Comparable early-stage decomposition but contrasting underlying drivers between surface and cave habitats along an elevational gradient

• Published in: Ecological indicators Vol. 154; p. 110607
• Main Authors: Bodawatta, Kasun H., Ravn, Nynne, Oromí, Pedro, Esquivel, José Luis Martin, Michelsen, Anders, Poulsen, Michael, Jønsson, Knud Andreas, Reboleira, Ana Sofia
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.10.2023; Elsevier
• Subjects: Canary Islands; carbon; carbon sequestration; Decomposition; ecosystem respiration; Elevational gradient; global carbon budget; Microbiome; nutrient availability; Nutrient recycling; Subterranean ecosystems; Elevational gradient; Subterranean ecosystems; Canary Islands; Decomposition; Nutrient recycling; Microbiome
• ISSN: 1470-160X
• DOI: 10.1016/j.ecolind.2023.110607

[Display omitted] •Decomposition was studied at surface and in caves along an elevational gradient.•Overall decomposition levels were comparable in above and below ground habitats.•At the surface abiotic and biotic factors correlate only with decomposition rate.•In caves abiotic and biotic parameters are associated with stabilizing factor.•Current predictions underestimate the net carbon budget in areas with caves. Decomposition is a major contributor to ecosystem respiration, determining the carbon emission and nutrient cycling rates. Our current understanding of decomposition dynamics and their underlying drivers has mainly focused on surface habitats but largely ignored in subterranean environments. Here we studied abiotic and microbial drivers of early-stage litter decomposition inside and outside caves along an elevational gradient in Tenerife. We found comparable decomposition rates (k) and litter stabilizing factors (S), with contrasting drivers and elevational variation. At the surface, we observed a mid-elevational trend in k, which tended to correlate with water availability, cooler temperatures, nutrient availability, and surface-specific bacterial taxa. In sharp contrast, caves showed no elevational impact nor influence of abiotic parameters and bacterial communities on k. Despite this, we found higher levels of S in caves, which were associated mainly with reduced water availability, lower temperatures and cave-specific bacterial taxa, indicating that conditions in caves are strongly linked with carbon storage. Our findings imply that our current perception of terrestrial habitat-based carbon cycling are underestimating the net carbon budget in areas with caves. Disentangling the role of the environment on decomposition in caves is key to fully characterize their roles in nutrient cycling and to understand how increasing anthropogenic pressures will affect fundamental processes in subterranean ecosystems.