One-step purification and structural characterization of a recombinant His-tag 11S globulin expressed in transgenic tobacco

Amarantin, an 11S globulin, is one of the most important storage proteins of amaranth seeds, with relevant nutritional-functional and nutraceutical characteristics. Its cDNA was cloned in-frame with a sequence encoding a polyhistidine tag and expressed under the direction of a 35S promoter in transgenic tobacco seeds. The presence of a (His)(6) tag on the polypeptide permitted a high-yield single-step purification using immobilized metal-ion affinity chromatography and rapid characterization. Purified His-tag amarantin accounted for up to 5% of total soluble seed protein. Biochemical characterization indicated that purified His-tag amarantin migrated with the expected molecular weight (53 kDa) and was correctly processed into an acidic polypeptide (32 kDa) with isoelectric point (pI) of 5.58 and a basic polypeptide (21 kDa) with pI of 9.24, linked by a disulfide bridge. Moreover, His-tag amarantin was assembled into both homo- and hetero-hexameric 11S structures. These results show that the His tag did not change the biochemical and physicochemical properties of amarantin. The strategy presented here for rapid and high-yield expression and purification procedure should facilitate structure-function studies for this nutritional protein.     

Integrated strategy for selective expanded bed ion-exchange adsorption and site-specific protein processing using gene fusion technology

The highly charged domain Z(basic) can be used as a fusion partner to enhance adsorption of target proteins to cation exchanging resins at high pH-values. In this paper, we describe a strategy for purification of target proteins fused to Z(basic) at a constant physiological pH using cation exchange chromatography in an expanded bed mode. We show that two proteins, Klenow DNA polymerase and the viral protease 3C, can be efficiently purified from unclarified Escherichia coli homogenates in a single step with a selectivity analogous to what is normally achieved by affinity chromatography. The strategy also includes an integrated site-specific removal of the Z(basic) purification handle to yield a free target protein.     

Ubiquitin-intein and SUMO2-intein fusion systems for enhanced protein production and purification

Although most commonly used for protein production, expression of soluble and functional recombinant protein in Escherichia coli is still a major challenge. The development and application of fusion tags that can facilitate protein expression and solubility partly solve this problem, however, under most circumstance, the fusion tags have to be removed by proteases in order to use the proteins. Because the tag removal using proteases increases cost and introduces extra purification steps, it remains a significant problem that must be resolved before being widely used in industry production. Ubiquitin and SUMO have been successfully used to enhance protein expression and solubility. In the last decades, intein has also been widely used in protein production for its self-cleavage property, which could help to remove the fusion tag without any protease. Here, we take the advantages of ubiquitin, SUMO2 and intein in protein expression. We constructed tandem ubiquitin-intein and SUMO2-intein fusion tags, and chose human MMP13 (amino acid 104-274) and eGFP as the passenger proteins that fused to the C-terminus of the tags. These constructs were expressed in E. coli and both MMP13 and eGFP expression and solubility were evaluated. Both tags showed the ability to enhance the solubility of MMP13 and eGFP and improve the expression of eGFP, and the SUMO2-intein having a more significant effect. Both ubiquitin-intein-eGFP and SUMO2-intein-eGFP were purified using Ni-NTA column chromatography and self-cleavaged by changing pH. The recombinant un-tagged eGFP were released and eluted with high homogeneity. In summary, ubiquitin-intein and SUMO2-intein are convenient and useful fusion tags that can enhance the expression, solubility and improve the purification process of the model heterologous protein and these tags may have a good prospect in protein production.     

Single-step recovery and solid-phase refolding of inclusion body proteins using a polycationic purification tag

A strategy for purification of inclusion body-forming proteins is described, in which the positively charged domain Z(basic) is used as a fusion partner for capture of denatured proteins on a cation exchange column. It is shown that the purification tag is selective under denaturing conditions. Furthermore, the new strategy for purification of proteins from inclusion bodies is compared with the commonly used method for purification of His(6)-tagged inclusion body proteins. Finally, the simple and effective means of target protein capture provided by the Z(basic) tag is further successfully explored for solid-phase refolding. This procedure has the inherited advantage of combining purification and refolding in one step and offers the advantage of eluting the concentrated product in a suitable buffer.     

Recombinant Passenger Proteins Can Be Conveniently Purified by One-Step Affinity Chromatography

Fusion tag is one of the best available tools to date for enhancement of the solubility or improvement of the expression level of recombinant proteins in Escherichia coli. Typically, two consecutive affinity purification steps are often necessitated for the purification of passenger proteins. As a fusion tag, acyl carrier protein (ACP) could greatly increase the soluble expression level of Glucokinase (GlcK), α-Amylase (Amy) and GFP. When fusion protein ACP-G2-GlcK-Histag and ACP-G2-Amy-Histag, in which a protease TEV recognition site was inserted between the fusion tag and passenger protein, were coexpressed with protease TEV respectively in E. coli, the efficient intracellular processing of fusion proteins was achieved. The resulting passenger protein GlcK-Histag and Amy-Histag accumulated predominantly in a soluble form, and could be conveniently purified by one-step Ni-chelating chromatography. However, the fusion protein ACP-GFP-Histag was processed incompletely by the protease TEV coexpressed in vivo, and a large portion of the resulting target protein GFP-Histag aggregated in insoluble form, indicating that the intracellular processing may affect the solubility of cleaved passenger protein. In this context, the soluble fusion protein ACP-GFP-Histag, contained in the supernatant of E. coli cell lysate, was directly subjected to cleavage in vitro by mixing it with the clarified cell lysate of E. coli overexpressing protease TEV. Consequently, the resulting target protein GFP-Histag could accumulate predominantly in a soluble form, and be purified conveniently by one-step Ni-chelating chromatography. The approaches presented here greatly simplify the purification process of passenger proteins, and eliminate the use of large amounts of pure site-specific proteases.     

A simple and efficient expression and purification system using two newly constructed vectors

Structural biology places a high demand on proteins both in terms of quality and quantity. Although many protein expression and purification systems have been developed, an efficient and simple system which can be easily adapted is desirable. Here, we report a new system which combines improved expression, solubility screening and purification efficiency. The system is based on two newly constructed vectors, pEHISTEV and pEHISGFPTEV derived from a pET vector. Both vectors generate a construct with an amino-terminal hexahistidine tag (His-tag). In addition, pEHISGFPTEV expresses a protein with an N-terminal His-tagged green fluorescent protein (GFP) fusion to allow rapid quantitation of soluble protein. Both vectors have a tobacco etch virus (TEV) protease cleavage site that allows for production of protein with only two additional N-terminal residues and have the same multiple cloning site which enables parallel cloning. Protein purification is a simple two-stage nickel affinity chromatography based on the His tag removal. A total of seven genes were tested using this system. Expression was optimised using pEHISGFPTEV constructs by monitoring the GFP fluorescence and the soluble target proteins were quantified using spectrophotometric analysis. All the tested proteins were purified with sufficient quantity and quality to attempt structure determination. This system has been proven to be simple and effective for structural biology. The system is easily adapted to include other vectors, tags or fusions and therefore has the potential to be broadly applicable.     

A new tagging system for production of recombinant proteins in Drosophila S2 cells using the third domain of the urokinase receptor

The use of protein fusion tag technology greatly facilitates detection, expression and purification of recombinant proteins, and the demands for new and more effective systems are therefore expanding. We have used a soluble truncated form of the third domain of the urokinase receptor as a convenient C-terminal fusion partner for various recombinant extracellular human proteins used in basic cancer research. The stability of this cystein-rich domain, which structure adopts a three-finger fold, provides an important asset for its applicability as a fusion tag for expression of recombinant proteins. Up to 20mg of intact fusion protein were expressed by stably transfected Drosophila S2 cells per liter of culture using this strategy. Purification of these secreted fusion proteins from the conditioned serum free medium of S2 cells was accompanied by an efficient one-step immunoaffinity chromatography procedure using the immobilized anti-uPAR monoclonal antibody R2. An optional enterokinase cleavage site is included between the various recombinant proteins and the linker region of the tag, which enables generation of highly pure preparations of tag-free recombinant proteins. Using this system we successfully produced soluble and intact recombinant forms of extracellular proteins such as CD59, C4.4A and vitronectin, as well as a number of truncated domain constructs of these proteins. In conclusion, the present tagging system offers a convenient general method for the robust expression and efficient purification of a variety of recombinant proteins.     

High-recovery one-step purification of the DNA-binding protein Fur by mild guanidinium chloride treatment

Engineering of DNA-binding domains of regulatory proteins aimed to control gene expression requires a deep knowledge of protein–DNA interactions acquired from structural data on purified species. Most DNA-binding proteins work as dimers establishing multiple protein–protein contacts mainly driven by hydrophobic interactions, being its cleansing a difficult task because of solubility problems. One-step purification of soluble, functional recombinant FurA from the cyanobacterium Anabaena sp. PCC 7120 has been achieved using mild chaotropic conditions. FurA was isolated using a Zn-iminodiacetate chromatography of the crude extract obtained after sonication of Escherichia coli in the presence of 2 M guanidium chloride. CD and ¹D NMR spectroscopies demonstrate that FurA conserves the native tertiary structure. Functional analysis reveals FurA ability to recognise and bind target DNAs. We propose that the use of chaotropic agents under mild denaturating conditions might have general application in the purification of DNA-binding proteins and other proteins prone to aggregation.     

Metal ions‐binding T4 lysozyme as an intramolecular protein purification tag compatible with X‐ray crystallography

Phage T4 lysozyme is a well folded and highly soluble protein that is widely used as an insertion tag to improve solubility and crystallization properties of poorly behaved recombinant proteins. It has been used in the fusion protein strategy to facilitate crystallization of various proteins including multiple G protein‐coupled receptors, lipid kinases, or sterol binding proteins. Here, we present a structural and biochemical characterization of its novel, metal ions‐binding mutant (mbT4L). We demonstrate that mbT4L can be used as a purification tag in the immobilized‐metal affinity chromatography and that, in many respects, it is superior to the conventional hexahistidine tag. In addition, structural characterization of mbT4L suggests that mbT4L can be used as a purification tag compatible with X‐ray crystallography.     

pCold-GST vector: a novel cold-shock vector containing GST tag for soluble protein production

The production of recombinant protein in Escherichia coli is often hampered by low expression levels and low solubility. A variety of methodologies have been developed including protein production at low temperature, and fusion protein expression using soluble protein tags. Here, we present the novel cold-shock vector pCold-GST for high-level expression of soluble proteins in E. coli. This vector is a modified pCold I cold-shock vector that includes the glutathione S-transferase (GST) tag. The pCold-GST expression system developed was applied to 10 proteins that could not be expressed using conventional E. coli expression methodologies, and nine of these proteins were successfully obtained in the soluble fraction. The expression and purification of two unstable protein fragments were also demonstrated by employing a C-terminal hexa-histidine tag for purification purposes. The purified proteins were amenable to NMR analyses. These data suggest that the pCold-GST expression system can be utilized to improve the expression and purification of various proteins.     

A rapid and universal tandem-purification strategy for recombinant proteins

A major goal in the production of therapeutic proteins, subunit vaccines, as well as recombinant proteins needed for structure determination and structural proteomics is their recovery in a pure and functional state using the simplest purification procedures. Here, we report the design and use of a novel tandem (His)(6)-calmodulin (HiCaM) fusion tag that combines two distinct purification strategies, namely, immobilized metal affinity (IMAC) and hydrophobic interaction chromatography (HIC), in a simple two-step procedure. Two model constructs were generated by fusing the HiCaM purification tag to the N terminus of either the enhanced green fluorescent protein (eGFP) or the human tumor suppressor protein p53. These fusion constructs were abundantly expressed in Escherichia coli and rapidly purified from cleared lysates by tandem IMAC/HIC to near homogeneity under native conditions. Cleavage at a thrombin recognition site between the HiCaM-tag and the constructs readily produced untagged, functional versions of eGFP and human p53 that were >97% pure. The HiCaM purification strategy is rapid, makes use of widely available, high-capacity, and inexpensive matrices, and therefore represents an excellent approach for large-scale purification of recombinant proteins as well as small-scale protein array designs.     

A dual protease approach for expression and affinity purification of recombinant proteins

We describe a new method for affinity purification of recombinant proteins using a dual protease protocol. Escherichia coli maltose binding protein (MBP) is employed as an N-terminal tag to increase the yield and solubility of its fusion partners. The MBP moiety is then removed by rhinovirus 3C protease, prior to purification, to yield an N-terminally His₆-tagged protein. Proteins that are only temporarily rendered soluble by fusing them to MBP are readily identified at this stage because they will precipitate after the MBP tag is removed by 3C protease. The remaining soluble His₆-tagged protein, if any, is subsequently purified by immobilized metal affinity chromatography (IMAC). Finally, the N-terminal His₆ tag is removed by His₆-tagged tobacco etch virus (TEV) protease to yield the native recombinant protein, and the His₆-tagged contaminants are removed by adsorption during a second round of IMAC, leaving only the untagged recombinant protein in the column effluent. The generic strategy described here saves time and effort by removing insoluble aggregates at an early stage in the process while also reducing the tendency of MBP to “stick” to its fusion partners during affinity purification.     

New fusion protein systems designed to give soluble expression in Escherichia coli.

Three native E. coli proteins-NusA, GrpE, and bacterioferritin (BFR)-were studied in fusion proteins expressed in E. coli for their ability to confer solubility on a target insoluble protein at the C-terminus of the fusion protein. These three proteins were chosen based on their favorable cytoplasmic solubility characteristics as predicted by a statistical solubility model for recombinant proteins in E. coli. Modeling predicted the probability of soluble fusion protein expression for the target insoluble protein human interleukin-3 (hIL-3) in the following order: NusA (most soluble), GrpE, BFR, and thioredoxin (least soluble). Expression experiments at 37 degrees C showed that the NusA/hIL-3 fusion protein was expressed almost completely in the soluble fraction, while GrpE/hIL-3 and BFR/hIL-3 exhibited partial solubility at 37 degrees C. Thioredoxin/hIL-3 was expressed almost completely in the insoluble fraction. Fusion proteins consisting of NusA and either bovine growth hormone or human interferon-gamma were also expressed in E. coli at 37 degrees C and again showed that the fusion protein was almost completely soluble. Starting with the NusA/hIL-3 fusion protein with an N-terminal histidine tag, purified hIL-3 with full biological activity was obtained using immobilized metal affinity chromatography, factor Xa protease cleavage, and anion exchange chromatography.     

Heat treatment of thioredoxin fusions increases the purity of α‐helical transmembrane protein constructs

Membrane proteins play key roles in cellular signaling and transport, represent the majority of drug targets, and are implicated in many diseases. Their relevance renders them important subjects for structural, biophysical, and functional investigations. However, obtaining membrane proteins in high purities is often challenging with conventional purification steps alone. To address this issue, we present here an approach to increase the purity of α‐helical transmembrane proteins. Our approach exploits the Thioredoxin (Trx) tag system, which is able to confer some of its favorable properties, such as high solubility and thermostability, to its fusion partners. Using Trx fusions of transmembrane helical hairpin constructs derived from the human cystic fibrosis transmembrane conductance regulator (CFTR) and a bacterial ATP synthase, we establish conditions for the successful implementation of the selective heat treatment procedure to increase sample purity. We further examine systematically its efficacy with respect to different incubation times and temperatures using quantitative gel electrophoresis. We find that minute‐timescale heat treatment of Trx‐tagged fusion constructs with temperatures ranging from 50 to 90°C increases the purity of the membrane protein samples from ~60 to 98% even after affinity purification. We show that this single‐step approach is even applicable in cases where regular selective heat purification from crude extracts, as reported for Trx fusions to soluble proteins, fails. Overall, our approach is easy to integrate into existing purification strategies and provides a facile route for increasing the purity of membrane protein constructs after purification by standard chromatography approaches.     

A novel method for the purification of low soluble recombinant C-type lectin proteins

Snake venoms contain a complex mixture of many biological molecules including proteins. The purification of recombinant proteins is a key step in studying their function and structure with affinity chromatography as the common method used in their purification. In bacterial expression systems, hydrophobic recombinant proteins are usually precipitated into inclusion bodies, and contaminants are typically associated with tagged proteins after purification. The purpose of this study was to develop a procedure to purify hydrophobic recombinant proteins without an affinity tag. Snake venom mature C-type lectin-like proteins (CLPs) with a tag were cloned, expressed, and purified by repeated sonication and wash steps. The effects of the signal peptide on the expression and solubility of the recombinant protein were investigated. The CLPs in washed inclusion bodies were solubilized and refolded by dialysis. The CLPs without a tag were successfully purified with a yield 38 times higher than the traditional method, and inhibited blood platelet aggregation with an IC(50) of 100.57μM in whole blood. This novel procedure is a rapid, and inexpensive method to purify functional recombinant hydrophobic CLPs from snake venoms useful in the development of drug therapies.     

高活性重组hG-CSF的制备

我们构建了新的硫氧还蛋白（Ｔｈｉｏｒｅｄｏｘｉｎ）融合表达载体ｐＥＴＴｒｘＬ和ｐＥＴＴｒｘ－ＨｉｓＬ,它们可使功能蛋白在大肠杆菌胞质中以可溶性形式高效表达。利用此表达系统成功地获得的ｈＧ－ＣＳＦ－硫氧还蛋白融合蛋白的高效可溶性表达,表达水平达总细胞可溶蛋白的４１％以上。所表达的ｈＧ－ＣＳＦ－硫氧还蛋白融合蛋白可通过Ｃｕ２＋－ＩＤＡＳｅｐｈａｒｏｓｅＦＦ固相金属螯合层析柱,方便地从细胞破碎可溶上清中直接纯化。所获得的融合蛋白具有ｈＧ－ＣＳＦ特异的生物活性,其比活性达到０．５－１．３３×１０７ｕ／ｍｇ融合蛋白。这样表达的ｈＧ－ＣＳＦ融合蛋白能被ＩｇＡ蛋白酶特异地切割,将ｈＧ－ＣＳＦ从融合蛋白上切下获得与天然蛋白一级结构完全一致的重组ｈＧ－ＣＳＦ 。     

Fully automated protein purification

Obtaining highly purified proteins is essential to begin investigating their functional and structural properties. The steps that are typically involved in purifying proteins can include an initial capture, intermediate purification, and a final polishing step. Completing these steps can take several days and require frequent attention to ensure success. Our goal was to design automated protocols that would allow the purification of proteins with minimal operator intervention. Separate methods have been produced and tested that automate the sample loading, column washing, sample elution and peak collection steps for ion exchange, metal affinity, hydrophobic interaction, and gel filtration chromatography. These individual methods are designed to be coupled and run sequentially in any order to achieve a flexible and fully automated protein purification protocol.     

High-throughput protein purification and quality assessment for crystallization

The ultimate goal of structural biology is to understand the structural basis of proteins in cellular processes. In structural biology, the most critical issue is the availability of high-quality samples. "Structural biology-grade" proteins must be generated in the quantity and quality suitable for structure determination using X-ray crystallography or nuclear magnetic resonance (NMR) spectroscopy. The purification procedures must reproducibly yield homogeneous proteins or their derivatives containing marker atom(s) in milligram quantities. The choice of protein purification and handling procedures plays a critical role in obtaining high-quality protein samples. With structural genomics emphasizing a genome-based approach in understanding protein structure and function, a number of unique structures covering most of the protein folding space have been determined and new technologies with high efficiency have been developed. At the Midwest Center for Structural Genomics (MCSG), we have developed semi-automated protocols for high-throughput parallel protein expression and purification. A protein, expressed as a fusion with a cleavable affinity tag, is purified in two consecutive immobilized metal affinity chromatography (IMAC) steps: (i) the first step is an IMAC coupled with buffer-exchange, or size exclusion chromatography (IMAC-I), followed by the cleavage of the affinity tag using the highly specific Tobacco Etch Virus (TEV) protease; the second step is IMAC and buffer exchange (IMAC-II) to remove the cleaved tag and tagged TEV protease. These protocols have been implemented on multidimensional chromatography workstations and, as we have shown, many proteins can be successfully produced in large-scale. All methods and protocols used for purification, some developed by MCSG, others adopted and integrated into the MCSG purification pipeline and more recently the Center for Structural Genomics of Infectious Diseases (CSGID) purification pipeline, are discussed in this chapter.     

抗肿瘤疫苗MAGE1-MAGE3-HSP70蛋白特性及其纯化策略的研究

目的：对MAGE1-MAGE3-HSP70（M1-M3-HSP70）融合蛋白的理化性质及其纯化策略进行初步研究,为后期的临床前试验提供数据和依据。方法：以本实验室构建的菌种（BL21（DE3）pLysS-M1-M3-HSP70）为材料,采用常规细菌培养及诱导方法进行诱导表达,用聚丙烯酰胺凝胶（SDS—PAGE）电泳、免疫印迹（Westemblotting）对目的蛋白进行分析,然后确定盐析条件,使用ButylSepharoseHP疏水相互作用层析以及阴离子交换（Source30Q填料）对目的蛋白的纯化进行分析。结果：M1-M3-HSP70蛋白在大肠杆菌中表达后,目的蛋白分为两部分,一部分为包涵体形式（44．9％）,一部分为可溶表达（55．1％）。对其可溶部分进行研究发现．细菌裂解后,目的蛋白存在聚合和降解现象;确定了盐析条件、洗脱缓冲液以及稳定的PH值范围,基本确定了目的蛋白的纯4~．z-艺。结论：明确了M1-M3-HSP70融合蛋白的基本性质,确定了目的蛋白的纯化方法,为基于融合蛋白的肿瘤疫苗的进一步研究提供了参考。     

A novel self-cleavable tag Zbasic–∆I-CM and its application in the soluble expression of recombinant human interleukin-15 in Escherichia coli

Soluble expression of recombinant therapeutic proteins in Escherichia coli (E. coli) has been a challenging task in biopharmaceutical development. In this study, a novel self-cleavable tag Zbasic–intein has been constructed for the soluble expression and purification of a recombinant cytokine, human interleukin-15 (IL-15). We screened several solubilizing tags fused with the self-cleavable Mycobacterium tuberculosis recA mini-intein ∆I-CM and demonstrated that Zbasic tag can significantly improve the solubility of the product with correspondent to the intein activity. The fusion protein “Zbasic–∆I-CM–IL-15” was expressed with high solubility and easily enriched by the cost-effective cation-exchange chromatography. The self-cleavage of the fusion tag Zbasic–∆I-CM was then induced by a pH shift, with an activation energy of 7.48 kcal/mol. The mature IL-15 with natural N-terminus was released and further purified by hydrophobic interaction and anion-exchange chromatography. High-resolution reverse-phase high-performance liquid chromatography and mass spectrometry analysis confirmed that the product was of high purity and correct mass. With a CTLL-2 cell proliferation-based assay, the EC₅₀ was evaluated to be of about 0.126 ng/mL, similar to the product in clinical trials. By avoiding the time-consuming denaturing-refolding steps in previously reported processes, the current method is efficient and cost-effective. The novel tag Zbasic–∆I-CM can be potentially applied to large-scale manufacturing of recombinant human cytokines as well as other mammalian-sourced proteins in E. coli.