Candida Antarctica Research Articles

Combining the Nonnatural Activity of Lipase and Electrocatalysis in One Pot: Sustainable and Regioselective Synthesis of C‐3 Alkylated Oxindoles

AbstractIn this study, we report an environment‐friendly protocol by integrating the nonnatural catalytic activity of lipase with electrocatalysis for synthesizing C‐3 alkylated oxindoles, which are part of many natural and pharmaceuticals products. Gratifyingly, Candida antarctica lipase B (CALB) is found to be highly active and regioselective for catalyzing the nonnatural C‐3 alkylation reaction at indole when combined with an electrochemical C‐2 oxidation process in the same vessels. Further, the generality and feasibility of the developed protocol are shown by employing several functional groups on the indole moiety and obtaining the desired products in moderate to good yield. Besides, the control experiments are set up along with the molecular docking studies to substantiate the role of the active site of Candida antarctica lipase B (CALB) in carrying out the regioselective C‐3 alkylation reaction. In addition, control experiments and cyclic voltammetry are performed to get insight into the electrochemical C‐2 oxidation process and as a result, a plausible mechanism for the integrated process is presented.

Candida antarctica lipase B catalyzed condensation reactions: Water mediated chemo-enzymatic synthesis of different heterocycles

Candida antarctica lipase B catalyzed condensation reactions: Water mediated chemo-enzymatic synthesis of different heterocycles

Preparation of highly stable immobilized Candida antarctica lipase B (CALB) through adjusting the surface properties of carrier: Preparation, characterization and performance evaluation

The stability of the immobilized lipase is the key factor that determines the economy and feasibility of its industrial application. Here, two robust immobilized Candida antarctica lipase B (CALB) were prepared through adjusting the surface properties of ECR1030 resin. Silane coupling agent (SCA) and dialdehyde cellulose (DAC) were employed to modify the carrier surface. Contact angle measurement showed that the hydrophobicity of the modified carrier increased first, and then decreased with the increase of the chain length of SCA. FTIR results showed that Si-O-Si bond and aldehyde group were attached to ECR1030, respectively, indicating that the ECR1030 resin was successfully modified. Meanwhile, the NH and CN bond were observed in the corresponding immobilized CALB, suggesting CALB was immobilized onto the modified carriers. The effects of immobilization conditions on CALB immobilization was further investigated, and the C8-ECR1030-CALB and DAC-ECR1030-CALB with the activity of 12,736 U/g and 11,962 U/g were obtained. Moreover, the stability of the immobilized lipases was evaluated and compared with the commercial Novozym 435. The C8-ECR1030-CALB and DAC-ECR1030-CALB exhibited comparable or superior stability to Novozym 435 and showed better deacidification effect than Novozym 435. This study paves road for further study involving preparation of highly stable immobilized lipase.

Xylose Acetals - a New Class of Sustainable Solvents and Their Application in Enzymatic Polycondensation.

The use of organic solvents in academic research and industry applications is facing increasing regulatory pressure due to environmental and health concerns. Consequently, there is a growing demand for sustainable solvents, particularly in the enzymatic synthesis and processing of polyesters. Biocatalysts offer a sustainable method for producing these materials; however, achieving high molecular weights often necessitates use of solvents. In this work, we introduce a new class of alternative aprotic solvents with medium polarity produced directly from agricultural waste biomass in up to 83 mol% yield (on xylan basis). The new solvents have a largely unmodified xylose core and acetal functionality, yet they show no peroxide formation and provide reduced flammability risk. We also demonstrate their successful application in enzymatic polycondensation reactions with Candida antarctica lipase B (CaLB). In particular, the solvent dibutylxylose (DBX) outperformed the hazardous solvent diphenyl ether and facilitated polycondensation of the lignin-derived diester pyridine-2,4-dicarboxylate, yielding polyesters with a Mn of >15 kDa. Computational modelling studies provided further insight into the molecular structure and dynamics of CaLB in the presence of new solvents. Lastly, up to 98 wt% of the new xylose acetals were successfully recovered and recycled, further contributing to the sustainability of the overall process.

Boosting Enzyme Activity in an Anhydrous Gas Flux with Amphiphilic Polymers

AbstractGas‐phase enzymatic catalysis offers great potential for both green synthesis and the efficient degradation of volatile chemicals. However, solid enzymes often exhibit extremely low activity compared to their counterparts in native aqueous phase. Although a few immobilization methods have succeeded in increasing activity by preserving enzyme structure, approaches for boosting enzyme activity remain underdeveloped. In this study, we propose a general and facile method to boost enzyme activity in the gas phase, which utilizes amphiphilic polymers to energize enzyme conformational dynamics and thus enhance enzyme catalysis kinetics. The triblock copolymer Pluronics with low melting points were co‐lyophilized with Candida antarctica lipase B (CalB), yielding Pluronic/CalB powders that appeared a 70‐fold increase in activity compared to free CalB powder. Low‐field nuclear magnetic resonance (LF‐NMR), solid‐state nuclear magnetic resonance (ssNMR) and dielectric relaxation spectroscopy identified the enhancement of enzyme dynamics on the µs–ms timescale, whereas Fourier transform infrared spectroscopy (FTIR) detected structural perturbations of the native enzyme in Pluronic/CalB. The apparent activity of the enzyme/polymer powders correlated positively with both enzyme dynamics and polymer flexibility. These findings provide new molecular physical insights into gas‐phase enzyme catalysis, which are essential for advancing enzyme applications in nonnatural scenario.

Improved catalytic stability of immobilized Candida antarctica lipase B on macroporous resin with organic polymer coating for biodiesel production.

Lipase is one of the most widely studied and applied biocatalysts. Due to the high enzyme leakage rate of the immobilization method of physical adsorption, we propose a new lipase immobilization method, based on the combination of macroporous resin adsorption and organic polymer coating. The immobilized Candida antarctica lipase B (CALB@resin-CAB) was prepared by combining the macroporous resin adsorption with cellulose acetate butyrate coating, and its structure was characterized by various analytic methods. Immobilized lipase was applied for biodiesel production using acidified palm oil as the starting material, the conversion rate achieved as high as 98.5% in two steps. Furthermore, the immobilized lipase displayed satisfactory stability and reusability in biodiesel production. When the aforementioned reaction was carried out in a continuous flow packed bed system, the yield of biodiesel was 94.8% and space-time yield was 2.88g/(mL∙h). The immobilized lipase CALB@resin-CAB showed high catalytic activity and stability, which has good potential for industrial application in the field of oil processing.

Silica‐Mediated Incorporation of Lipase Into The Bulk of a Deep Eutectic Solvent: An Efficient Biocatalytic Phase for Esters Synthesis

Aiming at sustainable solutions suitable for industrial‐scale catalysis catalytic phase containing lipase and Deep Eutectic Solvent (DES) was designed. To achieve this, both physical and chemical immobilizations of lipases were performed on the surface of silica and carbon materials. The catalytic activity of developed biosystem was tested in biotransformation of α‐angelica lactone into butyl levulinate at 60°C. The best results were achieved for Candida antarctica lipase B adsorbed on fumed silica suspended in choline chloride: glycerol (1:2) with the addition of 20 wt% of water. Under these conditions 99.9% conversion of α‐angelica lactone and 100% selectivity to butyl levulinate were obtained after 45 min. The biocatalytic system maintained its activity for up to five consecutive reaction cycles with full conversion of lactone to ester. The heterogenization of the enzyme allowed the biocatalyst to be integrated into the bulk of the DES, which includes essential water. This combination resulted in the formation of a stable and easy‐to‐operate catalytic phase where reagents formed a second organic phase. The integration of cost‐effective biocatalyst with process efficiency provides a greener alternative with significant potential for industrial use.

Synthesis of polymeric nanoparticles with different functionalities to produce new biocatalysts

AbstractThis study aimed to synthesize functionalized nanosupports via emulsion polymerization to develop new promising nanobiocatalyts via enzyme immobilizations. The co‐monomers methyl methacrylate, divinylbenzene and the epoxy monomer glycidyl methacrylate (GMA) were used. The performance of the nanobiocatlysts was evaluated in hydrolysis and esterification reactions after the immobilization of lipase B from Candida antarctica (CAL B). Firstly, the nanosupports functionalized in situ with 25% and 50% w/w of GMA were successfully synthesized. In esterification reactions, the nanobiocatalysts containing 25% (w/w) of GMA were more active, achieving 254 U.g−1, or an enzyme activity per area of 2.8 U.m−2; such value was higher than the one obtained when the commercial matrix Octadecyl Sepabeads was used (328 U.g−1, 2.4 U.m−2). Such results point out that there is an optimum concentration of GMA epoxide groups that should be incorporated into the supports. The greater enzymatic activity obtained for 25% of GMA nanobiocatalyst was achieved not only because of their textural properties, but also due to a favorable interaction between the epoxide groups and CAL B. These results highlight the potential use of the heterofunctional matrices for the synthesis of new market‐competitive biocatalysts.

Ultrastable hierarchically porous nucleotide-based MOFs and their use for enzyme immobilization and catalysis

Immobilization of free enzymes facilitates their recovery and reuse, while also enhances their enzymatic characteristics. Hierarchically porous metal-organic frameworks (HP-MOFs) are promising candidates for enzyme immobilization. However, fabrication of HP-MOFs with more kinds of components as ligands is still a challenge. Herein, ultrastable crystalline MOFs with micro-, meso- and macroporous structure were constructed using guanosine 5′-monophosphate (GMP) as organic ligand through templated emulsification method. HP-MOFs crystals with the near rhomb-like, rod-like and slab-like morphology were interestingly obtained from Zn2+, Cu2+ and Cd2+ respectively. The HP-MOFs immobilized enzymes exhibited an enhanced enzymatic activity and stability. In addition, the immobilized CALB (Candida antarctica lipase B) showed great glycerolysis and esterification performances for glycerides preparation, with diacylglycerols (DAG) content over 60 wt% and triacylglycerols (TAG) content over 90 wt% obtained respectively from glycerolysis and esterification. Moreover, it retained 82.32 % of its initial glycerolysis activity after six cycles of reuse in glycerolysis. The present study will provide clues and show new horizons to explore new organic ligands for HP-MOFs fabrication, as well as to expand the applications of HP-MOFs and their supported enzymes.

Ethyl esters synthesis catalyzed by lipase B from Candida antarctica immobilized on NiFe2O4 magnetic nanoparticles

Ethyl esters synthesis catalyzed by lipase B from Candida antarctica immobilized on NiFe2O4 magnetic nanoparticles

From agricultural waste to value: Integrated chemo and biocatalytic biorefinery processes to produce 2-furoic acid

The integration of biocatalysis in biorefineries can lead to synergies for raw material valorization. Enzymes must perform efficient and selective reactions when using crude effluents (to avoid costly downstream units). Herein, this is showcased with the synthesis of 2-furoic acid, starting from rice husk (agricultural waste), via a sequential organic-acid catalyzed pretreatment – to afford xylose and cellulose and lignin –, followed by the microwave-assisted acidic xylose dehydration to furfural, in situ extraction in ethyl acetate, and the final biocatalytic selective oxidation of furfural to 2-furoic acid (2-FA). To validate the concept, a xylose-rich hydrolysate (∼ 15 g xylose L−1) obtained from rice husk (RH) was used, achieving a furfural yield of 70 % in a biphasic system (water – ethyl acetate). The obtained furfural extracted in the ethyl acetate was subsequently oxidized to 2-furoic acid via an organic peroxide reaction mediated by Candida antarctica lipase B (CALB), with an overall yield of 90 %, and, with a yield of 41.72 % based on the initial xylose in biomass. Notably, 20 mg/mL CALB could tolerate up to 400 mM of furfural under optimum conditions of 40 °C, 48 h. The recyclability of the biocatalyst was investigated, enabling an efficient reuse of four consecutive cycles.

Synthesis of lipid‐modified copolymers based on caprolactone via enzymatic ring‐opening polymerization and click chemistry and evaluation of their potential as vehicles in drug delivery

AbstractThis research focuses on the application of click chemistry to the synthesis of amphiphilic lipidic copolymers with a target number of oleyl, cholesteryl, and linoleic pendant groups. The synthesis was performed using a two‐step approach. In the first step, copolymerization of ε‐caprolactone (CL) and α‐azido‐caprolactone (N3CL) was carried out using enzymatic ring‐opening polymerization (eROP) catalyzed by Candida Antarctica lipase B (CALB). This resulted in copolymers with an average molecular weight of 9.53 kDa, each containing approximately seven azide groups per chain. Subsequently, click chemistry was utilized to react P(N3CL‐co‐CL) copolymers with propargylated lipidic compounds, achieving azide group consumption higher than 88%. These lipidic copolymers exhibited reduced crystallinity, as evidenced by their lower melting enthalpy values. In addition, these materials were evaluated for the fabrication of nanostructured vehicles for curcumin (Cur@NP) using the solvent emulsion‐evaporation methodology. The lipidic copolymers demonstrated enhanced encapsulation efficiencies and drug loading capacities of 25 and 12%, respectively, tunable particle sizes in the range of 260–420 nm, and controlled release profiles over 30 h. Cur@NPs demonstrated notable antioxidant and antibacterial activities, particularly against Gram‐positive bacteria such as Staphylococcus aureus, achieving efficiencies close to 50%.

Carbon-based magnetic nano-particle utilizing nano-biochar as core and its immobilizing lipase for biodiesel preparation

Using the transesterification capacity of lipase to produce eco-friendly biodiesel is a promising method for the achievement of a Net Zero future. The method of immobilized lipase enhances the usability of the enzyme and improves its stability. Carbon-based magnetic nano-particles (C-MNPs) with nano-biochar as the precipitation core were prepared as the support to immobilize Candida antarctica lipase B (CalB) for biodiesel preparation. The nano-biochar particles were derived through the calcination of rice straw powder and subsequently ground to the nanoscale. FT-IR, XRD, SEM, and VSM results showed that the obtained C-MNPs with a diameter of 13–17 nm were showing excellent superparamagnetism, and effectively immobilized the lipase on them (CalB@C-MNPs). The optimal reaction conditions in a 100-mL stoppered flask for biodiesel production were dissolving 5 g soybean oil in 3 mL tert-butanol solvent, adding 1.16 mL methanol (molar ratio of methanol to oil 5:1), 0.15 mL water, and 0.2 g CalB@C-MNPs, and then shaking at 200 rpm and 30 °C for 24 h. Its primarily optimized conversion efficiency of biodiesel was 83.1 %. After repeated use of immobilized CalB for 8 cycles, the remaining activity and biodiesel yield were 79.7 % and 66.3 %, respectively. As a robust catalyst, CalB@C-MNPs exhibited outstanding transesterification efficiency, the ability for rapid recovery under an external magnetic field, and a promising candidate in biodiesel production.

Design of green DES-based aqueous two phase systems for lipolytic enzymes extraction

This study pioneers a novel green and cost-effective separation process using reline deep eutectic solvent (DES) for extracting Thermomyces lanuginosus lipase (TlL) from aqueous solutions. For the first time, it has been shown that various potassium organic salts combined with reline DES can induce phase separation in aqueous solutions of the biodegradable non-ionic surfactant Tergitol 15-S9, presenting a groundbreaking alternative to the banned surfactant Triton X-100. This work uniquely applies three different equations to describe the experimental solubility curves. The selection of reline DES is particularly innovative as it avoids significant deactivation effects with three commercial lipases: Candida antarctica lipases A and B, and TlL, with the latter undergoing a detailed study. This includes an unprecedented analysis of its thermodeactivation kinetics in reline DES aqueous solutions. Additionally, a novel investigation of immiscibility regions at different temperatures, involving comprehensive Tie-Line characterizations (slope and length), preceded the evaluation of lipase extraction. Remarkably, the study demonstrates that optimizing the feed composition to contain higher water concentrations can achieve exceptionally high extraction efficiencies (approximately 90%), suggesting a transformative potential for future applications in real aqueous cultures.

Supramolecular assembly strategy of modified starch chains for achieving recyclable emulsion biocatalysis within a narrow pH range

Stimuli-responsive Pickering emulsions are promising in biocatalysis for their ease of product separation and emulsifier recovery. However, pH responsiveness, though simple and cost-effective, faces challenges in precise control and narrow transition ranges, limiting its use in enzymatic catalysis. Herein we introduced amorphous octenyl succinic anhydride-modified debranched starch chains (Am-OSA-St) to control emulsion properties within a pH range suitable for enzymatic catalysis. By adjusting the OSA group density and molecular weight, Am-OSA-St allowed emulsions to transition reversibly between pH 7.3 and 5.5 and enabled self-recycling through supramolecular self-assembly. Employing molecular dynamics simulations and physicochemical characterization, we elucidated the control mechanism of oil-water interfaces via the microstructure transformation of Am-OSA-St. The findings revealed that protonation of carboxylate groups disrupted the charge balance and polarity of starch chains, leading to strong electrostatic and van der Waals interactions that drove self-assembly. This entanglement caused starch chains in the aqueous phase to “drag” those at the oil-water interface, moving them into the aqueous phase and forming micelles. These micelles, with a hydrophobic interior and hydrophilic exterior, prevented re-adsorption. Testing with Candida antarctica Lipase B (CALB) and N-acetylneuraminic lyase showed that the pH-regulated emulsion system maintained excellent efficiency and cycling stability in mild conditions.

Structured Triacylglycerol with Optimal Arachidonic Acid and Docosahexaenoic Acid Content for Infant Formula Development: A Bio-Accessibility Study.

Polyunsaturated fatty acids (PUFAs), especially arachidonic acid (ARA) and docosahexaenoic acid (DHA), are extremely important fatty acids for brain development in the fetus and early childhood. Premature infants face challenges obtaining these two fatty acids from their mothers. It has been reported that supplementation with triacylglycerols (TAGs) with an ARA:DHA (w/w) ratio of 2:1 may be optimal for preterm infants, as presented in commercial formulas such as Formulaid™. This study explored methods to produce TAGs with a 2:1 ratio (ARA:DHA), particularly at the more bioavailable sn-2 position of the glycerol backbone. Blending and enzymatic acidolysis of microalgae oil (rich in DHA) and ARA-rich oil yielded products with the desired ARA:DHA ratio, enhancing sn-2 composition compared to Formulaid™ (1.6 for blending and 2.3 for acidolysis versus 0.9 in Formulaid™). Optimal acidolysis conditions were 45 °C, a 1:3 substrate molar ratio, 10% Candida antarctica lipase, and 4 h. The process was reproducible, and scalable, and the lipase could be reused. In vitro digestion showed that 75.5% of the final product mixture was bio-accessible, comprising 19.1% monoacylglycerols, ~50% free fatty acids, 14.6% TAGs, and 10.1% diacylglycerols, indicating better bio-accessibility than precursor oils.

Enzymatic Transesterification Using Different Immobilized Lipases and its Biodiesel Effect on Gas Emission

Biodiesel, a third-generation bio-fuels, offering several advantages over regular diesel fuel. Waste cooking oil (WCO) emerges as an ideal feedstock due to its availability and easy accessibility. In this work, biodiesel is utilized from two different types of immobilized lipases: Rhizomucor miehei lipase (RMIM) and Candida antarctica lipase B (CALB). The impact of the molar ratio of oil to methyl acetate (1:3-1:12) was evaluated for both lipases, and the resultant biodiesel was tested in diesel engine. The enzymatic transesterification was carried out in ultrasonic assistance and the results showed that the greatest yield of 81.20% at 45℃, using CALB as a biocatalyst, 1.8% (w/v) lipase and oil to methyl acetate molar ratio of 1:12 within 3 hours. Triacetin, by-product was determined their concentration for each molar ratio and analyzed using FTIR range of 500cm-1 to 4000cm-1, revealing a significant absorption peak at 1238.90cm-1. Biodiesel was blended with commercial diesel fuel in varying quantities of 7, 10, and 20% by volume (B20). The results were compared to Industrial Diesel Fuel 7% (B7) and Commercial Diesel Fuel 10% (B10). NOx and CO2 emission drops as the percentage of diesel/biodiesel blends increases, supporting WCO as a cost-effective biodiesel feedstock with low petrol pollution.

Hook loop dynamics engineering transcended the barrier of activity-stability trade-off and boosted the thermostability of enzymes

The improvement of enzyme thermostability often accompanies the decreased activity due to the loss of the key regions' flexibility. As a representative structure, unlocking the potential of loop dynamics will not only provide new ideas for stabilization strategies, but also help to deepen the understanding of the relationship between enzyme structural dynamics and function. In this study, a creative “hook loop dynamics engineering” (HLoD) strategy was successfully proposed for simultaneously improving the thermostability and maintaining activity of the model enzyme, Candida Antarctica lipase B. A small and smart mutant library involving five key residues located at the “hook loop” was meticulously identified and systematically investigated and thus yielded a five-point multiple mutant M1 (L147S/T244P/S250P/T256D/N292D), demonstrating a remarkable 7.0-fold increase in thermostability at 60 °C compared to the wild-type (WT). Furthermore, the activity of M1 remained comparable to that of WT, effectively transcending the barrier of activity-stability trade-off. Molecular dynamics simulations revealed that the precise regulation of hook loop dynamics via intermolecular interactions, such as salt bridges and hydrogen bonding, curbed the excessive flexibility of the pivotal regions α5 and α10 at high temperatures, thus driving the substantial enhancement of the thermostability of M1. Refining the dynamics of the flexible region via HLoD, which transcended the barrier of activity-stability trade-off, exhibited to be a robust and potentially universal strategy for designing enzymes with outstanding thermostability and activity.

Preparation of chiral polyether dendrimer and its non-bonding immobilized CALB for high enantioselective synergy resolution of amines

Monodisperse polyethylene glycol monomethyl ether and chiral glycidyl tosylate were utilized as substrates in the synthesis of the chiral monomer unit epoxypropyl polyethylene glycol monomethyl ether (MPEGn-EPO). The initiator propargyl-terminated polyethylene glycol alkyne-PEG3-OH was employed, while the phosphazene base P4-t-Bu facilitated the controlled ROP of MPEGn-EPO, resulting in clickable dendritic P(MPEGn-EPO) with terminal alkyne. The chiral four-arm dendritic polymer 4-Arm-PEG3-Mn was synthesized through a click reaction between 4-Arm-PEG3-N3 and P(MPEGn-EPO) using Cu(PPh3)3Br/CuBr as a catalyst. Candida antarctica lipase B (CALB) was chosen as a model enzyme for the preparation of a non-covalently immobilized biocatalyst (CALB-M) via a simple adsorption process with magnesium silicate and 4-Arm-PEG3-M4-20. The immobilized lipase CALB-M16 demonstrated high enzyme activity in the resolution of racemic amines, yielding chiral amines with enantioselectivity up to 99 % ee. Circular dichroism (CD) analysis indicated the formation of helical conformation in the dendritic polyethers 4-Arm-PEG3-M16-20 in the presence of magnesium silicate at 5 °C. The polyethylene glycol side groups of 4-Arm-PEG3-M16-20 are suggested to potentially form a crown ether-like structure with magnesium ions, which could enhance steric hindrance and induce a right-handed helix. Furthermore, the helical structure of this dendritic polyether is thought to work in synergy with CALB, improving the enantioselective resolution of amines.

Synthesis of biodegradable polydisulfides from renewable resources

In this paper, we report the synthesis and preliminary characterization of polydisulfides from a renewable resource. Di-linoleic diol was first converted into dithiol via transesterification of methyl-3-mercaptopropionate catalyzed by Candida antarctica Lipase B (CALB). The kinetics of the reaction was monitored using a newly developed Thin Layer Chromatography method. The dithiol was then polymerized by Reversible Radical Recombination Polymerization (R3P), a scalable “green” polymerization process using triethylamine (TEA) catalyst, aqueous H2O2, and air. 3 wt% H2O2 yielded low molecular weight polymer, while with 30 wt% concentration DL-SS with Mn = 66,400 g/mol and polydispersity of 1.26 was obtained. 800 MHz NMR and Raman spectroscopy did not detect thiol end group signals in this polymer, indicating that it had a cyclic structure. Dithiothreitol degraded the polymer to monomer in two weeks. Full characterization of this new polymer is in progress.