Arctic soil creatures respond unpredictably to warming, threatening nutrient cycles
Researchers warmed tundra soil ecosystems up to 9°C and found that soil organisms—nematodes and microarthropods—responded in contradictory ways, with some thriving and others collapsing. Since these creatures control how nutrients cycle and organic matter breaks down in frozen regions, their chaotic responses under warming could destabilize carbon storage and food webs across the Arctic, complicating climate-impact predictions.
Originaltitel: Effects of multi-level warming on soil nematodes and microarthropods in tundra heath mesocosms
Soil fauna, including nematodes and microarthropods (mites and springtails), regulate nutrient cycling and decomposition, yet their responses to warming remain unclear in temperature-sensitive tundra ecosystems. We experimentally warmed intact tundra heath monoliths from northern Sweden under five temperature treatments (ambient to +9 °C) for 20 weeks. Monoliths were dominated by either Betula nana or Empetrum nigrum subsp. hermaphroditum . After incubation, we quantified nematode and microarthropod densities and community composition. Warming altered both nematode and microarthropod communities, with responses mediated by vegetation type, trophic group, and taxon. Microarthropods densities were generally more sensitive to warming, especially under the dominance of E. nigrum , whereas nematode communities showed stronger compositional shifts. Overall nematode densities were stable across warming levels, except for fungivorous nematodes, which decreased linearly with warming. In contrast, total and carnivorous microarthropod densities increased linearly with warming, while springtails and fungivorous microarthropods displayed non-linear, U-shaped responses. Together, these results demonstrate that soil fauna responses to warming range from negligible to linear and non-linear, underscoring the importance of experimental designs that span multiple warming levels. The strong dependence of these responses on vegetation context and trophic identity emphasizes the need to account for local environmental heterogeneity when predicting tundra ecosystem responses to climate change. • Responses of tundra soil fauna observed were tested under five levels of warming. • Non-linearity and context dependence characterized soil fauna responses to warming. • Microarthropods shifted in density, nematodes shifted mainly in community composition. • Soil fauna showed greater sensitivity to warming in Empetrum nigrum -dominated soil.