Elution of antibodies from a Protein-A column by aqueous arginine solutions

Acidic pH is commonly used to elute antibodies from Protein-A affinity column, although low pH may result in aggregation of the proteins. As an alternative, here arginine was tested as an eluent and compared with a more conventional eluent of citrate. Using purified monoclonal antibodies, recovery of antibodies with 0.1M citrate, pH 3.8, was less than 50% and decreased further as the pH was increased to 4.3. At the same pH, the recovery of antibodies was greatly increased with 0.5M arginine and more so with 2M arginine. Even at pH 5.0, 2M arginine resulted in 31% recovery, although the elution under such condition showed extensive tailing. Such tailing was observed at pH 3.8 when 0.1M citrate was used. Size exclusion analysis indicated that the eluted antibodies were mostly monomeric whether eluted with citrate or arginine. This demonstrates the usefulness of arginine as an efficient eluent for Protein-A chromatography.     

Effective elution of antibodies by arginine and arginine derivatives in affinity column chromatography

It has been shown that the recovery of monomeric antibodies from protein A affinity chromatography is enhanced significantly by using arginine as an eluent. To extend the applications of arginine to antibody purification and obtain an insight into the mechanism of arginine elution, we compared arginine with citrate, guanidine hydrochloride (GdnHCl), arginine derivatives, and other amino acids in protein A chromatography. We also applied arginine to elution of polyclonal antibodies (pAbs) in antigen affinity chromatography. As described previously, arginine was effective in eluting monoclonal antibodies IgG1 and IgG4. Two arginine derivatives, acetyl-arginine and agmatine, resulted in efficient elution at pH 4.0 or higher, and this was comparable to arginine. On the other hand, other amino acids, such as glycine, proline, lysine, and histidine, are much less effective than arginine under identical pH conditions. Whereas elution increased with arginine concentration, elution with citrate was insignificant in excess of 1 M at pH 4.3. Arginine was also effective in fractionation of pAbs using antigen-conjugated affinity columns. Although GdnHCl was also effective under similar conditions, the eluted material showed more aggregation than did the protein eluted by arginine.     

MEP chromatography of antibody and Fc-fusion protein using aqueous arginine solution

MEP HyperCel resin, one of the Protein-A mimetic columns, is designed to bind antibodies at physiological pH and elutes the bound antibodies at mildly acidic pH. We have tested aqueous arginine solution for washing and elution of the resin. To our surprise, bound antibody and Fc-fusion protein eluted at pH 7.0 using 1 M arginine solution. Various solvent additives were then examined at pH 7.0. Among the tested additives, urea and arginine were the only additives that were effective in elution. Thus, urea and arginine at low concentrations were effectively used for washing the resin. NaCl and MgCl₂ at 0.1–1 M and ethanol at 5–20% were not effective. Based on these observations, it appears that protein binds to MEP resin through both polar and hydrophobic interactions with some contribution of electrostatic interaction, which can be simultaneously reduced by arginine or urea. On the other hand, Mabsorbent, another Protein-A mimetic column, appears to be more non-specific and non-selective.     

The effects of arginine on protein binding and elution in hydrophobic interaction and ion-exchange chromatography

Arginine is effective in suppressing aggregation of proteins and may be beneficial to be included during purification processes. We have shown that arginine reduces non-specific protein binding in gel permeation chromatography and facilitates elution of antibodies from Protein-A columns. Here we have examined the effects of arginine on binding and elution of the proteins during hydrophobic interaction (HIC) and ion- exchange chromatographies (IEC) using recombinant monoclonal antibodies (mAbs) and human interleukin-6. In the case of HIC, the proteins were bound to a phenyl-Sepharose column in the presence of ammonium sulfate (AS) with or without arginine and eluted with a descending concentration of AS. While use of 1 M AS in the loading buffer resulted in complete binding of the mAb, inclusion of 1 M arginine in loading and equilibration buffer, only when using low-substituted phenyl-Sepharose, resulted in weaker binding of the proteins. While decreasing AS concentration to 0.75 M resulted in partial elution of the mAB, elution was facilitated with inclusion of 0.5-1 M arginine. In the case of IEC, arginine was included in the loading samples. Inclusion of arginine during binding to the IEC columns resulted in a greater recovery and less aggregation even when elution was done in the absence of arginine. These results indicate that arginine enhances elution of proteins bound to the resin, suggesting its effectiveness as a solvent for elution in HIC and IEC.     

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.     

Resolution of human mercapt- and nonmercaptalbumin by high-performance liquid chromatography

Gel-exclusion high-performance liquid chromatographic (HPLC) analysis of human serum albumin (HSA) on PGP 2000 column (0.10 M sodium phosphate buffer, 0.30 M NaCl, pH 6.86) showed at least two peaks, the principal component corresponding to human mercaptalbumin (HMA) and the second one to human nonmercaptalbumin (HNA). Mechanism for the separation of HMA and HNA might be due to weak resin-HSA interaction. HPLC analysis of bovine plasma albumin (BPA) showed a single peak on PGP 2000 column. The elution volume of HSA was larger than that of BPA, resulting in a clear resolution of HSA and BPA.     

Arginine as an eluent overcomes the hindrance of monoclonal antibody quantification by dextran sulfate in protein A affinity chromatography

Analytical chromatography using protein A affinity columns was employed for the fast and simple quantitative analysis of monoclonal antibodies (mAb) from suspension cultures of recombinant Chinese hamster ovary (rCHO) cells. Reliable results could not be obtained from analysis of rCHO cell culture supernatants containing dextran sulfate using elution buffers such as phosphate, glycine, or MgCl₂. These problems increased as the number of analysis and the concentration of dextran sulfate in samples increased. Arginine was identified as an alternative eluent to overcome the hindrance by dextran sulfate. When the samples contain dextran sulfate up to 100 mg/L, the elution buffer containing 0.6–1.0 M arginine at pH 3.0–3.8 is useful for the effective analysis. Reproducible results in the mAb quantification could be obtained by this developed arginine elution buffer from rCHO cell culture supernatants containing dextran sulfate. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:1536–1541, 2015     

Predicting the elution behavior of proteins in affinity chromatography on non-porous particles.

Affinity chromatography on non-porous particles of microsize is particularly useful for the rapid analysis and micropreparative separation of proteins. The elution behavior of proteins in an affinity column packed with non-porous copolymerized particles of styrene, methyl methacrylate and glycidyl methacrylate was investigated both theoretically and experimentally, using the lysozyme-Cibacron Blue 3G-A affinity system. Equations used to predict the elution profiles, resulting from the elution by increasing the ionic strength (NaCl concentration) in the mobile phase, were obtained. The maximum adsorbate concentration, desorption rate constant and equilibrium constant under elution conditions were determined by matching experimental data with predicted elution profiles. Based on the parameters determined at a flow-rate of 0.5 ml/min and with 1 M NaCl in the elution buffer, the model equations could predict the elution profiles for other experimental runs, where different flow-rates and sodium chloride concentrations were used. Both the experimental and predicted results revealed that the affinity interaction kinetics are not significantly influenced by the flow-rate and, hence, the film mass transfer. To elute bound lysozyme from immobilized dye ligand, a higher value of the ionic strength leads to a faster elution and a sharper elution peak. The influence of elution conditions on the kinetic and thermodynamic parameters and, consequently, on the elution peak profiles was evaluated. The model equations can also predict the behavior of protein elution from an affinity column by changing the pH of the mobile phase, according to a previous study.     

Purification of the H-2Kk molecule of the murine major histocompatibility complex.

The intact H-2Kk antigen has been detergent-solubilized and purified using an immunoabsorbent column prepared from the 11-4.1 monoclonal antibody described by Oi et al. (Oi, V. T., Jones, P. P., Goding, J. Current Topics in Microbiology and Immunology (Melchers, F., Potter, M., and Warner, N. L., eds) Vol. 81, pp. 115-129, Springer-Verlag, New York). The mild conditions used for elution from the column, 0.5% deoxycholate in 10 mM Tris buffer, pH 8, with 0.14 M NaCl, result in recovery of 70 to 100% of the allogeneic serological activity. A murine lymphoma, RDM-4, was found to express high levels of H2-Kk; approximately 2 X 10(6) molecules/cell. Milligram quantities of H-2Kk can be purified readily using these cells.     

Effect of poly(vinyl alcohol) treatment of the dyematrix on the chromatography of pyruvate kinase

Summary The utility of poly(vinyl alcohol) as a shielding polymer in dye-affinity chromatography was studied. Difference spectroscopy was used to estimate the strength of the polymer-dye complex. The target enzyme, pyruvate kinase (E.C. 2.7.1.40) from porcine muscle was purified on a Red HE3B-Sepharose column with 95% recovery by salt elution and 85% recovery with specific eluent.     

Efficient and rapid purification of recombinant human alpha-galactosidase A by affinity column chromatography

The lysosomal enzyme alpha-galactosidase A (alpha-Gal A) metabolizes neutral glycosphingolipids that possess alpha-galactoside residues at the non-reducing terminus, and inherited defects in the activity of alpha-Gal A lead to Fabry disease. We describe here an efficient and rapid purification procedure for recombinant alpha-Gal A by sequential Concanavalin A (Con A)-Sepharose and immobilized thio-alpha-galactoside (thio-Gal) agarose column chromatography. Optimal elution conditions for both columns were obtained using overexpressed human alpha-Gal A. We recommend the use of a mixture of 0.9 M methyl alpha-mannoside and 0.9 M methyl alpha-glucoside in 0.1 M acetate buffer (pH 6.0) with 0.1 M NaCl for the maximum recovery of glycoproteins with multiple high-mannose type sugar chains from Con A column chromatography, and that the Con A column should not be reused for the purification of glycoproteins that are used for structural studies. Binding of the enzyme to the thio-Gal column requires acidic condition at pH 4.8. A galactose-containing buffer (25 mM citrate-phosphate buffer, pH 5.5, with 0.1 M galactose, and 0.1 M NaCl) was used to elute alpha-Gal A. This procedure is especially useful for the purification of mutant forms of alpha-Gal A, which are not stable under conventional purification techniques. A protocol that purifies an intracellular mutant alpha-Gal A (M279I) expressed in COS-7 cells within 6h at 62% overall yield is presented.     

Adsorption chromatography of nucleic acids on silicone-coated porous glass

Bovine liver tRNA was adsorbed on silicone-coated porous glass in 5 M NaCl, 10 mM Tris-HCl (pH 7.6) and fractionated by elution with decreasing NaCl concentrations. tRNAPro, tRNAVal, tRNAIle, tRNAThr, tRNASer, and tRNAPhe were eluted in this order. tRNA which had been digested with ribonuclease A was not adsorbed. Q beta RNA (adsorbed onto the glass in 5 M NaCl) was eluted with 1.5 M NaCl. RNA species in a crude rRNA fraction from Escherichia coli were separated into tRNA, 5S rRNA, and high molecular weight rRNA on siliconized porous glass. A half of calf thymus DNA was adsorbed on the glass in 5 M NaCl and the residual part passed through the column. The CD spectra showed that DNA and tRNA took the C-form and the A-form in 5 M NaCl, respectively. Therefore, the discrepancies of behavior of the DNA and RNA on siliconized porous glass may be related to the occurrence of these forms. The recovery of these nucleic acids from the column was 83-100%. Adsorption chromatography on siliconized porous glass may be a useful method for the separation of tRNA, rRNA, and mRNA.     

Affinity chromatography of antibodies directed against soybean lipoxygenase-1 and -2 and an enzyme-linked immunosorbent assay (ELISA) for antibodies and lipoxygenases

Crude immunoglobulin G (IgG) fractions of antisera directed against soybean lipoxygenase-1 and -2 were purified by being passed through an immunoadsorbent column containing lipoxygenase coupled to CNBr-activated Sepharose 4B. Bound immunoglobulin was desorbed with pulses of 2 M or 3 M ammonium thiocyanate or 0.1 M glycine-HCl buffer (pH 2.5). The total column recoveries of anti-lipoxygenase-1 IgG and anti-lipoxygenase-2 IgG were 45% and 58%, respectively. The affinity for lipoxygenase of immunospecific antibodies was determined in an enzyme-linked immunosorbent assay (ELISA). In a reaction with lipoxygenase-1, anti-lipoxygenase-1 IgG, which was eluted with glycine-HCl buffer (pH 2.5) with recovery of 24%, had a 6.5-times higher affinity than the whole IgG fraction of antiserum. The affinity of anti-lipoxygenase-2 IgG for lipoxygenase-2 increased 2.2-times after chromatography of IgG over an immunoadsorbent column using 2 M ammonium thiocyanate as eluent (recovery 21%).     

The effect of heparin on the affinity chromatography of plasminogen. Demonstration of heparin-plasminogen interaction.

Evidence is presented that heparin binds rabbit plasminogen types I and II under affinity chromatographic conditions using the single stage technique earlier described (Hatton, M.W.C. and Regoeczi, E. (1974) Biochim. Biophys. Acta 359, 55-65). Thus, the affinity of types I and II for Sepharose-lysine is markedly increased in the presence of heparin and elution by epsilon-aminohexanoic acid requires a steeper gradient to recover the plasminogen types. Furthermore by adding sufficient epsilon-aminohexanoic acid to non-heparinised plasma to suppress plasminogen affinity, the presence of heparin is shown to encourage binding of plasminogen (type II more so than type I) to the gel. However, the heparin effect is quickly reversed by washing the column with 0.5 M NaCl prior to elution by epsilon-aminohexanoic acid. No evidence of a stable plasminogen-heparin complex has been found from gel filtration studies and any interaction between plasminogen and heparin probably only takes place when heparin is bound to an affinity site. Studies with 35-S-labelled heparin have shown the mucopolysaccharide to bind to the free amino group of Sepharose-lysine and Sepharose-cadaverine and to be displaced by 0.5 M NaCl elution but not by 0.1 M epsilon-aminohexanoic acid. The plasminogen types produced from heparinised plasma are free from heparin and closely resemble preparations from non-heparinised plasma when compared by polyacrylamide gel electrophoresis, Sephadex gel filtration and arginine esterase activity after urokinase activation.     

Size-exclusion chromatography of biological samples which contain extremely alkaline proteins

An improved size-exclusion chromatography (SEC) was developed to isolate extremely basic (alkaline) proteins, such as trypsin (pI=10.5), lysozyme (pI=11), and histone (pI=10.8). Develosil 300 Diol-5 (300 x 8 mm I.D., 30 nm average pore diameter) column was used with an eluent of 0.1 M sodium phosphate, 1.5 M sodium chloride, glycerol (40%, v/v), 2-propanol (10%, v/v), and Brij-58 (1%, v/v). Under these conditions, the final apparent pH becomes to 4.0, and pH adjustment is not necessary. Column temperature and flow rate were 15 degrees C and 0.2 ml/min, respectively. This elution system is stable and reliable, and applications onto human pancreatic juice, human bile, and tissue homogenates were successfully achieved. Since this system is convenient for protein analysis, it is expected to be generally applicable to clinical and biochemical research for identifying protein components in combination with microsequencing.     

The displacement effect of phenylalanine on lysozyme elution in hydrophobic interaction chromatography

The volume, retention time, and shape of the lysozyme peak eluted from a hydrophobic interaction chromatography column (TosoHaas 650 M Phenyl) was influenced by the presence and concentration of phenylalanine in the elution buffer. Lysozyme peak retention time decreased by a factor of 2.5 with the addition of 86 mM phenylalanine to the elution buffer.     

Isolation of human fibrinogen by axial and radial flow chromatography from Nitschmann fraction I

An axial column (3×2.6 cm) and a radial flow column (3.5×5 cm) packed with DEAE Sepharose Fast Flow media had been evaluated for the separation of human fibrinogen. Nitschmann fraction I dissolved in buffered saline (0.015 M NaCl buffered with 0.06 M Tris/HCl to pH 7.5) was the starting material. Under radial flow conditions, sample flow up to 15 ml min^–1 (i.e., 18 bed volumes h^–1) was achieved. The operating pressures were below 0.2 MPa, even though the elution velocity was 30 ml min^–1 (i.e., 36 bed volumes h^–1).     

凝胶层析在发酵液中分离提纯透明质酸中的应用

采用葡聚糖凝胶G-100,以0.1 mol/L氯化钠溶液为洗脱剂,在优化的凝胶层析条件(层析柱高度30 cm、进样量2 ml、洗脱流速1 ml/4 min)下,对透明质酸发酵液进行分离纯化,得到了高纯度的透明质酸.HA提取率达到79.85%,蛋白质去除率为84.93%.     

吸附层析分离麻黄生物碱的过程优化

研究了用吸附层析取代现有的二甲苯萃取麻黄生物碱的工艺,重点考察了洗脱剂和操作条件对产品纯度和回收率的影响,发现在树脂吸附后的洗脱中,0．08M草酸的洗脱率最高,达99．3％,纯化倍数大于20;在操作条件中,进料量、pH和料液在层析柱中的停留时间影响最大：进料量增大导致纯度和收率的下降,树脂的动态吸附容量为27．5mg／mL树脂;停留时间在20rain时纯度较高,而洗脱率随停留时间减少却略有下降;pH=10时吸附性能较好。     

Lipoprotein lipase-like activity in the liver of mice with Sarcoma 180

The triglyceride lipase (TGL) activity of liver homogenates of mice with Sarcoma 180 was measured. The liver homogenate of normal or tumor-bearing mice was treated with 0.25% Triton X-100 and centrifuged at 100,000 g for 60 min, and the supernatant was applied to a heparin-Sepharose column. In normal mice, most of the TGL activities in the supernatant was eluted with 0.75 M NaCl from the column. In mice with Sarcoma 180, the TGL gave two peaks on heparin-Sepharose column chromatography, which were eluted with 0.75 M and 1.5 M NaCl, respectively. The activity in the first peak (0.75 M NaCl eluate) decreased; that in the second peak (1.5 M NaCl eluate) increased, and the ratio of the second peak to the first peak increased during tumor development. The livers of normal mice and mice on day 10 after tumor inoculation were perfused with heparin. The highest rate of the TGL release occurred within 1 min of heparin perfusion, and the bulk of heparin-releasable activity appeared within 2 min of perfusion in both normal and tumor-bearing mice. The TGL activity in liver perfusate of tumor-bearing mice, as well as that of liver homogenate, was resolved on a heparin-Sepharose column into two peaks, which were eluted with 0.75 M and 1.5 M NaCl, and most of the activity was eluted with 1.5 M NaCl. The nature of the TGL activity eluted from a heparin-Sepharose column was investigated. In both liver homogenates and liver perfusates, the first peak did not require serum for maximal activity and was relatively resistant to a high concentration of NaCl or protamine sulfate.(ABSTRACT TRUNCATED AT 250 WORDS)