A new method for affinity chromatography of heme-binding proteins: Synthesis and characterization of hematin- and hematoporphyrin-agarose

Two new affinity columns, using hematin and hematoporphyrin as ligands, have been prepared. Both were made by first attaching 1,6-diaminohexane to Sepharose 4B by the cyanogen bromide procedure and then coupling the porphyrins to the free amino groups of this arm with carbodiimide. This second reaction was done in dimethylformamide to increase the solubility of the porphyrins at pH 4.7. This resin was then washed extensively with dimethylformamide to remove all of the unreacted porphyrin. The new affinity columns are able to bind apoglobin, albumin, and hemopexin, which demonstrates their ability to purify heme-binding proteins. The proteins could be removed by washing the column with a deforming buffer, such as 8 m urea or 0.1 m sodium citrate buffer at pH 4. Neither lysozyme nor hemoglobin bound to these resins demonstrating that the absorbants are specific for apo heme-binding proteins.     

The transformation-sensitive heat shock protein (hsp47) binds specifically to Fetuin

The transformation-sensitive heat shock protein of Mr = 47,000 (hsp47) has been shown to bind to collagen and gelatin. We examined the binding specificity of hsp47. The binding of hsp47 to gelatin-Sepharose 4B was competitively inhibited by fetuin as effectively as by gelatin or collagen, whereas a variety of other proteins tested had no effect. Fetuin-coupled Sepharose 4B was found to bind hsp47 even at high ionic strength, but the complex was dissociated at pH less than or equal to 5.5.)     

Hemoglobin & serum albumin: salt-mediated hydrophobic chromatography.

The binding of pure human serum albumin and pure human hemoglobin to L-phenylalinine Sepharose and aniline Sepharose columns, two chromatographic columns of differing hydrophobicity, has been investigated for various concentrations of ammonium sulfate salts.The binding of hemoglobin at a lower ammonium sulfate concentration than albumin in both hydrophobic support systems parallels the solubility and precipitation characteristics of these two proteins in solution and mirrors the phenomenon of salting out of proteins in solution. Both hemoglobin and albumin bind at lower concentrations on aniline Sepharose than on L-phenylalanine Sepharose, reflecting the greater efficiency of binding by the more hydrophobic support matrix.     

Evaluation of CNBr, FMP and hydrazide resins for immunoaffinity purification of factor IX.

The American Red Cross has developed an immunoaffinity chromatography method to purify human coagulation Factor IX to high levels of purity for therapeutic treatment of hemophilia B. The resin currently used in this process is Sepharose CL2B, a cross-linked 2% agarose, which is activated with cyanogen bromide to immobilize an anti-Factor IX monoclonal antibody. This study evaluated two alternative resins and coupling chemistries, a synthetic polymer bead activated by 2-fluoro-1-methyl-pyridinium toluene 4-sulfonate (FMP) and a cross-linked 2% agarose bead with free hydrazide groups for site-specific coupling. The cyanogen bromide and FMP chemistries immobilize the monoclonal antibody in a random orientation. In hydrazide coupling, the monoclonal antibody is immobilized by the non-antigen-binding part of the molecule which, theoretically, should increase the amount of immobilized monoclonal antibody able to bind antigen. To examine this, the capacity of the resins to bind Factor IX and the purity and recovery of Factor IX eluted from the resins were measured. The FMP-activated resin exhibited the lowest capacity, binding only 2% of the Factor IX feed. Sepharose CL2B bound 87% of the loaded protein, while the hydrazide resin bound 43%. These results suggest that (a) hydrazide activation may be insufficient to orient monoclonal antibody and (b) other factors such as steric hindrances and diffusional resistances during immobilization may be important. Neither of the other resins tested demonstrated improved performance compared with cyanogen bromide-activated Sepharose CL2B for the immunoaffinity purification of Factor IX.     

Inactivation and reactivation of horseradish peroxidase immobilized by various procedures.

Horseradish peroxidase (HRP) immobilized by coupling the amino acid side chain amino groups or carbohydrate spikes to the matrix has been studied for its resistance to heat, urea-induced inactivation and ability to regain activity after denaturation in order to understand the influence of the nature of immobilization procedure on these processes. The various immobilized preparations were obtained and their properties studied: Sp-HRP was obtained by direct coupling of HRP to cyanogen bromide-activated Sepharose, Sp-NHHRP by coupling periodate oxidized and diamine-treated enzyme to the cyanogen bromide activated Sepharose, SpNH-COHRP by coupling periodate-treated enzyme to amino-Sepharose and SpCon A-HRP by binding of the enzyme on Con A-Sepharose. All the immobilized preparations exhibited higher stability against heat-induced inactivation as compared to the native HRP. Sp-NHHRP was most stable followed by Sp-HRP, SpNH-COHRP and SpCon A-HRP. Sp-NHHRP was also superior in its ability to regain enzyme activity after thermal denaturation, although Sp-HRP regained maximum activity after urea denaturation. Inclusion of Ca2+ was essential for the reactivation of all preparations subsequent to denaturation by urea.     

Controlled coupling of mildly reduced proteins to Sepharose gelatin by heterobifunctional reagent

The heterobifunctional reagent N-succinimidyl 3-(2-pyridyldithio) propionate was utilized for controlled coupling of mildly reduced BSA and lysozyme to Sepharose gelatin to prepare immunoabsorbents. Each reaction step was examined and quantitated. The free amino groups on gelatin after coupling gelatin to cyanogen bromide-activated Sepharose as well as the number of 3-(2-pyridyldithio) propionyl groups on Sepharose gelatin were quantitated. Coupling of mildly reduced BSA as well as lysozyme to PDP-Sepharose gelatin occurred through sulfhydryl-disulfide exchange and permitted the formation of an immunoabsorbent. The immunoabsorbents were capable of binding the respective antibody and the eluted antibodies were pure and free of plasma proteins.     

A new approach (cyano-transfer) for cyanogen bromide activation of Sepharose at neutral pH,which yields activated resins,free of interfering nitrogen derivatives

A new approach for the reaction of Sepharose with cyanogen bromide is described, using triethylamine as a “cyano-transfer” reagent. An optimized procedure for activation at neutral pH was developed. This procedure requires only about 5% of the usual amount of cyanogen bromide. Activated resins are free of imidocarbonates and carbamates, containing only active cyanate esters. Extremely high coupling capacities (75 μmol ligand/g wet Sepharose 4B) can be obtained using this method.     

Analysis of histidine-containing dipeptides, polyamines, and related amino acids by high-performance liquid chromatography: application to guinea pig brain.

A procedure is described for coupling wheat germ agglutinin to cyanogen bromide-activated Sepharose to yield a lectin affinity column of high capacity. Covalent linkage of the lectin to the insoluble matrix is carried out in the presence of a mixture of β-1,4-linked N-acetylglucosamine oligosaccharides prepared from chitin. The lectin-affinity column specifically recognizes glycoproteins containing N-acetylglucosamine residues with the capacity of binding 0.6–1.0 mg of ovomucoid per milliliter of gel. The affinity column is stable (as determined by ovomucoid binding) and shows little loss in binding capacity or specificity after repeated usage. Important characteristics for the use of this column to purify glycoproteins are described.     

Assessment of the use of cyanogen bromide-activated Sepharose in analytical and preparative immunoadsorption

Procedures are described for the analytical and preparative purification of antigens based on their specific interaction with their complementary antibody immunoadsorbents prepared from cyanogen bromide-derivatized macroporous agarose matrices. In principle, the antigen to be purified in the affinity chromatography/immunoadsorption process should bind specifically and reversibly to the attached antibody, while other proteins pass through unretarded. In the case of tight binding, elution of the antigen is achieved by the use of eluting solutions of very high or very low pH, or with the use of chaotropic solutions such as 3 m KSCN. The performance of immunoadsorbents prepared from Sepharose 4B have been studied with the aim of improving the efficient utilization of immunoadsorption techniques. As a model, human serum was applied serially to several columns of Sepharose 4B sheep anti-human IgG which were then subjected to a number of successive adsorption/desorption cycles. Loading the columns with increasing amounts of serum showed that the performance was best when the antigen load was approximately threefold the ideal binding capacity. By limiting the amount of immobilized protein and carefully controlling the antigen load, significant improvements in yield and purity have been achieved. Antigen loads of threefold the potential binding capacity of the immunoadsorbent column results in the optimal yield of antigen with high purity and significant concomitant reduction in non-specific interference from other serum proteins. The non-specific adsorption which is an inherent problem and which leads to considerable inactivation of the covalently coupled antibody is highlighted. Although the popularity of such matrices is probably unsurpassed, it is clear that use has been made of them very frequently without an examination of quantitative aspects or side reactions.     

Preparation and Properties of an Immunosorbent Column Specific for the Myelin Basic Protein

Abstract: An immunosorbent column specific for the myelin basic protein (BP) was prepared by coupling purified anti-BP antibodies to cyanogen bromide (BrCN)-activated Sepharose 4B. The BP-immunosorbent column bound BP between pH 4.5 and pH 6.8. In its working range the column bound approximately 400-475 μg of BP at pH 6.8 and 250 μg at pH 4.5 with recoveries of 72-77%. The BP-immunosorbent column could effectively separate BP from simple mixtures of BP and proteins of similar size and charge and from acid extracts of bovine brain. The results indicate that the BP-immunosorbent column can be used to isolate BP from a mixture of proteins and may be adapted for use in the small-scale purification of the myelin basic proteins involving a minimum number of steps.     

Temperature-sensitive binding of solid phase C1q to aggregated human immunoglobulin G

The first component of complement (C1q) coupled to Sepharose by cyanogen bromide was found not to bind aggregated human gamma-globulin or immune complexes at room temperature, whereas at 4 degrees C binding was nearly complete. The temperature sensitivity of solid phase C1q binding was reversible. Elution of aggregated human gamma-globulin bound at 42 degrees C was possible by raising the temperature to 23 degrees C. However, free C1q or C1q adsorbed onto polystyrene balls could bind immune complex-like material at both 23 and 4 degrees C. The conformational restraints of C1q covalently coupled to a solid support may not allow functional activity at elevated temperatures.     

Affinity chromatography of fibrinogen on Lens culinaris agglutinin immobilized on CNBr-activated sepharose: study of the active groups involved in nonspecific adsorption

Fibrinogen binds specifically to Lens culinaris agglutinin coupled to CNBr-activated Sepharose. However, a fraction of the retained fibrinogen remains tightly bound to the gel and is eluted only by electrophoretic desorption. The irreversible binding of fibrinogen results from the interaction of fibrinogen specifically bound to the immobilized lectin with some reactive groups still present on the Sepharose matrix. Therefore, the active groups present on lectin-Sepharose after different treatments and their influence on the irreversible binding of fibrinogen have been studied. After the coupling step some cyanate esters remain on the gel, but they are neutralized under all the conditions studied. In addition, imidocarbonates formed under the basic conditions used to activate Sepharose, and carbonates resulting from acid treatment of the gel, are also present. Carbonates seem to be the main active groups involved in the irreversible binding of fibrinogen to lectin-Sepharose. Imidocarbonates also contribute to the nonspecific binding, although to a lesser extent than carbonates. Treatment of CNBr-activated Sepharose with 0.1 M HCl prior to the coupling step and neutralization, after coupling, with 0.1 M ethanolamine, pH 9.5, for 24 h at room temperature reduce the nonspecific binding to less than 9% of the fibrinogen fraction retained by the column. This percentage is appreciably smaller than that obtained by neutralization for 2 h at room temperature with either 0.1 M Tris-HCl, pH 8.0 (congruent to 66%), or 1 M ethanolamine, pH 9.0 (congruent to 23%).     

Preparation of a stable folate-sepharose complex for affinity chromatography.

A stable folic acid affinity gel has been developed for the purification of nanograms of protein that bind folic acid or its derivatives. The affinity gel was prepared by first coupling folic acid covalently to bovine serum albumin, followed by covalent coupling of the albumin to p-benzoquinone-activated Sepharose. After the albumin-folic acid complex was formed, it was treated with charcoal to remove ionically bound folate which would otherwise elute from the gel and decrease the recovery of the binding protein. The p-benzoquinone activation resulted in a more stable binding of the albumin to the Sepharose.     

The isolation of lectins on acid-treated agarose.

The ability of several D-galactose and N-acetyl-D-galactosamine-binding lectins to bind to Sepharose was investigated. Lectins from soybean, Wistaria floribunda, Bauhinia purpurea alba, and Sophora japonica could be isolated by affinity chromatography on acid-treated Sepharose 6B. These lectins would not bind to untreated Sepharose 2B, 4B, and 6B. The binding of B. purpurea alba and S. japonica was temperature-dependent. The S. japonica lectin would bind only at high pH. Ricinus communis toxin also showed a temperature-dependence of binding; acid-treated Sepharose 6B was a better affinity support for the toxin than was untreated Sepharose 4B Lectins from lima bean, Dolichos biflorus, and kidney-bean phytohemagglutinin did not bind to Sepharose under any of the conditions studied.     

Immobilized hemin affinity chromatography as a probe for proteins having potentiality to bind with heme

After Sepharose 4B polymer beads were activated by using epichlorohydrin, hemin was binded with them to prepare an immobilized hemin affinity chromatography column. The coupling rate of this column was very high, more than 0.25mg hemin could be fixed by 1g of wet Sepharose 4B beads. The column equilibrated with deionized water and eluated with pH 3.0 NaAc-HAc buffer was applied to capture the proteins in human serum, earthworm body and Bacillus subtilis cells. Three polypeptides in human serum were captured, one of which was verified as serum albumin after comparison to the control. At least one polypeptide in earthworm body, two in Bacillus subtilis cells displayed the powerful binding specificity to hemin. Our experiments demonstrated that the immobilized hemin affinity chromatography was available as a probe for some proteins having potentiality to bind with heme.     

Interactions of thrombospondin with extracellular matrix proteins: selective binding to type V collagen

Thrombospondin (TS), a protein first described in platelets, was recently shown to be synthesized and secreted by endothelial cells, fibroblasts, and smooth muscle cells. The presence of TS in the extracellular matrix of cultured cells has prompted us to examine the associations of this protein with matrix macromolecules. Interactions of TS with both matrix and serum proteins were tested using an enzyme- linked immunosorbent assay. With this assay we assessed the binding of TS in solution to proteins adsorbed to polystyrene microtiter plates. Among collagens, platelet TS bound to type V but not to types I, III, or IV. This selective interaction was confirmed in experiments using proteins linked to cyanogen bromide-activated Sepharose. TS released from platelets in response to thrombin activation, as well as that secreted by endothelial cells in culture, bound to type V but not to type I collagen-Sepharose. No binding was observed to denatured type V collagen-Sepharose. The binding region for type V collagen was located in a chymotrypsin-produced fragment of TS with chains of Mr = 70,000, after reduction. Interactions of TS with a number of other proteins, including fibronectin, fibrinogen, and laminin, could be demonstrated using the enzyme-linked immunosorbent assay technique but the interpretation of these findings is difficult since comparable binding to protein-Sepharose was not always observed. Our findings suggest that both the extravascular distribution and function of TS in vivo may involve an interaction with type V collagen.     

Influence of type of linkage and spacer on the interaction of beta-galactoside-binding proteins with immobilized affinity ligands

Affinity chromatography provides a powerful tool for isolation of carbohydrate-binding proteins. However, the choice of the ligand and spacer has an important impact on effectiveness. The influence of several different ligands on qualitative and quantitative aspects of the purification of two beta-galactoside-specific lectins has been evaluated. Sepharose was modified by coupling four types of neoglycoproteins (galactosylated or lactosylated bovine serum albumin with increasing sugar content) and two naturally occurring asialoglycoproteins at similar densities. Carbohydrate ligands at essentially equal density were made accessible to the lectins by seven commonly used methods. The yield of mistletoe lectin was high when lactosylated neoglycoproteins were used for separation. For these resins the sugar incorporation exceeded 10 sugar groups per protein carrier molecule. The yield was similarly high with the asialoglycoproteins and with lactose; the sugar was coupled to the resin as a p-aminophenyl derivative or by means of divinyl sulfone activation. An epoxy group in linkages of galactose or lactose decreased the binding capacity. A quantitatively similar degree of protein yields was obtained for the beta-galactoside-binding protein of bovine heart, although different proteins were obtained when neoglycoproteins were used as ligand. The nature of the affinity ligand in lectin purification can increase the yield and may also influence the profile of the carbohydrate-binding proteins.     

Regulation by Mg2+ and Ca2+ of mitochondrial membrane integrity: study of the effects of a cytosolic molecule and Ca2+ antagonists.

The coupling of aliphatic amines to agarose by the cyanogen bromide reaction yields isourea linkages which are positively charged at pH 7. The presence of these cationic sites in affinity gels causes significant non-specific adsorption of proteins. Serum albumin was found to bind to a number of derivatized gels which possessed these charged groups. The use of adipic dihydrazide as the leash moiety yielded affinity gels which were noncharged at pH 7. Serum albumin failed to adsorb to these gels. Beta-galactosidase from Escherichia coli was found to be sensitive to both ionic and hydrophobic groups in an affinity gel. A sample of active-site inhibited enzyme was found to bind to an affinity gel which contained both the cationic isourea and a phenyl structure in the leash. Thus it was concluded that the affinity purification of this enzyme has yet to be demonstrated. These studies dictate against the use of salt and pH gradients to desorb enzymes from affinity sorbents.