Effects of planting broadleaf trees and Moso bamboo on soil carbon mineralization and microbial community structure

doi:10.13287/j.1001-9332.202101.033

Abstract

Abstract: We conducted a pot experiment to investigate the effects of planting broadleaf tree species (i.e., Cinnamomum camphora, Schima superba, and Quercus glauca) and Moso bamboo (Phyllostachys edulis) on soil carbon mineralization and microbial community structure. The rates of soil carbon mineralization were measured via alkali trapping method. The structural and functional diversity of soil bacterial and fungal communities were analyzed by terminal restriction fragment length polymorphism (T-RFLP) and real-time quantitative PCR techniques. The soil planted with Moso bamboo exhibited a significantly higher carbon mineralization rate and labile carbon content than those in the soils planted with broadleaf tree species. The underground biomass of Moso bamboo was higher than that of broadleaf tree species. The soil bacterial communities were more sensitive than fungal communities to the planting of different plant species . Moreover, soil fungal diversity of Moso bamboo was distinctly different from that of broadleaf tree species. Compared to the diversity of soil bacterial communities, the diversity of soil fungal communities was more closely related with soil pH, organic carbon content, and carbon mineralization. In comparison to the broadleaf tree species, the Moso bamboo planting could substantially increase soil organic carbon minera-lization, which was affected mainly by the soil fungal community structure.

Key words: soil carbon mineralization, tree species, soil bacterial, soil fungal, community characteristics

FANG Tao, LI Yong-chun, YAO Ze-xiu, LI Yong-fu, WANG Xing-meng, WANG Yue, YU Ye-fei. Effects of planting broadleaf trees and Moso bamboo on soil carbon mineralization and microbial community structure[J]. Chinese Journal of Applied Ecology, 2021, 32(1): 82-92.

References

[1] Jandl R, Lindner M, Vesterdal L, et al. How strongly can forest management influence soil carbon sequestration? Geoderma, 2007, 137: 253-268
[2] Cleveland CC, Nemergut DR, Schmidt SK, et al. Increases in soil respiration following labile carbon additions linked to rapid shifts in soil microbial community composition. Biogeochemistry, 2007, 82: 229-240
[3] Yang H, Cao JH, Zhang LK, et al. Pool sizes and turnover of soil organic carbon of farmland soil in karst area of guilin. Journal of Northeast Agricultural University, 2011, 18: 39-45
[4] 吴建国, 张小全, 徐德应, 等. 六盘山林区几种土地利用方式对土壤有机碳矿化影响的比较. 植物生态学报, 2004, 28(4): 530-538 [Wu J-G, Zhang X-Q, Xu D-Y, et al. Effects of several land use patterns on soil organic carbon mineralization in the Liupan mountain forest zone. Chinese Journal of Plant Ecology, 2004, 28(4): 530-538]
[5] 史学军, 潘剑君, 陈锦盈, 等. 不同类型凋落物对土壤有机碳矿化的影响. 环境科学, 2009, 30(6): 1832-1837 [Shi X-J, Pan J-J, Chen J-Y, et al. Effects of different types of litters on soil organic carbon minera-lization. Environmental Science, 2009, 30(6): 1832-1837]
[6] Alvarez R, Alvarez CR. Soil organic matter pools and their associations with carbon mineralization kinetics. Soil Science Society of America Journal, 2000, 64: 184-189
[7] Pernille LP, Elberling B, Vesterdal L. Soil carbon stocks, mineralization rates, and CO₂ effluxes under 10 tree species on contrasting soil types. Canadian Journal of Forest Research, 2005, 35: 1277-1284
[8] Yin LM, Dijkstra FA, Wang P, et al. Rhizosphere priming effects on soil carbon and nitrogen dynamics among tree species with and without intraspecific competition. New Phytologist, 2018, 218: 1036-1048
[9] Segura JH, Nilsson MB, Sparrman T, et al. Boreal tree species affect soil organic matter composition and saprotrophic mineralization rates. Plant and Soil, 2019, 441: 173-190
[10] Thoms C, Gattinger A, Jacob M, et al. Direct and indirect effects of tree diversity drive soil microbial diversity in temperate deciduous forest. Soil Biology and Biochemi-stry, 2010, 42: 1558-1565
[11] Drake JE, Darby BA, Giasson MA, et al. Stoichiometry constrains microbial response to root exudation-Insights from a model and a field experiment in a temperate forest. Biogeosciences, 2013, 10: 821-838
[12] Wang QK, Zhong M. Composition and mineralization of soil organic carbon pools in four single-tree species forest soils. Journal of Forestry Research, 2016, 27: 1277-1285
[13] Kuzyakov Y, Friedel JK, Stahr K. Review of mechanisms and quantification of priming effects. Soil Biology and Biochemistry, 2000, 32: 1485-1498
[14] Cheng WX, Parton WJ, Gonzalez-Meler MA, et al. Synthesis and modeling perspectives of rhizosphere priming. New Phytologist, 2014, 201: 31-44
[15] Raich JW, Nadelhoffer KJ. Belowground carbon allocation in forest ecosystems: Global trends. Ecology, 1989, 70: 1346-1354
[16] Bauhus J, Parea D, Coate L. Effects of tree species, stand age and soil type on soil microbial biomass and its activity in a southern boreal forest. Soil Biology and Biochemistry, 1998, 30: 1007-1089
[17] Priha O, Grayston SJ, Hiukka R, et al. Microbial community structure and characteristics of the organic matter in soils under Pinus sylvestris, Picea abies and Betula pendula at two forest sites. Biology and Fertility of Soils, 2001, 33: 17-24
[18] Grayston SJ, Campbell CD. Functional biodiversity of microbial communities in the rhizospheres of hybrid larch (Larix eurolepis) and sitka spruce (Picea sitchen-sis). Tree Physiology, 1996, 16: 1031-1038
[19] Lejon DPH, Chaussod R, Ranger J, et al. Microbial community structure and density under different tree species in an acid forest soil (Morvan, France). Microbial Ecology, 2005, 50: 614-625
[20] Parent B, Suard B, Serraj R, et al. Rice leaf growth and water potential are resilient to evaporative demand and soil water deficit once the effects of root system are neutralized. Plant, Cell and Environment, 2010, 33: 1256-1267
[21] Singh BK, Millard P, Andrew S, et al. Whiteley unrave-lling rhizosphere-microbial interactions: Opportunities and limitations. Trends in Microbiology, 2004, 12: 386-393
[22] Wolfe BE, Klironomos JN. Breaking new ground: Soil communities and exotic plant invasion. Bioscience, 2005, 55: 477-487
[23] Lu S, Zhang Y, Chen C, et al. Plant-soil interaction affects the mineralization of soil organic carbon: Evidence from 73-year-old plantations with three coniferous tree species in subtropical Australia. Journal of Soils and Sediments, 2017, 17: 985-995
[24] Rousk J, Brookes PC, Bååth E. Contrasting soil pH effects on fungal and bacterial growth suggest functional redundancy in carbon mineralization. Applied and Environmental Microbiology, 2009, 75: 1589-1596
[25] Fox CA, MacDonald KB. Challenges related to soil biodiversity research in agroecosystems-Issues within the context of scale of observation. Canadian Journal of Soil Science, 2003, 83: 231-244
[26] 辜翔, 方晰, 项文化, 等. 湘中丘陵区4种森林类型土壤有机碳和可矿化有机碳的比较. 生态学杂志, 2013, 32(10): 2687-2694 [Gu X, Fang X, Xiang W-H, et al. Soil organic carbon and mineralizable organic carbon in four subtropical forests in hilly region of central Hunan Province, China. Chinese Journal of Ecology, 2013, 32(10): 2687-2694]
[27] Li YC, Liang X, Tang CX, et al. Moso bamboo invasion into broadleaf forests is associated with greater abundance and activity of soil autotrophic bacteria. Plant and Soil, 2018, 428: 163-177
[28] Li YC, Li YF, Chang SX, et al. Bamboo invasion of broadleaf forests altered soil fungal community closely linked to changes in soil organic C chemical composition and mineral N production. Plant and Soil, 2017, 418: 507-521
[29] Spielvogel S, Prietzel J, Kögel-Knabner I. Stand scale variability of topsoil organic matter composition in a high-elevation Norway spruce forest ecosystem. Geoderma, 2016, 267: 112-122
[30] Redin M, Guénon R, Recous S, et al. Carbon mineralization in soil of roots from twenty crop species, as affected by their chemical composition and botanical family. Plant and Soil, 2014, 378: 205-214
[31] Giardina CP, Ryan MG, Hubbard RM, et al. Tree species and soil textural controls on carbon and nitrogen mineralization rates. Soil Science Society of America Journal, 2001, 65: 1272-1279
[32] 王兴萌, 陈志豪, 李永春, 等. 氮素形态及配比对毛竹和青冈实生苗生长特性的影响. 生态学杂志, 2019, 38(9): 2655-2661 [Wang X-M, Chen Z-H, Li Y-C, et al. Effects of different nitrogen forms and ratios on growth characteristics of Phyllostachys edulis and Quercus glauca seedlings. Chinese Journal of Ecology, 2019, 38(9): 2655-2661]
[33] Luo Y, Zang H, Yu Z, et al. Priming effects in biochar enriched soils using a three-source-partitioning approach: ¹⁴C labelling and ¹³C natural abundance. Soil Biology and Biochemistry, 2017, 106: 28-35
[34] Chen YP, Chen GS, Robinson D, et al. Large amounts of easily decomposable carbon stored in subtropical forest subsoil are associated with r-strategy-dominated soil microbes. Soil Biology and Biochemistry, 2016, 95: 233-242
[35] 鲍士旦. 土壤农化分析(第3版). 北京: 中国农业出版社, 2000 [Bao S-D. Soil Agrochemical Analysis (3^rd Ed). Beijing: China Agriculture Press, 2000]
[36] 陈志豪, 梁雪, 李永春, 等.不同施肥模式对雷竹林土壤真菌群落特征的影响. 应用生态学报, 2017, 28(4): 1168-1176 [Chen Z-H, Liang X, Li Y-C, et al. Effects of different fertilization regimes on soil fungal communities under Phyllostachys violascens stand. Chinese Journal of Applied Ecology, 2017, 28(4): 1168-1176]
[37] 张梦瑶, 高永恒, 谢青琰. 干湿交替对土壤有机碳矿化影响的研究进展. 世界科技研究与发展, 2017, 39(1): 20-26 [Zhang M-Y, Gao Y-H, Xie Q-Y. Effects of alternate drying and wetting on soil organic carbon mineralization:a review. World Sci-tech R and D, 2017, 39(1): 20-26]
[38] 王清奎, 汪思龙, 于小军, 等. 常绿阔叶林与杉木林的土壤碳矿化潜力及其对土壤活性有机碳的影响. 生态学杂志, 2007, 26(12): 1918-1923 [Wang Q-K, Wang S-L, Yu X-J, et al. Soil carbon mineralization potential and its effect on soil active organic carbon in evergreen broadleaved forest and Chinese fir plantation. Chinese Journal of Ecology, 2007, 26(12): 1918-1923]
[39] Bradley RL, Fyles JW. Growth of paper birch (Betula papyrifera) seedlings increases soil available C and microbial acquisition of soil-nutrients. Soil Biology and Biochemistry, 1995, 27:1565-1571
[40] Cheng WX. Rhizosphere feedbacks in elevated CO₂. Tree Physiology, 1999, 19: 313-320
[41] 刘骏, 杨清培, 余定坤, 等. 细根对竹林-阔叶林界面两侧土壤养分异质性形成的贡献. 植物生态学报, 2013, 37(8): 739-749 [Liu J, Yang Q-P, Yu D-K, et al. Contribution of fine root to soil nutrient heterogeneity at two sides of the bamboo and broad-leaved forest interface. Chinese Journal of Plant Ecology, 2013, 37(8): 739-749]
[42] 刘骏, 杨清培, 宋庆妮, 等. 毛竹种群向常绿阔叶林扩张的细根策略. 植物生态学报, 2013, 37(3): 230-238 [Liu J, Yang Q-P, Song Q-N, et al. Strategy of fine root expansion of Phyllostachys pubescens population into evergreen broad-leaved forest. Chinese Journal of Plant Ecology, 2013, 37(3): 230-238]
[43] Grayston SJ, Campbell CD, Bardgett RD, et al. Assessing shifts in microbial community structure across a range of grasslands of differing management intensity using CLPP, PLFA and community DNA techniques. Applied Soil Ecology, 2004, 25: 63-84
[44] 王卫霞, 史作民, 罗达, 等. 南亚热带3种人工林土壤微生物生物量和微生物群落结构特征. 应用生态学报, 2013, 24(7): 1784-1792 [Wang W-X, Shi Z-M, Luo D, et al. Characteristics of soil microbial biomass and community composition in three types of plantations in southern subtropical area of China. Chinese Journal of Applied Ecology, 2013, 24(7): 1784-1792]
[45] Cantrell SA, Molina M, Lodge DJ, et al. Effects of a simulated hurricane disturbance on forest floor microbial communities. Forest Ecology and Management, 2014, 332: 22-31
[46] Miura T, Niswati A, Swibawa IG, et al. No tillage and bagasse mulching alter fungal biomass and community structure during decomposition of sugarcane leaf litter in Lampung Province, Sumatra, Indonesia. Soil Biology and Biochemistry, 2013, 58: 27-35
[47] 孙广仁. 长白山主要林型土壤酵母菌功能多样性的研究. 博士论文. 长春: 东北师范大学, 2015 [Sun G-R. Study on Functional Diversity of Soil Yeast in the Main Forests of the Changbai Mountain. PhD Thesis. Changchun: Northeast Normal University, 2015]
[48] Morriën E, Hannula SE, Snoek LB, et al. Soil networks become more connected and take up more carbon as nature restoration progresses. Nature Communications, 2017, 8: 10.1038/NCOMMS14349
[49] Xiao D, Huang Y, Feng SZ, et al. Soil organic carbon mineralization with fresh organic substrate and inorganic carbon additions in a red soil is controlled by fungal diversity along a pH gradient. Geodarma, 2018, 321: 79-89
[50] Miya RK, Firestone MK. Phenanthrene-degrader community dynamics in rhizosphere soil from a common annual grass. Journal of Environmental Quality, 2000, 29: 584-592
[51] 周丽霞, 丁明懋. 土壤微生物学特性对土壤健康的指示作用. 生物多样性, 2007, 15(2): 58-67 [Zhou L-X, Ding M-M. Soil microbial characteristics as bioindicators of soil health. Biodiversity Science,2007, 15(2): 58-67]
[52] Medina-Villar S, Rodríguez-Echeverría S, Lorenzo P, et al. Impacts of the alien trees Ailanthus altissima (Mill.) Swingle and Robinia pseudoacacia L. on soil nutrients and microbial communities. Soil Biology and Biochemistry, 2016, 96: 65-73
[53] Malik AA, Chowdhury S, Schlager V, et al. Soil fungal:bacterial ratios are linked to altered carbon cycling. Frontiers in Microbiology, 2016,7: 10.3389/fmicb.2016.01247