Construction of a dual-tag system for gene expression, protein affinity purification and fusion protein processing

An E. coli vector system was constructed which allows the expression of fusion genes via a l-rhamnose-inducible promotor. The corresponding fusion proteins consist of the maltose-binding protein and a His-tag sequence for affinity purification, the Saccharomyces cerevisiae Smt3 protein for protein processing by proteolytic cleavage and the protein of interest. The Smt3 gene was codon-optimized for expression in E. coli. In a second rhamnose-inducible vector, the S. cerevisiae Ulp1 protease gene for processing Smt3 fusion proteins was fused in the same way to maltose-binding protein and His-tag sequence but without the Smt3 gene. The enhanced green fluorescent protein (eGFP) was used as reporter and protein of interest. Both fusion proteins (MalE-6xHis-Smt3-eGFP and MalE-6xHis-Ulp1) were efficiently produced in E. coli and separately purified by amylose resin. After proteolytic cleavage the products were applied to a Ni-NTA column to remove protease and tags. Pure eGFP protein was obtained in the flow-through of the column in a yield of around 35% of the crude cell extract.     

The HMG-I(Y) A.T-hook peptide motif confers DNA-binding specificity to a structured chimeric protein.

Chromosomal translocations involving genes coding for members of the HMG-I(Y) family of "high mobility group" non-histone chromatin proteins (HMG-I, HMG-Y, and HMG-IC) have been observed in numerous types of human tumors. Many of these gene rearrangements result in the creation of chimeric proteins in which the DNA-binding domains of the HMG-I(Y) proteins, the so-called A.T-hook motifs, have been fused to heterologous peptide sequences. Although little is known about either the structure or biophysical properties of these naturally occurring fusion proteins, the suggestion has been made that such chimeras have probably assumed an altered in vivo DNA-binding specificity due to the presence of the A.T-hook motifs. To investigate this possibility, we performed in vitro "domain-swap" experiments using a model protein fusion system in which a single A. T-hook peptide was exchanged for a corresponding length peptide in the well characterized "B-box" DNA-binding domain of the HMG-1 non-histone chromatin protein. Here we report that chimeric A. T-hook/B-box hybrids exhibit in vitro DNA-binding characteristics resembling those of wild type HMG-I(Y) protein, rather than the HMG-1 protein. These results strongly suggest that the chimeric fusion proteins produced in human tumors as a result of HMG-I(Y) gene chromosomal translocations also retain A.T-hook-imparted DNA-binding properties in vivo.     

Characterization of MB-1. A dimeric helical protein with a compact core.

MB-1 is a de-novo protein designed to incorporate a large number of the nutritionally important amino acids methionine, lysine, leucine and threonine into a stable four-helix bundle protein. MB-1 has been expressed and purified from Escherichia coli, indicating it was resistant to intracellular proteases [Beauregard, M., Dupont, C., Teather, R.M. & Hefford, M.A. (1995) Bio/Technology 13, 974]. Here we report an analysis of the secondary, tertiary and quaternary structures in MB-1 using circular dichroism, fluorospectroscopy and size-exclusion chromatography. Our data indicate that the MB-1 structure is close to the target structure, an alpha-helical bundle, in many respects and is highly helical in solution. The single tyrosine incorporated into the designed protein as a spectrocopic probe of tertiary structure, is buried in a compact, folded core and becomes accessible on protein denaturation, as per design. Furthermore, MB-1 was found to be native-like in many respects: (a) protein denaturation induced by urea is cooperative and fully reversible; (b) its oligomeric state at moderate concentration is well defined; and (c) MB-1 has very low affinity for 8-anilino-1-naphthalenesulfonic acid (ANSA), leading to enhancement of ANSA fluorescence that resembles that of other native proteins. On the other hand, our analysis revealed two aspects that command further attention. The folding stability of MB-1 as assessed by urea and thermal denaturation is somewhat less than that found for natural globular proteins of similar size. Size-exclusion chromatography experiments and analysis of MB-1 denaturation indicate that MB-1 is dimeric, not monomeric as designed. In light of these results, the utility and the current limitations of our design approach are discussed.     

Structural and functional characterisation of the DNA binding domain of the Aspergillus nidulans gene regulatory protein AreA

The 876-aa protein AreA regulates the expression of numerous genes involved in nitrogen metabolism in Aspergillus nidulans, and interacts with GATA sequences upstream of the relevant genes. We have carried out limited proteolysis of the C-terminal domain of the AreA protein in order to identify possible structural domains within the protein. A stable 156-amino-acid fragment was identified that contained the zinc finger region, and this sequence was cloned and expressed in E. coli. Fluorescence spectroscopy of the purified protein showed that the proteolytic domain was folded and could be denatured by high concentrations of urea (approximately 4 M), exhibiting a sharp transition. Fluorescence spectroscopy was also used to monitor binding to a DNA duplex containing the AreA recognition site, demonstrating tight binding of the domain to its DNA recognition sequence. The DNA binding affinity of the domain is comparable with that of the native AreA protein and much higher than that of the minimal zinc finger region of AreA.     

Design of affinity tags for one-step protein purification from immobilized zinc columns

Affinity tags are often used to accomplish recombinant protein purification using immobilized metal affinity chromatography. Success of the tag depends on the chelated metal used and the elution profile of the host cell proteins. Zn(II)-iminodiacetic acid (Zn(II)-IDA) may prove to be superior to either immobilized copper or nickel as a result of its relatively low binding affinity for cellular proteins. For example, almost all Escherichia coli proteins elute from Zn(II)-IDA columns between pH 7.5 and 7.0 with very little cellular protein emerging at pH values lower than 7.0. Thus, a large portion of the Zn(II)-IDA elution profile may be free of contaminant proteins, which can be exploited for one-step purification of a target protein from raw cell extract. In this paper we have identified several fusion tags that can direct the elution of the target protein to the low background region of the Zn(II)-IDA elution profile. These tags allow targeting of proteins to different regions of the elution profile, facilitating purification under mild conditions.     

Choice of expression vector alters the localization of a human cellular protein

The fusion of synthetic epitopes with proteins of interest is an important tool in the identification and characterization of recombinant proteins. Several mammalian expression vectors are commercially available containing unique identification tags or epitopes. These vectors offer a great advantage to researchers, as highly specific antibodies and purification resins against these specific epitopes are readily available. The tags facilitate immunologic assays and the purification of the recombinant proteins. The fusion of these epitopes with the recombinant proteins is not expected to alter the behavior of the protein of interest. In this report, we demonstrate that the mere expression of a cellular protein, hVIP/mov34, which we earlier identified as a cellular HIV-1 Vpr ligand, in two different vectors clearly altered its localization pattern in HeLa cells. Specifically, cloning of hVIP/mov34 in pcDNA3/HisA resulted in its nuclear localization, whereas the expression of this gene from a TOPO cloning expression vector, pcDNA3.1/V5/His, resulted in cytoplasmic expression. The native staining pattern of hVIP/mov34 using polyclonal antisera raised against hVIP/mov34 demonstrated cytoplasmic staining. During cloning, other leader sequences intended for targeting this protein into a cytoplasmic or a nuclear location were not fused to the actual ORF of this protein. Also, the amino acid sequence of the fusion region arising from cloning of hVIP/mov34 in both vectors does not match any reported NLS sequences. These results indicate that the choice of the expression vectors, as well as the position of synthetic epitopes, can significantly alter the behavior and the biology of recombinant proteins. This result suggests the need for a careful examination of these features when characterizing a newly identified protein.     

Biological activities of histidine-rich peptides; merging biotechnology and nanomedicine

Histidine-rich peptides are commonly used in recombinant protein production as purification tags, allowing the one-step affinity separation of the His-tagged proteins from the extracellular media or cell extracts. Genetic engineering makes feasible the post-purification His-tag removal by inserting, between the tag and the main protein body, a target site for trans-acting proteases or a self-proteolytic peptide with regulatable activities. However, for technical ease, His tags are often not removed and the fusion proteins eventually used in this form. In this commentary, we revise the powerful biological properties of histidine-rich peptides as endosomolytic agents and as architectonic tags in nanoparticle formation, for which they are exploited in drug delivery and other nanomedical applications. These activities, generally unknown to biotechnologists, can unwillingly modulate the functionality and biotechnological performance of recombinant proteins in which they remain trivially attached.     

Thermodynamics of denaturation of hisactophilin, a beta-trefoil protein

Hisactophilin is a histidine-rich pH-dependent actin-binding protein from Dictyostelium discoideum. The structure of hisactophilin is typical of the beta-trefoil fold, a common structure adopted by diverse proteins with unrelated primary sequences and functions. The thermodynamics of denaturation of hisactophilin have been measured using fluorescence- and CD-monitored equilibrium urea denaturation curves, pH-denaturation, and thermal denaturation curves, as well as differential scanning calorimetry. Urea denaturation is reversible from pH 5.7 to pH 9.7; however, thermal denaturation is highly reversible only below pH approximately 6.2. Reversible denaturation by urea and heat is well fit using a two-state transition between the native and the denatured states. Urea denaturation curves are best fit using a quadratic dependence of the Gibbs free energy of unfolding upon urea concentration. Hisactophilin has moderate, roughly constant stability from pH 7.7 to pH 9.7; however, below pH 7.7, stability decreases markedly, most likely due to protonation of histidine residues. Enthalpic effects of histidine ionization upon unfolding also appear to be involved in the occurrence of cold unfolding of hisactophilin under relatively mild solution conditions. The stability data for hisactophilin are compared with data on hisactophilin function, and with data for two other beta-trefoil proteins, human interleukin-1beta, and basic fibroblast growth factor.     

SUA41蛋白表达和纯化及其多克隆抗体制备

旨在制备特异性SUA41多克隆抗体,为深入研究其在植物生长发育中的功能提供有力的分子生物学和生物化学的工具。PCR扩增拟南芥SUA41基因中编码280个氨基酸(401-680位氨基酸)的特异片段,经过GATEWAY的DNA重组技术构建了原核表达载体pDEST17-SUA41,用热休克法转化到E.coliBL21(DE3)star感受态细胞,以异丙基β-D-硫代半乳糖苷(IPTG)诱导表达出6×His-SUA41融合蛋白,用8 mol/L尿素缓冲液溶解包涵体并且经过水逐级去除尿素获得提纯的融合蛋白,并利用Western blotting鉴定确认。融合蛋白经Ni金属螯合柱亲和层析得以纯化,用SDS-PAGE进一步纯化。纯化的融合蛋白经过SDS-PAGE后切胶回收,免疫小白兔,制备多抗血清,然后用Western blotting进行检测,鉴定血清特异性和效价。结果显示,融合蛋白6×His-SUA41免疫兔,产生特异性的SUA41兔抗血清,可以检测到细菌和拟南芥组织中SUA41蛋白。用水提纯变性剂尿素溶解的包涵体蛋白具有可行性。制备的特异性SUA41兔抗血清效价高,能够有效地识别大肠杆菌表达的和拟南芥的SUA41蛋白。在有合适的对照情况下,该兔抗血清可以用于分析植物中SUA41蛋白的功能。     

The DNA-binding domain of human c-Abl tyrosine kinase promotes the interaction of a HMG chromosomal protein with DNA.

The biological activity of the c-Abl protein is linked to its tyrosine kinase and DNA-binding activities. The protein, which plays a major role in the cell cycle response to DNA damage, interacts preferentially with sequences containing an AAC motif and exhibits a higher affinity for bent or bendable DNA, as is the case with high mobility group (HMG) proteins. We have compared the DNA-binding characteristics of the DNA-binding domain of human c-Abl and the HMG-D protein from Drosophila melanogaster. c-Abl binds tightly to circular DNA molecules and potentiates the interaction of DNA with HMG-D. In addition, we used a series of DNA molecules containing modified bases to determine how the exocyclic groups of DNA influence the binding of the two proteins. Interfering with the 2-amino group of purines affects the binding of the two proteins similarly. Adding a 2-amino group to adenines restricts the access of the proteins to the minor groove, whereas deleting this bulky substituent from guanines facilitates the protein-DNA interaction. In contrast, c-Abl and HMG-D respond very differently to deletion or addition of the 5-methyl group of pyrimidine bases in the major groove. Adding a methyl group to cytosines favours the binding of c-Abl to DNA but inhibits the binding of HMG-D. Conversely, deleting the methyl group from thymines promotes the interaction of the DNA with HMG-D but diminishes its interaction with c-Abl. The enhanced binding of c-Abl to DNA containing 5-methylcytosine residues may result from an increased propensity of the double helix to denature locally coupled with a protein-induced reduction in the base stacking interaction. The results show that c-Abl has unique DNA-binding properties, quite different from those of HMG-D, and suggest an additional role for the protein kinase.     

The utility of affinity-tags for detection of a streptococcal protein from a variety of streptococcal species

There is no systematic examination of affinity tag utility in Gram-positive bacteria, which limits the investigation of protein function in this important group of bacteria as specific antibodies for many of native proteins are generally not available. In this study, we utilized an E. coli-streptococcal shuttle vector pVT1666 and constructed two sets of expression plasmids pVPT-CTag and pVPT-NTag, with each set containing five affinity tags (GST, GFP, HSV, T7 and Nano) that can be fused to either the C- or N-terminus of a target protein. A putative glycosyltransferase (Gtf2) essential for Fap1 glycosylation was used to demonstrate the utility of the cassettes in detection of Gtf2 fusion proteins, and the biological relevance of the proteins in our working strain Streptococcus parasanguinis. GFP and T7 tags were readily expressed in S. parasanguinis as either an N- or C-terminal fusion to Gtf2. Only the C- terminal fusion of GST and HSV were able to be identified in S. parasanguinis. The Nano tag was not detected in either E. coli or S. parasanguinis. Genetic complementation experiments indicated that all the tagged Gtf2 fusion proteins could restore the Gtf2 function in the null mutant except for the Nano-tagged Gtf2 at its N-terminal fusion. Using a T7-tagged Gtf2 fusion construct, we demonstrated that the fusion cassette is also useful in detection of the fusion tag expression in other streptococci including S. mutans, S. pneumoniae and S. sanguinis. Therefore, the expression cassettes we constructed will be a useful tool not only to investigate protein-protein interactions in Fap1 biogenesis in S. parasanguinis, but also to study protein functions in other gram-positive bacteria in which pVT1666 replicates.     

Carnosine promotes the heat denaturation of glycated protein

Glycation alters protein structure and decreases biological activity. Glycated proteins, which accumulate in affected tissue, are reliable markers of disease. Carnosine, which prevents glycation, may also play a role in the disposal of glycated protein. Carnosinylation tags glycated proteins for cell removal. Since thermostability determines cell turnover of proteins, the present study examined carnosine's effect on thermal denaturation of glycated protein using cytosolic aspartate aminotransferase (cAAT). Glycated cAAT (500 microM glyceraldehyde for 72h at 37 degrees C) increased the T(0.5) (temperature at which 50% denaturation occurs) and the Gibbs free energy barrier (DeltaG) for denaturation. The enthalpy of denaturation (DeltaH) for glycated cAAT was also higher than that for unmodified cAAT, suggesting that glycation changes the water accessible surface. Carnosine enhanced the thermal unfolding of glycated cAAT as evidenced by a decreased T(0.5) and a lowered Gibbs free energy barrier. Additionally, carnosine decreased the enthalpy of denaturation, suggesting that carnosine may promote hydration during heat denaturation of glycated protein.     

Stability and folding properties of a model beta-sheet protein, Escherichia coli CspA.

Although beta-sheets represent a sizable fraction of the secondary structure found in proteins, the forces guiding the formation of beta-sheets are still not well understood. Here we examine the folding of a small, all beta-sheet protein, the E. coli major cold shock protein CspA, using both equilibrium and kinetic methods. The equilibrium denaturation of CspA is reversible and displays a single transition between folded and unfolded states. The kinetic traces of the unfolding and refolding of CspA studied by stopped-flow fluorescence spectroscopy are monoexponential and thus also consistent with a two-state model. In the absence of denaturant, CspA refolds very fast with a time constant of 5 ms. The unfolding of CspA is also rapid, and at urea concentrations above the denaturation midpoint, the rate of unfolding is largely independent of urea concentration. This suggests that the transition state ensemble more closely resembles the native state in terms of solvent accessibility than the denatured state. Based on the model of a compact transition state and on an unusual structural feature of CspA, a solvent-exposed cluster of aromatic side chains, we propose a novel folding mechanism for CspA. We have also investigated the possible complications that may arise from attaching polyhistidine affinity tags to the carboxy and amino termini of CspA.     

Enhanced soluble protein expression using two new fusion tags

Production of soluble recombinant proteins is vital for structure-function analysis and therapeutic applications. Unfortunately, when expressed in a heterologous host, such as Escherichia coli, most proteins are expressed as insoluble aggregates. Two new fusion partners have been identified to address these solubility problems. One of the tags was derived from a bacteriophage T7 protein kinase and the other one from a small E. coli chaperone, Skp. We have expressed a panel of insoluble human proteins including Hif1alpha, IL13, and folliculin as fusion proteins using these tags. Most of these fusion proteins were able to be expressed in a soluble form and could be purified by virtue of a Strep-tag II installed at the amino-terminal end of the fusion partners. In addition, we show that some of these proteins remained soluble after removal of the fusion tags by a site-specific protease. The results with these tags compare favorably to results with the most commonly used solubility tags described in the literature. Therefore, these two new fusion tags have the potential to express soluble proteins when fused with many recalcitrant proteins.     

Conformational stability of HPr: the histidine-containing phosphocarrier protein from Bacillus subtilis.

The conformational stability of the histidine-containing phosphocarrier protein (HPr) from Bacillus subtilis has been determined using a combination of thermal unfolding and solvent denaturation experiments. The urea-induced denaturation of HPr was monitored spectroscopically at fixed temperatures and thermal unfolding was performed in the presence of fixed concentrations of urea. These data were analyzed in several different ways to afford a measure of the cardinal parameters (delta Hg, Tg, delta Sg, and delta Cp) that describe the thermodynamics of folding for HPr. The method of Pace and Laurents (Pace CN, Laurents DV, 1989, Biochemistry 28:2520-2525) was used to estimate delta Cp as was a global analysis of the thermal- and urea-induced unfolding data. Each method used to analyze the data gives a similar value for delta Cp (1,170 +/- 50 cal mol-1K-1). Despite the high melting temperature for HPr (Tg = 73.5 degrees C), the maximum stability of the protein, which occurs at 26 degrees C, is quite modest (delta Gs = 4.2 kcal mol-1). In the presence of moderate concentrations of urea, HPr exhibits cold denaturation, and thus a complete stability curve for HPr, including a measure of delta Cp, can be achieved using the method of Chen and Schellman (Chen B, Schellman JA, 1989, Biochemistry 28:685-691). A comparison of the different methods for the analysis of solvent denaturation curves is provided and the effects of urea on the thermal stability of this small globular protein are discussed. The methods presented will be of general utility in the characterization of the stability curve for many small proteins.     

Variability in the immunodetection of His-tagged recombinant proteins

Labeling of recombinant proteins with polypeptide fusion partners, or affinity tagging, is a useful method to facilitate subsequent protein purification and detection. Poly-histidine tags (His-tags) are among the most commonly used affinity tags. We report strikingly variable immunodetection of two His-tagged recombinant human erythropoietins (Epo): wild type Epo (Epo(wt)) and Epo containing an R103A mutation (Epo(R103A)). Both were engineered to contain a C-terminal six residue His-tag. The cDNA constructs were stably transfected into Chinese hamster ovary (CHO) cells and COS-7 cells. Clones from the CHO cell transfections were selected for further characterization and larger-scale protein expression. Three chromatographic steps were utilized to achieve pharmacologically pure Epo. Conditioned media from the Epo-expressing cell lines and protein-containing samples from each step of purification were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and dot blot, using both monoclonal anti-human Epo antibody (AE7A5) and anti-His antibodies. While the successful incorporation of the His-tag into our constructs was confirmed by Epo binding to Ni(2+)- nitrilotriacetic acid resin and by microcapillary reverse-phase high-performance liquid chromatography nano-electrospray tandem mass spectrometery amino acid sequencing, the levels of immunodetection of His-tagged protein varied markedly depending on the particular anti-His-tag antibody used. Such variability in His-tag immunorecognition can lead to critical adverse effects on several analytical methods.     

The starch-binding domain as a tool for recombinant protein purification

Recombinant protein purification with affinity tags is a widely employed technique. One of the most common tags used for protein purification is the histidine tag (His_tag). In this work, we use a tandem starch-binding domain (SBD_tag) as a tag for protein purification. Four proteins from different sources were fused to the SBD_tag, and the resulting fusion proteins were purified by affinity chromatography using the His_tag or the SBD_tag. The results showed that the SBD_tag is superior to the His_tag for protein purification. The efficient adsorption of the fusion proteins to raw corn starch was also demonstrated, and two fusions were selected to test purification directly using raw starch from rice, corn, potato, and barley. The two fusion proteins were successfully recovered from crude bacterial extract using raw starch, thus demonstrating that the SBD_tag can be used as an efficient affinity tag for recombinant protein purification on an inexpensive matrix.