An alternative view of the proposed alternative activities of hemopexin.

Hemopexin is a plasma protein that plays a well-established biological role in sequestering heme that is released into the plasma from hemoglobin and myoglobin as the result of intravascular or extravascular hemolysis as well as from skeletal muscle trauma or neuromuscular disease. In recent years, a variety of additional biological activities have been attributed to hemopexin, for example, hyaluronidase activity, serine protease activity, pro-inflammatory and anti-inflammatory activity as well as suppression of lymphocyte necrosis, inhibition of cellular adhesion, and binding of divalent metal ions. This review examines the challenges involved in the purification of hemopexin from plasma and in the recombinant expression of hemopexin and evaluates the questions that these challenges and the characteristics of hemopexin raise concerning the validity of many of the new activities proposed for this protein. As well, an homology model of the three-dimensional structure of human hemopexin is used to reveal that the protein lacks the catalytic triad that is characteristic of many serine proteases but that hemopexin possesses two highly exposed Arg-Gly-Glu sequences that may promote interaction with cell surfaces.

Metal ions and electrolytes regulate the dissociation of heme from human hemopexin at physiological pH.

The stability of the hemopexin-heme (Hx-heme) complex to dissociation of the heme prosthetic group has been examined in bicarbonate buffers in the presence and absence of various divalent metal ions. In NH(4)HCO(3) buffer (pH 7.4, 20 mm, 25 degrees C) containing Zn(2+) (100 microm), 14% of the heme dissociates from this complex (4.5 microm) within 10 min, and 50% dissociates within 2 h. In the absence of metal ions, the rate of dissociation of this complex is far lower, is decreased further in KHCO(3) solution, and is minimal in NaHCO(3). In NH(4)HCO(3) buffer, dissociation of the Hx-heme complex is accelerated by addition of divalent metals with decreasing efficiency in the order Zn(2+) > Cu(2+) >> Ni(2+) > Co(2+)>>Mn(2+). Addition of Ca(2+) prior to addition of Zn(2+) stabilizes the Hx-heme complex to dissociation of the heme group, and addition of Ca(2+) after Zn(2+)-induced dissociation of the Hx-heme complex results in re-formation of the Hx-heme complex. These effects are greatly accelerated at 37 degrees C and diminished in other buffers. Overall, the solution conditions that promote formation of the Hx-heme complex are similar to those found in blood plasma, and conditions that promote release of heme are similar to those that the Hx-heme complex should encounter in endosomes following endocytosis of the complex formed with its hepatic receptor.

Metal ion facilitated dissociation of heme from b-type heme proteins.

Addition of Ni(2+), Cu(2+), or Zn(2+) (10-40 equiv) to metMb in sodium bicarbonate buffer (25 degrees C) at alkaline pH (7.8-9.5) results in a time-dependent (2-6 h) change in the electronic absorption spectrum of the protein that is consistent with dissociation of the heme from the active site and that can be largely reversed by addition of EDTA. Similar treatment of cytochrome b(5), indoleamine 2,3-dioxygenase, and cytochrome P450(cam) (in the presence or absence of camphor) produces a similar spectroscopic response. Elution of metMb treated with Ni(2+) in this manner over an anion exchange column in buffer containing Ni(2+) affords apo-myoglobin without exposure to acidic pH or organic solvents as usually required. Bovine liver catalase, in which the heme groups are remote from the surface of the protein, and horseradish peroxidase, which has four disulfide bonds and just three histidyl residues, exhibit a much smaller spectroscopic response. We propose that formation of carbamino groups by reaction of bicarbonate with protein amino groups promotes both protein solubility and the interaction of the protein with metal ions, thereby avoiding precipitation while destabilizing the interaction of heme with the protein. From these observations, bicarbonate buffers may be of value in the study of nonmembrane proteins of limited solubility.

Chromatographically distinguishable heme insertion isoforms of human hemopexin.

Two spectroscopically distinct, non-interconverting forms of human hemopexin have been isolated by immobilized metal ion affinity chromatography and characterized spectroscopically. Form alpha (characterized by a bisignate Soret CD spectrum) and form beta (Soret CD characterized by a positive Cotton effect) exhibit different spectroscopic responses to addition of Zn2+ or Cu2+, yet both forms exhibit the same metal ion-induced decrease in Tm for the thermally induced release of the heme prosthetic group. Far UV-CD spectra indicate that the two isoforms possess essentially identical secondary structures, but their differential retention during metal ion affinity chromatography indicates slight differences in exposure of His residues on the protein surface. We propose that these observations result from the binding of heme in form beta with an orientation that differs from the crystallographically observed binding orientation for rabbit hemopexin by rotation of the heme prosthetic group by 180 degrees about the alpha-gamma meso-carbon axis and from interaction of metal ions at two separate binding sites.

Effects of metal ion binding on structural dynamics of human hemopexin.

Hemopexin (Hx) functions as a major heme scavenging protein in blood plasma and as such circulates without heme bound. In recent work, we have demonstrated that Hx binds metal ions in vitro in a manner that varies from one metal ion to another and that changes with heme binding. The structural consequences of metal ion binding to the form of Hx that dominates in plasma have now been evaluated by monitoring metal ion-linked changes in tertiary structure of the protein as reflected by changes in the near-UV CD spectrum and the ultraviolet absorption spectrum as a function of temperature. As part of this analysis we have developed thermally induced difference absorption maps (TIDAMs) to afford efficient visualization of temperature-dependent changes in the UV spectrum of Hx that are induced by binding of metal ions. The results are interpreted in terms of recent models proposed for metal ion binding sites on Hx and have implications for the possible modulation of heme binding to Hx by metal ions in vivo.

Functional characterization of the dimerization domain of the ferric uptake regulator (Fur) of Pseudomonas aeruginosa.

The functional properties of the recombinant C-terminal dimerization domain of the Pseudomonas aeruginosa Fur (ferric uptake regulator) protein expressed in and purified from Escherichia coli have been evaluated. Sedimentation velocity measurements demonstrate that this domain is dimeric, and the UV CD spectrum is consistent with a secondary structure similar to that observed for the corresponding region of the crystallographically characterized wild-type protein. The thermal stability of the domain as determined by CD spectroscopy decreases significantly as pH is increased and increases significantly as metal ions are added. Potentiometric titrations (pH 6.5) establish that the domain possesses a high-affinity and a low-affinity binding site for metal ions. The high-affinity (sensory) binding site demonstrates association constants (K(A)) of 10(+/-7)x10(6), 5.7(+/-3)x10(6), 2.0(+/-2)x10(6) and 2.0(+/-3)x10(4) M(-1) for Ni2+, Zn2+, Co2+ and Mn2+ respectively, while the low-affinity (structural) site exhibits association constants of 1.3(+/-2)x10(6), 3.2(+/-2)x10(4), 1.76(+/-1)x10(5) and 1.5(+/-2)x10(3) M(-1) respectively for the same metal ions (pH 6.5, 300 mM NaCl, 25 degrees C). The stability of metal ion binding to the sensory site follows the Irving-Williams order, while metal ion binding to the partial sensory site present in the domain does not. Fluorescence experiments indicate that the quenching resulting from binding of Co2+ is reversed by subsequent titration with Zn2+. We conclude that the domain is a reasonable model for many properties of the full-length protein and is amenable to some analyses that the limited solubility of the full-length protein prevents.

Metal ion binding to human hemopexin.

Binding of divalent metal ions to human hemopexin (Hx) purified by a new protocol has been characterized by metal ion affinity chromatography and potentiometric titration in the presence and absence of bound protoheme IX. ApoHx was retained by variously charged metal affinity chelate resins in the following order: Ni(2+) > Cu(2+) > Co(2+) > Zn(2+) > Mn(2+). The Hx-heme complex exhibited similar behavior except the order of retention of the complex on Zn(2+)- and Co(2+)-charged columns was reversed. One-dimensional (1)H NMR of apoHx in the presence of Ni(2+) implicates at least two His residues and possibly an Asp, Glu, or Met residue in Ni(2+) binding. Potentiometric titrations establish that apoHx possesses more than two metal ion binding sites and that the capacity and/or affinity for metal ion binding is diminished when heme binds. For most metal ions that have been studied, potentiometric data did not fit to binding isotherms that assume one or two independent binding sites. For Mn(2+), however, these data were consistent with a high-affinity site [K(A) = (15 +/- 3) x 10(6) M(-)(1)] and a low-affinity site (K(A)

pH- and metal ion-linked stability of the hemopexin-heme complex.

Thermal denaturation of the human hemopexin-heme complex was investigated under a variety of solution conditions to identify factors that influence heme release. The midpoint temperature for the transition between the folded and folded states, T(m), of the hemopexin-ferriheme complex exhibits a significant dependence on pH. When the pH is reduced from 7 to 5 (50 mM BisTris buffer and 50 mM NaCl), T(m) decreases by approximately 23 degrees C despite the relatively higher chloride concentration that tends to stabilize the protein. The thermal stability of the hemopexin-ferroheme complex was examined at pH 7.4 to yield a T(m) that is 3.2 degrees C lower than that of the hemopexin-ferriheme complex under identical conditions. The effect of transition metal ions, which hemopexin has recently been shown to bind [Mauk, M. R., Rosell, F. I., Lelj-Garolla, B., Moore, G. R., and Mauk, A. G. (2005) Biochemistry 44, XXXX-XXXX], was also considered. Cu(2+) and Zn(2+) had the greatest effect, reducing T(m) for the transition by 4.8 and 6.5 degrees C, respectively, relative to the value for the protein in the absence of metal ions [T(m) = 64.9 degrees C [10 mM sodium phosphate buffer (pH 7.4)]]. These metal ions also interfered significantly with the recovery of the native state from the unfolded protein when the protein on returning to 20 degrees C. The current results demonstrate how the conditions within the endosomes of hepatocytes (pH approximately 5.0, [Cl(-)] approximately 60 mM) and the potential presence of transition metal ions or heme iron reduction contribute to the membrane receptor-mediated process of heme release from hemopexin.

Introduction and characterization of a functionally linked metal ion binding site at the exposed heme edge of myoglobin.

A binding site for metal ions has been created on the surface of horse heart myoglobin (Mb) near the heme 6-propionate group by replacing K45 and K63 with glutamyl residues. One-dimensional (1)H NMR spectroscopy indicates that Mn(2+) binds in the vicinity of the heme 6-propionate as anticipated, and potentiometric titrations establish that the affinity of the new site for Mn(2+) is 1.28(4) x 10(4) M(-1) (pH 6.96, ionic strength I = 17.2 microM, 25 degrees C). In addition, these substitutions lower the reduction potential of the protein and increase the pK(a) for the water molecule coordinated to the heme iron of metmyoglobin. The peroxidase [2,2'-azinobis(3-ethylbenzthiazoline-6-sulfonic acid), ABTS, as substrate] and the Mn(2+)-peroxidase activity of the variant are both increased approximately 3-fold. In contrast to wild-type Mb, both the affinity for azide and the midpoint potential of the variant are significantly influenced by the addition of Mn(2+). The structure of the variant has been determined by x-ray crystallography to define the coordination environment of bound Mn(2+) and Cd(2+). Although slight differences are observed between the geometry of the binding of the two metal ions, both are hexacoordinate, and neither involves coordination by E63.