.92a (0.01) |
Litter intact (B) | 7.32a (0.02) | 5.61a (0.55) | 4.63a (0.44) | 5.89a (0.28) | 1.01a (0.13) | 0.79a (0.07) | 0.69a (0.08) | 0.83a (0.03) |
Litter removal (B) | 5.32b (0.31) | 3.73b (0.11) | 2.97b (0.06) | 4.01b (0.13) | 0.99a (0.09) | 0.75a (0.04) | 0.67a (0.03) | 0.81a (0.03) |
Nitrogen (C) | 0.86a (0.10) | 0.26a (0.03) | 0.06a (0.01) | 0.39a (0.04) | 0.60a (0.10) | 0.53a (0.03) | 0.13a (0.02) | 0.42a (0.03) |
No nitrogen (C) | 0.52b (0.02) | 0.10b (0.02) | 0.08a (0.01) | 0.23b (0.01) | 0.57a (0.04) | 0.51a (0.05) | 0.13a (0.02) | 0.40a (0.03) |
Litter intact (C) | 0.87a (0.01) | 0.44a (0.03) | 0.32a (0.04) | 0.54a (0.01) | 0.63a (0.05) | 0.55a (0.03) | 0.13a (0.02) | 0.43a (0.02) |
Litter removal (C) | 0.53b (0.03) | 0.13b (0.02) | 0.09b (0.03) | 0.25b (0.01) | 0.61a (0.02) | 0.51a (0.04) | 0.13a (0.02) | 0.42a (0.02) |
Nitrogen (D) | 15.99a (3.72) | 9.52a (2.86) | 5.43a (1.23) | 10.31a (1.93 | 0.65a (0.04) | 0.54a (0.03) | 0.47a (0.04) | 0.55a (0.02) |
No nitrogen (D) | 12.03b (1.43) | 5.49b (0.86) | 4.20b (0.70) | 7.24b (0.61) | 0.61a (0.04) | 0.51a (0.06) | 0.47a (0.05) | 0.53a (0.02) |
Litter intact (D) | 15.79a (1.11) | 8.36a (1.85) | 5.43a (0.33) | 9.86a (0.63) | 0.65a (0.02) | 0.52a (0.05) | 0.43a (0.05) | 0.53a (0.02) |
Litter removal (D) | 12.39b (1.47) | 5.96b (2.12) | 2.43b (0.80) | 6.92b (0.89) | 0.63a (0.04) | 0.56a (0.01) | 0.47a (0.04) | 0.56a (0.02) |
Rights and permissions
About this article
Cite this article
Wang, C., Long, R., Wang, Q. et al. Fertilization and litter effects on the functional group biomass, species diversity of plants, microbial biomass, and enzyme activity of two alpine meadow communities. Plant Soil 331, 377–389 (2010). https://doi.org/10.1007/s11104-009-0259-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11104-009-0259-8
Keywords
- Functional group biomass
- Species diversity
- Microbial biomass
- Enzyme activity
- Fertilization
- Alpine meadow