Recombinant chymosin used for exact and complete removal of a prochymosin derived fusion tag releasing intact native target protein

Fusion tags add desirable properties to recombinant proteins, but they are not necessarily acceptable in the final products. Ideally, fusion tags should be removed releasing the intact native protein with no trace of the tag. Unique endoproteinases with the ability to cleave outside their own recognition sequence can potentially cleave at the boundary of any native protein. Chymosin was recently shown to cleave a pro‐chymosin derived fusion tag releasing native target proteins. In our hands, however, not all proteins are chymosin‐resistant under the acidic cleavage conditions (pH 4.5) used in this system. Here, we have modified the pro‐chymosin fusion tag and demonstrated that chymosin can remove this tag at more neutral pH (pH 6.2); conditions, that are less prone to compromise the integrity of target proteins. Chymosin was successfully used to produce intact native target protein both at the level of small and large‐scale preparations. Using short peptide substrates, we further examined the influence of P1′ amino acid (the N‐terminus of the native target protein) and found that chymosin accepts many different, although not all, amino acids. We conclude that chymosin has several appealing characteristics for the exact removal of fusion tags. It is readily available in highly purified recombinant versions approved by the FDA for preparation of food for human consumption. We suggest that one should consider extending the use of chymosin to the preparation of pharmaceutical proteins.     

Crystal structure of tobacco etch virus protease shows the protein C terminus bound within the active site

Tobacco etch virus (TEV) protease is a cysteine protease exhibiting stringent sequence specificity. The enzyme is widely used in biotechnology for the removal of the affinity tags from recombinant fusion proteins. Crystal structures of two TEV protease mutants as complexes with a substrate and a product peptide provided the first insight into the mechanism of substrate specificity of this enzyme. We now report a 2.7A crystal structure of a full-length inactive C151A mutant protein crystallised in the absence of peptide. The structure reveals the C terminus of the protease bound to the active site. In addition, we determined dissociation constants of TEV protease substrate and product peptides using isothermal titration calorimetry for various forms of this enzyme. Data suggest that TEV protease could be inhibited by the peptide product of autolysis. Separate modes of recognition for native substrates and the site of TEV protease self-cleavage are proposed.     

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.     

A generic protocol for the expression and purification of recombinant proteins in Escherichia coli using a combinatorial His6-maltose binding protein fusion tag

We describe a generic protocol for the overproduction and purification of recombinant proteins in Escherichia coli. The strategy utilizes a dual His6-maltose binding protein (HisMBP) affinity tag that can be removed from the target protein by digestion of the fusion protein at a designed site by tobacco etch virus protease. The MBP moiety serves to enhance the solubility and promote the proper folding of its fusion partners, and the polyhistidine tag facilitates its purification to homogeneity. This protocol is divided into three stages, each of which takes approximately 1 week to complete: (i) construction of a HisMBP fusion vector; (ii) a pilot experiment to assess the yield and solubility of the target protein; and (iii) the large-scale production and purification of the target protein.     

Self-cleaving fusion tags for recombinant protein production

Fusion expression is a common practice for recombinant protein production. Some fusion tags confer solubility on the target protein whereas others provide affinity handles that facilitate purification. However, the tag usually needs to be removed from the final product, which involves using expensive proteases or hazardous chemicals and requires additional chromatography steps. Self-cleaving tags are a special group of fusion tags that possess inducible proteolytic activity. Combined with appropriate affinity tags, they enable fusion purification, cleavage and target separation to be achieved in a single step, which saves time, labor and cost. This paper reviews currently available self-cleaving fusion tags for recombinant protein production. For each system, an introduction of its key characteristics and a brief discussion of its advantages and disadvantages is given.     

Expression of a kallikrein-like protease from the snake venom: engineering of autocatalytic site in the fusion protein to facilitate protein refolding

In order to circumvent the difficulty encountered in the expression and purification of the recombinant products in E. coli system, we have developed a novel and facile method of removing the polyhistidine tag from target proteins after heterologous gene expression. The expression of a serine protease (Tm-5) from Taiwan habu (Trimeresurus mucrosquamatus) is taken as an exemplar to illustrate the basic rationales and protocols involved. In place of an enterokinase recognition site, a polyhistidine tag linked to an autocatalyzed site based on cleavage specificity of the serine protease flanking on the 5'-end of Tm-5 clone sequence was engineered before protein expression in E. coli system. Renaturation of the fusion protein after expression revealed that the recombinant protease had refolded successfully from the inclusion bodies. Upon autocleavage of the expressed protease, the polyhistidine tag with additional amino acid residues appended to the N-terminus of the coding sequence is found to be removed accordingly. The protein expressed and purified by this new strategy possesses a molecular weight of approximately 28,000 in accord with the expected value for this venom protease. Further characterization of the recombinant protein employing a variety of techniques which include immunoblot analysis, RP-HPLC, ESI-MS, and N-terminal amino acid sequencing all shows indistinguishable properties to those of the isolated native protease. Most noteworthy is that the recombinant Tm-5 protease also exhibits amidase activity against N-benzoyl-Pro-Phe-Arg-p-nitroanilide, a unique and strict substrate for native Tm proteases reported previously.     

Inhibition of tobacco etch virus protease activity by detergents

Affinity tags such as polyhistidine greatly facilitate recombinant protein production. The solubility of integral membrane proteins is maintained by the formation of protein-detergent complexes (PDCs), with detergent present at concentration above its critical micelle concentration (CMC). Removal of the affinity tag necessitates inclusion of an engineered protease cleavage site. A commonly utilized protease for tag removal is tobacco etch virus (TEV) protease. TEV is available in a recombinant form (rTEV) and frequently contains its own polyhistidine affinity tag for removal after use in enzymatic digestion. Proteolytic cleavage of the tagged domain is carried out by incubation of the protein with rTEV protease. We have observed that the efficiency of rTEV digestion decreases significantly in the presence of a variety of detergents utilized in purification, crystallization, and other biochemical studies of integral membrane proteins. This reduction in protease activity is suggestive of detergent-induced inhibition of rTEV. To test this hypothesis, we examined the effects of detergents upon the rTEV proteolytic digestion of a soluble fusion protein, alpha(1) platelet activating factor acetylhydrolase (PAFAHalpha(1)). Removal of a hexahistidine amino-terminal affinity tag has been characterized in the presence of 16 different detergents at concentrations above their respective CMCs. Our data indicate that half of the detergents tested reduce the activity of rTEV and that these detergents should be avoided or otherwise accounted for during rTEV digestion of recombinant integral membrane proteins.     

Increased solubility of integrin betaA domain using maltose-binding protein as a fusion tag

In proteomics research, generation of recombinant proteins in their native, soluble form with large quantity is often a challenging task. To tackle the expression difficulties, different expression vectors with distinct affinity fusion tags, i.e. pET-43.1a (N-utilization substance A tag), pMAL-cRI (maltose binding protein tag) (MBP tag), pGEX-4T-2 (glutathione S-transferase tag), and pET-15b (hexahistidine tag) were compared for their effects on the productivity and solubility, which were assessed by SDS-PAGE and immunoblotting, of the integrin betaA domain. The incubation temperatures were tested for its effects on these parameters. Our data suggested that MBP tag enhanced the yield and solubility of the betaA domain protein, which can also be recognized using an anti-CD18 antibody, at room temperature incubation. Thus, the nature of fusion partner chosen for expression in bacteria and its incubation temperature would significantly affect the yield and solubility of the recombinant target protein.     

A PCR-directed cell-free approach to optimize protein expression using diverse fusion tags

N-terminal fusion tags that enhance translation initiation or protein solubility are often used to facilitate protein overexpression. As the optimal tag for a given target protein cannot be predicted a priori, valuable time can be lost in cloning and manipulating the corresponding gene to generate different fusion constructs for expression analysis. We have developed a cell-free strategy that consolidates these steps, enabling the utility of a panel of nine fusion-tags to be determined within one to two days. This approach exploits the fact that PCR-amplified DNA can be used as a template for cell-free protein synthesis. Overlap/extension PCR using the TEV protease site as the overlap region allows the fusion of different T7 promoter (T7p)-tag-TEV DNA fragments with a TEV-gene-T7 terminator (T7ter) fragment. For tag sequences where the TEV site is not compatible, a short C?G? repeat (CGr) sequence can be used as the overlap region. The resulting T7p-tag-TEV-gene-T7ter constructs are then used as templates for PCR-directed cell-free protein synthesis to identify which tag-TEV-gene fusion protein produces the highest amount of soluble protein. We have successfully applied this approach to the overexpression of the Adiponectin hypervariable domain (AHD). Five of the nine N-terminal fusion tags tested enabled the synthesis of soluble recombinant protein. The best of these was the Peptidyl-prolylcis-trans isomerise B (PpiB) fusion tag which produces 1mg/ml amounts of soluble fusion protein. PpiB is an example of a new class of fusion tag known as the "stress-responsive proteins". Our results suggest that this cell-free fusion-tag expression screen facilitates the rapid identification of suitable fusion-tags that overcome issues such as poor expression and insolubility, often encountered using conventional approaches.     

The novel Fh8 and H fusion partners for soluble protein expression in Escherichia coli: a comparison with the traditional gene fusion technology

The Escherichia coli host system is an advantageous choice for simple and inexpensive recombinant protein production but it still presents bottlenecks at expressing soluble proteins from other organisms. Several efforts have been taken to overcome E. coli limitations, including the use of fusion partners that improve protein expression and solubility. New fusion technologies are emerging to complement the traditional solutions. This work evaluates two novel fusion partners, the Fh8 tag (8 kDa) and the H tag (1 kDa), as solubility enhancing tags in E. coli and their comparison to commonly used fusion partners. A broad range comparison was conducted in a small-scale screening and subsequently scaled-up. Six difficult-to-express target proteins (RVS167, SPO14, YPK1, YPK2, Frutalin and CP12) were fused to eight fusion tags (His, Trx, GST, MBP, NusA, SUMO, H and Fh8). The resulting protein expression and solubility levels were evaluated by sodium dodecyl sulfate polyacrylamide gel electrophoresis before and after protein purification and after tag removal. The Fh8 partner improved protein expression and solubility as the well-known Trx, NusA or MBP fusion partners. The H partner did not function as a solubility tag. Cleaved proteins from Fh8 fusions were soluble and obtained in similar or higher amounts than proteins from the cleavage of other partners as Trx, NusA or MBP. The Fh8 fusion tag therefore acts as an effective solubility enhancer, and its low molecular weight potentially gives it an advantage over larger solubility tags by offering a more reliable assessment of the target protein solubility when expressed as a fusion protein.     

Comparison of SUMO fusion technology with traditional gene fusion systems: enhanced expression and solubility with SUMO

Despite the availability of numerous gene fusion systems, recombinant protein expression in Escherichia coli remains difficult. Establishing the best fusion partner for difficult-to-express proteins remains empirical. To determine which fusion tags are best suited for difficult-to-express proteins, a comparative analysis of the newly described SUMO fusion system with a variety of commonly used fusion systems was completed. For this study, three model proteins, enhanced green fluorescent protein (eGFP), matrix metalloprotease-13 (MMP13), and myostatin (growth differentiating factor-8, GDF8), were fused to the C termini of maltose-binding protein (MBP), glutathione S-transferase (GST), thioredoxin (TRX), NUS A, ubiquitin (Ub), and SUMO tags. These constructs were expressed in E. coli and evaluated for expression and solubility. As expected, the fusion tags varied in their ability to produce tractable quantities of soluble eGFP, MMP13, and GDF8. SUMO and NUS A fusions enhanced expression and solubility of recombinant proteins most dramatically. The ease at which SUMO and NUS A fusion tags were removed from their partner proteins was then determined. SUMO fusions are cleaved by the natural SUMO protease, while an AcTEV protease site had to be engineered between NUS A and its partner protein. A kinetic analysis showed that the SUMO and AcTEV proteases had similar KM values, but SUMO protease had a 25-fold higher kcat than AcTEV protease, indicating a more catalytically efficient enzyme. Taken together, these results demonstrate that SUMO is superior to commonly used fusion tags in enhancing expression and solubility with the distinction of generating recombinant protein with native sequences.     

HaloTag7: A genetically engineered tag that enhances bacterial expression of soluble proteins and improves protein purification

Over-expression and purification of soluble and functional proteins remain critical challenges for many aspects of biomolecular research. To address this, we have developed a novel protein tag, HaloTag7, engineered to enhance expression and solubility of recombinant proteins and to provide efficient protein purification coupled with tag removal. HaloTag7 was designed to bind rapidly and covalently with a unique synthetic linker to achieve an essentially irreversible attachment. The synthetic linker may be attached to a variety of entities such as fluorescent dyes and solid supports, permitting labeling of fusion proteins in cell lysates for expression screening, and efficient capture of fusion proteins onto a purification resin. The combination of covalent capture with rapid binding kinetics overcomes the equilibrium-based limitations associated with traditional affinity tags and enables efficient capture even at low expression levels. Following immobilization on the resin, the protein of interest is released by cleavage at an optimized TEV protease recognition site, leaving HaloTag7 bound to the resin and pure protein in solution. Evaluation of HaloTag7 for expression of 23 human proteins in Escherichia coli relative to MBP, GST and His₆Tag revealed that 74% of the proteins were produced in soluble form when fused to HaloTag7 compared to 52%, 39% and 22%, respectively, for the other tags. Using a subset of the test panel, more proteins fused to HaloTag7 were successfully purified than with the other tags, and these proteins were of higher yield and purity.     

Improving expression and solubility of rice proteins produced as fusion proteins in Escherichia coli

For proteins of higher eukaryotes, such as plants, which have large genomes, recombinant protein expression and purification are often difficult. Expression levels tend to be low and the expressed proteins tend to misfold and aggregate. We tested seven different expression vectors in Escherichia coli for rapid subcloning of rice genes and for protein expression and solubility levels. Each expressed gene product has an N-terminal fusion protein and/or tag, and an engineered protease site upstream of the mature rice protein. Several different fusion proteins/tags and protease sites were tested. We found that the fusion proteins and the protease sites have significant and varying effects on expression and solubility levels. The expression vector with the most favorable characteristics is pDEST-trx. The vector, which is a modified version of the commercially available expression vector, pET-32a, contains an N-terminal thioredoxin fusion protein and a hexahistidine tag, and is adapted to the Gateway expression system. However, addition of an engineered protease site could drastically change the expression and solubility properties. We selected 135 genes corresponding to potentially interesting rice proteins, transferred the genes from cDNAs to expression vectors, and engineered in suitable protease sites N-terminal to the mature proteins. Of 135 genes, 131 (97.0%) could be expressed and 72 (53.3%) were soluble when the fusion proteins/tags were present. Thirty-eight mature-length rice proteins and domains (28.1%) are suitable for NMR solution structure studies and/or X-ray crystallography. Our expression systems are useful for the production of soluble plant proteins in E. coli to be used for structural genomics studies.     

Do-it-yourself histidine-tagged bovine enterokinase: A handy member of the protein engineer's toolbox

Enterokinase, a two-chain duodenal serine protease, activates trypsinogen by removing its N-terminal propeptide. Due to a clean cut after the non-primed site recognition sequence, the enterokinase light chain is frequently employed in biotechnology to separate N-terminal affinity tags from target proteins with authentic N-termini. In order to obtain large quantities of this protease, we adapted an in vitro folding protocol for a pentahistidine-tagged triple mutant of the bovine enterokinase light chain. The purified, highly active enzyme successfully processed recombinant target proteins, while the pentahistidine-tag facilitated post-cleavage removal. Hence, we conclude that producing enterokinase in one's own laboratory is an efficient alternative to the commercial enzyme.     

Recombinant Human Cytomegalovirus Protease with a C-Terminal (His)6Extension: Purification, Autocatalytic Release of the Mature Enzyme, and Biochemical Characterization

Human cytomegalovirus protease (CMV PR) is a target for the development of antiviral therapeutics. To obtain large amounts of native protease, a 268-amino-acid polypeptide with a hexahistidinyl tag at the C terminus was expressed inEscherichia coli.The first 262 amino acids of the recombinant protein were identical to the amino acid sequence of native CMV PR, except for mutations introduced at the internal cleavage site to eliminate autoproteolysis at that site. The hexahistidinyl tag was placed downstream of amino acid 262 of the native CMV PR sequence. In this design, the Ala-Ser bond at amino acids 256–257 constitutes a site naturally cleaved by the protease during capsid maturation. The 268-amino-acid polypeptide with the (His)₆tag was expressed at high levels inE. colias inclusion bodies. After solubilization of the inclusion bodies, the protease was purified to homogeneity by a single step using Ni²⁺affinity chromatography. The protease was refolded to an active enzyme using dialysis which leads to effective autocleavage of the Ala-Ser bond at amino acids 256–257 to remove 12 amino acids including the (His)₆tag from the C terminus of the protein. This strategy yielded large amounts of highly purified CMV PR with the native N terminus and C terminus. Approximately 40 mg of purified CMV PR was obtained per liter of cell culture using this strategy. The enzymatic activity of CMV PR purified from inclusion bodies and refolded to an active enzyme was similar to the enzymatic activity of CMV PR expressed as a soluble protein inE. coli.In addition, the refolded CMV PR could be crystallized for X-ray diffraction.     

The P1' specificity of tobacco etch virus protease

Affinity tags have become indispensable tools for protein expression and purification. Yet, because they have the potential to interfere with structural and functional studies, it is usually desirable to remove them from the target protein. The stringent sequence specificity of the tobacco etch virus (TEV) protease has made it a useful reagent for this purpose. However, a potential limitation of TEV protease is that it is believed to require a Gly or Ser residue in the P1' position of its substrates to process them with reasonable efficiency. Consequently, after an N-terminal affinity tag is removed by TEV protease, the target protein will usually retain a non-native Ser or Gly residue on its N-terminus, and in some cases this may affect its biological activity. To investigate the stringency of the requirement for Gly or Ser in the P1' position of a TEV protease recognition site, we constructed 20 variants of a fusion protein substrate with an otherwise optimal recognition site, each containing a different amino acid in the P1' position. The efficiency with which these fusion proteins were processed by TEV protease was compared both in vivo and in vitro. Additionally, the kinetic parameters K(M) and k(cat) were determined for a representative set of peptide substrates with amino acid substitutions in the P1' position. The results indicate that many side-chains can be accommodated in the P1' position of a TEV protease recognition site with little impact on the efficiency of processing.     

A Pair of Ligation-Independent Escherichia coli Expression Vectors for Rapid Addition of a Polyhistidine Affinity Tag to the N- or C-Termini of Recombinant Proteins

6×His tag is one of the most widely used affinity fusion tags that facilitates detection and purification of recombinant proteins. However, the location of this tag within a particular type of protein may influence the expression, solubility, and bioactivity of the protein, and the optimal location needs to be determined experimentally. To provide a tool for rapid generation of 6× His tags at the N- or C-terminus of any recombinant protein, we have constructed a pair of Escherichia coli expression vectors—pLIC-NHis and pLIC-CHis—based on the pET30a vector, for ligation-independent cloning (LIC). Construction of this new pair of LIC vectors was accomplished by replacement of the multiple cloning site of pET30a with two specifically designed LIC cloning sites. A target gene derived by PCR with a pair of predesigned primers can be inserted into the LIC site of pLIC-NHis for expression of recombinant proteins fused with the N-terminal sequence MHHHHHHG or into that of pLIC-CHis for expression of recombinant proteins with the C-terminal sequence THHHHHH. Successful expression of two normal mammalian prion proteins and five bacterial proteins in E. coli using this pair of LIC vectors reveals that these vectors are valuable tools for the production of recombinant His-tagged proteins in E. coli.     

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.     

High level expression and single-step purification of hexahistidine-tagged L-2-hydroxyisocaproate dehydrogenase making use of a versatile expression vector set

Affinity tags as fusions to the N- or C-terminal part of proteins are valuable tools to facilitate the production and purification of proteins. In many cases, there may be the necessity to remove the tag after protein preparation to regain activity. Removal of the tag is accomplished by insertion of a unique amino acid sequence that is recognized and cleaved by a site specific protease. Here, we report the construction of an expression vector set that combines N- or C-terminal fusion to either a hexahistidine tag or Streptag with the possibility of tag removal by factor Xa or recombinant tobacco etch virus protease (rTEV), respectively. The vector set offers the option to produce different variants of the protein of interest by cloning the corresponding gene into four different Escherichia coli expression vectors. Either immobilized metal affinity chromatography or streptactin affinity chromatography can be used for the one-step purification. Furthermore, we show the successful application of the expression vector for C-terminal hexahistidine tagging. The expression and purification of His-tagged L-2-hydroxyisocaproate dehydrogenase yields fully active enzyme. The tag removal is here accomplished by a derivative of rTEV.     

Hyper-acidic protein fusion partners improve solubility and assist correct folding of recombinant proteins expressed in Escherichia coli

High expression of recombinant proteins in Escherichia coli (E. coli) often leads to protein aggregation. One popular approach to address this problem is the use of fusion tags (or partners) that improve the solubility of the proteins in question. However, such fusion tags are not effective for all proteins. In this study, we demonstrate that the hyper-acidic protein fusion partners can largely enhance the soluble expression of target proteins recalcitrant to the efforts by using routine solubilising tags. This new type of fusion partners examined includes three extremely acidic E. coli polypeptides, i.e. yjgD, the N-terminal domain of rpoD (sigma 70 factor of RNA polymerase) and our preliminarily evaluated msyB. The target proteins used are highly aggregation-prone, including EK (the bovine enterokinase), TEV (the tobacco etch virus protease) and rbcL (the large subunit of tobacco ribulose-1,5-bisphosphate carboxylase/oxygenase). On removal in vitro and in vivo of the fusion tags by using yeast SUMO/Ulp1 reaction and TEV auto-cleavage, the resultant findings indicate the hyper-acidic fusion partners can function as intramolecular chaperones assisting in the correct folding of the target proteins.