Recovery of lysozyme from hen egg white by selective magnetic cake filtration

A new concept for the improvement of the downstream processing and purification is the so‐called magnetic separation. By using surface functionalized magnetic substrate particles, which selectively adsorb the target product, it can be directly separated out of a crude bioprocess stream. These methods are already used for analytical purposes, where only small amounts of functionalized particles are necessary. To apply the same concept at a larger scale, effective and economical procedures have to be provided. First, suitable process equipment has to be developed. Second, the magnetic particles have to be manufactured with a stable surface functionalization and long‐term stability for their reuse. Up to now mainly high‐gradient magnetic separation filter devices are applied for selective magnetic separation. They consist of a magnetic matrix in which the magnetic particles are trapped. In this work, a new magnetic filter is introduced that overcomes the capacity limitations of the current high‐gradient magnetic separation technology. The principle is demonstrated by selective recovery of lysozyme from hen egg white. Prior to the separation experiments magnetic beads with a strong acid cation‐exchange surface functionalization are synthesized. The separation procedure is implemented in only one unit operation. With the implementation of the displacement elution sequence lysozyme can be separated out of a hen egg white solution with a purification factor of PF=36 and a purity P=0.83.     

Real-time PCR to study the sequence specific magnetic purification of DNA

The performance of various molecular techniques using complex biological samples greatly depends on the efficient separation and purification of DNA targets. In recent years, magnetic separation technology making use of small magnetic beads, has gained immense popularity. Most of these methods rely on the non-specific adsorption of DNA/RNA. However, as presented here, when functionalizing the beads with complementary DNA probes, the target of interest can selectively be isolated. Such sequence specific purification was evaluated for short DNA targets by means of simple fluorescent measurements, resulting in purification efficiencies around 80%. Besides standard fluorescent techniques, a real-time PCR (qPCR) method was applied for monitoring the purification of longer DNA targets. This qPCR method was specifically optimized for directly quantifying the purification efficiency of low concentrated DNA targets bound to magnetic beads. Additionally, parameters possibly affecting the magnetic isolation, including the length of the used capture probe or the hybridization location, were investigated. Using optimized conditions in combination with qPCR, purification efficiencies between 60% and 80% were observed and this over a large concentration window. These data also show the power of a direct qPCR approach to monitor the magnetic isolation of DNA at very low concentrations.     

Magnetic separation techniques: their application to medicine

Summary Whilst separation techniques relying on gravitational forces have become relatively sophisticated in their application to biology the same is not true for magnetic separation procedures. The use of the latter has been limited to the few cells which contain paramagnetic iron. However with the development of several different types of magnetic particles and selective delivery system (e.g. monoclonal antibodies) the use of magnetic separation techniques is growing rapidly. This review describes the different types of particles currently available, the magnetic separation technique applied to the different magnetic compounds and illustrates major uses to which magnetic separation procedures are currently applied in the area of biology and medicine.Abbreviations WBC White blood cells - RBC Red blood cells - Met-Hb Methemoglobin - SRBC Sheep red blood cells - Ig Immunoglobulin - FACS Fluorescent activated cell sorter     

Protein purification using magnetic adsorbent particles

The application of functionalised magnetic adsorbent particles in combination with magnetic separation techniques has received considerable attention in recent years. The magnetically responsive nature of such adsorbent particles permits their selective manipulation and separation in the presence of other suspended solids. Thus, it becomes possible to magnetically separate selected target species directly out of crude biological process liquors (e.g. fermentation broths, cell disruptates, plasma, milk, whey and plant extracts) simply by binding them on magnetic adsorbents before application of a magnetic field. By using magnetic separation in this way, the several stages of sample pretreatment (especially centrifugation, filtration and membrane separation) that are normally necessary to condition an extract before its application on packed bed chromatography columns, may be eliminated. Magnetic separations are fast, gentle, scaleable, easily automated, can achieve separations that would be impossible or impractical to achieve by other techniques, and have demonstrated credibility in a wide range of disciplines, including minerals processing, wastewater treatment, molecular biology, cell sorting and clinical diagnostics. However, despite the highly attractive qualities of magnetic methods on a process scale, with the exception of wastewater treatment, few attempts to scale up magnetic operations in biotechnology have been reported thus far. The purpose of this review is to summarise the current state of development of protein separation using magnetic adsorbent particles and identify the obstacles that must be overcome if protein purification with magnetic adsorbent particles is to find its way into industrial practice.     

Analysis and isolation of human transferrin receptor using the OKT-9 monoclonal antibody covalently crosslinked to magnetic beads.

A method is described for the use of magnetic beads as a solid phase for the immunoprecipitation of labeled proteins. The anti-human transferrin receptor monoclonal antibody OKT-9 has been coupled to sheep anti-mouse IgG1-coated magnetic beads using the crosslinking agent dimethyl pimelimidate. The transferrin receptor is readily detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography following immunoprecipitation from 35S-labeled cell lysates. When compared with precipitations using OKT-9 coupled to protein G Sepharose the magnetic beads result in fewer nonspecific bands. The protocol described is generally applicable to the identification of labeled proteins. In addition, because magnetic beads are amenable to covalent crosslinking procedures they can be used for the purification of proteins from complex mixtures. Covalently crosslinked OKT-9 sheep anti-mouse IgG1-coated magnetic beads have been used to affinity purify unlabeled transferrin receptor from cell lysates giving comparable purity and yield to transferrin Sepharose isolated transferrin receptor. The major advantages offered by magnetic beads compared to conventional affinity matrices are low nonspecific binding and the rapidity with which the purification can be performed.     

Bioseparation using affinity techniques.

Bioseparation of proteins from dilute solutions using different novel affinity procedures is reviewed. Emphasis is also placed on the quality of the product separated. Whenever possible, physical insights into the separation procedure are provided, besides indicating suitable directions where appropriate further research may be carried out. The procedures analyzed are different affinity chromatographic techniques, affinity separation using liquid perfluorocarbon supports, water soluble nonionic surfactants for affinity bioseparations, affinity cross-flow filtration, bioaffinity separation using reversed micelles, affinity precipitation and dual-functional affinity protein purification.     

A convenient procedure for purification of thymidylate synthase from L1210 cells

Several laboratories have described procedures for purification of thymidylate synthase (TMP synthase) that utilize folates or folate analogs covalently attached to a matrix. The principle of separation is the formation of a ternary complex between dUMP, TMP synthase, and the bound ligand and the subsequent elution of the enzyme with buffers that do not contain dUMP. We have successfully used 10-formylfolic acid as the bound ligand for the purification of TMP synthase. As compared to other ligands that have been used, 10-formylfolic acid has the advantages that it can be easily synthesized, it is stable, and the enzyme is eluted as a sharp peak. Application of this procedure to L1210 leukemia cells gave 1765-fold purification of TMP synthase with a recovery of 39%. The native enzyme had a molecular weight of 78,000, which is about the same as that reported.     

Bioseparation and bioanalytical techniques in environmental monitoring

The growing use of antibody-based separation methods has paralleled the expansion of immunochemical detection methods in moving beyond the clinical diagnostic field to applications in environmental monitoring. In recent years high-performance immunoaffinity chromatography, which began as a separation technique in biochemical and clinical research, has been adapted for separating and quantifying environmental pollutants. Bioaffinity offers a selective biological basis for separation that can be incorporated into a modular analytical process for more efficient environmental analysis. The use of immunoaffinity chromatography for separation complements the use of immunoassay for detection. A widely used immunochemical detection method for environmental analyses is enzyme immunoassay. The objective of this paper is to review the status of bioaffinity-based analytical procedures for environmental applications and human exposure assessment studies. Environmental methods based on bioaffinity range from mature immunoassays to emerging techniques such as immunosensors and immunoaffinity chromatography procedures for small molecules.     

Magnetic Precipitation: A New Platform for Protein Purification

One of the trends in downstream processing comprises the use of “anything‐but‐chromatography” methods to overcome the current downfalls of standard packed‐bed chromatography. Precipitation and magnetic separation are two techniques already proven to accomplish protein purification from complex media, yet never used in synergy. With the aim to capture antibodies directly from crude extracts, a new approach combining precipitation and magnetic separation is developed and named as affinity magnetic precipitation. A precipitation screening, based on the Hofmeister series, and a commercial precipitation kit are tested with affinity magnetic particles to assess the best condition for antibody capture from human serum plasma and clarified cell supernatant. The best conditions are obtained when using PEG3350 as precipitant at 4 °C for 1 h, reaching 80% purity and 50% recovery of polyclonal antibodies from plasma, and 99% purity with 97% recovery yield of anti‐TNFα mAb from cell supernatants. These results show that the synergetic use of precipitation and magnetic separation can represent an alternative for the efficient capture of antibodies.     

嗜热四膜虫有性后代的分离纯化

在实验条件下诱导四膜虫种群交配进行有性生殖时,交配后的种群中除有性后代外,还会混杂一定比例的亲本细胞,而高纯度的有性后代是研究四膜虫一些基本生物学问题的重要基础。本研究利用四膜虫交配时不能摄食并且新产生的有性后代几小时后才恢复摄食能力的特性,以嗜热四膜虫(Tetrahymenathermophila)交配种群为对象,在其有性生殖阶段后期向交配体系中加入Fe3O4磁性纳米颗粒,未交配的亲本细胞由于能够摄入磁性颗粒而具有磁性;再利用有性后代和未交配细胞的磁性差异,在磁场作用下将有性后代分离纯化出来。通过优化过柱分离的时间点、分离柱的口径、分离柱中铁粉/石英粉的质量等分离条件,有性后代的分离纯度及收率均能达到98%以上。该分离方法亦可为其他种四膜虫或纤毛虫有性后代的分离纯化提供借鉴。     

蛋白质纯化技术研究进展

蛋白质组学研究的基础就是蛋白质的分离。对于天然蛋白来说,可能需要一系列的纯化步骤才能获得纯度满足研究要求的蛋白质,但是蛋白质在分离过程中常常由于溶液环境变化或外力作用造成构象变化而引起失活。本文首先介绍了常用的蛋白质分离纯化技术及其研究进展,包括膜分离技术、沉淀分离技术、电泳分离技术以及层析分离技术等常用的蛋白质纯化技术,总结了现有技术存在的问题,并对近年来发展的新型蛋白质分离技术--非对称流场流分离技术进行了介绍和展望。     

High-gradient magnetic affinity separation of trypsin from porcine pancreatin

We introduce a robust and scale-flexible approach to macromolecule purification employing tailor-made magnetic adsorbents and high-gradient magnetic separation technology adapted from the mineral processing industries. Detailed procedures for the synthesis of large quantities of low-cost defined submicron-sized magnetic supports are presented. These support materials exhibit unique features, which facilitate their large-scale processing using high magnetic field gradients, namely sufficiently high magnetization, a relatively narrow particle size distribution and ideal superparamagnetism. Following systematic optimization with respect to activation chemistry, spacer length and ligand density, conditions for preparation of effective high capacity (Q(max) = 120 mg g(-1)) strongly interacting (Kd < 0.3 microm) trypsin-binding adsorbents based on immobilized benzamidine were established. In small-scale studies approximately 95% of the endogenous trypsin present in a crude porcine pancreatin feedstock was recovered with a purification factor of approximately 4.1 at the expense of only a 4% loss in alpha-amylase activity. Efficient recovery of trypsin from the same feedstock was demonstrated at a vastly increased scale using a high-gradient magnetic separation system to capture loaded benzamidine-linked adsorbents following batch adsorption. With the aid of a simple recycle loop over 80% of the initially adsorbed trypsin was recovered in-line with an overall purification factor of approximately 3.5.     

Isolation of antigen-specific B cells

Cell separation techniques are important in immunology. Major cell populations can be separated successfully with high purity. However, isolation of cells which are specific for particular antigens is more challenging because of the relatively small numbers of antigen-specific cells, and the lack of independent markers available to determine the purity of the isolated population. In this review, the literature describing three principal techniques used to separate antigen-specific cells has been reviewed. Particular emphasis has been placed on yield and purity; the two most important parameters of any purification method. The most promising isolation methods have used immunomagnetic sorting and multiparametric flow cytometric analysis.     

Identification and characterization of lipids from endosomes purified by electromagnetic chromatography

Traditional separation techniques do not yield endolysosomes of sufficient purity to permit detailed biochemical characterization of this important class of intracellular vesicles. Here, we have used a magnetic chromatography technique to isolate the endosomes from rat peritoneal macrophages and studied their lipid composition. Electromagnetic isolation works by retention of colloidal iron containing vesicles on magnetic column. The data suggested that both early and late endosomes were rich in cholesterol, whereas sphingomyelin (SM) and specific phospholipids like phosphatidylcholine. phosphatidylethanolamine, phosphatidylglycerol and phosphatidylserine are enriched in the late compartments. Our results also indicated that the purified fractions are enriched in raft lipids like SM, but not in cholesterol. The endosomal purification method described here yields pure endosomes with little or no contamination from mitochondria and hence could be used for further biochemical and marker analysis, giving insight into mechanisms of endocytic traffic.     

Centrifugal partition chromatography as a tool for preparative purification of pea albumin with enhanced yields

A new procedure including the use of centrifugal partition chromatography (CPC) is proposed to purify PA1b and its isoforms. These pea (Pisum sativum L.) seed proteins are toxic against weevils and can be used as an environment-friendly insecticide. CPC was applied to a whole albumin fraction prepared from pea flour. The butanol:aqueous TFA system used in CPC allowed the separation of PA1b from other albumins and a degree of purification above 95%. Compared to analytical procedures based on methanol extraction, anion exchange and then reversed-phase chromatography (RPC), CPC recovered PA1b in much better yield, which is indispensable for large-scale purification of a biodegradable insecticide.     

A METHOD FOR THE FRACTIONATION AND PURIFICATION OF SEA URCHIN SPERM

Procedures for fractionation and purification of sea urchin sperm subunits were studied. Fragmentation of cells was observed rather than fractionation of cell subunits when classic sonication or homogenization techniques were used. Calcium shock in alcohol solution which successfully removes Protozoa cilia was not effective in removing sperm flagella. Alcohol was found to induce cohesion among whole sperm rendering separation of isolated subunits by centrifugation impossible. Calcium shock without alcohol in the medium was not effective in achieving dissociation of sperm subunits.
Successful fractionation of sperm subunits was achieved by application of a stepwise vortex-shearing action in a 0.22 micron filtered calcium-free medium. Analysis by Nomarski optics indicated little or no cellular fragmentation. Centrifugation with various discontinuous sucrose-sea water solutions proved to be a successful technique to purify the fractionated heads, midpieces, and tails.
The procedures reported here can be used to obtain fractionated and purified sperm cell heads, midpieces, and tails. These procedures do not require enzyme, homogenization, or sonication treatment of the material.     

Magnetic particles for the separation and purification of nucleic acids

Nucleic acid separation is an increasingly important tool for molecular biology. Before modern technologies could be used, nucleic acid separation had been a time- and work-consuming process based on several extraction and centrifugation steps, often limited by small yields and low purities of the separation products, and not suited for automation and up-scaling. During the last few years, specifically functionalised magnetic particles were developed. Together with an appropriate buffer system, they allow for the quick and efficient purification directly after their extraction from crude cell extracts. Centrifugation steps were avoided. In addition, the new approach provided for an easy automation of the entire process and the isolation of nucleic acids from larger sample volumes. This review describes traditional methods and methods based on magnetic particles for nucleic acid purification. The synthesis of a variety of magnetic particles is presented in more detail. Various suppliers of magnetic particles for nucleic acid separation as well as suppliers offering particle-based kits for a variety of different sample materials are listed. Furthermore, commercially available manual magnetic separators and automated systems for magnetic particle handling and liquid handling are mentioned.     

Solution-phase library generation: methods and applications in drug discovery

Solution-phase high throughput synthesis has emerged as a powerful method for the rapid generation of chemical libraries. The success of this approach is largely due to the development of novel synthetic methodologies that expedite the preparation of compounds. Several isolation/purification techniques have also been developed to eliminate the time-consuming purification procedures often associated with solution-phase chemistry. These methods are amenable to parallel synthesis and combinatorial strategies and can be fully automated. In addition, the compound libraries generated using solution-phase high throughput synthesis have been used to accelerate both lead identification and lead optimization programs at various companies.     

Purification of Proteins by the Use of Hydrophobic Zeolite Y

Hydrophobic zeolite Y can be used as a fast and efficient and inexpensive matrix in the purification of proteins from crude extracts. Preferably the zeolite can be used in the first purification step, replacing the commonly used precipitation techniques with (NH₄)₂SO₄ or ethanol. The time required for the zeolite prefractionation was a few hours compared to the much more time consuming precipitation procedure which demands centrifugation and subsequent dialysis. Proteins can be adsorbed on the zeolite either in order to remove undesired proteins or to be subsequently eluted from the zeolite in order to achieve purification and concentration. Removal of undesired proteins is exemplified by the purification of horseradish peroxidase from a crude extract. The zeolite procedure enhanced the specific activity five times and provided a yield similar to that which was obtained by the use of standard procedures, (NH₄)₂SO₄ fractionation and ion-exchange chromatography. Binding and subsequent elution of proteins from the zeolite is exemplified by the purification of monoclonal antibodies from hybridoma culture supernatants. Proteins were desorbed from the zeolite by the use of polyethylene glycol 600 and this procedure yielded a purification factor of 5.     

Separation procedures for phosphatidylserines

This paper reviews working procedures for the separation of phosphatidylserines (PS) in complex sample matrices. It begins with an introductory overview of important aspects of PS involvement in cellular lipid biochemistry. The main body of the review describes various procedures for the extraction, isolation, purification, and separation of the PS class and its molecular species in tissue samples. Published high-performance liquid chromatographic methods are summarized to demonstrate the variability and versatility of separation techniques. Factors influencing normal-phase and reversed-phase separations are delineated. The last section covers selected chemical derivatization procedures useful for enhancing the separation efficiency and detection sensitivity and specificity.