On the issue of interfacial activation of lipase in nonaqueous media

Louwrier, Ariel; Drtina, Gary J.; Klibanov, Alexander M.

doi:10.1002/(sici)1097-0290(19960405)50:1<1::aid-bit1>3.0.co;2-l

Cited by 72 publications

(8 citation statements)

References 24 publications

(1 reference statement)

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“…This result suggests that the closing of the lipase lid is caused by water, and the opening of the lipase lid is caused by an oil-water interface in oil-water twophase system. Both closing and opening cannot take place in organic solvents, which agrees with the report that interfacial activation of lipase was caused by an oil (methyl butyrate)water interface, and not by the oil-alcohol interface in a triolein-ethanol two-phase system (21). That is why the activation and inactivation of lipase here was carried out in the presence of an aqueous phase, and the activated lipase had a high activity in organic solvent.…”

Section: Resultssupporting

confidence: 91%

“…This revealed that the activated lipase was easily inactivated by water in the absence of an oil-water interface. Derewenda et al (21) reported that the lid of lipase had a high mobility in an aqueous solution and that specific molecular interactions with hydrophobic molecules affected and/or stabilized the lid. There was a subtle equilib-rium between the two conformations (open and closed) of lipase.…”

Section: Resultsmentioning

confidence: 99%

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Oil‐water interfacial activation of lipase for interesterification of triglyceride and fatty acid

Maruyama

Nakajima

Uchikawa

et al. 2000

J Americ Oil Chem Soc

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Lipase usually has little interesterification activity in organic solvents, probably owing to the absence of an oilwater interface. Lipases were processed in a two-phase hydrocarbon-water system that had an oil-water interface. Crude lipase (from Rhizopus japonicus) in a buffer and a small volume of aliphatic hydrocarbon as an oil phase were mixed and then lyophilized to remove the aqueous and oil phases. The interfacially processed lipase has a remarkable interesterification activity in n-hexane compared to crude native lipases. We postulate that this activation is caused by the oil-water interface, i.e., the interface between hydrocarbon and water makes the lipase lid open and enables the lipase to work effectively in n-hexane. Several different hydrocarbons were investigated as an oil phase, and n-tetradecane was found to be the best for interesterification. Activated lipase was successfully inactivated in a water suspension without an oil-water interface, and the inactivated lipase could be reactivated. We demonstrated that the oil (hydrocarbon)-water interface induced reversible activation to lipase for interesterificaiton.

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Section: Resultssupporting

confidence: 91%

Section: Resultsmentioning

confidence: 99%

Oil‐water interfacial activation of lipase for interesterification of triglyceride and fatty acid

Maruyama

Nakajima

Uchikawa

et al. 2000

J Americ Oil Chem Soc

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“…From Table , all BCL/MMS‐ x exhibited far higher activity than the non‐immobilized BCL in terms of the conversion of 1‐phenylethanol (C%), and the enantiomeric excess of ( S )‐1‐phenylethanol (ee S ), meanwhile, achieved the same enantiomeric excess of ( R )‐1‐phenylethyl acetate (ee P ), indicating a faster reaction rate. The result can be explained by the following reasons: (a) non‐immobilized BCL got aggregated in the organic solvent, leading to low dispersion and diffusion limitation; (b) during the process of immobilization, hydrophobic isooctane promotes the interfacial activation of the BCL, thus improving its catalytic activity; (c) the large number of mesopores of the MMS‐ x facilitated the mass transfer . These favorable factors make MMS‐ x a very suitable carrier for lipase immobilization.…”

Section: Resultsmentioning

confidence: 99%

“…Immobilization of BCL was conducted according to a procedure described previously, in which BCL was completely immobilized onto magnetic mesoporous silica (MMS‐ x ) via physical adsorption and interfacial activation . First, 0.1 g MMS‐ x was dispersed in 10 mL isooctane in a vessel, and then 0.1 mL 0.1 M pH 6.5 phosphate buffer solution (PBS), which provided “essential water” and pH, was added to the above suspension.…”

Section: Methodsmentioning

confidence: 99%

Enhancement of activity and reusability of lipase immobilized on magnetic mesoporous silica for the resolution of racemic secondary alcohols

Xue

Chunmiao

et al. 2018

J Chinese Chemical Soc

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Magnetic mesoporous silica (MMS) composites with an average mesopore size (~2.98 nm), large surface area (404–442 m2/g), and high saturated magnetization (17.7–33.5 emu/g) were successfully prepared by hydrothermal crystallization in the presence of monodisperse Fe3O4 microspheres. The as‐synthesized composites served as supports for lipase from Burkholderia cepacia (BCL) immobilization in isooctane via interfacial activation and were then employed as biocatalysts for the transesterification resolution of racemic aromatic secondary alcohols to synthesize chiral intermediates. The catalytic performance of the immobilized BCL (BCL/MMS) was notably improved compared to that of the non‐immobilized BCL, with the total conversion and enantiomeric excess reaching 50 and 99% of the maximum theoretical values, respectively. Furthermore, the magnetic BCL/MMS possessing the same textural properties and enzyme loading exhibited decreasing catalytic capability as their saturated magnetization value increased. Moreover, BCL/MMS could also be readily recycled from the reaction system by applying an external magnetic field so as to facilitate its reuse up to five cycles with retaining up to 90% of the initial activity. Its high activity, easy recovery, and excellent operational stability make the BCL/MMS a potential green catalyst for the synthesis of optically active intermediates.

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“…Among different hydrophobic polymers, Ormosils such as alkyl–alkoxysilanes shown better results than the free enzyme counterparts. This behavior of lipases is mainly due to the unique ‘lid’ structure which can be opened while exposing to any hydrophobic interface which facilitates the full expose of the binding site to the substrate . Moreover, the hydrophilic/hydrophobic balance of neighboring surfaces plays an important role in protein structure and biological activity sensitivity and subsequently towards improved structural rigidity.…”

Section: Discussionmentioning

confidence: 99%

Engineering aspects of immobilized lipases on esterification: A special emphasis of crowding, confinement and diffusion effects

Parashar

Srivastava

Dutta

et al. 2018

Engineering in Life Sciences

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Cross‐linked enzyme crystal (CLEC) and sol‐gel entrapped pseudomonas sp. lipase were investigated for the esterification of lauric acid with ethanol by considering the effects of reaction conditions on reaction rate. The activation energy for the reaction was estimated to be 1097.58 J/mol and 181.75 J/mol for sol‐gel and CLEC entrapped lipase respectively. CLEC lipase exhibited a marginal internal diffusion effect on reaction rate over sol‐gel lipases and found to be interesting. The overall reaction mechanism was found to conform to the Ping Pong Bi Bi mechanism. The higher efficiency of sol‐gel lipases over CLEC lipases in esterification reaction is mainly due to the combined effects of crowding, confinement and diffusional limitations.

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On the issue of interfacial activation of lipase in nonaqueous media

Cited by 72 publications

References 24 publications

Oil‐water interfacial activation of lipase for interesterification of triglyceride and fatty acid

Oil‐water interfacial activation of lipase for interesterification of triglyceride and fatty acid

Enhancement of activity and reusability of lipase immobilized on magnetic mesoporous silica for the resolution of racemic secondary alcohols

Engineering aspects of immobilized lipases on esterification: A special emphasis of crowding, confinement and diffusion effects

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