期刊
SOIL BIOLOGY & BIOCHEMISTRY
卷 177, 期 -, 页码 -出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.soilbio.2022.108893
关键词
Microbial biodiversity; Soil carbon; Ecological strategy; Ecosystem modeling
类别
Soil carbon feedbacks to global change are uncertain. Current ecosystem models fail to resolve the biological processes that govern soil organic matter decomposition. Incorporating microbial biodiversity into ecosystem models is challenging due to the high diversity of microbial communities. A new framework called Carbon Acquisition Ecological Strategies (CAES) is proposed to enhance predictions of soil carbon feedbacks by focusing on functional groups or ecological strategies.
Soil carbon feedbacks to global change are uncertain, and the biological processes that govern soil organic matter decomposition are not resolved in current ecosystem models. Though it is recognized that microbial biodiversity influences decomposition rates, incorporating this relationship into ecosystem models is challenging because microbial communities are prohibitively diverse. It is likely necessary to distill microbial biodiversity by focusing on functional groups or ecological strategies. The ecological strategies that currently dominate the microbial ecology literature derive from macroecological theory, have clear weaknesses, and have had limited success when applied to predict soil carbon dynamics. Here, we present a new framework for soil microorganisms: Carbon Acquisition Ecological Strategies (CAES), and we outline a path toward incorporating microbial biodi-versity into ecosystem models using this framework to enhance predictions of soil carbon feedbacks to global change. Because a microorganism's diet is central to its ecological niche and likely to covary with other ecologically significant traits, we posit that carbon acquisition may serve as a tractable foundation for developing ecological strategies. We describe four candidate ecological strategies for soil microorganisms: 1 degrees decomposers that assimilate complex plant polymers, 2 degrees decomposers that assimilate microbial necromass, passive consumers that assimilate dissolved organic carbon, and predatory microbes that assimilate live microbial biomass. These strategies are directly linked to soil carbon pools currently represented in ecosystem models and may provide a foundation for greater integration of microbial community dynamics into ecosystem models.
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