Solubilization and enhanced degradation of benzene phenolic derivatives—Bisphenol A/Triclosan using a biosurfactant producing white rot fungus Hypocrea lixii S5 with plant growth promoting traits

Chaturvedi, Mridula; Kaur, Navpreet; Rahman, Pattanathu K. S. M.; Sharma, Shashi

doi:10.3389/fmicb.2024.1433745

Front. Microbiol.

2024

DOI: 10.3389/fmicb.2024.1433745

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Solubilization and enhanced degradation of benzene phenolic derivatives—Bisphenol A/Triclosan using a biosurfactant producing white rot fungus Hypocrea lixii S5 with plant growth promoting traits

Mridula Chaturvedi,

Navpreet Kaur,

Pattanathu K. S. M. Rahman

et al.

Abstract: IntroductionEndocrine disrupting chemicals (EDCs) as benzene phenolic derivatives being hydrophobic partition to organic matter in sludge/soil sediments and show slow degradation rate owing to poor bioavailability to microbes.MethodsIn the present study, the potential of a versatile white rot fungal isolate S5 identified as Hypocrea lixii was monitored to degrade bisphenol A (BPA)/triclosan (TCS) under shake flask conditions with concomitant production of lipopeptide biosurfactant (BS) and plant growth promoti… Show more

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Cited by 2 publications

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Sustainable Approaches for Managing Phthalate Pollution: Navigating Challenges, and Establishing the Future of Environmental Protection

Marcharla,

Chauhan,

Hariharan

et al. 2024

Advanced Sustainable Systems

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Phthalates have become a widespread environmental pollutant that has severe implications for aquatic and terrestrial ecosystems. They are found in various sources, including industrial processes, consumer products, and food packaging, resulting in significant environmental contamination. Their persistence and ability to bioaccumulate present significant risks, especially impacting reproductive, developmental, and endocrine systems in humans. This review explores how phthalates function as mixed micropollutants, adding complexity to their evaluation and control in environmental systems. It also focuses on remediation strategies using novel biotechnological approaches, such as enzymatic degradation, genetic engineering, microbial remediation, and nanotechnology‐based approaches. Enzymatic degradation utilizes specific enzymes for the breakdown of phthalates, thereby, transforming them into less toxic metabolites. Novel genetic engineering techniques have opened possibilities for improving the breakdown of phthalates by microorganisms, offering potential solutions for more efficient remediation. Nanotechnology‐based approaches showcase the effectiveness of nanomaterials in absorbing and breaking down phthalates on a molecular scale. This review also highlights the importance of microbial consortia and biochar‐microbial composites for environmental restoration. The unique contribution of this review lies in its comprehensive analysis of advanced biotechnological strategies for phthalate remediation, emphasizing the synergistic potential of novel techniques to protect and safeguard the environment for future generations.

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Sustainable Approaches for Managing Phthalate Pollution: Navigating Challenges, and Establishing the Future of Environmental Protection

Marcharla,

Chauhan,

Hariharan

et al. 2024

Advanced Sustainable Systems

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Sustainable Approach for Degradation of Low‐Density Polyethylene Plastic Waste Using Ligninolytic White Rot Fungus

Chaturvedi,

Kaur,

Alam

et al. 2024

Journal of Basic Microbiology

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Bisphenol A (BPA), an endocrine disruptor is used in manufacturing of polycarbonate plastics for food—drink packaging. In the present study, optimized set of conditions to degrade commercial grade BPA has been used and applied in degrading shredded leached low‐density polyethylene (LDPE) residues and its leachate (198 µg/L BPA) using white rot fungus Hypocrea lixii. One‐at‐a‐time method showed maximum BPA degradation of 98.73 ± 0.02% with 190.1 ± 0.2 U/L laccase and 1913.2 ± 0.3 U/L lignin peroxidase in glucose‐yeast extract‐malt extract‐peptone (GYMP) medium supplemented with 5% sawdust, mediators—CuSO4 (0.2 mM), veratryl alcohol (0.1 mM) and Tween 80 (0.1 mM). Three sets were prepared by dissolving these optimized nutritional components in leachates—A (only leachate), B (leached LDPE residues in leachate) and C (leached LDPE residues, sawdust in leachate). All sets showed 100% degradation in 5 days. Cracks and holes in degraded LDPE pieces was confirmed by SEM analysis and changes in functional groups by FTIR. Toxicity assay of treated leachate on soil microfauna revealed the elimination of BPA as it supported sufficient microbial growth of soil bacteria. Thus, the present process provides a sustainable solution for the management of LDPE with the possibility of using treated leachate for irrigation.

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Solubilization and enhanced degradation of benzene phenolic derivatives—Bisphenol A/Triclosan using a biosurfactant producing white rot fungus Hypocrea lixii S5 with plant growth promoting traits

Cited by 2 publications

References 59 publications

Sustainable Approaches for Managing Phthalate Pollution: Navigating Challenges, and Establishing the Future of Environmental Protection

Sustainable Approaches for Managing Phthalate Pollution: Navigating Challenges, and Establishing the Future of Environmental Protection

Sustainable Approach for Degradation of Low‐Density Polyethylene Plastic Waste Using Ligninolytic White Rot Fungus

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