Authors: Elsa Abs, Scott R. Saleska, Steven D. Allison, Philippe Ciais, Yang Song, Michael N. Weintraub, Regis Ferriere
Published: 2025-06-20
DOI: 10.1111/gcb.70301
Source: Full article
ABSTRACTWarming alters soil microbial traits through ecological and evolutionary processes, directly influencing the decomposition of organic matter, which significantly affects global soil carbon emissions. Yet, soil carbon models largely ignore these processes and their implications for global responses to warming. Here, we incorporate eco‐evolutionary theory into a mechanistic model describing microbial soil carbon decomposition to address the question of whether such processes could have consequential effects on climate carbon feedbacks globally. We assume that a key trait of microbes, their resource allocation to production of exoenzymes (which facilitate decomposition of organic matter)—is optimized to environmental temperatures by natural selection. We find that eco‐evolutionary optimization results in microbes allocating more resources to enzyme production under warming. When applied at the global scale, eco‐evolutionary optimization enhances the biological realism of soil carbon models and significantly amplifies global soil carbon loss by 2100. Our results highlight the significant potential of microbial eco‐evolutionary responses to influence carbon cycle feedbacks to climate change, and motivate an urgent need for more comprehensive data to accurately quantify the adaptive potential of microbiomes in response to climate change.