Protein recovery from the all-agarose ProSieve gel system.

Electrophoresis in polyacrylamide gels is one of the most powerful tools used for the analysis of proteins. However, this technique is not widely used for protein purification for a variety of reasons such as the following: less than quantitative recoveries; involved, time-consuming methodologies; and impurities in the protein preparations from gel-polymerization by-products that can modify the proteins and interfere with subsequent experiments. As an alternative, we have developed a simple and quantitative recovery procedure for proteins separated by electrophoresis in the all-agarose ProSieve gel system. Using this procedure, greater than 90% of each protein examined was recovered, and these proteins were unaffected by the recovery procedure.     

On-column tris(2-carboxyethyl)phosphine reduction and IC5-maleimide labeling during purification of a RpoC fragment on a nickel-nitrilotriacetic acid Column

Fluorescence labeling of proteins has become increasingly important since fluorescent techniques like FRET and fluorescence polarization are now commonly used in protein binding studies, proteomics, and for high-throughput screening in drug discovery. In our efforts to study the binding of the beta(')-subunit from Escherichia coli RNA polymerase (RNAP) to sigma70, we synthesized a fluorescent-labeled beta(')-fragment (residues 100-309) in a very convenient way, that could be used as a general protocol for hexahistidine-tagged proteins. By performing all the following steps, purification, reduction, derivatization with IC5-maleimide, and free dye removal while the protein was bound to the column, we were able to reduce the procedure time significantly and at the same time achieve better labeling efficiency and quality. The beta(')-fragment with a N-terminal His(6)-tag was purified from inclusion bodies and could be refolded prior to or after binding to a Ni-NTA affinity column. Reduction prior to labeling was achieved with TCEP that does not interfere with Ni-NTA chemistry. The labeled beta(')-fragment was tested with sigma70 that was labeled with an europium-based fluorophore for binding in a electrophoretic mobility-shift assay. The sigma-to-core protein interaction in bacterial RNA polymerase offers a potentially specific target for drug discovery, since it is highly conserved among the eubacteria, but differs significantly from eukaryotes.     

Effects of arginine on heat-induced aggregation of concentrated protein solutions

Arginine is one of the commonly used additives to enhance refolding yield of proteins, to suppress aggregation of proteins, and to increase solubility of proteins, and yet the molecular interactions that contribute to the role of arginine are unclear. Here, we present experiments, using bovine serum albumin (BSA), lysozyme (LYZ), and β-lactoglobulin (BLG) as model proteins, to show that arginine can enhance heat-induced aggregation of concentrated protein solutions, contrary to the conventional belief that arginine is a universal suppressor of aggregation. Results show that the enhancement in aggregation is caused only for BSA and BLG, but not for LYZ, indicating that arginine's preferential interactions with certain residues over others could determine the effect of the additive on aggregation. We use this previously unrecognized behavior of arginine, in combination with density functional theory calculations, to identify the molecular-level interactions of arginine with various residues that determine arginine's role as an enhancer or suppressor of aggregation of proteins. The experimental and computational results suggest that the guanidinium group of arginine promotes aggregation through the hydrogen-bond-based bridging interactions with the acidic residues of a protein, whereas the binding of the guanidinium group to aromatic residues (aggregation-prone) contributes to the stability and solubilization of the proteins. The approach, we describe here, can be used to select suitable additives to stabilize a protein solution at high concentrations based on an analysis of the amino acid content of the protein.     

Analysis of methylthiohydantoins of amino acids by gas-liquid chromatography of their trimethylsilyl derivatives

A procedure is described for the analysis of methylthiohydantoins of amino acids from the Edman degradation of proteins and peptides by gas-liquid chromatography of their trimethylsilyl derivatives. The procedure is applicable to the methylthiohydantoins of all the amino acids commonly found in proteins with the exception of arginine, which did not yield a volatile derivative, and hydroxyproline and hydroxylysine, which were not investigated. Chromatographic separation is achieved in a single run with only one unresolved pair, which can be separated by a supplementary procedure requiring only 4.5 min.     

Interaction of arginine,lysine, and guanidine with surface residues of lysozyme: implication to protein stability

Additives are widely used to suppress aggregation of therapeutic proteins. However, the molecular mechanisms of effect of additives to stabilize proteins are still unclear. To understand this, we herein perform molecular dynamics simulations of lysozyme in the presence of three commonly used additives: arginine, lysine, and guanidine. These additives have different effects on stability of proteins and have different structures with some similarities; arginine and lysine have aliphatic side chain, while arginine has a guanidinium group. We analyze atomic contact frequencies to study the interactions of the additives with individual residues of lysozyme. Contact coefficient, quantified from contact frequencies, is helpful in analyzing the interactions with the guanidine groups as well as aliphatic side chains of arginine and lysine. Strong preference for contacts to the additives (over water) is seen for the acidic followed by polar and the aromatic residues. Further analysis suggests that the hydration layer around the protein surface is depleted more in the presence of arginine, followed by lysine and guanidine. Molecular dynamics simulations also reveal that the internal dynamics of protein, as indicated by the lifetimes of the hydrogen bonds within the protein, changes depending on the additives. Particularly, we note that the side-chain hydrogen-bonding patterns within the protein differ with the additives, with several side-chain hydrogen bonds missing in the presence of guanidine. These results collectively indicate that the aliphatic chain of arginine and lysine plays a critical role in the stabilization of the protein.     

High-throughput assessment of antigen conformational stability by ultraviolet absorption spectroscopy and its application to excipient screening

In high-throughput screening (HTS) assays, the use of ultraviolet absorption spectroscopy (UA) is commonly limited to concentration and turbidity measurements. Our aim was to evaluate microplate-based UA and its second-derivative [(2d)UA] for measuring the conformational stability of two recombinant antigenic proteins in the presence of 44 excipients. Protein conformational stability was assessed by (2d)UA upon titration with guanidine hydrochloride. (2d)UA was compared with tryptophan fluorescence spectroscopy (TF) and differential scanning fluorimetry (DSF), both commonly used techniques for measuring protein conformational stability. The HTS data were corrected for plate, row and column effects by applying a median polish procedure. Irrespective of the unfolding method applied, similar stabilizing excipients were identified by all analytical methods for a given antigen. The native forms of both antigens were destabilized by arginine, hydroxypropyl-β-cyclodextrin, and sodium docusate, and were protected by polyols. The median polish correction improved the quality of the prediction models and the screening resolution. The higher sensitivities of TF and DSF compared with (2d)UA allowed the identification of a larger number of stabilizing excipients. However, similar screening resolutions (z'-factor > 0.8) were observed for 2dUA, TF, and DSF in a HTS of excipients applied to one of the antigens. Therefore, (2d)UA deserves more attention in HTS studies focused on protein conformational stability.     

Colorimetric determination of arginine residues in proteins by p-nitrophenylglyoxal

A new method is presented for the colorimetric determination of arginine residues in proteins. Under mildly alkaline conditions, p-nitrophenylglyoxal reacted with arginine to produce a stable colored solution in the presence of 0.15 m sodium ascorbate. Complete color development was obtained after 30 min at pH 9.0 and 30°C. The color produced at 475 nm obeyed Beer's law in the range 0.03–0.33 mm arginine. This color reaction was used to determine the number of arginine residues in several proteins of known arginine content. Best results were obtained when the protein samples were digested with a mixture of trypsin and subtilisin prior to assaying. The arginine contents obtained by this method agreed well with either the published values or with the results of amino acid analysis.     

Utilization of Arg-elution method for FLAG-tag based chromatography

FLAG-tag is one of the commonly used purification technologies for recombinant proteins. An antibody, M2, specifically binds to the FLAG-tag whether it is attached to N- or C-terminus of proteins to be purified. The bound proteins are generally eluted by competition with a large excess of free FLAG peptide. This requires synthetic FLAG peptide and also removal of bound FLAG peptide for M2 column regeneration. We have shown before that arginine at mild pH can effectively dissociate protein–protein or protein–ligand interactions, e.g. in Protein-A, antigen and dye-affinity chromatography. We have tested here elution of FLAG-fused proteins by arginine for columns of M2-immobilized resin using several proteins in comparison with competitive elution by FLAG peptide or low pH glycine buffer. Active and folded proteins were successfully and effectively eluted using 0.5–1 M arginine at pH 3.5–4.4, as reported in this paper.     

Intrinsic Protein Fluorescence Interferes with Detection of Tear Glycoproteins in SDS-Polyacrylamide Gels Using Extrinsic Fluorescent Dyes

Intrinsic protein fluorescence may interfere with the visualization of proteins after SDS-polyacrylamide electrophoresis. In an attempt to analyze tear glycoproteins in gels, we ran tear samples and stained the proteins with a glycoprotein-specific fluorescent dye. The fluorescence detected was not limited to glycoproteins. There was strong intrinsic fluorescence of proteins normally found in tears after soaking the gels in 40% methanol plus 1-10% acetic acid and, to a lesser extent, in methanol or acetic acid alone. Nanograms of proteins gave visible native fluorescence and interfere with extrinsic fluorescent dye detection. Poly-L-lysine, which does not contain intrinsically fluorescent amino acids, did not fluoresce.     

Thermal precipitation fluorescence assay for protein stability screening

A simple and reliable method of protein stability assessment is desirable for high throughput expression screening of recombinant proteins. Here we described an assay termed thermal precipitation fluorescence (TPF) which can be used to compare thermal stabilities of recombinant protein samples directly from cell lysate supernatants. In this assay, target membrane proteins are expressed as recombinant fusions with a green fluorescence protein tag and solubilized with detergent, and the fluorescence signals are used to report the quantity of the fusion proteins in the soluble fraction of the cell lysate. After applying a heat shock, insoluble protein aggregates are removed by centrifugation. Subsequently, the amount of remaining protein in the supernatant is quantified by in-gel fluorescence analysis and compared to samples without a heat shock treatment. Over 60 recombinant membrane proteins from Escherichia coli were subject to this screening in the presence and absence of a few commonly used detergents, and the results were analyzed. Because no sophisticated protein purification is required, this TPF technique is suitable to high throughput expression screening of recombinant membrane proteins as well as soluble ones and can be used to prioritize target proteins based on their thermal stabilities for subsequent large scale expression and structural studies.     

Comparison of fixation protocols for adherent cultured cells applied to a GFP fusion protein of the epidermal growth factor receptor

BACKGROUND: The analysis of the subcellular distribution of proteins is essential for the understanding of processes such as signal transduction. In most cases, the parallel analysis of multiple components requires fixation and immunofluorescence labeling. Therefore, one has to ascertain that the fixation procedure preserves the in vivo protein distribution. Fusion proteins with the green fluorescent protein (GFP) are ideal tools for this purpose. However, one must consider specific aspects of the fluorophore formation or degradation, i.e. reactions that may interfere with the detection of GFP fusion proteins. METHODS: Fusion proteins of the epidermal growth factor receptor (EGFR) with GFP as well as free, soluble GFP stably or transiently expressed in adherent cultured cells served as test cases for comparing the distribution in vivo with that after fixation by conventional epifluorescence and laser scanning microscopy. Indirect immunofluorescence was employed to compare the distributions of the GFP signal and of the GFP polypeptide in the fusion protein. RESULTS: Paraformaldehyde (PFA) fixation with subsequent mounting in the antifading agent Mowiol, but not in Tris- or HEPES buffered saline, led to a partial redistribution of the EGFR from the plasma membrane to the perinuclear region. The redistribution was confirmed with the GFP and EGFR immunofluorescence. The in vivo distribution in Mowiol mounted cells was preserved if cells were treated with a combined PFA/methanol fixation procedure, which also retained the fluorescence of soluble GFP. The anti-GFP antiserum was negative for the N-terminal fusion protein. CONCLUSIONS: The combined PFA/methanol protocol is universally applicable for the fixation of transmembrane and soluble cytoplasmic proteins and preserves the fluorescence of GFP.     

A comprehensive analysis of filamentous phage display vectors for cytoplasmic proteins: an analysis with different fluorescent proteins

Filamentous phage display has been extensively used to select proteins with binding properties of specific interest. Although many different display platforms using filamentous phage have been described, no comprehensive comparison of their abilities to display similar proteins has been conducted. This is particularly important for the display of cytoplasmic proteins, which are often poorly displayed with standard filamentous phage vectors. In this article, we have analyzed the ability of filamentous phage to display a stable form of green fluorescent protein and modified variants in nine different display vectors, a number of which have been previously proposed as being suitable for cytoplasmic protein display. Correct folding and display were assessed by phagemid particle fluorescence, and with anti-GFP antibodies. The poor correlation between phagemid particle fluorescence and recognition of GFP by antibodies, indicates that proteins may fold correctly without being accessible for display. The best vector used a twin arginine transporter leader to transport the displayed protein to the periplasm, and a coil-coil arrangement to link the displayed protein to g3p. This vector was able to display less robust forms of GFP, including ones with inserted epitopes, as well as fluorescent proteins of the Azami green series. It was also functional in mock selection experiments.     

Fluorometric assay for urea in urine, plasma, and tubular fluid

The variation in the sensitivity of proteins to some commonly used protein assay procedures was estimated by a calculation of the ideal titer per unit weight of protein for a sample of 350 proteins. On the basis of such calculations, the variation expected of nitrogen-based assay procedures is expected to be small, and such procedures are considered to give a more consistent quantification of a variety of proteins than other commonly used assay procedure.     

Arginine-aromatic interactions and their effects on arginine-induced solubilization of aromatic solutes and suppression of protein aggregation

We examine the interaction of aromatic residues of proteins with arginine, an additive commonly used to suppress protein aggregation, using experiments and molecular dynamics simulations. An aromatic-rich peptide, FFYTP (a segment of insulin), and lysozyme and insulin are used as model systems. Mass spectrometry shows that arginine increases the solubility of FFYTP by binding to the peptide, with the simulations revealing the predominant association of arginine to be with the aromatic residues. The calculations further show a positive preferential interaction coefficient, Γ(XP), contrary to conventional thinking that positive Γ(XP)'s indicate aggregation rather than suppression of aggregation. Simulations with lysozyme and insulin also show arginine's preference for aromatic residues, in addition to acidic residues. We use these observations and earlier results reported by us and others to discuss the possible implications of arginine's interactions with aromatic residues on the solubilization of aromatic moieties and proteins. Our results also highlight the fact that explanations based purely on Γ(XP), which measures average affinity of an additive to a protein, could obscure or misinterpret the underlying molecular mechanisms behind additive-induced suppression of protein aggregation.     

PRMT11: a new Arabidopsis MBD7 protein partner with arginine methyltransferase activity

Plant methyl-DNA-binding proteins (MBDs), discovered by sequence homology to their animal counterparts, have not been well characterized at the physiological and functional levels. In order better to characterize the Arabidopsis AtMBD7 protein, unique in bearing three MBD domains, we used a yeast two-hybrid system to identify its partners. One of the interacting proteins we cloned is the Arabidopsis arginine methyltransferase 11 (AtPRMT11). Glutathione S-transferase pull-down and co-immunoprecipitation assays confirmed that the two proteins interact with each other and can be co-isolated. Using GFP fluorescence, we show that both AtMBD7 and AtPRMT11 are present in the nucleus. Further analyses revealed that AtPRMT11 acts as an arginine methyltransferase active on both histones and proteins of cellular extracts. The analysis of a T-DNA mutant line lacking AtPRMT11 mRNA revealed reduced levels of proteins with asymmetrically dimethylated arginines, suggesting that AtPRMT11, which is highly similar to mammalian PRMT1, is indeed a type I arginine methyltransferase. Further, AtMBD7 is a substrate for AtPRMT11, which post-translationally modifies the portion of the protein-containing C-terminal methylated DNA-binding domain. These results suggest the existence of a link between DNA methylation and arginine methylation.     

Role of arginine in protein refolding, solubilization, and purification

Recombinant proteins are often expressed in the form of insoluble inclusion bodies in bacteria. To facilitate refolding of recombinant proteins obtained from inclusion bodies, 0.1 to 1 M arginine is customarily included in solvents used for refolding the proteins by dialysis or dilution. In addition, arginine at higher concentrations, e.g., 0.5-2 M, can be used to extract active, folded proteins from insoluble pellets obtained after lysing Escherichia coli cells. Moreover, arginine increases the yield of proteins secreted to the periplasm, enhances elution of antibodies from Protein-A columns, and stabilizes proteins during storage. All these arginine effects are apparently due to suppression of protein aggregation. Little is known, however, about the mechanism. Various effects of solvent additives on proteins have been attributed to their preferential interaction with the protein, effects on surface tension, or effects on amino acid solubility. The suppression of protein aggregation by arginine cannot be readily explained by either surface tension effects or preferential interactions. In this review we show that interactions between the guanidinium group of arginine and tryptophan side chains may be responsible for suppression of protein aggregation by arginine.     

Evaluating the compatibility of three colorimetric protein assays for two-dimensional electrophoresis experiments

To evaluate compatibility of commonly used colorimetric protein assays for 2-DE experiments, we investigated the interfering mechanisms of major 2-DE component(s) in the Lowry-based assay, the Bradford assay and the bicinchoninic acid (BCA) assay. It was found that some 2-DE components did not directly interfere with the assays' color development reaction, but possibly influenced the quantitation results by interacting with proteins. Generally, simultaneous presence of 2-DE components in the samples demonstrated a cooperative rather than additive interference. Interference by reductants in the Lowry-based assay and the BCA assay were too prominent and could not be completely eliminated by either the reported alkylation procedure or the water dilution procedure. The Bradford assay however, presented a more suitable method for quantitating 2-DE samples because it was less interfered by most 2-DE components. Furthermore, despite slightly compromising protein solubility, utilization of reductant free 2-DE sample buffers conferred application of the Lowry-based and BCA assays in the 2-DE experiments.     

Interference of some detergent micelles with the titration of protein

We have examined the possible interferences with spectrophotometric protein determination of some detergents commonly used for the solubilization of membrane proteins. The results show that some mixtures of Triton X100 with SDS or DOC, at given concentrations, interfere with BSA determination by the method of Lowry.     

Recombinant production of the p10CKS1At protein from Arabidopsis thaliana and 13C and 15N double-isotopic enrichment for NMR studies.

The CKS1At gene product, p10CKS1At from Arabidopsis thaliana, is a member of the cyclin-dependent kinase subunit (CKS) family of small proteins. These proteins bind the cyclin-dependent kinase (CDK)/cyclin complexes and play an essential, but still not precisely known role in cell cycle progression. To solve the structure of p10CKS1At, a protocol was needed to produce the quantity of protein large enough for nuclear magnetic resonance (NMR) spectroscopy. The first attempt to express CKS1At in Escherichia coli under the control of the T7 promoter was not successful. E. coli BL21(DE3) cotransformed with the CKS1At gene and the E. coli argU gene that encoded the arginine acceptor tRNAUCU produced a sufficient amount of p10CKS1At to start the structural study by NMR. Replacement of four rare codons in the CKS1At gene sequence, including a tandem arginine, by highly used codons in E. coli, restored also a high expression of the recombinant protein. Double-isotopic enrichment by 13C and 15N is reported that will facilitate the NMR study. Isotopically labeled p10CKS1At was purified to yield as much as 55 mg from 1 liter of minimal media by a two-step chromatographic procedure. Preliminary results of NMR spectroscopy demonstrate that a full structural analysis using triple-resonance spectra is feasible for the labeled p10CKS1At protein.     

Measurement of microgram quantities of protein by a generally applicable turbidimetric procedure

A modified turbidimetric method for protein determination which involves the use of trichloroacetic acid as the precipitating agent is described. Maximal turbidity develops in less than 30 min and is stable for at least 120 min. A linear relationship between turbidity at 340 nm and protein concentration is observed between 2 and 40 micrograms protein. Sodium dodecyl sulfate is added to avoid the interference by nonionic and cationic detergents and lipids and to decrease the protein-to-protein variation. The use of cetyltrimethyl ammonium bromide provides a two-step procedure to correct for the contribution of contaminating nucleic acid. Many compounds which interfere with other protein quantitation methods have no effect on this system. The interference of commonly used reagents as sucrose and urea can be easily corrected. This procedure compared favorably with the most widely used protein quantitation methods in simplicity, sensitivity, and specificity.