Purification of mammalian arylsulfatase A enzymes by subunit affinity chromatography

Rabbit liver arylsulfatase A (arylsulfatase sulfohydrolase, EC 3.1.6.1) monomer was immobilized on cyanogen bromide-activated Sepharose-6MB and on Affi-Gel-10 under various experimental conditions in order to study the effects of variables in sulfatase monomer/oligomer subunit affinity chromatography. First, the number of reactive groups on activated Sepharose-6MB and Affi-Gel-10 was determined by a procedure involving spectrophotometric titration with L-tyrosine. After covalent coupling of sulfatase monomers to the gels, the enzyme binding capacities of the sulfatase subunit affinity gel matrixes were determined at pH 4.5. The maximum binding of free monomers from solution could be achieved when the Affi-Gel-10 protein monomer matrix was prepared at low degrees of covalent loading. The introduction of a batch technique for equilibration of the protein sample with the monomer affinity matrix also increased the efficiency of the subunit affinity gel in purification procedures. The effect of pH on the stability of the heterodimers formed between monomers of rabbit liver arylsulfatase A immobilized on Affi-Gel-10 and free monomers of arylsulfatase A enzymes from different tissues and organisms was studied using the batch technique. For all sulfatase A enzymes tested, the midpoint of the pH transition for subunit association was pH 6.2, suggesting that the amino acid residues involved in the dimerization are similar. The versatility of the Affi-Gel-10 monomer affinity matrix was further demonstrated by purifying 13 mammalian arylsulfatase A enzymes to homogeneity, as assessed by Sephacryl chromatography, native and SDS gel electrophoresis. The molecular weights of the homogeneous monomers and their peptide subunits were in the range of 110-180 KDa and 50-64 KDa, respectively. The amino acid compositions of these enzymes were also determined.     

The structural basis of anomalous kinetics of rabbit liver aryl sulfatase A

Rabbit liver aryl sulfatase A (aryl sulfate sulfohydrolase, EC 3.1.6.1) is inactivated during the hydrolysis of nitrocatechol sulfate and the rate of formation of turnover-modified aryl sulfatase A depends on the initial velocity of the enzymatic reaction. Organic solvents such as ethanol and dioxane favor the anomalous kinetic behavior. The turnover-modified enzyme can apparently be reactivated by arsenate, phosphate, pyrophosphate, and sulfate in the presence of nitrocatechol sulfate. The apparent dissociation constants of these ions in the reactivation of the enzyme are similar to their K_i values. Sulfite, which is a competitive inhibitor, does not reactivate the turnover-modified enzyme. Thus, all known activators are competitive inhibitors but not all competitive inhibitors are effective as activators. Inactivation of aryl sulfatase A during hydrolysis of ³⁵S-labeled substrate at pH values near the pH optimum (pH 5–6) is accompanied by the incorporation of radioactivity into the protein molecule and the turnover-modified enzyme is thereby covalently labeled. The stoichiometry of the incorporation of radioactivity corresponds to 2 g atom of sulfur per mole of enzyme monomer, or 1 g atom of sulfur per equivalent peptide chain. It is also shown that isolated turnover-modified rabbit liver aryl sulfatase A has lost approximately 76% of its secondary structure as compared to the native enzyme. The specific activity of the inactive enzyme is also decreased by 82%. Turnover-modified rabbit liver aryl sulfatase A is partially reactivated by sulfate ions in the presence of nitrocatechol sulfate. However, circular dichroism measurements and fluorescence spectra of the isolated “reactivated” turnover-modified enzyme indicate only a further loss of secondary structure. The specific activity of this “reactivated” enzyme is in fact decreased. The loss in secondary structure and the enzyme activity of the “reactivated” aryl sulfatase A is prevented in the presence of sulfate ions. Turnover-modified rabbit liver aryl sulfatase A behaves as a very fragile molecule.     

The monomer -- dimer association of rabbit lver aryl sulfatase A and its relationship to the anomalous kinetics.

The polymerization of aryl sulfatase A (aryl sulfate sulfohydrolase, EC 3.1.6.1) has been studied by frontal gel chromatography on Sephadex G-200 and Bio-Gel A-5m under various conditions of pH, ionic strength, and temperature. The aryl sulfatase A molecule exists as a monomer and as a dimer at pH 7.5 and pH 4.5, respectively. The extent of dissociation is markedly pH-, protein concentration-, and ionic strength-dependent. Only a small effect of temperature was observed. The enthalpy change (ΔH^o) for the dissociation was ?2.5 ± 1 kcal/mol at pH 5.5–5.6, and the entropy change for dissociation of the enzyme dimer to two monomeric units was ?47 cal mol^?1 deg^?1. Sulfate ion has little effect on the extent of dissociation of the enzyme at pH 5.6. The present studies suggest that the dissociation of rabbit liver aryl sulfatase A is regulated by the ionization of amino acid residues whose apparent pK is between pH 5 and 6. The driving force for the association of the subunits of the enzyme is primarily ionic and/or ionic/hydrogen bond formation. The small enthalpy change and the fact that dissociation is strongly favored by an increase in the ionic strength suggest that hydrophobic interactions play only a minor role in stabilizing the dimeric quaternary structure relative to the monomeric state. The monomeric form of the enzyme exhibits the anomalous kinetics often observed with sulfatase A but the dimer does not show anomalous kinetics. Since aryl sulfatase A is probably in the dimeric form in the lysosome, the anomalous kinetics of the enzyme are unlikely to be of physiological importance in the intact lysosome.     

Purification of an ammonium-inducible glutamate dehydrogenase and the use of its antigen affinity column-purified antibody in specific immunoprecipitation and immunoadsorption procedures

A modified five-step purification procedure was developed which gave an 80–87% yield of pure NADP-specific glutamate dehydrogenase (NADP-GDH) from Chlorella. The enzyme was shown to be composed of six identical subunits with alanine as the C-terminal amino acid. The purified enzyme was covalently coupled to CNBr-activated Sepharose-4B, and then the subunits were linked together with dimethyl suberimidate to make a stable antigen affinity column for purification of anti-NADP-GDH IgG from rabbit antiserum. When the subunits of the column-bound holoenzyme were not linked together, elution of the anti-NADP-GDH IgG resulted in a 50% loss of enzyme subunits from the column. This loss of subunits inactivated the column. The monospecific, affinity-purified anti-NADP-GDH IgG was used in an indirect immunoprecipitation procedure with purified sheep anti-rabbit IgG or in an indirect procedure with Staphylococcus Protein A Sepharose 4B to obtain a 95–98% recovery (by either procedure) of ³⁵S-labeled NADP-GDH from radioactive Chlorella cell homogenates. As shown by sodium dodecyl sulfate polyacrylamide gel electrophoresis, the [³⁵S]NADP-GDH recovered by these procedures was free of contaminating radioactive cellular proteins. When direct precipitation was used with the purified antibody, only an 85–90% recovery of the radioactive enzyme was obtained. Thus, the indirect procedures would be the ones of choice for measurements of the in vivo rates of synthesis and degradation of the NADP-GDH which comprises approximately 0.2% of the total soluble protein of Chlorella.     

Affinity chromatography of Ankistrodesmus braunii nitrate reductase using blue dextran-sepharose (author's transl)

Blue Dextran has been coupled covalently to Sepharose-4B to purify the enzymatic complex NAD(P)H-nitrate reductase (EC 1.6.6.2) from the green alga Ankistrodesmus braunii by affinity chromatography. The optimum conditions for the accomplishment of the chromatographic process have been determined. The adsorption of nitrate reductase on Blue Dextran Sepharose is optimum when a phosphate buffer of low ionic strength and pH 6.5-7.0 is used. Once the enzyme has been bound to Blue Dextran Sepharose, it can be specifically eluted by addition of NADH and FAD to the washing buffer. However, none of the nucleotides added separately is able to promote the elution of the enzyme from the column. The elution can be also achieved, but not specifically, by increasing the ionic strength of the buffer with KCl. These results have made possible a procedure for the purification of A. braunii nitrate reductase which led to electrophoretic homogeneity, with an overall yield of 70% and a specific activity of 49 units/mg of protein.     

Covalent modification as the cause of the anomalous kinetics of aryl sulfatase A.

Mammalian aryl sulfatase A enzymes are known to exhibit an anomalous kinetic behavior in which the enzyme becomes inactivated as it catalyzes the hydrolysis of substrate. Part of the activity of this inactive, turnover-modified form of the enzyme can apparently be restored by the simultaneous presence of substrate and sulfate ion. The present experiments, conducted with 2-hydroxy-5-nitrophenyl [³⁵S]sulfate (nitrocatechol sulfate), establish that the turnover-modified enzyme is covalently labeled. The stoichiometry of the incorporation of radioactivity corresponds to 2 g atom of ³⁵S per mole of enzyme monomer (each monomer of rabbit liver aryl sulfatase consists of two equivalent subunits). It is also shown that isolated, turnover-modified enzyme has lost 80% of its secondary structure when compared to the native enzyme. A commonly used sulfating agent, pyridine-sulfur trioxide complex brings about a similar loss of activity and of secondary structure.     

An oligodeoxynucleotide affinity column for the isolation of sequence specific DNA binding proteins.

A nucleic acid affinity matrix containing a short oligodeoxynucleotide ligand has been prepared as an example of a material which can be used for the rapid and effective isolation of sequence specific DNA binding proteins. Two complementary oligodeoxynucleotides have been employed, one of which contains a small 5'-spacer arm with a terminal thiol group. Using this terminal thiol group, the ligand can be covalently coupled to Tresyl-activated Sepharose 4B or Epoxy-activated Sepharose 6B via a thioether linkage. This approach allows the specific attachment of the nucleic acid ligand via its 5'-terminus to the insoluble matrix. The double stranded affinity material was obtained by annealing of the complementary DNA fragment. As an example, we have used an eicosomer affinity column containing the sequence d(GAATTC) for the isolation of the Eco RI restriction endonuclease. Using a single column, the enzyme could be isolated by eluting the column with a single step or multistep gradient of increasing salt concentration. The enzyme was purified to 75%-85% homogeneity with yields of 0.1 mg to 0.2 mg from 0.5 g of cell paste.     

A rapid method for the purification of S-adenosylmethionine: Protein-carboxyl O-methyltransferase by affinity chromatography

A simple method to purify S-adenosylmethionine: protein-carboxyl O-methyltransferase (protein methylase II, EC 2.1.1.24) from calf brain has been developed using affinity chromatography. The product of the reaction, S-adenosyl-l-homocysteine, which is a competitive inhibitor of the enzyme, was covalently linked to Sepharose beads. This gel proved to be an effective binder for protein methylase II at pH 6.2 and allowed for specific removal of the enzyme by the addition of the methyl donor substrate, S-adenosyl-l-methionine to the elution buffer. One step using this affinity chromatography column resulted in 377-fold purification of the enzyme and 71% recovery of the activity. Subsequent Sephadex G-100 chromatography enabled the enzyme to be purified 3000-fold from the calf brain whole homogenate. The purified enzyme showed a number of protein methylase II activity peaks following preparative gel electrophoresis with one major enzyme peak.     

Method of purification of glucose oxidase by means of affinity chromatography on immunoabsorbent]

The possibility to purify glucose oxidase from Penicillium vitale on immunosorbent containing specific antibodies to the enzyme covalently bound with Sepharose 4B is studied. The method of affinity chromatography was applied, beside routine methods of fractionating blood serum proteins, to isolate specific antibodies from antiserum of rabbits immunized with glucose oxidase. Immobilized on Sepharose glucose oxidase was used as biospecific sorbent. Specific antibodies to the enzyme were isolated using chromatograpy of gamma-globulins mixture followed by protein desorption from the column with 1 M NaC1 and 3% glucose. Antibodies were immobilized by their covalent binding to activated Sepharose. The immunosorbent obtained was used to purify low active preparation of glucose oxidase by means of affinity chromatography under conditions worked out for the antibodies isolation. The enzyme was eluted from the column with 1 M NaC1 (pH 3.0) containing 3% glucose. 5-Fold purified enzyme preparation was isolated.     

Purification of rat liver phenylalanine hydroxylase by affinity chromatography

Rat liver phenylalanine hydroxylase has been purified to homogeneity on a totally synthesized affinity matrix. The affinity matrix consisted of a succinylated diaminodipropylamine arm linked to Sepharose-4B, to which the cofactor, 6,7-dimethyl-5,6,7,8-tetrahydropterin, was covalently linked. The pure enzyme was eluted with buffered 50% ethylene glycol, 1 m KCl in one step after the 50% ammonium sulfate fraction of the rat liver homogenate was applied to the affinity column. Specific activities ranging from 1.4 to 3.0 units/mg of protein were obtained. The enzyme has been shown to be homogeneous by: (i) discontinuous gel electrophoresis, and (ii) sodium dodecyl sulfate gel electrophoresis. The subunit molecular weight was determined by the same technique and was calculated to be between 51,000 and 55,000.     

The properties of subunits of avidin coupled to Sepharose

Avidin that had been coupled to Sepharose 4B activated with CNBr retained over 90% of its biotin-binding capacity. When low concentrations of CNBr were used about 75% of the protein could be removed from the Sepharose by washing with guanidinium chloride (6 m). The remaining 25%, the covalently bound subunits, had an almost undiminished capacity for biotin but a decreased affinity. Addition of avidin subunits in guanidinium chloride to the coupled subunits followed by dilution or dialysis restored the original biotin-binding capacity and affinity. Three classes of binding sites were present in preparations of the subunits. About 25% were weak (K=5x10(-8)m), about one third exchanged their biotin in a few minutes (K approximately 10(-10)m) and the remainder were indistinguishable from the native tetramer. The last-named exchanged their bound biotin at a similar rate at pH5 and at pH2, they did not lose their biotin in 6 m-guanidinium chloride and they were resistant to tryptic digestion in the absence of biotin. The proportion of these stable sites could be increased to 65% when the subunits coupled to Sepharose were incubated at 37 degrees C. This increase was reversed by guanidinium chloride, which suggested that it was caused by a temperature-dependent association of covalently linked subunits. This in turn implies a temperature-dependent mobility of the agarose matrix of the Sepharose. Analysis of the spatial distribution of subunits within the Sepharose beads led to the conclusion that the association of subunits implied that they could move through distances greater than 20nm (several hundred A). This mobility and consequent formation of tetramer was greatly decreased when avidin subunits were coupled to Sepharose that had been cross-linked with divinyl sulphone.     

Bacillus megaterium, KM beta-galactosidase: purification by affinity chromatography and characterization of the active species

The enzyme β-galactosidase from Bacillus megaterium, strain KM has been purified by affinity chromatography. The enzyme was found to have a dimeric subunit structure, with the monomer having a molecular weight of 120,000. The K_eq of the monomer-dimer equilibrium was strongly shifted towards dissociation in the isolated state. Inclusion of 5% sucrose in the buffer (and maintenance of the temperature at 5 °) minimized this dissociation. Molecularly homogeneous monomer and dimer could be prepared on sucrose gradients. The dimer was determined to have an S_20,w of 8, while the monomer had an S_20,w of 3. The amino acid composition was found to be similar to that of the E. coli β-galactosidase although significant differences occur. The activity of the monomer was studied by both urea-denaturation experiments and by immobilization of the monomer on Sepharose-4B. The monomer, bound to Sepharose-4B, was found to be inactive but still capable of binding the inhibitor thio-methyl galactoside. Activity was reconstituted by adding free monomer, in 8 M urea, to the Sepharose-bound monomer, followed by removal of the urea by dialysis. In addition, free monomers from E. coli β-galactosidase were found to form active hybrids with Sepharose-bound B. megaterium β-galactosidase monomers. We conclude on the basis of these studies that the free monomer is inactive, and that the dimer is the active species, in marked contrast to E. coli β-galactosidase where only the tetrameric form is active.     

Evidence of an essential histidine residue in rabbit liver aryl sulfatase A.

A detailed study of the pH dependence of the Michaelis-Menten constants (V and K_m) of aryl sulfatase A (EC 3.1.6.1) from rabbit liver indicates that at least two functional groups (pK's ~4.3 and ~7 in the enzyme-substrate complex) participate in the enzymic degradation of substrate. Aryl sulfatase A is inactivated by diethyl pyrocarbonate (ethoxyformic anhydride). The enzyme that has been modified with this reagent can in turn be reactivated by treatment with hydroxylamine. The pH dependence of inactivation reveals a reactive group having a pK of 6.5–7.0. The results indicate that at least one histidine plays an important catalytic role in rabbit liver aryl sulfatase A, consistent with the results of earlier workers who employed diazotized sulfanilic acid. Phosphate ion, a competitive inhibitor, partially protects the enzyme from inactivation by diethyl pyrocarbonate whereas sulfate ion, also a competitive inhibitor, increases the rate of inactivation by diethyl pyrocarbonate. This result is of particular significance in view of the anomalous kinetics of aryl sulfatase A. The kinetic effects of even small amounts of sulfate ion impurities in many commercial sulfate ester substrate preparations is also discussed.     

Removal of the ϵ subunit from Escherichia coli F1-ATPase using monoclonal anti-ϵ antibody affinity chromatography

The usefulness of two monoclonal antibodies, ϵ-1 and ϵ-4, which recognize the ϵ subunit of Escherichia coli F₁-ATPase, for removing that subunit from ATPase was assessed. The ϵ subunit is a tightly bound, but dissociable, inhibitor of the ATPase. ϵ-1 binds ϵ with 10-fold higher affinity than ϵ-4. ϵ-1 recognizes a site on ϵ which is hidden by the quaternary structure of ATPase, while ϵ-4 can recognize ϵ when it is part of ATPase. Each antibody was purified and coupled to Sepharose to generate affinity columns. Solutions of ATPase in a buffer which was designed to reduce the affinity of ϵ for the enzyme were pumped through the columns and the degree of ϵ depletion was determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by Western blotting. Neither column retained ATPase significantly. At low ATPase concentrations and low flow rates, the ϵ-1 column was more efficient than the ϵ-4 column, removing in excess of 95% of the ϵ in a single passage compared with 93% removal by the ϵ-4 column. At higher protein concentrations or flow rates, however, the performance of the ϵ-1 column was substantially poorer, while that of the ϵ-4 column was much less affected. Very little ϵ emerged from the ϵ-4 column before most of the measured ϵ-binding capacity was filled. A second passage through the ϵ-4 column reduced residual ϵ to less than 2% of that which was originally present. Pure, active ϵ was eluted from either column by 1 m NH₄OH, pH 11. The relatively poor performance of ϵ-1 is discussed in terms of the low availability of the epitope and the tendency of the ϵ-depleted complex to compete with ϵ-1 for residual ϵ subunit. From consideration of these factors it appears likely that antibodies which recognize exposed epitopes will generally be more effective than antibodies which recognize cryptic epitopes in removing spontaneously dissociable subunits from protein complexes.     

Purification of phosphatidylinositol kinase from bovine brain myelin.

A membrane-bound phosphatidylinositol (PI) kinase (EC 2.7.1.67) was purified by affinity chromatography from bovine brain myelin. This enzyme activity was solubilized with non-ionic detergent and chromatographed on an anion-exchange column. Further purification was achieved by affinity chromatography on PI covalently coupled to epoxy-activated Sepharose, which was eluted with a combination of PI and detergent. The final step in the purification was by gel filtration on an Ultrogel AcA44 column. This procedure afforded greater than 5500-fold purification of the enzyme from whole brain myelin. The resulting activity exhibited a major silver-stained band on SDS/polyacrylamide-gel electrophoresis with an apparent Mr 45,000. The identity of this band as PI kinase was corroborated by demonstration of enzyme activity in the gel region corresponding to that of the stained protein. The purified enzyme exhibited a non-linear dependence on PI as substrate, with two apparent kinetic components. The lower-affinity component exhibited a Km similar to that observed for the phosphorylation of phosphatidylinositol 4-phosphate by the enzyme.     

Purification of a beta-D-galactosidase from bovine liver by affinity chromatography

A beta-D-galactosidase from bovine liver was purified to apparent homogeneity. The major purification step was affinity chromatography on a column of D-galactose attached to a Sepharose support activated with divinyl sulfone. Affinity media prepared by binding ligands to Sepharose activated with cyanogen bromide were unsuitable for purification of the enzyme, even though such media have been used to purify beta-D-galactosidases from other sources. The molecular weight of the denatured enzyme was 67,000. The molecular weight of the native enzyme at pH 7.0 was 68,000, and at pH 4.5 or 5.0, was 141,000. These data suggest that the enzyme has a single, fundamental subunit with a molecular weight of 67,000, and that the enzyme exists as a monomer at pH 7.0, and a dimer at pH 4.5 or 5.0. The Vmax values of the enzyme with p-nitrophenyl beta-D-galactoside, p-nitrophenyl beta-D-fucoside, lactose, and beta-Gal-(1----4)-beta-GlcNAc-1---- OC6H4NO2 -p were 10,204, 11,550, 9,479, and 8,859 nmol/min/mg of protein, respectively, and the Km values for these substrates were 0.08, 14.9, 14.2, and 1.6mM, respectively. D-Galactose, beta-D- galactosylamine , p-aminophenyl 1-thio-beta-D-galactoside, and D- galactono -1,4-lactone were competitive inhibitors of the enzyme, with Ki values of 0.9, 0.6, 0.6, and 0.8mM, respectively. The enzyme catalyzed the transfer of the D-galactosyl group from p-nitrophenyl beta-D-galactoside to D-glucose. The pH optimum of the enzyme was 4.5, and the pI was 4.7.     

Purification and properties of a homogeneous aryl sulfatase A from rabbit liver.

Aryl sulfatase A (aryl sulfate sulfohydrolase EC 3.1.6.1) has been purified > 10,000-fold from rabbit liver; by disc gel electrophoresis the enzyme appears homogeneous. Various properties of the enzyme have been determined and comparisons are made with other aryl sulfatases. Sodium dodecyl sulfate gel electrophoresis indicates that the enzyme is made up of monomers of molecular weight ～ 70,000. At pH 7.4 the enzyme exists as a dimer whereas a tetrameric form predominates at pH 4.8.The enzyme exhibits the anomalous kinetics often observed with aryl sulfatase A from mammalian tissues (the enzyme is modified to an inactive form while degrading substrate and the inactive form can be reactivated by sulfate ion). The enzyme activity has been studied under a variety of reaction conditions. Two pH optima are observed and neither enzyme concentration or changes in ionic strength appear to have an effect on the relative magnitudes of the optima. Aryl sulfatase A is competitively inhibited by potassium sulfate, potassium phosphate, and sodium sulfite (K_i = 2.9 × 10^?3 M, 3.4 × 10^?5 M, and 1.1 × 10^?6 M, respectively). Kinetic constants for some substituted phenyl sulfate esters have been determined. The variation in V is not consistent with a reaction mechanism involving a rate-limiting breakdown of a common intermediate.The inactive (modified) form of the enzyme has been isolated from reaction mixtures containing aryl sulfatase A and substrate. A procedure is presented for determining the relative amount of modified and native enzyme in these preparations. In the presence of substrate, sulfate displaces the equilibrium between native and modified enzyme in favor of native enzyme. In the absence of substrate neither sulfate or phosphate have an effect on the equilibrium. A study is made of the temperature dependence of the process in which the modified enzyme is converted back to native enzyme. The relatively small entropy of activation for the conversion of the modified to the native form (ΔS3 = ?8 cal/mole deg) does not seem to be consistent with a major modification of protein conformation.     

Plant aspartate transcarbamylase: an affinity chromatographic method for the purification of the enzyme from germinated seedings.

A simple and rapid affinity chromatographic method for the isolation of aspartate transcarbamylase from germinated seedlings of mung bean (Phaseolus aureus) was developed. A partially purified preparation of the enzyme was chromatographed on an affinity column containing aspartate linked to CNBr-activated Sepharose 4B. Aspartate transcarbamylase was specifically eluted from the column with 10 mm aspartate or 0.5 m KCl. The enzyme migrated as a single sharp band during disc electrophoresis at pH 8.6 on polyacrylamide gels. Electrophoresis of the sodium dodecyl sulfate-treated enzyme showed two distinct protein bands, suggesting that the mung bean aspartate transcarbamylase was made up of nonidentical subunits. Like the enzyme purified by conventional procedures, this enzyme preparation also exhibited positive homotropic interactions with carbamyl phosphate and negative heterotropic interactions with UMP. This method was extended to the purification of aspartate transcarbamylase from Lathyrus sativus, Eleucine coracona, and Trigonella foenum graecum.     

Purification of chondroitinase B and chondroitinase C using glycosaminoglycan-bound AH-Sepharose 4B

Chondroitinase B and chondroitinase C were separated from an extract of Flavobacterium heparinum induced with chondroitin 6-sulfate by using column chromatography on hydroxylapatite. Chondroitinase C was eluted together with the activities of hyaluronidase, delta4,5glycosiduronase, and sulfatase. The latter two activities were eliminated exclusively by passing the crude chondroitinase C fraction through a phosphono-cellulose column pre-equilibrated with 0.07M sodium phosphate buffer (pH 6.8). Chondroitinase C was then purified by affinity chromatography using dermatan sulfate-bound AH-Sepharose 4B coated with the same glycosaminoglycan. Purification of the enzyme was achieved 18-fold and in 73% yield. On the other hand, the activities of delta4,5glycosiduronase and sulfatase were decreased to 50 and 60%, respectively, as compared with those in the crude chondroitinase B fraction, after passing the fraction through a column of phosphono-cellulose pre-equilibrated with 0.1M sodium phosphate buffer (pH 6.8). The remaining activities of these two enzymes were then eliminated from chondroitinase B by affinity chromatography with heparin-bound AH-Sepharose 4B coated with dermatan sulfate. In the affinity chromatography used in the present study, non-covalent coating of the glycosaminoglycan-bound (covalently) AH-Sepharose 4B with the same or another glycosaminoglycan was found to be important.