Isolation and Characterization of Three Bacterial Strains Capable of Phosphate-solubilizing from Soil

doi:10.13560/j.cnki.biotech.bull.1985.2016-0915

Abstract

Abstract: This work is to isolate and identify the phosphate-solubilizing microorganisms and develop microbial complex agents targeting for solving the problems of agricultural non-point source pollution. The organic phosphorus pesticide “chlorpyrifos”,“trichlorfon” and insoluble inorganic phosphorus Ca₃（PO₄）₂ were used as phosphorus source to screen and identify the phosphate-solubilizing microbe from soil,as well as analyze their phosphate-solubilizing capacity. The result showed that three phosphate-solubilizing bacterial strains（W,Y and B）were isolated from the soil. All three strains were gram-negative strains. The degradation results of organophosphorus pesticides showed that strain W had the strongest degradation rate of trichlorfon with 17.39%,and strain B had the strongest degradation rate of chlorpyrifos with 23.06%. All three strains solubilized significantly solid insoluble phosphate,and the B strain had the highest phosphorus-solubilizing capacity of 96.31 mg/L. The solubilizing phosphate results of single strain and compound strains showed that the effect of compound strains was significantly better than single strain. When W,Y,and B strains mixed with EM,the phosphorus-solubilizing capacity rose to 119.46 mg/L,and the phosphorus-solubilizing capacity in paddy fields and greenhouse soil was improved to 18.38 mg/L and 14.08 mg/L,respectively. In conclusion,three strains isolated from soil have the abilities of degrading organic phosphorus pesticide and solubilizing inorganic phosphorus Ca₃（PO₄）₂. The compound strains significantly improved the phosphorus-solubilizing capacity of soil significantly.

Key words: organophosphorus pesticides, inorganic phosphorus, compound microbial, phosphate-solubilizing bacteria

LI Bai LI Jun SHEN Ya-qiang. Isolation and Characterization of Three Bacterial Strains Capable of Phosphate-solubilizing from Soil[J]. Biotechnology Bulletin, 2017, 33(5): 203-209.

References

[1] 董秀金. 区域农业环境与蔬菜质量安全风险评价[D]. 杭州：浙江大学, 2011.
[2] 孙元设. 微囊藻毒素与原发性肝癌的关系研究[D]. 福州：福建医科大学, 2011.
[3] 熊彩珍, 顾立明. 中秋蚕发生大面积农药中毒的思考[J]. 中国蚕业, 2007, 28（2）：54-55.
[4] 杨林章, 施卫明, 薛利红, 等. 农村面源污染治理的“4R”理论与工程实践——总体思路与“4R”治理技术[J]. 农业环境科学学报, 2013（1）：1-8.
[5] 李白, 李军. 微生物技术在防治农业面源水污染中的研究[J]. 生物技术通报, 2015（10）：99-104.
[6] 于涛, 叶鑫, 张海楼. 保护地蔬菜重金属污染微生物修复的研究[J]. 安徽农业科学, 2013, 41（3）：1065-1066.
[7] 刘春法, 丁学峰, 丁哲利, 等. EM菌联合陆生植物对尾水的净化效应[J]. 中国给水排水, 2013, 29（18）：130-133.
[8] 万田英, 尹亚琳, 华玉妹, 等. 光合细菌投加量对湖泊污染修复的作用效应[J]. 环境工程, 2014（8）：29-32.
[9] 张扬, 王飞, 黄彦, 等. 罗尔斯顿菌（Ralstonia sp. ）T6对三氯吡啶醇污染土壤的修复及能完全矿化毒死蜱工程菌株的构建[J]. 生态与农村环境学报, 2014（6）：761-767.
[10] 张闻, 陈贯虹, 高永超, 等. 石油和重金属污染土壤的微生物修复研究进展[J]. 环境科学与技术, 2012（S2）：174-181.
[11] 段秀梅, 高晓蓉, 吕军, 等. 两株土壤分离菌的解磷能力及对玉米的促生作用[J]. 中国土壤与肥料, 2010（2）：79-85.
[12] 张瑞福, 颜春荣, 张楠, 等. 微生物肥料研究及其在耕地质量提升中的应用前景[J]. 中国农业科技导报, 2013, 15（5）：8-16.
[13] 周正义, 印天寿, 唐玉华. 催化光度法测定痕量敌百虫[J]. 分析化学, 1996（10）：1190-1192.
[14] 段海明, 王开运, 王冕, 等. 蜡状芽孢杆菌HY-1降解甲基对硫磷和毒死蜱的影响因素研究[J]. 农业环境科学学报, 2010（3）：437-443.
[15] 陈贵, 张红梅, 沈亚强, 等. 绿肥和小麦秸秆与化肥配施对水稻生长和青紫泥土壤肥力的影响[J]. 浙江农业学报, 2015, 27（10）：1797-1801.
[16] 李金钟, 李中华, 刘利平. 罗尔斯顿菌属和亲铜菌属的研究进展[J]. 国际检验医学杂志, 2008（5）：437-439.
[17] 冷守琴, 魏芳, 张丽丽, 等. 一株氯苯降解新菌株的分离鉴定及其降解特性研究[J]. 环境科学与技术, 2011（2）：6-11.
[18] Ryan MP, Pembroke JT, Adley CC. Ralstonia pickettii in environmental biotechnology：potential and applications[J]. J Appl Microbiol, 2007, 103（4）：754-764.
[19] Qin YM, Tao H, Liu YY, et al. A novel non-hydrolytic protein from Pseudomonas oryzihabitans enhances the enzymatic hydrolysis of cellulose[J]. J Biotechnol, 2013, 168（1）：24-31.
[20] Khayi S, Raoul DEY, Mondy S, et al. Draft Genome Sequences of the Three Pectobacterium-Antagonistic Bacteria Pseudomonas brassicacearum PP1-210F and PA1G7 and Bacillus simplex BA2H3[J]. Genome Announc, 2015, 3（1）：e01497-14.
[21] Novinscak A, Gadkar VJ, Joly DL, et al. Complete Genome Sequence of Pseudomonas brassicacearum LBUM300, a Disease-Suppressive Bacterium with Antagonistic Activity toward Fungal, Oomycete, and Bacterial Plant Pathogens[J]. Genome Announc, 2016, 4（1）：e01623-15.
[22] Zhou T, Chen D, Li C, et al. Isolation and characterization of Pseudomonas brassicacearum J12 as an antagonist against Ralstonia solanacearum and identification of its antimicrobial components[J]. Microbiol Res, 2012, 167（7）：388-394.
[23] 李振东, 陈秀蓉, 杨成德, 等. 乳白香青内生解磷菌的筛选鉴定及解磷特性研究[J]. 草业学报, 2013, 22（6）：150-158.
[24] Thomas GV, Shantaram MV, Saraswathy N. Occurrence and activity of phosphate-solubilizing fungi from coconut plantation soils[J]. Plant and Soil, 1985, 87（3）：357-364.
[25] Asea PEA, Kucey RMN, Stewart JWB. Inorganic phosphate solubilization by two Penicillium species in solution culture and soil[J]. Soil Biology & Biochemistry, 1988, 20（4）：459-464.
[26] Paul NB, Rao WVBS. Phosphate-dissolving bacteria in the rhizosphere of some cultivated legumes[J]. Plant and Soil, 1971, 35（1-3）：127-132.
[27] 王继雯, 谢宝恩, 甄静, 等. 一株无机磷细菌的分离、鉴定及其溶磷能力分析[J]. 河南科学, 2011（3）：293-296.
[28] 荆世杰. 微波、臭氧和EM菌处理对温室土壤健康和甜瓜生产的影响[D]. 兰州：甘肃农业大学, 2007.
[29] 侯佳奇, 李鸣晓, 贾璇, 等. 复合菌剂解无机磷条件优化研究[J]. 农业环境科学学报, 2013（2）：385-392.