New methods of protein purification. Affinity ultrafiltration.

This review describes a recently developed method for protein purification-affinity ultrafiltration. In affinity ultrafiltration, the protein to be purified is complexed with a macroligand composed of a soluble polymer or an insoluble microparticle with covalently bound, target protein-specific affinity ligands. The complex is trapped by an ultrafiltration membrane, whereas unwanted proteins pass through the membrane. The unwanted proteins are removed from the system by the carrier liquid. The system is then supplemented with an agent eluting the target protein by dissociating it from the microligand complex. The purified protein then passes the membrane, while the macroligand is trapped by it. The macroligand can be re-used after regeneration. Affinity ultrafiltration has a number of advantages over other protein purification techniques: 1) commercial availability of ultrafiltration systems with various high-productivity designs; 2) availability of presynthesized macroligands, which can be supplemented with additional, easily manufactured, commercial latex-based macroligands; 3) rapid separation of large solution volumes; 4) repeated use of equipment, enabling consecutive purification of different proteins; 5) simple scale-up and automation procedures.     

DNA purification by triple-helix affinity precipitation

Recent advances in DNA-based medicine (gene therapy, genetic vaccination) have intensified the necessity for pharmaceutical-grade plasmid DNA purification at comparatively large scales. In this contribution triple-helix affinity precipitation is introduced for this purpose. A short, single-stranded oligonucleotide sequence (namely (CTT)(7)), which is capable of recognizing a complementary sequence in the double-stranded target (plasmid) DNA, is linked to a thermoresponsive N-isopropylacrylamide oligomer to form a so-called affinity macroligand (AML). At 4 degrees C, i.e., below its critical solution temperature, the AML binds specifically to the target molecule in solution; by raising the temperature to 40 degrees C, i.e., beyond the critical solution temperature of the AML, the complex can be precipitated quantitatively. After redissolution of the complex at lower temperature, the target DNA can be released by a pH shift to slightly alkaline conditions (pH 9.0). Yields of highly pure (plasmid) DNA were routinely between 70% and 90%. Non-specific co- precipitation of either the target molecule by the non-activated AML precursor or of contaminants by the AML were below 7% and presumably due to physical entrapment of these molecules in the wet precipitate. Ligand efficiencies were at least 1 order of magnitude higher than in triple-helix affinity chromatography.     

Preliminary studies on the purification of a monoclonal antibody by affinity precipitation with Eudragit S-100

A simple procedure for the purification of an IgG-type monoclonal antibody by affinity precipitation using Eudragit S-100 is presented. The ligand, a microbial lipase previously used as antigen, was coupled to the polymer at a concentration of 40 mg lipase/g Eudragit. This macroligand was reversibly precipitated by manipulating the pH at values higher and lower than 4.8. The effects of polymer concentration and dilution of hybridoma culture supernatant on the overall precipitation process were evaluated. The best purification factor was achieved with a polymer concentration of 0.1% (w/v) and a supernatant dilution of 1:3. The preliminary studies reported here enabled the purification of a monoclonal antibody in one step with an activity yield (by ELISA) of 50%-55% and a purification factor of ca 6.     

Affinity adsorption of lysozyme on a macroligand prepared with Cibacron Blue 3GA attached to yeast cells

The objective of this study was the development of affinity adsorbent particles with the appropriate characteristics to be applied in protein purification using the affinity ultrafiltration method. To prepare affinity macroligands Cibacron Blue 3GA, as a ligand molecule, was immobilized by covalent bonding onto yeast cell walls, the support material or matrix. The maximum attachment of the ligand to the matrix was 212 μmol/g (ligand dry weight/yeast dry weight). Lysozyme was selected as the protein model for the adsorption studies. Its adsorption onto the matrix without ligand and matrix with attached ligand were investigated batch-wise. The adsorption equilibrium isotherms appeared to follow a typical Langmuir isotherm. The maximum adsorption capacity (q(m)) of the Cell-Cibacron macroligand for lysozyme was 110 mg/ml of wet macroligand. The adsorbent was also employed for the separation of lysozyme from hen egg white. High purity lysozyme was obtained.     

Recognition of oxidatively modified bases within the biotin-binding site of avidin

Oxidative damage of DNA results in the formation of many products, including 8-oxodeoxyguanosine, which has been used as a marker to quantify DNA damage. Earlier studies have demonstrated that avidin, a protein prevalent in egg-white and which has high affinity for the vitamin biotin, binds to 8-oxodeoxyguanosine and related bases. In this study, we have determined crystal structures of avidin in complex with 8-oxodeoxyguanosine and 8-oxodeoxyadenosine. In each case, the base is observed to bind within the biotin-binding site of avidin. However, the mode of association between the bases and the protein varies and, unlike in the avidin:biotin complex, complete ordering of the protein in this region does not accompany binding. Fluorescence studies indicate that in solution the individual bases, and a range of oligonucleotides, bind to avidin with micromolar affinity. Only one of the modes of binding observed is consistent with recognition of oxidised purines when incorporated within a DNA oligomer, and from this structure a model is proposed for the selective binding of avidin to DNA containing oxidatively damaged deoxyguanosine. These studies illustrate the molecular basis by which avidin might act as a marker of DNA damage, although the low levels of binding observed are inconsistent with the recognition of oxidised purines forming a major physiological role for avidin.     

The use of the 2-iminobiotin-avidin interaction for the selective retrieval of labeled plasma membrane components

A general method for the selective retrieval of surface labeled plasma membrane components had been devised. The basis of the technique is the covalent attachment of compounds containing 2-iminobiotin, the cyclic guanidino analog of biotin, onto the cell surface proteins and the use of immobilized avidin to recover the labeled components uncontaminated by other cytosolic and membrane components. The pH-dependent interaction of 2-iminobiotin with avidin makes recovery possible. At high pH the free base form of 2-iminobiotin retains the high affinity specific binding to avidin characteristic of biotin, whereas at acidic pH values, the salt form of the analog interacts poorly with avidin. Model studies on the interaction of 2-iminobiotinylated proteins with avidin-Sepharose 4B show that for tight binding to the affinity matrix, the pH of the column must be 9.5 or higher, that a single 2-iminobiotin group is sufficient for binding, and that proteins with different extents of labeling behave similarly when the low pH buffer is applied. When intact human erythrocytes were sequentially labeled with periodate and 2-iminobiotin hydrazide and the Triton X-100-solubilized plasma membrane proteins were subjected to affinity isolation, the major sialoglycoproteins, periodic acid-Schiff (PAS) 1, PAS 2, and PAS 3, plus two proteins with apparent molecular weights higher than band 3 were retrieved. The recovery of these proteins is not due to a nonspecific adsorption to the affinity matrix.     

DNA fractionation by two-phase partition with aid of a base-specific macroligand

The application of a GC (guanosine-cytidine)-specific DNA macroligand, consisting of a GC-specific phenazinium dye covalently bound to one end of polyethylene glycol (6000–7500 $\text{M}{}_{\mathrm{r}}\text{)}$, for preparative DNA fractionation with base composition is described. The fractionation is performed in aqueous two-phase systems formed by polyethylene glycol and dextran in which the macroligand shows a strong affinity for the upper phase and shifts the partition coefficient of the DNA as a function of its GC content. Examples of fractionations by simple extractions and countercurrent distributions of calf thymus DNA over a few steps are given.     

Synthesis and characterization of soluble concanavalin A oligomer

Concanavalin A, (Con A, MW 26,500/monomer unit) was crosslinked with glutaraldehyde to form soluble, high-molecular-weight (larger than MW 300,000) Con A Oligomers. After filtration to remove insoluble and low-molecular-weight portions (below 300,000 daltons), the size and molecular-weight distribution were characterized by laser light scattering and gel-filtration chromatography. The molecular-size determined by laser light scattering ranged from 870 to 4070 A, while the molecular weight determined by gel chromatography ranged from 6 x 10(5) to higher than 2 x 10(6) daltons. The affinity and kinetics of Con A oligomer binding to polysaccharide (glycogen) were evaluated by precipitation test and turbidity development, respectively. The binding with glycogen was strongest at neutral pH and showed similar activity to unmodified Con A molecules. The binding constants of alpha-D-glucose and succinyl-aminophenyl alpha-D glucopyranoside-insulin to Con A oligomer were 1.0 x 10(3)M(-1) and 4.5 x 10(4)M(-1), respectively and the binding capacity of the oligomer was nearly 85% to 95% of monomeric Con A. The complexes of saccharides and soluble Con A oligomer were stable for at least 7 days. (c) 1993 Wiley & Sons, Inc.     

Application of reversible biotinylated label for directed immobilization of synthetic peptides and proteins: isolation of ligates from crude cell lysates

Chaperonin 10 protein from Rattus norvegicus (Rat cpn10) has been reported to bind chaperonin 60 from Escherichia coli (GroEL) in an ATP-dependent manner. Chemically synthesized Rat cpn10 was immobilized in a defined orientation to agarose-bound monomeric avidin using a reversible biotinylated affinity label ( 1 ), attached to the N^α-terminal residue. The resulting affinity chromatographic matrix was then used to isolate binding proteins from a crude cell lysate. Following affinity separation the bound ligand and ligate was released by treatment with organic base. Rat cpn10 was prepared using a highly effective synthetic protocol involving HBTU/HOBt activation and capping with N-(2-chlorobenzyloxycarbonyloxy) succinimide to terminate unreacted amino groups. The biotinylated Fmoc-based molecule ( 1 ) was introduced specifically onto the N^α-terminal amino acid as the succinimidyl carbonate, before final cleavage and deprotection of side-chain protecting groups using a low-TFMSA/high-HF procedure. Crude biotinylated Rat cpn10 (Rat cpn10+ 1 ) was immobilized on monomeric avidin with a binding efficiency of approximately 75% and unlabelled truncated/capped impurities eluted off the column with buffer. The biotinylated Rat cpn10–avidin affinity matrix was then used to isolate GroEL from a crude cell lysate. The identity of the purified protein was confirmed by SDS–PAGE and binding to a specific anti-GroEL monoclonal antibody (MoAb). These results extend the applicability of the biotinylated label ( 1 ), providing a reversible non-covalent anchor for immobilization of peptide and protein ligands, thus simplifying isolation of ligates and enabling recovery of synthetic material under mild conditions. © 1997 European Peptide Society and John Wiley & Sons, Ltd.     

Hairpin and duplex formation in DNA fragments CCAATTTTGG, CCAATTTTTTGG, and CCATTTTTGG: a proton NMR study

Three DNA fragments, CCAATTTTGG (1), CCAATTTTTTGG (2), and CCATTTTTGG (3), were studied by proton NMR spectroscopy in aqueous solution. All these oligodeoxyribonucleotides contain common sequences at the 5' and 3' ends (5'-CCA and TGG-3'). 2 as well as 3 forms only hairpin structures with four unpaired thymidylyl units, four and three base pair stems, respectively, in neutral solution under low and high NaCl concentrations. At high salt concentration the oligomer 1 forms a duplex structure with -TT- internal loop. On the other hand, the same oligomer forms a stable hairpin structure at low salt and low strand concentrations at pH 7. The hairpin structure of 1 has a stem containing only three base pairs (CCA.TGG) and a loop containing four nucleotides (-ATTT-) that includes a dissociated A.T base pair. The two secondary structures of 1 coexist in an aqueous solution containing 0.1 M NaCl, at pH 7. The equilibrium shifts to the hairpin side when the temperature is raised. The stabilities and base-stacking modes of all three oligonucleotides in two different structures are reported.     

Multistage affinity cross-flow filtration: process optimization

The recovery yield (REC) and productivity (PRD) are used as objective functions to optimize the multistage affinity cross-flow filtration (mACFF) process. The effects of the operating conditions such as feed loading volume (Q _L ⁺), total protein concentration and target protein purity in the feeding broth are analyzed. For higher affinity system or by a mACFF process with larger number of stages as well as more macroligand loading, there is a critical value of Q _L ⁺ below which the REC keeps constant and maximal. This maximal value of REC is affected by the stage number as well as macroligand loading of the mACFF process and the affinity system (i.e., the binding constant of the target protein to its macroligand), but independent of the feeding broth properties (i.e., total protein concentration and target protein purity) and membrane permeability. An optimum of Q _L ⁺ exists to give a maximum of PRD. The optimal Q _L ⁺ is somewhat larger than the critical Q _L ⁺ value below which REC keeps constant. The maximum of PRD is raised by increasing the stage number and macroligand loading of the mACFF process, affinity binding constant, and total protein concentration as well as target protein purity in the feeding broth, but reduced by increasing the membrane rejection coefficient (R). However, it is encouraging that the decrease of the maximal PRD is less significant when R is less than 0.5. Therefore, if it is not possible to find a membrane that is completely permeable to proteins and at the same time completely impermeable to the macroligand, a membrane with R less than 0.5 may be selected to obtain a larger PRD. The results obtained in this work give further predictive understanding of the mACFF technique, and will be useful to the process design.     

Purification of histidine-tagged single-chain Fv-antibody fragments by metal chelate affinity precipitation using thermoresponsive copolymers

Metal chelate affinity precipitation (MCAP) has been successfully developed as a simple purification process for proteins that have affinity for metal ions. The present lack of widespread applications for this technique as compared to immobilized metal affinity chromatography (IMAC) may be related to the scarcity of well-characterized metal affinity macroligands (AML) and their applications to the number of different purification systems. In the present work we describe a detailed study of a new purification system using metal-loaded thermoresponsive copolymers as AML. The copolymers of vinylimidazole (VI) with N-isopropylacrylamide (NIPAM) were synthesized by radical polymerization with imidazole contents of 15 and 24 mol%. When loaded with Cu(II) and Ni(II) ions the copolymers selectively precipitated extracellularly expressed histidine-tagged single-chain Fv-antibody fragments (His(6)-scFv fragments) from the fermentation broth free from E. coli cells. Precipitation was induced by salt at mild temperatures and the bound antibody fragments were recovered by dissolving the protein-polymer complex in EDTA buffer and subsequent reprecipitation of the polymer. His(6)-scFv fragments were purified with yields of 91 and 80% and purification folds of 16 and 21 when Cu(II) and Ni(II) copolymers were used, respectively. The protein precipitation capacity of the Ni(II) copolymer showed a dependence on the VI concentration in the copolymer. The SDS-PAGE pattern showed significant purification of the antibody fragments.     

Simultaneous refolding/purification of xylanase with a microwave treated smart polymer

Affinity precipitation with a smart polymer, Eudragit S-100 (a methyl methacrylate polymer), was exploited for simultaneous refolding and purification of xylanase. Affinity precipitation consisted of this reversibly soluble-insoluble polymer-binding xylanase selectively. The complex was precipitated by lowering the pH and xylanase was eluted off the polymer using 1 M NaCl. For refolding experiments, the commercial preparation of Aspergillus niger xylanase was denatured with 8 M urea. Addition of microwave irradiated Eudragit S-100 and affinity precipitation led to recovery of 96% enzyme activity by refolding. Simultaneously, the enzyme was purified 45 times. Thermally inactivated preparation, when subjected to similar steps, led to 95% recovery of enzyme activity with 42-fold purification. The strategy has the potential for recovering pure proteins in active forms from overexpressed proteins, which generally form inclusion bodies in E. coli.     

Nonspecific staining of mast cells by avidin-biotin-peroxidase complexes (ABC)

A nonspecific staining of mast cells by avidin-biotinylated peroxidase complexes (ABC) has been observed and related to an ionic binding of the basic residues of avidin (isoelectric point at pH 10) and peroxidase to the sulphate groups of heparin. This affects the correct interpretation of the results of the immuno-peroxidase ABC procedure, especially in mast cells-rich areas such as the lymphoid tissues. The spurious staining can be prevented by using the ABC solution at pH 9.4 (instead of pH 7.6 as usually recommended): this high pH does not affect the previous binding of primary antibodies nor the affinity of avidin to biotin. The modified ABC procedure provides a clear background and a sharp specific staining and can be recommended for routine use.     

A modular design of low‐background bioassays based on a high‐affinity molecular pair barstar:barnase

High‐affinity molecular pairs provide a convenient and flexible modular base for the design of molecular probes and protein/antigen assays. Specificity and sensitivity performance indicators of a bioassay critically depend on the dissociation constant (K_D) of the molecular pair, with avidin:biotin being the state‐of‐the‐art molecular pair (K_D ～ 1 fM) used almost universally for applications in the fields of nanotechnology and proteomics. In this paper, we present an alternative high‐affinity protein pair, barstar:barnase (K_D ～ 10 fM), which addresses several shortfalls of the avidin:biotin system, including non‐negligible background due to the non‐specific binding. A quantitative assessment of the non?specific binding carried out using a model assay revealed inherent irreproducibility of the [strept]avidin:biotin‐based assays, attributed to the avidin binding to solid phases, endogenous biotin molecules and serum proteins. On the other hand, the model assays assembled via a barstar:barnase protein linker proved to be immune to such non‐specific binding, showing good prospects for high‐sensitivity rare biomolecular event nanoproteomic assays.     

The purification of avidin and its derivatives on 2-iminobiotin-6-aminohexyl-Sepharose 4B

The pH-dependent interaction between the cyclic guanidino analog of biotin, 2-iminobiotin, and avidin has been used in the design of an efficient affinity isolation system for avidin and its fluorescent and iodinated derivatives. Avidin and its derivatives are retained by a column of 2-iminobiotin-6-aminohexyl-Sepharose 4B at pH values between 9 and 11 and are specifically eluted from the column at pH 4. This affinity isolation procedure overcomes the harsh conditions, i.e., 6 m guanidine-HCl, pH 1.5, required to dissociate avidin from an immobilized biotin column.     

Preparation and Characterization of a pH-responsive Polymer that Interacts with Microbial Transglutaminase during Affinity Precipitation

Microbial transglutaminase (MTG) has been widely used in the food and pharmaceuticals industries. In this study, MTG was purified using affinity precipitation with an affinity polymer (P_MMDN-T), which was synthesized using a pH-responsive polymer (PMMDN) coupled with L-thyroxin as an affinity ligand. Interactions between MTG and P_MMDN-T were investigated using turbidimetric titration, zeta potential measurements, and low-field nuclear magnetic resonance (LF-NMR). We found different behaviors, architectures, and phase states of pH-dependent interactions between MTG and P_MMDN-T interactions. Binding energetics between MTG and P_MMDN-T were determined by isothermal titration calorimetry (ITC). The isoelectric point (pI) of the affinity polymer was 4.65 and was recovered with 96.7% efficiency after recycling the polymer three times. The optimal adsorption condition was 0.02 mol/L phosphate buffer (pH 6.0) with 1.0 mol/L NaCl at 30.0°C and a ligand density of 50.0 μmol/g. The maximum elution recoveries of total MTG were 98.44% (protein) with 92.19% (activity) using 0.02 mol/L pH 10.0 Gly-NaOH as the eluent.     

Protein complexation with acrylic polyampholytes

The interaction of dilute mixtures of proteins and ABC triblock methacrylic polyampholytes at different values of pH was investigated turbidimetrically. The onset of interaction was manifested by large changes in turbidity at certain critical pHs which lie close to the isoelectric points of the two interacting components. Protein precipitation yields in protein-polyampholyte binary mixtures followed the corresponding turbidity profiles and varied from 10% to 90%. The synthetic polyampholytes self-aggregate around their isoelectric point. The kinetics of precipitation of one of the same polymer with soybean trypsin inhibitor were studied, with turbidity-based characteristic times (exponential fit) of 2-3 min. The kinetics of precipitation of the protein-polymer mixture are slower than that of pure polymer because a small, but steady, long-term increase in turbidity is observed in the former case. The pH-dependence of the turbidity of binary mixtures of one protein and one synthetic polyampholyte, as well as a tertiary mixture of two proteins and one polyampholyte, were measured 30 min after the pH adjustment. The observations in these experiments along with the measured protein precipitation yields in the binary mixtures and the polyampholyte self-aggregation can be used for polymer removal and recycling. The latter constitutes a significant advantage over the use of homopolyelectrolytes which cannot easily be recycled. (c) 1994 John Wiley & Sons, Inc.     

Affinity precipitation of proteins by polyligands

A novel technique for affinity precipitation has been developed in which multimeric target proteins are precipitated as a result of network formation by polymer-conjugated ligands (polyligands). A polyligand precipitant for avidin was synthesized by conjugation of biotin to a polyacrylamide-based backbone. The effects of mixing conditions, ligand substitution frequency, and molecular weight on affinity precipitation were examined using the biotin-PAAm precipitant. Biotin was replaced by iminobiotin to study the effect of the ligand-protein dissociation constant o affinity precipitation. The iminobiotin-PAAm precipitant was also used to examine the reversibility of the precipitation and recovery of the target protein after precipitation. (c) 1993 Wiley & Sons, Inc.     

Disintegration of layer-by-layer assemblies composed of 2-iminobiotin-labeled poly(ethyleneimine) and avidin

A layer-by-layer thin film composed of avidin and 2-iminobiotin-labeled poly(ethyleneimine) (ib-PEI) was prepared and their sensitivity to the environmental pH and biotin was studied. The avidin/ib-PEI multilayer assemblies were stable at pH 8-12, whereas the assemblies were decomposed at pH 5-6 due to the low affinity of the protonated iminobiotin residue to avidin. The avidin/ib-PEI assemblies can be disintegrated upon addition of biotin and analogues in the solution as a result of the preferential binding of biotin or analogues to the binding site of avidin. The decomposition rate was arbitrarily controlled by changing the type of stimulant (biotin or analogues) and its concentration. The avidin/ib-PEI assemblies were disintegrated rapidly by the addition of biotin or desthiobiotin, whereas the rate of decomposition was rather slow upon addition of lipoic acid or 2-(4'-hydroxyphenylazo)benzoic acid. The present system may be useful for constructing the stimuli-sensitive devices that can release drug or other functional molecules.