Litcius/Paper detail

Soil organic matter, rather than temperature, determines the structure and functioning of subarctic decomposer communities

Sinikka I. Robinson, Eoin J. O’Gorman, Beat Frey, Marleena Hagner, Juha Mikola

2022Global Change Biology30 citationsDOIOpen Access PDF

Abstract

The impacts of climate change on ecosystem structure and functioning are likely to be strongest at high latitudes due to the adaptation of biota to relatively low temperatures and nutrient levels. Soil warming is widely predicted to alter microbial, invertebrate, and plant communities, with cascading effects on ecosystem functioning, but this has largely been demonstrated over short-term (<10 year) warming studies. Using a natural soil temperature gradient spanning 10-35°C, we examine responses of soil organisms, decomposition, nitrogen cycling, and plant biomass production to long-term warming. We find that decomposer organisms are surprisingly resistant to chronic warming, with no responses of bacteria, fungi, or their grazers to temperature (fungivorous nematodes being an exception). Soil organic matter content instead drives spatial variation in microorganism abundances and mineral N availability. The few temperature effects that appear are more focused: root biomass and abundance of root-feeding nematodes decrease, and nitrification increases with increasing soil temperature. Our results suggest that transient responses of decomposers and soil functioning to warming may stabilize over time following acclimation and/or adaptation, highlighting the need for long-term, ecosystem-scale studies that incorporate evolutionary responses to soil warming.

Topics & Concepts

DecomposerEnvironmental scienceEcologyEcosystemSubarctic climateBiomass (ecology)Soil biologySoil organic matterGlobal warmingNutrient cycleNitrogen cycleSoil ecologySoil biodiversityBiologyClimate changeSoil waterChemistryNitrogenOrganic chemistrySoil Carbon and Nitrogen DynamicsPolar Research and EcologyPlant responses to elevated CO2
Soil organic matter, rather than temperature, determines the structure and functioning of subarctic decomposer communities | Litcius