Exploring Novel Microorganisms for PAH Degradation in Egyptian Soil: A Bioremediation Strategy for Soil Detoxification.

Q3 Biochemistry, Genetics and Molecular Biology

Recent patents on biotechnology Pub Date : 2025-08-19 DOI:10.2174/0118722083393750250630081655

Amira A Shendy, Heba K Abdelhakim, Mohamed A El-Desouky, Fatma B Rashidi

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Abstract

Introduction: Polycyclic aromatic hydrocarbons (PAHs) are toxic petroleum byproducts in soil, exhibiting significant genotoxic properties. Microorganisms residing in contaminated soils serve as effective detoxifying agents. Among various strategies, bioremediation is an efficient biological method for detoxifying PAHs.

Method: Hundreds of soil samples were collected from the Gulf of Suez, Egypt. The isolation process utilized an enrichment culture system with phenol naphthalene (PN) (10 mg/mL) as the primary carbon source. HPLC analysis was applied to confirm PN degradation. Consequently, the bacterial strain was characterized morphologically, biochemically, and through partial sequencing of its 16S rRNA gene. Subsequently, its plasmid was purified to transfer its phenotype to Escherichia coli. Finally, a bioremediation approach was conducted to test its PAH degradation.

Results: HPLC analysis was performed to confirm PN degradation by the isolated strain. The isolated strain was identified as Lysinibacillus species AAS1 (OR044755.1) with 98.43% sequence similarity to the Lysinibacillus genus. Subsequently, E. coli transformants with the isolated plasmid were grown in the presence of PN as the primary carbon source. Finally, the bioremediation assay of the isolated strain exhibited a high efficiency in detoxifying PN.

Discussion: The novel identified Lysinibacillus species AAS1 (OR044755.1) shows promise for PAHs detoxification, which may lead to the exploration of a biological agent for the remediation of water and soil contaminated with PAHs.

Conclusion: A novel bacterial strain bearing a plasmid that can degrade PN was isolated from Egyptian petroleum waste-contaminated soil. It paved the way for further studies to isolate the whole gene(s) responsible for such degradation.

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探索埃及土壤中降解多环芳烃的新微生物：土壤解毒的生物修复策略。

多环芳烃（PAHs）是土壤中有毒的石油副产品，具有显著的遗传毒性。污染土壤中的微生物是有效的解毒剂。在多种解毒策略中，生物修复是一种有效的解毒多环芳烃的生物方法。方法：在埃及苏伊士湾采集了数百份土壤样品。分离过程采用苯酚萘（PN）（10 mg/mL）为主要碳源的富集培养体系。HPLC分析证实了PN的降解。因此，对该菌株进行了形态学、生化和16S rRNA基因部分测序。随后，纯化其质粒，将其表型转移到大肠杆菌中。最后，采用生物修复方法测试其对多环芳烃的降解能力。结果：高效液相色谱分析证实分离菌株可降解PN。分离菌株经鉴定为Lysinibacillus species AAS1 (OR044755.1)，与Lysinibacillus genus序列相似性为98.43%。随后，用分离的质粒在PN作为主要碳源的条件下培养大肠杆菌转化子。最后，分离菌株的生物修复实验显示出对PN的高效解毒。讨论：新发现的赖氨酸芽孢杆菌AAS1 （OR044755.1）具有解毒多环芳烃的潜力，这可能会导致对修复被多环芳烃污染的水和土壤的生物制剂的探索。结论：从埃及石油废弃物污染的土壤中分离到一株具有降解PN质粒的新型细菌。它为进一步分离导致这种降解的整个基因的研究铺平了道路。

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来源期刊

Recent patents on biotechnology Biochemistry, Genetics and Molecular Biology-Biotechnology

CiteScore

2.90

自引率

0.00%

发文量

期刊介绍： Recent Patents on Biotechnology publishes review articles by experts on recent patents on biotechnology. A selection of important and recent patents on biotechnology is also included in the journal. The journal is essential reading for all researchers involved in all fields of biotechnology.