Effects and Mechanism of Indoleacetic Acid on the Removal of Nitrogen and Phosphorus from Water by Peripheral Organisms

doi:10.13304/j.nykjdb.2021.0109

Abstract

Abstract:

In order to explore the effects and mechanism of the sequence and concentration of adding indoleacetic acid on the removal of nitrogen and phosphorus from the water by peripheral organisms， the artificially cultivated peripheral organisms were as the research object， and the peripheral organisms that had been pre-cultured with indoleacetic acid （pretreatment group） and those that have not been pre-cultured with indoleacetic acid （control group） were cultured in nitrogen and phosphorus sewage with different concentrations of indoleacetic acid （0， 5 and 10 mg·L^-1）. The results revealed that the addition of indoleacetic acid improved the removal efficiency of nitrogen and phosphorus by peripheral organisms. In control group， the removal rates of NH $4 +$ -N and PO $4 3 -$ -P by peripheral organisms added with 5 mg·L^-1 indoleacetic acid were 99.9% and 95.0%， respectively， on the 2^nd day， and the removal rate of NO $3 -$ -N was 99.0% on the 7^th day， whose removal rates were faster 2 d than those of^{pretreatment group. Indoleacetic acid changed the microbial community structure of peripheral organisms with the total composition of phospholipids fatty acids decreasing， the number of bacteria， actinomycetes and gram-positive bacteria （G⁺） increasing， chlorophyll fluorescence F_t reducing and pH increasing. In conclusion， the addition of indoleacetic acid could promote the growth of algae in peripheral organisms and improve the removal efficiency of nitrogen and phosphorus by periplexus organisms.}

Key words: periphyton, indoleacetic acid, nitrogen and phosphorus, microbial community

摘要：

为探究吲哚乙酸添加的先后顺序和质量浓度对周丛生物去除水体中氮磷的影响及其作用机理，以人工培养的周丛生物为研究对象，分别用预先经过吲哚乙酸培养的周丛生物（预处理组）和未经过吲哚乙酸培养的周丛生物（对照组）在含有不同质量浓度（0、5 和10 mg·L^-1）吲哚乙酸的氮磷污水中培养。结果表明，添加吲哚乙酸提高了周丛生物对水体中氮磷的去除效率，对照组中，添加5 mg·L^-1吲哚乙酸的周丛生物在第2天对NH $4 +$ -N、PO $4 3 -$ -P的去除率分别为99.9%、95.0%，第7天对NO $3 -$ -N的去除率为99.0%，且对照组比预处理组的去除速率更高，比预处理组快2 d。吲哚乙酸的添加改变了周丛生物的微生物群落结构，总磷脂脂肪酸组成减少，细菌、放线菌以及革兰氏阳性菌（G⁺）数量增加，溶液叶绿素荧光F_t值下降，pH升高。综上所述，添加吲哚乙酸促进了周丛生物中藻类的生长，提高了周丛生物对氮磷的去除效率。

关键词: 周丛生物, 吲哚乙酸, 氮和磷去除, 微生物群落

CLC Number:

X172

Chenchen SUN, Lan MA, Yonghong WU, Yuanchun YU. Effects and Mechanism of Indoleacetic Acid on the Removal of Nitrogen and Phosphorus from Water by Peripheral Organisms[J]. Journal of Agricultural Science and Technology, 2022, 24(3): 204-209.

孙沉沉, 马兰, 吴永红, 俞元春. 吲哚乙酸对周丛生物去除水体中氮磷的影响及机理[J]. 中国农业科技导报, 2022, 24(3): 204-209.

Figures/Tables 4

References 30

1	李文静,毛纪隆,吴玉环,等.吲哚乙酸对铝胁迫下栝楼生理响应及DNA损伤的缓解作用[J].应用生态学报,2020,31(12):4235-4242.
	LI W J, MAO J L, WU Y H, et al.. Effects of IAA on physiological response to aluminum stress and DNA damage of Trichosan-thes kirilowii [J]. Chin. J. Appl. Ecol., 2020, 31(12):4235-4242.
2	DUCA D, LORV J, PATTEN C L, et al.. Indole-3-acetic acid in plant-microbe interactions [J]. Antonie Van Leeuwenhoek Int. J. Gen. Mol. Microbiol., 2014, 106(1):85-125.
3	TSAVKELOVA E A, CHERDYNTSEVA T A, NETUSOV A I. Auxin production by bacteria associated with orchid roots [J]. Microbiology, 2005, 74(1):46-53.
4	BIANCO C, IMPERLINI E, CALOGERO R, et al.. Indole-3-acetic acid improves Escherichia coli's defences to stress [J]. Archives Microbiol., 2006, 185(5):373-382.
5	SPAEPEN S, VANDERLEYDEN J, REMENS R. Indole-3-acetic acid in microbial and microorganism-plant signaling [J]. Fems Microbiol. Rev., 2007, 31(4):425-448.
6	赵婧宇,韩建刚,孙朋飞,等.周丛生物对稻田氨挥发的影响[J].土壤学报,2021,58(5):1267-1277.
	ZHAO J Y,HAN J G,SUN P F,et al.. Effect and mechanism of periphyton affecting ammonia volatilization in paddy field [J]. Acta Pedol. Sin., 2021, 58(5):1267-1277.
7	BONDAR-KUNZE E, MAIER S, SHCOENAUER D, et al.. Antagonistic and synergistic effects on a stream periphyton community under the influence of pulsed flow velocity increase and nutrient enrichment [J]. Sci. Total Environ., 2016, 573:594-602.
8	HUNG J J, HUNG C S, SU H M. Biogeochemical responses to the removal of maricultural structures from an eutrophic lagoon (Tapong Bay) in Taiwan [J]. Mar. Environ. Res., 2008, 65:1-17.
9	崔经国.海河流域典型河流周丛生物的生态计量学研究[D].北京:中国科学院研究生院,2011.
	CUI J G. Ecological stoichiometric study on periphyton of typical rivers in the Hai River Basin [D]. Beijing: Chinese Academy of Sciences, 2011.
10	SONG C, LIN J, HUANG X, et al.. Effect of butyl paraben on the development and microbial composition of periphyton [J]. Ecotoxicology, 2016, 25(2):342-349.
11	PROSSER R S, RICHARD A, MALIA J, et al.. Assessing temporal and spatial variation in sensitivity of communities of periphyton sampled from agro ecosystem to, and ability to recover from, atrazine exposure [J]. Ecotoxicol. Environ. Saf., 2015, 118(5):204-216.
12	MERCIER A, GRAVOUIL K, AUCHER W, et al.. Fate of eight different polymers under uncontrolled composting conditions: relationships between deterioration, biofilm formation, and the material surface properties [J]. Environ. Sci. Technol., 2017, 51(4):1988-1997.
13	WU Y, LI T, YANG L, et al.. Mechanisms of removing pollutants from aqueous solutions by microorganisms and their aggregates: a review [J]. Bioresour. Technol., 2012, 107(1):10-18.
14	MORENO GARRIDO I. Microalgae immobilization: current techniques and uses [J]. Bioresour. Technol., 2008, 99(10):3949-3964.
15	马兰.吲哚乙酸(IAA)作用下周丛生物的响应及其对水体中氮磷的去除效果[D].南京:南京林业大学,2018.
	MA L. The responses of periphyton and the removal of nitrogen and phosphorus from water under the action of indole acetic acid (IAA) [D]. Nanjing: Nanjing Forestry University, 2018.
16	BLIGH E G, DYER W J. A rapid method of total lipid extraction and purification [J]. Can. J. Biochem. Physiol., 1959, 37:911-917.
17	BRANT J B, SULZMAN E W, MYROLD D D. Microbial community utilization of added carbon substrates in response to long-term carbon input manipulation [J]. Soil Biol. Biochem., 2006, 38(8):2219-2232.
18	任南琪,赵庆良.水污染控制原理与技术[M].北京:清华大学出版社,2007:172-174.
19	JETTEN M S M,STROUS M,DE PAS⁃SCHOONEN K TVAN,et al.. The anaerobic oxidation of ammonium [J]. FEMS Microbiol. Rev., 1998, 22(5):421-437.
20	吴国平,高孟宁,唐骏,等.自然生物膜对面源污水中氮磷去除的研究进展[J].生态与农村环境学报,2019,35(7):817-825.
	WU G P, GAO M N, TANG J, et al.. Progress of researches on nitrogen and phosphorus removal by periphytic biofilm from non⁃point source wastewater [J]. J. Ecol. Rura. Environ., 2019, 35(7):817-827.
21	BOELEE N C, TEMMINK H, JANSSEN M, et al.. Nitrogen and phosphorus removal from municipal wastewater effluent using microalgal biofilms [J]. Water Res., 2011, 45(18):5925-5933.
22	JARVIE H P, NEAL C, WARWICK A, et al.. Phosphorus uptake into algal biofilms in a lowland chalk river [J]. Sci. Total Environ., 2002, 282:353-373.
23	LIU J, DANNEELS B, VANORMELINGEN P, et al.. Nutrient removal from horticultural wastewater by benthic filamentous algae Klebsormidium sp., Stigeoclonium spp. and their communities: from laboratory flask to outdoor Algal Turf Scrubber (ATS) [J]. Water Res., 2016, 92:61-68.
24	WU Y H, LIU J Z, RENE E R. Periphytic biofilms: A promising nutrient utilization regulator in wetlands [J]. Bioresour. Technol., 2018, 248:44-58.
25	LU H Y, WAN J J, LI J Y, et al.. Periphytic biofilm: A buffer for phosphorus precipitation and release between sediment sandwater [J]. Chemosphere, 2016, 144:2058-2064.
26	凌晓欢,况琪军,胡征宇,等.两种藻类对水体氮、磷去除效果[J].武汉大学学报(理学版),2006,52(4):487-491.
	LING X H, KUANG Q J, HU Z Y, et al.. Removal efficiency of nitrogen and phosphorus in wastewater by two species of algae [J]. J. Wuhan Univ. (Nat. Sci.), 2006, 52(4):487-491.
27	吕福荣,杨海波,李英敏,等.自养条件下小球藻净化氮、磷能力的研究[J].生物技术,2003,13(6):46-47.
	LV F R, YANG H B, LI Y M, et al.. Study on the N,P purification ability of chlorella under autotrophic condition [J]. Biotechnlogy, 2003, 13(6):46-47.
28	WU Y H, LIU J Z, RENE E R. Periphytic biofilms: a promising nutrient utilization regulator in wetlands [J]. Bioresour. Technol., 2018, 248:44-48.
29	邓旭,魏斌,胡章立,等.利用莱茵衣藻去除污水中氮磷的研究[J].环境科学,2010,31(6):1489-1493.
	DENG X, WEI B, HU Z L, et al.. Study on the removal of nitrogen and phosphorus from wastewater by chlamydomonas Reinhardt [J]. Environ. Sci., 2010, 31(6):1489-1493.
30	马军,雷国元.水绵(Spirogyra)的除磷特性及其对微藻生长的抑制作用[J].环境科学学报,2008,28(3):476-483.
	MA J, LEI G Y. Characeristics of phosphorus removal and growth inhibition of microalgal species by Spirogyra [J]. Acta Sci. Circumst., 2008, 28(3):476-483.

处理 Treatment	磷脂脂肪酸PLFA/ （nmol·g^-1）	细菌 Bacteria/ （nmol·g^-1）	真菌 Fungus/ （nmol·g^-1）	放线菌 Actinmyces/（nmol·g^-1）	革兰氏阴性菌 G^-/ （nmol·g^-1）	革兰氏阳性菌G⁺/ （nmol·g^-1）	原生动物 Protozoon/（nmol·g^-1）
CK	99.66±1.65 a	15.05±0.48 c	21.79±0.31 a	0.18±0.05 a	11.67±0.05 b	2.98±0.26 c	0.29±0.02 d
A₅	99.05±2.49 a	17.02±0.64 b	17.60±0.78 c	0.75±0.01 b	9.91±0.17 c	6.48±0.08 b	0.36±0.01 c
A₁₀	98.13±2.67 a	18.63±0.74 a	18.83±0.9 b	0.31±0.04 c	11.81±0.36 b	5.86±0.39 b	0.22±0.06 d
B₅	99.10±2.82 a	19.17±0.95 a	19.37±0.49 abc	0.49±0.61 abc	12.40±0.88 ab	5.83±0.67 abc	1.07±0.01 a
B₁₀	98.47±1.39 a	18.77±0.81 a	19.18±0.67 bc	0.49±0.64 abc	13.55±0.05 a	4.38±0.81 a	0.57±0.02 b

处理 Treatment	磷脂脂肪酸PLFA/ （nmol·g^-1）	细菌 Bacteria/ （nmol·g^-1）	真菌 Fungus/ （nmol·g^-1）	放线菌 Actinmyces/（nmol·g^-1）	革兰氏阴性菌 G^-/ （nmol·g^-1）	革兰氏阳性菌G⁺/ （nmol·g^-1）	原生动物 Protozoon/（nmol·g^-1）
CK	99.66±1.65 a	15.05±0.48 c	21.79±0.31 a	0.18±0.05 a	11.67±0.05 b	2.98±0.26 c	0.29±0.02 d
A₅	99.05±2.49 a	17.02±0.64 b	17.60±0.78 c	0.75±0.01 b	9.91±0.17 c	6.48±0.08 b	0.36±0.01 c
A₁₀	98.13±2.67 a	18.63±0.74 a	18.83±0.9 b	0.31±0.04 c	11.81±0.36 b	5.86±0.39 b	0.22±0.06 d
B₅	99.10±2.82 a	19.17±0.95 a	19.37±0.49 abc	0.49±0.61 abc	12.40±0.88 ab	5.83±0.67 abc	1.07±0.01 a
B₁₀	98.47±1.39 a	18.77±0.81 a	19.18±0.67 bc	0.49±0.64 abc	13.55±0.05 a	4.38±0.81 a	0.57±0.02 b

[1]	GAO Lin1, WANG Xinwei1, SHEN Guoming1, TIAN Feng2, CHEN Qianfeng2, ZHANG Mingfa2, ZHANG Chengsheng1*. Differences of Bacteria and Fungi Community Structure in Tobacco-planting Soil of Different Continuous Cropping Years [J]. Journal of Agricultural Science and Technology, 2019, 21(8): 147-152.
[2]	CHEN Qinghua1, XU Zhuo1, TANG Jichao1,2, JIN Weibin2, SUN Zhigui1, LU Bilin1*. Influences of Adding Biochar on Loss of Nitrogen and Phosphorus and Yield of Rape in Soil [J]. Journal of Agricultural Science and Technology, 2019, 21(11): 130-137.
[3]	LIU Yue1, MENG Hai-bo1*, SHEN Yu-jun1, CHENG Hong-sheng1, HOU Yue-qing1, LIU Hon. Studies on Resource Distribution and Gross Control of Animal and Poultry Manure in Hainan Province [J]. , 2015, 17(4): 114-121.
[4]	ZHANG Ming\\|yan1, ZHANG Ji\\|guang1*, SHEN Guo\\|ming1, ZHANG Zhong\\|feng1, CAI Xi. Present Research Status and Prospects of Microbial Communities Structure and Functional Microorganisms in Tobacco\\|Planting Soil [J]. , 2014, 16(5): 115-122.
[5]	MENG Yao1, GU Wan\\|rong2, LI Jing2, WEI Shi2*, YANG De\\|guang2. Effect of Bt Transgenic Corn Straw Fermentation on SFC\\|2 Microbial Community [J]. , 2014, 16(4): 87-94.
[6]	SUN Chuan-fan . Research Progress on Microalgae Rehabilitation of Water Environment [J]. , 2011, 13(3): 92-96.
[7]	LI Xin-xin1, LI Xiao-hui1, LI Liang1, PING Shu-zhen1, CHEN Ming1, ZHANG Wei1, . Impacts of Transgenic Crops on Soil Microbes [J]. , 2010, 12(6): 24-27.
[8]	LIU Xiao-ning, HU Zheng-yi, ZHU Chun-you, WANG Jin-zhi, SHI Yi-chao, HUANG Li-ju. Studies on Technology for Controlling Pollutants from Decentralized Duck Breeding at Islet of Baiyangdian [J]. , 1, 1(1): 132-137.