Accelerated Degradation of four Organophosphorus Insecticides by Malathion Tolerant Aspergillus niger MRU01 a Soil Fungus

IF 2.2 4区环境科学与生态学 Q3 ENVIRONMENTAL SCIENCES

Geomicrobiology Journal Pub Date : 2023-09-21 DOI:10.1080/01490451.2023.2259912

Debasish Mohapatra, Sakti Kanta Rath, Pradipta K. Mohapatra

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引用次数: 1

Abstract

AbstractInsecticides are widely used in agriculture, horticulture, medicine, and industry, as well as domestically. Increased insecticide application has been attributed to higher agricultural productivity and lower infield and postharvest crop loss in the twentieth century. Malathion is a very commonly used organophosphorus (OP) insecticide applied in over 100 food crops in agriculture and post-harvest storage. Different species of Aspergillus have shown their efficiency to degrade OP chemicals. A malathion tolerant Aspergillus niger MRU01, developed by prolonged malathion exposure, was tested for its efficiency to remove malathion as well as three other commonly used OP insecticides, viz., parathion, chlorpyrifos and dimethoate. The tolerant strain showed growth efficiency as well as enhanced production of phosphatases and esterase enzyme as compared to untreated and treated wild type (A. niger ATCC16404). The removal of malathion was 29% and 68%, in the wild type and the tolerant strain, respectively during five days. The tolerant strain was also able to remove dimethoate (63%) and chlorpyrifos (54%) with high efficiency while a low rate of removal of parathion (33%) was observed. The strain can be tested in the microcosms more specifically for bioremediation of other OP insecticides before its application in the field.HIGHLIGHTSThe malathion tolerant Aspergillus niger MRU01 grew efficiently in the presence of 500 μM malathion.Treatment of the fungus with malathion and other OP insecticides – parathion, chlorpyrifos, and dimethoate – caused enhanced expression of phosphatases and esterases.The tolerant A. niger MRU01 strain had significantly lower mycelia concentrations of insecticides than of the wild type A. niger ATCC16404.Degradation of insecticides by the tolerant strain was significantly higher than by the wild type indicating its broad spectrum of tolerance.Keywords: Aspergillus nigermalathion mutantOP insecticidesesterasesphosphatasesremoval AcknowledgmentsThe research was partly funded by Department of Science and Technology, Government of Odisha, and OHEPEE, Government of Odisha. The infrastructure grants of DST, Government of India under DST-FIST programme is gratefully acknowledged.Authors’ contributionsAll authors contributed to the study conception and design. Conceptualization, investigation, original draft was performed by Debasish Mohapatra. Data curation, formal analysis was done by Sakti Kanta Rath and project administration, data analysis, review and editing was performed by Pradipta K Mohapatra. All authors read and approved the final manuscript.”Disclosure statementNo potential conflict of interest was reported by the author(s).Additional informationFundingThis work was supported by Department of Science and Technology, Government of Odisha, and OHEPEE, Government of Odisha. The infrastructure grants of DST, Government of India under DST-FIST

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耐马拉硫磷黑曲霉MRU01加速降解4种有机磷杀虫剂的研究

摘要农药广泛应用于农业、园艺、医药、工业和家庭。杀虫剂使用量的增加归因于20世纪农业生产力的提高和田间和收获后作物损失的减少。马拉硫磷是一种非常常用的有机磷杀虫剂，应用于农业和收获后储存的100多种粮食作物中。不同种类的曲霉已经显示出它们对OP化学物质的降解效率。通过长期接触马拉硫磷而培育出的耐马拉硫磷黑曲霉MRU01，对其去除马拉硫磷以及其他三种常用的有机磷杀虫剂(对硫磷、毒死蜱和乐果)的效率进行了测试。与未经处理和处理的野生型(A. niger ATCC16404)相比，该耐药菌株表现出生长效率，并提高了磷酸酶和酯酶的产量。野生型和耐受性菌株在5 d内对马拉硫磷的去除率分别为29%和68%。耐药菌株对乐果(63%)和毒死蜱(54%)的去除率较高，对硫磷(33%)的去除率较低。该菌株在野外应用前可在微生物中进行更特异性的生物修复试验，以便对其他有机磷杀虫剂进行生物修复。耐马拉硫磷黑曲霉MRU01在500 μM马拉硫磷环境下生长良好。用马拉硫磷和其他有机磷杀虫剂(对硫磷、毒死蜱和乐果)处理真菌可增强其磷酸酶和酯酶的表达。耐药菌株MRU01菌丝体杀虫剂浓度显著低于野生型菌株ATCC16404。耐受性菌株对杀虫剂的降解率明显高于野生型，表明其耐受性谱广。本研究由奥里萨邦政府科技部和奥里萨邦政府OHEPEE部分资助。感谢印度政府DST在DST- first方案下提供的基础设施赠款。作者的贡献所有作者都对研究的构思和设计做出了贡献。概念化，调查，原稿由Debasish Mohapatra完成。数据管理、形式分析由Sakti Kanta Rath完成，项目管理、数据分析、审查和编辑由Pradipta K Mohapatra完成。所有作者都阅读并认可了最终的手稿。”披露声明作者未报告潜在的利益冲突。这项工作得到了奥里萨邦政府科技部和奥里萨邦政府OHEPEE的支持。印度政府在DST- first下的DST基础设施拨款

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来源期刊

Geomicrobiology Journal 环境科学-地球科学综合

CiteScore

4.80

自引率

8.70%

发文量

审稿时长

3.3 months

期刊介绍： Geomicrobiology Journal is a unified vehicle for research and review articles in geomicrobiology and microbial biogeochemistry. One or two special issues devoted to specific geomicrobiological topics are published each year. General articles deal with microbial transformations of geologically important minerals and elements, including those that occur in marine and freshwater environments, soils, mineral deposits and rock formations, and the environmental biogeochemical impact of these transformations. In this context, the functions of Bacteria and Archaea, yeasts, filamentous fungi, micro-algae, protists, and their viruses as geochemical agents are examined. Articles may stress the nature of specific geologically important microorganisms and their activities, or the environmental and geological consequences of geomicrobiological activity. The Journal covers an array of topics such as: microbial weathering; microbial roles in the formation and degradation of specific minerals; mineralization of organic matter; petroleum microbiology; subsurface microbiology; biofilm form and function, and other interfacial phenomena of geological importance; biogeochemical cycling of elements; isotopic fractionation; paleomicrobiology. Applied topics such as bioleaching microbiology, geomicrobiological prospecting, and groundwater pollution microbiology are addressed. New methods and techniques applied in geomicrobiological studies are also considered.