A Simplified Method for the Efficient Refolding and Purification of Recombinant Human GM-CSF

Human granulocyte macrophage colony-stimulating factor (hGM-CSF) is a haematopoietic growth factor and proinflammatory cytokine. Recombinant hGM-CSF is important not only as a research tool but also as a biotherapeutic. However, rhGM-CSF expressed in E. coli is known to form inclusion bodies of misfolded, aggregated protein. Refolding and subsequent purification of rhGM-CSF from inclusion bodies is difficult with low yields of bioactive protein being produced. Here we describe a method for the isolation, refolding and purification of bioactive rhGM-CSF from inclusion bodies. The method is straightforward, not requiring extensive experience in protein refolding nor purification and using standard laboratory equipment.     

用疏水色谱法复性并同时纯化重组人粒细胞-巨噬细胞集落刺激因子

目的：建立一种简单、快速复性并同时纯化大肠杆菌表达的重组人粒细胞一巨噬细胞集落刺激因子（rhGM-CSF）的方法。方法：研究rhGM-CSF在疏水色谱（HIC）上的复性和纯化机理,并对固定相和流动相进行选择和优化,包括固定相配基、流动相中盐的种类、流动相pH值、流动相中还原型谷胱甘肽（GSH）和氧化型谷胱甘肽（GSSG）的比例,以及流动相中尿素的浓度。结果：优化后的固定相为PEG600,流动相中的盐为（NH4）2SO4,流动相pH值为7．0,流动相中添加2．0mol／L尿素、1．8mmol／LGSH和0-3mmol／LGSSG。在优化条件下,HIC可使rhGM-CSF在分离纯化的同时得到复性,比活达1．58×10^7U／mg,纯度为95．7％,质量回收率为56．8％。结论：建立的疏水色谱复性和纯化工艺可简化操作步骤,缩短生产周期。     

Refolding of recombinant human interferon ��-2a from Escherichia coli by urea gradient size exclusion chromatography

Protein refolding is still a puzzle in the production of recombinant proteins expressed as inclusion bodies (IBs) in Escherichia coli. Gradient size exclusion chromatography (SEC) is a recently developed method for refolding of recombinant proteins in IBs. In this study, we used a decreasing urea gradient SEC for the refolding of recombinant human interferon ??-2a (rhIFN??-2a) which was overexpressed as IBs in E. coli. In chromatographic process, the denatured rhIFN??-2a would pass along the 8.0?C3.0 M urea gradient and refold gradually. Several operating conditions, such as final concentration of urea along the column, gradient length, the ratio of reduced to oxidized glutathione and flow rate were investigated, respectively. Under the optimum conditions, 1.2 × 10⁸ IU/mg of specific activity and 82% mass recovery were obtained from the loaded 10 ml of 1.75 mg/ml denatured protein, and rhIFN??-2a was also purified during this process with the purity of higher than 92%. Compared with dilution method, urea gradient SEC was more efficient for the rhIFN??-2a refolding in terms of specific activity and mass recovery.     

Oxidative refolding of lysozyme assisted by DsbA, DsbC and the GroEL apical domain immobilized in cellulose

Expression of recombinant proteins in Escherichia coli often leads to formation of inclusion bodies (IB). If a recombinant protein contains one or more disulfide bonds, protein refolding and thiol oxidation reactions are required to recover its biological activity. Previous studies have demonstrated that molecular chaperones and foldases assist with the in vitro protein refolding. However, their use has been limited by the stoichiometric amount required for the refolding reaction. In search of alternatives to facilitate the use of these folding biocatalysts in this study, DsbA, DsbC, and the apical domain of GroEL (AD) were fused to the carbohydrate-binding module CBD_Cex of Cellulomonas fimi. The recombinant proteins were purified and immobilized in cellulose and used to assist the oxidative refolding of denatured and reduced lysozyme. The assisted refolding yields obtained with immobilized folding biocatalysts were at least twice of those obtained in the spontaneous refolding, suggesting that the AD, DsbA, and DsbC immobilized in cellulose might be useful for the oxidative refolding of recombinant proteins that are expressed as inclusion bodies. In addition, the spontaneous or assisted refolding kinetics data fitted well (r² > 0.9) to a previously reported lysozyme refolding model. The estimated refolding (k _N) and aggregation (k _A) constants were consistent with the hypothesis that foldases assisted the oxidative refolding of lysozyme by decreasing protein aggregation rather than increasing the refolding rate.     

大肠杆菌表达的重组人粒细胞-巨噬细胞集落刺激因子的纯化

对重组人粒细胞－巨噬细胞集落刺激因子（ｒｈＧＭ－ＣＳＦ）高效表达克隆ｐＺＷ．ＧＭ的表达产物进行了纯化,并对纯化的ＧＭ－ＣＳＦ进行了Ｎ端氨基酸序列分析。人ＧＭ－ＣＳＦ基因表达产物在大肠杆菌中以不溶性包涵体形式存在,经过超声破菌、包涵体抽提、凝胶过滤层析、复性、离子交换一系列化步骤,终产物纯度达９９％,按蛋白总量计算回收率达１０％,比活性达１×１０＾７ｕ／ｍｇ蛋白质。通过测定纯化人ＧＭ－ＣＳＦ的Ｎ端１     

Statistical optimization and multiple objective programming of lysozyme refolding catalyzed by recombinant DsbA in vitro

DsbA (disulfide bond formation protein A) is essential for disulfide bond formation directly affecting the nascent peptides folding to the correct conformation in vivo. In this paper, recombinant DsbA protein was employed to catalyze denatured lysozyme refolding and inhibit the aggregation of folding intermediates in vitro. Statistical methods, i.e., Plackett–Burman design and small central composite design, were adopted to screen out important factors affecting the refolding process and correlating these parameters with the refolding efficiency including both protein recovery and specific activity of refolded lysozyme. Four important parameters: initial lysozyme concentration, urea concentration, KCl concentration and GSSG (glutathione disulfide) concentration were picked out and operating conditions were optimized by introducing the effectiveness coefficient method and transforming the multiple objective programming into an ordinary constrained optimization issue. Finally, 99.7% protein recovery and 25,600 U/mg specific activity of lysozyme were achieved when 281.35 μg/mL denatured lysozyme refolding was catalyzed by an equivalent molar of DsbA at the optimal settings. The results indicated that recombinant DsbA protein could effectively catalyze the oxidized formation and reduced isomerization of intramolecular disulfide bonds in the refolding of lysozyme in vitro.     

Expression of human transforming growth factor β1 inE. coli (I)

PCR technique is used to amplify the mature peptide gene of human transforming growth factor pl (hTGFβ1); the gene is verified by full-length sequence analysis. In DHSa/pBV220 expression system, hTGFβ1 attains expression in the cytoplasm ofE. coli up to 16%. The recombinant protein is proved to be the monomer of hTGFPl by N-terminal amino acids analysis and immunoblotting. After refolding of the monomer proteinin vitm in glutathione system or CHPAS/DMSO system, the dimeric protein accumulates to 30% in the refolding mixture. The recombinant protein is purified to homogeneity on silver staining, and is shown to have strong biological activity from MTT bioassay on MvlLu cells.     

Purification and efficient refolding process for recombinant tissue-type plasminogen activator derivative (reteplase) using glycerol and Tranexamic acid

In this study, a novel and economic method for refolding and purifying recombinant tissue plasminogen activator derivative (r-PA; reteplase) was developed. Reteplase with nine disulfide bonds in its complex structure is expressed in the form of inclusion bodies in Escherichia coli and requires tedious dissolving and refolding processes to achieve its biological activity. Among the different refolding additives that were evaluated, glycerol and tranexamic acid (Txa) were found to be more effective in increasing the refolding yield of reteplase. Using response surface methodology, a solution containing 3.5 M urea, 33% (v/v) glycerol, and 400 mM Txa was found to give the highest refolding yield. The synergic effect of urea, glycerol, and Txa under optimum conditions for a reteplase concentration of 25 μg ml⁻¹ resulted in a high refolding yield of 76.41%. Increased reteplase concentration in the refolding buffer was achieved using the pulse-fed method. In the pulse-fed method, a refolding yield of 49.53% was achieved for a final reteplase concentration of 300 μg ml⁻¹. Using Txa as a novel refolding aid for reteplase instead of ionic amino acids like l-Arginine allowed to purify the refolded reteplase directly by cation-exchange chromatography with high purity.     

Studies on the Refolding Process of Recombinant Horseradish Peroxidase

Horseradish peroxidase (HRP) is an important heme-containing glyco-enzyme that has been used in many biotechnological fields. Valuable proteins like HRP can be obtained in sufficient amounts using Escherichia coli as an expression system. However, frequently, the expression of recombinant enzyme results in inclusion bodies, and the refolding yield is generally low for proteins such as plant peroxidases. In this study, a recombinant HRP was cloned and expressed in the form of inclusion bodies. Initially, the influence of few additives on HRP refolding was assessed by the one factor at a time method. Subsequently, factors with significant effects including glycerol, GSSG/DTT, and the enzyme concentration were selected for further optimization by means of the central composite design of response surface methodology (RSM). Under the obtained optimal condition, refolding increased about twofold. The refolding process was then monitored by the intrinsic fluorescence intensity under optimal conditions (0.35 mM GSSG, 0.044 mM DTT, 7 % glycerol, 1.7 M urea, and 2 mM CaCl₂ in 20 mM Tris, pH 8.5) and the reconstitution of heme to the refolded peroxidase was detected by the Soret absorbance. Additionally, samples under unfolding and refolding conditions were analyzed by Zetasizer to determine size distribution in different media.     

Construction of a recombinant human GM-CSF/MCAF fusion protein and study on itsin vitro andin vivo antitumor effects

A novel cytokine fusion protein was constructed by fusing granulocyte macrophage colony stimulating factor (GM-CSF) with monocyte chemotactic activating factor (MCAF), which acts as a factor directing effector cells (monocytes) to a target site. The recombinant human GM-CSF/MCAF fusion protein could sustain the growth of GMCSF-dependent cell line TF1 and was chemotactic for monocytes. Thein vitro antitumor effect showed that rhGM-CSF/MCAF could activate monocytes to inhibit the growth of several human tumor cell lines, including a promyelocyte leukemia cell line HL-60, a lung adenocarcinoma cell line A549, a hepatoma cell line SMMC-7721 and a melanoma cell line Bowes. Furthermore, the cytotoxicity of monocytes activated by rhGM-CSF/MCAF against HL-60 and A549 was greater than that activated by GM-CSF or MCAF alone, even greater than that activated by a combination of GM-CSF and MCAF, suggesting that the fusion protein has synergistic or enhanced effects. Thein vivo antitumor effect indicated that rhGM-CSF/MCAF had marked antitumor effect against A549 tumor in nude mice and even completely suppressed tumor formation. rhGM-CSF/MCAF was significantly more effective in inhibiting tumor growth than rhGM-CSF. Histological analysis showed that tumor site injected with rhGM-CSF/MCAF was infiltrated by a large number of monocytes while a sparse infiltration of monocytes was observed at the tumor site injected with rhGM-CSF or normal saline, suggesting that the antitumor effect of rhGM-CSF/MCAF was mediated by the recruitment of a large number of monocytes to the tumor site.     

Immobilized Triton X-100-assisted refolding of Green Fluorescent Protein-Tobacco Etch Virus protease fusion protein using β-cyclodextrin as the eluent

A new protein refolding technique based on the use of the non-charged detergent Triton X-100 immobilized to the cross-linked agarose gel Sepharose High Performance has been developed. The new solid phase was used in combination with soluble β-cyclodextrin (β-CD) to refold recombinant Green Fluorescent Protein fused to Tobacco Etch Virus protease (GFPTEVP) expressed as inclusion bodies in E. coli. Previous attempts to refold recombinant GFPTEVP by dilution had failed. In the new procedure a column packed with Triton X-100-coupled Sepharose High Performance was used to capture unfolded GFPTEVP followed by elution using an increasing β-CD concentration gradient. The yield of properly refolded GFPTEVP was 46% at a protein concentration of 380 μg/ml. In contrast, dilution refolding of GFPTEVP at 200 μg/ml refolding buffer resulted in only 4.7% of native protein.     

Increasing the refolding efficiency in vitro by site-directed mutagenesis of Cys383 in rat procarboxypeptidase B

This study examines a novel method to reduce the probability of disulfide mismatches during the refolding process by the replacement of cysteines within a protein. Specifically, Cys383 of recombinant rat procarboxypeptidase B was replaced by other amino acids to increase the refolding efficiency in vitro. Mutants C383G, C383A and C383S could refold successfully, but mutants C383R, C383E, C383L and C383Y failed to refold correctly. Compared with wild type, the refolding efficiencies of mutants C383G and C383A were enhanced. The Cys383 mutations changed some of the properties of rat carboxypeptidase B. Mutants C383G, C383A had higher k_cat/K_m values which indicated increased catalytic abilities. And both had higher thermal stability. pH had different effects on the activities and stabilities of the mutant and wild type proteins. The studies suggested that mutating Cys383 of rat procarboxypeptidase B could improve the renaturation process by increasing the refolding efficiency. This new method could be taken as a new attempt to improve the refolding efficiency of other recombinant proteins containing disulfide bonds that are expressed as inclusion bodies. While the results also claimed that the potential effects of the substituted amino acid on the protein itself should be seriously considered in addition to its ability to reduce the probability of disulfide mismatches.     

An efficient in vitro refolding of recombinant bacterial laccase in Escherichia coli

Laccases (benzenediol oxygen oxidoreductases, EC 1.10.3.2) are important multicopper enzymes that are used in many biotechnological processes. A recombinant form of laccase from Bacillus sp. HR03 was overexpressed in Escherichia coli BL-21(DE3). Inclusion body (IB) formation happens quite often during recombinant protein production. Hence, developing a protocol for efficient refolding of proteins from inclusion bodies to provide large amounts of active protein could be advantageous for structural and functional studies. Here, we have tried to find an efficient method of refolding for this bacterial enzyme. Solubilization of inclusion bodies was carried out in phosphate buffer pH 7, containing 8 M urea and 4 mM β-mercaptoethanol and refolding was performed using the dilution method. The effect of different additives was investigated on the refolding procedure of denaturated laccase. Mix buffer (phosphate buffer and citrate buffer, 100 mM) containing 4 mM ZnSO₄ and 100 mM sorbitol was selected as an optimized refolding buffer. Also Kinetic parameters of soluble and refolded laccase were analyzed.     

Highly efficient production of soluble proteins from insoluble inclusion bodies by a two-step-denaturing and refolding method

The production of recombinant proteins in a large scale is important for protein functional and structural studies, particularly by using Escherichia coli over-expression systems; however, approximate 70% of recombinant proteins are over-expressed as insoluble inclusion bodies. Here we presented an efficient method for generating soluble proteins from inclusion bodies by using two steps of denaturation and one step of refolding. We first demonstrated the advantages of this method over a conventional procedure with one denaturation step and one refolding step using three proteins with different folding properties. The refolded proteins were found to be active using in vitro tests and a bioassay. We then tested the general applicability of this method by analyzing 88 proteins from human and other organisms, all of which were expressed as inclusion bodies. We found that about 76% of these proteins were refolded with an average of >75% yield of soluble proteins. This "two-step-denaturing and refolding" (2DR) method is simple, highly efficient and generally applicable; it can be utilized to obtain active recombinant proteins for both basic research and industrial purposes.     

Refolding process of cysteine-rich proteins:Chitinase as a model

Background:

Recombinant proteins overexpressed in E. coli are usually deposited in inclusion bodies. Cysteines in the protein contribute to this process. Inter- and intra- molecular disulfide bonds in chitinase, a cysteine-rich protein, cause aggregation when the recombinant protein is overexpressed in E. coli. Hence, aggregated proteins should be solubilized and allowed to refold to obtain native- or correctly- folded recombinant proteins.

Methods:

Dilution method that allows refolding of recombinant proteins, especially at high protein concentrations, is to slowly add the soluble protein to refolding buffer. For this purpose: first, the inclusion bodies containing insoluble proteins were purified; second, the aggregated proteins were solubilized; finally, the soluble proteins were refolded using glutathione redox system, guanidinium chloride, dithiothreitol, sucrose, and glycerol, simultaneously.

Results:

After protein solubilization and refolding, SDS-PAGE showed a 32 kDa band that was recognized by an anti-chitin antibody on western blots.

Conclusions:

By this method, cysteine-rich proteins from E. coli inclusion bodies can be solubilized and correctly folded into active proteins.Key Words: Chitinase, Cysteine-rich proteins, Protein refolding, Protein solubilization     

An Efficient System for Production of Recombinant Urokinase-Type Plasminogen Activator

A system was developed to produce recombinant urokinase-type plasminogen activator inEscherichia coli.The urokinase-type plasminogen activator was produced with a 6× His-tag at the C-terminus which was shown to have the same activity, after refolding, as the wild-type protein. Purification of the recombinant protein to homogeneity (95%) was possible by one-step affinity chromatography under denaturing conditions. As a result, proteolysis by bacterial proteases during purification was avoided. A higher refolding efficiency (40%) and a higher total recovery yield (25%) of the recombinant protein were obtained by this method.     

One-step Purification and Immobilization in Cellulose of the GroEL Apical Domain Fused to a Carbohydrate-binding Module and its use in Protein Refolding

The apical domain of the chaperonin, GroEL, fused to the carbohydrate binding module type II, CBD_Cex, of Cellulomonas fimi, was expressed in Escherichia coli. The recombinant protein, soluble or from inclusion bodies, was directly purified and immobilized in microcrystalline cellulose particles or cellulose fabric membranes. Assisted refolding of rhodanese by the immobilized mini-chaperone showed a two-fold improvement as compared to a control. Using chromatographic refolding, 35% of rhodanese activity was recovered in only 5 min (mean residence time) as compared to 17% for spontaneous refolding. This mini-chaperone immobilized in cellulose could be a cost-efficient method to refold recombinant proteins expressed as inclusion bodies.     

Refolding of the recombinant protein Sm29, a step toward the production of the vaccine candidate against schistosomiasis

Schistosomiasis is an important parasitic disease, with about 240 million people infected worldwide. Humans and animals can be infected, imposing an enormous social and economic burden. The only drug available for chemotherapy, praziquantel, does not control reinfections, and an efficient vaccine for prophylaxis is still missing. However, the tegumental protein Sm29 of Schistosoma mansoni was shown to be a promising antigen to compose an anti-schistosomiasis vaccine. Though, recombinant Sm29 is expressed in Escherichia coli as insoluble inclusion bodies requiring an efficient process of refolding, thus, hampering its production in large scale. We present in this work studies to refold the recombinant Sm29 using high hydrostatic pressure, a mild condition to dissociate aggregated proteins, leading to refolding on a soluble conformation. Our studies resulted in high yield of rSm29 (73%) as a stably soluble and structured protein. The refolded antigen presented protective effect against S. mansoni development in immunized mice. We concluded that the refolding process by application of high hydrostatic pressure succeeded, and the procedure can be scaled-up, allowing industrial production of Sm29.     

Computer Simulation and Additive-Based Refolding Process of Cysteine-Rich Proteins: VEGF-A as a Model

Refolding of cysteine-rich protein for establishing native conformation and a biologically active form is the most challenging step in recombinant protein synthesis. In this study, expressed vascular endothelial growth factor-A (VEGF-A), as a cysteine-rich protein, in a prokaryotic expression cell was refolded based on computer simulation technique and multiple chemical additive-based buffers to recover its biologically active form. For this purpose, cloned and expressed VEGF-A in Escherichia coli BL21 (DE3) was purified and dialyzed by a basic buffer containing nine diverse chemical additives. In parallel with the evaluations of the applied additives, professional computer simulation software was also used. The activity of refolded protein was evaluated in differentiation of mesenchymal stem cells (MSCs) to the endothelial cells (ECs). The results showed that dialyzing the produced recombinant VEGF-A in chemical additive-based buffers containing cysteine, 1, 4-dithiothreitol (DTT), arginine, and Triton X-100 led to efficient VEGF-A refolding. The results of flowcytometry analysis indicated that CD31 and CD144 as the specific ECs markers in VEGF-A treated MSCs were 31 and 73%, respectively. Protein refolding method using chemical additive-based buffers containing cysteine, DTT, arginine and Triton X-100 was the best accessible technique for refolding cysteine-rich recombinant VEGF-A.     

huGM-CSF(9-127)-IL-6(29-184)融合蛋白的复性及纯化研究

利用Q Sepharose H.P.离子交换柱层析在8mol/L尿素变性条件下对huGM-CSF(9-127)-IL-6(29-184）融合蛋白进行初步纯化,然后再利用Sephacryl S-200分子筛柱层析复性及纯化后获得目的蛋白,其纯度达到95％以上。该纯化方案成功地解决了稀释复性或透析复性产物在进行Q Sepharose H.P.离子交换柱层析时目的蛋白不稳定而沉积于柱上的问题,获得了较好的复性效果,复性率达到80％以上。使用该纯化方案,1天内便可基本完成重组蛋白的复性及纯化过程,而且也便于扩大。