Effects of Microbial Agents on Physicochemical Properties and Microbial Flora of Rhizosphere Saline-alkali Soil

doi:10.16258/j.cnki.1674-5906.2022.10.006

Ecology and Environment ›› 2022, Vol. 31 ›› Issue (10): 1984-1992.DOI: 10.16258/j.cnki.1674-5906.2022.10.006

• Research Articles • Previous Articles Next Articles

Effects of Microbial Agents on Physicochemical Properties and Microbial Flora of Rhizosphere Saline-alkali Soil

ZHANG Xiaoli¹^,²(), WANG Guoli¹, CHANG Fangdi¹, ZHANG Hongyuan¹, PANG Huancheng¹, ZHANG Jianli³, WANG Jing¹, JI Hongjie¹, LI Yuyi¹^,^*()

1. Institute of Agricultural Resources and Regional Planning, Chinese Academy of Agricultural Sciences, Beijing 100081, P. R. China
2. Deartment of Ecology and Resources Engineering, Hetao College, Bayannur 015000, P. R. China
3. School of Life Science, Beijing Institute of Technology, Beijing 100081, P. R. China

Received:2021-02-24 Online:2022-10-18 Published:2022-12-09
Contact: LI Yuyi

生物菌剂对根际盐碱土壤理化性质和微生物区系的影响

张晓丽¹^,²(), 王国丽¹, 常芳弟¹, 张宏媛¹, 逄焕成¹, 张建丽³, 王婧¹, 冀宏杰¹, 李玉义¹^,^*()

1.中国农业科学院农业资源与农业区划研究所，北京 100081
2.河套学院生态与资源工程系，内蒙古巴彦淖尔 015000
3.北京理工大学生命学院，北京 100081

通讯作者: 李玉义
作者简介:张晓丽（1993年生），助教，硕士，从事盐碱地改良利用研究。E-mail: 1695952120@qq.com
基金资助:
国家自然科学基金项目(31871584);中国农业科学院科技创新工程(CAAS-ZDRW202201);鄂尔多斯市“揭榜挂帅”项目(JBGS-2021-001);“科技兴蒙”行动重点专项(2021EEDSCXSFQZD011);内蒙古自治区盐碱化耕地改良试点项目

Abstract

Abstract:

Clarifying the role of microbial agents in the improvement of moderately saline-alkali soil in the Hetao area of Inner Mongolia, can provide technical support for improving the quality of saline-alkali soil. In this study, adopting the field randomized block test design method, with the blank treatment (CK) as the control, three kinds of microbial inoculum treatments were set up, including the Danlu brand microbial inoculum (DL), and two doses of self-developed composite microbial inoculum BZ1^T/1-15 (it was composed of Bacillus, bacillus and peat). The dosage of two self-developed composite microbial inoculants BZ1T/1-15 were 570 kg·hm^-2 (BL1) and 1140 kg·hm^-2 (BL2) respectively. The change characteristics of saline-alkali soil salt, nutrients, and bacterial community structure and diversity under different treatment measures were analyzed. The results showed that the application of microbial agents (DL, BL) can significantly reduce soil salinity and pH. BL2 treatment had the most significant effects on reducing soil salinity, which reduced 14.03%, 4.21% and 7.36% compared with CK, DL and BL1 respectively (P<0.05). At the same time, the application of BL1 and BL2 microbial agents had a significant effect on increasing the content of alkali hydrolyzable nitrogen, available potassium and available phosphorus in the saline-alkail soil. Compared with CK and DL, the alkali hydrolyzable nitrogen content of BL1 and BL2 treatments were significantly increased by 26.42% and 11.67%, 50.94% and 33.33%. Compared with CK, DL and BL1, the available potassium content of BL2 treatment was significantly increased by 24.09%, 24.69% and 11.11% (P<0.05). High-throughput sequencing results showed that the richness index (ACE, Chao1) of BL2 treatment was significantly higher than other treatments (P<0.05). BL2 treatment significantly increased the abundance of the dominant flora of Actinobacteria, Firmicutes and Cyanobacteria. In addition, BL1 and BL2 treatment reduced the acid bacteria, Bacillus, Bacteroidetes, Nitrospirae and Floating bacteria. Correlation analysis results showed that Actinomycetes were significantly negatively correlated with soil pH (r= -0.581*) and positively correlated with alkaline hydrolyzed nitrogen (r=0.595*). Soil available potassium was negatively correlated, positively correlated and positively correlated with Proteus, Acidobacter and Campylobacter, respectively (r= -0.753**, 0.503* and 0.569*).The results of factor analysis showed that organic matter, salt and nutrient were the main environmental factors affecting the soil bacterial community, which explained a total of 67.0% of the community changes. The rank of the contribution rate was as follows: soil organic matter>salt>available potassium>pH>available Phosphorus>alkaline nitrogen. In addition, the application of BL1 and BL2 bacteria significantly increased sunflower yield. There was a significant positive correlation between crop yield and nutrient content. Therefore, the application of microbial inoculants cannot only reduce soil salinity and pH, but also significantly increase soil nutrient content and crop yields, and improve the structure of bacterial flora. This study could provide a test basis for microbial agents to improve saline-alkali soil in Hetao Irrigation District in Inner Mongolia.

Key words: saline-alkali soil, microbial agents, salinity, soil nutrients, high-throughput sequencing, Microflora

摘要：

为明确微生物菌剂在内蒙古河套地区中度盐碱土壤改良中的作用，可为盐碱土壤质量提升提供技术支撑。采用大田随机区组试验设计方法，以空白处理（CK）为对照，设置3种微生物菌剂处理，包括丹路牌微生物菌剂（DL）、自主研发的复合微生物菌剂BZ1^T/1-15（由芽孢杆菌、芽单胞菌和草炭组成），其使用量分别为570 kg·hm^-2（BL1）和1140 kg·hm^-2（BL2）。分析不同处理措施下的土壤盐分、养分以及细菌群落结构组成和多样性的变化特征。结果表明：施用微生物菌剂（DL、BL）均可显著降低土壤盐分和pH值，其中BL2处理对降低土壤盐分的效果最显著，与CK、DL、BL1相比分别降低了14.0%、4.2%、7.4%（P<0.05）。同时，施用BL1和BL2微生物菌剂对提高根际土壤的碱解氮、速效钾和有效磷含量有显著作用，其中BL1、BL2处理的碱解氮含量较CK和DL分别显著提高26.4%和11.67%、50.94%和33.33%，BL2处理的速效钾含量较CK、DL和BL1分别显著提高24.1%、24.7%和11.1%（P<0.05）。高通量测序结果表明，BL2处理的丰富度指数（ACE、Chao1）显著高于其他处理，还可显著提升放线菌门、厚壁菌门和蓝细菌门的优势菌群丰度，另外BL1和BL2处理显著降低了酸杆菌门、芽单胞菌门、拟杆菌门、硝化螺旋菌门和浮霉菌门细菌菌群的相对丰度（P<0.05）。相关性分析结果显示，放线菌门与土壤pH值、碱解氮分别呈显著负相关、正相关（r分别为-0.581*、0.595*）；土壤速效钾与变形菌门、酸杆菌门和绿弯菌门分别呈极显著负相关、正相关和正相关（r分别为-0.753**、0.503*和0.569*）。因子分析结果表明，有机质、盐分和养分等是影响土壤细菌群落结构的主控环境因子，因为其总共解释了67.0%的群落变化；它们的贡献率依次为：土壤有机质>盐分>速效钾>pH>有效磷>碱解氮。另外，BL1和BL2菌剂的施用对提高向日葵的产量有显著作用，且作物产量与养分含量呈极显著正相关关系。因此，施用微生物菌剂不仅可以降低土壤盐分和pH值，而且还可显著提高土壤养分含量和作物产量，改善细菌菌群结构。该研究可以为微生物菌剂在内蒙古河套灌区盐碱土壤改良方面提供试验基础和参考。

关键词: 盐碱土, 微生物菌剂, 盐分, 土壤养分, 高通量测序, 微生物区系

CLC Number:

ZHANG Xiaoli, WANG Guoli, CHANG Fangdi, ZHANG Hongyuan, PANG Huancheng, ZHANG Jianli, WANG Jing, JI Hongjie, LI Yuyi. Effects of Microbial Agents on Physicochemical Properties and Microbial Flora of Rhizosphere Saline-alkali Soil[J]. Ecology and Environment, 2022, 31(10): 1984-1992.

张晓丽, 王国丽, 常芳弟, 张宏媛, 逄焕成, 张建丽, 王婧, 冀宏杰, 李玉义. 生物菌剂对根际盐碱土壤理化性质和微生物区系的影响[J]. 生态环境学报, 2022, 31(10): 1984-1992.

Figures/Tables 7

References 37

[1]	BARTER-LENNARD E G, 2002. Restoration of saline land though revegetation[J]. Agricultural Water Management, 53(1-3): 213-226. DOI URL
[2]	BOKULICH N A, SUBRAMANIAN S, FAITH J J, et al., 2012. Quality-filtering vastly improves diversity estimates from Illumina amplicon sequencing[J]. Nature Methods, 10(1): 57-59. DOI URL
[3]	GRIFFIYHS B S, PHILIPPOT L, 2013. Nsights into the resistance and resilience of the soil microbial community[J]. FEMS Microbiology Reviews, 37(2): 112-129. DOI URL
[4]	QADIR M, GHAFOOR A, MURTAZA G, et al., 2000. Amelioration strategies for saline soils: A review[J]. Land Degradation and Development, 11(6): 501-521. DOI URL
[5]	QUAST C, PRUESSE E, YILMAZ P, et al., 2013. The SILVA ribosomal RNA gene database project: improved data processing and web-based tools[J]. Nucleic Acids Research, 41(D1): D590-D596. DOI URL
[6]	SAIT M, DAVIS K E R, JANSSEN P H, 2006. Effect of pH on isolation and distribution of members of subdivision 1 of the phylum Acidobacteria occurring insoil[J]. Applied and Environmental Microbiology, 72(3): 1852-1857. DOI URL
[7]	SCHLOSS P D, WESTCOTT S L, RYABIN T, et al., 2009. Introducing mothur: Open-source, platform-independent, community-supported software for describing and comparing microbial communities[J]. Applied and Environmental Microbiology, 75(23): 7537-7541. DOI PMID
[8]	STAFF P O, 2014. Correction: Salinity and bacterial diversity: To what extent does the concentration of salt affect the bacterial community in a saline soil[J]. Plos One, 9(9): e114658. DOI URL
[9]	ZHANG H Y, LU C, PANG H C, et al., 2020. Straw layer burial to alleviate salt stress in silty loam soils: Impacts of straw forms[J]. Journal of Integrative Agriculture, 19(1): 265-276. DOI URL
[10]	ZHENG W, XIE D M, LI X Z, et al., 2017. The responses and adaptations of microbial communities to salinity in farmland soils: A molecular ecological network analysis[J]. Applied Soil Ecology, 120: 239-246. DOI URL
[11]	鲍士旦, 2005. 土壤农化分析[M]. 3版. 北京: 中国农业出版社.
	BAO S D, 2005. Soil Agrochemical Analysis[M]. 3rd edition. Beijing: China Agriculture press.
[12]	邓松华, 梁富忠, 2018. 盐胁迫条件下微生物菌剂及助剂对土壤盐分及小白菜生长的影响[J]. 磷肥与复肥, 33(11): 37-38, 41.
	DENG S H, LIANG F Z, 2018. Effects of microbial agents and additives on soil salinity and growth of Chinese cabbage under salt stress[J]. Phosphate and Compound Fertilizer, 33(11): 37-38, 41.
[13]	邓天天, 周士波, 胡烨, 等, 2019. 添加微生物菌剂对土壤中氮磷形态及含量的影响[J]. 江苏农业科学, 47(9): 276-280.
	DENG T T, ZHOU S B, HU Y, et al., 2019. The effect of adding microbial agents on the form and content of nitrogen and phosphorus in soil[J]. Jiangsu Agricultural Sciences, 47(9): 276-280.
[14]	高圣超, 关大伟, 马鸣超, 等, 2017. 大豆连作条件下施肥对东北黑土细菌群落的影响[J]. 中国农业科学, 50(7): 1271-1281.
	GAO S C, GUAN D W, MA M C, et al., 2017. The effect of fertilization on the bacterial community in black soil of northeast under the condition of soybean continuous cropping[J]. China Agricultural Sciences, 50(7): 1271-1281.
[15]	葛诚, 吴薇, 1994. 我国微生物肥料的生产、应用及问题[J]. 中国农学通报, 10(3): 24-28.
	GE C, WU W, 1994. Production, application and problems of microbial fertilizers in my country[J]. Chinese Agricultural Science Bulletin, 10(3): 24-28.
[16]	黄雅丽, 田琪, 秦光华, 等, 2018. 黄河三角洲刺槐白蜡混交对土壤细菌群落结构及多样性的影响[J]. 生态学报, 38(11): 3859-3867.
	HUANG Y L, TIAN Q, QIN G H, et al., 2018. Effects of the mixture of Robinia pseudoacacia and white wax on soil bacterial community structure and diversity in the Yellow River Delta[J]. Acta Ecologica Sinica, 38(11): 3859-3867.
[17]	李刚, 张乃明, 毛昆明, 等, 2004. 大棚土壤盐分累积特征与调控措施研究[J]. 农业工程学报, 20(3): 44-47.
	LI G, ZHANG N M, MAO K M, et al., 2004. Characteristics of soil salt accumulation in plastic greenhouse and its control measures[J]. Transactions of the CSAE, 20(3): 44-47.
[18]	李新, 焦燕, 代钢, 等, 2016. 内蒙古河套灌区不同盐碱程度的土壤细菌群落多样性[J]. 中国环境科学, 36(01): 249-260.
	LI X, JIAO Y, DAI G, et al., 2016. Diversity of soil bacterial communities with different salinity in Hetao Irrigation District, Inner Mongolia[J]. China Environmental Science, 36(1): 249-260.
[19]	李岩, 杨晓东, 秦璐, 等, 2018. 两种盐生植物根际土壤细菌多样性和群落结构[J]. 生态学报, 38(9): 3118-3131.
	LI Y, YANG X D, QIN L, et al., 2018. Bacterial diversity and community structure in the rhizosphere soil of two halophytes[J]. Acta Ecologica Sinica, 38(9): 3118-3131.
[20]	刘广明, 杨劲松, 吕真真, 等, 2011. 不同调控措施对轻中度盐碱土壤的改良增产效应[J]. 农业工程学报, 27(9): 164-169.
	LIU G M, YANG J S, LÜ Z Z, et al., 2011. The improvement and yield increase effects of different control measures on mild to moderate saline-alkali soil[J]. Transactions of the CSAE, 27(9): 164-169.
[21]	刘健, 李俊, 葛诚, 2001. 微生物肥料作用机理的研究新进展[J]. 微生物学杂志, 21(1): 33-36, 46.
	LIU J, LI J, GE C, 2001. New progress in the study of the mechanism of microbial fertilizers[J]. Journal of Microbiology, 21(1): 33-36, 46.
[22]	鲁奥, 2019. 盐碱地中纤维素降解菌的植物促生特性研究[D]. 长春: 东北师范大学.
	LU A, 2019. Study on the plant growth promotion characteristics of cellulose degrading bacteria in saline alkali land[D]. Changchun: Northeast Normal University.
[23]	马慧媛, 黄媛媛, 刘胜尧, 等, 2020. 微生物菌剂施用对设施茄子根际土壤养分和细菌群落多样性的影响[J]. 微生物学通报, 47(1): 140-150.
	MA H Y, HUANG Y Y, LIU S Y, et al., 2020. Effects of microbial inoculants on rhizosphere soil nutrients and bacterial community diversity in facility eggplant[J]. Bulletin of Microbiology, 47(1): 140-150.
[24]	逄焕成, 李玉义, 严慧峻, 等, 2009. 微生物菌剂对盐碱土理化和生物性状影响的研究[J]. 农业环境科学学报, 28(5): 951-955.
	PANG H C, LI Y Y, YAN H J, et al., 2009. Study on the influence of microbial agents on the physical and chemical and biological properties of saline-alkali soil[J]. Journal of Agro-Environment Science, 28(5): 951-955.
[25]	逄焕成, 李玉义, 于天一, 等, 2011. 不同盐胁迫条件下微生物菌剂对土壤盐分及苜蓿生长的影响[J]. 植物营养与肥料学报, 17(6): 1403-1408.
	PANG H C, LI Y Y, YU T Y, et al., 2011. Effects of microbial agents on soil salinity and alfalfa growth under different salt stress conditions[J]. Journal of plant Nutrition and Fertilizer, 17(6): 1403-1408.
[26]	宋以玲, 于建, 陈士更, 等, 2019. 复合微生物菌剂对棉花生理特性及根际土壤微生物和化学性质的影响[J]. 土壤, 51(3): 477-487.
	SONG Y L, YU J, CHEN S G, et al., 2019. Effects of compound microbial inoculants on cotton physiological characteristics and rhizosphere soil microbes and chemical properties[J]. Soil, 51(3): 477-487.
[27]	覃小红, 2013. 固氮巨大芽孢杆菌在桉树栽培上的应用初探[D]. 南宁: 广西大学.
	QIN X H, 2013. A preliminary study on the application of Bacillus megaterium nitrogen-fixing in eucalyptus cultivation[D]. Nanning: Guangxi University.
[28]	王劲松, 戴茨华, 徐红, 等, 2012. 红壤连续施用绿肥和有机肥对玉米产量及土壤肥力的影响[J]. 中国土壤与肥料 (5): 27-30.
	WANG J S, DAI C H, XU H, et al., 2012. Effects of continuous application of green manure and organic manure in red soil on corn yield and soil fertility[J]. China Soil and Fertilizer (5): 27-30.
[29]	王婧, 逄焕成, 李玉义, 等, 2012. 微生物菌肥对盐渍土壤微生物区系和食葵产量的影响[J]. 农业环境科学学报, 31(11): 2186-2191.
	WANG J, PANG H C, LI Y Y, et al., 2012. Effects of microbial fertilizer on saline soil microbial flora and sunflower yield[J]. Journal of Agro-Environment Science, 31(11): 2186-2191.
[30]	邢世和, 熊德中, 周碧青, 等, 2004. 不同土壤改良剂对土壤生化性质与烤烟产量的影响[J]. 土壤通报, 36(3): 72-75.
	XING S H, XIONG D Z, ZHOU B Q, et al., 2004. Effects of different soil amendments on soil biochemical properties and flue-cured tobacco yield[J]. Soil Bulletin, 36(3): 72-75.
[31]	严慧峻, 逄焕成, 李玉义, 等, 2008. 微生物复混肥对盐碱土及白菜品质改良的影响[J]. 中国农学通报, 24(12): 270-273.
	YAN H J, PANG H C, LI Y Y, et al., 2008. Effects of microbial compound fertilizer on the quality improvement of saline-alkali soil and cabbage[J]. Chinese Agricultural Science Bulletin, 24(12): 270-273.
[32]	易克, 张锦韬, 刘建峰, 等, 2019. 施用功能微生物菌剂对烤烟生长及烟叶产质量的影响[J]. 作物研究, 33(3): 215-219.
	YI K, ZHANG J T, LIU J F, et al., 2019. Effects of application of functional microbial agents on flue-cured tobacco growth and tobacco leaf yield and quality[J]. Crop Research, 33(3): 215-219.
[33]	于占东, 宋述尧, 2003. 稻草配施生物菌剂对大棚连作土壤的改良作用[J]. 农业工程学报, 19(1): 177-179.
	YU Z D, SONG S Y, 2003. The effect of rice straw combined with biological inoculants on soil improvement in greenhouse continuous cropping[J]. Transactions of the CSAE, 19(1): 177-179.
[34]	俞仁培, 陈德明, 1999. 我国盐渍土资源及其开发利用[J]. 土壤通报, 30(4): 158-159.
	YU R P, CHEN D M, 1999. My country’s saline soil resources and their development and utilization[J]. Chinese Journal of Soil Science, 30(4): 158-159.
[35]	张慧敏, 郭慧娟, 侯振安, 2018. 不同盐碱胁迫对土壤细菌群落结构的影响[J]. 新疆农业科学, 55(6): 1074-1084. DOI
	ZHANG H M, GUO H J, HOU Z A, 2018. Effects of different salt-alkali stress on soil bacterial community structure[J]. Xinjiang Agricultural Sciences, 55(6): 1074-1084.
[36]	张金柱, 张兴, 郭春景, 等, 2007. 生物有机肥对轻度盐碱土理化性质影响的研究[J]. 生物技术, 17(6): 73-75.
	ZHANG J Z, ZHANG X, GUO C J, et al., 2007. Research on the effect of bio-organic fertilizer on the physical and chemical properties of mild saline-alkaline soil[J]. Biotechnology, 17(6): 73-75.
[37]	赵柏霞, 潘凤荣, 王薇, 等, 2018. 生物菌剂对樱桃的促生效应及根际细菌群落的影响[J]. 沈阳农业大学学报, 49(3): 286-292.
	ZHAO B X, PAN F R, WANG W, et al., 2018. The growth-promoting effect of cherries and the effect of rhizosphere bacterial community of biological inoculants[J]. Journal of Shenyang Agricultural University, 49(3): 286-292.

处理 Treatments	w_{(全盐 Salt)}/ (g·kg^-1)	pH	w_{(有机质Organic Matter)}/ (g·kg^-1)	w_{(碱解氮Available-N)}/ (mg·kg^-1)	w_{(有效磷Available-P)}/ (mg·kg^-1)	w_{(速效钾Available-K)}/ (mg·kg^-1)
CK	2.89±0.01a	8.90±0.15a	11.8±0.73a	28±0.33d	12.3±0.24c	238±6.96b
DL	2.60±0.01b	8.70±0.08b	10.9±0.70a	34±0.58c	13.5±0.15b	235±5.49b
BL1	2.62±0.02b	8.76±0.29b	12.2±0.32a	37±0.33b	13.2±0.18b	279±7.64a
BL2	2.49±0.01c	8.69±0.22b	12.1±0.61a	42±0.33a	14.4±0.13a	294±4.84a

处理 Treatments	w_{(全盐 Salt)}/ (g·kg^-1)	pH	w_{(有机质Organic Matter)}/ (g·kg^-1)	w_{(碱解氮Available-N)}/ (mg·kg^-1)	w_{(有效磷Available-P)}/ (mg·kg^-1)	w_{(速效钾Available-K)}/ (mg·kg^-1)
CK	2.89±0.01a	8.90±0.15a	11.8±0.73a	28±0.33d	12.3±0.24c	238±6.96b
DL	2.60±0.01b	8.70±0.08b	10.9±0.70a	34±0.58c	13.5±0.15b	235±5.49b
BL1	2.62±0.02b	8.76±0.29b	12.2±0.32a	37±0.33b	13.2±0.18b	279±7.64a
BL2	2.49±0.01c	8.69±0.22b	12.1±0.61a	42±0.33a	14.4±0.13a	294±4.84a

样品名称 Sample name	序列 Reads	OUT数目 OUT amount	香农指数 Shannon index	辛普森指数 Simpson index	ACE指数 ACE index	Chao 1指数 Chao 1 index	覆盖率 Coverage
CK	22420	1963±2.86c	6.39±0.01a	0.0040±0.0004a	1832±18a	1847±24a	0.9886±0.0002a
DL	22420	2037±4.53b	6.44±0.01a	0.0031±0.0001a	1848±14a	1857±17a	0.9881±0.0001a
BL1	22420	2067±1.55a	6.42±0.02a	0.0032±0.0000a	1829±19a	1847±7a	0.9903±0.0006a
BL2	22420	2076±1.61a	6.38±0.03a	0.0037±0.0002a	1799±21b	1828±31b	0.9880±0.0017a

样品名称 Sample name	序列 Reads	OUT数目 OUT amount	香农指数 Shannon index	辛普森指数 Simpson index	ACE指数 ACE index	Chao 1指数 Chao 1 index	覆盖率 Coverage
CK	22420	1963±2.86c	6.39±0.01a	0.0040±0.0004a	1832±18a	1847±24a	0.9886±0.0002a
DL	22420	2037±4.53b	6.44±0.01a	0.0031±0.0001a	1848±14a	1857±17a	0.9881±0.0001a
BL1	22420	2067±1.55a	6.42±0.02a	0.0032±0.0000a	1829±19a	1847±7a	0.9903±0.0006a
BL2	22420	2076±1.61a	6.38±0.03a	0.0037±0.0002a	1799±21b	1828±31b	0.9880±0.0017a

微生物类群	盐分 Salt content	pH	有机质 Organic Matter	碱解氮 Available-N	有效磷 Available-P	速效钾 Available-K
变形菌门 Proteobacteria	0.078	0.108	-0.824**	-0.434	-0.300	-0.753**
放线菌门 Actinobacteria	-0.283	-0.581^*	0.058	0.595^*	0.192	0.002
酸杆菌门 Acidobacteria	0.010	0.376	0.443	-0.470	0.187	0.503*
绿弯菌门 Chloroflexi	-0.068	-0.299	0.689**	0.151	0.270	0.569*
芽单胞菌门 Gemmatimonadetes	-0.055	0.283	0.055	-0.403	-0.041	0.113
拟杆菌门 Bacteroidetes	0.547*	0.317	-0.304	-0.556*	-0.569*	-0.442
硝化螺旋菌门 NitrosPirae	-0.430	-0.101	-0.549*	-0.246	0.034	-0.216
浮霉菌门 Planctomycetes	0.159	0.618^*	0.245	-0.494	-0.003	0.291
厚壁菌门 Firmicutes	0.263	-0.037	0.081	0.401	0.012	0.024
蓝细菌门 Cyanobacteria	0.288	-0.158	0.040	0.504*	-0.151	-0.048
螺旋体菌门 Saccharibacteria	-0.112	-0.239	0.623*	0.445	0.324	0.379

Effects of Microbial Agents on Physicochemical Properties and Microbial Flora of Rhizosphere Saline-alkali Soil

生物菌剂对根际盐碱土壤理化性质和微生物区系的影响

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处理 Treatments	花盘数 Number of faceplates/ (a·hm^-2)	植株干物质量 Plant dry mass/ (kg·hm^-2)	籽粒产量 Yield/ (kg·hm^-2)
CK	23813±364a	538±46c	1948±23b
DL	18574±744b	976±103c	2129±9b
BL1	15716±1883bc	1845±110b	2560±45a
BL2	12859±1091c	2460±40a	2724±102a

项目 Project	产量 Yield	盐分 Salt content	pH	有机质 Organic matter	碱解氮Available-N	速效钾 Available-K	有效磷Available-P
盐分 Salt content	-0.112	1
pH	-0.236	0.301	1
有机质 Organic Matter	0.623*	-0.080	-0.145	1
碱解氮 Available-N	0.906**	-0.816**	-0.281	0.482	1
速效钾 Available-K	0.854**	-0.631*	-0.239	0.724**	0.878**	1
有效磷 Available-P	0.624*	-0.894**	-0.184	0.367	0.956**	0.835**	1

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