Lignin is a heterogeneous aromatic polymer found as 10-35% of lignocellulose, found in plant cell walls. The bio-conversion of plant lignocellulose to glucose is an important part of second generation biofuel production, but the resistance of lignin to breakdown is a major obstacle in this process, hence there is considerable interest in the microbial breakdown of lignin. White-rot fungi are known to break down lignin with the aid of extracellular peroxidase and laccase enzymes. There are also reports of bacteria that can degrade lignin, and recent work indicates that bacterial lignin breakdown may be more significant than previously thought. The review will discuss the enzymes for lignin breakdown in fungi and bacteria, and the catabolic pathways for breakdown of the β-aryl ether, biphenyl and other components of lignin in bacteria and fungi. The review will also discuss small molecule phenolic breakdown products from lignin that have been identified from lignin-degrading microbes, and includes a bioinformatic analysis of the occurrence of known lignin-degradation pathways in Gram-positive and Gram-negative bacteria.
Rhodococcus jostii RHA1 peroxidase DypB has been recently identified as a bacterial lignin peroxidase. The dypB gene is cotranscribed with a gene encoding an encapsulin protein, which has been shown in Thermotoga maritima to assemble to form a 60‐subunit nanocompartment, and DypB contains a C‐terminal sequence motif that is thought to target the protein to the encapsulin nanocompartment. R. jostii RHA1 encapsulin protein was overexpressed in R. jostii RHA1, and purified as a high‐Mr assembly (Mr > 106). The purified nanocompartment could be disassembled to form a low‐Mr species by treatment at pH 3.0, and reassembled to form an assembly of similar size and shape, as assessed by dynamic light scattering. Recombinant DypB could be assembled in vitro with monomeric encapsulin to form an assembly of similar size to the encapsulin‐only nanocompartment, as assessed by gel filtration. The assembled complex showed enhanced lignin degradation activity per milligram of DypB present as compared with native DypB, as determined with a nitrated lignin UV–visible assay method. The measured stoichiometry of 8.6 μmol encapsulin/μmol DypB in the complex was similar to the value of 10 predicted from the crystal structure.
Structured digital abstract
encapsulin and encapsulin bind by blue native page ( View interaction)
encapsulin and encapsulin bind by dynamic light scattering ( View interaction)
A Dyp-type peroxidase enzyme from thermophilic cellulose degrader Thermobifida fusca (TfuDyP) was investigated for catalytic ability towards lignin oxidation. TfuDyP was characterised kinetically against a range of phenolic substrates, and a compound I reaction intermediate was observed via pre-steady state kinetic analysis at max 404 nm. TfuDyP showed reactivity towards Kraft lignin, and was found to oxidise a -aryl ether lignin model compound, forming an oxidised dimer. A crystal structure of TfuDyP was determined, to 1.8Å resolution, which was found to contain a diatomic oxygen ligand bound to the heme centre, positioned close to active site residues Asp-203 and Arg-315. The structure contains two channels providing access to the heme cofactor for organic substrates and hydrogen peroxide. Site-directed mutant D203A showed no activity towards phenolic substrates, but reduced activity towards ABTS, while mutant R315Q showed no activity towards phenolic substrates, nor ABTS.
The study demonstrates the feasibility of using an in situ bacterial treatment to enhance gas release and resource recovery from landfill soil containing lignocellulosic waste. This article is protected by copyright. All rights reserved.
Abstract. A significant problem in the oxidative breakdown of lignin is the tendency of phenolic radical fragments to re-polymerise to form higher molecular weight species. In this paper we identify an extracellular flavin-dependent dehydrolipoamide dehydrogenase from Thermobifida fusca that prevents oxidative dimerization of a dimeric lignin model compound, which could be used as an accessory enzyme for lignin depolymerisation.
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