Abstract
Decomposition of vertebrate remains is a dynamic process that creates localized soil enrichment zones. A growing body of literature has documented effects of vertebrate decomposition on soil pH, electrical conductivity, oxygen levels, nitrogen and carbon speciation, microbial biomass, and microbial successional patterns. However, relatively few studies have examined the microfaunal members of the soil food web that function as secondary consumers, specifically nematodes. Nematodes are often used as indicators of enrichment in other systems, and initial observations from vertebrate decomposition zones have indicated there is an effect on nematode communities. Our goal was to catalog decomposition-induced nematode succession and changes to alpha, beta, and functional diversity, and identify potential indicator taxa associated with decomposition progression. Six adult beaver (Castor canadensis) carcasses were allowed to decompose in a forest ecosystem for one year. During this period soil temperature, moisture, and electrical conductivity were monitored. Soils samples were taken at two depths in order to assess nematode community dynamics: 30-cm cores and 1-cm interface samples. Nematode abundance, alpha, beta, and functional diversity all responded to soil enrichment at the onset of active decay, and impacts persisted through skeletonization. After one year, nematode abundances and alpha diversity had recovered to original levels, however both community membership and functional diversity remained significantly altered. We identified seven indicator taxa that marked major transitions in decomposition progression. Enrichment of Rhabditidae (B1) and Diplogasteridae (B1) coupled with depletion in Filenchus (F2) characterized active and advanced decay prior to skeletonization in both cores and interface soils. Enrichment of Acrobeloides (B2), Aphelenchoides (F2), Tylencholaimidae (F4) and Seinura (P2) occurred during a narrow period in mid-skeletonization (day 153). Our study has revealed soil nematode successional patterns during vertebrate decomposition and has identified organisms that may function as indicator taxa for certain periods during decomposition.
Highlights
Decomposition of vertebrate remains is a dynamic process that creates localized soil enrichment zones
While nematode community composition has been evaluated over a variety of agricultural and field conditions, few studies have explored responses associated with vertebrate hotspots [24,26,27,28,35,36,37,38,39,40,41,42,43]
We identified potential indicator taxa associated with decomposition progress
Summary
Decomposition of vertebrate remains is a dynamic process that creates localized soil enrichment zones. These biogeochemical hotspots exhibit increased rates of nutrient cycling which are short-lived in comparison with surrounding areas [1,2]. In comparison with soil chemistry and microbial studies, targeted examination of multicellular soil faunas, microfaunal members of the soil food web that function as secondary consumers of these resources, have received the least attention [but see 20–24]
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