Biodegradation of low-density polyethylene (LDPE) through application of indigenous strain Alcaligenesfaecalis ISJ128.

Autor: Devi, Deepa, Gupta, Kartikey Kumar, Chandra, Harish, Sharma, Kamal Kant, Sagar, Kalpana, Mori, Edna, de Farias, Pablo Antonio Maia, Coutinho, Henrique Douglas Melo, Mishra, Abhay Prakash
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Zdroj: Environmental Geochemistry & Health; Dec2023, Vol. 45 Issue 12, p9391-9409, 19p
Abstrakt: The resiliency of plastic products against microbial degradation in natural environment often creates devastating changes for humans, plants, and animals on the earth's surface. Biodegradation of plastics using indigenous bacteria may serve as a critical approach to overcome this resulting environmental stress. In the present work, a polyethylene degrading bacterium Alcaligenesfaecalis strain ISJ128 (Accession No. MK968769) was isolated from partially degraded polyethylene film buried in the soil at plastic waste disposal site. The biodegradation studies were conducted by employing various methods such as hydrophobicity assessment of the strain ISJ128, measurement of viability and total protein content of bacterial biofilm attached to the polyethylene surface. The proliferation of bacterial cells on polyethylene film, as indicated by high growth response in terms of protein content (85.50 µg mL−1) and viability (1010 CFU mL−1), proposed reasonable suitability of our strain A.faecalis ISJ128 toward polyethylene degradation. The results of biodegradation assay revealed significant degradation (10.40%) of polyethylene film within a short period of time (i.e., 60 days), whereas no signs of degradation were seen in control PE film. A.faecalis strain ISJ128 also demonstrated a removal rate of 0.0018 day−1 along with half-life of 462 days. The scanning electron microscope (SEM) and Fourier transform infrared (FTIR) spectroscopy studies not only displayed changes on polyethylene surface but also altered level of intensity of functional groups and an increase in the carbonyl indexes justifying the degradation of polyethylene film due to bacterial activity. In addition, the secondary structure prediction (M fold software) of 16SrDNA proved the stable nature of the bacterial strain, thereby reflecting the profound scope of A.faecalis strain ISJ128 as a potential degrader for the eco-friendly disposal of polyethylene waste. Schematic representation of methodology [ABSTRACT FROM AUTHOR]
Databáze: Complementary Index
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