Protein Purification Strategies Research Articles

A Surface Biotinylation Strategy for Reproducible Plasma Membrane Protein Purification and Tracking of Genetic and Drug-Induced Alterations.

Plasma membrane (PM) proteins contribute to the identity of a cell, mediate contact and communication, and account for more than two-thirds of known drug targets.1-8 In the past years, several protocols for the proteomic profiling of PM proteins have been described. Nevertheless, comparative analyses have mainly focused on different variations of one approach.9-11 We compared sulfo-NHS-SS-biotinylation, aminooxy-biotinylation, and surface coating with silica beads to isolate PM proteins for subsequent analysis by one-dimensional gel-free liquid chromatography mass spectrometry. Absolute and relative numbers of PM proteins and reproducibility parameters on a qualitative and quantitative level were assessed. Sulfo-NHS-SS-biotinylation outperformed aminooxy-biotinylation and surface coating using silica beads for most of the monitored criteria. We further simplified this procedure by a competitive biotin elution strategy achieving an average PM annotated protein fraction of 54% (347 proteins). Computational analysis using additional databases and prediction tools revealed that in total over 90% of the purified proteins were associated with the PM, mostly as interactors. The modified sulfo-NHS-SS-biotinylation protocol was validated by tracking changes in the plasma membrane proteome composition induced by genetic alteration and drug treatment. Glycosylphosphatidylinositol (GPI)-anchored proteins were depleted in PM purifications from cells deficient in the GPI transamidase component PIGS, and treatment of cells with tunicamycin significantly reduced the abundance of N-glycoproteins in surface purifications.

Overview of the purification of recombinant proteins.

When the first version of this unit was written in 1995, protein purification of recombinant proteins was based on a variety of standard chromatographic methods and approaches, many of which were described and mentioned throughout Current Protocols in Protein Science. In the interim, there has been a shift toward an almost universal usage of the affinity or fusion tag. This may not be the case for biotechnology manufacture where affinity tags can complicate producing proteins under regulatory conditions. Regardless of the protein expression system, questions are asked as to which and how many affinity tags to use, where to attach them in the protein, and whether to engineer a self-cleavage system or simply leave them on. We will briefly address some of these issues. Also, although this overview focuses on E.coli, protein expression and purification, other commonly used expression systems are mentioned and, apart from cell-breakage methods, protein purification methods and strategies are essentially the same.

RNA complex purification using high-affinity fluorescent RNA aptamer tags.

RNA plays important roles in cellular processes, but RNA-protein complexes are notoriously hard to isolate and study. We compare and contrast existing RNA- and protein-purification strategies with the potential of new RNA-tagging systems such as RNA Spinach and RNA Mango. Each RNA aptamer binds a small fluorophore, resulting in a highly fluorescent complex that is thousands of times brighter than the unbound fluorophore. Provided that the aptamer binding affinity is high enough, derivatized dyes can be used in conjunction with these aptamers to purify RNA complexes while simultaneously using their intrinsic fluorescence to track the complex of interest. The known strengths and weakness of these RNA tagging systems are discussed.

Modular microfluidics for point-of-care protein purifications.

Biochemical separations are the heart of diagnostic assays and purification methods for biologics. On-chip miniaturization and modularization of separation procedures will enable the development of customized, portable devices for personalized health-care diagnostics and point-of-use production of treatments. In this report, we describe the design and fabrication of miniature ion exchange, size exclusion and affinity chromatography modules for on-chip clean-up of recombinantly-produced proteins. Our results demonstrate that these common separations techniques can be implemented in microfluidic modules with performance comparable to conventional approaches. We introduce embedded 3-D microfluidic interconnects for integrating micro-scale separation modules that can be arranged and reconfigured to suit a variety of fluidic operations or biochemical processes. We demonstrate the utility of the modular approach with a platform for the enrichment of enhanced green fluorescent protein (eGFP) from Escherichia coli lysate through integrated affinity and size-exclusion chromatography modules.

Ni(II) chelated IDA functionalized poly(HEMA-GMA) cryogels for urease adsorption.

Cryogelic support materials have been intensively used for the purification and separation of biomolecules. Cryogels are cheap materials, they can be easily used for different purposes and their chemical and physical stabilities are very high. Cryogels can also be easily functionalized with different type of ligands and are be applicable to different affinity systems. Within these affinity systems, immobilized metal affinity chromatography (IMAC) offers efficient and simple protein purification strategies. IMAC technology has been deeply applied to bioseparations studies. In the present chapter, the preparation of a cryogel support material and the functionalization with the chelating agent iminodiacetic acid (IDA) and the subsequent Ni(II) chelation are described. Characterization techniques and the cryogel preparation method are summarized and urease adsorption studies on the metal chelate cryogel are briefly explained.

Semi-Automated Hydrophobic Interaction Chromatography Column Scouting Used in the Two-Step Purification of Recombinant Green Fluorescent Protein

BackgroundHydrophobic interaction chromatography (HIC) most commonly requires experimental determination (i.e., scouting) in order to select an optimal chromatographic medium for purifying a given target protein. Neither a two-step purification of untagged green fluorescent protein (GFP) from crude bacterial lysate using sequential HIC and size exclusion chromatography (SEC), nor HIC column scouting elution profiles of GFP, have been previously reported.Methods and ResultsBacterial lysate expressing recombinant GFP was sequentially adsorbed to commercially available HIC columns containing butyl, octyl, and phenyl-based HIC ligands coupled to matrices of varying bead size. The lysate was fractionated using a linear ammonium phosphate salt gradient at constant pH. Collected HIC eluate fractions containing retained GFP were then pooled and further purified using high-resolution preparative SEC. Significant differences in presumptive GFP elution profiles were observed using in-line absorption spectrophotometry (A395) and post-run fluorimetry. SDS-PAGE and western blot demonstrated that fluorometric detection was the more accurate indicator of GFP elution in both HIC and SEC purification steps. Comparison of composite HIC column scouting data indicated that a phenyl ligand coupled to a 34 µm matrix produced the highest degree of target protein capture and separation.ConclusionsConducting two-step protein purification using the preferred HIC medium followed by SEC resulted in a final, concentrated product with >98% protein purity. In-line absorbance spectrophotometry was not as precise of an indicator of GFP elution as post-run fluorimetry. These findings demonstrate the importance of utilizing a combination of detection methods when evaluating purification strategies. GFP is a well-characterized model protein, used heavily in educational settings and by researchers with limited protein purification experience, and the data and strategies presented here may aid in development other of HIC-compatible protein purification schemes.

Identification of E6AP/UBE3A as a ubiquitin‐protein ligase that catalyzes encephalomyocarditis virus 3C protease ubiquitylation (952.1)

The 3C proteases of encephalomyocarditis virus (EMCV) and hepatitis A virus (HAV) are rapidly degraded by the ubiquitin‐26S protease system, which limits the 3C protease concentration that develops in infected cells. We have discovered that at least one UbcH7‐dependent ubiquitylation pathway is important for EMCV replication success determination. To identify the UbcH7‐dependent E3 ubiquitin‐protein ligase(s) involved in tagging the 3C proteases for destruction, we developed a protein purification scheme that begins with mouse cell lysate and ends with a ubiquitin‐UbcH7 affinity column. Analysis by mass spectroscopy of the proteins eluted from this column revealed the presence of four E3s, one of which is the HECT E3 E6AP/UBE3. The ability of this E3 to recognize the EMCV 3C protease as a substrate was confirmed using reconstituted mixtures containing purified E6AP. The major product of these reactions was monoubiquitylated 3C protease rather than polyubiquitylated conjugates. Whether this accurately reflects E6AP action in vivo remains to be determined, but it is possible that E6AP must function with other E3s to catalyze 3C protease polyubiquitylation in infected cells. Either UbcH7 or UbcH5 support E6AP‐catalyzed EMCV 3C protease ubiquitylation, with a slight kinetic preference for UbcH7. While the HAV 3C protease is also ubiquitylated by a UbcH7‐dependent E3, our results show that this E3 is not E6AP.Grant Funding Source: Supported by NIH Award 1R15AI099134‐01.

Aqueous two-phase extraction for partial purification of Schizophyllum commune phytase produced under solid-state fermentation

This study describes a simple strategy for partial protein purification using an aqueous two- phase system (ATPS) of polyethyleneglycol (PEG)/sodium citrate. The protein studied was phytase produced by Schizophyllum commune under solid-state fermentation (SSF). A 24 experimental design (20 runs and 4 central points) was carried out with four factors (PEG molar mass, citrate concentration, PEG concentration, and pH) to evaluate the enzyme extraction. The responses’ partition coefficient (K), yield (Y), and the purification factor (PF) were analysed. The best system obtained was with 14% (w/w) sodium citrate, 22% (w/w) PEG with a molar mass of 1500 (g/mol), and pH of 7. The maximum partition coefficient (K) was 2.63 and also the citrate concentration had a positive effect. Under these conditions, in the top phase the highest phytase yield achieved was 367%, and the purification factor (PEG) was 5.43. Liquid–liquid extraction can therefore be used as a first step in the purification processes of phytase from S. commune.

Structural and Dynamic Regulation of TFIID-Mediated Transcription Initiation Complex Assembly by the Tumor Suppressor P53 Protein

p53 plays a central role in tumor suppression. To quickly respond to diverse stress stimuli, p53 binds specific elements in various target promoters to induce vast gene networks for maintaining cellular integrity. p53 stimulates transcription in part by aiding promoter recruitment of the transcription machinery. TFIID, a key component within the transcription machinery, is responsible for binding specific core promoter DNA sequences and recruiting other basal factors including RNA Polymerase II to initiate transcription. However, the exact mechanism underlying how p53 facilitates TFIID-mediated transcription is unclear.Each p53 target gene has a unique arrangement of p53-responsive and core promoter elements. How these various arrangements on different gene promoters regulate the structural architecture of TFIID and the positioning of p53/specific elements remains unknown. Moreover, structural information of p53 bound to its various target promoters and other factors remains elusive. Therefore, we aim to decipher the molecular mechanism underlying p53's ability to stimulate transcription by revealing the biochemical, structural and dynamic basis of TFIID bound to p53 and promoter DNA.To this end, we established unique protein purification strategies to generate high-purity native TFIID complex bound to p53/TFIIA/native promoter DNA. We next determined the 3D structures of TFIID/p53/TFIIA co-complexes on two distinct p53 target gene promoters via single particle cryo-electron microscopy. Strikingly, we discovered a common mode of TFIID binding to different types of promoters. Our biochemical studies showed that p53 significantly promotes TFIID's interaction with DNA. To further mechanistically dissect TFIID's enhanced promoter recognition/binding directed by p53, we examined the dynamic interaction between p53, TFIID and promoter DNA via single molecule TIRF microscopy. Taken together, our structural and functional studies elucidate how p53 facilitates TFIID-mediated transcription initiation complex assembly on different p53 target gene promoters.

Improved Protein Overexpression and Purification Strategies for Structural Studies of Cyanobacterial Metal-Responsive Transcription Factor, SmtB from Marine Synechococcus sp. PCC 7002

There are structural and functional differences in SmtB homologs, metal-responsive transcription factors responsible for sensing of excess heavy metal ions in marine and freshwater cyanobacterial strains. The structure of SmtB from freshwater Synechococcus sp. strain PCC 7942 is elucidated with nuclear magnetic resonance (NMR) and crystallography techniques. But knowledge about the functioning of SmtB homologs from marine species is limited till date. To enable NMR spectroscopic studies for investigating structural and functional aspects, modified protocols with higher yields of isotopically labeled SmtB, from marine species like Synechococcus sp. PCC 7002 are essential. In this study, smtB gene was cloned from genome of Synechococcus sp. PCC 7002 and overexpression protocol for recombinant SmtB was standardized in Escherichia coli containing T7 RNA polymerase/promoter system. Further, the protocol for large-scale production, isotope labeling with (15)N, and purification of recombinant SmtB in E. coli BL21(DE3)/pLysS cells was developed. Purified recombinant protein was successfully used for NMR spectroscopy experiments. These results indicate that the overexpression technique now developed is applicable to the structural and functional studies for the proteins being homologous to cyanobacterial SmtB from Synechococcus sp. PCC 7002.

Budding Yeast Protein Extraction and Purification for the Study of Function, Interactions, and Post-translational Modifications

Homogenization by bead beating is a fast and efficient way to release DNA, RNA, proteins, and metabolites from budding yeast cells, which are notoriously hard to disrupt. Here we describe the use of a bead mill homogenizer for the extraction of proteins into buffers optimized to maintain the functions, interactions and post-translational modifications of proteins. Logarithmically growing cells expressing the protein of interest are grown in a liquid growth media of choice. The growth media may be supplemented with reagents to induce protein expression from inducible promoters (e.g. galactose), synchronize cell cycle stage (e.g. nocodazole), or inhibit proteasome function (e.g. MG132). Cells are then pelleted and resuspended in a suitable buffer containing protease and/or phosphatase inhibitors and are either processed immediately or frozen in liquid nitrogen for later use. Homogenization is accomplished by six cycles of 20 sec bead-beating (5.5 m/sec), each followed by one minute incubation on ice. The resulting homogenate is cleared by centrifugation and small particulates can be removed by filtration. The resulting cleared whole cell extract (WCE) is precipitated using 20% TCA for direct analysis of total proteins by SDS-PAGE followed by Western blotting. Extracts are also suitable for affinity purification of specific proteins, the detection of post-translational modifications, or the analysis of co-purifying proteins. As is the case for most protein purification protocols, some enzymes and proteins may require unique conditions or buffer compositions for their purification and others may be unstable or insoluble under the conditions stated. In the latter case, the protocol presented may provide a useful starting point to empirically determine the best bead-beating strategy for protein extraction and purification. We show the extraction and purification of an epitope-tagged SUMO E3 ligase, Siz1, a cell cycle regulated protein that becomes both sumoylated and phosphorylated, as well as a SUMO-targeted ubiquitin ligase subunit, Slx5.

A baculovirus-mediated strategy for full-length plant virus coat protein expression and purification.

BackgroundGarlic production is severely affected by virus infection, causing a decrease in productivity and quality. There are no virus-free cultivars and garlic-infecting viruses are difficult to purify, which make specific antibody production very laborious. Since high quality antisera against plant viruses are important tools for serological detection, we have developed a method to express and purify full-length plant virus coat proteins using baculovirus expression system and insects as bioreactors.ResultsIn this work, we have fused the full-length coat protein (cp) gene from the Garlic Mite-borne Filamentous Virus (GarMbFV) to the 3′-end of the Polyhedrin (polh) gene of the baculovirus Autographa californica multiple nucleopolyhedrovirus (AcMNPV). The recombinant baculovirus was amplified in insect cell culture and the virus was used to infect Spodoptera frugiperda larvae. Thus, the recombinant fused protein was easily purified from insect cadavers using sucrose gradient centrifugation and analyzed by Western Blotting. Interestingly, amorphous crystals were produced in the cytoplasm of cells infected with the recombinant virus containing the chimeric-protein gene but not in cells infected with the wild type and recombinant virus containing the hexa histidine tagged Polh. Moreover, the chimeric protein was used to immunize rats and generate antibodies against the target protein. The antiserum produced was able to detect plants infected with GarMbFV, which had been initially confirmed by RT-PCR.ConclusionsThe expression of a plant virus full-length coat protein fused to the baculovirus Polyhedrin in recombinant baculovirus-infected insects was shown to produce high amounts of the recombinant protein which was easily purified and efficiently used to generate specific antibodies. Therefore, this strategy can potentially be used for the development of plant virus diagnostic kits for those viruses that are difficult to purify, are present in low titers or are present in mix infection in their plant hosts.

Protein Production in Yarrowia lipolytica Via Fusion to the Secreted Lipase Lip2p

We established a strategy for protein production and purification via expression in Yarrowia lipolytica as Lip2p fusion protein. To evaluate the expression system a cysteine-rich miniprotein, an antibody fragment and an enzyme showing galactose oxidase activity were chosen. These proteins have varying disulfide bond content, size, and structural complexity. Endogenous lipase Lip2p was used as a fusion partner to direct the fused proteins to the extracellular medium. A linker sequence was introduced at the junction of Lip2p and the respective fused protein that contains a hexahistidine tag followed by a TEV protease cleavage site. This allows for a specific and simple purification via IMAC for capturing the secreted proteins from the supernatant followed by a second IMAC for removing all contaminants after proteolytic release of the protein of interest. Up to 174 mg/L fusion protein was obtained using shake flask cultivation. Functionality of each of the purified proteins was confirmed by individual assays. Expression of proteins of interest via Lip2p fusion not only provides a convenient expression and purification scheme but also enables for an online monitoring of accumulation of secreted fusion proteins in the medium by exploiting the intrinsic lipase activity of the fusion.

An Improved Strategy for Easy Process Monitoring and Advanced Purification of Recombinant Proteins

In this work, a multifunctional expression cassette, termed Multitags, combining different and complementary functionalities, was designed and used to monitor the expression and the purification of two model proteins (Pfu DNA polymerase and Myosin-VIIa- and Rab-Interracting protein : MyRIP). Multitags contains two affinity purification tags, a polyhistidine sequence (10× His) and the streptavidin-binding peptide (SBP) and as a marker tag the heme-binding domain of rat cytochrome b5 followed by the TEV cleavage site. Using the Multitags as fusion partner, more than 90% of both fusion proteins were produced in soluble form when expressed in Escherichia coli KRX. In addition, high purity (99%) of recombinant proteins was achieved after two consecutive affinity purification steps. The expression cassette also demonstrated an accurate monitoring capability comparable to that of a dual recognition-based method. The choice of the SBP tag was considered as an integral process that included a method for tag removal. Thus, an immobilized TEV protease fixed on streptavidin-agarose matrix was used for the cleavage of fusion proteins. After digestion, both unprocessed fusion proteins and Multitags were retained on the proteolytic column via their SBP sequence, allowing cleavage and recovery of target proteins on one step. This combined approach may accelerate the development of optimized production processes, while insuring high product quality and a low production cost.

Purification of mitochondrial proteins HSP60 and ATP synthase from ascidian eggs: implications for antibody specificity.

Use of antibodies is a cornerstone of biological studies and it is important to identify the recognized protein with certainty. Generally an antibody is considered specific if it labels a single band of the expected size in the tissue of interest, or has a strong affinity for the antigen produced in a heterologous system. The identity of the antibody target protein is rarely confirmed by purification and sequencing, however in many cases this may be necessary. In this study we sought to characterize the myoplasm, a mitochondria-rich domain present in eggs and segregated into tadpole muscle cells of ascidians (urochordates). The targeted proteins of two antibodies that label the myoplasm were purified using both classic immunoaffinity methods and a novel protein purification scheme based on sequential ion exchange chromatography followed by two-dimensional gel electrophoresis. Surprisingly, mass spectrometry sequencing revealed that in both cases the proteins recognized are unrelated to the original antigens. NN18, a monoclonal antibody which was raised against porcine spinal cord and recognizes the NF-M neurofilament subunit in vertebrates, in fact labels mitochondrial ATP synthase in the ascidian embryo. PMF-C13, an antibody we raised to and purified against PmMRF, which is the MyoD homolog of the ascidian Phallusia mammillata, in fact recognizes mitochondrial HSP60. High resolution immunolabeling on whole embryos and isolated cortices demonstrates localization to the inner mitochondrial membrane for both ATP synthase and HSP60. We discuss the general implications of our results for antibody specificity and the verification methods which can be used to determine unequivocally an antibody's target.

Cell Fractionation of Pseudomonas aeruginosa

[Abstract] Pseudomonas aeruginosa is a Gram negative bacterium. Separating the cell envelope compartments enables proteins to be localized to confirm where in the cell they function. Cell fractionation can also provide a first step in a protein purification strategy (Williams et al., 1998). This protocol has been designed to obtain the different fractions of P. aeruginosa, namely the inner membrane, outer membrane, cytoplasmic and periplasmic compartments. Specific detection of the arginine specific autotransporter (AaaA) (Luckett et al., 2012) in the outer membrane of P. aeruginosa has been performed using this protocol.

Efficient N‐Terminal Labeling of Proteins by Use of Sortase

Efficient N‐Terminal Labeling of Proteins by Use of Sortase

Characterization of Salmonella Type III Secretion Hyper-Activity Which Results in Biofilm-Like Cell Aggregation

We have previously reported the cloning of the Salmonella enterica serovar Typhimurium SPI-1 secretion system and the use of this clone to functionally complement a ΔSPI-1 strain for type III secretion activity. In the current study, we discovered that S. Typhimurium cultures containing cloned SPI-1 display an adherent biofilm and cell clumps in the media. This phenotype was associated with hyper-expression of SPI-1 type III secretion functions. The biofilm and cell clumps were associated with copious amounts of secreted SPI-1 protein substrates SipA, SipB, SipC, SopB, SopE, and SptP. We used a C-terminally FLAG-tagged SipA protein to further demonstrate SPI-1 substrate association with the cell aggregates using fluorescence microscopy and immunogold electron microscopy. Different S. Typhimurium backgrounds and both flagellated and nonflagellated strains displayed the biofilm phenotype. Mutations in genes essential for known bacterial biofilm pathways (bcsA, csgBA, bapA) did not affect the biofilms formed here indicating that this phenomenon is independent of established biofilm mechanisms. The SPI-1-mediated biofilm was able to massively recruit heterologous non-biofilm forming bacteria into the adherent cell community. The results indicate a bacterial aggregation phenotype mediated by elevated SPI-1 type III secretion activity with applications for engineered biofilm formation, protein purification strategies, and antigen display.

Purification of phage display-modified bacteriophage T4 by affinity chromatography

BackgroundAffinity chromatography is one of the most efficient protein purification strategies. This technique comprises a one-step procedure with a purification level in the order of several thousand-fold, adaptable for various proteins, differentiated in their size, shape, charge, and other properties. The aim of this work was to verify the possibility of applying affinity chromatography in bacteriophage purification, with the perspective of therapeutic purposes. T4 is a large, icosahedral phage that may serve as an efficient display platform for foreign peptides or proteins. Here we propose a new method of T4 phage purification by affinity chromatography after its modification with affinity tags (GST and Histag) by in vivo phage display. As any permanent introduction of extraneous DNA into a phage genome is strongly unfavourable for medical purposes, integration of foreign motifs with the phage genome was not applied. The phage was propagated in bacteria expressing fusions of the phage protein Hoc with affinity tags from bacterial plasmids, independently from the phage expression system.ResultsElution profiles of phages modified with the specific affinity motifs (compared to non-specific phages) document their binding to the affinity resins and effective elution with standard competitive agents. Non-specific binding was also observed, but was 102-105 times weaker than the specific one. GST-modified bacteriophages were also effectively released from glutathione Sepharose by proteolytic cleavage. The possibility of proteolytic release was designed at the stage of expression vector construction. Decrease in LPS content in phage preparations was dependent on the washing intensity; intensive washing resulted in preparations of 11-40 EU/ml.ConclusionsAffinity tags can be successfully incorporated into the T4 phage capsid by the in vivo phage display technique and they strongly elevate bacteriophage affinity to a specific resin. Affinity chromatography can be considered as a new phage purification method, appropriate for further investigations and development.

Growing and Harvesting TAP-Tagged Yeast Cells

INTRODUCTIONOne approach to identifying protein–protein interactions is the biochemical purification of a target protein from cells or tissues under nondenaturing conditions followed by the mass spectrometric identification of the components of the purified protein complex. This combination of highly specific protein purification strategies and mass spectrometry has proven to be a very successful approach for identifying protein–protein interactions. The tandem affinity purification (TAP) affinity tag and purification method allows efficient recovery of proteins present at low cellular concentrations under native conditions. Expressing the target protein at its natural levels avoids the assembly of overexpressed proteins into nonphysiological complexes. This protocol describes the preparation of TAP-tagged yeast cells.