A new strategy for the on-column exopeptidase cleavage of poly-histidine tagged proteins

This paper describes a new strategy, which aims to make on-column poly-histidine tag removal more useful in the production of recombinant proteins by improving the yield and efficiency of on-column exopeptidase cleavage. This involves improvement of the on-column cleavage condition by using imidazole concentrations in the range of 100-500 mM in the cleavage buffer. At 300 mM imidazole, maximum on-column cleavage yield (in excess of 99%) was achieved in 3h of incubation. However, as a result of the increased imidazole concentration, this new strategy of on-column cleavage results in some residual uncleaved poly-histidine tagged proteins (~0.1%) and the production of cleaved dipeptides, both of which need to be further removed in a subsequent step. A method involving the recirculation of recovered proteins and peptides through the immobilized metal affinity chromatography (IMAC) column (same-column recirculation) was found to be superior to subtractive IMAC for the purpose of contaminant clearance. Recovery of the detagged target proteins was achieved using 10 column volumes of recovery buffer, which had the effect of diluting the imidazole concentration to a suitably low level for contaminant removal by same-column recirculation. This strategy was also applicable at a higher adsorbent loading of 10 mg protein/mL adsorbent with an optimal ratio of 200 mU of DAPase per mg of adsorbed tagged maltose binding protein (MBP), giving a cleavage yield of 99.1% in 3 h. Finally, on-column cleavage conditions including the effect of protease concentration and incubation time on the new strategy have been investigated and comparisons are made for different tag removal strategies.     

An Automatic Refolding Apparatus for Preparative-Scale Protein Production

Protein refolding is an important process to recover active recombinant proteins from inclusion bodies. Refolding by simple dilution, dialysis and on-column refolding methods are the most common techniques reported in the literature. However, the refolding process is time-consuming and laborious due to the variability of the behavior of each protein and requires a great deal of trial-and-error to achieve success. Hence, there is a need for automation to make the whole process as convenient as possible. In this study, we invented an automatic apparatus that integrated three refolding techniques: varying dilution, dialysis and on-column refolding. We demonstrated the effectiveness of this technology by varying the flow rates of the dilution buffer into the denatured protein and testing different refolding methods. We carried out different refolding methods on this apparatus: a combination of dilution and dialysis for human stromal cell-derived factor 1 (SDF-1/CXCL12) and thioredoxin fused-human artemin protein (Trx-ARTN); dilution refolding for thioredoxin fused-human insulin-like growth factor I protein (Trx-IGF1) and enhanced fluorescent protein (EGFP); and on-column refolding for bovine serum albumin (BSA). The protein refolding processes of these five proteins were preliminarily optimized using the slowly descending denaturants (or additives) method. Using this strategy of decreasing denaturants concentration, the efficiency of protein refolding was found to produce higher quantities of native protein. The standard refolding apparatus configuration can support different operations for different applications; it is not limited to simple dilution, dialysis and on-column refolding techniques. Refolding by slowly decreasing denaturants concentration, followed by concentration or purification on-column, may be a useful strategy for rapid and efficient recovery of active proteins from inclusion bodies. An automatic refolding apparatus employing this flexible strategy may provide a powerful tool for preparative scale protein production.     

A method for the prevention of thrombin-induced degradation of recombinant proteins

A new strategy to prevent degradation of recombinant proteins caused by non-specific cleavage by thrombin is described. We demonstrate that degradation due to non-specific cleavage of recombinant protein mediated by thrombin can be completely prevented by separation of thrombin from the recombinant protein on spin columns packed with heparin-sepharose. This method is generally applicable to all recombinant proteins that require the thrombin for the cleavage of affinity tags for purification. To our knowledge, this is the first report of an efficient and reliable method for the separation of residual thrombin from purified recombinant proteins.     

Soluble expression of aggregating proteins by covalent coupling to the ribosome

Ribosomes are extremely soluble ribonucleoprotein complexes. Heterologous target proteins were fused to ribosomal protein L23 (rpL23) and expressed in an rpL23 deficient Escherichia coli strain. This enabled the isolation of 70S ribosomes with covalently bound target protein. Isolation of recombinant proteins from 70S ribosomes was achieved by specific proteolytic cleavage followed by efficient removal of ribosomes by centrifugation. By this procedure we isolated active green fluorescent protein, streptavidin (SA), and murine interleukin-6 (mIL-6). Approximately 500microg of each protein was isolated per gram cellular wet weight. By pull-down assays we demonstrate that SA covalently bound to the ribosome binds d-biotin. Ribosomal coupling is therefore suggested as a method for the investigation of protein interactions. The presented strategy is in particular efficient for the expression, purification, and investigation of proteins forming inclusion bodies in the E. coli cytoplasm.     

The Xenopus laevis Atg4B Protease: Insights into Substrate Recognition and Application for Tag Removal from Proteins Expressed in Pro- and Eukaryotic Hosts

During autophagy, members of the ubiquitin-like Atg8 protein family get conjugated to phosphatidylethanolamine and act as protein-recruiting scaffolds on the autophagosomal membrane. The Atg4 protease produces mature Atg8 from C-terminally extended precursors and deconjugates lipid-bound Atg8. We now found that Xenopus laevis Atg4B (xAtg4B) is ideally suited for proteolytic removal of N-terminal tags from recombinant proteins. To implement this strategy, an Atg8 cleavage module is inserted in between tag and target protein. An optimized xAtg4B protease fragment includes the so far uncharacterized C-terminus, which crucially contributes to recognition of the Xenopus Atg8 homologs xLC3B and xGATE16. xAtg4B-mediated tag cleavage is very robust in solution or on-column, efficient at 4°C and orthogonal to TEV protease and the recently introduced proteases bdSENP1, bdNEDP1 and xUsp2. Importantly, xLC3B fusions are stable in wheat germ extract or when expressed in Saccharomyces cerevisiae, but cleavable by xAtg4B during or following purification. We also found that fusions to the bdNEDP1 substrate bdNEDD8 are stable in S. cerevisiae. In combination, or findings now provide a system, where proteins and complexes fused to xLC3B or bdNEDD8 can be expressed in a eukaryotic host and purified by successive affinity capture and proteolytic release steps.     

Construction of a mini-intein fusion system to allow both direct monitoring of soluble protein expression and rapid purification of target proteins

Affinity purification of recombinant proteins has been facilitated by fusion to a modified protein splicing element (intein). The fusion protein expression can be further improved by fusion to a mini-intein, i.e. an intein that lacks an endonuclease domain. We synthesized three mini-inteins using overlapping oligonucleotides to incorporate Escherichia coli optimized codons and allow convenient insertion of an affinity tag between the intein (predicted) N- and C-terminal fragments. After examining the splicing and cleavage activities of the synthesized mini-inteins, we chose the mini-intein most efficient in thiol-induced N-terminal cleavage for constructing a novel intein fusion system. In this system, green fluorescent protein (GFP) was fused to the C-terminus of the affinity-tagged mini-intein whose N-terminus was fused to a target protein. The design of the system allowed easy monitoring of soluble fusion protein expression by following GFP fluorescence, and rapid purification of the target protein through the intein-mediated cleavage reaction. A total of 17 target proteins were tested in this intein-GFP fusion system. Our data demonstrated that the fluorescence of the induced cells could be used to measure soluble expression of the intein fusion proteins and efficient intein cleavage activity. The final yield of the target proteins exhibited a linear relationship with whole cell fluorescence. The intein-GFP system may provide a simple route for monitoring real time soluble protein expression, predicting final product yields, and screening the expression of a large number of recombinant proteins for rapid purification in high throughput applications.     

The use of recombinant fusion proteases in the affinity purification of recombinant proteins

In the affinity purification of recombinant fusion proteins, the rate-limiting step is usually the efficient proteolytic cleavage and removal of the affinity tail and the protease from the purified recombinant protein. We have developed a rapid, convenient, and efficient method of affinity purification that can overcome this limitation. In one example of the method, the protease 3C from a picornavirus (3Cpro), which cleaves specific sequences containing a minimum of 6-7 amino acids, has been expressed as a fusion with glutathione S-transferase. The resultant recombinant "fusion protease" cleaves fusion proteins bearing (from the amino-terminus) the same affinity tail as the fusion protease, a 3Cpro cleavage recognition site, and the recombinant protein of interest. The recombinant protein is purified in a single chromatographic step, which removes both the affinity tail and the fusion protease. The advantages over existing methods include much improved specificity of proteolytic cleavage, complete removal of the protease and the affinity tail in one step, and the option of adding any desired amount of fusion protease to ensure efficient cleavage. The potential flexibility of the method is shown by the use of various affinity tails and alternative fusion proteases.     

A cleavable self‐assembling tag strategy for preparing proteins and peptides with an authentic N‐terminus

Recombinant protein expression and purification remains a central need for biotechnology. Herein, the authors report a streamlined protein and peptide purification strategy using short self‐assembling peptides and a C‐terminal cleavage intein. In this strategy, the fusion protein is first expressed as an aggregate induced by the self‐assembling peptide. Upon simple separation, the target protein or peptide with an authentic N‐terminus is then released in the solution by intein‐mediated cleavage. Different combinations of four self‐assembling peptides (ELK16, L₆KD, FK and FR) with three inteins (Sce VMA, Mtu ΔI‐CM and Ssp DnaB) were explored. One protein and two peptides were used as model polypeptides to test the strategy. The intein Mtu ΔI‐CM, which has pH‐shift inducible cleavage, was found to work well with three self‐assembling peptides (L₆KD, FR, FK). Using this intein gave a yield of protein or peptide comparable with that from other more established strategies, such as the Trx‐strategy, but in a simpler and more economical way. This strategy provides a simple and efficient method by which to prepare proteins and peptides with an authentic N‐terminus, which is especially effective for peptides of 30‐100 amino acids in length that are typically unstable and susceptible to degradation in Escherichia coli.     

HaloTag-based purification of functional human kinases from mammalian cells

Although cultured mammalian cells are preferred for producing functional mammalian proteins with appropriate post-translational modifications, purification of recombinant proteins is frequently hampered by low expression. We have addressed this by creating a new method configured specifically for mammalian cell culture that provides rapid detection and efficient purification. This approach is based on HaloTag, a protein fusion tag designed to bind rapidly, selectively and covalently to a series of synthetic ligands that can carry a variety of functional groups, including fluorescent dyes for detection or solid supports for purification. Since the binding of HaloTag to the HaloLink resin is essentially irreversible, it overcomes the equilibrium-based binding limitations associated with affinity tags and enables efficient capture and purification of target protein, even at low expression levels. The target protein is released from the HaloLink resin by specific cleavage using a TEV protease fused to HaloTag (HaloTEV), leaving both HaloTag and HaloTEV permanently attached to the resin and highly pure, tag-free protein in solution. HaloTag fluorescent ligands enable fluorescent labeling of HaloTag fusion proteins, providing a convenient way to monitor expression, and thus facilitate the identification of optimal transient transfection conditions as well as the selection of high expression stable cell lines. The capabilities of this method have been demonstrated by the efficient purification of five functional human kinases from HEK293T cells. In addition, when purifications using FLAG, 3xFLAG, His(6)Tag and HaloTag were performed in parallel, HaloTag was shown to provide significantly higher yields, purity and overall recovery of the expressed proteins.     

Screening methods to determine biophysical properties of proteins in structural genomics

We have developed and tested a simple and efficient protein purification method for biophysical screening of proteins and protein fragments by nuclear magnetic resonance (NMR) and optical methods, such as circular dichroism spectroscopy. The method constitutes an extension of previously described protocols for gene expression and protein solubility screening [M. Hammarstr?m et al., (2002), Protein Science 11, 313]. Using the present purification scheme it is possible to take several target proteins, produced as fusion proteins, from cell pellet to NMR spectrum and obtain a judgment on the suitability for further structural or biophysical studies in less than 1 day. The method is independent of individual protein properties as long as the target protein can be produced in soluble form with a fusion partner. Identical procedures for cell culturing, lysis, affinity chromatography, protease cleavage, and NMR sample preparation then initially require only optimization for different fusion partner and protease combinations. The purification method can be automated, scaled up or down, and extended to a traditional purification scheme. We have tested the method on several small human proteins produced in Escherichia coli and find that the method allows for detection of structured proteins and unfolded or molten globule-like proteins.     

Production and purification of an analog of glucagon-like peptide-1 by auto-induction and on-column cleavage in <Emphasis Type="Italic">Escherichia coli</Emphasis>

As a promising type 2 anti-diabetic agent, glucagon-like peptide-1 (GLP-1) is attracting more and more interest. Mutated GLP-1 (mGLP-1) is an analog of native GLP-1. To facilitate the production and purification of mGLP-1, auto-induction and on-column cleavage was employed in this study. By using auto-induction system, after 24 h of shaking culture, about 12.6 g wet bacterial cells could be obtained from 1 l medium, and this was about 3.6 times more than that of the IPTG-induction group. After disruption and centrifugation, the fusion protein was directly purified and cleaved on Ni–Sepharose 6 Fast Flow column. Then, RESOURCE15 RPC column was used for further purification. By using these two steps of purification, about 1.58 mg of mGLP-1 with the purity of up to 98% could be obtained from 1 g wet bacterial cells. In the bioactivity study, mGLP-1 displayed a significant and dose-dependent glucose-lowering activity. These results suggested that auto-induction and on-column cleavage could facilitate the production and purification of mGLP-1. These methods could also be applied to the preparation of other proteins and peptides.     

Simplified characterization through site-specific protease-mediated release of affinity proteins selected by staphylococcal display

The production of candidate affinity proteins in a soluble form, for downstream characterization, is often a time-consuming step in combinatorial protein engineering methods. Here, a novel approach for efficient production of candidate clones is described based on direct cleavage of the affinity protein from the surface of Staphylococcus carnosus, followed by affinity purification. To find a suitable strategy, three new fusion protein constructs were created, introducing a protease site for specific cleavage and purification tags for affinity chromatography purifications into the staphylococcal display vector. The three modified strains were evaluated in terms of transformation frequency, surface expression level and protease cleavage efficiency. A protocol for efficient affinity purification of protease-released affinity proteins using the introduced fusion-tags was successfully used, and the functionality of protease-treated and purified proteins was verified in a biosensor assay. To evaluate the devised method, a previously selected HER2-specific affibody was produced applying the new principle and was used to analyze HER2 expression on human breast cancer cells.     

A rapid method to attain isotope labeled small soluble peptides for NMR studies

A widely applicable strategy is presented for efficient and rapid production of small water soluble peptides expressed as fusion proteins with the immunoglobulin-binding domain of streptococcal protein G. A simple extraction and purification scheme that includes a protease cleavage step to release the target peptide is described. The yield of authentic target peptide exceeds 10 mg per liter of culture. Production of U-¹³C, ¹⁵N and highly deuterated U-¹³C, ¹⁵N isotope labeled peptide is demonstrated for the 11 residue S2 peptide, corresponding to the C-terminus of the -subunit of transducin, and the coiled coil trimerization domain from cartilage matrix protein (CMPcc), respectively. Heteronuclear two-dimensional NMR spectra are used for initial peptide characterization.     

Expression vectors for enzyme restriction- and ligation-independent cloning for producing recombinant His-fusion proteins

In this work we have constructed two novel expression vectors, designated as pURI2 and pURI3, which enable parallel cloning of a given target gene for producing recombinant His-fusion proteins. The vectors were created using the well-known pT7-7 and pIN-III-A3 plasmids as their template. The same DNA fragment containing the His-tag, enterokinase cleavage site, and a NotI unique site, as well as keeping the HindIII unique restriction site, was introduced in both vectors. These vectors have been designed to avoid the enzyme restriction and ligation steps during the cloning. The unique NotI site was introduced to facilitate the selection of the adequate recombinant plasmid. Parallel cloning of the same polymerase chain reaction fragment can be carried out since both vectors shared the same leader sequence. The described strategy avoids tedious cloning efforts into different expression vectors and represents a highly efficient means of cloning. To validate our vectors, we have cloned one target gene in both vectors and used expression and purification techniques to obtain the recombinant target protein. We herein show that both vectors function effectively in all the required experimental steps-cloning, expression, purification, and cleavage.     

Chemical ligation and cleavage on solid support facilitate recombinant peptide purification

Recombinant peptide technology offers a promising means alternative to chemical synthesis and natural extraction of peptides. The bottleneck in the process of recombinant peptide production is the paucity of efficient purification protocols to eliminate heterogeneity of the desired preparation. Here, we introduce a combination strategy to facilitate purification of recombinant therapeutic peptide via native chemical ligation and chemical cleavage on a solid support. In this study, one promising therapeutic peptide called for type-2 diabetes, GLP-1(7-37), was prepared with high yield and purity without an expensive HPLC purification. Furthermore, this method is also useful for the preparation of isotopically labeled NMR peptide samples. Hopefully, this strategy combining chemical ligation with chemical cleavage on a solid support will ameliorate the production of important recombinant pharmaceutical peptides.     

An expression vector tailored for large-scale, high-throughput purification of recombinant proteins

Production of milligram quantities of numerous proteins for structural and functional studies requires an efficient purification pipeline. We found that the dual tag, his(6)-tag-maltose-binding protein (MBP), intended to facilitate purification and enhance proteins' solubility, disrupted such a pipeline, requiring additional screening and purification steps. Not all proteins rendered soluble by fusion to MBP remained soluble after its proteolytic removal, and in those cases where the protein remained soluble, standard purification protocols failed to remove completely the stoichiometric amount of his(6)-tagged MBP generated by proteolysis. Both liabilities were alleviated by construction of a vector that produces fusion proteins in which MBP, the his(6)-tag and the target protein are separated by highly specific protease cleavage sites in the configuration MBP-site-his(6)-site-protein. In vivo cleavage at the first site by co-expressed protease generated untagged MBP and his(6)-tagged target protein. Proteins not truly rendered soluble by transient association with MBP precipitated, and untagged MBP was easily separated from the his-tagged target protein by conventional protocols. The second protease cleavage site allowed removal of the his(6)-tag.     

Study of protein splicing and intein-mediated peptide bond cleavage under high-cell-density conditions

Protein splicing elements (inteins), capable of catalyzing controllable peptide bond cleavage reactions, have been used to separate recombinant proteins from affinity tags during affinity purification. Since the inteins eliminate the use of a protease in the recovery process, the intein-mediated purification system has the potential to significantly reduce recovery costs for the industrial production of recombinant proteins. Thus far, the intein system has only been examined and utilized for expression and purification of recombinant proteins at the laboratory scale for cells cultivated at low cell densities. In this study, protein splicing and in vitro cleavage of intein fusion proteins expressed in high-cell-density fed-batch fermentations of recombinant Escherichia coli were examined. Three model intein fusion constructs were used to examine the stability and splicing/cleavage activities of the fusion proteins produced under high-cell-density conditions. The data indicated that the intein fusion protein containing the wild-type intein catalyzed efficient in vivo protein splicing during high-cell-density cultivation. Also, the intein fusion proteins containing modified inteins catalyzed efficient thiol-induced in vitro cleavage reactions. The results of this study demonstrated the potential feasibility of using the intein-mediated protein purification system for industrial-scale production of recombinant proteins.     

SOn-column Protein Refolding for Crystallization

One major bottleneck in protein production in Escherichia coli for structural genomics projects is the formation of insoluble protein aggregates (inclusion bodies). The efficient refolding of proteins from inclusion bodies is becoming an important tool that can provide soluble native proteins for structural and functional studies. Here we report an on-column refolding method established at the Berkeley Structural Genomics Center (BSGC). Our method is a combination of an ‘artificial chaperone-assisted refolding’ method previously proposed and affinity chromatography to take advantage of a chromatographic step: less time-consuming, no filtration or concentration, with the additional benefit of protein purification. It can be easily automated and formatted for high-throughput process.     

A self-cleavable sortase fusion for one-step purification of free recombinant proteins

A new protein fusion system has been developed to generate free recombinant protein in a single affinity chromatographic step. The key component in the fusion is the catalytic core of sortase A from Staphylococcus aureus (SrtAc), which recognizes and cleaves the Thr-Gly bond at an LPXTG sequence with moderate activity. The fusion here consists of an N-terminal His6 tag, SrtAc, and an LPETG linker followed by protein of interest at the C-terminus. The fusion protein is expressed in Escherichia coli and purified by immobilized metal-ion affinity chromatography (IMAC). The immobilized fusion then undergoes on-column SrtAc-mediated cleavage at the LPETG site in the presence of Ca2+ and/or triglycine. The target protein with an extra N-terminal glycine is released from the fusion while the N-terminal portion remains bound to the column. Because the cleavage enzyme SrtAc is co-expressed as a fusion with the target protein, the purification system eliminates exogenous proteolysis. This purification approach is simple, robust, inexpensive, time saving, and allows purification of free recombinant protein via one-step chromatography.     

An effective system for detecting protein-protein interaction based on in vivo cleavage by PPV NIa protease

Detection of protein-protein interaction can provide valuable information for investigating the biological function of proteins. The current methods that applied in protein-protein interaction, such as co-immunoprecipitation and pull down etc., often cause plenty of working time due to the burdensome cloning and purification procedures. Here we established a system that characterization of protein-protein interaction was accomplished by co-expression and simply purification of target proteins from one expression cassette within E. coli system. We modified pET vector into co-expression vector pInvivo which encoded PPV NIa protease, two cleavage site F and two multiple cloning sites that flanking cleavage sites. The target proteins (for example: protein A and protein B) were inserted at multiple cloning sites and translated into polyprotein in the order of MBP tag-protein A-site F-PPV NIa protease-site F-protein B-His₆ tag. PPV NIa protease carried out intracellular cleavage along expression, then led to the separation of polyprotein components, therefore, the interaction between protein A-protein B can be detected through one-step purification and analysis. Negative control for protein B was brought into this system for monitoring interaction specificity. We successfully employed this system to prove two cases of reported protien- protein interaction: RHA2a/ANAC and FTA/FTB. In conclusion, a convenient and efficient system has been successfully developed for detecting protein-protein interaction.