2018
DOI: 10.1007/s00253-018-9040-3
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Microbial β-etherases and glutathione lyases for lignin valorisation in biorefineries: current state and future perspectives

Abstract: Lignin is the major aromatic biopolymer in nature, and it is considered a valuable feedstock for the future supply of aromatics. Hence, its valorisation in biorefineries is of high importance, and various chemical and enzymatic approaches for lignin depolymerisation have been reported. Among the enzymes known to act on lignin, β-etherases offer the possibility for a selective cleavage of the β-O-4 aryl ether bonds present in lignin. These enzymes, together with glutathione lyases, catalyse a reductive, glutath… Show more

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Cited by 15 publications
(20 citation statements)
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“…Similar pathways were also described for some other bacteria of the order Sphingomonadales (20). Even though C␣ dehydrogenases, ␤-etherases, and glutathione lyases are intracellular enzymes and, hence, likely act on soluble lignin degradation products in nature (12), their potential for lignin polymer degradation has been demonstrated in several studies (8,10,11). When applying this enzymatic pathway for lignin depolymerization, aromatic monomers such as guaiacyl hydroxypropanone (GHP) and syringyl hydroxypropanone (SHP) could be released rather selectively (10,11).…”
supporting
confidence: 62%
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“…Similar pathways were also described for some other bacteria of the order Sphingomonadales (20). Even though C␣ dehydrogenases, ␤-etherases, and glutathione lyases are intracellular enzymes and, hence, likely act on soluble lignin degradation products in nature (12), their potential for lignin polymer degradation has been demonstrated in several studies (8,10,11). When applying this enzymatic pathway for lignin depolymerization, aromatic monomers such as guaiacyl hydroxypropanone (GHP) and syringyl hydroxypropanone (SHP) could be released rather selectively (10,11).…”
supporting
confidence: 62%
“…S2). Optima in the alkaline pH range have been reported for all previously known ␤-etherases as well, and they are very likely caused by the pK a of the glutathione thiol (reported pK a of 9.65 for free GSH) (9,12,20). Hence, a high pH facilitates deprotonation of the GSH thiol, which is a prerequisite for nucleophilic attack of the ether substrate.…”
Section: Resultsmentioning
confidence: 92%
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“…Second, β-etherases (the glutathione S -transferases (GSTs) LigF, LigE, and LigP in SYK-6) replace the β-aryl ether bond of MPHPV with a β-thioether bond involving glutathione (GSH), producing guaiacol and the GSH conjugate, β-glutathionyl-γ-hydroxypropiovanillone (GS-HPV) (20, 21). Known bacterial β-etherases fall into two distinct GST subclasses and are strictly stereospecific for the chirality of the bond's β-carbon (22), with LigE homologues (which include LigP and which are similar to fungal FuA GSTs (2325)) cleaving the β( R ) isomer of the bond and LigF homologues (which are distinct in amino acid sequence and three-dimensional structure from known members of any previously established GST class (25)) cleaving the β( S ) isomer. Finally, GSH lyases (the GSTs LigG (20) and SYK6GST Nu (26) in SYK-6) remove the GSH moiety from GS-HPV and combine it with another GSH, producing hydroxypropiovanillone (HPV) and GSH disulfide (GSSG).…”
Section: Introductionmentioning
confidence: 99%
“…Finally, GSH lyases (the GSTs LigG (20) and SYK6GST Nu (26) in SYK-6) remove the GSH moiety from GS-HPV and combine it with another GSH, producing hydroxypropiovanillone (HPV) and GSH disulfide (GSSG). LigG homologues, which share some features with Omega-class GSTs (27), are reported to preferentially cleave β( R )-GS-HPV, whereas the Nu-class GST Nu homologues cleave both the β( R ) and β( S ) stereoisomers of GS-HPV with similar catalytic efficiencies (22, 26).…”
Section: Introductionmentioning
confidence: 99%