Bison and cattle grazing influences on soil microbial N cycling and ecosystem N pools in annually burned tallgrass prairies
Date
Authors
Journal Title
Journal ISSN
Volume Title
Publisher
Abstract
Nitrogen (N) cycling is soil microbially mediated and essential for soil fertility. Grazing animals are integral to N cycling in grassland systems, especially historically grazed grasslands like the tallgrass prairie ecosystem which supported large populations of bison pre-colonization. Grazing animals impact the N cycle by recycling forage through consumption and deposition of more bioavailable N to the soil, promoting soil fertility. However, bison and cattle may have different impacts on N cycling due to differences in management, physiology, and behavior. Further comparative impacts of bison and cattle grazing on N cycling in tallgrass prairie have not been investigated. I predicted that N cycling microbial activities and plant and soil N pools would be similarly higher under both types of grazing relative to ungrazed conditions. To evaluate these predictions, I sampled upland mineral soils in annually burned bison-grazed, cattle-grazed, and ungrazed experimental tallgrass prairie watersheds at the Konza Prairie Biological Station near Manhattan, KS, USA, over the 2020-2022 summer growing seasons; and measured soil characteristics, N availability indices, microbial N cycling activity rate potentials, and N pools including total soil N, soil microbial biomass N, and aboveground primary productivity and forage N uptake within moveable exclosures with paired ungrazed plots. Overall, soil N cycling rates in bison-grazed watersheds were higher than in ungrazed watersheds, and generally intermediate between the two in cattle-grazed watersheds. Under bison, there was higher soil pH, plant available N, lower extracellular enzyme activity estimated N limitation, and greater nitrification and denitrification potential than in ungrazed soils, though effects on denitrification were weaker than on N mineralization and nitrification. Forage N content, soil N concentration and N stock was also higher under bison grazing than in cattle grazed or ungrazed conditions. Interannual variability in microbial N cycling was high, and likely related to higher precipitation and soil moisture in 2020 than 2021 and 2022 but did not change grazing effects. However, dung N content did not differ between the two grazers, and forage production and N uptake into grass was significantly greater under cattle than bison grazing. In conclusion, while ungrazed soils had lower N-cycling rates and higher C:N ratios than either bison or cattle grazed soils, both soil fertility and forage quality was consistently greater under bison than cattle grazing. Results show that higher grass %N under bison grazing is related to more plant available N, accelerated soil N cycling rates, and a larger soil N stock, showing that stronger grazer-plant-soil fertility feedbacks exist in bison-grazed prairie than cattle-grazed prairie. Differences may be attributed either to animal physiology and behavior, and/or to greater grazing pressure from bison than cattle due to different management. This investigation establishes that relationships between animal and soil microbial processes mediate terrestrial N cycling in tallgrass prairie, and may be used to inform cattle and bison rangeland management decisions.