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Linking increased isotope fractionation at low concentrations to enzyme activity regulation: 4-Cl phenol degradation by Arthrobacter chlorophenolicus A6.
Environ. Sci. Technol. 56, 3021-3032 (2022)
Slow microbial degradation of organic trace chemicals ("micropollutants") has been attributed to either downregulation of enzymatic turnover or rate-limiting substrate supply at low concentrations. In previous biodegradation studies, a drastic decrease in isotope fractionation of atrazine revealed a transition from rate-limiting enzyme turnover to membrane permeation as a bottleneck when concentrations fell below the Monod constant of microbial growth. With degradation of the pollutant 4-chlorophenol (4-CP) by Arthrobacter chlorophenolicus A6, this study targeted a bacterium which adapts its enzyme activity to concentrations. Unlike with atrazine degradation, isotope fractionation of 4-CP increased at lower concentrations, from ε(C) = -1.0 ± 0.5‰ in chemostats (D = 0.090 h-1, 88 mg L-1) and ε(C) = -2.1 ± 0.5‰ in batch (c0 = 220 mg L-1) to ε(C) = -4.1 ± 0.2‰ in chemostats at 90 μg L-1. Surprisingly, fatty acid composition indicated increased cell wall permeability at high concentrations, while proteomics revealed that catabolic enzymes (CphCI and CphCII) were differentially expressed at D = 0.090 h-1. These observations support regulation on the enzyme activity level─through either a metabolic shift between catabolic pathways or decreased enzymatic turnover at low concentrations─and, hence, reveal an alternative end-member scenario for bacterial adaptation at low concentrations. Including more degrader strains into this multidisciplinary analytical approach offers the perspective to build a knowledge base on bottlenecks of bioremediation at low concentrations that considers bacterial adaptation.
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Publication type
Article: Journal article
Document type
Scientific Article
Keywords
Cell Wall Permeability ; Chemostat ; Enzyme Regulation ; Isotope Effect ; Limits Of Biodegradation ; Mass Transfer ; Proteomics
Language
english
Publication Year
2022
HGF-reported in Year
2022
ISSN (print) / ISBN
0013-936X
e-ISSN
1520-5851
Quellenangaben
Volume: 56,
Issue: 5,
Pages: 3021-3032
Publisher
American Chemical Society (ACS)
Publishing Place
Washington, DC
Reviewing status
Peer reviewed
POF-Topic(s)
20403 - Sustainable Water Management
30203 - Molecular Targets and Therapies
30203 - Molecular Targets and Therapies
Research field(s)
Environmental Sciences
Enabling and Novel Technologies
Enabling and Novel Technologies
PSP Element(s)
G-504390-001
G-505700-001
G-505700-001
WOS ID
WOS:000776699100015
Scopus ID
85125354830
PubMed ID
35148097
Erfassungsdatum
2022-05-05