Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- Acknowledgements
- PART I Introduction
- PART II The soil environment
- PART III Patterns and drivers of soil biodiversity
- 5 The use of model Pseudomonas fluorescens populations to study the causes and consequences of microbial diversity
- 6 Patterns and determinants of soil biological diversity
- 7 How plant communities influence decomposer communities
- 8 The balance between productivity and food web structure in soil ecosystems
- 9 Rhizosphere carbon flow: a driver of soil microbial diversity?
- PART IV Consequences of soil biodiversity
- PART V Applications of soil biodiversity
- PART VI Conclusion
- Index
- References
7 - How plant communities influence decomposer communities
Published online by Cambridge University Press: 17 September 2009
Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- Acknowledgements
- PART I Introduction
- PART II The soil environment
- PART III Patterns and drivers of soil biodiversity
- 5 The use of model Pseudomonas fluorescens populations to study the causes and consequences of microbial diversity
- 6 Patterns and determinants of soil biological diversity
- 7 How plant communities influence decomposer communities
- 8 The balance between productivity and food web structure in soil ecosystems
- 9 Rhizosphere carbon flow: a driver of soil microbial diversity?
- PART IV Consequences of soil biodiversity
- PART V Applications of soil biodiversity
- PART VI Conclusion
- Index
- References
Summary
SUMMARY
The issue of how plant community composition affects decomposer community composition and function is considered, by reviewing recent literature and through the use of two examples.
It is apparent from the available literature that plant species identity exerts important effects on soil food webs, and that specific attributes such as the body size distribution of soil animals, and the relative importance of bacterial-based vs. fungal-based energy channels, respond to plant species identity. This has important implications for ecosystem functioning.
The first example involves below-ground effects of changes in plant community composition, such as might occur during C4 grass invasion resulting from global warming, in a perennial pasture in New Zealand. The second involves below-ground consequences of changes in vegetation community structure caused by introduced browsing mammals in New Zealand rainforest. Both examples point to above-ground, human-induced changes affecting the composition of the soil food web across several trophic levels, and key ecosystem functions carried out by the soil biota.
The issues of how above-ground biodiversity affects below-ground biodiversity, and the nature of reciprocal feedbacks between the above-ground and below-ground biota, are discussed. It is concluded that understanding the nature of above-ground–below-ground feedbacks may offer opportunities for better understanding how ecosystems function and the ecological consequences of global change phenomena.
Introduction
All functional ecosystems consist of explicit producer and decomposer subsystems. Producers fix atmospheric carbon, which is utilised by the decomposer organisms, and the decomposers in turn break down organic matter, which regulates the availability and supply of nutrients required for plant growth.
- Type
- Chapter
- Information
- Biological Diversity and Function in Soils , pp. 119 - 138Publisher: Cambridge University PressPrint publication year: 2005
References
(1978). Inter- and intra-habitat relationships between woodland Cryptostigmata species diversity and the diversity of soil and litter microhabitats. Oecologia, 32, 341–348CrossRefGoogle ScholarPubMed
& (1989). Relationships between moas and plants. New Zealand Journal of Ecology, 12 (suppl), 67–96Google Scholar
, & (1998). Linking above-ground and below-ground interactions: how plant responses to foliar herbivory influence soil organisms. Soil Biology and Biochemistry, 30, 1867–1878CrossRefGoogle Scholar
(1998). Effects of dominant plant species on soils during succession in nutrient poor ecosystems. Biogeochemistry, 42, 73–88CrossRefGoogle Scholar
(2000). The impact of the New Zealand flatworm on earthworms and moles in agricultural land in western Scotland. Aspects of Applied Biology, 62, 79–84Google Scholar
& (1991). Single-tree influence on earthworms in forest soils in eastern Kentucky. Soil Science Society of America Journal, 55, 862–865CrossRefGoogle Scholar
(1996). Plant functional types and climate at the global scale. Journal of Vegetation Science, 7, 309–320CrossRefGoogle Scholar
, & (1999). Climate profiles of temperate C3 and subtropical C4 species in New Zealand Pastures. New Zealand Journal of Agricultural Research, 42, 223–233CrossRefGoogle Scholar
, & (1983). Biological strategies of nutrient cycling in soil systems. Advances in Ecological Research, 13, 1–55CrossRefGoogle Scholar
, , & (1991). Increased atmospheric CO2 and litter quality: decomposition of sweet chestnut leaf litter with animal food webs of different complexities. Oikos, 61, 53–64CrossRefGoogle Scholar
, & (1995). Energetics, patterns of interaction strength and stability in real ecosystems. Science, 269, 1257–1260CrossRefGoogle Scholar
& (1997). Plant functional types and ecosystem function in relation to global change. Journal of Vegetation Science, 8, 463–474CrossRefGoogle Scholar
, , , & (2003). Functional diversity revealed through removal experiments. Trends in Ecology and Evolution, 18, 140–146CrossRefGoogle Scholar
, & (1999). Riparian soil response to surface nitrogen input: temporal changes in denitrification, labile and microbial C and N pools, and bacterial and fungal respiration. Soil Biology and Biochemistry, 31, 1609–1624CrossRefGoogle Scholar
, , & (2002). The diet and diet preferences of introduced ungulates (order: Artiodactyla) in New Zealand. New Zealand Journal of Zoology, 29, 323–343CrossRefGoogle Scholar
, , & (1992). The effect of nitrate-nitrogen on bacteria and bacterial-feeding fauna in the rhizosphere of different grass species. Oecologia, 91, 253–259CrossRefGoogle ScholarPubMed
(2001). Plant Strategies, Vegetation Processes and Ecosystem Properties. Chichester: WileyGoogle Scholar
, , & (1996). Evidence of a causal connection between anti-herbivore defence and the decomposition rate of leaves. Oikos, 77, 489–494CrossRefGoogle Scholar
, , , et al. (1997). Integrated screening validates primary axes of specialization in plants. Oikos, 79, 259–281CrossRefGoogle Scholar
, & (1960). Community structure, population control and competition. American Naturalist, 94, 421–425CrossRefGoogle Scholar
(1954). Mull and Mor in Relation to Forest Soils. London: Her Majesty's Stationery OfficeGoogle Scholar
(1999). Red oak litter promotes a microarthropod functional group that accelerates its decomposition. Plant and Soil, 209, 37–45CrossRefGoogle Scholar
& (1998). Litter complexity and composition are determinants of the diversity and species composition of oribatid mites (Acari: Oribatida) in litterbags. Applied Soil Ecology, 9, 17–23CrossRefGoogle Scholar
& (1995). Shifting dominance within a montane vegetation community: results of a climate-warming experiment. Science, 267, 876–880CrossRefGoogle ScholarPubMed
, , , et al. (1986). Detritus food webs in conventional and no-tillage agroecosystems. BioScience, 36, 374–380CrossRefGoogle Scholar
(1992). Effects of plant species on nutrient cycling. Trends in Ecology and Evolution, 7, 336–339CrossRefGoogle ScholarPubMed
, , , et al. (2000). Interactions between above- and belowground biodiversity in terrestrial ecosystems: patterns, mechanisms and feedbacks. BioScience, 50, 1049–1061CrossRefGoogle Scholar
, , , & (1988). Nitrogen limitation of production and decomposition in prairie, mountain meadow and pine forest. Ecology, 69, 1009–1016CrossRefGoogle Scholar
(1994). Biological Diversity. The Coexistence of Species on Changing Landscapes. Cambridge: Cambridge University PressGoogle Scholar
(1997). Hidden treatments in ecological experiments: re-evaluating the ecosystem function of biodiversity. Oecologia, 110, 449–460CrossRefGoogle ScholarPubMed
& (1994). Competition and coexistence: the effects of resource transport and supply rates. American Naturalist, 144, 854–877CrossRefGoogle Scholar
, & (1989). An analysis of food web structure and function in a shortgrass prairie, a mountain meadow and a lodgepole pine forest. Biology and Fertility of Soils, 8, 29–37CrossRefGoogle Scholar
& (1986). Nitrogen mineralization by native and introduced earthworms: effects on big bluestem growth. Ecology, 67, 1094–1097CrossRefGoogle Scholar
& (1999). Mixed leaf litter effects on decomposition rates and soil arthropod communities in an oak–pine forest stand in Japan. Ecological Research, 14, 131–138CrossRefGoogle Scholar
(2002). Feedback with soil biota contributes to plant rarity and invasiveness in communities. Nature, 417, 67–70CrossRefGoogle ScholarPubMed
& (1993). Ghost stories: moa, plant defenses and evolution in New Zealand. Tuatara, 32, 1–18Google Scholar
& (1998). Effect of exclosures on soils, biomass, plant nutrients and vegetation, on unfertilized steeplands, upper Waitaki district, South Island, New Zealand. New Zealand Journal of Ecology, 22, 209–217Google Scholar
& (1976). Species diversity gradients: synthesis of the roles of predation, competition and spatial heterogeneity. American Naturalist, 110, 351–369CrossRefGoogle Scholar
& (1988). Resource compartmentation and the stability of real ecosystems. Nature, 333, 261–263CrossRefGoogle Scholar
(1884). Studier over skovjord, som bidrag til skovdyrkningens theori: II. Om muld og mor i egeskove og paa heder. Tidsskrift for Skovbrug, 7, 1–232Google Scholar
, , , & (1999). Ecosystem properties and microbial community changes in primary succession on a glacier forefront. Oecologia, 119, 239–246CrossRefGoogle ScholarPubMed
, , & (1981). Exploitation ecosystems in gradients of primary productivity. American Naturalist, 118, 240–261CrossRefGoogle Scholar
& (2000). Soil pathogens and spatial patterns of seedling mortality in a temperate tree. Nature, 404, 278–281CrossRefGoogle Scholar
, & (1989). Decomposition and nitrogen dynamics of surface weed residues in no-tillage agroecosystems under drought conditions: influence of resource quality on the decomposer community. Soil Biology and Biochemistry, 21, 97–103CrossRefGoogle Scholar
(1998). Decomposition, microbial community structure and earthworm effects along a birch–spruce soil gradient. Ecology, 79, 834–846Google Scholar
& (1990). The fauna of beech forests: comparison between a mull and moder soil. Pedobiologia, 34, 299–304Google Scholar
Schmid, B., Joshi, J. & Schläpfer, F. (2002). Empirical evidence for biodiversity: ecosystem functioning relationships. The Functional Consequences of Biodiversity: Empirical Progress and Theoretical Extensions (Ed. by , & ), pp. 120–150. Princeton: Princeton University PressGoogle Scholar
, & (2001). Biogeochemical impact of Hieracium invasion in New Zealand's grazed tussock grasslands: sustainability implications. Ecological Applications, 11, 1311–1322CrossRefGoogle Scholar
& (1991). Soil fauna increase Betula pendula growth: laboratory experiments with coniferous forest floor. Ecology, 72, 665–671CrossRefGoogle Scholar
(1996). Structure and composition of the nematode fauna in pine forests under the influence of clear-cutting: effects of slash removal and field layer vegetation. European Journal of Soil Biology, 32, 1–14Google Scholar
& (1997). How soil-borne pathogens may affect plant competition. Ecology, 78, 1785–1795CrossRefGoogle Scholar
, , , & (1996). Impact of faunal complexity on microbial biomass and N turnover in field mesocosms from a spruce forest soil. Biology and Fertility of Soils, 22, 22–30CrossRefGoogle Scholar
, , , & (1987). Biological invasion by Myrica faya alters ecosystem development in Hawaii. Science, 238, 802–804CrossRefGoogle ScholarPubMed
(1995). Impact of disturbance on detritus food-webs in agro-ecosystems of contrasting tillage and weed management practices. Advances in Ecological Research, 26, 105–185CrossRefGoogle Scholar
(2002). Communities and Ecosystems: Linking the Aboveground and Belowground Components. Princeton: Princeton University PressGoogle Scholar
, , , & (2001). Introduced browsing mammals in natural New Zealand forests: aboveground and belowground consequences. Ecological Monographs, 71, 587–614CrossRefGoogle Scholar
, & (2002). Linkages between plant litter decomposition, litter quality and vegetation responses to herbivores. Functional Ecology, 16, 585–595CrossRefGoogle Scholar
, , , et al. (1999). Plant removals in perennial grassland: vegetation dynamics, decomposers, soil biodiversity and ecosystem properties. Ecological Monographs, 69, 535–568CrossRefGoogle Scholar
, , & (2003). Determinants of litter mixing effects in a Swedish boreal forest. Soil Biology and Biochemistry, 35, 827–835CrossRefGoogle Scholar
Wardle, D. A. & van der Putten, W. (2002). Biodiversity, ecosystem functioning and aboveground-belowground linkages. Biodiversity and Ecosystem Functioning (Ed. by , and ), pp. 155–168. Oxford: Oxford University PressGoogle Scholar
& (1993). The dual importance of competition and predation as regulatory forces in terrestrial ecosystems: evidence from decomposer food-webs. Oecologia, 93, 303–306CrossRefGoogle ScholarPubMed
, , & (1997). Influence of island area on ecosystem properties. Science, 277, 1296–1299CrossRefGoogle Scholar
(1998). Effects of disturbance on species diversity: a multitrophic perspective. American Naturalist, 152, 803–825CrossRefGoogle ScholarPubMed
- 26
- Cited by