Metagenomics-Based Discovery of Malachite Green-Degradation Gene Families and Enzymes From Mangrove Sediment

Malachite green (MG) is an organic contaminant and the effluents with MG negatively influence the health and balance of the coastal and marine ecosystem. The diverse and abundant microbial communities inhabiting in mangroves participate actively in various ecological processes. Metagenomic sequencin...

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Published inFrontiers in microbiology Vol. 9; p. 2187
Main Authors Qu, Wu, Liu, Tan, Wang, Dexiang, Hong, Guolin, Zhao, Jing
Format Journal Article
LanguageEnglish
Published Switzerland Frontiers Media S.A 11.09.2018
Subjects
biochemical analysis
degradation pathway
gene expression
mangrove sediment
metagenome
MG biodegradation
Microbiology
degradation pathway
metagenome
MG biodegradation
mangrove sediment
biochemical analysis
gene expression
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Summary:Malachite green (MG) is an organic contaminant and the effluents with MG negatively influence the health and balance of the coastal and marine ecosystem. The diverse and abundant microbial communities inhabiting in mangroves participate actively in various ecological processes. Metagenomic sequencing from mangrove sediments was applied to excavate the resources MG-degradation genes (MDGs) and to assess the potential of their corresponding enzymes. A data set of 10 GB was assembled into 33,756 contigs and 44,743 ORFs were predicted. In the data set, 666 bacterial genera and 13 pollutant degradation pathways were found. and were the most dominate phyla in taxonomic assignment. A total of 44 putative MDGs were revealed and possibly derived from 30 bacterial genera, most of which belonged to the phyla of and . The MDGs belonged to three gene families, including genes (up to 93.54% of total MDGs), (3.40%), and (3.06%). Of the three gene families, three representatives (Mgv-rLACC, Mgv-rPOD, and Mgv-rCYP) which had lower similarities to the closest sequences in GenBank were prokaryotic expressed and their enzymes were characterized. Three recombinant proteins showed different MG-degrading activities. Mgv-rPOD had the strongest activity which decolorized 97.3% of MG (300 mg/L) within 40 min. In addition, Mgv-rPOD showed a more complete process of MG degradation compared with other two recombinant proteins according to the intermediates detected by LC-MS. Furthermore, the high MG-degrading activity was maintained at low temperature (20°C), wider pH range, and the existence of metal ions and chelating agent. Mgv-rLACC and Mgv-rCYP also removed 63.7% and 54.1% of MG (20 mg/L) within 24 h, respectively. The results could provide a broad insight into discovering abundant genetic resources and an effective strategy to access the eco-friendly way for preventing coastal pollution.
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Edited by: Shaohua Chen, South China Agricultural University, China
This article was submitted to Microbiotechnology, Ecotoxicology and Bioremediation, a section of the journal Frontiers in Microbiology
Reviewed by: Dong Li, University of California, Santa Barbara, United States; Qing Hong, Nanjing Agricultural University, China; Hongzhi Tang, Shanghai Jiao Tong University, China
ISSN:1664-302X
1664-302X
DOI:10.3389/fmicb.2018.02187