Hemopexin-mediated heme uptake by liver. Characterization of the interaction of heme-hemopexin with isolated rabbit liver plasma membranes

Plasma membranes isolated from rabbit liver retain the ability to interact specifically with heme-hemopexin. In this system, apohemopexin does not compete effectively with heme-hemopexin for binding. The membranes bind heme-hemopexin complexes with high affinity (KD = 6.8 X 10(-7) M) and with an apparent capacity of 2.3 pmol/mg of membrane protein. These membranes also retain the ability to remove heme from heme-hemopexin. The release of heme reaches a plateau after 15-30 min at 30 degrees C and does not involve metabolic energy, proteolysis of hemopexin or pH gradients. The apohemopexin formed is rapidly released from the membranes. The accumulation of heme is saturable and is affected by pH and temperature with maximum uptake occurring between pH 5.5 and 6.5 and at 30 degrees C. Interestingly, much more heme (approximately 25 pmol/mg of membrane protein) is accumulated than hemopexin at saturation, implying that the receptor can turn over several times and that a heme-binding component exists in the rabbit liver plasma membrane.     

A protein with multiple heme-binding sites from rabbit serum

A 93,000 molecular weight protein (HBP.93) which binds hemin and protoporphyrin IX with high affinity has been isolated from rabbit serum using affinity chromatography on hemin-conjugated agarose. The amino acid composition of this protein is unique in that the proline and histidine contents are remarkably high (16.6 and 9.9 mol %, respectively). A large increase in the absorbance of the Soret region arises from the heme-protein interaction. The spectrophotometric titration showed that the protein can bind 25-35 mol of hemin/mol of protein. The apparent dissociation constant was estimated to be 1-4 X 10(-7) M for hemin at pH 7.4 and approximately 10(-6) M for protoporphyrin IX at pH 9.2. The similarity of the difference spectrum of heme-HBP.93 complex to that of heme-hemopexin complex suggests that a bisimidazol-type coordination of heme iron is involved in the binding. The extremely high capacity of HBP.93 to bind heme is also demonstrated by a large increase in the sedimentation velocity of the protein upon heme binding. The native heme-protein complex migrates faster than the heme-free protein in a polyacrylamide gel at pH 8.8; the increased mobility appears to be due to the charge on the carboxyl groups of the bound heme. Although the use of a hemin-agarose column has failed to reveal a protein of similar size and heme affinity in the sera of a number of other species, including man, the heme-binding properties and high histidine level of the human alpha 2-histidine-rich glycoprotein raise the possibility that the two proteins are related.     

Interaction of heme and heme-hemopexin with an extracellular oxidant system used to measure cell growth-associated plasma membrane electron transport

Since redox active metals are often transported across membranes into cells in the reduced state, we have investigated whether exogenous ferri-heme or heme bound to hemopexin (HPX), which delivers heme to cells via receptor-mediated endocytosis, interact with a cell growth-associated plasma membrane electron transport (PMET) pathway. PMET reduces the cell-impermeable tetrazolium salt, WST-1, in the presence of the mandatory low potential intermediate electron acceptor, mPMS. In human promyelocytic (HL60) cells, protoheme (iron protoporphyrin IX; 2,4-vinyl), mesoheme (2,4-ethyl) and deuteroheme (2,4-H) inhibited reduction of WST-1/mPMS in a saturable manner supporting interaction with a finite number of high affinity acceptor sites (Kd 221 nM for naturally occurring protoheme). A requirement for the redox-active iron was shown using gallium-protoporphyrin IX (PPIX) and tin-PPIX. Heme-hemopexin, but not apo-hemopexin, also inhibited WST-1 reduction, and copper was required. Importantly, since neither heme nor heme-hemopexin replace mPMS as an intermediate electron acceptor and since inhibition of WST-1/mPMS reduction requires living cells, the experimental evidence supports the view that heme and heme-hemopexin interact with electrons from PMET. We therefore propose that heme and heme-hemopexin are natural substrates for this growth-associated electron transfer across the plasma membrane.     

The aromatic and heme chromophores of rabbit hemopexin. Difference absorption and fluorescence spectra.

Spectrophotometric and fluorimetric techniques were employed to charcterize the environment of the heme chromophore of rabbit hemopexin and to monitor changes in the environment of aromatic amino acid residues induced by the interaction of hemopexin with porphyrins and metalloporphyrins. Difference spectra showed maxima at 292 and 285 nm when hemopexin binds heme or deuteroheme but not deuteroporphyrin. These maxima are attributed to alterations in the local environment of tryptophan and tyrosine residues. Spectro-photometric titrations of the tyrosine residues of hemopexin, heme-hemopexin and hemopexin in 8 M urea showed apparent pK values at 11.4, 11.7, and 10.9 respectively. Perturbation difference spectra produced by 20% v/v ethylene glycol are consistent with the exposure of 6-8 of the 14 tyrosine residues and 6-8 of the 15 tryptophan residues of rabbit hemopexin to this perturbant. Only small differences were found between the perturbation spectra of apo- and heme-hemopexin near 290 nm, suggesting that slight or compensating changes in the exposure to solvent of tryptophan chromophores occur. In the Soret spectral region, the exposure of heme in the heme-hemopexin complex to ethylene glycol was 0.7, relative to the fully exposed heme peptide of cytochrome c. The fluorescence quantum yields of rabbit apo- and heme-hemopexin were estimated to be 0.06 and 0.03, respectively, compared to a yield of 0.13 for L-tryptophan. Iodide quenched 50% of the fluorescence of the deuteroheme-hemopexin complex. Cesium was not an effective quencher. Modification of approximately, 4 tryptophan residues with N-bromosuccinimide also decreased the relative fluorescence of apo-hemopexin by 50% and concomitantly reduced the heme-binding ability of the protein by 70%. The existence of sterically unhindered tryptophan residues in either apo- heme-hemopexin is unlikely since no charge transfer compelxes between these proteins and N-methylnicotinamide were detected.     

Interaction of heme and heme-hemopexin with an extracellular oxidant system used to measure cell growth-associated plasma membrane electron transport

Since redox active metals are often transported across membranes into cells in the reduced state, we have investigated whether exogenous ferri-heme or heme bound to hemopexin (HPX), which delivers heme to cells via receptor-mediated endocytosis, interact with a cell growth-associated plasma membrane electron transport (PMET) pathway. PMET reduces the cell-impermeable tetrazolium salt, WST-1, in the presence of the mandatory low potential intermediate electron acceptor, mPMS. In human promyelocytic (HL60) cells, protoheme (iron protoporphyrin IX; 2,4-vinyl), mesoheme (2,4-ethyl) and deuteroheme (2,4-H) inhibited reduction of WST-1/mPMS in a saturable manner supporting interaction with a finite number of high affinity acceptor sites (Kd 221 nM for naturally occurring protoheme). A requirement for the redox-active iron was shown using gallium-protoporphyrin IX (PPIX) and tin-PPIX. Heme-hemopexin, but not apo-hemopexin, also inhibited WST-1 reduction, and copper was required. Importantly, since neither heme nor heme-hemopexin replace mPMS as an intermediate electron acceptor and since inhibition of WST-1/mPMS reduction requires living cells, the experimental evidence supports the view that heme and heme-hemopexin interact with electrons from PMET. We therefore propose that heme and heme-hemopexin are natural substrates for this growth-associated electron transfer across the plasma membrane.     

Thermodynamics of heme-induced conformational changes in hemopexin: role of domain-domain interactions.

Hemopexin is a serum glycoprotein that binds heme with high affinity and delivers heme to the liver cells via receptor-mediated endocytosis. A hinge region connects the two non-disulfide-linked domains of hemopexin, a 35-kDa N-terminal domain (domain I) that binds heme, and a 25-kDa C-terminal domain (domain II). Although domain II does not bind heme, it assumes one structural state in apo-hemopexin and another in heme-hemopexin, and this change is important in facilitating the association of heme-hemopexin with its receptor. In order to elucidate the structure and function of hemopexin, it is important to understand how structural information is transmitted to domain II when domain I binds heme. Here we report a study of the protein-protein interactions between domain I and domain II using analytical ultracentrifugation and isothermal titration calorimetry. Sedimentation equilibrium analysis showed that domain I associates with domain II both in the presence and absence of heme with Kd values of 0.8 microM and 55 microM, respectively. The interaction between heme-domain I and domain II has a calorimetric enthalpy of +11 kcal/mol, a heat capacity (delta Cp) of -720 cal/mol.K, and a calculated entropy of +65 cal/mol.K. By varying the temperature of the centrifugation equilibrium runs, a van't Hoff plot with an apparent change in enthalpy (delta H) of -3.6 kcal/mol and change in entropy (delta S) of +8.1 cal/mol.K for the association of apo-domain I with domain II was obtained.(ABSTRACT TRUNCATED AT 250 WORDS)     

Importance of ligand-induced conformational changes in hemopexin for receptor-mediated heme transport

Hemopexin alters conformation upon binding heme as shown by circular dichroism (CD), but hemopexin binds the heme analog, iron-meso-tetra-(4-sulfonatophenyl)-porphine (FeTPPS), without undergoing concomitant changes in its CD spectrum. Moreover, FeTPPS, unlike heme, does not increase the compactness of the heme-binding domain (I) of hemopexin shown by an increased sedimentation rate in sucrose gradients. On the other hand, like heme, FeTPPS forms a bishistidyl coordination complex with hemopexin and upon binding protects hemopexin from cleavage by plasmin. Competitive inhibition and saturation studies demonstrate that FeTPPS-hemopexin binds to the hemopexin receptor on mouse hepatoma cells but with a lower affinity (Kd 125 nM) more characteristic of apo-hemopexin than heme-hemopexin (Kd 65 nM). This provides evidence that conformational changes produced in hemopexin upon binding heme, but not upon binding FeTPPS, are important for increasing the affinity of hemopexin for its receptor. The amount of cell-associated radiolabel from 55FeTPPS-hemopexin increases linearly for up to 90 min but at a rate only about a third of that of the mesoheme-complex. As expected from the recycling of hemopexin, more iron-tetrapyrrole than protein is associated with the Hepa cells, but the ratio of 55Fe-ligand to 125I-hemopexin is only 2:1 for FeTPPS-hemopexin compared to 4:1 for mesoheme complexes. [55Fe]Mesoheme was associated at 5 min with lower density fractions containing plasma membranes and at 30 min with fractions containing higher density intracellular compartments. In contrast, 55FeTPPS was found associated with plasma membrane fractions at both times and was not transported into the cell. Although FeTPPS-hemopexin binds to the receptor, subsequent events of heme transport are impaired. The results indicate that upon binding heme at least three types of conformational changes occur in hemopexin which have important roles in receptor recognition and that the nature of the ligand influences subsequent heme transport.     

Epr Studies on the Effects of Complexation of Heme by Hemopexin upon its Reactions with Organic Peroxides

Hemopexin, a heme-binding serum glycoprotein, is thought to play an important role in the prevention of oxidative damage that may be catalysed by free heme. Through the use of EPR techniques, the generation of free radicals from organic hydroperoxides by heme and heme-hemopexin complexes, and the concomitant formation of high oxidation-state iron species has been studied; these species are implicated as causative agents in processes such as cardiovascular disease and carcinogenesis. From the rates of production of these species from both n-alkyl and branched hydroperoxides, it has been inferred that the dramatic reduction in the yield of oxidising species generated by heme upon its complexation with hemopexin arises from steric hindrance of the access of hydroperoxide to the bound heme.     

Hemopexin in the human retina: Protection of the retina against heme-mediated toxicity

The existence of the blood-retinal barrier means that proteins that protect the retina from damage by reactive oxygen species must either be made locally or specifically transported across the barrier cells; however, such transepithelial transport does not seem to occur. Among the circulatory proteins that protect against iron-catalyzed production of free radicals are apo-transferrin, which binds ferric iron and has previously been shown to be made by cells of the neural retina (Davis and Hunt, 1993, J. Cell Physiol., 156:280–285), and the extracellular antioxidant, apo-hemopexin, which binds free heme (iron-protoporphyrin IX). Since hemorrhage and heme release can be important contributing factors in retinal disease, evidence of a hemopexin-based retinal protection system was sought. The human retina has been shown to contain apo-hemopexin which is probably synthesized locally since its mRNA can be detected in retinal tissue dissected from human donor eyes. It is likely that the retina contains a mechanism for the degradation of hemopexin-bound heme since the blood-retinal barrier also precludes the exit of heme-hemopexin from the retina. Retinal pigment epithelial cells have been found to bind and internalize heme-hemopexin in a temperature-dependent, saturable, and specific manner, analogous to the receptor-mediated endocytic system of hepatoma cells. Moreover, the binding of heme-hemopexin to the cells stimulates the expression of heme oxygenase-1, metallothionein-1, and ferritin. © 1996 Wiley-Liss, Inc.     

Protein-mediated efflux of heme from isolated rat liver mitochondria

Proteins are required for the efflux of heme from mitochondria and liposomes. The efflux from liposomes is independent of the heme-binding affinity of the protein (Biochem. 23:3715, 1984). We tested whether heme-binding proteins increase efflux of newly synthesized heme from structurally and functionally intact rat liver mitochondria. Mitochondria whose heme was labeled with 14C-delta-aminolevulinic acid, were incubated in the presence of glutathione transferases (GSTs), serum albumin (RSA) or heme-binding protein (HBP), all from the rat. HBP caused a 6-8 fold increase in efflux of newly synthesized heme as compared to that effected by RSA or GSTs. This result indicates that heme efflux from intact mitochondria, unlike that from liposomes, depends on the type of protein present and that HBP may specifically facilitate heme efflux from mitochondria.     

Cell surface receptor for hemopexin in human leukemia HL60 cells. Specific binding, affinity labeling, and fate of heme

The binding of 125I-labeled human hemopexin to human leukemia HL60 cell at 4 degrees C was saturable with time and with increasing concentrations of 125I-hemopexin. Scatchard analysis of the binding data revealed the presence of approximately 42,000 binding sites/cell with an apparent dissociation constant (Kd) of 1.0 X 10(-9) M. When cells were incubated with radioactive hemopexin at 37 degrees C, 125I-hemopexin was rapidly bound and then was dissociated after the release of heme. Treatment of surface-bound 125I-hemopexin with divalent lysine-directed cross-linking disuccinimidyl suberate revealed a membrane polypeptide of about 80,000 Da, to which hemopexin is cross-linked. To examine the fate of the internalized heme, lysates from the cells previously incubated with [59Fe]heme-hemopexin complex were analyzed by CM-cellulose and Sephacryl S-200 column chromatography. A considerable amount of the radioactivity was present in the fraction which co-eluted with the myeloperoxidase activity. When myeloperoxidase was isolated from the cells incubated with [59Fe]heme-hemopexin complex by immunoprecipitation with anti-myeloperoxidase antibody, radiolabeled iron associated with myeloperoxidase increased with time, and more than 30% of the radioactivity in the cells was present in the myeloperoxidase. These results indicate that the binding of hemopexin to the surface receptors triggers a release of heme and that this heme is incorporated into the intracellular myeloperoxidase.     

Transport of heme by hemopexin to the liver: Evidence for receptor-mediated uptake

We used carefully defined heme-hemopexin complexes to investigate the role of hemopexin in the catabolism of heme in vivo. Uptake of rabbit [⁵⁹Fe]heme-[¹²⁵I]hemopexin by rat liver was rapid. The liver-associated ¹²⁵I reached a maximum 5 minutes after injection, nearly 7-fold higher than apo-hemopexin, whereas liver-associated ⁵⁹Fe increased with time. This together with an inverse relationship of [¹²⁵I]hemopexin in the liver and serum during the course of heme transport suggests that hemopexin was released from the liver back to the circulation. Saturation of uptake with heme-hemopexin, reaching about 170 pmol [¹²⁵I]hemopexin (gm liver)^?1 5 minutes after injection of 11 nmol, indicates a receptor-mediated process.We conclude that hemopexin delivers heme to the liver via interaction with a finite number of receptors and returns to the circulation.     

Hemoglobin-haptoglobin receptor in rat liver plasma membrane

The presence of a receptor specific for the hemoglobin . haptoglobin complex is demonstrated in rat liver plasma membranes. Hemoglobin . haptoglobin complex, administered intravenously to rats, was cleared from the circulation at a constant rate with exclusive incorporation of the molecule into hepatocytes. This incorporation was unaffected by the simultaneous injection of asialoglycoprotein or heme . hemopexin complex. In vitro experiments with isolated liver plasma membranes indicated the absence of competitive binding of these molecules to the membrane and suggested that this receptor might recognize an altered conformation of the haptoglobin moiety of the complex resulting from the binding with hemoglobin. These observations suggest that the mechanism of recognition and binding of hemoglobin . haptoglobin complex by the receptor is different from that of the asialoglycoprotein receptor or heme . hemopexin receptor.     

Biochemical properties of the heme oxygenase inhibitor, Sn-protoporphyrin. Interactions with apomyoglobin and human serum albumin

Sn-protoporphyrin is a strong competitive inhibitor of heme oxygenase and a potential pharmacological agent for the treatment of neonatal hyperbilirubinemia. Little is otherwise known about the biochemistry of tin porphyrins. We have investigated aspects of the chemistry of tin-protoporphyrin in aqueous solution and of its interactions with heme-binding proteins other than heme oxygenase, specifically apomyoglobin and human serum albumin. In the pH region 7-10, Soret region absorption studies of unbound Sn-protoporphyrin demonstrate a pH-dependent monomer-dimer equilibrium (KD congruent to 10(6) M-1 at pH 7) with little higher aggregation. Dissociation of the dimer is relatively slow at neutral pH, permitting interaction of protein ligands with monomeric and dimeric species to be distinguished and providing insights into kinetic mechanisms of porphyrin binding by heme-binding proteins. In the present study, the kinetics of interaction of Sn-protoporphyrin with apomyoglobin are presented as novel evidence that this binding proceeds by an induced fit mechanism. Binding of Sn-protoporphyrin to both apomyoglobin and serum albumin is unexpectedly weak. Between pH 7 and 9, the apparent affinity of Sn-protoporphyrin for apomyoglobin is less than 1/200 that of heme and, at pH 9, is also significantly less than that of protoporphyrin. The apparent affinity of Sn-protoporphyrin for human serum albumin is less than 1/1000 that of heme and 1/30 to 1/100 that of protoporphyrin. Competition studies between heme and Sn-protoporphyrin and between bilirubin and Sn-protoporphyrin indicate that Sn-protoporphyrin distributes differently among porphyrin-binding sites on serum albumin than does heme and that it is also not an effective competitor with bilirubin for bilirubin-binding sites. These results argue that Sn-protoporphyrin should not significantly alter normal mechanisms for the binding and transport of heme or of preformed bilirubin by serum albumin. From a more general perspective, the results indicate potentially unusual binding site selectivity by tin chelates; possible origins of this selectivity are discussed.     

A protein of the Z class of liver cytosolic proteins in the rat that preferentially binds heme

A low molecular weight protein purified from rat liver cytosol was observed to bind heme with an affinity higher than that for other organic anions. Purification was achieved by two procedures, one employing affinity chromatography on oleic acid-agarose, and the other using sequential ion-exchange and gel filtration chromatography after initial removal of aprotinin-sensitive proteases. Removal rather than inhibition of proteases improved the yield four times. Both procedures produced a stable protein. The purified protein binds heme with a higher affinity (Kd 0.15 microM) than any other organic anion tested including other (metallo)porphyrins, bilirubin, and oleic acid. Based on its molecular weight, amino acid composition, immunological properties, and the increase of its tissue levels in response to the administration of hypolipidemic agents, the protein was identified as being related to proteins of the Z class, whose members include fatty acid binding protein and sterol carrier protein. Like other Z proteins, our protein exhibits several forms on electrofocusing, but differs from fatty acid-binding protein and sterol carrier protein in that its major form exhibits a pI of 7.4. In view of its distinct isoelectric focusing pattern, its higher affinity for heme than for oleic acid, and its apparent inability to bind cholesterol and steroids, we cannot identify this protein as any of the above-mentioned proteins of the Z class. Consequently we have provisionally designated it heme-binding protein.     

Isolation of the haemopexin-haem receptor from pig liver cells

Isolated pig liver plasma membranes interact specifically with the haemopexin-haem complex (Kd 4.4 X 10(-7) M). Affinity chromatography was used to isolate a membrane component which binds this complex with high affinity. Pig serum haemopexin was first isolated by affinity chromatography on haemin-Sepharose followed by HPLC gel filtration. Liver membranes solubilized with Triton X-100 were incubated with haemin-Sepharose saturated with haemopexin, and as a control, with affinity gel lacking haemopexin. SDS-poly-acrylamide gel electrophoresis of the eluted protein indicated that from the haemin-Sepharose emerglow-molecular-mass haemin-binding proteins whereas the eluate from haemopexin-haemin-Sepharose contained an additional 71 kDa protein, which did not bind free haemin. This protein appears to represent the haemopexin-haem receptor or a part of it. Haem from the haemopexin complex, as also free haemin, was accepted by a binder in the plasma membrane, which in gel filtration behaved like an 80 kDa molecule. This component probably represents a second functional subunit of the haemopexin-haem receptor.     

Purification and properties of heme oxygenase from rat liver microsomes.

Heme oxygenase was purified to apparent homogeneity from liver microsomes of rats which had been treated with either cobaltous chloride or hemin to induce heme oxygenase in the liver and the purified preparations from either rats showed an apparent molecular weight of about 200,000 when estimated by gel filtration on a column of Sephadex G-200, and gave a minimum molecular weight of about 32,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The hepatic heme oxygenase could bind heme to form a heme . heme oxygenase complex showing an absorption peak at 405 nm, and the extinction coefficient at 405 nm of the heme . heme oxygenase complex was 140 mM-1 cm-1. The heme bound to the hepatic heme oxygenase protein was easily converted to biliverdin when the complex was incubated with the NADPH-cytochrome c reductase system in air. The hepatic heme oxygenase appears to have characteristics essentially similar to those of the splenic heme oxygenase (Yoshida, T., and Kikuchi, G. (1978) J. Biol. Chem. 253, 4224 and 4230). The heme oxygenase preparation which was purified from the cobalt-treated rats contained a small amount of cobaltic protoporphyrin, indicating that cobalt protoporphyrin was synthesized in these rats.     

Interaction of hemopexin with Sn-protoporphyrin IX, an inhibitor of heme oxygenase. Role for hemopexin in hepatic uptake of Sn-protoporphyrin IX and induction of mRNA for heme oxygenase

Sn-protoporphyrin IX (SnPP), an inhibitor of heme oxygenase and a potential therapeutic agent for neonatal hyperbilirubinemia, is bound tightly by hemopexin. The apparent dissociation constant (Kd) at pH 7.4 is 0.25 +/- 0.15 microM, but estimation of the Kd for the SnPP-hemopexin complex is hampered by the fact that at physiological pH SnPP exists as monomers and dimers, both of which are bound by hemopexin. SnPP is readily displaced from hemopexin by heme (Kd less than 1 pM). The hemopexin-SnPP interaction, like that of heme-hemopexin, is dependent on the histidine residues of hemopexin. However, as expected from the differences in the coordination chemistries of tin and iron, the stability of the histidyl-metalloporphyrin complex is lower for SnPP-hemopexin than for mesoheme-hemopexin. Nevertheless, when SnPP binds to hemopexin, certain of the ligand-induced changes in the conformation of hemopexin which increase the affinity of the protein for its receptor are produced. Binding of SnPP produces the conformational change in hemopexin which protects the hinge region of hemopexin from proteolysis, but SnPP does not produce the characteristic increase in the ellipticity of hemopexin at 231 nm that heme does. Competition experiments confirmed that human serum albumin (apparent Kd = 4 +/- 2 microM) has a significantly lower affinity for SnPP than does hemopexin. Appreciable amounts of SnPP (up to 35% in adults and 20% in neonates) would be bound by hemopexin in the circulation, and the remainder of SnPP would be associated with albumin due to the latter's high concentration in serum. Essentially no non-protein-bound SnPP is present. Importantly, SnPP-hemopexin binds to the hemopexin receptor on mouse hepatoma cells with an affinity comparable to that of heme-hemopexin and treatment of the hepatoma cells with SnPP-hemopexin causes a rapid increase in the steady state level of heme oxygenase messenger RNA. These results show that hemopexin participates in the transport of SnPP to heme oxygenase and in its regulation by SnPP.     

The lipocalin alpha(1)-microglobulin binds heme in different species

The lipocalin alpha(1)-microglobulin (alpha(1)m), found in plasma and tissues of various vertebrates, is brown, forms complexes with other proteins and has immunomodulatory effects in vitro, but the physiological function is not yet established. Human alpha(1)m was recently shown to bind heme and, after cleavage of a C-terminal tetrapeptide, initiate heme degradation, thus suggesting a heme-scavenger function. In this work the heme-binding of alpha(1)m was characterized using heme immobilized on agarose beads, spectrophotometry, and electrophoresis. alpha(1)m, both in plasma and in purified form, displayed a concentration-dependent binding to heme-agarose. The apparent dissociation-constant was estimated to be around 2 x 10(-6)M for both free alpha(1)m and the IgA-alpha(1)m complex. Incubation with free heme resulted in two forms of alpha(1)m with different electrophoretic mobility. alpha(1)m, identified on Western blotting, was found in eluates from heme-agarose after incubation with human biological fluids as well as sera from non-human species, indicating evolutionary conservation of the heme-binding property. Heme-binding could be instrumental for isolating new alpha(1)m-homologues.