酶的固定化技术最新研究进展

酶是一种高效、绿色、应用广泛的生物催化剂,因其固定化形态在多种性质上均优于游离态,酶固定化技术应运而生并不断发展。我国固定化技术研究始于20世纪70年代,目前固定化酶在食品、医疗、能源、环境治理等领域得到了广泛的应用,但现有固定化技术仍存在适用范围小、成本较高等缺陷。因此,在较为成熟的传统固定化技术基础上,研究者们对新型固定化技术的研究与创新进行了大量尝试,形成了一批以固定化载体和固定化方式为核心的新型固定化技术。文中作者结合团队十余年对固定化技术的研究和理解,归纳介绍了新型酶固定化技术的发展方向和应用趋势,并阐述了对固定化技术未来发展的理解和建议。     

固定化酶及其应用研究进展

酶作为一种生物催化剂 ,一经发现就被人们广泛应用在酿造、食品、医药等领域。由于酶可以在常温、常压等温和的反应条件下高效地催化反应 ,一些难以进行的化学反应在酶的催化下能顺利地完成。酶的开发利用在2 0世纪得到了巨大的发展 ,但由于酶一般必需在温和的条件下才有催化作用 ,在实际运用中也就带来了很多问题 ,从而限制了酶制剂产品的使用和开发 ,固定化酶就是在这种情况下产生的。1　固定化酶简介1916年 Nelson和 Griffin最先发现了酶的固定化现象后 ,科学家就开始了固定化酶的研究工作。 196 9年日本一家制药公司第 1次将固定化的酰…     

Polymer materials for enzyme immobilization and their application in bioreactors

Enzymatic catalysis has been pursued extensively in a wide range of important chemical processes for their unparalleled selectivity and mild reaction conditions. However, enzymes are usually costly and easy to inactivate in their free forms. Immobilization is the key to optimizing the in-service performance of an enzyme in industrial processes, particularly in the field of non-aqueous phase catalysis. Since the immobilization process for enzymes will inevitably result in some loss of activity, improving the activity retention of the immobilized enzyme is critical. To some extent, the performance of an immobilized enzyme is mainly governed by the supports used for immobilization, thus it is important to fully understand the properties of supporting materials and immobilization processes. In recent years, there has been growing concern in using polymeric materials as supports for their good mechanical and easily adjustable properties. Furthermore, a great many work has been done in order to improve the activity retention and stabilities of immobilized enzymes. Some introduce a spacer arm onto the support surface to improve the enzyme mobility. The support surface is also modified towards biocompatibility to reduce non-biospecific interactions between the enzyme and support. Besides, natural materials can be used directly as supporting materials owning to their inert and biocompatible properties. This review is focused on recent advances in using polymeric materials as hosts for lipase immobilization by two different methods, surface attachment and encapsulation. Polymeric materials of different forms, such as particles, membranes and nanofibers, are discussed in detail. The prospective applications of immobilized enzymes, especially the enzyme-immobilized membrane bioreactors (EMBR) are also discussed.     

融合酶的设计和应用研究进展

酶的分子改造和重新设计是解决酶催化工业应用瓶颈的重要途径。基于融合蛋白设计的融合酶技术是分子酶工程的一个研究热点,已逐渐应用于多功能酶和酶靠近效应的构建与控制研究中,显示出重要的理论和应用研究价值。文中对近年来融合酶的分子设计策略和应用研究的进展进行了综述。首先介绍了融合酶的概念和特点,并对最近研究中出现的融合酶构建策略进行了归纳总结,重点阐述了不同种类连接肽对融合酶的影响及其可能机理。同时,对目前融合酶的应用研究进行了归纳和讨论。最后,结合本实验室的研究,指出了融合酶领域的关键问题并对其发展方向进行了探讨和展望。     

A simple laboratory experiment for teaching enzyme immobilization with urease and its application in blood urea estimation

An experiment is described in which students carry out urease purification, immobilization and its application in blood urea estimation. Urease from pigeonpea is partially purified using acetone fractionation and then immobilized on calcium alginate in the form of beads. The immobilized enzyme has a better shelf-life at 4°C than soluble enzyme. Various aspects of enzyme immobilization are discussed. Blood urea estimation is carried out with immobilized enzyme beads and the beads can be used repeatedly for this purpose making it an economical procedure compared to commercial kits.     

Recent trends using natural polymeric nanofibers as supports for enzyme immobilization and catalysis

All the disciplines of science, especially biotechnology, have given continuous attention to the area of enzyme immobilization. However, the structural support made by material science intervention determines the performance of immobilized enzymes. Studies have proven that nanostructured supports can maintain better catalytic performance and improve immobilization efficiency. The recent trends in the application of nanofibers using natural polymers for enzyme immobilization have been addressed in this review article. A comprehensive survey about the immobilization strategies and their characteristics are highlighted. The natural polymers, e.g., chitin, chitosan, silk fibroin, gelatin, cellulose, and their blends with other synthetic polymers capable of immobilizing enzymes in their 1D nanofibrous form, are discussed. The multiple applications of enzymes immobilized on nanofibers in biocatalysis, biosensors, biofuels, antifouling, regenerative medicine, biomolecule degradation, etc.; some of these are discussed in this review article.     

Recent progress in developing enzyme and tissue-based membrane electrodes

The article summarizes the work of this laboratory on the design of eleven types of amperometricpenzyme electrodes mainly based on the CLARK oxygen sensor in connection with cross-linked oxidases. Special attention is paid to the sensors coupled with plant tissue slice for determining L-ascorbic acid and phenols. A “second generation” bienzyme electrode is reported which enables tow analytes forming a metabolic couple to be determined simultaneously. A principle of the first useful model of conductimetric enzyme electrode for assaying urea and arginase is also presented.     

固定化细胞技术及其应用研究进展

细胞固定技术是将具有特定生理功能的生物细胞用一定的方法进行固定,并以其作为生物催化剂加以利用的一门技术。相对于游离的单细胞,固定化细胞可简化生产工艺,降低生产成本。本文回顾了细胞固定技术在制备方法和载体材料等方面的研究进展,并总结了近几年来固定化细胞技术在新能源开发、食品加工及环境污染物处理中的应用,对其发展前景进行展望。     

Peptide-modified surfaces for enzyme immobilization

Background

Chemistry and particularly enzymology at surfaces is a topic of rapidly growing interest, both in terms of its role in biological systems and its application in biocatalysis. Existing protein immobilization approaches, including noncovalent or covalent attachments to solid supports, have difficulties in controlling protein orientation, reducing nonspecific absorption and preventing protein denaturation. New strategies for enzyme immobilization are needed that allow the precise control over orientation and position and thereby provide optimized activity.

Methodology/Principal Findings

A method is presented for utilizing peptide ligands to immobilize enzymes on surfaces with improved enzyme activity and stability. The appropriate peptide ligands have been rapidly selected from high-density arrays and when desirable, the peptide sequences were further optimized by single-point variant screening to enhance both the affinity and activity of the bound enzyme. For proof of concept, the peptides that bound to β-galactosidase and optimized its activity were covalently attached to surfaces for the purpose of capturing target enzymes. Compared to conventional methods, enzymes immobilized on peptide-modified surfaces exhibited higher specific activity and stability, as well as controlled protein orientation.

Conclusions/Significance

A simple method for immobilizing enzymes through specific interactions with peptides anchored on surfaces has been developed. This approach will be applicable to the immobilization of a wide variety of enzymes on surfaces with optimized orientation, location and performance, and provides a potential mechanism for the patterned self-assembly of multiple enzymes on surfaces.     

嗜盐微生物的工业应用研究及进展

嗜盐微生物是一类生长于高盐环境的微生物,在新型生物化工产业及生物修复领域具有突出的应用潜力。本文简要介绍了嗜盐微生物的种类、生理特性,着重阐述了嗜盐微生物产生的活性物质在工业生产上的应用价值和开发前景,总结了近年来国内外在嗜盐微生物工业应用上的研究进展,对嗜盐微生物的应用研究做了概括。     

Recent advances in immobilization strategies for glycosidases

Glycans play important biological roles in cell‐to‐cell interactions, protection against pathogens, as well as in proper protein folding and stability, and are thus interesting targets for scientists. Although their mechanisms of action have been widely investigated and hypothesized, their biological functions are not well understood due to the lack of deglycosylation methods for large‐scale isolation of these compounds. Isolation of glycans in their native state is crucial for the investigation of their biological functions. However, current enzymatic and chemical deglycosylation techniques require harsh pretreatment and reaction conditions (high temperature and use of detergents) that hinder the isolation of native glycan structures. Indeed, the recent isolation of new endoglycosidases that are able to cleave a wider variety of linkages and efficiently hydrolyze native proteins has opened up the opportunity to elucidate the biological roles of a higher variety of glycans in their native state. As an example, our research group recently isolated a novel Endo‐β‐N‐acetylglucosaminidase from Bifidobacterium longum subsp. infantis ATCC 15697 (EndoBI‐1) that cleaves N‐N′‐diacetyl chitobiose moieties found in the N‐linked glycan (N‐glycan) core of high mannose, hybrid, and complex N‐glycans. This enzyme is also active on native proteins, which enables native glycan isolation, a key advantage when evaluating their biological activities. Efficient, stable, and economically viable enzymatic release of N‐glycans requires the selection of appropriate immobilization strategies. In this review, we discuss the state‐of‐the‐art of various immobilization techniques (physical adsorption, covalent binding, aggregation, and entrapment) for glycosidases, as well as their potential substrates and matrices. © 2016 American Institute of Chemical Engineers Biotechnol. Prog., 33:104–112, 2017     

Glucose-isomerizing enzyme from Actinomyces olivocinereus and its immobilization on aminosilochrome]

Glucose-isomerizing enzyme was isolated from the culture of Actinomyces olivocinereus. It was purified by the chromatography on DEAE-cellulose. The samples of glucose-isomerasing enzyme are homogeneous according to the results of analytical electrophoresis and ultracentrifugation. Glucose-isomerase is more stable than soluble one. The pH-optima of soluble and immobilized enzymes are 8.5 and 7.5, respectively. The temperature optimum of immobilized enzyme, Km, V, and activation energy do not change during immobilization. The immobilized sample has 58% activity of soluble enzyme.     

Hydrophobic salt-modified Nafion for enzyme immobilization and stabilization

Over the last decade, there has been a wealth of application for immobilized and stabilized enzymes including biocatalysis, biosensors, and biofuel cells. In most bioelectrochemical applications, enzymes or organelles are immobilized onto an electrode surface with the use of some type of polymer matrix. This polymer scaffold should keep the enzymes stable and allow for the facile diffusion of molecules and ions in and out of the matrix. Most polymers used for this type of immobilization are based on polyamines or polyalcohols - polymers that mimic the natural environment of the enzymes that they encapsulate and stabilize the enzyme through hydrogen or ionic bonding. Another method for stabilizing enzymes involves the use of micelles, which contain hydrophobic regions that can encapsulate and stabilize enzymes. In particular, the Minteer group has developed a micellar polymer based on commercially available Nafion. Nafion itself is a micellar polymer that allows for the channel-assisted diffusion of protons and other small cations, but the micelles and channels are extremely small and the polymer is very acidic due to sulfonic acid side chains, which is unfavorable for enzyme immobilization. However, when Nafion is mixed with an excess of hydrophobic alkyl ammonium salts such as tetrabutylammonium bromide (TBAB), the quaternary ammonium cations replace the protons and become the counter ions to the sulfonate groups on the polymer side chains (Figure 1). This results in larger micelles and channels within the polymer that allow for the diffusion of large substrates and ions that are necessary for enzymatic function such as nicotinamide adenine dinucleotide (NAD). This modified Nafion polymer has been used to immobilize many different types of enzymes as well as mitochondria for use in biosensors and biofuel cells. This paper describes a novel procedure for making this micellar polymer enzyme immobilization membrane that can stabilize enzymes. The synthesis of the micellar enzyme immobilization membrane, the procedure for immobilizing enzymes within the membrane, and the assays for studying enzymatic specific activity of the immobilized enzyme are detailed below.     

Novel method for cell immobilization and its application for production of organic acid

AIMS: The aim was to develop a novel and simple technique for the entrapment of fungal hyphae. METHODS AND RESULTS: A novel immobilization technique was developed by using a structural fibrous network (SFN) of papaya wood as an immobilizing matrix. The technique is simple and a stable entrapment was achieved simply by inoculating the Aspergillus terreus hyphae within culture medium containing SFN pieces for 3 days, without any prior chemical treatment. Results show that SFN has no detrimental effect both on growth and bioactivity of fungi. A 23.5% increase in the itaconic acid production by SFN-immobilized A. terreus was noted when compared with free biomass. SFN-immobilized fungal biomass retained 95% itaconic acid productivity for five repeated batch cycles, 7 days each, without any disintegration/release of hyphae in the production medium. CONCLUSIONS: This is the first report on the use of SFN, a structural material, as an immobilizing matrix for the entrapment of any kind of microbial biomass and its application in organic acid. SIGNIFICANCE AND IMPACT OF THE STUDY: The low cost of SFN and simplicity of the technique applied for immobilization of fungal hyphae within/onto SFN make its use ideal for the immobilization of fungal biomass to produce commercially valuable products.     

One-step enzyme extraction and immobilization for biocatalysis applications

An extraction/immobilization method for HIs(6) -tagged enzymes for use in synthesis applications is presented. By modifying silica oxide beads to be able to accommodate metal ions, the enzyme was tethered to the beads after adsorption of Co(II). The beads were successfully used for direct extraction of C. antarctica lipase B (CalB) from a periplasmic preparation with a minimum of 58% activity yield, creating a quick one-step extraction-immobilization protocol. This method, named HisSi Immobilization, was evaluated with five different enzymes [Candida antarctica lipase B (CalB), Bacillus subtilis lipase A (BslA), Bacillus subtilis esterase (BS2), Pseudomonas fluorescence esterase (PFE), and Solanum tuberosum epoxide hydrolase 1 (StEH1)]. Immobilized CalB was effectively employed in organic solvent (cyclohexane and acetonitrile) in a transacylation reaction and in aqueous buffer for ester hydrolysis. For the remaining enzymes some activity in organic solvent could be shown, whereas the non-immobilized enzymes were found inactive. The protocol presented in this work provides a facile immobilization method by utilization of the common His(6) -tag, offering specific and defined means of binding a protein in a specific location, which is applicable for a wide range of enzymes.     

Polymerizing immobilization of acrylamide-modified nucleic acids and its application

The immobilization of nucleic acids on solid supports has been widely used in the detection of DNA and other biomolecules in sensor technology. Because three dimensional (3-D) hydrogel matrixes offer significant advantages for capturing probes over more conventional two dimensional (2-D) rigid substrates and the ability to provide a solution-mimicking environment, they are becoming increasingly attractive as desired supports for bio-analysis. Acrylamide-modified nucleic acids and acrylamide monomers being polymerized directly to immobilize nucleic acids is only one-step chemical process which is not interfered by exterior surroundings, and the 3-D polyacrylamide gel fabricated by this method is not required to be activated by some labile chemical treatments. Moreover, the attachment is extremely stable to withstand the cycling process involved in the polymerase chain reaction (PCR). In this paper, the development of polymerizing immobilization of acrylamide-modified nucleic acids is reviewed, and its applications in DNA sequence high-throughput analysis including mutation analysis and the whole genome sequencing are summarized.