重组人Fab金属螯合层析法纯化条件的研究

在重组人Fab(rh Fab)表达载体的羧基端插入六个组氨酸, 使其对金属螯合层析介质产生特异性吸附, 可用金属螯合亲和层析法进行分离纯化. 采用自制金属(铜、锌金属离子)螯合层析介质, 以pH和咪唑两种洗脱方法,对rh Fab段的纯化效果进行了探讨. 结果显示: 铜离子螯合层析介质比锌离子螯合层析介质对rh Fab的亲和能力更强; pH洗脱方法的重复性优于咪唑法; 金属铜离子螯合层析法对rh Fab进行一步纯化可得到纯度大于95%的rh Fab产品.     

金属螯合亲和层析的应用研究进展

金属螯合亲和层析是近30年来出现的一种新型的分离纯化技术,它以配基简单、吸附量大、分离条件温和、通用性强等特点,逐渐成为分离纯化蛋白质等生物工程产品最有效的技术之一.其在蛋白质、酶和核苷酸纯化以及蛋白质分析等方面具有广泛的应用.而随着研究的进一步深入,其新应用也越来越广泛的被发现.     

固定化金属螯合亲和膜纯化重组抗菌肽研究

用自行制备的固定化金属螯合亲和膜对N端含六个组氨酸标记的重组抗菌肽进行了分离纯化,并较好地解决了金属离子泄露问题.实验表明,固定化金属螯合亲和膜性能优于传统琼脂糖凝胶介质,完全适用于分离纯化含有多组氨酸标记的重组蛋白质.     

金属螯合亲和层析纯化金属硫蛋白

将二价铜离子螯合在Chelating Sepharose Fast Flow凝胶上制成亲和层析柱,锌诱导兔肝和镉诱导小鼠肝经匀浆、乙醇处理后上柱,用pH4.0的醋酸盐缓冲液平衡,再用pH5.2不同浓度的醋酸盐缓冲液分别洗脱,可得两个金属硫蛋白(MT)洗脱峰,经确定先后为MT-2和MT-1.分离方法比传统的凝胶过滤-离子交换法简单、省时,适于实验室规模分离纯化.     

金属螯合肽分离纯化及其抗氧化活性的研究进展

综述了金属螯合肽的来源、分离纯化及构效关系,分析了金属螯合肽抗氧化活性的相关研究进展,并展望了金属螯合肽的发展前景。     

重组人Fab金属螯合金层析法纯化条件的研究

在重组人Ｆａｂ表达载体的羧基端插入六个组氨酸,使其对金属螯合层析介质产生特异性吸附,可用金属螯合亲和层析法进行分离纯化。采用自制金属螯合层析介质,以ＰＨ和咪唑两种脱方法,对ｒｈＦａｂ段的纯效果进行了探讨。     

二维液相色谱法在羊草地上部总蛋白分离中的应用

取8周龄羊草的地上部分,用三氯乙酸-丙酮法沉淀总蛋白,沉淀裂解后将缓冲液置换为起始缓冲液,进行第一维色谱聚焦分离。将第一维分离收集的pH值为8.5至4.0之间的组分分别进行第二维无孔硅胶反相高效液相色谱分离,利用ProteoVue软件获得羊草植株总蛋白pI/UV图谱,即羊草植株总蛋白质表达谱。文中对二维液相色谱法分离羊草蛋白质进行了方法学的研究,在第二维分离中尝试用3种不同的洗脱梯度条件进行分离,优化二维液相色谱分离条件并与传统凝胶双向电泳进行了比较,另外还对二维液相色谱的重现性和准确性进行了检验。实验建立了利用二维液相色谱分离羊草总蛋白的技术方法。     

植物对重金属的吸收和分布

植物修复是利用植物来清除污染土壤中重金属的一项技术。该技术成功与否取决于植 物从土壤中吸取金属以及向地上部运输金属的能力。植物对金属的吸收主要取决于自由态离子活度。许多螯合剂能诱导植物对重金属的吸收。金属离子在液泡中的区域化分布是植物耐 重金属的主要原因。同时,细胞内的金属硫蛋白、植物螯合肽等蛋白质以及有机酸、氨基酸等在金属贮存和解毒方面也起重要作用。本文还论述了重金属在植物体内运输的生理及分子 方面的研究进展。     

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。     

蛋白质色谱的高效化技术

过去30年间,以基因工程和细胞融合技术为代表的现代生物技术的发展让治疗和诊断用蛋白质的规模化生产成为现实.与此同时,蛋白质色谱、膜分离等生物下游核心技术的创新也适应了这种发展.以蛋白质色谱为例,琼脂糖、纤维素和亲水性高分子聚合物等材料被广泛地应用于色谱介质的合成,其孔道结构得到一定的改良;离子交换色谱等技术日趋完善,新型色谱技术(如金属螯合亲和色谱等)不断涌现;色谱的生产效率通过过程集成和外场(如电场、磁场、超重力场等)的引入得以进一步提高.同时,蛋白质色谱也为基因组学、蛋白质组学等组学研究提供了有力的工具.     

Exploiting the interactions between poly-histidine fusion tags and immobilized metal ions

Immobilized metal affinity chromatography (IMAC) of proteins containing poly-histidine fusion tags is an efficient research tool for purifying recombinant proteins from crude cellular feedstocks at laboratory scale. Nevertheless, to achieve successful purification of large amounts of the target protein for critical therapeutic applications that demand the precise removal of fusion tags, it is important to also take into consideration issues such as protein quality, efficiency, cost effectiveness, and optimal affinity tag choice and design. Despite the many considerations described in this article, it is expected that enhanced selectivity, the primary consideration in the field of protein separation, will continue to see the use of IMAC in solving new purification challenges. In addition, the platform nature of this technology makes it an ideal choice in purifying proteins with unknown properties. Finally, the unique interaction between immobilized metal ions and poly-histidine fusion tag has enabled new developments in the areas of biosensor, immunoassay, and other analytical technologies.     

Nucleic acid separations utilizing immobilized metal affinity chromatography

Immobilized metal affinity chromatography (IMAC) is widely used for protein purification, e.g., in the isolation of proteins bearing the well-known hexahistidine affinity tag. We report that IMAC matrixes can also adsorb single-stranded nucleic acids through metal ion interactions with aromatic base nitrogens and propose that metal affinity technologies may find widespread application in nucleic acid technology. Oligonucleotide duplexes, plasmid, and genomic DNA show low IMAC binding affinity, while RNA and single-stranded oligonucleotides bind strongly to matrixes such as Cu(II) iminodiacetic acid (IDA) agarose. The affinity of yeast RNA for IDA-chelated metal ions decreases in the following order: Cu(II), Ni(II), Zn(II), and Co(II). Adsorption isotherms for 20-mer oligonucleotide homopolymers show that purines are strongly favored over pyrimidines and that double-stranded duplexes are not bound. IMAC columns have been used to purify plasmid DNA from E. coli alkaline lysates, to purify a ribozyme, to remove primers and imperfect products from PCR reactions, and to separate 20-mer oligonucleotide duplexes containing centered single-base mismatches. Potential further applications include SNP scoring, hybridization assays, and the isolation of polyadenylated messenger RNA.     

Immobilized metal-ion affinity chromatography of human antibodies and their proteolytic fragments

Immobilized metal-ion affinity chromatography (IMAC) performed with four different transition metal ions: copper(II), nickel(II), zinc(II) and cobalt(II), was used to study the adsorption properties of human polyclonal gamma-globulines (IgG), Cohn II-III fractions, and their pepsin cleaved fragments: Fab'2 and F'c. In each case, digested products showed lower affinity for metal ions, as well by decreasing pH elution as by competition with imidazole. An explanation was proposed by the presence of a histidine (His) cluster in the F'c domain of IgGs, identified by computer calculation (accessible surface area (ASA) determination) as the more probable His 433-x-His 435 sequence presented in the CH3 domain of human IgG heavy chain. As shown by IMAC and electrophoresis, F'c and undigested IgG have higher affinity for transition metal ions than Fab'2 fragments and could be then separated in one step by IMAC. When chelated Zn(II) or Co(II) are used as ligands, the Fab'2 fragment could be easily recovered under mild conditions (pH 7) in the non-retained fraction. This approach could be used as a powerful alternative to conventional protein A/G methods for the commercial preparation of non immunogen active Fab'2 fragments.     

Parameters for effective in vitro production of zinc finger nucleic acid-binding proteins

Immobilized metal affinity chromatography (IMAC) is widely used for the production of recombinant proteins for a variety of applications; however, a number of challenges are typically encountered by researchers depending on the properties of the specific proteins in question. Here, we describe technical issues we have encountered in production of recombinant zinc finger nucleic acid-binding proteins by IMAC intended for detailed and accurate in vitro analysis. The process encountered leading to a modified IMAC protocol for effective production of high-purity, native zinc finger nucleic acid-binding proteins is described in detail. The parameters with respect to solubility, lysis and redox conditions, removal of residual metal ions with chelating agents, and renaturation in the presence of divalent metal cations are described. These procedures have been extended to production of a wide array of RNA-binding proteins in our laboratory and would be relevant to a number of protein purification applications.     

Application of immobilized metal affinity chromatography in proteomics

It has been proved that the progress of proteomics is mostly determined by the development of advanced and sensitive protein separation technologies. Immobilized metal affinity chromatography (IMAC) is a powerful protein fractionation method used to enrich metal-associated proteins and peptides. In proteomics, IMAC has been widely employed as a prefractionation method to increase the resolution in protein separation. The combination of IMAC with other protein analytical technologies has been successfully utilized to characterize metalloproteome and post-translational modifications. In the near future, newly developed IMAC integrated with other proteomic methods will greatly contribute to the revolution of expression, cell-mapping and structural proteomics.     

Application of immobilized metal affinity chromatography in proteomics

It has been proved that the progress of proteomics is mostly determined by the development of advanced and sensitive protein separation technologies. Immobilized metal affinity chromatography (IMAC) is a powerful protein fractionation method used to enrich metal-associated proteins and peptides. In proteomics, IMAC has been widely employed as a prefractionation method to increase the resolution in protein separation. The combination of IMAC with other protein analytical technologies has been successfully utilized to characterize metalloproteome and post-translational modifications. In the near future, newly developed IMAC integrated with other proteomic methods will greatly contribute to the revolution of expression, cell-mapping and structural proteomics.     

Immobilized metal affinity chromatography without chelating ligands: purification of soybean trypsin inhibitor on zinc alginate beads

Immobilized metal affinity chromatography (IMAC) is a widely used technique for bioseparation of proteins in general and recombinant proteins with polyhistidine fusion tags in particular. An expensive and critical step in this process is coupling of a chelating ligand to the chromatographic matrix. This chelating ligand coordinates metal ions such as Cu(2+), Zn(2+), and Ni(2+), which in turn bind proteins. The toxicity of chemicals required for coupling and their slow release during the separation process are of considerable concern. This is an important issue in the context of purification of proteins/enzymes which are used in food processing or pharmaceutical purposes. In this work, a simpler IMAC design is described which should lead to a paradigm shift in the application of IMAC in separation. It is shown that zinc alginate beads (formed by chelating alginate with Zn(2+) directly) can be used for IMAC. As "proof of concept", soybean trypsin inhibitor was purified 18-fold from its crude extract with 90% recovery of biological activity. The dynamic binding capacity of the packed bed was 3919 U mL(-1), as determined by frontal analysis. The media could be regenerated with 8 M urea and reused five times without any appreciable loss in its binding capacity.     

Homologous human blood protein separation using immobilized metal affinity chromatography: protein C separation from prothrombin with application to the separation of factor IX and prothrombin.

Protein C (PC) is a natural anticoagulant and antithrombotic present in human blood at a concentration of 4 microg/mL. Its deficiency can result in excessive clotting and thrombosis. Protein C can be obtained from human blood plasma; however, there are other coagulant proteins in blood, including prothrombin (factor II), which is present in relatively large amounts and is one of the most active components. Protein C and prothrombin are homologous proteins with similar biochemical features; therefore, immunoaffinity chromatography is used for their separation. However, this technology is very expensive, protein C recovery and activity is low, and contamination problems with mouse antibody are likely. Immobilized metal affinity chromatography (IMAC) utilizes the protein metal-binding properties for protein separation. Protein C has twelve surface-accessible histidines, which are the major metal-binding groups for IMAC separation. After investigating metal ion-binding properties of protein C, we used an IDA-Cu column to separate protein C and prothrombin. Following protein adsorption to the column, prothrombin was washed out using a sodium phosphate buffer containing 2 mM imidazole and protein C was recovered with 15 mM imidazole in the buffer. The mild elution condition allows a high protein C activity and a high recovery. Also, this technology introduces no immunoglobulins, and it is relatively inexpensive. IMAC could replace the immunoaffinity technology for the large-scale separation of protein C from blood plasma Cohn Fraction IV-1. In addition, this work demonstrates a significant application of this technology for the separation of factor IX from prothrombin. Prothrombin has proven to be a harmful contaminant in factor IX cocktails that have been administered to humans in the treatment of hemophilia B.     

Chelator,metal ion and buffer studies for protein C separation

Protein C (PC) is the pivotal anticoagulant and antithrombotic in the human coagulation cascade. PC deficiency can result in major medical problems such as deep vein thrombosis (DVT), leading to tissue oxygen deprivation. PC treatment has no bleeding or skin necrosis problems because it circulates in the blood as a zymogen and is only activated when and where it is needed. One source of PC is transgenic animal milk. The major components in the milk, such as alpha-casein, beta-casein, kappa-casein, alpha-lactalbumin and beta-lactoglobulin, are proteins that must be separated from PC. Immobilized metal affinity chromatography (IMAC) is an inexpensive separation technology with relatively high specificity, and it has great potential for difficult protein separations. After systematic studies of different chelator, metal ion and buffers, the combination of iminodiacetic acid (IDA) and Fe was found to be effective to separate PC from major milk components. alpha-Lactalbumin and beta-lactoglobulin fell through the column in the starting buffer. PC was eluted. alpha-Casein, beta-casein, kappa-casein remained bound in the column after PC elution. This technology might be applied for PC separation from transgenic animal milk. It is very important for PC production in large quantities and at low cost to treat PC-deficient patients.     

Immobilized metal affinity chromatography in the presence of arginine

Arginine hydrochloride (ArgHCl) is a versatile solvent additive, as it suppresses protein aggregation. ArgHCl has been used for protein refolding and to solubilize proteins from loose inclusion bodies. Immobilized metal affinity chromatography (IMAC) is one of the most commonly used technologies for purification of recombinant proteins. Here we have evaluated compatibility of ArgHCl with IMAC purification for his-tag proteins. ArgHCl clearly interfered with protein binding to Ni-columns. Nevertheless, such interference was greatly reduced at ArgHCl concentration below 200 mM, demonstrating that IMAC purification can be done even in the presence of ArgHCl.