Systems metabolic engineering upgrades Corynebacterium glutamicum to high-efficiency cis, cis-muconic acid production from lignin-based aromatics.

Lignin displays a highly challenging renewable. To date, massive amounts of lignin, generated in lignocellulosic processing facilities, are for the most part merely burned due to lacking value-added alternatives. Aromatic lignin monomers of recognized relevance are in particular vanillin, and to a lesser extent vanillate, because they are accessible at high yield from softwood-lignin using industrially operated alkaline oxidative depolymerization. Here, we metabolically engineered C. glutamicum towards cis, cis-muconate (MA) production from these key aromatics. Starting from the previously created catechol-based producer C. glutamicum MA-2, systems metabolic engineering first discovered an unspecific aromatic aldehyde reductase that formed aromatic alcohols from vanillin, protocatechualdehyde, and p- hydroxybenzaldehyde, and was responsible for the conversion up to 57% of vanillin into vanillyl alcohol. The alcohol was not re-consumed by the microbe later, posing a strong drawback on the producer. The identification and subsequent elimination of the encoding fudC gene completely abolished vanillyl alcohol formation. Second, the initially weak flux through the native vanillin and vanillate metabolism was enhanced up to 2.9-fold by implementing synthetic pathway modules. Third, the most efficient protocatechuate decarboxylase AroY for conversion of the midstream pathway intermediate protocatechuate into catechol was identified out of several variants in native and codon optimized form and expressed together with the respective helper proteins. Fourth, the streamlined modules were all genomically combined which yielded the final strain MA-9. MA-9 produced bio-based MA from vanillin, vanillate, and seven structurally related aromatics at maximum selectivity. In addition, MA production from softwood-based vanillin, obtained through alkaline depolymerization, was demonstrated.

Protocatechuic acid production from lignin-associated phenolics.

Biobased chemicals are gaining popularity and market in attempts to mitigate the deteriorating environmental and sustainability issues. Components of renewable agricultural and forest biomass residues are projected to serve as abundant precursors to synthesis of expanding range of products. Agroindustrial wastes comprises of several phenolic compounds associated with lignin via ether linkages such as ferulic acid, p-coumaric, syringic acid and vanillin. These aromatic chemicals have myriad industrial applications. In this study, p-coumaric acid and ferulic acid were found to be two major components in corn bran derived lignin hydrolysate. Engineered Pseudomonas putida KT2440 was constructed and found to convert p-coumaric acid and vanillic acid to protocatechuic acid in >90% and >50% yields, respectively. Engineering the strain included deletion of the gene encoding protocatechuate 3,4-dioxygenase, and overexpression of vanillate-O-demethylase gene from Acinetobacter sp. ADP1.

Biotransformation of corn bran derived ferulic acid to vanillic acid using engineered Pseudomonas putida KT2440.

Ferulic acid is a fraction of the phenolics present in cereals such as rice and corn as a component of the bran. Substantial amounts of waste bran are generated by the grain processing industry and this can be valorized via extraction, purification and conversion of phenolics to value added chemical products. Alkaline alcohol based extracted and purified ferulic acid from corn bran was converted to vanillic acid using engineered Pseudomonas putida KT2440. The strain was engineered by rendering the vanAB gene nonfunctional and obtaining the mutant defective in vanillic acid metabolism. Biotransformation of ferulic acid using resting Pseudomonas putida KT2440 mutant cells resulted in more than 95 ± 1.4% molar yield from standard ferulic acid; while the corn bran derived ferulic acid gave 87 ± 0.38% molar yield. With fermentation time of less than 24 h the mutant becomes a promising candidate for the stable biosynthesis of vanillic acid at industrial scale.

Identification of the protocatechuate transporter gene in Sphingobium sp. strain SYK-6 and effects of overexpression on production of a value-added metabolite.

Sphingobium sp. strain SYK-6 expresses the best characterized catabolic systems for lignin-derived aromatic compounds. However, the uptake systems for these aromatics remain unknown. In this study, we identified and characterized the protocatechuate (PCA) transporter gene SLG_12880 (pcaK) in SYK-6. Sequence comparisons revealed that PcaK belongs to the aromatic acid/H+ symporter family of major facilitator superfamily transporters. Further, pcaK was highly conserved among Sphingomonadales possessing catabolic genes for vanillate and PCA. The growth of an SYK-6 pcaK mutant was significantly delayed on PCA medium and PCA uptake rate was only 8% of wild type. In addition, vanillate uptake rate was 78% of wild type, although the pcaK mutant grew as well as the wild type on vanillate. When pcaK was expressed in Sphingobium japonicum UT26S, the transformant acquired the capacity to uptake both PCA and vanillate. These results indicate that pcaK is responsible for the major proportion of PCA uptake and a minor fraction of vanillate uptake in SYK-6. The productivity of 2-pyrone-4,6-dicarboxylate (PDC), a building block of functional polymers, was evaluated using a PDC hydrolase SYK-6 mutant harboring a pcaK plasmid. The mutant exhibited 1.27-fold greater PCA conversion and 1.24-fold greater PDC production compared to the control strain, suggesting that enhanced expression of transporter genes for lignin-derived aromatics can be used to increase the production of value-added metabolites.

Methyl vanillate for inhibiting the proliferation, migration, and epithelial-mesenchymal transition of ovarian cancer cells via the ZEB2/Snail signaling pathway.

Background: Globally, ovarian cancer is the leading cause of female reproductive-related death, with a 5-year survival rate below 50%. Conventional therapies, such as cancer cell reduction and paclitaxel chemotherapy, have strong toxicity and are prone to drug resistance. Thus, the development of alternatives for the treatment of ovarian cancer is urgently needed. Methyl vanillate is a principal component of Hovenia dulcis Thunberg. It is known that several cancer cells are inhibited by methyl vanillate; however, whether methyl vanillate can inhibit the proliferation and migration of ovarian cancer cells still needs to be further studied. Methods: In this study, cell counting kit 8 (CCK8) was used to examine the effects of methyl vanillic acid on the proliferation of SKOV3 cell lines and human ovarian surface epithelial cell (HOSEpiC) lines. Wound healing and transwell assays were used to determine the effect of methyl vanillate on cell migration. The expression of epithelial-mesenchymal transition (EMT) marker proteins (E-cadherin and vimentin), transcription factors (Snail and ZEB2), and skeletal proteins (F-actin) were evaluated with Western blotting. F-actin was detected by immunofluorescence assay. Results: The proliferation and migration of SKOV3 cells were dose-dependently inhibited by methyl vanillate, but HOSEpiC cells were not inhibited by low concentrations of methyl vanillate. Western blotting analyses revealed a significant decrease in the expression of vimentin and a significant increase in the expression of E-cadherin in SKOV3 cells treated with methyl vanillate. This finding indicated that EMT inhibition was induced by the vanillate. Furthermore, methyl vanillate inhibited the expression of transcription factors (Snail and ZEB2) in SKOV3 cells as well as cytoskeletal F-actin assembly. Conclusions: Methyl vanillate plays an important role in inhibiting EMT and cell proliferation and the migration of ovarian cancer, likely via the inhibition of the ZEB2/Snail signaling pathway. Consequently, methyl vanillate may be a promising therapeutic drug for ovarian cancer.

Successful selective production of vanillic acid from depolymerized sulfite lignin and its application to poly(ethylene vanillate) synthesis.

Towards lignin upgrading, vanillic acid (VA), a lignin-derived guaiacyl compound, was produced from sulfite lignin for successfully synthesizing poly(ethylene vanillate), an aromatic polymer. The engineered Sphingobium sp. SYK-6-based strain in which the genes responsible for VA/3-O-methyl gallic acid O-demethylase and syringic acid O-demethylase were disrupted was able to produce vanillic acid (VA) from the mixture consisting of acetovanillone, vanillin, VA, and other low-molecular-weight aromatics obtained by Cu(OH)2-catalyzed alkaline depolymerization of sulfite lignin and membrane fractionation. From the bio-based VA, methyl-4-(2-hydroxyethoxy)-3-methoxybenzoate was synthesized via methylesterification, hydroxyethylation, and distillation, and then it was subjected to polymerization catalyzed by titanium tetraisopropoxide. The molecular weight of the obtained poly(ethylene vanillate) was evaluated to be Mw = 13,000 (Mw/Mn = 1.99) and its melting point was 261 °C. The present work proved that poly(ethylene vanillate) is able to be synthesized using VA produced from lignin for the first time.

[Sevoflurane alleviates ventilator-induced lung injury in rats by down-regulating the TRPV4/C-PLA2 signaling pathway].

OBJECTIVE: To explore the mechanism underlying the protective effect of sevoflurane against ventilator-induced lung injury (VILI). METHODS: Thirty-two SD rats were randomized into mechanical ventilation (MV) group, MV+sevoflurane group (MS group), MV+sevoflurane+transient receptor potential vanillate subtype 4 (TRPV4) agonist group (MST group) and MV+ sevoflurane + vehicle group (MSV group). Arachidonic acid (AA) in the lung tissues was quantified with ELISA. TRPV4, cytoplasmic phospholipase A2 (C-PLA2) and myosin light chain kinase (MLCK) protein expressions were detected by Western blotting. Lung injury in the rats was evaluated by assessing MLCK protein expression level, pulmonary permeability index, lung wet/dry ratio, leukocyte count in the bronchoalveolar lavage fluid (BALF), myeloperoxidase content in lung tissue, and histological score of the lungs. RESULTS: The rats in MV group showed significantly increased TRPV4 and C-PLA2 expression levels in the lung tissues with increased lung permeability and obvious lung inflammation compared with those in the other 3 groups (P < 0.05). No significant differences were found in the parameters associated with lung injuries between MS group and MSV group. Compared with those in MST group, the rats in MS group and MSV group showed significantly reduced AA production and TRPV4 and C-PLA2 expressions in the lungs (P < 0.05) with alleviated lung hyper-permeability and inflammation (P < 0.05). CONCLUSION: Sevoflurane protects against VILI in rats by down-regulating the TRPV4/C-PLA2 signaling pathway.

The dimerization of methyl vanillate improves its effect against breast cancer cells via pro-oxidant effect.

Phenolic phytochemicals are a group of organic compounds with potent antioxidant features but can also act as powerful pro-oxidants. These characteristics are effective in reducing metastatic potential in cancer cells, and this effect has been associated with reactive oxygen species (ROS). Methyl vanillate (MV) and its dimer, methyl divanillate (DMV), are potent antioxidants. In the present study, we investigated the effects of MV and DMV on breast cancer cell lines MCF-7 and MDA-MB-231 and compared the results using the non-tumor cell line HB4a. Our results indicated that the compounds performed a pro-oxidant action, increasing the generation of ROS. DMV decreased the viability cell, showing a higher apoptotic effect and inhibition of proliferation than MV on both cell lines, with significant differences between groups (p < 0.05). Some modulation of NOX4, NOX5, and DUOX were observed, but the results did not correlate with the intracellular production of ROS. The dimer showed more effectivity and pro-oxidant effect than MV, impacting cell line MCF-7 in higher extension than MDA-MB-231. In conclusion, and corroborating with reported works, the dimerization of natural phenolic compounds was associated with improved beneficial biological effects as a potential cytotoxic agent to tumor cells.

Prediction of the Glass Transition Temperature in Polyethylene Terephthalate/Polyethylene Vanillate (PET/PEV) Blends: A Molecular Dynamics Study.

Polyethylene terephthalate (PET) is one of the most common polymers used in industries. However, its accumulation in the environment is a health risk to humans and animals. Polyethylene vanillate (PEV) is a bio-based material with topological, mechanical, and thermal properties similar to PET, allowing it to be used as a PET replacement or blending material. This study aimed to investigate some structural and dynamical properties as well as the estimated glass transition temperature (Tg) of PET/PEV blended polymers by molecular dynamics (MD) simulations with an all-atom force field model. Four blended systems of PET/PEV with different composition ratios (4/1, 3/2, 2/3, and 1/4) were investigated and compared to the parent polymers, PET and PEV. The results show that the polymers with all blended ratios have Tg values around 344-347 K, which are not significantly different from each other and are close to the Tg of PET at 345 K. Among all the ratios, the 3/2 blended polymer showed the highest number of contacting atoms and possible hydrogen bonds between the two chain types. Moreover, the radial distribution results suggested the proper interactions in this system, which indicates that this is the most suitable ratio model for further experimental studies of the PET/PEV polymer blend.

All-Atom Molecular Dynamics Simulations on a Single Chain of PET and PEV Polymers.

Polyethylene vanillic (PEV), a bio-based material, has mechanical and thermal properties similar to polyethylene terephthalate (PET), the most common polymer used in industries. The present study aimed to investigate and compare their structural dynamics and physical data using a computational approach. The simple model of a single-chain polymer containing 100 repeating units was performed by all-atom molecular dynamics (MD) simulations with refined OPLS-AA force field parameters. As a result, the flexibility of the PEV structure was greater than that of PET. PET and PEV polymers had the predicted glass transition temperature Tg values of approximately 345 K and 353 K, respectively. PEV showed a slightly higher Tg than PET, consistent with current experimental evidence.

Water Vapor Sorption and Diffusivity in Bio-Based Poly(Ethylene Vanillate)-PEV.

The dynamic and equilibrium water vapor sorption properties of amorphous and highly crystalline poly(ethylene vanillate) (PEV) films were determined via gravimetric analysis, at 20 °C, over a wide range of relative humidity (0-95% RH). At low RH%, the dynamic of the sorption process obeys Fick's law while at higher relative humidity it is characterized by a drift ascribable to non-Fickian relaxations. The non-Fickian relaxations, which are responsible for the incorporation of additional water, are correlated with the upturn of the sorption isotherms and simultaneously the hysteresis recorded between sorption and desorption cycles. The sorption isotherms of amorphous and highly crystalline PEV are arranged in the same concentration range of that of PET proving the similarity of the two polyesters. Water diffusion coefficients, whose determination from individual kinetic sorption/desorption curves required treatment with the Barens-Hopfenberg model, were demonstrated to be ≈ 10× higher for amorphous PEV compared to amorphous PET. Such a difference originates from the enhanced segmental flexibility of PEV chains.

Bidirectional differentiation of BMSCs induced by a biomimetic procallus based on a gelatin-reduced graphene oxide reinforced hydrogel for rapid bone regeneration.

Developmental engineering strategy needs the biomimetic composites that can integrate the progenitor cells, biomaterial matrices and bioactive signals to mimic the natural bone healing process for faster healing and reconstruction of segmental bone defects. We prepared the gelatin-reduced graphene oxide (GOG) and constructed the composites that mimicked the procallus by combining the GOG with the photo-crosslinked gelatin hydrogel. The biological effects of the GOG-reinforced composites could induce the bi-differentiation of bone marrow stromal cells (BMSCs) for rapid bone repair. The proper ratio of GOG in the composites regulated the composites' mechanical properties to a suitable range for the adhesion and proliferation of BMSCs. Besides, the GOG-mediated bidirectional differentiation of BMSCs, including osteogenesis and angiogenesis, could be activated through Erk1/2 and AKT pathway. The methyl vanillate (MV) delivered by GOG also contributed to the bioactive signals of the biomimetic procallus through priming the osteogenesis of BMSCs. During the repair of the calvarial defect in vivo, the initial hypoxic condition due to GOG in the composites gradually transformed into a well-vasculature robust situation with the bi-differentiation of BMSCs, which mimicked the process of bone healing resulting in the rapid bone regeneration. As an inorganic constituent, GOG reinforced the organic photo-crosslinked gelatin hydrogel to form a double-phase biomimetic procallus, which provided the porous extracellular matrix microenvironment and bioactive signals for the bi-directional differentiation of BMSCs. These show a promised application of the bio-reduced graphene oxide in biomedicine with a developmental engineering strategy.

A thermostable glycosyltransferase from Paenibacillus polymyxa NJPI29: recombinant expression, characterization, and application in synthesis of glycosides.

Glycosylation is a prominent biological mechanism, affecting the structural and functional diversity of many natural products. In this study, a novel thermostable uridine diphosphate-dependent glycosyltransferase gene PpGT1 was cloned from Paenibacillus polymyxa NJPI29 and recombinantly expressed in B. subtilis WB600. The purified PpGT1 had a molecular weight of 45 kDa, as estimated using SDS-PAGE. The PpGT1 could catalyze the glycosylation of vanillic acid, methyl vanillate, caffeic acid, cinnamic alcohol, and ferulic acid. Moreover, PpGT1 possessed good thermostability and retained 80% of its original activity even after 12 h of incubation at 45 °C. In addition, PpGT1 remained stable within a neutral to alkaline pH range as well as in the presence of metal ions. The synthesis of methyl vanillate 4-O-ß-D-glucoside by purified PpGT1 reached a yield 3.58 mM in a system with pH 8.0, 45 °C, 12 mM UDP-Glc, and 4 mM methyl vanillate. 3D-structure-based amino acid sequence alignments revealed that the catalytic residues and C-terminated PSPG motif were conserved. These unusual properties indicated that PpGT1 is a candidate UGT for valuable natural product industrial applications. SUPPLEMENTARY INFORMATION: The online version contains supplementary material available at 10.1007/s13205-021-02855-z.

Comparative Dose-Response Analysis of Inducible Promoters in Cyanobacteria.

Design and implementation of synthetic biological circuits highly depends on well-characterized, robust promoters with predictable input-output responses. While great progress has been made with heterotrophic model organisms such as Escherichia coli, the available variety of tunable promoter parts for phototrophic cyanobacteria is still limited. Commonly used synthetic and semisynthetic promoters show weak dynamic ranges or no regulation at all in cyanobacterial models. Well-controlled alternatives such as native metal-responsive promoters, however, pose the problems of inducer toxicity and lacking orthogonality. Here, we present the comparative assessment of dose-response functions of four different inducible promoter systems in the model cyanobacterium Synechocystis sp. PCC 6803. Using the novel bimodular reporter plasmid pSHDY, dose-response dynamics of the re-established vanillate-inducible promoter PvanCC was compared to the previously described rhamnose-inducible Prha, the anhydrotetracycline-inducible PL03, and the Co2+-inducible PcoaT. We estimate individual advantages and disadvantages regarding dynamic range and strength of each promoter, also in comparison with well-established constitutive systems. We observed a delicate balance between transcription factor toxicity and sufficient expression to obtain a dose-dependent response to the inducer. In summary, we expand the current understanding and employability of inducible promoters in cyanobacteria, facilitating the scalability and robustness of synthetic regulatory network designs and of complex metabolic pathway engineering strategies.

Development of a Vanillate Biosensor for the Vanillin Biosynthesis Pathway in E. coli.

The engineered de novo vanillin biosynthesis pathway constructed in Escherichia coli is industrially relevant but limited by the reaction catalyzed by catechol O-methyltransferase, which is intended to catalyze the conversion of protocatechuate to vanillate. To identify alternative O-methyltransferases, we constructed a vanillate sensor based on the Caulobacter crescentus VanR-VanO system. Using an E. coli promoter library, we achieved greater than 14-fold dynamic range in our best rationally constructed sensor. We found that this construct and an evolved variant demonstrate remarkable substrate selectivity, exhibiting no detectable response to the regioisomer byproduct isovanillate and minimal response to structurally similar pathway intermediates. We then harnessed the evolved biosensor to conduct rapid bioprospecting of natural catechol O-methyltransferases and identified three previously uncharacterized but active O-methyltransferases. Collectively, these efforts enrich our knowledge of how biosensing can aid metabolic engineering and constitute the foundation for future improvements in vanillin pathway productivity.

Synergistic Osteogenesis of Biocompatible Reduced Graphene Oxide with Methyl Vanillate in BMSCs.

Methyl vanillate (MV), a recently characterized small molecule, can promote the Wnt/ß-catenin signaling pathway and induce osteoblast differentiation both in vitro and in vivo. On the other hand, graphene-based materials have been introduced into the field of biomedical sciences in the past decade, and graphene oxide (GO), which serves as an efficient nanocarrier for drug delivery, has attracted great attention for its biomedical applications in tissue engineering. This study aimed to develop a biocompatible gelatin-reduced graphene oxide (GOG) for MV delivery so as to realize the effective osteogenesis for bone repair. First, GOG was prepared, and its morphology as well as properties were then characterized using scanning electron microscope (SEM), transmission electron microscopy (TEM), atomic force microscope (AFM), Raman spectroscopy, X-ray photoelectron spectroscopy (XPS), X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), and thermal gravimetric analysis (TGA), respectively. In addition, the endocytosis of GOG in bone marrow stromal cells (BMSCs) was also investigated with the treatment of Rhodamine 6G (R6G)-labeled GOG. Our results found that GOG could be easily absorbed by cells and was distributed in both nucleus and cytoplasm, thus suggesting the favorable biocompatibility of GOG. Moreover, the effect of MV on osteogenesis was also tested, the results of which indicated that MV could promote BMSC osteogenesis in a concentration-dependent manner, and significant enhancement could be achieved at the concentration of 1 µg/mL. In addition, the complex containing different concentrations of GOG and an optimal concentration of MV was used to investigate the synergistic effect between GOG and MV on pro-osteogenesis. The results revealed that the weight ratio of MV/GOG of 1:1000 could attain remarkably enhanced osteoinduction in BMSCs, as evaluated by alkaline phosphatase (ALP) assay, alizarin red S (ARS) staining, immunofluorescence staining, and gene expression of related osteogenic markers. Taken together, these data had provided strong evidence that the complex of MV and GOG could induce osteogenesis, which was promising for bone tissue engineering.

Synthesis, Thermal Properties and Decomposition Mechanism of Poly(Ethylene Vanillate) Polyester.

Plastics are perceived as modern and versatile materials, but their use is linked to numerous environmental issues as their production is based on finite raw materials (petroleum or natural gas). Additionally, their low biodegradability results in the accumulation of microplastics. As a result, there is extensive interest in the production of new, environmentally friendly, bio-based and biodegradable polymers. In this context, poly(ethylene vanillate) (PEV) has a great potential as a potentially bio-based alternative to poly(ethylene terephthalate); however, it has not yet been extensively studied. In the present work, the preparation of PEV is reported. The enthalpy and the entropy of fusion of the pure crystalline PEV have been estimated for the first time. Additionally, the equilibrium melting temperature has also been calculated. Furthermore, the isothermal and non-isothermal crystallization behavior are reported in detail, and new insights on the thermal stability and degradation mechanism of PEV are given.

First evidence of epicatechin vanillate in grape seed and red wine.

Flavan-3-ols are units incorporating condensed tannin, which are widely present in grape and wine. They play a considerable role in wine sensory perception such as astringency, bitterness and mouth-feel. In grape and wine, the flavan-3-ols reported to date are (epi)catechin, (epi)gallocatechin, (epi)gallocatechin gallate and (epi)catechin glycoside. This study now shows the presence of a new flavan-3-ol epicatechin vanillate in grape seed and red wine. A putative unknown flavan-3-ol derived from grape seed was targeted by LC-HRMS/MS. Fractionation and purification by centrifugal partition chromatography and Prep HPLC allowed us to obtain the pure new flavan-3-ol. NMR and HRMS data revealed this compound to be epicatechin-3-O-vanillate. Quantification analysis results showed that epicatechin vanillate present in grape seed and red wine in the µg/g dry seed and the µg/L concentration range, respectively.

Crystal structure of the VanR transcription factor and the role of its unique α-helix in effector recognition.

VanR is a negative transcriptional regulator of bacteria that belongs to the PadR family and modulates the expression of vanillate transport and degradation proteins in response to vanillate. Although VanR plays a key role in the utilization of vanillate as a carbon source, it is barely understood how VanR recognizes its effector. Thus, our knowledge concerning the gene regulatory mechanism of VanR is limited. Here, we reveal the vanillate-binding mode of VanR through structural, biophysical, and mutational studies. Similar to other PadR family members, VanR forms a functional dimer, and each VanR subunit consists of an N-terminal DNA-binding domain (NTD) and a C-terminal dimerization domain (CTD). One VanR dimer simultaneously binds two vanillate molecules using two interdomain cavities, as observed in PadR. In contrast to these common features, VanR contains an additional α-helix, αi, that has not been found in other PadR family members. The αi helix functions as an interdomain crosslinker that mediates interactions between the NTD and the CTD. In addition, the VanR-specific αi helix plays a key role in the formation of a unique effector-binding site. As a result, the effector-binding mode of VanR is distinguishable from that of PadR in the location and accessibility of the effector-binding site as well as the orientation of its bound effector. Furthermore, we propose the DNA-binding mode and vanillate-mediated transcriptional regulation mechanism of VanR based on comparative structural and mutational analyses. DATABASES: The atomic coordinates and the structure factors for VanR (PDB ID 5Z7B) have been deposited in the Protein Data Bank, www.pdb.org.

Enzymatic Kraft lignin demethylation and fungal O-demethylases like vanillate-O-demethylase and syringate O-demethylase catalyzed catechol-Fe3+ complexation method.

The ability of enzymatic Kraft Lignin (KL) demethylation was determined using catechol and ferric ion coordination (catechol-Fe3+ complexes) by reduction of Fe3+ to Fe2+ and formation of mono, bis- and/or tris-catechol-Fe3+ complexes has been investigated to identify enzyme that can strip-off O-methyl groups from lignin such as O-demethylase. To detect fungal demethylation and release of catechol-like structures, these were demonstrated using catechol, gallic acid and caffeic acid as standard model compounds to forms mono, bis- and/or tris-catechol-Fe3+ complexes. The catechol-Fe3+ complexes formation controlled by pH via the deprotonation of the catechol hydroxyls was investigated at pH 2.5, 8.0 and 10.0 and demonstrated that catechol formed mono, bis- and/or tris-catechol-Fe3+ complexes, and showed maximum absorbance at 547 nm. Lignin demethylation (O-demethylase) and formation of pyrocatecholic structures was detected using Aspergillus sp. and Galerina autumnalis culture filtrates as the enzyme source. The produced aromatic vicinal diol groups in lignin model compounds (LMCs) and KL were determined using different catecholic-binding reagents with the influence of H2O2, along with 4-antiaminopyrine reagent, was analyzed by the following: i) Fe3+-catechol complexation method, ii) HNO2 method, iii) FAS (Ferric Ammonium-Sulfate) method, iv) Ti(III)-NTA (Titanium (III)- Nitrilotriacetate) method for hydrolytic zone formation. Among the tested methods showing lytic zone formation was Fe3+-catechol complexation. The LMCs and KL treated using Aspergillus sp. culture filtrate showed maximum Fe3+-catechol complexes with 3-methoxy catechol (91 µmol/mL), o-vanillin (44 µmol/mL) and KL (100 µmol/mL). In addition, Galerina autumnalis culture filtrate showed demethylation of vanillin (48 µmol/mL), 3-methoxy catechol (82 µmol/mL), o-vanillin, (33 µmol/mL), 3 4-dimethoxybenzyl alcohol (49 µmol/mL) and KL (41 µmol/mL). The results suggest that lignin demethylation (O-demethylases) activity that strip-off methyl groups in LMCs and KL and produced vicinal diols that covalently bind with Fe3+ to form Fe3+-catechol complexes. The new Fe3+-catechol complexation method has the ability to characterize pyrocatechol and galloyl structures in chemically or biologically modified lignins and to detect O-demethylase activity.