Adaptive Multi-Paddock Grazing Lowers Soil Greenhouse Gas Emission Potential by Altering Extracellular Enzyme Activity

Adaptive multi-paddock (AMP) grazing is a form of rotational grazing in which small paddocks are grazed with high densities of livestock for short periods, with long recovery periods prior to regrazing. We compared the fluxes of greenhouse gases (GHGs), including carbon dioxide (CO₂), methane (CH₄), and nitrous oxide (N₂O), from soils of AMP-grazed grasslands to paired neighboring non-AMP-grazed grasslands across a climatic gradient in Alberta, Canada. We further tested GHG responses to changes in temperature (5 °C vs. 25 °C) and moisture levels (permanent wilting point (PWP), 40% of field capacity (0.4FC), or field capacity (FC)) in a 102-day laboratory incubation experiment. Extracellular enzyme activities (EEA), microbial biomass C (MBC) and N (MBN), and available-N were also measured on days 1, 13, and 102 of the incubation to evaluate biological associations with GHGs. The 102-day cumulative fluxes of CO₂, N₂O, and CH₄ were affected by both temperature and moisture content (<i>p</i> < 0.001). While cumulative fluxes of N₂O were independent of the grazing system, CH₄ uptake was 1.5 times greater in soils from AMP-grazed than non-AMP-grazed grasslands (<i>p</i> < 0.001). There was an interaction of the grazing system by temperature (<i>p</i> < 0.05) on CO₂ flux, with AMP soils emitting 17% more CO₂ than non-AMP soils at 5 °C, but 18% less at 25 °C. The temperature sensitivity (Q₁₀) of CO₂ fluxes increased with soil moisture level (i.e., PWP < 0.4FC ≤ FC). Structural equation modelling indicated that the grazing system had no direct effect on CO₂ or N₂O fluxes, but had an effect on CH₄ fluxes on days 1 and 13, indicating that CH₄ uptake increased in association with AMP grazing. Increasing soil moisture level increased fluxes of GHGs—directly and indirectly—by influencing EEAs. Irrespective of the grazing system, the MBC was an indirect driver of CO₂ emissions and CH₄ uptake through its effects on soil EEAs. The relationships of N-acetyl-β glucosaminidase and β-glucosidase to N₂O fluxes were subtle on day 1, and independent thereafter. AMP grazing indirectly affected N₂O fluxes by influencing N-acetyl-β glucosaminidase on day 13. We conclude that AMP grazing has the potential to mitigate the impact of a warmer soil on GHG emissions by consuming more CH₄ compared to non-AMP grazing in northern temperate grasslands, presumably by altering biogeochemical properties and processes.