Home > Archive>Volume 63, Issue 6, 2023 >2312-2329. DOI:10.13343/j.cnki.wsxb.20230287
PDF HTML XML Export Cite reminder
Response of geochemistry and bacterial communities to water-level rise in the soil and sediment of the coastal zone in Qinghai Lake
Author:
  • Article
    • | |
  • Metrics
    • |
  • Reference [57]
    • |
  • Related [20]
    • | | |
  • Comments
    Abstract:

    [Objective] To investigate the response of geochemistry and bacterial communities to water-level rise in the soil and sediment of the coastal zone of Qinghai Lake. [Methods] Surface samples were collected from the onshore soil (soil: S1, S2), littoral zone (transition: E0, E6, E17) and deep sediment (sediment: D1, D2) along the direction perpendicular to the shoreline near the Bird Island of Qinghai Lake. The water depth of the soil and sediment samples (soil water depths were expressed as negative numbers) was employed to characterize the transformation of shoreline soil into sediment caused by inundation. Geochemical analysis and 16S rRNA gene high-throughput sequencing were employed to explore the geochemical characteristics and microbial community composition in the collected soil and sediment samples. [Results] (1) The water level rise of Qinghai Lake significantly affects the geochemical characteristics, nutrient levels, and organic carbon types in the soils and sediments of the coastal zone. Specifically, the pH and mineral associated organic carbon contents of the soil and sediment in the shore zone increased significantly while the C/N value and the contents of dissolved organic carbon (DOC) and particulate organic carbon decreased significantly with the increase of water level; (2) The water level rise of Qinghai Lake will reduce the diversity of bacterial communities and change their community structure in the coastal soils and sediments. These changes in bacterial communities are closely related to changes in environmental factors caused by water level rise. Specifically, after the onshore soil was inundated by water level rise, the bacterial communities inhabiting it exhibited a decrease in the number of operational taxonomic unit (OTU) and Shannon diversity index; the changes of bacterial community diversity was closely related to the content of organic carbon bound with active metal; the important environmental factors that affect bacterial community structure included physicochemical properties (pH), nutrient level (total organic carbon content), and organic carbon quality (C/N value, organic carbon pool II, and mineral associated organic carbon content). Physicochemical properties, nutrient level, and organic carbon quality contributed equally to the differences in bacterial community structure. [Conclusion] The water level rise of Qinghai Lake has significantly affected the physiochemical characteristics, nutrient levels, and organic carbon quality of coastal soil and sediment, and reshaped the bacterial community structure. This implies that the regional carbon cycle homeostasis of the Qinghai-Tibetan lakes will change in the context of the extensive expansion of lakes on the Qinghai-Tibet Plateau. This study provides a data base and theoretical support for the evolution of soil and sediment microbial communities and the evaluation of ecosystem carbon stability in response to lake expansion.

    Reference
    [1] WANG JD, SONG CQ, REAGER JT, YAO FF, FAMIGLIETTI JS, SHENG YW, MACDONALD GM, BRUN F, SCHMIED HM, MARSTON RA, WADA Y. Recent global decline in endorheic basin water storages[J]. Nature Geoscience, 2018, 11(12):926-932.
    [2] 常超, 谢宗强, 熊高明, 储立民. 三峡水库蓄水对消落带土壤理化性质的影响[J]. 自然资源学报, 2011, 26(7):1236-1244. CHANG C, XIE ZQ, XIONG GM, CHU LM. The effect of flooding on soil physical and chemical properties of riparian zone in the Three Gorges Reservoir[J]. Journal of Natural Resources, 2011, 26(7):1236-1244(in Chinese).
    [3] 张金洋, 王定勇, 石孝洪. 三峡水库消落区淹水后土壤性质变化的模拟研究[J]. 水土保持学报, 2004, 18(6):120-123. ZHANG JY, WANG DY, SHI XH. Change of soil character after flooding in drawdown area of Three Gorges Reservoir[J]. Journal of Soil and Water Conservation, 2004, 18(6):120-123(in Chinese).
    [4] 唐罗忠, 生原喜久雄, 户田浩人, 黄宝龙. 湿地林土壤的Fe2+、Eh及pH值的变化[J]. 生态学报, 2005, 25(1):103-107. TANG LZ, HAIBARA K, TODA H, HUANG BL. Dynamics of ferrous iron, redox potential and pH of forested wetland soils[J]. Acta Ecologica Sinica, 2005, 25(1):103-107(in Chinese).
    [5] 焦坤, 李忠佩. 土壤溶解有机质的含量动态及转化特征的研究进展[J]. 土壤, 2005, 37(6):593-601. JIAO K, LI ZP. Advances in research on concentration and transformation of dissolved organic matter in soils[J]. Soils, 2005, 37(6):593-601(in Chinese).
    [6] MARTIN JC, MARK BD. Temperature and moisture effects on the production of dissolved organic carbon in a Spodosol[J]. Soil Biology and Biochemistry, 1996, 28(9):1191-1199.
    [7] KALBITZ K, KNAPPE S. Influence of soil properties on the release of dissolved organic matter (DOM) from the topsoil[J]. Zeitschrift fur Pflanzenernahrung und Bodenkunde, 1997, 160(5):475-483.
    [8] 张丹丹. 三峡水库消落区土壤有机碳动态格局与微生物学特征[D]. 北京:中国科学院大学博士学位论文, 2020. ZHANG DD. Dynamic pattern and microbiological characteristics of soil organic carbon in water-fluctuating zone of Three Gorges Reservoir[D]. Beijing:Doctoral Dissertation of University of Chinese Academy of Sciences, 2020(in Chinese).
    [9] 王嫒华, 苏以荣, 李杨, 胡乐宁, 吴金水. 水田和旱地土壤有机碳周转对水分的响应[J]. 中国农业科学, 2012, 45(2):266-274. WANG AH, SU YR, LI Y, HU LN, WU JS. Response of the turnover of soil organic carbon to the soil moisture in paddy and upland soil[J]. Scientia Agricultura Sinica, 2012, 45(2):266-274(in Chinese).
    [10] CHEN LY, LIU L, QIN SQ, YANG GB, FANG K, ZHU B, KUZYAKOV Y, CHEN PD, XU YP, YANG YH. Regulation of priming effect by soil organic matter stability over a broad geographic scale[J]. Nature Communications, 2019, 10:5112.
    [11] ROVIRA P, VALLEJO VR. Labile and recalcitrant pools of carbon and nitrogen in organic matter decomposing at different depths in soil:an acid hydrolysis approach[J]. Geoderma, 2002, 107(1/2):109-141.
    [12] HALL SJ, YE CL, WEINTRAUB SR, HOCKADAY WC. Molecular trade-offs in soil organic carbon composition at continental scale[J]. Nature Geoscience, 2020, 13(10):687-692.
    [13] SCHAEFFER A, NANNIPIERI P, KÄSTNER M, SCHMIDT B, BOTTERWECK J. From humic substances to soil organic matter-microbial contributions. in honor of Konrad Haider and James P. Martin for their outstanding research contribution to soil science[J]. Journal of Soils and Sediments, 2015, 15(9):1865-1881.
    [14] CAMBARDELLA CA, ELLIOTT ET. Particulate soil organic-matter changes across a grassland cultivation sequence[J]. Soil Science Society of America Journal, 1992, 56(3):777-783.
    [15] WATSON JR, PARSONS JW. Studies of soil organo-mineral fractions[J]. Journal of Soil Science, 1974, 25(1):1-8.
    [16] LALONDE K, MUCCI A, QUELLET A, GÉLINAS Y. Preservation of organic matter in sediments promoted by iron[J]. Nature, 2012, 483(7388):198-200.
    [17] POSSINGER AR, ZACHMAN MJ, ENDERS A, LEVIN BDA, MULLER DA, KOURKOUTIS LF, LEHMANN J. Organo-organic and organo-mineral interfaces in soil at the nanometer scale[J]. Nature Communications, 2020, 11:6103.
    [18] ARNDT S, JØRGENSEN BB, LAROWE DE, MIDDELBURG JJ, PANCOST RD, REGNIER P. Quantifying the degradation of organic matter in marine sediments:a review and synthesis[J]. Earth-Science Reviews, 2013, 123:53-86.
    [19] BURD AB, FREY S, CABRE A, ITO T, LEVINE NM, LØNBORG C, LONG M, MAURITZ M, THOMAS RQ, STEPHENS BM, VANWALLEGHEM T, ZENG N. Terrestrial and marine perspectives on modeling organic matter degradation pathways[J]. Global Change Biology, 2016, 22(1):121-136.
    [20] JANSSON JK, HOFMOCKEL KS. Soil microbiomes and climate change[J]. Nature Reviews Microbiology, 2020, 18(1):35-46.
    [21] JIANG HC, HUANG JR, LI L, HUANG LQ, MANZOOR M, YANG J, WU G, SUN XX, WANG BC, EGAMBERDIEVA D, PANOSYAN H, BIRKELAND NK, ZHU ZH, LI WJ. Onshore soil microbes and endophytes respond differently to geochemical and mineralogical changes in the Aral Sea[J]. Science of the Total Environment, 2021, 765:142675.
    [22] MO YL, JIN F, ZHENG Y, BAOYIN T, HO A, JIA ZJ. Succession of bacterial community and methanotrophy during lake shrinkage[J]. Journal of Soils and Sediments, 2020, 20(3):1545-1557.
    [23] SONG CQ, HUANG B, KE LH. Modeling and analysis of lake water storage changes on the Tibetan Plateau using multi-mission satellite data[J]. Remote Sensing of Environment, 2013, 135:25-35.
    [24] ZHANG GQ, CHEN WF, XIE HJ. Tibetan Plateau's Lake level and volume changes from NASA's ICESat/ICESat-2 and landsat missions[J]. Geophysical Research Letters, 2019, 46(22):13107-13118.
    [25] 严德行, 朱宝文, 谢启玉, 邓永龙, 唐仲涛, 任得萍, 严玉霞, 王红莉, 周少龙. 环青海湖地区气温变化特征[J]. 气象科技, 2011, 39(1):33-37. YAN DX, ZHU BW, XIE QY, DENG YL, TANG ZT, REN DP, YAN YX, WANG HL, ZHOU SL. Characteristics of temperature variation in regions around Qinghai Lake[J]. Meteorological Science and Technology, 2011, 39(1):33-37(in Chinese).
    [26] 莫申国, 张百平, 程维明, 谭娅, 肖飞, 武红智. 青藏高原的主要环境效应[J]. 地理科学进展, 2004, 23(2):88-96. MO SG, ZHANG BP, CHENG WM, TAN Y, XIAO F, WU HZ. Major environmental effects of the Tibetan Plateau[J]. Progress in Geography, 2004, 23(2):88-96(in Chinese).
    [27] CUI BL, XIAO B, LI XY, WANG Q, ZHANG ZH, ZHAN C, LI XD. Exploring the geomorphological processes of Qinghai Lake and surrounding lakes in the northeastern Tibetan Plateau, using multitemporal landsat imagery (1973-2015)[J]. Global and Planetary Change, 2017, 152:167-175.
    [28] 祁苗苗, 姚晓军, 刘时银, 朱钰, 高永鹏, 刘宝康. 1973-2018年青海湖岸线动态变化[J]. 湖泊科学, 2020, 32(2):573-586. QI MM, YAO XJ, LIU SY, ZHU Y, GAO YP, LIU BK. Dynamic change of Lake Qinghai shoreline from 1973 to 2018[J]. Journal of Lake Sciences, 2020, 32(2):573-586(in Chinese).
    [29] 杨显明, 张鸽, 加壮壮, 宋欣怡, 王晓梅. 全球气候变化背景下青海湖岸线变化及其对社会经济影响[J]. 高原科学研究, 2021, 5(4):1-9, 15. YANG XM, ZHANG G, JIA ZZ, SONG XY, WANG XM. Study on the shoreline evolution of Qinghai Lake and its socio-economic impact under the background of global climate change[J]. Plateau Science Research, 2021, 5(4):1-9, 15(in Chinese).
    [30] 王大钊. 基于GEE的青海湖近30年水量变化遥感分析[D]. 西安:西北大学硕士学位论文, 2020. WANG DZ. Remote sensing analysis of water quantity change in Qinghai Lake in recent 30 years based on GEE[D]. Xi'an:Master's Thesis of Northwest University, 2020(in Chinese).
    [31] 李璐璐, 江韬, 闫金龙, 郭念, 魏世强, 王定勇, 高洁, 赵铮. 三峡库区典型消落带土壤及沉积物中溶解性有机质(DOM)的紫外-可见光谱特征[J]. 环境科学, 2014, 35(3):933-941. LI LL, JIANG T, YAN JL, GUO N, WEI SQ, WANG DY, GAO J, ZHAO Z. Ultraviolet-visible (UV-vis) spectral characteristics of dissolved organic matter (DOM) in soils and sediments of typical water-level fluctuation zones of Three Gorges Reservoir areas[J]. Environmental Science, 2014, 35(3):933-941(in Chinese).
    [32] OHNO T, FERNANDEZ IJ, HIRADATE S, SHERMAN JF. Effects of soil acidification and forest type on water soluble soil organic matter properties[J]. Geoderma, 2007, 140(1/2):176-187.
    [33] CHEN CM, DYNES JJ, WANG J, SPARKS DL. Properties of Fe-organic matter associations via coprecipitation versus adsorption[J]. Environmental Science & Technology, 2014, 48(23):13751-13759.
    [34] LUGATO E, LAVALLEE JM, HADDIX ML, PANAGOS P, COTRUFO MF. Different climate sensitivity of particulate and mineral-associated soil organic matter[J]. Nature Geoscience, 2021, 14(5):295-300.
    [35] LAVALLEE JM, SOONG JL, COTRUFO MF. Conceptualizing soil organic matter into particulate and mineral-associated forms to address global change in the 21st century[J]. Global Change Biology, 2020, 26(1):261-273.
    [36] EDGAR RC. UPARSE:highly accurate OTU sequences from microbial amplicon reads[J]. Nature Methods, 2013, 10(10):996-998.
    [37] HAMMER O, HARPER D, RYAN P. PAST:paleontological statistics software package for education and data analysis version 2.09[J]. Palaeontologia Electronica, 2001, 4(1):4-9.
    [38] BLANCHET FG, LEGENDRE P, BORCARD D. Forward selection of explanatory variables[J]. Ecology, 2008, 89(9):2623-2632.
    [39] AMENDOLA D, MUTEMA M, ROSOLEN V, CHAPLOT V. Soil hydromorphy and soil carbon:a global data analysis[J]. Geoderma, 2018, 324:9-17.
    [40] BAI YF, MA LN, DEGEN AA, RAFIQ MK, KUZYAKOV Y, ZHAO JX, ZHANG R, ZHANG T, WANG WY, LI XG, LONG RJ, SHANG ZH. Long-term active restoration of extremely degraded alpine grassland accelerated turnover and increased stability of soil carbon[J]. Global Change Biology, 2020, 26(12):7217-7228.
    [41] PANDEY D, AGRAWAL M, SINGH BOHRA J, ADHYA TK, BHATTACHARYYA P. Recalcitrant and labile carbon pools in a sub-humid tropical soil under different tillage combinations:a case study of rice-wheat system[J]. Soil and Tillage Research, 2014, 143:116-122.
    [42] SHIELDS MR, BIANCHI TS, GÉLINAS Y, ALLISON MA, TWILLEY RR. Enhanced terrestrial carbon preservation promoted by reactive iron in deltaic sediments[J]. Geophysical Research Letters, 2016, 43(3):1149-1157.
    [43] ZHAO Q, POULSON SR, OBRIST D, SUMAILA S, DYNES JJ, MCBETH JM, YANG Y. Iron-bound organic carbon in forest soils:quantification and characterization[J]. Biogeosciences, 2016, 13(16):4777-4788.
    [44] KLEBER M, EUSTERHUES K, KEILUWEIT M, MIKUTTA C, MIKUTTA R, NICO PS. Mineral-organic associations:formation, properties, and relevance in soil environments[J]. Advances in Agronomy, 2015, 130:1-140.
    [45] ZHOU JZ, XIA BC, TREVES DS, WU LY, MARSH TL, O'NEILL RV, PALUMBO AV, TIEDJE JM. Spatial and resource factors influencing high microbial diversity in soil[J]. Applied and Environmental Microbiology, 2002, 68(1):326-334.
    [46] CHEN L, DING NF, FU QL, BROOKES PC, XU JM, GUO B, LIN YC, LI H, LI NY. The influence of soil properties on the size and structure of bacterial and fungal communities along a paddy soil chronosequence[J]. European Journal of Soil Biology, 2016, 76:9-18.
    [47] 杨毅, 张耀之, 李秀颖, 曾祥峰, 宋玉芳, 严俊. 脱卤球菌纲(Dehalococcodia class)在有机卤化物生物地球化学循环中的作用[J]. 环境科学学报, 2019, 39(10):3207-3214. YANG Y, ZHANG YZ, LI XY, ZENG XF, SONG YF, YAN J. Roles of Dehalococcodia class in the biogeochemical cycle of organohalides[J]. Acta Scientiae Circumstantiae, 2019, 39(10):3207-3214(in Chinese).
    [48] RATH KM, FIERER N, MURPHY DV, ROUSK J. Linking bacterial community composition to soil salinity along environmental gradients[J]. The ISME Journal, 2019, 13(3):836-846.
    [49] YANG J, MA LA, JIANG HC, WU G, DONG HL. Salinity shapes microbial diversity and community structure in surface sediments of the Qinghai-Tibetan lakes[J]. Scientific Reports, 2016, 6:25078.
    [50] XIONG JB, LIU YQ, LIN XG, ZHANG HY, ZENG J, HOU JZ, YANG YP, YAO TD, KNIGHT R, CHU HY. Geographic distance and pH drive bacterial distribution in alkaline lake sediments across Tibetan Plateau[J]. Environmental Microbiology, 2012, 14(9):2457-2466.
    [51] YANG J, JIANG HC, SUN XX, HUANG JR, HAN MX, WANG BC. Distinct co-occurrence patterns of prokaryotic community between the waters and sediments in lakes with different salinity[J]. FEMS Microbiology Ecology, 2021, 97(1):fiaa234.
    [52] SHI RJ, XU SM, QI ZH, ZHU QZ, HUANG HH, WEBER F. Influence of suspended mariculture on vertical distribution profiles of bacteria in sediment from Daya Bay, southern China[J]. Marine Pollution Bulletin, 2019, 146:816-826.
    [53] OLLIVIER J, TÖWE S, BANNERT A, HAI B, KASTL EM, MEYER A, SU MX, KLEINEIDAM K, SCHLOTER M. Nitrogen turnover in soil and global change[J]. FEMS Microbiology Ecology, 2011, 78(1):3-16.
    [54] PAN X, LIN L, HUANG HW, CHEN J. Differentiation of nitrogen and microbial community in the sediments from Lake Erhai, Yunnan-Kweichow Plateau, China[J]. Geomicrobiology Journal, 2020, 37(9):818-825.
    [55] XU CY, DU C, JIAN JS, HOU L, WANG ZK, WANG Q, GENG ZC. The interplay of labile organic carbon, enzyme activities and microbial communities of two forest soils across seasons[J]. Scientific Reports, 2021, 11:5002.
    [56] NAIR A, SARMA SJ. The impact of carbon and nitrogen catabolite repression in microorganisms[J]. Microbiological Research, 2021, 251:126831.
    [57] BURNS RG, DEFOREST JL, MARXSEN J, SINSABAUGH RL, STROMBERGER ME, WALLENSTEIN MD, WEINTRAUB MN, ZOPPINI A. Soil enzymes in a changing environment:current knowledge and future directions[J]. Soil Biology and Biochemistry, 2013, 58:216-234.
    Cited by
    Comments
    Comments
    分享到微博
    Submit
Get Citation

LI Xinyi, WANG Beichen, XIONG Xiong, AO Hongyi, WU Chenxi, YANG Jian, JIANG Hongchen. Response of geochemistry and bacterial communities to water-level rise in the soil and sediment of the coastal zone in Qinghai Lake. [J]. Acta Microbiologica Sinica, 2023, 63(6): 2312-2329

Copy
Share
Article Metrics
  • Abstract:275
  • PDF: 892
  • HTML: 640
  • Cited by: 0
History
  • Received:April 20,2023
  • Revised:May 29,2023
  • Online: June 06,2023
  • Published: June 04,2023
Article QR Code
  • WeChat ID
  • Mobile Terminal

Acta Microbiologica Sinica ® 2025 All Rights Reserved