The chemical logic of enzymatic lignin degradation

Archaeal tyrosinase as a versatile biocatalyst for lignin-derived aromatic compounds valorization

Biomass-derived aromatic compounds, including those obtained from lignin (which is the most abundant aromatic biopolymer on Earth), are valuable for sustainable chemical production. Various lignin-degrading approaches have been developed to cleave recalcitrant bonds. The incorporation of biocatalysts that operate under environmentally friendly and mild conditions with high substrate specificity is considered one of the emerging strategies for lignin valorization. In this study, an archaeal tyrosinase (Tyr-CNK), derived from the marine archaeon Candidatus nitrosopumilus koreensis, is characterized as a versatile biocatalyst for lignin biodegradation and valorization, based on kinetic studies, protein structure determination, and analysis. Notably, the extremely shallow active site pocket and the unique noncanonical caddy domain, which facilitate efficient copper incorporation without obstructing the active site, collectively empower Tyr-CNK with remarkable catalytic efficiency toward various lignin model compounds, such as p-coumaric acid, 4-phenoxyphenol, 4-(benzyloxy)phenol, and guaiacyl glycerol-β-guaiacyl ether. Together with molecular docking simulations, these catalytic and structural features indicate that Tyr-CNK serves as an efficient biocatalyst for the hydroxylation and oxidative degradation of lignin-derived phenolic compounds. Given its versatility, efficiency, and structural uniqueness, Tyr-CNK demonstrates great promise for expanding the catalytic repertoire for biomass conversions and offering new opportunities in sustainable biocatalysis, enzymatic and microbial biodegradation and biomass valorization.

Lignin-Degrading Enzymes and the Potential of Pseudomonas putida as a Cell Factory for Lignin Degradation and Valorization

Efficient utilization of lignin, a complex polymer in plant cell walls, is one of the key strategies for developing a green and sustainable bioeconomy. However, bioconversion of lignin poses a significant challenge due to its recalcitrant nature. Microorganisms, particularly fungi and bacteria, play a crucial role in lignin biodegradation, using various enzymatic pathways. Among bacteria, Pseudomonas putida is considered a promising host for lignin degradation and valorization, due to its robust and flexible metabolism and its tolerance to many noxious and toxic compounds. This review explores the various mechanisms of lignin breakdown by microorganisms, with a focus on P. putida's metabolic versatility and genetic engineering potential. By leveraging advanced genetic tools and metabolic pathway optimization, P. putida can be engineered to efficiently convert lignin into valuable bioproducts, offering sustainable solutions for lignin valorization in industrial applications.

Structural and Biochemical Insights into Lignin-Oxidizing Activity of Bacterial Peroxidases against Soluble Substrates and Kraft Lignin

Great interest has recently been drawn to the production of value-added products from lignin; however, its recalcitrance and high chemical complexity have made this challenging. Dye-decolorizing peroxidases and catalase-peroxidases are among the enzymes that are recognized to play important roles in environmental lignin oxidation. However, bacterial lignin-oxidizing enzymes remain less characterized compared to related proteins from fungi. In this study, screening of 18 purified bacterial peroxidases against the general chromogenic substrate 2,2'-azinobis(3-ethylbenzthiazoline-6-sulfonate) (ABTS) revealed the presence of peroxidase activity in all proteins. Agarose plate-based screens with kraft lignin identified detectable and high lignin oxidation activity in 15 purified proteins. Crystal structures were determined for the DyP-type peroxidases FC2591 from Frankia casuarinae, PF3257 from Pseudomonas fluorescens, and PR9465 from Pseudomonas rhizosphaerae. The structures revealed the presence of hemes with bound oxygens coordinated by conserved His, Arg, and Asp residues as well as three molecular tunnels connecting the heme with the protein surface. Structure-based site-directed mutagenesis of FC2591 identified at least five active site residues as essential for oxidase activity against both ABTS and lignin, whereas the S370A mutant protein showed a three- to 4-fold activity increase with both substrates. HPLC analysis of reaction products of the wild-type FC2591 and S370A mutant proteins with the model lignin dimer guaiacylglycerol-β-guaiacyl ether and kraft lignin revealed the formation of products consistent with the radical coupling of the reaction intermediates. Thus, this study identified novel bacterial heme peroxidases with lignin oxidation activity and provided further insights into our understanding of these enzymes.

Assembly of a lignocellulose-degrading synthetic community from the strong-flavor Daqu by a stepwise method

The lignocellulose in Daqu plays an important role during the Baijiu fermentation, such as providing energy for microbial metabolism and precursors for flavor compounds. However, due to the complexity of the Daqu microbial community and the fermentation environment, the regulation of lignocellulose degradation efficiency is limited. In such cases, artificial intervention can be achieved through the application of synthetic communities. Here, we studied the structure of the lignocellulose-degrading microbial communities in Daqu. Based on the characteristics of lignocellulose composition, we developed three high-throughput screening methods and used a stepwise assembly approach to construct a synthetic community composed of Bacillus stercori, Bacillus paramycoides, Klebsiella pneumoniae, and Cyberlindnera fabianii. After fermentation, 54.71 % of the bran was degraded and 11 substances were uniquely produced. 4-vinylguaiacol and 2-ethyl-3,5(6)-dimethylpyrazine were considered to be the key aroma compounds of the synthetic community. This synthetic community offers a new approach to control Daqu fermentation.

Analyze the impact of lignin depolymerization process and its products on humic substance formation

This study aimed to identify types of lignin depolymerization products (LDP) and their role in humic substances (HS) formation, and little research has revealed which LDP could participate into HS formation during composting. Therefore, rice straw (RS), peanut straw (PS) and pine needles (PN) were selected for their different lignin structures to qualitatively and quantitative analyze LDP firstly. Qualitative results indicated that RS, PS and PN mainly produced LDP with G-type, common group and dimer structure. While quantitative results showed that RS and PS were more prone to degradation, and PN mainly promoted the formation of HS.During the lignin humification, Proteobacteria, Firmicutes, Actinobacteria-dominated microorganisms played a major role in facilitating monomeric substances into HS formation. This study comprehensively analyzed the process of depolymerization and humification of different kinds of lignin. It provides guidance for the resource utilization of lignin and the efficient treatment of agricultural organic waste.

Sustainable production of aromatic chemicals from lignin using enzymes and engineered microbes

Lignin is an aromatic biopolymer found in plant cell walls and is the most abundant source of renewable aromatic carbon in the biosphere. Hence there is considerable interest in the conversion of lignin, either derived from agricultural waste or produced as a byproduct of pulp/paper manufacture, into high-value chemicals. Although lignin is rather inert, due to the presence of ether C-O and C-C linkages, several microbes are able to degrade lignin. This review will introduce these microbes and the enzymes that they use to degrade lignin and will describe recent studies on metabolic engineering that can generate high-value chemicals from lignin bioconversion. Catabolic pathways for degradation of lignin fragments will be introduced, and case studies where these pathways have been engineered by gene knockout/insertion to generate bioproducts that are of interest as monomers for bioplastic synthesis or aroma chemicals will be described. Life cycle analysis of lignin bioconversion processes is discussed.

Enhancing Manganese Peroxidase: Innovations in Genetic Modification, Screening Processes, and Sustainable Agricultural Applications

Manganese peroxidase (MnP), a vital extracellular enzyme for the degradation of lignin and other organic pollutants, has demonstrated immense potential for agricultural and environmental applications, including straw pretreatment, feed fermentation, mycotoxin degradation, and water treatment. However, current research remains in its exploratory phase, with naturally sourced MnP unable to meet industrial-scale demands and no mature commercial enzyme preparations available on the market. This comprehensive review innovatively constructs a framework for MnP research, probing into its molecular conformation and catalytic principles, while providing an overview of the advancements in high-throughput screening and In silco designing strategies. Specifically, this review focuses on the practical applications of MnP in sustainable agriculture, elaborating on its potential and challenges in straw resource utilization, efficient feed fermentation, mycotoxin control, and water quality improvement. Furthermore, this review summarizes the recent achievements in optimizing MnP activity through enzyme engineering techniques and discuss customized mutation strategies tailored to specific agricultural and environmental requirements, thereby laying a solid theoretical foundation and scientific basis for the industrial production and commercialization of MnP.

Polyphenol Oxidase Activity on Guaiacyl and Syringyl Lignin Units

The natural heterogeneity of guaiacyl (G) and syringyl (S) compounds resulting from lignin processing hampers their direct use as plant-based chemicals and materials. Herein, we explore six short polyphenol oxidases (PPOs) from lignocellulose-degrading ascomycetes for their capacity to react with G-type and S-type phenolic compounds. All six PPOs catalyze the ortho-hydroxylation of G-type compounds (guaiacol, vanillic acid, and ferulic acid), forming the corresponding methoxy-ortho-diphenols. Remarkably, a subset of these PPOs is also active towards S-compounds (syringol, syringic acid, and sinapic acid) resulting in identical methoxy-ortho-diphenols. Assays with 18O2 demonstrate that these PPOs in particular catalyze ortho-hydroxylation and ortho-demethoxylation of S-compounds and generate methanol as a co-product. Oxidative (ortho-) demethoxylation of S-compounds is a novel reaction for PPOs, which we propose occurs by a distinct reaction mechanism as compared to aryl-O-demethylases. We further show that addition of a reducing agent can steer the PPO reaction to form methoxy-ortho-diphenols from both G- and S-type substrates rather than reactive quinones that lead to unfavorable polymerization. Application of PPOs opens for new routes to reduce the heterogeneity and methoxylation degree of mixtures of G and S lignin-derived compounds.

Modeling the Production Process of Lignin Nanoparticles Through Anti-Solvent Precipitation for Properties Prediction

Global warming has recently intensified research interest in renewable polymer chemistry, with significant attention directed towards lignin nanoparticle (LNP) synthesis. Despite progress, LNP industrial application faces challenges: (1) reliance on kraft lignin from declining raw biomass processes, (2) sulfur-rich and condensed lignin use, (3) complex lignin macroparticles to LNP conversion, using harmful and toxic solvents, and, above all, (4) lack of control over the LNP production process (i.e., anti-solvent precipitation parameters), resulting in excessive variability in properties. In this work, eco-friendly LNPs with tailored properties were produced from a semi-industrial organosolv process by studying anti-solvent precipitation variables. Using first a parametric and then a Fractional Factorial Design, predictions of LNP sizes and size distribution, as well as zeta-potential, were derived from a model over beech by-products organosolv lignin, depending on initial lignin concentration (x1, g/L), solvent flow rate (x2, mL/min), antisolvent composition (x3, H2O/EtOH v/v), antisolvent ratio (x4, solvent/antisolvent v/v), and antisolvent stirring speed (x5, rpm). This novel chemical engineering approach holds promise for overcoming the challenges inherent in industrial lignin nanoparticle production, thereby accelerating the valorization of lignin biopolymers for high value-added applications such as cosmetics (sunscreen or emulsion) and medicine (encapsulation, nanocarriers), a process currently constrained by significant limitations.

Accessing monomers from lignin through carbon-carbon bond cleavage

Lignin, the heterogeneous aromatic macromolecule found in the cell walls of vascular plants, is an abundant feedstock for the production of biochemicals and biofuels. Many valorization schemes rely on lignin depolymerization, with decades of research focused on accessing monomers through C-O bond cleavage, given the abundance of β-O-4 bonds in lignin and the large number of available C-O bond cleavage strategies. Monomer yields are, however, invariably lower than desired, owing to the presence of recalcitrant C-C bonds whose selective cleavage remains a major challenge in catalysis. In this Review, we highlight lignin C-C cleavage reactions, including those of linkages arising from biosynthesis (β-1, β-5, β-β and 5-5) and industrial processing (5-CH2-5 and α-5). We examine multiple approaches to C-C cleavage, including homogeneous and heterogeneous catalysis, photocatalysis and biocatalysis, to identify promising strategies for further research and provide guidelines for definitive measurements of lignin C-C bond cleavage.

Lignin valorization through the oxidative activity of β-etherases: Recent advances and perspectives

The increasing interest in lignin, a complex and abundant biopolymer, stems from its ability to produce environmentally beneficial biobased products. β-Etherases play a crucial role by breaking down the β-aryl ether bonds in lignin. This comprehensive review covers the latest advancements in β-etherase-mediated lignin valorization, focusing on substrate selectivity, enzymatic oxidative activity, and engineering methods. Research on the microbial origin, protein modification, and molecular structure determination of β-etherases has improved our understanding of their effectiveness. Furthermore, the use of these enzymes in biorefinery processes is promising for enhancing lignin breakdown and creating more valuable products. The review also discusses the challenges and future potential of β-etherases in advancing lignin valorization for biorefinery applications that are economically viable and environmentally sustainable.

A comprehensive review on biological funnel mechanism in lignin valorization: Pathways and enzyme dynamics

Lignin, a significant byproduct of the paper and pulp industry, is attracting interest due to its potential utilization in biomaterial-based sectors and biofuel production. Investigating biological methods for converting lignin into valuable products is crucial for effective utilization and has recently gained growing attention. Several microorganisms effectively decomposed low molecular weight lignins, transforming them into intermediate compounds via upper and lower metabolic pathways. This review focuses on assessing bacterial metabolic pathways involved in the breakdown of lignin into aromatic compounds and their subsequent utilization by different bacteria through various metabolic pathways. Understanding these pathways is essential for developing efficient synthetic metabolic systems to valorize lignin and obtain valuable industrial aromatic chemicals. The concept of "biological funneling," which involves examining key enzymes, their interactions, and the complex metabolic pathways associated with lignin conversion, is crucial in lignin valorization. By manipulating lignin metabolic pathways and utilizing biological routes, many aromatic compounds can be synthesized within cellular factories. Although there is insufficient evidence regarding the complete metabolism of polyaromatic hydrocarbons by particular microorganisms, understanding lignin-degrading enzymes, regulatory mechanisms, and interactions among various enzyme systems is essential for optimizing lignin valorization. This review highlights recent advancements in lignin valorization, bio-funneling, multi-omics, and analytical characterization approaches for aromatic utilization. It provides up-to-date information and insights into the latest research findings and technological innovations. The review offers valuable insights into the future potential of biological routes for lignin valorization.

Unveiling the kinetic versatility of aryl-alcohol oxidases with different electron acceptors

Introduction: Aryl-alcohol oxidase (AAO) shows a pronounced duality as oxidase and dehydrogenase similar to that described for other glucose-methanol-choline (GMC) oxidase/dehydrogenase superfamily proteins involved in lignocellulose decomposition. In this work, we detail the overall mechanism of AAOs from Pleurotus eryngii and Bjerkandera adusta for catalyzing the oxidation of natural aryl-alcohol substrates using either oxygen or quinones as electron acceptors and describe the crystallographic structure of AAO from B. adusta in complex with a product analogue. Methods: Kinetic studies with 4-methoxybenzyl and 3-chloro-4- methoxybenzyl alcohols, including both transient-state and steady-state analyses, along with interaction studies, provide insight into the oxidase and dehydrogenase mechanisms of these enzymes. Moreover, the resolution of the crystal structure of AAO from B. adusta allowed us to compare their overall folding and the structure of the active sites of both AAOs in relation to their activities. Results and Discussion: Although both enzymes show similar mechanistic properties, notable differences are highlighted in this study. In B. adusta, the AAO oxidase activity is limited by the reoxidation of the flavin, while in P. eryngii the slower step takes place during the reductive half-reaction, which determines the overall reaction rate. By contrast, dehydrogenase activity in both enzymes, irrespective of the alcohol participating in the reaction, is limited by the hydroquinone release from the active site. Despite these differences, both AAOs are more efficient as dehydrogenases, supporting the physiological role of this activity in lignocellulosic decay. This dual activity would allow these enzymes to adapt to different environments based on the available electron acceptors.

Turning waste into treasure: A new direction for low-cost production of lipid chemicals from Thraustochytrids

Thraustochytrids are marine microorganisms known for their fast growth and ability to store lipids, making them useful for producing polyunsaturated fatty acids (PUFAs), biodiesel, squalene, and carotenoids. However, the high cost of production, mainly due to expensive fermentation components, limits their wider use. A significant challenge in this context is the need to balance production costs with the value of the end products. This review focuses on integrating the efficient utilization of waste with Thraustochytrids fermentation, including the economic substitution of carbon sources, nitrogen sources, and fermentation water. This approach aligns with the 3Rs principles (reduction, recycling, and reuse). Furthermore, it emphasizes the role of Thraustochytrids in converting waste into lipid chemicals and promoting sustainable circular production models. The aim of this review is to emphasize the value of Thraustochytrids in converting waste into treasure, providing precise cost reduction strategies for future commercial production.

Machine learning-aided engineering of a cytochrome P450 for optimal bioconversion of lignin fragments

Using machine learning, molecular dynamics simulations, and density functional theory calculations we gain insight into the selectivity patterns of substrate activation by the cytochromes P450. In nature, the reactions catalyzed by the P450s lead to the biodegradation of xenobiotics, but recent work has shown that fungi utilize P450s for the activation of lignin fragments, such as monomer and dimer units. These fragments often are the building blocks of valuable materials, including drug molecules and fragrances, hence a highly selective biocatalyst that can produce these compounds in good yield with high selectivity would be an important step in biotechnology. In this work a detailed computational study is reported on two reaction channels of two P450 isozymes, namely the O-deethylation of guaethol by CYP255A and the O-demethylation versus aromatic hydroxylation of p-anisic acid by CYP199A4. The studies show that the second-coordination sphere plays a major role in substrate binding and positioning, heme access, and in the selectivity patterns. Moreover, the local environment affects the kinetics of the reaction through lowering or raising barrier heights. Furthermore, we predict a site-selective mutation for highly specific reaction channels for CYP199A4.