Journal
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
Volume 115, Issue 52, Pages 13306-13311Publisher
NATL ACAD SCIENCES
DOI: 10.1073/pnas.1809790115
Keywords
termite mounds; methane oxidation; methanotrophs; termite biomass; methane emissions
Categories
Funding
- Australian Research Council [DP120101735, LP100100073]
- Terrestrial Ecosystem Research Network (TERN) OzFlux
- TERN Australian SuperSite Network
- Swiss National Science Foundation [P2EZP3_155596]
- Swiss National Science Foundation (SNF) [P2EZP3_155596] Funding Source: Swiss National Science Foundation (SNF)
- Australian Research Council [LP100100073] Funding Source: Australian Research Council
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Termites are responsible for similar to 1 to 3% of global methane (CH4) emissions. However, estimates of global termite CH4 emissions span two orders of magnitude, suggesting that fundamental knowledge of CH4 turnover processes in termite colonies is missing. In particular, there is little reliable information on the extent and location of microbial CH4 oxidation in termite mounds. Here, we use a one-box model to unify three independent field methods-a gas-tracer test, an inhibitor approach, and a stable-isotope technique- and quantify CH4 production, oxidation, and transport in three North Australian termite species with different feeding habits and mound architectures. We present systematic in situ evidence of widespread CH4 oxidation in termite mounds, with 20 to 80% of termite-produced CH4 being mitigated before emission to the atmosphere. Furthermore, closing the CH4 mass balance in mounds allows us to estimate in situ termite biomass from CH4 turnover, with mean biomass ranging between 22 and 86 g of termites per kilogram of mound for the three species. Field tests with excavated mounds show that the predominant location of CH4 oxidation is either in the mound material or the soil beneath and is related to species-specific mound porosities. Regardless of termite species, however, our data and model suggest that the fraction of oxidized CH4 (fox) remains well buffered due to links among consumption, oxidation, and transport processes via mound CH4 concentration. The mean f(ox) of 0.50 +/- 0.11 (95% CI) from in situ measurements therefore presents a valid oxidation factor for future global estimates of termite CH4 emissions.
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