Microbial community shifts reflect losses of native soil carbon with pyrogenic and fresh organic matter additions and are greatest in low-carbon soils

Thea Whitman; Silene DeCiucies; Kelly Hanley; Akio Enders; Jamie Woolet; Johannes Lehmann

doi:10.1128/AEM.02555-20

Microbial community shifts reflect losses of native soil carbon with pyrogenic and fresh organic matter additions and are greatest in low-carbon soils

Appl Environ Microbiol. 2021 Apr 15;87(8):e02555-20. doi: 10.1128/AEM.02555-20. Epub 2021 Jan 29.

Authors

Thea Whitman^{1

2}, Silene DeCiucies², Kelly Hanley², Akio Enders², Jamie Woolet³, Johannes Lehmann^{2

4}

Affiliations

¹ Department of Soil Science, University of Wisconsin, Madison, WI 53706, USA twhitman@wisc.edu.
² Soil and Crop Sciences, School of Integrative Plant Science, Cornell University, Ithaca, NY 14850, USA.
³ Department of Soil Science, University of Wisconsin, Madison, WI 53706, USA.
⁴ Atkinson Center for a Sustainable Future, Cornell University, Ithaca, NY 149850, USA.

Abstract

Soil organic carbon (SOC) plays an important role in regulating global climate change, carbon and nutrient cycling in soils, and soil moisture. Organic matter (OM) additions to soils can affect the rate at which SOC is mineralized by microbes, with potentially important effects on SOC stocks. Understanding how pyrogenic organic matter (PyOM) affects the cycling of native SOC (nSOC) and the soil microbes responsible for these effects is important for fire-affected ecosystems as well as for biochar-amended systems. We used an incubation trial with five different soils from National Ecological Observatory Network sites across the US and ¹³C-labelled 350°C corn stover PyOM and fresh corn stover OM to trace nSOC-derived CO₂ emissions with and without PyOM and OM amendments. We used high-throughput sequencing of rRNA genes to characterize bacterial, archaeal, and fungal communities and their response to PyOM and OM in soils that were previously stored at -80°C. We found that the effects of amendments on nSOC-derived CO₂ reflected the unamended soil C status, where relative increases in C mineralization were greatest in low-C soils. OM additions produced much greater effects on nSOC-CO₂ emissions than PyOM additions. Furthermore, the magnitude of microbial community composition change mirrored the magnitude of increases in nSOC-CO₂, indicating a specific subset of microbes were likely responsible for the observed changes in nSOC mineralization. However, PyOM responders differed across soils and did not necessarily reflect a common "charosphere". Overall, this study suggests that soils that already have low SOC may be particularly vulnerable to short-term increases in SOC loss with OM or PyOM additions.Importance Soil organic matter (SOM) has an important role in global climate change, carbon and nutrient cycling in soils, and soil moisture dynamics. Understanding the processes that affect SOM stocks is important for managing these functions. Recently, understanding how fire-affected organic matter (or "pyrogenic" organic matter (PyOM)) affects existing SOM stocks has become increasingly important, both due to changing fire regimes, and to interest in "biochar" - pyrogenic organic matter that is produced intentionally for carbon management or as an agricultural soil amendment. We found that soils with less SOM were more prone to increased losses with PyOM (and fresh organic matter) additions, and that soil microbial communities changed more in soils that also had greater SOM losses with PyOM additions. This suggests that soils that already have low SOM content may be particularly vulnerable to short-term increases in SOM loss, and that a subset of the soil microbial community is likely responsible for these effects.