一株耐铬真菌的分离鉴定及基于抗氧化酶的耐铬机制研究

doi:10.19677/j.issn.1004-7964.2022.04.002

皮革科学与工程 ›› 2022, Vol. 32 ›› Issue (4): 8-13.doi: 10.19677/j.issn.1004-7964.2022.04.002

一株耐铬真菌的分离鉴定及基于抗氧化酶的耐铬机制研究

朱超¹, 马靓琛¹, 王曼婷¹, 马宏瑞¹, 赵澜博²

1.陕西科技大学,陕西西安 710021;
2.西北工业大学,陕西西安 710072

收稿日期:2022-01-12 出版日期:2022-08-28 上线日期:2022-07-11
作者简介:朱超,副教授,博士,主要从事环境微生物及污染治理方面研究。
基金资助:
国家自然科学基金（22076113）

Isolation and Identification of a Chromium-Tolerant Fungus and its Chromium-Tolerant Mechanism Based on Antioxidant Enzymes Response

ZHU Chao¹, MA Jingchen¹, WANG Manting¹, MA Hongrui¹, ZHAO Lanbo²

1. Shaanxi University of Science & Technology, Xi'an 710021, China;
2. Northwestern Polytechnical University, Xi'an 710072, China

Received:2022-01-12 Online:2022-08-28 Published:2022-07-11

摘要/Abstract

摘要： 从实验室被真菌污染的100 mg/L的1∶1 Cr-EDTA中分离得到一株真菌,经形貌和分子生物学鉴定,该菌株为霜霉菌菌属,最佳生长条件为培养温度为30 ℃、培养pH为6或7。铬胁迫实验表明该分离株最高可耐受质量浓度为1000 mg/L的六价铬。通过测定该菌株在不同铬浓度下的总抗氧化酶（Total antioxidant enzymes,T-AOC）,总超氧化物歧化酶（Total Superoxide Dismutas,T-SOD）和过氧化氢酶（catalase,CAT）活性,研究铬胁迫下该菌株抗氧化酶系的响应路径,以及不同抗氧化酶活性响应的相关性,拟从抗氧化酶系的角度阐明分离株的耐铬机理。结果表明：在Cr胁迫下,T-SOD、T-AOC、CAT活性均呈现增长趋势,其中T-SOD活性增速最快,在Cr质量浓度为155 mg/L时可达到空白对照组的4倍,CAT为对照组的3.8倍,T-AOC是空白对照组的2倍,说明抗氧化酶系活性对于Cr⁶⁺胁迫的响应顺序依次为T-SOD、CAT和T-AOC,且T-AOC活性与T-SOD活性、T-AOC活性与过CAT活性、T-SOD活性与CAT活性分别呈线性正相关。

关键词: 耐铬真菌, 分离鉴定, 抗氧化酶, 铬鞣废水, 六价铬

Abstract: A strain of fungus was isolated from 100 mg/L 1∶1 Cr-EDTA solution contaminated by fungi in the laboratory. Results of identification by morphology and molecular biology show that the strain belongs to the genus downy mildew. Its optimal growth conditions are culture temperature of 30 ℃ and pH of 6 or 7. Chromium stress test confirmed that the strain could tolerate the hexavalent chromium with the maximum concentration of 1000 mg/L. By measuring the activities of total antioxidant enzymes (T-AOC), total superoxide dismutase (T-SOD) and catalase (CAT) of the strain under different concentrations of chromium, we investigated the response path of antioxidant enzyme system of the strain and the correlation of different antioxidant enzyme activity response under chromium stress, in order to clarify the chromium resistance mechanism of the strain from the perspective of antioxidant enzyme system. Results show that, under Cr stress, all the activities of T-SOD, T-AOC and CAT showed an increasing trend, among which the activity of T-SOD increased the fastest. When the Cr concentration was 155 mg/L, the activity of T-SOD was 4 times of that of the blank control group, and the activity of CAT was 3.8 times of that of the control group, while the activity of T-AOC was 2 times of that of the control group. These results indicate that the response sequence of antioxidant enzyme activities in the strain to Cr⁶⁺ stress is T-SOD>CAT>T-AOC, and there is a positive linear correlation between T-AOC and T-SOD activities, T-AOC and over-CAT activities, and T-SOD and CAT activities, respectively.

Key words: chromium-tolerant fungus, isolation and identification, antioxidant enzyme, chrome tanning wastewater, hexavalent chromium

中图分类号:

X794

朱超, 马靓琛, 王曼婷, 马宏瑞, 赵澜博. 一株耐铬真菌的分离鉴定及基于抗氧化酶的耐铬机制研究[J]. 皮革科学与工程, 2022, 32(4): 8-13.

ZHU Chao, MA Jingchen, WANG Manting, MA Hongrui, ZHAO Lanbo. Isolation and Identification of a Chromium-Tolerant Fungus and its Chromium-Tolerant Mechanism Based on Antioxidant Enzymes Response[J]. Leather Science and Engineering, 2022, 32(4): 8-13.

参考文献

[1] 马宏瑞,王慧,朱超,等.水解酶及硝化菌剂强化处理制革废水的研究[J].皮革科学与工程,2019,29(4):5-9.
[2] 圣夕云,陈泽睿,廖学品.以废铬屑为模板制备碳纳米纤维束锂离子电池负极材料[J].皮革科学与工程,2017,27(2):16-21.
[3] Shanker A K,Cervantes C,Loza-Tavera H,et al.Chromium toxicity in plants[J].Environment international,2005,31(5):739-753.
[4] 马莉,张新申.制革工业综合废水生物处理的研究进展[J].皮革科学与工程,2006,16(2):65-71.
[5] Ramana S,Biswas A K,Singh A B,et al.Potential of rose for phytostabilization of chromium contaminated soils[J].Indian Journal of Plant Physiology,2013,18(18):381-383.
[6] Singh H P,Mahajan P,Kaur S,et al.Chromium toxicity and tolerance in plants[J].Environmental Chemistry Letters,2013,11(3):229-254.
[7] 顾家熙,马宏瑞,李晓洁,等.制革生化尾水Fenton法处理对铬存在形态的影响[J].中国皮革,2019,48(1):53-58.
[8] 孙艳涛,刘适博,李婷婷,等.水中铬处理方法的研究进展[J].当代化工,2015,44(6):1368-1370.
[9] 黄水娥,杨海君,关向杰,等.制革工业中去Cr³+高效菌的筛选及其鉴定[J].中国皮革,2013,11:1-4.
[10] 于洪飞,刘森.一株抗镉真菌的鉴定及其抗性的初步研究[J],生物学杂志,2018,35(3):43-46.
[11] 吴思颖. 异化铁还原菌强化零价铁修复地下水中Cr(Ⅵ)污染的研究[D].绍兴文理学院,2020.
[12] 高小朋,张欠欠,许平,等.微生物还原Cr(VI)的研究进展[J].微生物学通报,2008,35(5):820-824.
[13] 梅丽娟,殷仕学,朴哲,等.一种耐Cr(Ⅵ)微生物筛选新方法[J].环境科学与技术,2019,42(5):41-45.
[14] 白群华,肖虹.具六价铬高度耐受和祛除能力菌株的分离[J].预防医学情报杂志,2007,23(4):416-418.
[15] Sriharsha D V,Lokesh Kumar R,Janakiraman S.Absorption and Reduction of Chromium by Fungi[J].Bulletin Environmental Contamination and Toxicology,2020,105(4):645-649.
[16] 王瑜谦. 制革工业含铬污泥耐铬菌株的分离及对污泥处置研究[D].郑州:河南师范大学,2018.
[17] 何难,徐恒.溶磷菌对铅胁迫下杏鲍菇氧化应激反应的影响[J].生物技术通报,2016,32(5):187-193.
[18] 王岩,代群威,陈国华,等.藻类吸附剂对六价铬的吸附特性[J].环境工程学报,2014,8(5):1769-1774.
[19] 葸玉琴,赖金霞,张明旭,等.Cr³⁺和Cd²⁺对普通小球藻生长及抗氧化酶活性的影响[J].微生物学报,2021,61(7):2091-2100.
[20] 陈兰,陈玉霞,冯军,等.Pb(Ⅱ)和Cd(Ⅱ)在长根菇菌丝体中的富集及其对SOD、CAT酶活的影响[J].四川大学学报(自然科学版),2011,48(6):1391-1396.
[21] 许飘. 白腐真菌对重金属的吸附富集特性及其重金属耐受性和抗性机制研究[D].长沙:湖南大学,2016.
[22] Hossan S,Hossain S,Islam M R,et al.Bioremediation of Hexavalent Chromium by Chromium Resistant Bacteria Reduces Phytotoxicity[J].International Journal of Environmental Research and Public Health,2020,17(17):6013.
[23] Fernandez P M,Vinarta S C,Bernal A R,et al.Bioremediation strategies for chromium removal:Current research,scale-up approach and future perspectives[J],Chemosphere,2018,208:139-148.
[24] 江澜,闵燕,宋梦雨,等.以细菌和真菌作为生物吸附剂去除重金属和多环芳烃的研究进展[J].应用化工,2021,50(7):1993-1997.

一株耐铬真菌的分离鉴定及基于抗氧化酶的耐铬机制研究

Isolation and Identification of a Chromium-Tolerant Fungus and its Chromium-Tolerant Mechanism Based on Antioxidant Enzymes Response

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	强涛涛, 尉梦笛. 酸调节锆基MOF材料在光催化还原Cr(VI)的应用[J]. 皮革科学与工程, 2022, 32(3): 1-5.
[2]	李沁阳, 陈占光, 周诚, 黄彦杰, 唐余玲, 周建飞. 碱溶液提取-火焰原子吸收分光光度法对皮革中六价铬测定的适用性[J]. 皮革科学与工程, 2022, 32(1): 63-67.
[3]	杨健根;张一炜;李圣强;单志华;. 铬革屑的稳定化及减排研究[J]. , 2017, 27(02): 22-.
[4]	章宦胜;刘强;鲍洁敏;胡秀红;魏小春;. 不确定度评定在皮革中六价铬测定的应用[J]. , 2017, 27(01): 54-57.
[5]	赵正喜;莫珊;高跃昕;鹿文慧;杜永华;张新申;. γ-氧化铝低压柱富集-流动注射检测六价铬[J]. , 2016, 26(02): 67-71.
[6]	栾俊;王全杰;王闪闪;刁屾;张文斌;曲敬轩;. 微生物处理制革废弃物研究进展[J]. , 2015, 25(06): 28-33.
[7]	王吉;钟英;冯志平;王智生;. 制鞋工艺及储存运输环境对皮革六价铬的影响[J]. , 2015, 25(05): 54-56.
[8]	张莉;李成琴;胡文炬;王豪;. 从欧盟对皮革制品召回中分析六价铬的来源及措施[J]. , 2015, 25(01): 37-39.
[9]	张莉;李成琴;胡文炬;王豪;. 从欧盟对皮革制品召回中分析六价铬的来源及措施[J]. , 2015, 25(01): 37-39.
[10]	吴楠;徐晓颖;陶小平;但年华;王康建;王坤余;. 复鞣加脂对皮革中六价铬含量的影响[J]. , 2012, 22(04): 29-33.
[11]	吴楠;徐晓颖;陶小平;但年华;王康建;王坤余;. 复鞣加脂对皮革中六价铬含量的影响[J]. , 2012, 22(04): 29-33.
[12]	苏静;俞从正;王瑞;马兴元;王锋;. 橡椀栲胶的改性及其对Cr(Ⅵ)防治作用研究[J]. , 2010, 20(03): 28-33.
[13]	余陆沐;邬宁昆;兰莉;邵双喜;. 有色液中六价铬测定进展[J]. , 2010, 20(03): 42-44.
[14]	文立乾;赵长青;陈武勇;. Bacillus fusiformis对Cr(Ⅵ)的还原特性研究[J]. , 2009, 19(05): 18-22.
[15]	陈慧,单志华,邵双嘉,蒋岚. 成革中Cr(Ⅵ)的测定及影响因素[J]. , 2004, 14(03): 11-15.