Biogeochemistry and the structure of tropical brown food webs

Litter invertebrates are notoriously patchy at small scales. Here we show that the abundance of 10 litter taxa also varies 100-fold at landscape and regional scales across 26 forest stands in Peru and Panama. We contrast three hypotheses that link gradients of abundance to ecosystem biogeochemistry....

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Bibliographic Details
Published in:Ecology (Durham) 2009-12, Vol.90 (12), p.3342-3351
Main Authors: Kaspari, Michael, Yanoviak, Stephen P
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
Animals
Ants
Araneae
biodegradation
Biodegradation, Environmental
biogeochemical cycles
Biogeochemistry
Biological and medical sciences
Biomass
calcium
Calcium - metabolism
Chilopoda
Collembola
Community ecology
Crustaceans
decomposition
Diplodia
Ecosystem
ecosystem size
Ecosystems
Food Chain
Food chains
Food webs
Forest ecology
Forest ecosystems
Forest litter
Forest stands
Formicidae
Fundamental and applied biological sciences. Psychology
General aspects
Invertebrates
Invertebrates - metabolism
Invertebrates - physiology
Isopoda
litter
Mesostigmata
nitrogen
Nitrogen - metabolism
Oribatida
phosphorus
Phosphorus - metabolism
Population Density
Population Dynamics
Population Growth
Predators
Predatory Behavior
Rainforests
Soil ecology
soil invertebrates
Soil Microbiology
species diversity
Species Specificity
Staphylinidae
stoichiometry
Synecology
Taxa
trophic structure
Tropical Climate
Tropical forests
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Summary:Litter invertebrates are notoriously patchy at small scales. Here we show that the abundance of 10 litter taxa also varies 100-fold at landscape and regional scales across 26 forest stands in Peru and Panama. We contrast three hypotheses that link gradients of abundance to ecosystem biogeochemistry. Of 14 factors considered (12 chemical elements, plus fiber and litter depth), four best predicted the abundance of litter invertebrates. In the Secondary Productivity Hypothesis, phosphorus limits abundance via the conversion of detritus to microbial biomass. Two of four microbivore taxa, collembola and isopods, increased with the percentage of P (%P) of decomposing litter. However, percentage of S (correlated with %P) best predicted the abundance of collembola, oribatids, and diplopods (r² = 0.38, 0.33, 0.21, respectively). In the Structural Elements Hypotheses, N and Ca limit the abundance of silk-spinning and calcareous taxa, respectively. Mesostigmatids, pseudoscorpions, and spiders, all known to make silk, each increased with percentage of N of litter (r² = 0.22, 0.31, 0.26, respectively). Calcareous isopods, but not diplopods, increased with percentage of Ca of litter (r² = 0.59). In the Ecosystem Size Hypothesis, top predators are limited by available space. The abundance of the three remaining predators, chilopods, staphylinids, and ants, increased with litter depth (r² = 0.31, 0.74, 0.69, respectively), and food webs from forests with deeper litter supported a higher ratio of predators to microbivores. These results suggest that biogeochemical gradients can provide a mechanism, through stoichiometry and trophic theory, shaping the geography of community structure.
ISSN:0012-9658
1939-9170
DOI:10.1890/08-1795.1