排水对我国两种典型湿地土壤有机碳微生物转化过程的影响

doi:10.13287/j.1001-9332.202401.013

应用生态学报 ›› 2024, Vol. 35 ›› Issue (1): 133-140.doi: 10.13287/j.1001-9332.202401.013

• 土壤微生物残体碳专栏 • 上一篇下一篇

排水对我国两种典型湿地土壤有机碳微生物转化过程的影响

贾娟^1,2, 李星奇^1,2,3, 冯晓娟^1,2,3*

¹中国科学院植物研究所植被与环境变化国家重点实验室, 北京 100093;
²国家植物园, 北京 100093;
³中国科学院大学, 北京 100049

收稿日期:2023-07-03 接受日期:2023-11-23 出版日期:2024-01-18 发布日期:2024-03-21
通讯作者: * E-mail: xfeng@ibcas.ac.cn
作者简介:贾娟, 女, 1986年生, 博士。主要从事土壤碳循环与生物地球化学研究。E-mail: jiajuan221@163.com责任编委马剑英
基金资助:
国家自然科学基金项目(42230501,42207341)和中国科学院青年创新促进会项目(Y2022077)

Effect of drainage on microbial transformation processes of soil organic carbon in two typical wetlands of China

JIA Juan^1,2, LI Xingqi^1,2,3, FENG Xiaojuan^1,2,3*

¹State Key Laboratory of Vegetation and Environmental Change, Institute of Botany, Chinese Academy of Sciences, Beijing 100093, China;
²China National Botanical Garden, Beijing 100093, China;
³University of Chinese Academy of Sciences, Beijing 100049, China

Received:2023-07-03 Accepted:2023-11-23 Online:2024-01-18 Published:2024-03-21

摘要/Abstract

摘要： 湿地储存了全球三分之一的土壤有机碳(SOC),并受到人为排水的强烈影响。然而,排水引起的水位下降对不同湿地碳循环(特别是微生物转化)过程的影响尚不明确。为此,本研究以我国两种典型湿地(贫营养型的大九湖湿地和富营养型的红原湿地)土壤为研究对象,通过添加¹³C标记葡萄糖的室内培养试验,分析了短期和长期排水对SOC降解、胞外酶活性、微生物碳利用效率(CUE)和微生物碳积累效率(CAE)的影响。结果表明: 长期和短期排水显著提高了两种湿地SOC降解速率(从淹水处理的1.47 μg C·g^-1·h^-1升高到排水处理的2.47 μg C·g^-1·h^-1)、葡萄糖来源的微生物生物量碳(从0.21 mg C·g^-1升高到1.00 mg C·g^-1)和CAE(从0.29升高到0.73),但未改变CUE(变化范围为0.34～0.86)。长期排水提高了大九湖湿地α-葡萄糖苷酶活性,但降低了红原湿地β-葡萄糖苷酶和酚氧化酶活性。综上,排水主要通过增强微生物胞内代谢过程(包括呼吸)提高湿地土壤“微生物碳泵”作用和效率,同时加速了SOC降解。

关键词: 微生物碳利用效率, 微生物碳积累效率, 土壤有机碳循环, 湿地, 排水

Abstract: Wetlands store one third of global soil organic carbon (SOC) and are strongly affected by artificial drainage. The impact of drainage-induced water-table decline on carbon cycling in different wetlands, particularly microbial transformation processes, remains unclear. To address this knowledge gap, we collected soil samples from two typical wetlands of China (a nutrient-poor bog located in Dajiuhu and a nutrient-rich fen in Hongyuan) and conducted an incubation experiment with the addition of ¹³C-labeled glucose to analyze the effects of short- and long-term drainage on SOC decomposition, extracellular enzyme activity, microbial carbon use efficiency (CUE), and microbial carbon accumulation efficiency (CAE). The results showed that both short- and long-term drainage significantly increased SOC decomposition rates in both wetlands (from 1.47 μg C·g^-1·h^-1 in submerged soils to 2.47 μg C·g^-1·h^-1 in drained soils), microbial biomass carbon derived from glucose (from 0.21 mg C·g^-1 to 1.00 mg C·g^-1) and CAE (from 0.29 to 0.73), but did not alter CUE (ranging from 0.34 to 0.86). Long-term drainage increased α-glucosidase activity in the Dajiuhu wetland and decreased β-glucosidase and phenol oxidase activities in the Hongyuan wetland. In conclusion, drainage enhanced the ‘microbial carbon pump' and its efficiency in wetlands mainly via increasing microbial intracellular metabolism (including respiration), but also acce-lerated SOC decomposition.

Key words: microbial carbon use efficiency, microbial carbon accumulation efficiency, soil organic carbon cycling, wetland, drainage

贾娟, 李星奇, 冯晓娟. 排水对我国两种典型湿地土壤有机碳微生物转化过程的影响[J]. 应用生态学报, 2024, 35(1): 133-140.

JIA Juan, LI Xingqi, FENG Xiaojuan. Effect of drainage on microbial transformation processes of soil organic carbon in two typical wetlands of China[J]. Chinese Journal of Applied Ecology, 2024, 35(1): 133-140.

参考文献

[1] Mitsch WJ, Bernal B, Nahlik AM, et al. Wetlands, carbon, and climate change. Landscape Ecology, 2013, 28: 583-597
[2] Bullock A, Acreman M. The role of wetlands in the hydrological cycle. Hydrology and Earth System Sciences, 2003, 7: 358-389
[3] 祝惠, 武海涛, 邢晓旭, 等. 中国湿地保护修复成效及发展策略. 中国科学院院刊, 2023, 38(3): 365-375
[4] Fenner N, Freeman C. Drought-induced carbon loss in peatlands. Nature Geoscience, 2011, 4: 895-900
[5] Zhong Y, Jiang M, Middleton BA. Effects of water level alteration on carbon cycling in peatlands. Ecosystem Health and Sustainability, 2020, 6: 1806113
[6] Luo F, Jiang X, Li H, et al. Does hydrological fluctuation alter impacts of species richness on biomass in wetland plant communities? Journal of Plant Ecology, 2016, 9: 434-441
[7] Urbanová Z, Bárta J. Effects of long-term drainage on microbial community composition vary between peatland types. Soil Biology and Biochemistry, 2016, 92: 16-26
[8] Wasilewska L. Changes in the structure of the soil nematode community over long-term secondary grassland succession in drained fen peat. Applied Soil Ecology, 2006, 32: 165-179
[9] Liang C, Schimel JP, Jastrow JD. The importance of anabolism in microbial control over soil carbon storage. Nature Microbiology, 2017, 2: 17105
[10] Keraval B, Fontaine S, Lallement A, et al. Cellular and non-cellular mineralization of organic carbon in soils with contrasted physicochemical properties. Soil Biology and Biochemistry, 2018, 125: 286-289
[11] Shen H, Nagamine T, Shiratori Y, et al. Enhanced mite grazing leads to pattern shifts in soil N₂O emissions after organic fertilizer application. Soil Biology and Bioche-mistry, 2023, 181: 109027
[12] Leifeld J, Menichetti L. The underappreciated potential of peatlands in global climate change mitigation strategies. Nature Communications, 2018, 9: 1071
[13] Tao F, Huang Y, Hungate BA, et al. Microbial carbon use efficiency promotes global soil carbon storage. Nature, 2023, 618: 981-985
[14] Jia J, Feng X, He JS, et al. Comparing microbial carbon sequestration and priming in the subsoil versus topsoil of a Qinghai-Tibetan alpine grassland. Soil Biology and Biochemistry, 2017, 104: 141-151
[15] Cai Y, Ma T, Wang Y, et al. Assessing the accumulation efficiency of various microbial carbon components in soils of different minerals. Geoderma, 2022, 407: 115562
[16] Ma T, Gao W, Shi B, et al. Effects of short- and long-term nutrient addition on microbial carbon use efficiency and carbon accumulation efficiency in the Tibetan alpine grassland. Soil and Tillage Research, 2023, 229: 105657
[17] Mathias JM, Trugman AT. Climate change impacts plant carbon balance, increasing mean future carbon use efficiency but decreasing total forest extent at dry range edges. Ecology Letters, 2022, 25: 498-508
[18] 李志威, 王兆印, 张晨笛, 等. 若尔盖沼泽湿地的萎缩机制. 水科学进展, 2014, 25(2): 172-180
[19] Harris D, Horwath WR, van Kessel C. Acid fumigation of soils to remove carbonates prior to total organic carbon or carbon-13 isotopic analysis. Soil Science Society of America Journal, 2001, 65: 1853-1856
[20] Di Stefano C, Ferro V, Mirabile S. Comparison between grain-size analyses using laser diffraction and sedimentation methods. Biosystems Engineering, 2010, 106: 205-215
[21] Huang W, Hall SJ. Elevated moisture stimulates carbon loss from mineral soils by releasing protected organic matter. Nature Communications, 2017, 8: 1774
[22] Burns RG, DeForest JL, Marxsen J, et al. Soil enzymes in a changing environment: Current knowledge and future directions. Soil Biology and Biochemistry, 2013, 58: 216-234
[23] German DP, Weintraub MN, Grandy S, et al. Optimization of hydrolytic and oxidative enzyme methods for ecosystem studies. Soil Biology and Biochemistry, 2011, 43: 1387-1397
[24] Vance E, Brookes P, Jenkinson D. An extraction method for measuring soil microbial biomass C. Soil Biology and Biochemistry, 1987, 19: 703-707
[25] Geyer K, Schnecker J, Grandy AS, et al. Assessing microbial residues in soil as a potential carbon sink and moderator of carbon use efficiency. Biogeochemistry, 2020, 151: 237-249
[26] Wei X, Cao R, Wu X, et al. Effect of water table decline on the abundances of soil mites, springtails, and nematodes in the Zoige peatland of eastern Tibetan Pla-teau. Applied Soil Ecology, 2018, 129: 77-83
[27] Mganga KZ, Sietiö OM, Meyer N, et al. Microbial carbon use efficiency along an altitudinal gradient. Soil Biology and Biochemistry, 2022, 173: 108799
[28] Allison SD. Modeling adaptation of carbon use efficiency in microbial communities. Frontiers in Microbiology, 2014, 5: 00571
[29] Šantrůčková H, Picek T, Tykva R, et al. Short-term partitioning of ¹⁴C-glucose in the soil microbial pool under varied aeration status. Biology and Fertility of Soils, 2004, 40: 386-392
[30] 陈智, 于贵瑞. 土壤微生物碳素利用效率研究进展. 生态学报, 2020, 40(3): 756-767
[31] Hill BH, Elonen CM, Herlihy AT, et al. Microbial ecoenzyme stoichiometry, nutrient limitation, and organic matter decomposition in wetlands of the conterminous United States. Wetlands Ecology and Management, 2018, 26: 425-439
[32] Voegelin A, Kaegi R, Frommer J, et al. Effect of phosphate, silicate, and Ca on Fe(III)-precipitates formed in aerated Fe(II)- and As(III)-containing water stu-died by X-ray absorption spectroscopy. Geochimica et Cosmochimica Acta, 2010, 74: 164-186
[33] Mason-Jones K, Breidenbach A, Dyckmans J, et al. Intracellular carbon storage by microorganisms is an overlooked pathway of biomass growth. Nature Communications, 2023, 14: 2240
[34] Angst G, Mueller KE, Nierop KGJ, et al. Plant- or microbial-derived? A review on the molecular composition of stabilized soil organic matter. Soil Biology and Biochemistry, 2021, 156: 108189
[35] Jia B, Niu Z, Wu Y, et al. Waterlogging increases organic carbon decomposition in grassland soils. Soil Bio-logy and Biochemistry, 2020, 148: 107927
[36] Solomon D, Lehmann J, Zech W. Land use effects on amino sugar signature of chromic Luvisol in the semi-arid part of northern Tanzania. Biology and Fertility of Soils, 2001, 33: 33-40
[37] Ma T, Zhu S, Wang Z, et al. Divergent accumulation of microbial necromass and plant lignin components in grassland soils. Nature Communications, 2018, 9: 3480
[38] Barcenas-Moreno G, Baath E, Rousk J. Functional implications of the pH-trait distribution of the microbial community in a re-inoculation experiment across a pH gradient. Soil Biology and Biochemistry, 2016, 93: 69-78
[39] Liu C, Wang S, Zhu E, et al. Long-term drainage induces divergent changes of soil organic carbon contents but enhances microbial carbon accumulation in fen and bog. Geoderma, 2021, 404: 115343
[40] Wang Y, Wang H, He JS, et al. Iron-mediated soil carbon response to water-table decline in an alpine wetland. Nature Communications, 2017, 8: 15972

排水对我国两种典型湿地土壤有机碳微生物转化过程的影响

Effect of drainage on microbial transformation processes of soil organic carbon in two typical wetlands of China

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