[1]ZHANG Aidi,ZHENG Yangxiong,WU Bishan,et al.Soil Microbial Community Diversity and Its Influencing Factors in Coastal Wetland[J].Research of Soil and Water Conservation,2020,27(03):8-14,22.
Copy
Soil Microbial Community Diversity and Its Influencing Factors in Coastal Wetland
Research of Soil and Water Conservation[ISSN 1005-3409/CN 61-1272/P] Volume:
27
Number of periods:
2020 03
Page number:
8-14,22
Column:
目次
Public date:
2020-04-20
- Title:
- Soil Microbial Community Diversity and Its Influencing Factors in Coastal Wetland
- CLC:
- X172; S153.6
- DOI:
- -
- Abstract:
- In order to study the variation of soil microbial community diversity and its influencing factors in coastal wetland from 2015—2018, mangrove wetland, reed wetland, salicornia wetland and mutual flower rice grass wetland were selected to explore soil microbial community diversity and its influencing factors. The results showed that the basic soil pH values decreased in the order: mangrove wetland>reed wetland>salicornia wetland>mutual flower rice grass wetland, and there was no significant difference in soil pH value between different wetland plant communities (p>0.05); soil organic carbon, total nitrogen and total potassium increased in the order: mangrove wetland<reed wetland<salicornia wetland<mutual flower rice grass wetland; the use of soil microbial carbon sources(AWCD)in different plant communities in coastal wetlands showed a gradually increasing trend on the whole, AWCD increased rapidly within 24 to 72 hours after cultivation, but slowly after 72 hours and sharply after 192 hours. At the same time, the uses of AWCD increased in the order: mangrove wetland<reed wetland<salicornia wetland<mutual flower rice grass wetland, with local fluctuations; carbohydrate and carboxylic acid carbon sources are the main carbon sources of soil microorganisms in different plant communities in coastal wetlands, followed by amino acids, phenolic acids and polymers, and amine carbon sources have the lowest utilization rate; the species richness index(H), evenness index(E), dominance index(Ds)and carbon source utilization richness index(S)of soil microbial community increased in the order: mangrove wetland<reed wetland<salicornia wetland<mutual flower rice grass wetland, with no significant difference in dominance index(Ds)(p>0.05). Principal component analysis results show that there is the high correlation among 18 kinds of carbon sources, among which there are five kinds of carboxylic acid compounds, 3 kinds of polymer compounds, 6 kinds of carbohydrates, 1 kind of aromatic compound, 2 kinds of amino acids, 1 kind of amine compound, amines and amino acids carbon source have main contribution to the separation of main component. Correlation analysis showed that soil nutrients and pH were closely related to the microbial community functional diversity, pH had the negative contribution to soil microbial community functional diversity, and soil nutrients had the positive contribution to soil microbial community functional diversity, which were the important influence factors on the differences of soil microbial community diversity in different plant communities in coastal wetland.
- References:
-
[1] Shen G, Ashworth D J, Gan J, et al. Biochar amendment to the soil surface reduces fumigant emissions and enhances soil microorganism recovery[J]. Environmental Science & Technology, 2016,50(3):1182-1189.
[2] Lange M, Eisenhauer N, Sierra C A, et al. Plant diversity increases soil microbial activity and soil carbon storage[J]. Nature Communications, 2015,6:6707. doi:10,1038/ncomms7707.
[3] Leff J W, Jones S E, Prober S M, et al. Consistent responses of soil microbial communities to elevated nutrient inputs in grasslands across the globe[J]. Proceedings of the National Academy of Sciences, 2015,112(35):10967-10972.
[4] Hartmann M, Frey B, Mayer J, et al. Distinct soil microbial diversity under long-term organic and conventional farming[J]. the Isme Journal, 2015,9(5):1177. doi:10,1038/ismej, 2014.210.
[5] Berg M, Stenuit B, Ho J, et al. Assembly of the Caenorhabditis elegans gut microbiota from diverse soil microbial environments[J]. the Isme Journal, 2016,10(8):1998. doi:10,1038/ismej, 2015.253.
[6] Maestre F T, Delgado-Baquerizo M, Jeffries T C, et al. Increasing aridity reduces soil microbial diversity and abundance in global drylands[J]. Proceedings of the National Academy of Sciences, 2015,112(51):15684-15689.
[7] Locey K J, Lennon J T. Scaling laws predict global microbial diversity[J]. Proceedings of the National Academy of Sciences, 2016,113(21):5970-5975.
[8] Delgado-Baquerizo M, Maestre F T, Reich P B, et al. Microbial diversity drives multifunctionality in terrestrial ecosystems[J]. Nature Communications, 2016,7:10541. doi:10,1038/ncomms10541.
[9] Simonin M, Richaume A. Impact of engineered nanoparticles on the activity, abundance, and diversity of soil microbial communities:a review[J]. Environmental Science and Pollution Research, 2015,22(18):13710-13723.
[10] Zhalnina K, Dias R, de Quadros P D, et al. Soil pH determines microbial diversity and composition in the park grass experiment[J]. Microbial Ecology, 2015,69(2):395-406.
[11] Zeng J, Liu X, Song L, et al. Nitrogen fertilization directly affects soil bacterial diversity and indirectly affects bacterial community composition[J]. Soil Biology and Biochemistry, 2016,92:41-49.
[12] Su J Q, Ding L J, Xue K, et al. Long‐term balanced fertilization increases the soil microbial functional diversity in a phosphorus-limited paddy soil[J]. Molecular Ecology, 2015,24(1):136-150.
[13] 刘红宜,陈冲,卢瑛,等.珠江三角洲平原农田土壤有机碳组分及剖面分布特征[J].土壤通报,2017,48(2):399-405.
[14] 韩志轩,王学求,迟清华,等.珠江三角洲冲积平原土壤重金属元素含量和来源解析[J].中国环境科学,2018,38(9):3455-3463.
[15] 鲍恋君,郭英,刘良英,等.珠江三角洲典型有机污染物的环境行为及人群暴露风险[J].化学进展,2017,29(9):943-961.
[16] 陈冲,贾重建,卢瑛,等.珠江三角洲平原土壤磷剖面分布及形态特征研究[J].土壤通报,2015,46(5):1025-1033.
[17] 郭颖,郭治兴,刘佳,等.亚热带典型区域水稻土氧化铁高光谱反演:以珠江三角洲为例[J].应用生态学报,2017,28(11):3675-3683.
[18] 肖蓉,韩玲,白军红,等.基于污染压力—退化表征的珠江河口湿地土壤退化评价[J].北京师范大学学报:自然科学版,2018,54(1):125-130.
[19] 杨宁,邹冬生,杨满元,等.衡阳紫色土丘陵坡地不同植被恢复阶段土壤微生物群落多样性的变化[J].林业科学,2016,52(8):146-156.
[20] 赵亚丽,郭海斌,薛志伟,等.耕作方式与秸秆还田对土壤微生物数量,酶活性及作物产量的影响[J].应用生态学报,2015,26(6):1785-1792.
[21] 朱永官,沈仁芳,贺纪正,等.中国土壤微生物组:进展与展望[J].中国科学院院刊,2017,32(6):554-565.
[22] 韩剑,张静文,徐文修,等.新疆连作,轮作棉田可培养的土壤微生物区系及活性分析[J].棉花学报,2015,23(1):69-74.
[23] 邹锋,李金前,韩丽丽,等.鄱阳湖湿地土壤微生物活性对年际水文变化的响应[J].湖泊科学,2019,31(2):551-559.
[24] 张杰,胡维,刘以珍,等.鄱阳湖湿地不同土地利用方式下土壤微生物群落功能多样性[J].生态学报,2015,35(4):729-734.
[25] 王娜,高婕,魏静,等.三江平原湿地开垦对土壤微生物群落结构的影响[J].环境科学,2019,2(5):321-329.
[26] 刘亚军,蔡润发,李赟璟,等.湿地土壤微生物碳源代谢活性对不同水分条件的动态响应:以鄱阳湖为例[J].土壤,2018,50(4):8-13.
[27] 青烨,孙飞达,李勇,等.若尔盖高寒退化湿地土壤碳氮磷比及相关性分析[J].草业学报,2015,24(3):38-45.
[28] 肖烨,黄志刚,武海涛,等.三江平原典型湿地类型土壤微生物特征与土壤养分的研究[J].环境科学,2015,36(5):1842-1848.
- Similar References:
Memo
-
Last Update:
2020-04-30