Verma_2024_Int.J.Biol.Macromol_280_136006

Reference

Title : In-silico characterization of a hypothetical protein of Sulfobacillus sp. hq2 for degradation of phthalate diesters - Verma_2024_Int.J.Biol.Macromol_280_136006
Author(s) : Verma S , Singh A , Kumar P , Singla J
Ref : Int J Biol Macromol , 280 :136006 , 2024
Abstract :

Phthalate plasticizers are hazardous compounds capable of causing endocrine disruption, cancers, and developmental disorders. Phthalate diesters are commonly used plasticizers in plastic products (PVC pipes) that leach out into the environment due to changes in temperature, pressure, and pH, posing harmful effects on different life forms. Bioremediation of phthalate diesters utilizing bacterial esterase has been recognized as an efficient approach but few effective esterases capable of degrading a wide range of phthalate diesters have been identified. Further, the thermostability of these esterases is a highly desirable property for their applications in diverse in-situ conditions. In this present in-silico study a hypothetical protein (POB10642.1) as a high-potential esterase from a thermostable strain of Sulfobacillus sp. hq2 has been characterized. Analysis revealed a significant sequence identity of 42.67 % and structural similarity (RMSD 0.557) with known phthalate diester degrading EstS1 esterase and a high Tm range of 55-66 degreesC. Structural analysis revealed the presence of two cavities on the surface mediating toward the catalytic site forming a catalytic tunnel. The enzyme POB10642.1 has significant molecular docking binding energies in the range of -5.4 to -7.5 kcal/mol with several phthalate diesters, including Diethyl phthalate, Dipropyl phthalate, Dibutyl phthalate, Dipentyl phthalate, Dihexyl phthalate, Benzyl butyl phthalate, Dicyclohexyl phthalate, and Bis(2-ethylhexyl) phthalate. High stability of binding during 100 ns molecular dynamics simulations revealed efficient and stable binding of the enzyme with a wide range of phthalate diesters at its active site, demonstrating the ability of the identified esterase to interact with and degrade diverse phthalate diesters. Therefore, POB10642.1 esterase can be an efficient candidate to be utilized in the development of enzyme-based bioremediation technologies to reduce the toxic levels of phthalate diesters.

PubMedSearch : Verma_2024_Int.J.Biol.Macromol_280_136006
PubMedID: 39326604

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Citations formats

Verma S, Singh A, Kumar P, Singla J (2024)
In-silico characterization of a hypothetical protein of Sulfobacillus sp. hq2 for degradation of phthalate diesters
Int J Biol Macromol 280 :136006

Verma S, Singh A, Kumar P, Singla J (2024)
Int J Biol Macromol 280 :136006