Mapping protein interfaces with a fluorogenic cross-linker and mass spectrometry: application to nebulin-calmodulin complexes.

Nebulin is a giant multifunctional protein that is thought to serve as both a length-regulating protein ruler and calcium/CaM-mediated regulatory protein on the thin filaments of the skeletal muscle sarcomere. To define molecular interfaces between nebulin and CaM, we thiolated lysines of CaM and ND66, a four-module cloned fragment from the C-terminus of nebulin, with 2-iminothiolane and cross-linked the complex with dibromobimane, which alkylates thiol pairs within approximately 6 A of each other to form a fluorescent adduct. Such a two-stage cross-linking generated mainly 1:1 complexes of ND66 and CaM, with a limited extent of intramolecular cross-linking. In-gel chymotryptic digestion of the dibromobimane-cross-linked complexes yielded peptides that were first screened by HPLC with fluorescence detection and then scored for cross-linking with mass spectrometry. Several inter- and intramolecular sites were identified and confirmed further by ESI-MS/MS experiments, defining molecular interfaces and patterns of protein folding. In particular, five intermolecular cross-linking products of sequences within the region of amino acids 83-99 (YKENMGKGTPLPVTPEM) in ND66 and several sequences of CaM indicate that the nebulin-CaM interface is close to, and may overlap with, the nebulin-actin interface. This proximity suggests a potential competition between CaM and actin for this nebulin interface. Intramolecular cross-linking of amino acids 13-16 (KEAF) and 13-18 (KEAFSL) with amino acids 145-148 (MTAK) and 146-148 (TAK) in CaM suggests the interaction of two lobes across the central helix. The cross-linking of amino acids 1-6 (MKTPEM) with amino acids 114-129 (YKENVGKATATPVTPE) and 115-129 (KENVGKATATPVTPE) in ND66 hints at an association of noncontiguous nebulin modules in solution.     

Cooperativity between the hydrophobic and cross-linking domains of elastin

The principal protein component of the elastic fiber found in elastic tissues is elastin, an amorphous, cross-linked biopolymer that is assembled from a high molecular weight monomer. The hydrophobic and cross-linking domains of elastin have been considered separate and independent, such that changes to one region are not thought to affect the other. However, results from these solid-state 13C NMR experiments demonstrate that cooperativity in protein folding exists between the two domain types. The sequence of the EP20-24-24 polypeptide has three hydrophobic sequences from exons 20 and 24 of the soluble monomer tropoelastin, interspersed with cross-linking domains constructed from exons 21 and 23. In the middle of each cross-linking domain is a "hinge" sequence. When this pentapeptide is replaced with alanines, as in EP20-24-24[23U], its properties are changed. In addition to the expected increase in alpha-helical content and the resulting increase in rigidity of the cross-linking domains, changes to the organization of the hydrophobic regions are also observed. Using one-dimensional CPMAS (cross-polarization with magic angle spinning) techniques, including spectral editing and relaxation measurements, evidence for a change in dynamics to both domain types is observed. Furthermore, it is likely that the methyl groups of the leucines of the hydrophobic domains are also affected by the substitution to the hinge region of the cross-linking sequences. This cooperativity between the two domain types brings new questions to the phenomenon of coacervation in elastin polypeptides and strongly suggests that functional models for the protein must include a role for the cross-linking regions.     

Degradation of the D1 protein of photosystem II under illumination in vivo: two different pathways involving cleavage or intermolecular cross-linking

The D1 protein of the photosystem II reaction center turns over the most rapidly of all the proteins of the thylakoid membrane under illumination in vivo. In vitro, the D1 protein sustained cleavage in a surface-exposed loop (DE loop) or cross-linking with another reaction center protein, the D2 protein or cytochrome b(559), under illumination. We found that the D1 protein was damaged in essentially the same way in vivo, although the resultant fragments and cross-linked adducts barely accumulated due to digestion by proteases. In vitro studies detected a novel stromal protease(s) that digested the adducts but not the monomeric D1 protein. These observations suggest that, in addition to cleavage, the cross-linking reactions themselves are processes involved in complete degradation of the D1 protein in vivo. Peptide mapping experiments located the cross-linking sites with the D2 protein among residues 226-244, which includes the cross-linking site with cytochrome b(559) [Barbato, R., et al. (1995) J. Biol. Chem. 270, 24032-24037], in the N-terminal part of the DE loop, while N-terminal amino acid sequencing of the fragment located the cleavage site around residue 260 in the C-terminal part of the loop. We propose a model explaining the occurrence of simultaneous cleavage and cross-linking and discuss the mechanisms of complete degradation of the D1 protein in vivo.     

Part of the matrix on the 5' side from codon in the E-segment is close to protein S26 on the human 80S ribosome

Positioning of mRNA on the 80S ribosome upstream the E site bound codon was studied using derivatives of nona- and dodecaribonucleotides containing the triplet UUU coding for Phe at the 3'-terminus, and a perfluorophenylazide cross-linker on either the first or the third nucleotide. Two sets of the mRNA analogues were used, with the photoactivatable groups on either the C5 atom of the uridine or the N7 atom of the guanosine. The modified nucleotides were directed to positions from -4 to -9 with respect to the first nucleotide of the P site bound codon by tRNA(Phe) cognate to the triplet UUU targeted to the P site. Mild UV-irradiation of ribosomecomplexes with tRNA(Phe) and mRNA analogues resulted in the cross-linking to the 40S subunits preferentially, mainly to the proteins. The principal target for the cross-linking was protein S26 in all cases. Location of the photoactivatable group on the nucleotide at position -4 lead also to the minor cross-linking to protein S3, and at position -6 to protein S14. In the absence of tRNA, all mRNA analogues cross-linked to protein S3.     

Irreversible binding of bacteriophage T5 to its FhuA receptor protein is associated with covalent cross-linking of 3 copies of tail protein pb4

Irreversible binding of bacteriophage T5 to its FhuA receptor protein is characterized by a high activation energy, typical for reactions where covalent bonds are formed [Zarnitz, M.L. and Weidel, W. (1963) Z. Naturforsch. 18b, 276-280]. Upon binding of radiolabeled T5 phages to FhuA formation of a new protein of 250 kDa was observed. Using electrophoretical and Western blotting techniques this protein was shown to be formed by cross-linking of 3 copies of tail protein pb4, rather than by cross-linking of FhuA and the receptor-binding protein.     

Peptidoglycan and lipopolysaccharide bind to the same binding site on lymphocytes

Bacterial cell wall peptidoglycan (PGN) and lipopolysaccharide (LPS), which are both macrophage activators and polyclonal B cell mitogens, were shown to bind to the same dominant 70-kDa 6.5 pI protein on the surface of mouse B lymphocytes. This conclusion was supported by the following results: (a) the PGN- and LPS-binding proteins co-migrated following photoaffinity cross-linking and two-dimensional polyacrylamide gel electrophoresis; (b) cross-linking of PGN to this 70-kDa protein was competitively inhibited by LPS (IC50 = 7.3 microM), LPS from a deep rough mutant (IC50 = 6.9 microM), and lipid A (IC50 = 18-72 microM); (c) cross-linking of LPS to this 70-kDa protein was competitively inhibited by polymeric soluble PGN (IC50 = 0.09 microM) and sonicated high Mr PGN (IC50 = 0.6 microM); (d) cross-linking of both PGN and LPS to this 70-kDa protein was also competitively inhibited by dextran sulfate (IC50 = 115-124 microM); (e) cross-linking of both PGN and LPS to this 70-kDa protein was inhibited by a (GlcNAc)2-specific lectin; and (f) peptide maps of the 70-kDa proteins digested with chymotrypsin, subtilisin, staphylococcal protease V, or papain were identical for PGN- and LPS-binding proteins and unique for each enzyme. Based on competitive inhibition experiments, binding of PGN to the 70-kDa protein was 20-1200 times stronger than the binding of LPS or lipid A on a per mol basis. However, when aggregated micellar structures of LPS or lipid A were considered, the avidities of LPS and PGN binding were similar. These results demonstrate binding of PGN and LPS to the same 70-kDa protein on lymphocytes and suggest that the binding is specific for the (GlcNAc-MurNAc)n backbone of PGN and the (GlcNAc)2 part of lipid A.     

Identification of a receptor for peptides of the bombesin family in Swiss 3T3 cells by affinity cross-linking

The cross-linking agent ethylene glycol-bis(succinimidyl succinate) was used to covalently link 125I-labeled gastrin releasing peptide (125I-GRP) to an Mr 75,000-85,000 surface protein in Swiss 3T3 cells that displays many characteristics of a specific receptor for peptides of the bombesin family. This protein was not present in other cell lines which do not exhibit receptors for bombesin-like peptides. Unlabeled GRP competed for affinity labeling of the Mr 75,000-85,000 protein in a concentration-dependent manner, and other bombesin-related peptides also inhibited the cross-linking of 125I-GRP to this component. In contrast, high concentrations of a variety of other peptide hormones and mitogens had no effect. Affinity labeling of the Mr 75,000-85,000 protein was dependent on the concentration of 125I-GRP and exhibited saturability. 125I-GRP affinity labeling of this protein was also demonstrated by two-dimensional gel electrophoresis. These studies suggest that an Mr 75,000-85,000 surface protein with an isoelectric point of 6.0 to 6.5 is a major component of the receptor for peptides of the bombesin family in Swiss 3T3 cells.     

Phosphorylation of microtubule-associated proteins regulates their interaction with actin filaments

We have determined the absolute phosphate content of microtubule-associated proteins (MAPs) and established that phosphorylation inhibits the actin filament cross-linking activity of MAPs and both of the major MAP components, MAP-2 and tau. Similar results were obtained with actin from rabbit muscle, hog brain, and Acanthamoeba castellanii. We used the endogenous phosphatases and kinases in hog brain microtubule protein to modulate MAP phosphate level before isolating heat-stable MAPs. MAPs isolated directly from twice-cycled microtubule protein contain 7.1 +/- 0.1 (S.E.) mol of phosphate/300,000 g protein. After incubating microtubule protein without ATP, MAPs, had 4.9 +/- 0.6 phosphates. After incubating microtubule protein with 1 mM ATP and 5 microM cAMP in 2 mM EGTA, MAPs had 8.6 +/- 0.5 phosphates but there was also exchange of three more [32P]phosphates from gamma-labeled ATP for preexisting MAP phosphate. Incubation of microtubule protein with ATP and cAMP in 5 mM CaCl2 resulted in exchange but no net addition of phosphate to MAPs. We fractionated the MAP preparations by gel filtration and obtained MAP-2 with 4.3 to 7.5 and tau with 1.5 to 2.2 mol of phosphate/mol of protein depending on how we treated the microtubule protein prior to MAP isolation. The actin filament cross-linking activity of whole MAPs, MAP-2, and tau depended on the MAP-phosphate content. In all cases, phosphorylation of MAPs inhibited actin filament cross-linking activity. The concentration of high phosphate MAPs required to form a high viscosity solution with actin filaments was 2 to 4 times more than that of low phosphate. MAPs. During incubation of microtubule protein with [gamma-32P]ATP, only MAP peptides are labeled. Treatment of these MAPs with either acid or alkaline phosphatase removes phosphate mainly from MAP-2, with an increase in actin filament cross-linking activity. Thus, both MAP phosphorylation and the effect of phosphorylation on actin cross-linking activity of MAPs are reversible.     

Mapping spatial proximities of sulfhydryl groups in proteins using a fluorogenic cross-linker and mass spectrometry

Chemical cross-linking of proteins in combination with mass spectrometric analysis of the reaction products has gained renewed interest as a method of obtaining distance constraints within a protein and determining a low-resolution three-dimensional structure. We present a method for identifying spatially close sulfhydryl groups in proteins employing chemical cross-linking with the fluorogenic, homobifunctional cross-linker dibromobimane, which cross-links thiol pairs within approximately 3-6A. The applicability of our strategy was demonstrated by cross-linking the sulfhydryl groups of Cys-18 and Cys-78 in gamma-crystallin F, which are within a distance of 3.57A according to the X-ray structure. Intramolecularly cross-linked gamma-crystallin was first separated from reaction side products by reversed-phase chromatography on a C-4 column. Subsequently, the fraction containing the reacted protein was enzymatically digested with trypsin, and the resulting peptide mixture was separated by a second reversed-phase chromatographic step on a C-18 column, in which the cross-linked peptides were tracked by their fluorescence. The cross-linking product between Cys-18 and Cys-78 in gamma-crystallin F was identified by matrix-assisted laser desorption/ionization-time of flight mass spectrometry. This strategy presents a rapid method for mapping sulfhydryl groups separated by a distance of approximately 3-6A within a protein.     

Cross-linking studies of the protein topography of rat liver microsomes

A cleavable cross-linking reagent, dithiobis(succinimidyl propionate), DSP, was used to study the topography of the proteins in the endoplasmic reticulum membrane of rat liver. Reaction of untreated (control), phenobarbital- or 3-methylcholanthrene-induced microsomes with 0.5 mM DSP for 30 min at 0°C resulted in the cross-linking of a protein with a molecular weight of about 52 000 to form an apparent dimer. In phenobarbital microsomes, a smaller amount of a 52 000-dalton protein also appeared in a dimer in the absence of DSP if N-ethylmaleimide was not included during homogenization. In phenobarbital and 3-methylcholanthrene microsomes, a 48 000-dalton protein was cross-linked by DSP to a protein of about 57 000. In all three types of microsomes, a protein with an M_I of about 52 000 was also cross-linked to a protein of about 79 000. In phenobarbital and control microsomes, cross-linking resulted in an oligomeric protein of approximate molecular weight 180 000 which contained three proteins, two with M_r of about 52 000 and one about 79 000. Under the cross-linking conditions, little or no denaturation of cytochrome P-450 and NADPH-cytochrome c reductase was observed. The aryl hydrocarbon hydroxylase activity was significantly inhibited by the bifunctional cross-linking reagent, DSP, but not by the monofunctional reagent N-succinimidyl-3-(4-hydroxyphenyl) propionate. However, attempts to regenerate the aryl hydrocarbon hydroxylase activity by cleavage of the disulfide linkage with 2-mercapto-ethanol or dithiothreitol were not successful.     

The use of 2-iminothiolane as an RNA-protein cross-linking agent in Escherichia coli ribosomes, and the localisation on 23S RNA of sites cross-linked to proteins L4, L6, L21, L23, L27 and L29.

When E. coli ribosomal subunits are reacted with 2-iminothiolane and then subjected to a mild ultraviolet irradiation, an RNA-protein cross-linking reaction occurs. About 5% of the total protein in each subunit becomes cross-linked to the RNA, and a specific sub-set of proteins is involved in the reaction. In the case of the 50S subunit, the sites of cross-linking to the 23S RNA have been determined for six of these proteins: protein L4 is cross-linked within an oligonucleotide comprising positions 613-617 in the 23S sequence, L6 within positions 2473-2481, L21 within positions 540-548, L23 within positions 137-141, L27 within positions 2332-2337 and L29 within positions 99-107.     

General method of isolation and analysis of polynucleotide fragments cross-linked with proteins

A fragment of 16S RNA, cross-linked to S7 protein by UV irradiation of the 30S subunit of E. coli ribosome, was obtained by the action of T1 ribonuclease on the irradiated nucleoprotein. The digest was treated with polynucleotide kinase in the presence of [gamma-32P]ATP and the S7-cross-linked oligonucleotides were isolated. An individual oligonucleotide attached to S7 protein was obtained after proteinase treatment of the respective spot followed by electrophoresis. Sequencing of this oligonucleotide established its structure as 1233-1240 fragment of 16S RNA, the U1239 residue being the site of the S7 cross-linking. The developed general approach can be used for localizing protein - cross-linked residues in polynucleotides, whatever is the procedure employed for cross-linking.     

Structural properties of the D1 and surrounding photosystem II polypeptides as revealed by their interaction with cross-linking reagents

Treatment of Chlamydomonas reinhardtii thylakoids with cross-linking reagents including glutaraldehyde causes polymerization of all thylakoid polypeptides, but not of the reaction center II polypeptide D1 unless the thylakoids are presolubilized by octyl beta-D-glucoside (Adir, N., and Ohad, I. (1986) Biochim. Biophys. Acta 850, 264-274). The results presented here show that this is a general property of D1 as it can be demonstrated in thylakoids of cyanophytes, Dasicladaceae, green algae, and C3 and C4 plants. Solubilization of the membranes by ionic detergents, deoxycholate, lauryl sucrose, or dodecyl beta-D-maltoside is not effective in inducing cross-linking of the D1 polypeptides by glutaraldehyde. The most effective alkyl glucosides were those with 7-9 carbon alkyl chains. The same behavior toward glutaraldehyde was exhibited by the unprocessed D1 precursor and by the palmitoylated D1 protein. Based on the refractility of the D1 protein to cross-linking reagents, a procedure was developed for its isolation from cross-linked thylakoids by lithium dodecyl sulfate-polyacrylamide gel electrophoresis. Isolated D1 retained its behavior toward cross-linking by glutaraldehyde and generated tryptic fragments similar to those obtained following trypsin treatment of intact thylakoids. Denaturation of isolated D1 protein by acetone facilitates cross-linking by glutaraldehyde and extensive degradation by trypsin. The photosystem II polypeptides are differentially cross-linked with increasing concentrations of glutaraldehyde, the most susceptible being the 28- and 23-kDa components of the light-harvesting chlorophyll a-b protein complex and the core complex 44- and 51-kDa polypeptides, and the least affected being the cytochrome b559, the D2 protein, and a 24-kDa component of the light-harvesting chlorophyll a-b protein complex. These results reflect the relative position and interaction of the photosystem II polypeptides within the complex and suggest that strong and specific hydrophobic interactions may be responsible for the tight and stable conformation of D1. This may be based mostly on the conserved amino acid sequences of D1 and possibly plays a role in the process of D1 integration and removal from the reaction center during its light-dependent turnover.     

Photoaffinity labeling of the erythropoietin receptor and its identification in a ligand-free form.

Pure human recombinant erythropoietin (EP) was acylated through a primary amino residue with a cross-linking reagent, N-[[3-[[4-[(p-azido-m-[125I]iodophenyl)azo]benzoyl]amino] propanoyl]oxy]-succinimide (Denny-Jaffe reagent), which is photoreactive and cleavable at the azo residue. The resulting conjugated hormone (DJ-EP) was purified from unmodified EP by reverse-phase high-pressure liquid chromatography and maintained its capacity to bind to receptors for EP on erythroid progenitor cells. The receptor for EP was previously identified as two related proteins of 100 and 85 kDa molecular mass by chemical cross-linking to 125I-EP. Recently, D'Andrea and co-workers [(1989) Cell 57, 277-285] cloned a cDNA that codes for a protein of 55-66 kDa, which is thought to be the EP receptor. In this report, cross-linking to the receptor through the monofunctional DJ-EP labeled the same 140- and 125-kDa molecular mass bands (100- and 85-kDa proteins) cross-linked with 125I-EP and disuccinimidyl suberate. Furthermore, cleavage of the azo bond of the DJ-EP receptor complex by sodium dithionite (80 degrees C, 5 min) demonstrated that proteins of 105 and 90 kDa were labeled in ligand-free form by DJ-EP. This result demonstrates that artifactual cross-linking of multiple proteins or other artifacts of cross-linking do not explain the difference in molecular mass of the EP receptor identified by cross-linking and the receptor identified by expression cloning.     

Relation of protein synthesis and transglutaminase activity to formation of the cross-linked envelope during terminal differentiation of the cultured human epidermal keratinocyte

When serially cultivated human epidermal keratinocytes are placed in suspension culture they stop growing and form, beneath the plasma membrane, an insoluble envelope consisting of protein cross-linked by ε- (γ-glutamyl)lysine. The formation of envelopes in suspended cells is preceded by a sharp decline in the rate of protein synthesis, and most envelopes appear only after the average rate of protein synthesis has fallen to a very low level. If protein synthesis is reduced over 98 percent with cycloheximide or emetine at the time that surface-grown cells are placed in suspension culture, cross-linked envelopes form in most of the cells. This shows that the precursor of the envelope and the cross-linking enzyme are already in the cytoplasm in most cells of growing surface cultures. The process of envelope formation by suspension cultures is actually accelerated by the inhibitors of protein synthesis; an increased number of cells with cross-linked envelopes is observable within 4-6 h after the addition of cycloheximide. The inhibitor also induces a large fraction of the cells of surface cultures to form enveloped within a few days. These findings suggest that arrest of protein synthesis leads to activation of the cross-linking process. Agents known to inhibit transglutaminase-mediated protein cross-linking-putrescine, iodoacetamide, and ethylene glycol-bis(beta-aminoethyl ether)N,N,N',N'-tetraacetate (EGTA)- also prevent envelope formation. Though the activity of the cross-linking transglutaminase depends on the presence of cellular Ca++, we have not been able to activate the cross-linking process by high external Ca++ concentration or ionophores.     

Divinyl sulfone as a cross-linking reagent for oligomeric proteins

The kinetics of the nucleophilic addition reactions of divinyl sulfone to amino groups of glycine and model proteins was studied in aqueous solution at 30 degrees C. The rate constants for glycine, bovine serum albumin, and alpha 1-casein were (4.84 +/- 0.58) x 10(-1), (2.97 +/- 0.31) x 10(-2), and (2.38 +/- 0.49) x 10(-2) M-1s-1, respectively. Divinyl sulfone was proposed as a cross-linking reagent for the qualitative detection of protein association in solution. The cross-linking capacity of divinyl sulfone was compared to that of 1,3,5-triacryloylhexahydro-s-triazine.     

蛋白质交联用酶的作用机制及研究进展北大核心CSCD

蛋白质交联在食品、化工和医药等领域发挥重要的作用。利用酶催化蛋白质交联是一种可替代物理和化学交联的高效经济的方法。然而,目前仍缺乏详细的酶促蛋白质交联分子层面的解析。本文综述了酶催化的蛋白质交联反应机制及其对蛋白质结构的影响,以及在食品、化工和医药领域的应用,并展望了酶促交联的发展。     

A specific, UV-induced RNA-protein cross-link using 5-bromouridine-substituted RNA.

The well-characterized RNA binding site of the bacteriophage R17 coat protein has been used to investigate the cross-linking of protein to 5-bromouridine (BrU)-substituted RNA using medium-wavelength UV light. We have demonstrated a specific RNA-protein cross-link and identified the site on the RNA of protein attachment. Formation of the covalent complex is dependent upon the presence of BrU at position -5 of the RNA and specific binding of the RNA by coat protein. The amount of cross-linking increases with time and depends on the light source and conditions used. Irradiations using a broad-spectrum UV transilluminator (peak at 312 nm) or monochromatic XeCl excimer laser (308 nm) gave levels of cross-linking exceeding 20 and 50%, respectively. The quantum yield of photo-cross-linking, determined with 308-nm excitation, was 0.003. While little strand breakage or debromination of the RNA occurred, significant protein photodamage was observed.     

The surface location of individual residues in a bacterial S-layer protein

Bacterial surface layer (S-layer) proteins self-assemble into large two-dimensional crystalline lattices that form the outermost cell-wall component of all archaea and many eubacteria. Despite being a large class of self-assembling proteins, little is known about their molecular architecture. We investigated the S-layer protein SbsB from Geobacillus stearothermophilus PV72/p2 to identify residues located at the subunit-subunit interface and to determine the S-layer's topology. Twenty-three single cysteine mutants, which were previously mapped to the surface of the SbsB monomer, were subjected to a cross-linking screen using the photoactivatable, sulfhydryl-reactive reagent N-[4-(p-azidosalicylamido)butyl]-3′-(2′-pyridyldithio)propionamide. Gel electrophoretic analysis on the formation of cross-linked dimers indicated that 8 out of the 23 residues were located at the interface. In combination with surface accessibility data for the assembled protein, 10 residues were assigned to positions at the inner, cell-wall-facing lattice surface, while 5 residues were mapped to the outer, ambient-exposed lattice surface. In addition, the cross-linking screen identified six positions of intramolecular cross-linking within the assembled protein but not in the monomeric S-layer protein. Most likely, these intramolecular cross-links result from conformational changes upon self-assembly. The results are an important step toward the further structural elucidation of the S-layer protein via, for example, X-ray crystallography and cryo-electron microscopy. Our approach of identifying the surface location of residues is relevant to other planar supramolecular protein assemblies.     

Conjugation of horseradish peroxidase to staphylococcal protein A with benzoquinone, glutaraldehyde, or periodate as cross-linking reagents

Horseradish peroxidase was conjugated to Staphylococcal protein A by three different two-step procedures using an increasing excess of peroxidase in the second step reaction. The yield of conjugated protein A was analyzed by SDS-polyacrylamide gel electrophoresis. Conjugation of peroxidase to protein A with benzoquinone or glutaraldehyde as cross-linking reagents at a 3- to 4-fold molar excess of peroxidase resulted in a high yield of coupled protein A with conjugates of low molecular size. Conjugation of peroxidase to protein A by the periodate method resulted in a high yield of coupled protein A with polymeric conjugates of large molecular size. Based on these results, conjugates produced with glutaraldehyde as cross-linking reagents were further analyzed. The capacity of the conjugates to precipitate human immunoglobulin evaluated by radial immunodiffusion was found to be reduced to about 50% of that of native protein A. Conjugates produced with glutaraldehyde as cross-linking reagent retained 70% of the enzyme activity of native peroxidase.