Effect of prescribed burning on the small-scale spatial heterogeneity of soil microbial biomass in Pinus koraiensis and Quercus mongolica forests of China

doi:10.1007/s11676-022-01516-y

Abstract

Abstract:

Prescribed burning can alter soil microbial activity and spatially redistribute soil nutrient elements. However, no systematic, in-depth studies have investigated the impact of prescribed burning on the spatial patterns of soil microbial biomass in temperate forest ecosystems in Northeast China. The present study investigated the impacts of prescribed burning on the small-scale spatial heterogeneity of microbial biomass carbon (MBC) and microbial biomass nitrogen (MBN) in the upper (0–10 cm) and lower (10–20 cm) soil layers in Pinus koraiensis and Quercus mongolica forests and explored the factors that influence spatial variations of these variables after prescribed burning. Our results showed that, MBC declined by approximately 30% in the 10–20 cm soil layer in the Q. mongolica forest, where there were no significant effects on the soil MBC and MBN contents of the P. koraiensis forest (p > 0.05) after prescribed burning. Compared to the MBC of the Q. mongolica forest before the prescribed burn, MBC spatial dependence in the upper and lower soil layers was approximately 7% and 2% higher, respectively. After the prescribed burn, MBN spatial dependence in the upper and lower soil layers in the P. koraiensis forest was approximately 1% and 13% lower, respectively, than that before the burn, and the MBC spatial variability in the 0–10 cm soil layer in the two forest types was explained by the soil moisture content (SMC), whereas the MBN spatial variability in the 0–10 cm soil layer in the two forests was explained by the soil pH and nitrate nitrogen (NO₃ ^–-N), respectively. In the lower soil layer (10–20 cm) of the Q. mongolica forest, elevation and ammonium nitrogen (NH₄ ⁺-N) were the main factors affecting the spatial variability of MBC and MBN, respectively. In the 10–20 cm soil layer of the P. koraiensis forest, NO₃ ^–-N and slope were the main factors affecting the spatial variability of MBC and MBN, respectively, after the burn. The spatial distributions of MBC and MBN in the two forests were largely structured with higher spatial autocorrelation (relative structural variance C/[C ₀ + C] > 0.75). However, the factors influencing the spatial variability of MBC and MBN in the two forest types were not consistent between the upper and lower soil layers with prescribed burning. These findings have important implications for developing sustainable management and conservation policies for forest ecosystems.

Key words: Prescribed burn, Soil microbial biomass, Spatial heterogeneity, Temperate forest

Xu Dou, Hongzhou Yu, Jianyu Wang, Fei Li, Qi Liu, Long Sun, Tongxin Hu. Effect of prescribed burning on the small-scale spatial heterogeneity of soil microbial biomass in Pinus koraiensis and Quercus mongolica forests of China[J]. JOURNAL OF FORESTRY RESEARCH, 2023, 34(3): 609-622.

Xu Dou, Hongzhou Yu, Jianyu Wang, Fei Li, Qi Liu, Long Sun, Tongxin Hu. [J]. 林业研究(英文版), 2023, 34(3): 609-622.

References 80

1	Ahn JH, Song J, Kim BY, Kim MS, Joa JH, Weon HY. Characterization of the bacterial and archaeal communities in rice field soils subjected to long-term fertilization practices. J Appl Microbiol, 2012, 50: 754-765
2	Akburak S, Son Y, Makineci E, Çakir M. Impacts of low-intensity prescribed fire on microbial and chemical soil properties in a Quercus frainetto forest. J For Res, 2018, 29(3): 687-696, DOI
3	Bastias BA, Xu Z, Cairney JWG. Influence of long-term repeated prescribed burning on mycelial communities of ectomycorrhizal fungi. New Phytol, 2006, 172: 149-158, DOI
4	Boisramé G, Thompson S, Stephens S. Hydrologic responses to restored wildfire regimes revealed by soil moisture–vegetation relationships. Adv Water Resour, 2018, 112: 124-146, DOI
5	Brookes PC, Landman A, Pruden G, Jenkinson DS. Chloroform fumigation and the release of soil nitrogen: a rapid direct extraction method to measure microbial biomass nitrogen in soil. Soil Biol Biochem, 1985, 17: 837-842, DOI
6	Bru D, Ramette A, Saby NPA, Dequiedt S, Ranjard L, Jolivet C, Arrouays D, Philippot L. Determinants of the distribution of nitrogen-cycling microbial communities at the landscape scale. ISME J, 2010, 5: 532-542, DOI
7	Burrows N, McCaw L. Prescribed burning in southwestern Australian forests. Front Ecol Environ, 2013, 11: e25-e34, DOI
8	Butler OM, Lewis T, Chen C. Fire alters soil labile stoichiometry and litter nutrients in Australian eucalypt forests. Int J Wildland Fire, 2017, 26: 783-788, DOI
9	Byram GM. Davis KP. Forest fire behavior. Forest fire: control and use, 1959 New York McGraw-Hill 90-123
10	Cai WH, Yang J, Liu ZH, Hu YM, Weisberg PJ. Post-fire tree recruitment of a boreal larch forest in Northeast China. For Ecol Manag, 2013, 307: 20-29, DOI
11	Cairney JWG, Bastias BA. Influences of fire on forest soil fungal communities. Can J for Res, 2007, 37: 207-215, DOI
12	Choromanska U, DeLuca TH. Prescribed fire alters the impact of wildfire on soil biochemical properties in a ponderosa pine forest. Soil Sci Soc Am J, 2001, 65: 232-238, DOI
13	Deutsch CV, Journel AG. Geostatistical software library and user’s guide, 1992 New York Oxford University Press
14	Dooley SR, Treseder KK. The effect of fire on microbial biomass: a meta-analysis of field studies. Biogeochemistry, 2012, 109: 49-61, DOI
15	Eldridge DJ, Travers SK, Val J, Wang JT, Liu H, Singh BK. Grazing regulates the spatial heterogeneity of soil microbial communities within ecological networks. Ecosystems, 2020, 23: 932-942, DOI
16	Elith J, Leathwick JR, Hastie TA. working guide to boosted regression trees. J Anim Ecol, 2008, 77: 802-813, DOI
17	González-Pérez JA, González-Vila FJ, Almendros G, Knicker H. The effect of fire on soil organic matter—a review. Environ Int, 2004, 30: 855-870, DOI
18	Goovaerts P. Geostatistical modelling of uncertainty in soil science. Geoderma, 2001, 103: 3-26, DOI
19	Grady KC, Hart SC. Influences of thinning, prescribed burning, and wildfire on soil processes and properties in southwestern ponderosa pine forests: A retrospective study. For Ecol Manag, 2006, 234: 123-135, DOI
20	Green JL, Holmes AJ, Westoby M, Oliver I, Briscoe D, Dangerfield M, Beattie AJ. Spatial scaling of microbial eukaryote diversity. Nature, 2004, 432: 747, DOI
21	Grosjean P, Ibanez F, Etienne M. Pastecs: Package for Analysis of Space-Time Ecological Series. R Package Version, 2014, 1: 3-18
22	Gundale MJ, Deluca TH, Fiedler CE, Ramsey PW, Gannon JE. Restoration treatments in a Montana ponderosa pine forest: effects on soil physical, chemical and biological properties. For Ecol Manag, 2005, 213: 25-38, DOI
23	Hanan EJ, Tague C, Schimel JP. Nitrogen cycling and export in California chaparral: the role of climate in shaping ecosystem responses to fire. Ecol Monogr, 2017, 87: 76-90, DOI
24	Harden JW, Mack M, Veldhuis H, Gower ST (2002) Fire dynamics and implications for nitrogen cycling in boreal forests. J Geophys Res Atmos 107: WFX 4–1–WFX 4–8.
25	Hernández DL, Hobbie SE. Effects of fire frequency on oak litter decomposition and nitrogen dynamics. Oecologia, 2008, 158: 535-543, DOI
26	Hicke JA, Allen CD, Desai AR, Dietze MC, Hall RJ, Hogg EH, Vogelmann J. Effects of biotic disturbances on forest carbon cycling in the United States and Canada. Glob Chang Biol, 2012, 18: 7-34, DOI
27	Hobbie SE. Effects of plant species on nutrient cycling. Trends Ecol Evol, 1992, 7: 336-339, DOI
28	Hu TX, Hu HQ, Li F, Zhao BQ, Wu S, Zhu GY, Sun L. Long-term effects of post-fire restoration types on nitrogen mineralisation in a Dahurian larch (Larix gmelinii) forest in boreal China. Sci Total Environ, 2019, 679: 237-247, DOI
29	Hu HQ, Hu TX, Sun L. Spatial heterogeneity of soil respiration in a Larix gmelinii forest and the response to prescribed fire in the Greater Xing’ an Mountains, China. J Forestry Res, 2016, 27: 1153-1162, DOI
30	Hu TX, Zhao BQ, Li F, Dou X, Sun L. Effects of fire on soil respiration and its components in a dahurian larch (Larix gmelinii) forest in northeast china: implications for forest ecosystem carbon cycling. Geoderma, 2021, 402: 115273, DOI
31	Ilstedt U, Giesler R, Nordgren A, Malmer A. Changes in soil chemical and microbial properties after a wildfire in a tropical rainforest in Sabah, Malaysia. Soil Biol Biochem, 2003, 35: 1071-1078, DOI
32	Jin ZZ, Lei JQ, Xu XW, Li SY, Fan JL, Zhao SF, Zhou HW, Gu F. Relationships of soil microbial biomass with soil environmental factors in Tarim Desert highway shelter-forest. Chin J Appl Ecol, 2009, 20: 51-57
33	Johnstone JF, Hollingsworth TN, Chapin FS (2008) A key for predicting postfire successional trajectories in black spruce stands of interior Alaska. USDA Forest Service, Pacific Northwest Research Station, Portland, p 37
34	Kara O, Bolat I. Short-term effects of wildfire on microbial biomass and abundance in black pine plantation soils in Turkey. Ecol Indic, 2009, 9: 1151-1155, DOI
35	Kasischke ES, Turetsky MR. Recent changes in the fire regime across the North American boreal region—Spatial and temporal patterns of burning across Canada and Alaska. Geophys Res Lett, 2006, 33: L09703
36	Keith H (1991) Effects of fire and fertilization on nitrogen cycling and tree growth in a subalpine eucalypt forest. Dissertation, Australian National University
37	Krawchuk MA, Moritz MA, Parisien MA, Van Dorn J, Hayhoe K. Global pyrogeography: the current and future distribution of wildfire. PLoS ONE, 2009, 4: e5102, DOI
38	Lavoie M, Mack MC. Spatial heterogeneity of understory vegetation and soil in an Alaskan upland boreal forest fire chronosequence. Biogeochemistry, 2012, 107: 227-239, DOI
39	Liu GS, Jiang NH, Zhang LD, Liu ZL. Soil physical and chemical analysis and description of soil profiles, 1996 Beijing China Standard Methods Press 33-38
40	Liu S, Wang CK. Spatio-temporal patterns of soil microbial biomass carbon and nitrogen in five temperate forest ecosystems. Acta Ecol Sinica, 2010, 30: 3135-3143
41	Liu WX, Xu WH, Hong JP, Wan SQ. Interannual variability of soil microbial biomass and respiration in responses to topography, annual burning and N addition in a semiarid temperate steppe. Geoderma, 2010, 158: 259-267, DOI
42	Long XE, Chen C, Xu Z, He JZ. Shifts in the abundance and community structure of soil ammonia oxidizers in a wet sclerophyll forest under long-term prescribed burning. Sci Total Environ, 2014, 470: 578-586, DOI
43	Mabuhay JA, Nakagoshi N, Horikoshi T. Microbial biomass and abundance after forest fire in pine forests in Japan. Adv Ecol Res, 2003, 18: 431-441, DOI
44	Mabuhay JA, Nakagoshi N, Isagi Y. Soil microbial biomass, abundance, and diversity in a Japanese red pine forest: first year after fire. J for Res JPN, 2006, 11: 165-173, DOI
45	Meira-Castro A, Shakesby RA, Marques JE, Doerr SH, Meixedo JP, Teixeira J. Effects of prescribed fire on surface soil in a Pinus pinaster plantation, Northern Portugal. Environ Earth Sci, 2015, 73: 3011-3018, DOI
46	Moore CM, Keeley JE (2000) Long-term hydrologic response of a forested catchment to prescribed fire. In: Proceedings of the American water resource association spring specialty conference, water resources in extreme environments, pp 37–42.
47	Neary DG, Ryan KC, DeBano LF (2005) Wildland fire in ecosystems: effects of fire on soils and water; General Technical Report RMRSGTR-42-VOL.4; Department of Agriculture. Forest Service Station, Ogden, pp 5–17
48	Olea RA. Optimal contour mapping using universal Kriging. J Geophys Res, 1974, 79: 695-702, DOI
49	Outeiro L, Asperó F, Úbeda X. Geostatistical methods to study spatial variability of soil cations after a prescribed fire and rainfall. CATENA, 2008, 74: 310-320, DOI
50	Pietikäinen J, Fritze H. Clear-cutting and prescribed burning in coniferous forest: comparison of effects on soil fungal and total microbial biomass, respiration activity and nitrification. Soil Biol Biochem, 1995, 27: 101-109, DOI
51	Ponder P Jr, Tadros M, Loewenstein EF. Microbial properties and litter and soil nutrients after two prescribed fires in developing savannas in an upland Missouri Ozark Forest. For Ecol Manag, 2009, 257: 755-763, DOI
52	Qian YB, Wu ZN, Yang HF, Jiang C. Spatial heterogeneity for grain size distribution of eolian sand soil on longitudinal dunes in the southern gurbantunggut desert. J Arid Land, 2009, 1: 26-33
53	Reich PB, Peterson DW, Wedin DA, Wrage K. Fire and vegetation effects on productivity and nitrogen cycling across a forest-grassland continuum. Ecology, 2001, 82: 1703-1719
54	Rezanezhad F, Moore T, Zak D, Negassa W, Leinweber P. Small-scale spatial variability of soil chemical and biochemical properties in a rewetted degraded peatland. Front Environ Sci, 2019, 7: 116, DOI
55	Robertson GP, Klingensmith KM, Klug MJ, Paul EA, Crum JR, Ellis BG. Soil resources, microbial activity, and primary production across an agricultural ecosystem. Ecol Appl, 1997, 7: 158-170, DOI
56	Robichaud PR, Miller SM. Spatial interpolation and simulation of post-burn duff thickness after prescribed fire. Int J Wildland Fire, 1999, 9: 137-143, DOI
57	Rodríguez A, Duran J, Fernández-Palacios JM, Gallardo A. Short-term wildfire effects on the spatial pattern and scale of labile organic-N and inorganic-N and P pools. For Ecol Manag, 2009, 257: 739-746, DOI
58	Russell JR, Betteridge K, Costall DA, Mackay AD. Cattle treading effects on sediment loss and water infiltration. J Range Manag, 2001, 54: 184-190, DOI
59	Rutigliano FA, De Marco A, D’Ascoli R, Castaldi S, Gentile A, De Santo AV. Impact of fire on fungal abundance and microbial efficiency in C assimilation and mineralisation in a Mediterranean maquis soil. Biol Fertil Soils, 2007, 44: 377-381, DOI
60	Saetre P, Bååth E. Spatial variation and patterns of soil microbial community structure in a mixed spruce-birch stand. Soil Biol Biochem, 2000, 32: 909-917, DOI
61	Schloter M, Dilly O, Munch JC. Indicators for evaluating soil quality. Agric Ecosyst Environ, 2003, 98: 255-262, DOI
62	Scott-Denton LE, Rosenstiel TN, Monson RK. Differential controls by climate and substrate over the heterotrophic and rhizospheric components of soil respiration. Glob Chang Biol, 2006, 12: 205-216, DOI
63	Shapiro SS, Wilk MB. An analysis of variance test for normality (complete samples). Biometrika, 1965, 52: 591-611, DOI
64	Shen CC, Xiong JB, Zhang HY, Feng YZ, Lin XG, Li XY, Liang WJ, Chu HY. Soil pH drives the spatial distribution of bacterial communities along elevation on changbai mountain. Soil Biol Biochem, 2013, 57: 204-211, DOI
65	Shibata H, Petrone KC, Hinzman LD, Boone RD. Effect of fire on dissolved organic carbon and inorganic solutes in spruce forest in the permafrost region of interior Alaska. Soil Sci Plant Nutr, 2003, 49: 25-29, DOI
66	Stark CHE, Condron LM, Di Stewart AHJ, O'Callaghan M. Small-scale spatial variability of selected soil biological properties. Soil Biol Biochem, 2004, 36: 601-608, DOI
67	Sun YX, Wu JP, Shao YH, Zhou LX, Mai BX, Lin YB, Fu SL. Responses of soil microbial communities to prescribed burning in two paired vegetation sites in southern China. Ecol Res, 2011, 26: 669-677, DOI
68	Vega JA, Fontúrbel T, Merino A, Fernández C, Ferreiro A, Jiménez E. Testing the ability of visual indicators of soil burn severity to reflect changes in soil chemical and microbial properties in pine forests and shrubland. Plant Soil, 2013, 369: 73-91, DOI
69	Volkova L, Meyer CPM, Murphy S, Fairman T, Reisen F, Weston C. Fuel reduction burning mitigates wildfire effects on forest carbon and greenhouse gas emission. Int J Wildland Fire, 2014, 23: 771-780, DOI
70	Vos M, Wolf AB, Jennings SJ, Kowalchuk GA. Micro-scale determinants of bacterial diversity in soil. FEMS Microbiol Rev, 2013, 37: 936-954, DOI
71	Wang J, Fu BJ, Qiu Y, Chen LD, Yu L. Spatial heterogeneity of soil nutrients in a small catchment of the Loess Plateau. Acta Ecol Sinica, 2002, 22: 1173-1178
72	Williams RJ, Hallgren SW, Wilson GWT. Frequency of prescribed burning in an upland oak forest determines soil and litter properties and alters the soil microbial community. For Ecol Manag, 2012, 265: 241-247, DOI
73	Xu PB, Qu M, Xue L. Effects of forest fire on forest soils. Chin J Ecol, 2013, 32: 1596-1606
74	Yanai J, Sawamoto T, Oe T, Kusa K, Yamakawa K, Sakamoto K, Naganawa T, Inubushi K, Hatano R, Kosaki T. Spatial variability of nitrous oxide emissions and their soil-related determining factors in an agricultural field. J Environ Qual, 2003, 32: 1965-1977, DOI
75	Zhang W, Chen HS, Wang KL, Hou Y, Zhang JG. Spatial variability of soil organic carbon and available phosphorus in a typical Karst depression, northwest of Guangxi. Acta Ecol Sinica, 2007, 27: 5168-5175
76	Zhao W, Cornwell WK, Pomeren MV, Logtestijn RSPV, Cornelissen JHC. Species mixture effects on flammability across plant phylogeny: the importance of litter particle size and the special role for non-Pinus Pinaceae. Ecol Evol, 2016, 6: 8223-8234, DOI
77	Zhao X, Wang Q, Kakubari Y. Stand-scale spatial patterns of soil microbial biomass in natural cold temperate beech forests along an elevation gradient. Soil Biol Biochem, 2009, 41: 1466-1474, DOI
78	Zhou J, Guan DW, Zhou BK, Zhao BS, Ma MC, Qin J, Jiang X, Chen SF, Cao FM, Shen DL, Li J. Influence of 34-years of fertilization on bacterial communities in an intensively cultivated black soil in northeast China. Soil Biol Biochem, 2015, 90: 42-51, DOI
79	Zhou ZH, Wang CK. Reviews and syntheses: soil resources and climate jointly drive variations in microbial biomass carbon and nitrogen in China’s forest ecosystems. Biogeosciences, 2015, 12: 6751-6760, DOI
80	Zhou DW, Yue XQ, Sun G, Li YS. Changes of soil microorganisms after grassland fires. J Northeast Norm Univ, 1999, 01: 123-129