Novel sulfamethazine ligand used for one-step purification of immunoglobulin G from human plasma

To replace conventional affinity ligand like protein A or protein G, a pseudobioaffinity ligand seems to be an alternative for the purification of immunoglobulin G (IgG). In this study, sulfamethazine (SMZ) was chosen as novel affinity ligand for investigating its affinity to human IgG. Monodisperse, non-porous, cross-linked poly (glycidyl methacrylate) (PGMA) beads were employed as the support for high-performance affinity chromatography. SMZ was immobilized on PGMA beads using bisoxirane (ethanediol diglycigyl ether) as spacer. The resultant affinity media presented minimal non-specific interaction with other proteins. Results of high-performance frontal analysis indicated that the media showed specific affinity to human IgG with a dissociation constant on the order of 10(-6) M. The SMZ affinity column proved useful for a very convenient one-step purification of IgG from human plasma. Antibody purity after a one-step purification was higher than 90%, as determined by densitometric scanning of sodium dodecyl sulfate-polyacrylamide gel electrophoresis of purified fraction under reducing condition. The results obtained indicate that SMZ is a valuable affinity ligand for purification of human IgG.     

Molecular dynamic investigation of the interaction of supported affinity ligands with monoclonal antibodies

Diagnostics and therapeutic treatments based on monoclonal antibodies have been attaining an increasing importance in the past decades, but their large scale employment requires the optimization of purification processes. To obtain this goal, research is focusing on affinity chromatography techniques and the development of new synthetic ligands. In this work we present a computational investigation aimed at obtaining some guidelines for the rational design of affinity ligands, through the study of their interactions with both monoclonal antibodies (modeled as the FC domain of human IgG) and a model support material (agarose). The study was carried out performing molecular dynamics simulations of the support-spacer-ligand-IgG complex in explicit water. Binding energies between IgG and two supported ligands, a disubstituted derivative of trichlorotriazine and a tetrameric peptide, were determined with the linear interaction energy and MM-GBSA approaches. A detailed study of the possible binding sites of the considered ligands was performed exploiting docking protocols and MD simulations. It was found that both ligands bind IgG in the same site as protein A, which is the hinge region between the CH2 and CH3 domains of IgG. However this site is not easily accessible and requires a high mobility of the ligands. The energetic analysis revealed that van der Waals and electrostatic energies of interaction of the triazine ligand with the support are significant and comparable to those with the protein, so that they limit its capability to reach the protein binding site. A similar result was found also for the tetrameric peptide, which is however able to circumvent the problem; for steric reasons only two of its arms can interact at the same time with the agarose support, thus leaving the remaining two available to bind the protein. These results indicate that the interaction between ligand and support material is an important parameter, which should be considered in the computational and experimental design of ligands for affinity chromatography.     

On-line post-capillary affinity detection of immunoglobulin G for capillary zone electrophoresis

To address the quality issues of antibody manufacturing, post-capillary affinity detection of immunoglobulin G (IgG) is developed for capillary zone electrophoresis. In analogy to a two-dimensional separation system, capillary zone electrophoresis (CZE), as the first dimension, resolves IgG variants based on their differences in molecular structure. IgG variants separated by CZE are discriminated against other serum and cellular proteins by affinity complex formation with protein A binding fragment in a post-capillary reactor. The analytical power of post-capillary affinity detection is demonstrated for rapid and selective heterogeneity analysis of human IgG subclasses and monoclonal antibodies in complex sample matrices. By comparing with pre-capillary formation of affinity complexes between IgG and protein A, post-capillary affinity detection clearly exhibit greater resolving power for examining IgG microheterogeneity. Affinity complex formation prior to CZE analysis, however, has the advantage of lower detection limits. Detection limits suffer with post-capillary affinity detection because of the high fluorescence background contributed by the fluorescently labeled protein A in the post-capillary reactor, and the need to determine a small change in the background level upon complex formation.     

A蛋白亲和层析法纯化动物血清抗体的效果比较

用ＨｉｔｒａｐＰｒｏｔｅｉｎ－ＡＳｅｐｈａｒｏｓｅ亲和层析系统,对不同动物血清或抗血清抗体的纯化效率进行了比较,为选择抗体纯化方法提供依据。该方法简便快速,纯化的抗体纯度高,能较好地保持抗体免疫学活性。层析柱反复使用４０多次,纯化抗体效率不变。但Ｐｒｏｔｅｉｎ－Ａ对不同动物血清的ＩｇＧ吸附能力不同：对兔和豚鼠的血清抗体吸附能力强     

Concentration dependence of IgG-protein A affinity studied by wireless-electrodeless QCM

The binding affinity between human immunoglobulin G (IgG) and protein A was studied by the homebuilt wireless-electrodeless quartz crystal microbalance (QCM). Protein A was immobilized on the electrodeless AT-cut quartz plate of 0.05 mm thick and its fundamental resonance frequency near 34 MHz was measured by a noncontacting manner using a line antenna. The vibrational analysis was performed to ensure higher sensitivity of the electrodeless QCM. A flow-cell system was fabricated to continuously measure the resonance frequency during the injection sequence of the IgG solutions with concentrations of 1-20,000 ng/mL. The exponential frequency changes were recorded to determine the affinity based on the Langmuir kinetics. The equilibrium constant K(A) significantly varied between 6 x 10(6) and 6 x 10(10) M(-1), depending on the IgG concentration, which is attributed to various formations of IgG-protein A complexes.     

Interaction between heat shock protein DnaK and recombinant staphylococcal protein A.

When a protein derived from the immunoglobulin G (IgG)-binding domains of staphylococcal protein A was expressed in Escherichia coli and recovered from cell extract by IgG affinity chromatography, the 69-kilodalton heat shock protein DnaK was found to be copurified. DnaK could be selectively eluted from the IgG column by ATP or by lowering the pH to 4.7. Protein A could subsequently be eluted by lowering the pH to 3.2. Thus, this procedure allows a one-step purification of both DnaK and protein A from cell extract. In vitro experiments with pure DnaK and protein A revealed that DnaK did not interfere with the IgG-binding properties of protein A but associated with its unfolded C-terminal in a salt-resistant manner. In addition, a specific interaction between DnaK and denaturated casein was found.     

Biomimetic design of affinity peptide ligands for human IgG based on protein A-IgG complex

Staphylococcal protein A (SpA) has been widely used as an affinity ligand for the purification of immunoglobulin G (IgG). Based on the affinity motif of SpA, we have herein developed a biomimetic design strategy for affinity peptide ligands of IgG. First, according to the distribution of the six hot spots of the SpA affinity motif determined previously, the number of residues that should be inserted into between the hot spots was determined. Cysteine was introduced as one of the middle inserted residues of the peptide for later immobilization. Then, amino acid location was performed to identify other amino acid residues for insertion, leading to the construction of a peptide library. The library was screened by using different molecular simulation protocols, resulting in the selection of 15 peptide candidates. Thereafter, molecular dynamics simulations were performed to validate the dynamics of the affinity interactions between the candidates and IgG, and 14 of them were found to keep high affinities. Finally, the affinity and specificity of the top one ligand FYWHCLDE were exemplified by protein chromatography and IgG purification. The results indicate that the design strategy was successful and the affinity peptide ligand for IgG is promising for application in antibody purifications.     

Fucose depletion from human IgG1 oligosaccharide enhances binding enthalpy and association rate between IgG1 and FcgammaRIIIa

Depletion of fucose from human IgG1 oligosaccharide improves its affinity for Fcgamma receptor IIIa (FcgammaRIIIa). This is the first case where a glycoform modification is shown to improve glycoprotein affinity for the receptors without carbohydrate-binding capacity, suggesting a novel glyco-engineering strategy to improve ligand-receptor binding. To address the mechanisms of affinity improvement by the fucose depletion, we used isothermal titration calorimetry (ITC) and biosensor analysis with surface plasmon resonance. ITC demonstrated that IgG1-FcgammaRIIIa binding was driven by favorable binding enthalpy (DeltaH) but opposed by unfavorable binding entropy change (DeltaS). Fucose depletion from IgG1 enhanced the favorable DeltaH, leading to the increase in the binding constant of IgG1 for the receptor by a factor of 20-30. The increase in the affinity was mainly attributed to an enhanced association rate. A triple amino acid substitution in IgG1, S298A/E333A/K334A, is also known to improve IgG1 affinity for FcgammaRIIIa. ITC demonstrated that the amino acid substitution attenuated the unfavorable DeltaS resulting in a three- to fourfold increase in the binding constant. The affinity enhancement by the amino acid substitution was due to a reduced dissociation rate. These results indicate that the mechanism of affinity improvement by the fucose depletion is quite distinct from that by the amino acid substitution. Defucosylated IgG1 exhibited higher antibody-dependent cellular cytotoxicity (ADCC) than S298A/E333A/K334A-IgG1, showing a correlation between IgG1 affinity for FcgammaRIIIa and ADCC. We also examined the effect of FcgammaRIIIa polymorphism (Val158/Phe158) on IgG1-FcgammaRIIIa binding. The Phe to Val substitution increased FcgammaRIIIa affinity for IgG1 in an enthalpy-driven manner with the reduced dissociation rate. These results together highlight the distinctive functional improvement of affinity by IgG1 defucosylation and suggest that engineering of non-interfacial monosaccharides can improve glycoprotein affinity for receptors via an enthalpy-driven and association rate-assisted mechanism.     

High-performance affinity chromatography with immobilization of protein A and L-histidine on molded monolith

Reactive monoliths of macroporous poly(glycidyl methacrylate-co-ethylene dimethacrylate) have been prepared by "in-situ" copolymerization of the monomers in the presence of porogenic diluents. Protein A and L-histidine were immobilized on the monoliths directly or through a spacer arm, respectively. The properties of these two kinds of affinity columns were characterized, and the results showed that the columns with coupling of ligands by a spacer arm have some extent of non-specific adsorption for bovine serum albumin. The affinity column based on the monolithic polymer support provided us with good hydrodynamic characteristic, low flow resistance, and easy preparation. These two affinity columns were used for the purification of immunoglobulin G from human serum. The purity of the purified IgG was detected by matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF-MS). The stability of the protein A affinity column was investigated, and its performance remained invariable after half a year. The effects of the nature and the pH of the buffer system on the adsorption capacity of human IgG on histidyl affinity column were also investigated. The protein A affinity column is favorable for rapid analysis of human IgG samples. In contrast, the advantages of mild elution conditions, high stability, as well as low cost provide the histidyl column further potential possibility for fast removal of IgG from human plasma in clinical applications.     

Toward improving selectivity in affinity chromatography with PEGylated affinity ligands: The performance of PEGylated protein A

Chemical modification of macromolecular affinity chromatography ligands with polyethylene glycol chains or “PEGylation” can potentially improve selectivity by sterically suppressing non‐specific binding interactions without sacrificing binding capacity. For a commercial protein A affinity media and with yeast extract (YE) and fetal bovine serum (FBS) serving as mock contaminants, we found that the ligand accounted for more than 90% of the media‐associated non‐specific binding, demonstrating an opportunity for improvement. The IgG static binding affinity of protein A mono‐PEGylated with 5.0 and 20.7 kDa poly(ethylene glycol) chains was found to be preserved using a biomolecular interaction screening platform. Similar in situ PEGylations of the commercial protein A media were conducted and the modified media was functionally characterized with IgG solutions spiked with YE and FBS. Ligand PEGylation reduced the mass of media‐associated contaminants by a factor of two to three or more. Curiously, we also found an increase of up to 15% in the average recovery of IgG on elution after PEGylation. Combined, these effects produced an order of magnitude increase in the IgG selectivity on average when spiked with YE and a two‐ to three‐fold increase when spiked with FBS relative to the commercial media. Dynamic binding capacity and mass‐transfer resistance measurements revealed a reduction in dynamic capacity attributed to a decrease in IgG effective pore diffusivity and possibly slower IgG association kinetics for the PEGylated protein A ligands. Ligand PEGylation is a viable approach to improving selectivity in affinity chromatography with macromolecular ligands. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 30:1364–1379, 2014     

A蛋白亲和色谱法纯化动物血清抗体的效果比较

比较Hitrap A蛋白琼脂糖凝胶亲和色谱系统,对不同动物血清或抗血清抗体的纯化效率,提供选择抗体纯化方法的依据。该方法简使快速,纯化的抗体纯度高,能较好地保持抗体免疫学活性。色谱柱反复使用40多次,纯化抗体效率不变。但A蛋白对不同动物血清的IgG吸附能力不同,对兔和豚鼠的血清抗体吸附能力强,而对小鼠、山羊和驴的血清抗体吸附能力较弱。说明虽然该方法纯化的抗体纯度高,但它对动物品种有选择。因此,应根据动物品种,选择适合的纯化方法。     

Identification,characterization, and cloning of an immunoglobulin degrading enzyme in the cat flea,Ctenocephalides felis

The degradation of cat immunoglobulin G (IgG) in blood-fed adult C. felis midguts was examined. SDS-PAGE analysis of dissected midgut extracts obtained from C. felis that had been blood fed for various times between 0 to 44 h revealed that by 24 h most of the high molecular weight proteins, including the heavy chain of IgG, were digested. A 31-kDa serine protease with IgG degrading activity was purified from fed C. felis midguts by benzamidine affinity chromatography, hydrophobic interaction chromatography, and cation exchange chromatography. Three primary cleavage products between 30- and 40-kDa were observed when the purified protease was incubated with protein A purified cat IgG. N-terminal amino acid sequence analysis of the products revealed that the IgG degrading protease cleaves after specific cysteine and lysine residues within the hinge region of IgG. The enzyme is also capable of degrading other immunoglobulins, serum albumin, and hemoglobin, suggesting that it may have roles in both combating the host's immune system and providing nutrients for the flea. A cDNA clone encoding the 265 amino acid IgG degrading protease proenzyme was isolated. When expressed in a baculovirus/insect cell expression system, the recombinant protein had the same N-terminus as the processed 237 amino acid mature native protein and possessed IgG degrading activity indistinguishable from the native protein. Arch. Insect Biochem.     

抗甲肝病毒基因工程单抗分离纯化与鉴定

为克服血源免疫球蛋白制品的不足,开发了抗甲肝病毒基因工程单克隆抗体anti-HAV IgG。用无血清培养基培养rCHO工程细胞株,上清液经过rProtein A SFF亲和层析→脱盐→离子交换层析→超滤换液纯化后,所得anti-HAV IgG纯度达99%以上,比活性约100IU/mg,anti-HAV IgG活性回收率40%。所纯化的anti-HAV IgG分子量150kD,等电点8.4～9.3。免疫印迹实验证实anti-HAV IgG为人源全抗体分子。亲和层析介质rProtein A SFF确实存在亲和配基脱落问题,但通过后续纯化步骤可有效除去。在亲和层析过程中加入高盐清洗步骤,可有效降低宿主DNA残留量水平。对样品中自由巯基含量进行了测定,认为非还原电泳图谱中低分子量条带是由于抗体分子内存在自由巯基引起。用该工艺制备的anti-HAV IgG各项纯度检测指标均达到我国对基因工程产品的质量要求。     

Single amino acid substitution in the mouse IgG1 Fc region induces drastic enhancement of the affinity to protein A

The purification of monoclonal antibody sometimes requires a lot of time and involves complicated steps because of the poorer ability of mouse IgG to interact with protein A, or also with protein G, than IgGs from other species such as those of human and rabbit. To resolve this problem, we exchanged one or two amino acid residues of mouse IgG Fc region with that of human IgG. Three mutants (T252M, T254S and T252M-T254S) showed significant improvement in the affinity to protein A. The exchange of the threonine 252 residue to methionine (T252M) was most efficient. This result suggests that a direct and simple modification allows the efficient purification of monoclonal antibody and of fusion protein containing mouse IgG Fc region.     

A physicochemical study of protein G, a molecule with unique immunoglobulin G-binding properties

Protein G, an IgG-binding molecule, was prepared from the cell walls of a group G streptococcal strain, G-148. The protein could be extracted from the cells by papain digestion and purified by the sequential use of ion-exchange chromatography on DEAE-Sephadex, affinity chromatography on Sepharose-coupled human IgG, and gel chromatography on Sephadex G-200. Two protein bands with similar molecular weight, 34,000 and 36,000, were obtained when analyzing the pure protein G on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The yield using this purification scheme was 27% of the protein G solubilized from the cells or 70 micrograms/ml packed bacteria. The Stokes radius and frictional ratio of protein G were determined to 3.53 nm and 1.64, respectively, suggesting an elongated fibrous molecule. The protein did not contain any intrachain disulfide bonds. The amino acid composition of protein G was determined and was found to be different from that of protein A, the well known staphylococcal IgG-binding protein. The equilibrium constants of the reactions between protein G and human, rabbit, mouse, and goat polyclonal IgG, determined by Scatchard plots, ranged between 1 X 10(10) and 7 X 10(10), for rat polyclonal IgG 1.4 X 10(9), and human monoclonal IgG1, IgG2, IgG3, and IgG4 between 2 X 10(9) and 6 X 10(9). These affinity constants were always greater than the corresponding values for protein A. The binding between protein G and various polyclonal and monoclonal IgG was pH dependent between 2.8 and 10, strongest at pH 4 and 5, and weakest at pH 10.     

Structural and molecular basis for hyperspecificity of RNA aptamer to human immunoglobulin G

Potential applications for functional RNAs are rapidly expanding, not only to address functions based on primary nucleotide sequences, but also by RNA aptamer, which can suppress the activity of any target molecule. Aptamers are short DNA or RNA folded molecules that can be selected in vitro on the basis of their high affinity for a target molecule. Here, we demonstrate the ability of RNA aptamers to recognize--and bind to--human IgG with high specificity and affinity. An optimized 23-nucleotide aptamer, Apt8-2, was prepared, and was shown to bind to the Fc domain of human IgG, but not to other IgG's, with high affinity. Apt8-2 was observed to compete with protein A, but not with the Fcgamma receptor, for IgG binding. NMR chemical-shift analyses localized the aptamer-binding sites on the Fc subdomain, which partially overlaps the protein A binding site but not the Fcgamma receptor binding site. The tertiary structures of the predicted recognition sites on the Fc domain differ significantly between human IgG and other species of IgGs; this, in part, accounts for the high specificity of the selected aptamer. Apt8-2 can therefore be used as a protein A alternative for affinity purification of human IgG and therapeutic antibodies. Using Apt8-2 would have several potential advantages, raising the possibility of developing new applications based on aptamer design.     

IgG PURIFICATION USING AFFINITY FILTRATION WITH SULFAMETHAZINE-AFFINITY CARRIERS

Immunoglobulin G (IgG) antibodies are used extensively for analytical, diagnostic, and therapeutic applications. However, there are some disadvantages to purify IgG antibodies by protein A and G affinity chromatography. Therefore, it is necessary to find an effective alternative and nonchromatographic method to purify IgG. Dextran microparticles were activated and coupled with sulfamethazine to form sulfamethazine-affinity carriers. Then the carriers were used to purify IgG by affinity filtration. Quantitative and qualitative determination proved that sulfamethazine would successfully bond to the surface of dextran microparticles with a density of 85.5 μmol/g (wet). Affinity carriers were proved to withstand high shear force and reveal rare sulfamethazine leakage under filtration conditions between pH 3 to 11. The maximum IgG-binding capacity of affinity carriers was 8.03 mg IgG/g (wet). The affinity filtration process obtained a recovery yield above 80% and purity above 90%. Thus, this work involved in both the advantages of membrane filtration and affinity purification. The results, for the first time, proved that it is possible to use the small ligand sulfamethazine for affinity filtration of IgG. It is an attractive alternative to conventional protein A or G affinity chromatography.     

Thermodynamic Stability and Functional Activity of Tumor-Associated Antibodies

Tumor-associated antibodies of human IgG1 subclass were eluted from cell-surface antigens of human carcinoma cells and studied by differential scanning calorimetry and binding to local conformational probes, protein A from Staphylococcus aureus and a monoclonal antibody targeted to the CH2 domain of the Fc fragment. At pH 2.0-7.0, we observed virtually identical enthalpies of thermal unfolding for IgG1 from normal human sera and tumor-associated IgG1. The exact values of calorimetric enthalpy (h) at pH 7.0 were 6.1 and 6.2-6.3 cal/g for IgG1 from normal serum and IgG1 from carcinoma cells, respectively. The affinity constants of protein A binding to the CH2–CH3 domain interface demonstrated differences between serum IgG1 and tumor associated IgG1 that did not exceed 3-8-fold. The binding affinity toward the anti-CH2 monoclonal antibody determined for serum IgG1 and IgG1 from carcinoma cells differed not more than 2.5-fold. The thermodynamic parameters of IgG1 from carcinoma cells strongly suggest that protein conformational stability was essentially unaltered and that the Fc fragment of the tumor-derived IgG1 preserved its structural integrity.     

G蛋白亲和色谱法纯化动物血清、抗体效果比较

比较 Hitrap G蛋白 Sepharose亲和色谱系统对不同动物血清或腹水的纯化效果 ,为抗体纯化提供依据。结果显示 ,G蛋白对不同动物血清 Ig G吸附能力不同 ,体现在单位体积抗体回收量明显不同 ,这一特点与 A蛋白亲和色谱系统相似。该方法简便快速 ,纯化抗体纯度高 ,免疫活性好 ,色谱柱可反复使用多次     

Engineered protein a for the orientational control of immobilized proteins

This work describes the genetic engineering and characterization of a histidine-tagged fragment of protein A. The histidine tag results in the site-selective immobilization of the protein A receptor and the preservation of its high ligand affinity when immobilized on solid supports. The fragment was expressed at high yield in E. coli and purified to homogeneity. When selectively immobilized to histidine binding matrices, the protein A fragment exhibits high affinity for soluble IgG. We further demonstrate from adsorption isotherms that the receptor exhibits a homogeneous, high affinity population at densities where steric crowding between large ligands does not affect the apparent receptor affinity. This engineered receptor is appropriate for a range of applications including sensor design or those using immobilized Fc-tagged proteins.