Responses of forest soil microbial communities to drought and nitrogen deposition: A review

doi:10.13287/j.1001-9332.202007.035

Abstract

Abstract: Drought and nitrogen input are profoundly influencing most life on Earth and the substance cycling in forest ecosystems in the Anthropocene, with consequences on global carbon balance and feedback on climate changes. Soil microorganisms drive biogeochemical cycling and key ecological processes, with central role and global importance in climate change biology. Here, we reviewed the research in the area of the effects of drought and nitrogen deposition on soil bacteria and mycorrhizal fungi in forest ecosystems. We proposed that future studies should focus on how microbial diversity, activity, and ecological functioning respond to multiple global change factors and their interactions; how subtropical forest ecosystems respond to global changes on the basis of establishment of the long-term field experimental station; the interaction of different soil biological guilds; utilizing microbial big data to construct the relevant mechanistic models. Taken together, based on improved understanding of the responses of soil microbial diversity and community composition to global changes, further research may subsequently focus on manipulating the microbial communities to enhance forest management, ecological resources protection, and environmental sustainability. This review would provide some critical theoretical basis for the microbial strategy in mitigating climate change in future.

Key words: nitrogen deposition, drought, mycorrhizal fungi, climate change, forest ecosystem, soil microorganism

ZHENG Yong, HE Ji-zheng. Responses of forest soil microbial communities to drought and nitrogen deposition: A review[J]. Chinese Journal of Applied Ecology, 2020, 31(7): 2464-2472.

References

[1] IPCC. Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press, 2013
[2] Ma ZH, Peng CH, Zhu QA, et al. Regional drought-induced reduction in the biomass carbon sink of Canada's boreal forests. Proceedings of the National Academy of Sciences of the United States of America, 2012, 109: 2423-2427
[3] Schlesinger WH, Dietze MC, Jackson RB, et al. Forest biogeochemistry in response to drought. Global Change Biology, 2016, 22: 2318-2328
[4] Lamarque JF, Kiehl JT, Brasseur GP, et al. Assessing future nitrogen deposition and carbon cycle feedback using a multimodel approach: Analysis of nitrogen deposition. Journal of Geophysical Research-Atmospheres, 2005, 110: D19303
[5] Galloway JN, Townsend AR, Erisman JW, et al. Transformation of the nitrogen cycle: Recent trends, questions, and potential solutions. Science, 2008, 320: 889-892
[6] Reay DS, Dentener F, Smith P, et al. Global nitrogen deposition and carbon sinks. Nature Geoscience, 2008, 1: 430-437
[7] Luo YQ, Jiang LF, Niu SL, et al. Nonlinear responses of land ecosystems to variation in precipitation. New Phytologist, 2017, 214: 5-7
[8] Cavicchioli R, Ripple WJ, Timmis KN, et al. Scientists' warning to humanity: Microorganisms and climate change. Nature Reviews Microbiology, 2019, 17: 569-586
[9] Pan Y, Birdsey RA, Phillips OL, et al. The structure, distribution, and biomass of the world's forests. Annual Review of Ecology, Evolution, and Systematics, 2013, 44: 593-622
[10] Corrales A, Turner BL, Tedersoo L, et al. Nitrogen addition alters ectomycorrhizal fungal communities and soil enzyme activities in a tropical montane forest. Fungal Ecology, 2017, 27: 14-23
[11] 鲁显楷, 莫江明, 张炜, 等. 模拟大气氮沉降对中国森林生态系统影响的研究进展. 热带亚热带植物学报, 2019, 27(5): 500-522 [Lu X-K, Mo J-M, Zhang W, et al. Effects of simulated atmospheric nitrogen deposition on forest ecosystems in China: An overview. Journal of Tropical and Subtropical Botany, 2019, 27(5): 500-522]
[12] Lladó S, López-Mondéjar R, Baldrian P. Forest soil bacteria: Diversity, involvement in ecosystem processes, and response to global change. Microbiology and Molecular Biology Reviews, 2017, 81: e00063-16
[13] de Vries FT, Liiri ME, Bjornlund L, et al. Legacy effects of drought on plant growth and the soil food web. Oecologia, 2012, 170: 821-833
[14] Manzoni S, Schimel JP, Porporato A. Responses of soil microbial communities to water stress: Results from a meta-analysis. Ecology, 2012, 93: 930-938
[15] Naylor D, Coleman-Derr D. Drought stress and root-associated bacterial communities. Frontiers in Plant Science, 2018, 8: 2223
[16] Alster CJ, German DP, Lu Y, et al. Microbial enzymatic responses to drought and to nitrogen addition in a southern California grassland. Soil Biology & Biochemistry, 2013, 64: 68-79
[17] Hartmann M, Brunner I, Hagedorn F, et al. A decade of irrigation transforms the soil microbiome of a semi-arid pine forest. Molecular Ecology, 2017, 26: 1190-1206
[18] Castaño C, Lindahl BD, Alday JG, et al. Soil microclimate changes affect soil fungal communities in a Mediterranean pine forest. New Phytologist, 2018, 220: 1211-1221
[19] Philippot L, Raaijmakers JM, Lemanceau P, et al. Going back to the roots: The microbial ecology of the rhizosphere. Nature Reviews Microbiology, 2013, 11: 789-799
[20] Preece C, Verbruggen E, Liu L, et al. Effects of past and current drought on the composition and diversity of soil microbial communities. Soil Biology & Biochemistry, 2019, 131: 28-39
[21] Bastida F, Lopez-Mondejar R, Baldrian P, et al. When drought meets forest management: Effects on the soil microbial community of a Holm oak forest ecosystem. Science of the Total Environment, 2019, 662: 276-286
[22] Fierer N, Carney KM, Horner-Devine MC, et al. The biogeography of ammonia-oxidizing bacterial communities in soil. Microbial Ecology, 2009, 58: 435-445
[23] Schimel JP, Gulledge JM, Clein-Curley JS, et al. Moisture effects on microbial activity and community structure in decomposing birch litter in the Alaskan taiga. Soil Biology & Biochemistry, 1999, 31, 831-838
[24] Fierer N, Bradford MA, Jackson RB. Toward an ecolo-gical classification of soil bacteria. Ecology, 2007, 88: 1354-1364
[25] Koyama A, Wallenstein MD, Simpson RT, et al. Soil bacterial community composition altered by increased nutrient availability in Arctic tundra soils. Frontiers in Microbiology, 2014, 5: 516
[26] Zeng QC, Dong YH, An SS. Bacterial community responses to soils along a latitudinal and vegetation gradient on the Loess Plateau, China. PLoS One, 2016, 11(4): e0152894
[27] Kersters K, De Vos P, Gillis M, et al. Introduction to the Proteobacteria// Dworkin M, Falkow S, Rosenberg E, eds. The Prokaryotes. New York: Springer, 2006
[28] Evans SE, Wallenstein MD. Climate change alters ecological strategies of soil bacteria. Ecology Letters, 2014, 17: 155-164
[29] Bouskill NJ, Lim HC, Borglin S, et al. Pre-exposure to drought increases the resistance of tropical forest soil bacterial communities to extended drought. The ISME Journal, 2013, 7: 384-394
[30] Chodak M, Golebiewski M, Morawska-Ploskonka J, et al. Soil chemical properties affect the reaction of forest soil bacteria to drought and rewetting stress. Annals of Microbiology, 2015, 65: 1627-1637
[31] Yuste JC, Fernandez-Gonzalez AJ, Fernandez-Lopez M, et al. Strong functional stability of soil microbial communities under semiarid Mediterranean conditions and subjected to long-term shifts in baseline precipitation. Soil Biology & Biochemistry, 2014, 69: 223-233
[32] Zhao Q, Jian SG, Nunan N, et al. Altered precipitation seasonality impacts the dominant fungal but rare bacterial taxa in subtropical forest soils. Biology and Fertility of Soils, 2017, 53: 231-245
[33] Homyak PM, Allison SD, Huxman TE, et al. Effects of drought manipulation on soil nitrogen cycling: A meta-analysis. Journal of Geophysical Research-Biogeosciences, 2017, 122: 3260-3272
[34] Uhlirova E, Elhottova D, Triska J, et al. Physiology and microbial community structure in soil at extreme water content. Folia Microbiologica, 2005, 50: 161-166
[35] 聂园园, 周贵尧, 邵钧炯, 等. 模拟干旱对亚热带森林土壤微生物生物量及群落结构的影响. 复旦学报:自然科学版, 2017, 56(1): 97-105 [Nie Y-Y, Zhou G-Y, Shao J-J, et al. Effects of simulating drought on soil microbial biomass and community structure in subtropical forest. Journal of Fudan University: Natural Science, 2017, 56(1): 97-105]
[36] Deepika S, Kothamasi D. Soil moisture-a regulator of arbuscular mycorrhizal fungal community assembly and symbiotic phosphorus uptake. Mycorrhiza, 2015, 25: 67-75
[37] Furze JR, Martin AR, Nasielski J, et al. Resistance and resilience of root fungal communities to water limitation in a temperate agroecosystem. Ecology and Evolution, 2017, 7: 3443-3454
[38] Guadarrama P, Castillo S, Ramos-Zapata JA, et al. Arbuscular mycorrhizal fungal communities in changing environments: The effects of seasonality and anthropogenic disturbance in a seasonal dry forest. Pedobiologia, 2014, 57: 87-95
[39] Zangaro W, Rostirola LV, de Souza PB, et al. Root colo-nization and spore abundance of arbuscular mycorrhizal fungi in distinct successional stages from an Atlantic rainforest biome in southern Brazil. Mycorrhiza, 2013, 23: 221-233
[40] Maitra P, Zheng Y, Chen L, et al. Effect of drought and season on arbuscular mycorrhizal fungi in a subtropical secondary forest. Fungal Ecology, 2019, 41: 107-115
[41] 吴强盛, 邹英宁, 王贵元. 丛枝菌根真菌生态学研究进展. 长江大学学报:自然科学版, 2007, 4(2): 76-80 [Wu Q-S, Zou Y-N, Wang G-Y. Advances of arbuscular mycorrhizal fungal ecology. Journal of Yangtze University: Natural Science, 2007, 4(2): 76-80]
[42] Kiers ET, Duhamel M, Beesetty Y, et al. Reciprocal rewards stabilize cooperation in the mycorrhizal symbiosis. Science, 2011, 333: 880-882
[43] Fellbaum CR, Gachomo EW, Beesetty Y, et al. Carbon availability triggers fungal nitrogen uptake and transport in arbuscular mycorrhizal symbiosis. Proceedings of the National Academy of Sciences of the United States of America, 2012, 109: 2666-2671
[44] 冯邦, 杨祝良. 外生菌根共生: 共生真菌多样性及菌根形成的分子机制. 中国科学: 生命科学, 2019, 49(4): 436-444 [Feng B, Yang Z-L. Ectomycorrhizal symbioses: Diversity of mycobionts and molecular mechanisms that entail the development of ectomycorrhizae. Scientia Sinica Vitae, 2019, 49(4): 436-444]
[45] Valdés M, Asbjornsen H, Gómez-Cárdenas M, et al. Drought effects on fine-root and ectomycorrhizal-root biomass in managed Pinus oaxacana Mirov stands in Oaxaca, Mexico. Mycorrhiza, 2006, 16: 117-124
[46] Kennedy PG, Peay KG. Different soil moisture conditions change the outcome of the ectomycorrhizal symbiosis between Rhizopogon species and Pinus muricata. Plant and Soil, 2007, 291: 155-165
[47] Meier S, Grand LF, Schoeneberger MM, et al. Growth, ectomycorrhizae and nonstructural carbohydrates of Loblolly Pine seedlings exposed to ozone and soil water deficit. Environmental Pollution, 1990, 64: 11-27
[48] Compant S, van der Heijden MGA, Sessitsch A. Climate change effects on beneficial plant-microorganism interactions. FEMS Microbiology Ecology, 2010, 73: 197-214
[49] Shi LB, Guttenberger M, Kottke I, et al. The effect of drought on mycorrhizas of beech (Fagus sylvatica L.): Changes in community structure, and the content of carbohydrates and nitrogen storage bodies of the fungi. Mycorrhiza, 2002, 12: 303-311
[50] di Pietro M, Churin JL, Garbaye J. Differential ability of ectomycorrhizas to survive drying. Mycorrhiza, 2007, 17: 547-550
[51] Nickel UT, Weikl F, Kerner R, et al. Quantitative losses vs. qualitative stability of ectomycorrhizal community responses to 3 years of experimental summer drought in a beech-spruce forest. Global Change Biology, 2018, 24: 560-576
[52] Swaty RL, Deckert RJ, Whitham TG, et al. Ectomycorrhizal abundance and community composition shifts with drought: Predictions from tree rings. Ecology, 2004, 85: 1072-1084
[53] Treseder KK. Nitrogen additions and microbial biomass: A meta-analysis of ecosystem studies. Ecology Letters, 2008, 11: 1111-1120
[54] Zhang TA, Chen HYH, Ruan HH. Global negative effects of nitrogen deposition on soil microbes. The ISME Journal, 2018, 12: 1817-1825
[55] Johnson D, Leake JR, Lee JA, et al. Changes in soil microbial biomass and microbial activities in response to 7 years simulated pollutant nitrogen deposition on a heathland and two grasslands. Environmental Pollution, 1998, 103: 239-250
[56] Wallenstein MD, McNulty S, Fernandez IJ, et al. Nitrogen fertilization decreases forest soil fungal and bacterial biomass in three long-term experiments. Forest Ecology and Management, 2006, 222: 459-468
[57] Tian D, Du EZ, Jiang L, et al. Responses of forest ecosystems to increasing N deposition in China: A critical review. Environmental Pollution, 2018, 243: 75-86
[58] Tian D, Jiang L, Ma S, et al. Effects of nitrogen deposition on soil microbial communities in temperate and subtropical forests in China. Science of the Total Environment, 2017, 607: 1367-1375
[59] Maaroufi NI, Nordin A, Palmqvist K, et al. Anthropogenic nitrogen enrichment enhances soil carbon accumulation by impacting saprotrophs rather than ectomycorrhizal fungal activity. Global Change Biology, 2019, 25: 2900-2914
[60] Vance ED, Chapin FS. Substrate limitations to microbial activity in taiga forest floors. Soil Biology & Biochemistry, 2001, 33: 173-188
[61] Frey SD, Knorr M, Parrent JL, et al. Chronic nitrogen enrichment affects the structure and function of the soil microbial community in temperate hardwood and pine forests. Forest Ecology and Management, 2004, 196: 159-171
[62] Fierer N, Lauber CL, Ramirez KS, et al. Comparative metagenomic, phylogenetic and physiological analyses of soil microbial communities across nitrogen gradients. The ISME Journal, 2012, 6: 1007-1017
[63] 赵超, 彭赛, 阮宏华, 等. 氮沉降对土壤微生物影响的研究进展. 南京林业大学学报: 自然科学版, 2015, 39(3): 149-155 [Zhao C, Peng S, Ruan H-H, et al. Effects of nitrogen deposition on soil microbes. Journal of Nanjing Forestry University: Natural Sciences, 2015, 39(3): 149-155]
[64] Wessén E, Hallin S, Philippot L. Differential responses of bacterial and archaeal groups at high taxonomical ranks to soil management. Soil Biology & Biochemistry, 2010, 42: 1759-1765
[65] Carrara JE, Walter CA, Hawkins JS, et al. Interactions among plants, bacteria, and fungi reduce extracellular enzyme activities under long-term N fertilization. Global Change Biology, 2018, 24: 2721-2734
[66] Nie YX, Han XG, Chen J, et al. The simulated N depo-sition accelerates net N mineralization and nitrification in a tropical forest soil. Biogeosciences, 2019, 16: 4277-4291
[67] Liu YJ, Shi GX, Mao L, et al. Direct and indirect influences of 8 yr of nitrogen and phosphorus fertilization on Glomeromycota in an alpine meadow ecosystem. New Phytologist, 2012, 194: 523-535
[68] Lilleskov EA, Kuyper TW, Bidartondo MI, et al. Atmospheric nitrogen deposition impacts on the structure and function of forest mycorrhizal communities: A review. Environmental Pollution, 2019, 246: 148-162
[69] Treseder KK. A meta-analysis of mycorrhizal responses to nitrogen, phosphorus, and atmospheric CO₂ in field studies. New Phytologist, 2004, 164: 347-355
[70] van Diepen LTA, Lilleskov EA, Pregitzer KS. Simulated nitrogen deposition affects community structure of arbuscular mycorrhizal fungi in northern hardwood forests. Molecular Ecology, 2011, 20: 799-811
[71] Averill C, Dietze MC, Bhatnagar JM. Continental-scale nitrogen pollution is shifting forest mycorrhizal associations and soil carbon stocks. Global Change Biology, 2018, 24: 4544-4553
[72] Camenzind T, Hempel S, Homeier J, et al. Nitrogen and phosphorus additions impact arbuscular mycorrhizal abundance and molecular diversity in a tropical montane forest. Global Change Biology, 2014, 20: 3646-3659
[73] Zheng Y, Kim YC, Tian XF, et al. Differential responses of arbuscular mycorrhizal fungi to nitrogen addition in a near pristine Tibetan alpine meadow. FEMS Microbiology Ecology, 2014, 89: 594-605
[74] Camenzind T, Homeier J, Dietrich K, et al. Opposing effects of nitrogen versus phosphorus additions on mycorrhizal fungal abundance along an elevational gradient in tropical montane forests. Soil Biology & Biochemistry, 2016, 94: 37-47
[75] Chen YL, Xu ZW, Xu TL, et al. Nitrogen deposition and precipitation induced phylogenetic clustering of arbuscular mycorrhizal fungal communities. Soil Biology & Biochemistry, 2017, 115: 233-242
[76] Johnson D, Leake JR, Read DJ. Liming and nitrogen fertilization affects phosphatase activities, microbial biomass and mycorrhizal colonisation in upland grassland. Plant and Soil, 2005, 271: 157-164
[77] van der Heijden MGA, Scheublin TR. Functional traits in mycorrhizal ecology: Their use for predicting the impact of arbuscular mycorrhizal fungal communities on plant growth and ecosystem functioning. New Phytologist, 2007, 174: 244-250
[78] Nilsson LO, Giesler R, Bääth E, et al. Growth and biomass of mycorrhizal mycelia in coniferous forests along short natural nutrient gradients. New Phytologist, 2005, 165: 613-622
[79] Kjøller R, Nilsson LO, Hansen K, et al. Dramatic changes in ectomycorrhizal community composition, root tip abundance and mycelial production along a stand-scale nitrogen deposition gradient. New Phytologist, 2012, 194: 278-286
[80] Hasselquist NJ, Högberg P. Dosage and duration effects of nitrogen additions on ectomycorrhizal sporocarp production and functioning: An example from two N-limited boreal forests. Ecology and Evolution, 2014, 4: 3015-3026
[81] Avis PG, McLaughlin DJ, Dentinger BC, et al. Long-term increase in nitrogen supply alters above- and below-ground ectomycorrhizal communities and increases the dominance of Russula spp. in a temperate oak savanna. New Phytologist, 2003, 160: 239-253
[82] Wright SHA, Berch SM, Berbee ML. The effect of fertilization on the below-ground diversity and community composition of ectomycorrhizal fungi associated with western hemlock (Tsuga heterophylla). Mycorrhiza, 2009, 19: 267-276
[83] Vallack HW, Leronni V, Metcalfe DB, et al. Application of nitrogen fertilizer to a boreal pine forest has a negative impact on the respiration of ectomycorrhizal hyphae. Plant and Soil, 2012, 352: 405-417
[84] Lilleskov EA, Fahey TJ, Lovett GM. Ectomycorrhizal fungal aboveground community change over an atmospheric nitrogen deposition gradient. Ecological Applications, 2001, 11: 397-410
[85] Wallenda T, Kottke I. Nitrogen deposition and ectomycorrhizas. New Phytologist, 1998, 139: 169-187
[86] Avis PG, Mueller GM, Lussenhop J. Ectomycorrhizal fungal communities in two North American oak forests respond to nitrogen addition. New Phytologist, 2008, 179: 472-483
[87] 李月蛟, 朱利英, 尹华军, 等. 连续三年夜间增温和施氮对云杉外生菌根及菌根真菌多样性的影响. 生态学报, 2015, 35(9): 2967-2977 [Li Y-J, Zhu L-Y, Yin H-J, et al. Effects of 3-year continuous night-time warming and nitrogen fertilization on ectomycorrhizae of Picea asperata and the ectomycorrhizal fungal diversity. Acta Ecologica Sinica, 2015, 35(9): 2967-2977]
[88] Zheng Y, Hu HW, Guo LD, et al. Dryland forest mana-gement alters fungal community composition and decouples assembly of root- and soil-associated fungal communities. Soil Biology & Biochemistry, 2017, 109: 14-22
[89] Soudzilovskaia NA, van Bodegom PM, Terrer C, et al. Global mycorrhizal plant distribution linked to terrestrial carbon stocks. Nature Communications, 2019, 10: 5077
[90] Valliere JM, Allen EB. Interactive effects of nitrogen deposition and drought-stress on plant-soil feedbacks of Artemisia californica seedlings. Plant and Soil, 2016, 403: 277-290
[91] Yan GY, Zhou MX, Wang M, et al. Nitrogen deposition and decreased precipitation altered nutrient foraging strategies of three temperate trees by affecting root and mycorrhizal traits. Catena, 2019, 181: 104094
[92] Khalili B, Ogunseitan OA, Goulden ML, et al. Interactive effects of precipitation manipulation and nitrogen addition on soil properties in California grassland and shrubland. Applied Soil Ecology, 2016, 107: 144-153
[93] Yan GY, Xing YJ, Lu XT, et al. Effects of artificial nitrogen addition and reduction in precipitation on soil CO₂ and CH₄ effluxes and composition of the microbial biomass in a temperate forest. European Journal of Soil Science, 2019, 70: 1197-1211
[94] Chen ZJ, Zhou XY, Geng SC, et al. Interactive effect of nitrogen addition and throughfall reduction decreases soil aggregate stability through reducing biological binding agents. Forest Ecology and Management, 2019, 445: 13-19
[95] Gessler A, Schaub M, McDowell NG. The role of nutrients in drought-induced tree mortality and recovery. New Phytologist, 2017, 214: 513-520
[96] Aguilar-Trigueros CA, Hempel S, Powell JR, et al. Bridging reproductive and microbial ecology: A case study in arbuscular mycorrhizal fungi. The ISME Journal, 2019, 13: 873-884
[97] Bueno CG, Gerz M, Zobel M, et al. Conceptual diffe-rences lead to divergent trait estimates in empirical and taxonomic approaches to plant mycorrhizal trait assignment. Mycorrhiza, 2019, 29: 1-11
[98] Treseder KK, Allen EB, Egerton-Warburton LM, et al. Arbuscular mycorrhizal fungi as mediators of ecosystem responses to nitrogen deposition: A trait-based predictive framework. Journal of Ecology, 2018, 106: 480-489