A highly efficient multifunctional tandem affinity purification approach applicable to diverse organisms

Determining the localization, binding partners, and secondary modifications of individual proteins is crucial for understanding protein function. Several tags have been constructed for protein localization or purification under either native or denaturing conditions, but few tags permit all three simultaneously. Here, we describe a multifunctional tandem affinity purification (MAP) method that is both highly efficient and enables protein visualization. The MAP tag utilizes affinity tags inserted into an exposed surface loop of mVenus offering two advantages: (1) mVenus fluorescence can be used for protein localization or FACS-based selection of cell lines; and (2) spatial separation of the affinity tags from the protein results in high recovery and reduced variability between proteins. MAP purification was highly efficient in multiple organisms for all proteins tested. As a test case, MAP combined with liquid chromatography-tandem MS identified known and new candidate binding partners and modifications of the kinase Plk1. Thus the MAP tag is a new powerful tool for determining protein modification, localization, and interactions.     

Human glutaredoxin 2 affinity tag for recombinant peptide and protein purification

Recombinant proteins are commonly expressed in fusion with an affinity tag to facilitate purification. We have in the present study evaluated the possible use of the human glutaredoxin 2 (Grx2) as an affinity tag for purification of heterologous proteins. Grx2 is a glutathione binding protein and we have shown in the present study that the protein can be purified from crude bacterial extracts by a one-step affinity chromatography on glutathione-Sepharose. We further showed that short peptides could be fused to either the N- or C-terminus of Grx2 without affecting its ability to bind to the glutathione column. However, when Grx2 was fused to either the 27 kDa green fluorescent protein or the 116 kDa beta-galactosidase, the fusion proteins lost their ability to bind glutathione-Sepharose. Insertion of linker sequences between the Grx2 and the fusion protein did not restore binding to the column. In summary, our findings suggest that Grx2 may be used as an affinity tag for purification of short peptides and possibly also certain proteins that do not interfere with the binding to glutathione-Sepharose. However, the failure of purifying either green fluorescent protein or beta-galactosidase fused to Grx2 suggests that the use of Grx2 as an affinity tag for recombinant protein purification is limited.     

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.     

Orthogonal Protein Purification Facilitated by a Small Bispecific Affinity Tag

Due to the high costs associated with purification of recombinant proteins the protocols need to be rationalized. For high-throughput efforts there is a demand for general methods that do not require target protein specific optimization¹ . To achieve this, purification tags that genetically can be fused to the gene of interest are commonly used² . The most widely used affinity handle is the hexa-histidine tag, which is suitable for purification under both native and denaturing conditions³ . The metabolic burden for producing the tag is low, but it does not provide as high specificity as competing affinity chromatography based strategies^1,2.Here, a bispecific purification tag with two different binding sites on a 46 amino acid, small protein domain has been developed. The albumin-binding domain is derived from Streptococcal protein G and has a strong inherent affinity to human serum albumin (HSA). Eleven surface-exposed amino acids, not involved in albumin-binding⁴ , were genetically randomized to produce a combinatorial library. The protein library with the novel randomly arranged binding surface (Figure 1) was expressed on phage particles to facilitate selection of binders by phage display technology. Through several rounds of biopanning against a dimeric Z-domain derived from Staphylococcal protein A⁵, a small, bispecific molecule with affinity for both HSA and the novel target was identified⁶ .The novel protein domain, referred to as ABDz1, was evaluated as a purification tag for a selection of target proteins with different molecular weight, solubility and isoelectric point. Three target proteins were expressed in Escherishia coli with the novel tag fused to their N-termini and thereafter affinity purified. Initial purification on either a column with immobilized HSA or Z-domain resulted in relatively pure products. Two-step affinity purification with the bispecific tag resulted in substantial improvement of protein purity. Chromatographic media with the Z-domain immobilized, for example MabSelect SuRe, are readily available for purification of antibodies and HSA can easily be chemically coupled to media to provide the second matrix.This method is especially advantageous when there is a high demand on purity of the recovered target protein. The bifunctionality of the tag allows two different chromatographic steps to be used while the metabolic burden on the expression host is limited due to the small size of the tag. It provides a competitive alternative to so called combinatorial tagging where multiple tags are used in combination^1,7.     

Synthesis, purification and bioactivity of recombinant human activin A expressed in the yeast Pichia pastoris

The transforming growth factor-beta (TGF-β) superfamily member, activin A, plays a central role in the regulation of multiple physiological processes including cell differentiation, mitogenesis, embryogenesis, apoptosis and inflammation. In normal cells, activin A signalling is regulated to maintain cellular and tissue health and suppress tumour growth. Disruption of activin A signalling has been implicated in tumour formation and progression. Hence, the availability of activin A is an important target for the development of diagnostics and drugs for therapeutic intervention. To this end, we have expressed human activin A in Pichia pastoris, permitting its secretion into culture medium and purification as the mature homodimer. A construct was engineered encoding the monomeric precursor protein with a N-terminal FLAG affinity tag (DYKDDDDK) and a cleavage site (EKR) for Kex2p protease. Procedures for the two-step purification of human activin A by ion-exchange and anti-FLAG antibody affinity chromatography, and for the removal of the FLAG affinity tag from purified recombinant human activin A by enteropeptidase, are described. The molecular weights of the FLAG-tagged and de-tagged human activin A were confirmed by MALDI-TOF mass spectroscopy. The biological activity of these recombinant activins was assessed for their effects on modulating the secretion of Endothelin-1 (ET-1) by human umbilical vein endothelial cells (HUVECs). The recombinant human activin A containing the intact FLAG tag resulted in a reduced ET-1 secretion from HUVECs, whereas upon removal of this affinity purification tag the purified recombinant human activin A restored ET-1 secretion to levels comparable to the positive control. These results document an approach of considerable potential for the simple, large-scale expression and purification of this important human growth factor for use in diagnostic and therapeutic purposes.     

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.     

Purification of components of the translation elongation factor complex of Plasmodium falciparum by tandem affinity purification

Plasmodium falciparum is the causative agent of severe human malaria, responsible for over 2 million deaths annually. Of the 5,300 polypeptides predicted to control the parasite life cycle in mosquitoes and humans, 60% are of unknown function. A major challenge of malaria postgenomic biology is to understand how the 5,300 predicted proteins coexist and interact to perform the essential tasks that define the complex life cycle of the parasite. One approach to assign function to these proteins is by identifying their physiological partners. Here we describe the use of tandem affinity purification (TAP) and mass spectrometry for identification of native protein interactions and purification of protein complexes in P. falciparum. Transgenic parasites were generated which express the translation elongation factor PfEF-1β harboring a C-terminal PTP tag which consists of the protein C epitope, a tobacco etch virus protease cleavage site, and two protein A domains. Purification of PfEF-1β-PTP from crude extracts followed by mass spectrometric analysis revealed, in addition to the tagged protein itself, the presence of the native PfEF-1β, the G-protein PfEF-1α, and two new proteins that we named PfEF-1γ and PfEF-1δ based on their homology to other eukaryotic γ and δ translation elongation factor subunits. These data, which constitute the first application of TAP for purification of a protein complex under native conditions in P. falciparum, revealed that the translation elongation complex in this organism contains at least two subunits of PfEF-1β. The success of this approach will set the stage for a systematic analysis of protein interactions in this important human pathogen.     

Relative position of the hexahistidine tag effects binding properties of a tumor-associated single-chain Fv construct

Hexahistidine tag (His-tag) is the most widely used tag for affinity purification of recombinant proteins for their structural and functional analysis. In the present study, single chain Fv (scFv) constructs were engineered form the monoclonal antibody (MAb) CC49 which is among the most extensively studied MAb for cancer therapy. For achieving efficient purification of scFvs by immobilized metal-ion affinity chromatography (IMAC), a His-tag was placed either at the C-terminal (scFv-His6) or N-terminal (His6-scFv) of the coding sequence. Solid-phase radioimmunoassay for scFv-His6 showed only 20-25% binding whereas both His6-scFv and scFv (no His-tag) showed 60-65% binding. Surface plasmon resonance studies by BIAcore revealed the binding affinity constant (KA) for His6-scFv and scFv as 1.19 x 10(6) M(-1) and 3.27 x 10(6) M(-1), respectively. No K(A) value could be calculated for scFv-His6 due to poor binding kinetics (kon and koff). Comparative homology modeling for scFv and scFv-His6 showed that the C-terminal position of the His-tag partially covered the antigen-binding site of the protein. The study demonstrates that the C-terminal position of His-tag on the CC49 scFv adversely affects the binding properties of the construct. The results emphasize the importance of functional characterization of recombinant proteins expressed with purification tags.     

Identification of Protein Interacting Partners Using Tandem Affinity Purification

A critical and often limiting step in understanding the function of host and viral proteins is the identification of interacting cellular or viral protein partners. There are many approaches that allow the identification of interacting partners, including the yeast two hybrid system, as well as pull down assays using recombinant proteins and immunoprecipitation of endogenous proteins followed by mass spectrometry identification¹. Recent studies have highlighted the utility of double-affinity tag mediated purification, coupled with two specific elution steps in the identification of interacting proteins. This approach, termed Tandem Affinity Purification (TAP), was initially used in yeast^2,3 but more recently has been adapted to use in mammalian cells^4-8.As proof-of-concept we have established a tandem affinity purification (TAP) method using the well-characterized eukaryotic translation initiation factor eIF4E^9,10.The cellular translation factor eIF4E is a critical component of the cellular eIF4F complex involved in cap-dependent translation initiation¹⁰. The TAP tag used in the current study is composed of two Protein G units and a streptavidin binding peptide separated by a Tobacco Etch Virus (TEV) protease cleavage sequence. The TAP tag used in the current study is composed of two Protein G units and a streptavidin binding peptide separated by a Tobacco Etch Virus (TEV) protease cleavage sequence⁸. To forgo the need for the generation of clonal cell lines, we developed a rapid system that relies on the expression of the TAP-tagged bait protein from an episomally maintained plasmid based on pMEP4 (Invitrogen). Expression of tagged murine eIF4E from this plasmid was controlled using the cadmium chloride inducible metallothionein promoter.Lysis of the expressing cells and subsequent affinity purification via binding to rabbit IgG agarose, TEV protease cleavage, binding to streptavidin linked agarose and subsequent biotin elution identified numerous proteins apparently specific to the eIF4E pull-down (when compared to control cell lines expressing the TAP tag alone). The identities of the proteins were obtained by excision of the bands from 1D SDS-PAGE and subsequent tandem mass spectrometry. The identified components included the known eIF4E binding proteins eIF4G and 4EBP-1. In addition, other components of the eIF4F complex, of which eIF4E is a component were identified, namely eIF4A and Poly-A binding protein. The ability to identify not only known direct binding partners as well as secondary interacting proteins, further highlights the utility of this approach in the characterization of proteins of unknown function.     

StreptoTag: a novel method for the isolation of RNA-binding proteins

We describe a fast and simple one-step affinity-purification method for the isolation of specific RNA-binding proteins. An in vitro-transcribed hybrid RNA consisting of an aptamer sequence with high binding specificity to the antibiotic streptomycin and a putative protein-binding RNA sequence is incubated with crude extract. After complex formation, the sample is applied to an affinity column containing streptomycin immobilized to Sepharose. The binding of the in vitro-assembled RNA-protein complex to streptomycin-Sepharose is mediated by the aptamer RNA and the specifically bound proteins are recovered from the affinity matrix by elution with the antibiotic. Employing two well-characterized RNA-protein interactions, we tested the performance of this new method. The spliceosomal U1A protein and the bacteriophage MS2 coat protein could be isolated via their appropriate RNA motif containing hybrid RNA from crude yeast extracts in high yield and purity after only one round of affinity purification. As the purification principle is independent of the extract source, this new affinity chromatography strategy that makes use of an in vitro-selected antibiotic-binding RNA as a tag, "StreptoTag," should be applicable to extracts from other organisms as well. Therefore, we propose StreptoTag to be a versatile tool for the isolation of unknown RNA-binding proteins.