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Response of the soil microbial biomass to glucose and selective inhibitors across a soil moisture gradient

Wardle, D.A.; Parkinson, D.

Soil Biology and Biochemistry 22(6): 825-834

1990

ISSN/ISBN: 0038-0717
DOI: 10.1016/0038-0717(90)90163-t
Accession: 007751671

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Summary
Methods for investigating the glucose-sensitive component of the soil microbial biomass were applied to soils held at five separate soil moisture contents (i.e. 15, 25, 35, 45 or 55%) following incubation for 6 h and 3, 10 or 30 days. The O2 uptake method proposed by Van de Werf and Verstraete (1987a, b) for measuring "active" (glucose-sensitive) microbial biomass predicted that this biomass increased with increased moisture status, except for samples that had been previously incubated for 30 days. However, measurements of the glucose-sensitive microbial biomass using total O2 uptake over 10 h following glucose addition [as proposed by Van de Werf and Vestraete (1987a, b)] appears to be influenced in part by decomposition of microbial biomass killed by prior incubation at low moisture contents, especially between hours 4 and 10. It is proposed that the total O2 uptake in the first 2-4 h following glucose addition is a superior indicator of the response of the soil microbial biomass to soil moisture. Substrate-induced respiration (SIR) and selective inhibition are also proposed for studying the glucose-responsive component of the soil microbial biomass. Selective inhibition checks microbial protein synthesis of this glucose-sensitive component. The inhibition of SIR by either bacterial or fungal selective inhibitors was largely independent of soil moisture content when samples were remoistened simultaneously with sample amendment, but was strongly related with soil moisture when samples were not remoistened. The bacterial-fungal ratios derived from these data were typically unaffected by soil moisture.

References

Wardle, D.A.; Parkinson, D. 1990: Comparison of physiological techniques for estimating the response of the soil microbial biomass to soil moisture Soil Biology and Biochemistry 22(6): 817-824
Zhao, B.; Chen, J.; Zhang, J.; Qin, S. 2010: Soil microbial biomass and activity response to repeated drying-rewetting cycles along a soil fertility gradient modified by long-term fertilization management practices Geoderma 160.2
Bingzi, Z.H.A.O.; Ji, C.H.E.N.; Jiabao, Z.H.A.N.G.; Shengwu, Q.I.N. 2010: Soil microbial biomass and activity response to repeated drying―rewetting cycles along a soil fertility gradient modified by long-term fertilization management practices Geoderma (Amsterdam) 160(2): 218-224
Xu, X.; Yin, L.; Duan, C.; Jing, Y. 2016: Effect of N addition, moisture, and temperature on soil microbial respiration and microbial biomass in forest soil at different stages of litter decomposition Journal of Soils and Sediments 16(5): 1421-1439
He, Y.; Li, C.-T.; Yu, Y.-C.; He, H.-P.; Tao, X. 2021: Variation of subtropical forest soil microbial biomass and soil microbial community functional characteristics along an urban-rural gradient Ying Yong Sheng Tai Xue Bao 32(1): 93-102
Li ShiQing; Ren ShuJie; Li ShengXiu 2004: Seasonal changes of soil microbial biomass N and its relation with soil moisture and temperature Plant Nutrition and Fertilizer Science 10(1): 18-23
Li, F; Liu, M; Li, Z; Jiang, C; Han, F; Che, Y 2013: Changes in soil microbial biomass and functional diversity with a nitrogen gradient in soil columns Applied Soil Ecology 64: 1-6
Sato, A; Tsuyuzaki, T; Seto, M 2000: Effect of Soil Agitation, Temperature or Moisture on Microbial Biomass Carbon of a Forest and an Arable Soil Microbes and Environments 15(1): 23-30
Ding, S.; Wang, C.-k. 2009: Soil microbial biomass in Larix gmelinii forests along a latitudinal gradient during spring soil thawing Ying Yong Sheng Tai Xue Bao 20(9): 2072-2078
Veen, J.A. van; Ladd, J.N.; Amato, M. 1985: Turnover of carbon and nitrogen through the microbial biomass in a sandy loam and a clay soil incubated with glucose and (NH4)2SO4 under different moisture regimes Soil Biology and Biochemistry 17(6): 747-756
Baldrian, P.; Merhautova, V.; Petrankova, M.; Cajthaml, T.; Snajdr, J. 2010: Distribution of microbial biomass and activity of extracellular enzymes in a hardwood forest soil reflect soil moisture content Applied Soil Ecology 46(2): 177-182
Wang, Y.-gang; Zhu, H.; Li, Y. 2013: Spatial heterogeneity of soil moisture, microbial biomass carbon and soil respiration at stand scale of an arid scrubland Environmental Earth Sciences 70(7): 3217-3224
Ross, D.J. 1987: Soil microbial biomass estimated by the fumigation incubation procedure seasonal fluctuations and influence of soil moisture content Soil Biology and Biochemistry 19(4): 397-404
Rocha, S.M.B.; Antunes, J.E.L.; Araujo, F.F.DE.; Mendes, L.W.; Sousa, R.S.DE.; Araujo, A.S.F.DE. 2019: Soil microbial C:N:P ratio across physiognomies of Brazilian Cerrado Soil microbial biomass across a gradient of preserved native Cerrado Anais da Academia Brasileira de Ciencias 91(4): E20190049
Ma, L.; Guo, C.; Lü, X.; Yuan, S.; Wang, R. 2015: Soil moisture and land use are major determinants of soil microbial community composition and biomass at a regional scale in northeastern China Biogeosciences 12(8): 2585-2596
Globus, A.; Rozenshtok, S. 1979: Effect of soil moisture on the interrelationship between intensity of soil moisture movement, caused by temperature gradient, and soil solution concentration Doklady 244(2): 458-461
Globus, A.M.; Rozenshtok, S.K. 1979: The effect of soil moisture content on the interrelationship between the concentration of the soil solution and the movement of soil moisture under the action of a temperature gradient Doklady Akademii Nauk SSSR 244(2): 458-461
Elmajdoub, B.; Marschner, P. 2015: Response of microbial activity and biomass to soil salinity when supplied with glucose and cellulose Journal of Soil Science and Plant Nutrition 15(4): 816-832