TY - JOUR
T1 - Mycobacteriaceae Mineralizes Micropolyethylene in Riverine Ecosystems
AU - Sun, Xiaoxu
AU - Chen, Zhenyu
AU - Kong, Tianle
AU - Chen, Zheng
AU - Dong, Yiran
AU - Kolton, Max
AU - Cao, Zhiguo
AU - Zhang, Xin
AU - Zhang, Haihan
AU - Liu, Guoqiang
AU - Gao, Pin
AU - Yang, Nie
AU - Lan, Ling
AU - Xu, Yating
AU - Sun, Weimin
N1 - Publisher Copyright:
© 2022 American Chemical Society. All rights reserved.
PY - 2022/11/15
Y1 - 2022/11/15
N2 - Microplastic (MP) contamination is a serious global environmental problem. Plastic contamination has attracted extensive attention during the past decades. While physiochemical weathering may influence the properties of MPs, biodegradation by microorganisms could ultimately mineralize plastics into CO2. Compared to the well-studied marine ecosystems, the MP biodegradation process in riverine ecosystems, however, is less understood. The current study focuses on the MP biodegradation in one of the world's most plastic contaminated rivers, Pearl River, using micropolyethylene (mPE) as a model substrate. Mineralization of 13C-labeled mPE into 13CO2provided direct evidence of mPE biodegradation by indigenous microorganisms. Several Actinobacteriota genera were identified as putative mPE degraders. Furthermore, two Mycobacteriaceae isolates related to the putative mPE degraders, Mycobacterium sp. mPE3 and Nocardia sp. mPE12, were retrieved, and their ability to mineralize 13C-mPE into 13CO2was confirmed. Pangenomic analysis reveals that the genes related to the proposed mPE biodegradation pathway are shared by members of Mycobacteriaceae. While both Mycobacterium and Nocardia are known for their pathogenicity, these populations on the plastisphere in this study were likely nonpathogenic as they lacked virulence factors. The current study provided direct evidence for MP mineralization by indigenous biodegraders and predicted their biodegradation pathway, which may be harnessed to improve bioremediation of MPs in urban rivers.
AB - Microplastic (MP) contamination is a serious global environmental problem. Plastic contamination has attracted extensive attention during the past decades. While physiochemical weathering may influence the properties of MPs, biodegradation by microorganisms could ultimately mineralize plastics into CO2. Compared to the well-studied marine ecosystems, the MP biodegradation process in riverine ecosystems, however, is less understood. The current study focuses on the MP biodegradation in one of the world's most plastic contaminated rivers, Pearl River, using micropolyethylene (mPE) as a model substrate. Mineralization of 13C-labeled mPE into 13CO2provided direct evidence of mPE biodegradation by indigenous microorganisms. Several Actinobacteriota genera were identified as putative mPE degraders. Furthermore, two Mycobacteriaceae isolates related to the putative mPE degraders, Mycobacterium sp. mPE3 and Nocardia sp. mPE12, were retrieved, and their ability to mineralize 13C-mPE into 13CO2was confirmed. Pangenomic analysis reveals that the genes related to the proposed mPE biodegradation pathway are shared by members of Mycobacteriaceae. While both Mycobacterium and Nocardia are known for their pathogenicity, these populations on the plastisphere in this study were likely nonpathogenic as they lacked virulence factors. The current study provided direct evidence for MP mineralization by indigenous biodegraders and predicted their biodegradation pathway, which may be harnessed to improve bioremediation of MPs in urban rivers.
KW - Mycobacterium
KW - Nocardia
KW - microplastic
KW - pangenomic analysis
KW - polyethylene biodegradation
UR - http://www.scopus.com/inward/record.url?scp=85141014456&partnerID=8YFLogxK
U2 - 10.1021/acs.est.2c05346
DO - 10.1021/acs.est.2c05346
M3 - Article
C2 - 36288260
AN - SCOPUS:85141014456
SN - 0013-936X
VL - 56
SP - 15705
EP - 15717
JO - Environmental Science and Technology
JF - Environmental Science and Technology
IS - 22
ER -
