Multifunctional Periphytic Biofilms: Polyethylene Degradation and Cd and Pb Bioremediation Under High Methane Scenario

Overview

Journal Int J Mol Sci

Publisher MDPI

Specialties Biochemistry
Chemistry
Molecular Biology

Date 2020 Jul 31

PMID 32727088

Citations 3

Authors

Muhammad Faheem

Sadaf Shabbir

Jun Zhao

Philip G Kerr

Shafaqat Ali

Nasrin Sultana

Zhongjun Jia

Affiliations

Soon will be listed here.

Abstract

Priority pollutants such as polyethylene (PE) microplastic, lead (Pb), and cadmium (Cd) have attracted the interest of environmentalists due to their ubiquitous nature and toxicity to all forms of life. In this study, periphytic biofilms (epiphyton and epixylon) were used to bioremediate heavy metals (HMs) and to biodegrade PE under high (120,000 ppm) methane (CH) doses. Both periphytic biofilms were actively involved in methane oxidation, HMs accumulation and PE degradation. Epiphyton and epixylon both completely removed Pb and Cd at concentrations of 2 mg L and 50 mg L, respectively, but only partially removed these HMs at a relatively higher concentration (100 mg L). Treatment containing 12% CH proved to be most effective for biodegradation of PE. A synergistic effect of HMs and PE drastically changed microbial biota and methanotrophic communities. High-throughput 16S rRNA gene sequencing revealed that Cyanobacteria was the most abundant class, followed by Gammaproteobacteria and Alphaproteobacteria in all high-methane-dose treatments. DNA stable-isotope probing was used to label C in a methanotrophic community. A biomarker for methane-oxidizing bacteria, gene sequence of a C-labeled fraction, revealed that was most abundant in all high-methane-dose treatments compared to near atmospheric methane (NAM) treatment, followed by . , , and were also found to be increased by high doses of methane compared to NAM treatment. Overall, Cd had a more determinantal effect on methanotrophic activity than Pb. Epiphyton proved to be more effective than epixylon in HMs removal and PE biodegradation. The findings proved that both epiphyton and epixylon can be used to bioremediate HMs and biodegrade PE as an efficient ecofriendly technique under high methane concentrations.

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