Oxidized Product Profiles of AA9 Lytic Polysaccharide Monooxygenases Depend on the Type of Cellulose.

Lytic polysaccharide monooxygenases (LPMOs) are essential for enzymatic conversion of lignocellulose-rich biomass in the context of biofuels and platform chemicals production. Considerable insight into the mode of action of LPMOs has been obtained, but research on the cellulose specificity of these enzymes is still limited. Hence, we studied the product profiles of four fungal Auxiliary Activity family 9 (AA9) LPMOs during their oxidative cleavage of three types of cellulose: bacterial cellulose (BC), Avicel PH-101 (AVI), and regenerated amorphous cellulose (RAC). We observed that attachment of a carbohydrate-binding module 1 (CBM1) did not change the substrate specificity of LPMO9B from Myceliophthora thermophila C1 (MtLPMO9B) but stimulated the degradation of all three types of cellulose. A detailed quantification of oxidized ends in both soluble and insoluble fractions, as well as characterization of oxidized cello-oligosaccharide patterns, suggested that MtLPMO9B generates mainly oxidized cellobiose from BC, while producing oxidized cello-oligosaccharides from AVI and RAC ranged more randomly from DP2-8. Comparable product profiles, resulting from BC, AVI, and RAC oxidation, were found for three other AA9 LPMOs. These distinct cleavage profiles highlight cellulose specificity rather than an LPMO-dependent mechanism and may further reflect that the product profiles of AA9 LPMOs are modulated by different cellulose types.

Unexplored lipolytic activity of Escherichia coli: Implications for lipase cloning.

Recent investigations on cloned bacterial lipases performed in our laboratory revealed the presence of lipolytic activity that was not due to the cloned lipase-coding gene but was probably the result of an intrinsic activity of Escherichia coli itself. To confirm such a hypothesis, we assayed the activity of frequently used E. coli strains by fast paper tests, zymograms and spectrofluorometry. A band of Ca. 18-20 kDa showing activity on MUF-butyrate was detected in zymogram analysis of crude cell extracts in all E. coli strains assayed. Moreover, the spectrofluorometric results obtained confirmed the presence of low but significant lipolytic activity in E. coli, with strain BL21 showing the highest activity. Detailed characterization of such a lipolytic activity was performed using E. coli BL21 cell extracts, where preference for C7 substrates was found, although shorter substrates were also hydrolysed to a minor extent. Interestingly, E. coli lipolytic activity displays traits of a thermophilic enzyme, showing maximum activity at 50 °C and pH 8, an unexpected feature never described before. Kinetic and inhibition analysis were also performed showing that activity can be inhibited by several metal ions or by Triton X-100® and SDS, used in zymogram analysis. Such properties ‒ low activity, preference for medium chain-length substrates, and high operational temperature ‒ might justify why this activity had gone unexplored until now, even when many lipases and esterases have been cloned and expressed in E. coli strains in the past. From now on, lipase researchers should take into consideration the presence of such a basal lipolytic activity before starting their lipase cloning or expression experiments in E.coli.

Development of an antimicrobial bioactive paper made from bacterial cellulose.

Bacterial cellulose (BC) has emerged as an attractive adsorptive material for antimicrobial agents due to its fine network structure, its large surface area, and its high porosity. In the present study, BC paper was first produced and then lysozyme was immobilized onto it by physical adsorption, obtaining a composite of lysozyme-BC paper. The morphology and the crystalline structure of the composite were similar to that of BC paper as examined by scanning electron microscopy and X-ray diffraction, respectively. Regarding operational properties, specific activities of immobilized and free lysozyme were similar. Moreover, immobilized enzyme showed a broader working temperature and higher thermal stability. The composites maintained its activity for at least 80 days without any special storage. Lysozyme-BC paper displayed antimicrobial activity against Gram-positive and Gram-negative bacteria, inhibiting their growth by 82% and 68%, respectively. Additionally, the presence of lysozyme increased the antioxidant activity of BC paper by 30%. The results indicated that BC is a suitable material to produce bioactive paper as it provides a biocompatible environment without compromising the activity of the immobilized protein. BC paper with antimicrobial and antioxidant properties may have application in the field of active packaging.

Bacterial Cellulose-Chitosan Paper with Antimicrobial and Antioxidant Activities.

The production of paper-based bacterial cellulose-chitosan (BC-Ch) nanocomposites was accomplished following two different approaches. In the first, BC paper sheets were produced and then immersed in an aqueous solution of chitosan (BC-ChI); in the second, BC pulp was impregnated with chitosan prior to the production of paper sheets (BC-ChM). BC-Ch nanocomposites were investigated in terms of physical characteristics, antimicrobial and antioxidant properties, and the ability to inhibit the formation of biofilms on their surface. The two types of BC-Ch nanocomposites maintained the hydrophobic character, the air barrier properties, and the high crystallinity of the BC paper. However, BC-ChI showed a surface with a denser fiber network and with smaller pores than those of BC-ChM. Only 5% of the chitosan leached from the BC-Ch nanocomposites after 96 h of incubation in an aqueous medium, indicating that it was well retained by the BC paper matrix. BC-Ch nanocomposites displayed antimicrobial activity, inhibiting growth of and having a killing effect against bacteria Staphylococcus aureus and Pseudomonas aeruginosa and yeast Candida albicans. Moreover, BC-Ch papers showed activity against the formation of a biofilm on their surface. The incorporation of chitosan increased the antioxidant activity of the BC paper. Paper-based BC-Ch nanocomposites combined the physical properties of BC paper and the antimicrobial, antibiofilm, and antioxidant activities of chitosan.

Differential antioxidant activity of glucuronoxylooligosaccharides (UXOS) and arabinoxylooligosaccharides (AXOS) produced by two novel xylanases.

XOS are particularly interesting bioactive molecules. Bacillus safensis CBLMA18, a xylanolytic bacterium has been isolated and two of its xylanases have been identified and fully characterized. Xyn11A is an extracellular 22.5-kDa GH11 xylanase while a second xylanase, Xyn10B, corresponds to an intracellular 48-kDa GH10 enzyme. Both unimodular xylanases showed activity only on xylan substrates with important differences in their catalytic pattern. Xyn11A displays higher activity on glucuronoxylans, with an optimum at pH 8 and 50 °C, and a Vmax of 5281 U/mg on beechwood xylan, meanwhile Xyn10B prefers arabinoxylans, with an optimum of pH 7 and 60 °C, and a Vmax of 50.29 U/mg on rye arabinoxylan. The antioxidant activity of xylanase-generated XOS obtained from glucuronoxylans (UXOS) and arabinoxylans (AXOS) was tested with the ABTS (2, 2'-Azino-bis (3-ethylbenzothiazoline-6-sulfonic acid)) method. UXOS showed higher antioxidant activity than AXOS (>80% of antioxidant capacity). Thin layer chromatography and MALDI-TOF MS analysis showed that UXOS comprise neutral and acidic XOS with methylglucuronic acid (MeGlcA) ramifications, while AXOS contain only neutral molecules with arabinose decorations. The MeGlcA ramifications seem to have an important role in the antioxidant capacity of oligosaccharides. Besides, the increase of UXOS size correlates with an increase in their activity.

Assessing the enzymatic effects of cellulases and LPMO in improving mechanical fibrillation of cotton linters.

BACKGROUND: The increasing interest in replacing petroleum-based products by more sustainable materials in the packaging sector gives relevance to cellulose as a biodegradable natural resource. Moreover, its properties can be modified physically, chemically or biotechnologically in order to obtain new bioproducts. Refined cotton linters with high cellulose content were treated with hydrolytic (cellulases) and oxidative (LPMO and Laccase_Tempo) enzymes to evaluate their effect on fibre properties and in improving mechanical fibrillation. RESULTS: Cellulases released cellooligosaccharides, reducing fibre length and partially degrading cellulose. They also improved mechanical fibrillation yielding up to 18% of nanofibrillated cellulose (NFC). LPMO introduced a slight amount of COOH groups in cellulose fibres, releasing cellobionic acid to the effluents. The action of cellulases was improved after LPMO treatment; however, the COOH groups created disappeared from fibres. After mechanical fibrillation of LPMO-cellulase-treated cotton linters a 23% yield of NFC was obtained. Laccase_Tempo treatment also introduced COOH groups in cellulose fibres from cotton, yielding 10% of NFC. Degree of polymerization was reduced by Laccase_Tempo, while LPMO treatment did not significantly affect it but produced a higher reduction in fibre length. The combined treatment with LPMO and cellulase provided films with higher transparency (86%), crystallinity (92%), smoothness and improved barrier properties to air and water than films casted from non-treated linters and from commercial NFC. CONCLUSIONS: The combined enzymatic treatment with LPMO and cellulases boosted mechanical fibrillation of cotton linters, improving the NFC production and providing bioproducts with high transparency and high barrier properties.

Differential activity of lytic polysaccharide monooxygenases on celluloses of different crystallinity. Effectiveness in the sustainable production of cellulose nanofibrils.

A series of cellulosic substrates has been produced, treated with lytic polysaccharide monooxygenase (LPMO) from Streptomyces ambofaciens (SamLPMO10C), and analyzed by high performance anion exchange chromatography (HPAEC) with pulsed amperometric detection (PAD). The activity of the bacterial LPMO showed high variability depending on the origin and degree of crystallinity of the substrate. Additionally, we tested the effectiveness of SamLPMO10C in the nanofibrillation of flax, a high crystalline agricultural fiber, as a single pretreatment or in combination with cellulases. All pretreatments were followed by a mechanical defibrillation by high-pressure homogenization (HPH) to obtain cellulose nanofibrils (NFC). The combined LPMO-cellulase treatment showed higher fibrillation yield, optical transmittance and carboxylate content than control reactions. Therefore, it could be explored as a promising green alternative to reduce the energy consumption in the production of NFC. To our knowledge, this is the first study reporting the effect of a bacterial LPMO in nanocellulose production.

Antioxidant activity of xylooligosaccharides produced from glucuronoxylan by Xyn10A and Xyn30D xylanases and eucalyptus autohydrolysates.

Antioxidant activity of xylooligosaccharides (XOS) released from beechwood and birchwood glucuronoxylans by two different xylanases, one from family GH10 (Xyn10A) and another from family GH30 (Xyn30D) was examined. The ABTS (2, 2'-Azino-bis(3-ethylbenzothiazoline-6-sulfonic acid)) method was used, since it resulted more accurate for the antioxidant activity determination of XOS. Thin layer chromatography and MALDI-TOF MS analysis showed that Xyn10A produced a mixture of neutral and acidic XOS whereas the XOS produced by Xyn30D were all acidic, containing a methylglucuronic acid (MeGlcA) ramification. These acidic XOS, MeGlcA substituted, showed a strongly higher antioxidant activity than the XOS produced by Xyn10A (80% vs. 10% respectively, at 200 µg mL-1). Moreover, the antioxidant activity increased with the degree of polymerization of XOS, and depended on the xylan substrate used. The antioxidant capacity of eucalyptus autohydrolysates after xylanase treatment was also analysed, showing a decrease of their antioxidant activity simultaneous with the decrease in XOS length.

Fast purification method of functional LPMOs from Streptomyces ambofaciens by affinity adsorption.

A simple purification method by affinity adsorption was developed to obtain functional lytic polysaccharide monooxygenases (LPMOs). The system allows the successful purification to homogeneity of the most characterized bacterial LPMO, CBP21 from Serratia marcescens, and two LPMOs from Streptomyces ambofaciens, which have not been previously characterized. The first of these new LPMOs, named SamLPMO10B is a small enzyme (15 kDa) belonging to family 10 of auxiliary activities (AA10), showing activity on ß-chitin. The second LPMO, SamLPMO10C (34.7 kDa), is a bimodular enzyme comprised of an AA10 catalytic module and a carbohydrate binding module of family CBM2. SamLPMO10C shows activity on cellulosic substrates, including agricultural fiber paper pulps. The methodology developed simplifies the purification process to a binding-elution protocol with low-grade polysaccharides including Avicel. The strategy can be a cheap, simple and fast solution for the purification of LPMOs for industrial applications, leaving out periplasmic fractionation from recombinant strains therefore, with reduction of time and costs compared to conventional processes. The activity of SamLPMO10C expands the potential of the high valued LPMOs in lignocellulosic biomass valorization, reaffirming their promising role in cellulose deconstruction.

The Glycoside Hydrolase Family 8 Reducing-End Xylose-Releasing Exo-oligoxylanase Rex8A from Paenibacillus barcinonensis BP-23 Is Active on Branched Xylooligosaccharides.

UNLABELLED: A GH8 family enzyme involved in xylan depolymerization has been characterized. The enzyme, Rex8A, is a reducing-end xylose-releasing exo-oligoxylanase (Rex) that efficiently hydrolyzes xylooligosaccharides and shows minor activity on polymeric xylan. Rex8A hydrolyzes xylooligomers of 3 to 6 xylose units to xylose and xylobiose in long-term incubations. Kinetic constants of Rex8A were determined on xylotriose, showing a Km of 1.64 ± 0.03 mM and a kcat value of 118.8 s(-1) Besides linear xylooligosaccharides, the enzyme hydrolyzed decorated xylooligomers. The catalytic activity on branched xylooligosaccharides, i.e., the release of xylose from the reducing end, is a newly described trait of xylose-releasing exo-oligoxylanases, as the exo-activity on these substrates has not been reported for the few of these enzymes characterized to date. Modeling of the three-dimensional (3D) structure of Rex8A shows an (α/α)6 barrel fold where the loops connecting the α-helices contour the active site. These loops, which show high sequence diversity among GH8 enzymes, shape a catalytic cleft with a -2 subsite that can accommodate methyl-glucuronic acid decorations. The hydrolytic ability of Rex8A on branched oligomers can be crucial for the complete depolymerization of highly substituted xylans, which is indispensable to accomplish biomass deconstruction and to generate efficient catalysts. IMPORTANCE: A GH8 family enzyme involved in xylan depolymerization has been characterized. The Rex8A enzyme from Paenibacillus barcinonensis is involved in depolymerization of glucuronoxylan, a major component of the lignocellulosic substrates. The study shows that Rex8A is a reducing-end xylose-releasing exo-oligoxylanase that efficiently hydrolyzes xylose from neutral and acidic xylooligosaccharides generated by the action of other xylanases also secreted by the strain. The activity of a Rex enzyme on branched xylooligosaccharides has not been described to date. This report provides original and useful information on the properties of a new example of the rarely studied Rex enzymes. Depolymerization of highly substituted xylans is crucial for biomass valorization as a platform for generation of biofuels, chemicals, and solvents.

A newly discovered arabinoxylan-specific arabinofuranohydrolase. Synergistic action with xylanases from different glycosyl hydrolase families.

Arabinofuranosidase Abf43A from Bacillussp. BP-7 i s a newly discovered arabinoxylan arabinofuranohydrolase (AXH). It is a modular enzyme comprised of a GH43 catalytic domain and a carbohydrate-binding module of family CBM6. Recombinant Abf43A showed high activity on arabinoxylans, being rye arabinoxylan the preferred substrate on which the purified enzyme exhibited a Km of 10.6 ± 3.3 mg/ml and a Vmax of 29.2 ± 3.4 U/mg. Thin-layer chromatography analysis of hydrolysis products showed arabinose as the only sugar released by the enzyme from its substrates. The GH43 and CBM6 modules of the enzyme were individually cloned and expressed in Escherichia coli. While the isolated catalytic GH43 module did not show hydrolytic activity, the purified CBM6 bound to soluble arabinoxylan in affinity gel electrophoresis analysis. Evaluation of cooperative activity of arabinofuranosidase Abf43A with xylanases from families GH10, GH11, andGH30, (Xyn10A, Xyn11E, and Xyn30D from Paenibacillus barcinonensis) on arabinoxylan depolymerization revealed that the studied enzyme showed synergism with Xyn11E, a 2.54-fold increase in the amount of sugars released. On the contrary, Abf43A did not show synergism with the xylanases of families GH10 or GH30 evaluated. The enzyme characterized contributes to understanding the role of this class of enzymes in the catalytic depolymerization of arabinoxylans and their potential for the production of valuable xylooligosaccharides from these abundant plant polymers.

Unusual carboxylesterase bearing a GGG(A)X-type oxyanion hole discovered in Paenibacillus barcinonensis BP-23.

Strain Paenibacillus barcinonensis BP-23, previously isolated from Ebro's river delta (Spain), bears a complex hydrolytic system showing the presence of at least two enzymes with activity on lipidic substrates. EstA, a cell-bound B-type carboxylesterase from the strain was previously isolated and characterized. The gene coding for a second putative lipase, located upstream cellulase Cel5A, was obtained using a genome walking strategy and cloned in Escherichia coli for further characterization. The recombinant clone obtained displayed high activity on medium/short-chain fatty acid-derivative substrates. The enzyme, named Est23, was purified and characterized, showing maximum activity on pNP-caprylate (C8:0) or MUF-heptanoate (C7:0) under conditions of moderate temperature and pH. Although Est23 displays a GGG(A)X-type oxyanion hole, described as an important motif for tertiary alcohol ester resolution, neither conversion nor enantiomeric resolution of tertiary alcohols could be detected. Amino acid sequence alignment of Est23 with those of known bacterial lipase families and with closely related proteins suggests that the cloned enzyme does not belong to any of the described bacterial lipase families. A phylogenetic tree including Est23 and similar amino acid sequences showed that the enzyme belongs to a differentiated sequence cluster which probably constitutes a new family of bacterial lipolytic enzymes.

Xyn11E from Paenibacillus barcinonensis BP-23: a LppX-chaperone-dependent xylanase with potential for upgrading paper pulps.

A new xylanase from Paenibacillus barcinonensis BP-23, Xyn11E, has been identified and characterized. Xyn11E has been cloned and heterologously expressed in Escherichia coli. It is a single-domain xylanase belonging to the family 11 of glycosyl hydrolases (GH11) with a predicted molecular weight of 20.652 kDa and an isoelectric point (pI) of 8.7. Substrate specificity, kinetic properties, and mode of action of the purified xylanase were characterized. Xyn11E exhibited high activity toward branched xylans, being beechwood xylan the preferred substrate. The optimum pH and temperature of the purified enzyme were 6.5 and 50 °C, respectively. Catalytic constants were determined on beechwood xylan, on which Xyn11E showed a Km of 12.98 mg/ml and a Vmax of 3,023 U/mg. The enzyme hydrolyzed long xylooligosaccharides, while oligomers shorter than xylotetraose were not degraded. Products released from glucuronoxylans were shorter than those liberated from cereal arabinoxylans. The xylanase was dependent on P. barcinonensis BP-23 LppX for its expression in an active form. Coexpression of Xyn11E with E. coli chaperones could not replace the need of LppX, which seems to act as a specific chaperone for Xyn11E correct folding. Activity of the enzyme on bleached pulps was evaluated. Xyn11E liberated reducing sugars from ECF and TCF pulps from eucalyptus, sisal, and flax, which makes it a good candidate for the enzymatic-assisted production of high-cellulose-content pulps from paper-grade pulps.

A glucuronoxylan-specific xylanase from a new Paenibacillus favisporus strain isolated from tropical soil of Brazil.

A new xylanolytic strain, Paenibacillus favisporus CC02-N2, was isolated from sugarcane plantation fields in Brazil. The strain had a xylan-degrading system with multiple enzymes, one of which, xylanase Xyn30A, was identified and characterized. The enzyme is a single-domain xylanase belonging to family 30 of the glycosyl hydrolases (GH30). Xyn30A shows high activity on glucuronoxylans, with a Vmax of 267.2 U mg⁻¹, a Km of 4.0 mg/ml, and a kcat of 13,333 min⁻¹ on beechwood xylan, but it does not hydrolyze arabinoxylans. The three-dimensional structure of Xyn30A consists of a common (ß/α)8 barrel linked to a side-chain-associated ß-structure, similar to previously characterized GH30 xylanases. The hydrolysis products from glucuronoxylan were methylglucuronic-acid-substituted xylooligomers (acidic xylooligosaccharides). The enzyme bound to insoluble xylan but not to crystalline cellulose. Our results suggest a specific role for Xyn30A in xylan biodegradation in natural habitats. The enzyme is a good candidate for the production of tailored xylooligosaccharides for use in the food industry and in the biotechnological transformation of biomass.

Recombinant expression of an alkali stable GH10 xylanase from Paenibacillus barcinonensis.

Xylanase A from Paenibacillus barcinonensis, a new species isolated from a rice field, has been cloned and expressed in Escherichia coli. Purified recombinant xylanase showed high activity on xylans from hardwoods and cereals, and exhibited K(m) and V(max) of 2.93 mg/mL and 50.67 U/mg on birchwood xylan. Xylanase A was highly active at 60 degrees C in alkaline pH values up to 9.5 and remained stable for at least 3 h in alkaline conditions. The amino acid sequence deduced from xynA revealed that it is a single domain xylanase belonging to the GH10 family. Thin layer chromatography analysis showed that the enzyme released a mixture of hydrolysis products including substituted xylooligomers from cereal arabinoxylans, while xylose, xylobiose, and aldotetraouronic acid were the main products released from glucuronoxylan from birchwood. The enzyme released a complex mixture of xylooligomers for acetylated xylan from eucalyptus, revealing its potential to depolymerize this widely used resource in the pulp and paper industry.