Isolation and characterization of microorganisms capable of cleaving the ether bond of 2-phenoxyacetophenone

Lignin is a heterogeneous aromatic polymer and major component of plant cell walls. The β- O -4 alkyl aryl ether is the most abundant linkage within lignin. Given that lignin is effectively degraded on earth, as yet unknown ether bond–cleaving microorganisms could still exist in nature. In this stud...

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Bibliographic Details
Published in:Scientific reports 2022-02, Vol.12 (1), p.2874-9, Article 2874
Main Authors: Oya, Saki, Tonegawa, Satoshi, Nakagawa, Hirari, Habe, Hiroshi, Furuya, Toshiki
Format: Article
Language:English
Subjects:
631/326
631/61
Acetophenones - metabolism
Acidic soils
Acinetobacter
Acinetobacter - metabolism
Benzoic acid
Biodegradation
Carbon sources
Cell walls
Colorimetry
Cupriavidus - metabolism
Ether - metabolism
Gram-negative bacteria
High-performance liquid chromatography
Humanities and Social Sciences
Humic acids
Lignin
Lignin - metabolism
Liquid chromatography
Microorganisms
multidisciplinary
Nocardioides - metabolism
Organic compounds
Organic soils
Penicillium - metabolism
Phenols
Polymers
Science
Science (multidisciplinary)
Strains (organisms)
Streptomyces - metabolism
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Summary:Lignin is a heterogeneous aromatic polymer and major component of plant cell walls. The β- O -4 alkyl aryl ether is the most abundant linkage within lignin. Given that lignin is effectively degraded on earth, as yet unknown ether bond–cleaving microorganisms could still exist in nature. In this study, we searched for microorganisms that transform 2-phenoxyacetophenone (2-PAP), a model compound for the β- O -4 linkage in lignin, by monitoring ether bond cleavage. We first isolated microorganisms that grew on medium including humic acid (soil-derived organic compound) as a carbon source. The isolated microorganisms were subsequently subjected to colorimetric assay for 2-PAP ether bond–cleaving activity; cells of the isolated strains were incubated with 2-PAP, and strains producing phenol via ether bond cleavage were selected using phenol-sensitive Gibbs reagent. This screening procedure enabled the isolation of various 2-PAP–transforming microorganisms, including 7 bacteria (genera: Acinetobacter , Cupriavidus , Nocardioides , or Streptomyces ) and 1 fungus (genus: Penicillium ). To our knowledge, these are the first microorganisms demonstrated to cleave the ether bond of 2-PAP. One Gram-negative bacterium, Acinetobacter sp. TUS-SO1, was characterized in detail. HPLC and GC–MS analyses revealed that strain TUS-SO1 oxidatively and selectively cleaves the ether bond of 2-PAP to produce phenol and benzoate. These results indicate that the transformation mechanism differs from that involved in reductive β-etherase, which has been well studied. Furthermore, strain TUS-SO1 efficiently transformed 2-PAP; glucose-grown TUS-SO1 cells converted 1 mM 2-PAP within only 12 h. These microorganisms might play important roles in the degradation of lignin-related compounds in nature.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-022-06816-1