Abstract
To explain the differences in microbial diversity between soil from termite mounds and their nearby soils, we evaluated the impact of termite biopedturbation on the respiration profiles of microorganisms from termite mound soils. The MicroRespTM technique was employed to assess the whole-soils’ community-level-physiological-profiles (CLPP) assays using 21 carbon substrates chosen on the ground of significance to biotas dwellings in the soil. Principal component analyses showed that carbon substrate groups in the soils from termite mound were separated from those of the nearby soils. The results supported our first premise that the CLPP of soils from termite mounds could be distinguishable from the CLPP of the nearby soil and the degree of the differences was based on which substrates were added in the analysis. The assumption that any variance established in the CLPP could be attributed to a higher use of structurally complex carbon substrates in soils from termite mounds compared to the nearby soil samples was also supported. The higher soil respiration and the capacity to degrade carbon sources in soils from termite mounds than the nearby soil samples connote a rise in microbial functional diversity due to the differences in the diversity of microorganisms between both habitats.
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B.J.E appreciates NRF-TWAS (UID110909) for PhD stipend. A.E.A. appreciates NWU for postdoctoral fellowship. O.O.B acknowledges funding (Grants Ref: UID123634 and UID132595) acquisition from The NRF, South Africa.
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This study was sponsored by RSA-NRF (UID123634 and UID132595).
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This is part of B.J.E. PhD study. A.E.A. assisted in analysis. O.O.B. designed the research, critically revised the manuscript drafts, and as the principal investigator brought B.J.E and A.E.A into the project, and funded the study.
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Enagbonma, B.J., Amoo, A.E. & Babalola, O.O. Biopedturbation by Termites Affects Respiration Profiles of Microbial Communities from Termite Mound Soils. J Soil Sci Plant Nutr 21, 2115–2123 (2021). https://doi.org/10.1007/s42729-021-00507-y
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DOI: https://doi.org/10.1007/s42729-021-00507-y