Stabilizing roles of residual structure in the empty heme binding pockets and unfolded states of microsomal and mitochondrial apocytochrome b5

The microsomal (Mc) and mitochondrial (OM) isoforms of mammalian cytochrome b5 are the products of different genes, which likely arose via duplication of a primordial gene and subsequent functional divergence. Despite sharing essentially identical folds, heme-polypeptide interactions are stronger in OM b5s than in Mc b5s due to the presence of two conserved patches of hydrophobic amino acid side chains in the OM heme binding pockets. This is of fundamental interest in terms of understanding heme protein structure-function relationships, because stronger heme-polypeptide interactions in OM b5s in comparison to Mc b5s may represent a key source of their more negative reduction potentials. Herein we provide evidence that interactions amongst the amino acid side chains contributing to the hydrophobic patches in rat OM (rOM) b5 persist when heme is removed, rendering the empty heme binding pocket of rOM apo-b5 more compact and less conformationally dynamic than that in bovine Mc (bMc) apo-b5. This may contribute to the stronger heme binding by OM apo-b5 by reducing the entropic penalty associated with polypeptide folding. We also show that when bMc apo-b5 unfolds it adopts a structure that is more compact and contains greater nonrandom secondary structure content than unfolded rOM apo-b5. We propose that a more robust beta-sheet in Mc apo-b5s compensates for the absence of the hydrophobic packing interactions that stabilize the heme binding pocket in OM apo-b5s.     

Divergence in nonspecific hydrophobic packing interactions in the apo state, and its possible role in functional specialization of mitochondrial and microsomal cytochrome b5

The outer mitochondrial membrane isoform of mammalian cytochrome b(5) (OM b(5)) is distinguished from the microsomal isoform (Mc b(5)) by its considerably greater stability. In contrast, OM and Mc apocytochrome b(5) (apo-b(5)) exhibit similar thermodynamic stability. Contributing substantially to the greater stability of OM b(5) relative to that of Mc b(5) is the presence of Leu at position 71. Replacing Leu-71 in OM b(5) with the corresponding Mc b(5) residue (Ser) not only diminishes holoprotein stability but also markedly compromises apoprotein stability. The studies reported herein were undertaken to clarify the role played by Leu-71 in stabilizing OM b(5)s relative to Mc b(5)s, and were motivated by the possibility that stability is related to other differences in OM and Mc b(5) properties that are important for their specialized subcellular roles. The results of these studies show that Leu-71 plays an essential role in maintaining the structural integrity of the heme-independent folding core of OM apo-b(5) (core 2), despite its location in the disordered empty heme-binding pocket (core 1). The conformational integrity of core 2 in Mc apo-b(5)s is not similarly dependent on the presence of a hydrophobic residue at position 71, providing new evidence for evolution of compensating structural features not present in OM b(5)s. We propose that Leu-71 achieves its effect on OM apo-b(5) core 2 structure by participating in a nonspecific hydrophobic collapse of disordered core 1, templated by more conformationally restricted side chains of residues in the beta-sheet that separates the two cores. We hypothesize that this has the added effect of maintaining core 1 of OM apo-b(5)s in a state more compact than that which occurs in Mc apo-b(5)s, possibly contributing to stronger heme binding by limiting the number of non-native conformations that the empty heme-binding pocket can populate.     

A histidine/tryptophan pi-stacking interaction stabilizes the heme-independent folding core of microsomal apocytochrome b5 relative to that of mitochondrial apocytochrome b5

The outer mitochondrial membrane isoform of mammalian cytochrome b5 (OM b5) is considerably more stable than its microsomal counterpart (Mc b5), whereas the corresponding apoproteins (OM and Mc apo-b5) exhibit similar stability. OM and Mc apo-b5 are also similar in that their empty heme-binding pockets (core 1) are highly disordered but that the remainder of each apoprotein (core 2) displays substantial hololike structure. Core 1 residue 71 is leucine in all known mammalian OM b5's and serine in the corresponding Mc proteins. Replacing Leu-71 in rat OM (rOM) b5 with Ser has been shown to (1) decrease apoprotein thermodynamic stability by >2 kcal/mol and (2) extend conformational disorder beyond core 1 and into core 2, as evidenced in part by loss of a near-UV circular dichroism signal associated with the side chain of invariant residue Trp-22. Herein we report identification of a conserved Mc b5 core 2 packing motif that plays a key role in stabilizing apoprotein conformation in the vicinity of Trp-22, thereby compensating for the presence of Ser at position 71: a pi-stacking interaction between the side chains of Trp-22 and His-15 that is extended by hydrogen bonding between the side chains of His-15, Ser-20, and Glu-11. The corresponding conserved packing motif in OM b5's differs in having arginine at position 15 and glutamate at position 20. We also present evidence indicating that the conserved Mc b5 packing motif noted above contributes to the unusually extensive secondary structure exhibited by bovine Mc apo-b5 in the urea-denatured state.     

Mitochondrial and microsomal ferric b5 cytochromes exhibit divergent conformational plasticity in the context of a common fold

Native-state hydrogen-deuterium exchange (HDX) monitored by NMR spectroscopy has been used to compare conformational plasticity in ferric rat liver outer mitochondrial membrane cytochrome b5 (rOM b5) and ferric bovine liver microsomal cytochrome b5 (bMc b5). Analysis of the data indicated that rOM b5 is the less conformationally flexible protein on the time scale probed by the HDX experiments. The data also suggest a likely contributor to the much higher kinetic barrier for the release of hemin from OM b5s in comparison to Mc b5s, a characteristic that may be to a large extent the source of their divergent functional properties. Specifically, the data indicate that conformational mobility within helices alpha4 and alpha5, which flank the loop harboring axial ligand His63, is considerably more restricted in rOM b5 than in bMc b5. The lower conformational flexibility of alpha4 and alpha5 in rOM b5 can reasonably be attributed to more extensive hydrophobic packing in that region of the protein, arising from two conserved side chain packing motifs in OM cytochrome b5s [Altuve, A., Wang, L., Benson, D. R., and Rivera, M. (2004) Biochem. Biophys. Res. Commun. 314, 602-609].     

Mammalian mitochondrial and microsomal cytochromes b(5) exhibit divergent structural and biophysical characteristics

The only outer mitochondrial membrane cytochrome b(5) examined to date, from rat (rOM b(5)), exhibits greater stability than known mammalian microsomal (Mc) isoforms, as well as a much higher kinetic barrier for hemin dissociation and a more negative reduction potential. A BlastP search of available databases using the protein sequence of rOM b(5) as template revealed entries for analogous proteins from human (hOM b(5)) and mouse (mOM b(5)). We prepared a synthetic gene coding for the heme-binding domain of hOM b(5), and expressed the protein to high levels. The hOM protein exhibits stability, hemin-binding, and redox properties similar to those of rOM b(5), suggesting that they are characteristic of the OM b(5) subfamily. The divergence in properties between the OM and Mc b(5) isoforms in mammals can be attributed, at least in part, to the presence of two extended hydrophobic patches in the former. The biophysical properties characteristic of the OM proteins may be important in facilitating the two functions proposed for them so far, reduction of ascorbate radical and stimulation of androgen synthesis.     

Influence of point mutations on the flexibility of cytochrome b5: molecular dynamics simulations of holoproteins

Two membrane-bound isoforms of cytochrome b5 have been identified in mammals, one associated with the outer mitochondrial membrane (OM b5) and the other with the endoplasmic reticulum (microsomal, or Mc b5). The soluble heme binding domains of OM and Mc b5 have highly similar three-dimensional structures but differ significantly in physical properties, with OM b5 exhibiting higher stability due to stronger heme association. In this study, we present results of 8.5-ns length molecular dynamics simulations for rat Mc b5, bovine Mc b5, and rat OM b5, as well as for two rat OM b5 mutants that were anticipated to exhibit properties intermediate between those of rat OM b5 and the two Mc proteins: the A18S/I32L/L47R triple mutant (OM3M) and the A18S/I25L/I32L/L47R/L71S quintuple mutant (OM5M). Analysis of the structure, fluctuations, and interactions showed that the five b5 variants used in this study differed in organization of their molecular surfaces and heme binding cores in a way that could be used to explain certain experimentally observed physical differences. Overall, our simulations provided qualitative microscopic explanations of many of the differences in physical properties between OM and Mc b5 and two mutants in terms of localized changes in structure and flexibility. They also reveal that opening of a surface cleft between hydrophobic cores 1 and 2 in bovine Mc b5, observed in two previously reported simulations (E. M. Storch and V. Daggett, Biochemistry, 1995, Vol. 34, pp. 9682-9693; A. Altuve, Biochemistry, 2001, Vol. 40, pp. 9469-9483), probably resulted from removal of crystal contacts and likely does not occur on the nanosecond time scale. Finally, the MD simulations of OM5M b5 verify that stability and dynamic properties of cytochrome b5 are remarkably resistant to mutations that dramatically alter the stability and structure of the apoprotein.     

The distinct heme coordination environments and heme-binding stabilities of His39Ser and His39Cys mutants of cytochrome b5

A gene mutant library containing 16 designed mutated genes at His39 of cytochrome b(5) has been constructed by using gene random mutagenesis. Two variants of cytochrome b(5), His39Ser and His39Cys mutant proteins, have been obtained. Protein characterizations and reactions were performed showing that these two mutants have distinct heme coordination environments: ferric His39Ser mutant is a high-spin species whose heme is coordinated by proximal His63 and likely a water molecule in the distal pocket, while ferrous His39Ser mutant has a low-spin heme coordinated by His63 and Ser39; on the other hand, the ferric His39Cys mutant is a low-spin species with His63 and Cys39 acting as two axial ligands of the heme, the ferrous His39Cys mutant is at high-spin state with the only heme ligand of His63. These two mutants were also found to have quite lower heme-binding stabilities. The order of stabilities of ferric proteins is: wild-type cytochrome b(5) > His39Cys > His39Ser.     

Structural and dynamic perturbations induced by heme binding in cytochrome b5

The water-soluble domain of rat hepatic cytochrome b(5) undergoes marked structural changes upon heme removal. The solution structure of apocytochrome b(5) shows that the protein is partially folded in the absence of the heme group, exhibiting a stable module and a disordered heme-binding loop. The quality of the apoprotein structure in solution was improved with the use of heteronuclear NMR data. Backbone amide hydrogen exchange was studied to characterize cooperative units in the protein. It was found that this criterion distinguished the folded module from the heme-binding loop in the apoprotein, in contrast to the holoprotein. The osmolyte trimethylamine N-oxide (TMAO) did not affect the structure of the apoprotein in the disordered region. TMAO imparted a small stabilization consistent with an unfolded state effect correlating with the extent of buried surface area in the folded region of the native apoprotein. The failure of the osmolyte to cause large conformational shifts in the disordered loop supported the view that the specificity of the local sequence for the holoprotein fold was best developed with the stabilization of the native state through heme binding. To dissect the role of the heme prosthetic group in forcing the disordered region into the holoprotein conformation, the axial histidine belonging to the flexible loop (His63) was replaced with an alanine, and the structural properties of the protein with carbon-monoxide-ligated reduced iron were studied. The His63Ala substitution resulted in a protein with lower heme affinity but nevertheless capable of complete refolding. This indicated that the coordination bond was not necessary to establish the structural features of the holoprotein. In addition, the weak binding of the heme in this protein resulted in conformational shifts at a location distant from the binding site. The data suggested an uneven distribution of cooperative elements in the structure of the cytochrome.     

Toward engineering the stability and hemin-binding properties of microsomal cytochromes b5 into rat outer mitochondrial membrane cytochrome b5: examining the influence of residues 25 and 71

As part of a larger effort to engineer the stability and hemin-binding properties of microsomal (Mc) cytochromes b(5) into rat liver outer mitochondrial membrane (OM) cytochrome (cyt) b(5), several mutants of rat OM cyt b(5) were prepared to study the effect of gradual and complete elimination of two extended hydrophobic networks, which are present in the structure of the mitochondrial protein and are absent in the structure of mammalian Mc cytochromes b(5). One of the hydrophobic networks, identified in a previous study [Altuve, A., Silchenko, S., Lee, K.-H., Kuczera, K., Terzyan, S., Zhang, X., Benson, D. R., and Rivera, M. (2001) Biochemistry 40, 9469-9483], encompasses the side chains of Ala-18, Ile-32, Leu-36, and Leu-47, whereas a second hydrophobic network, identified as part of this work, encompasses the side chains of Ile-25, Phe-58, Leu-71, and the heme. The X-ray structure of the A18S/I25L/I32L/L47R/L71S quintuple mutant of rat OM cyt b(5) demonstrates that both hydrophobic networks have been eliminated and that the corresponding structural elements of the Mc isoform have been introduced. The stability of the rat OM mutant proteins studied was found to decrease in the order wild type > I25L > A18S/I32L/L47R > L71S > A18S/I32L/L47R/L71S > 18S/I25L/I32L/L47R/L71S, indicating that the two hydrophobic networks do indeed contribute to the high stability of rat OM cyt b(5) relative to the bovine Mc isoform. Surprisingly, the quintuple mutant of rat OM cyt b(5) is less stable than bovine Mc cyt b(5), even though the former exhibits significantly slower rates of hemin release and hemin reorientation at pH 7.0. However, at pH 5.0 the bovine Mc and rat OM quintuple mutant proteins release hemin at comparable rates, suggesting that one or both of the His axial ligands in the rat OM protein are more resistant to protonation under physiological conditions. Results obtained from chemical denaturation experiments conducted with the apoproteins demonstrated that mutants containing L71S are significantly less stable than bovine Mc apocyt b(5), strongly suggesting that Leu-71 plays a pivotal role in the stabilization of rat OM apocyt b(5), presumably via hydrophobic interactions with Ile-25 and Phe-58. Because comparable interactions are absent in bovine Mc apocyt b(5), which contains Ser at position 71, it must resort to different interactions to stabilize its fold, thus highlighting yet another difference between rat OM and bovine Mc cyt b(5). During the course of these investigations we also discovered that rat OM cyt b(5) can be made to strongly favor hemin orientational isomer A (I32L) or isomer B (L71S) with a single point mutation and that release of hemin orientational isomers A and B can be kinetically resolved in certain rat OM mutants.     

A cytochrome b562 variant with a c-type cytochrome CXXCH heme-binding motif as a probe of the Escherichia coli cytochrome c maturation system

Cytochrome b562 is a periplasmic Escherichia coli protein; previous work has shown that heme can be attached covalently in vivo as a consequence of introduction of one or two cysteines into the heme-binding pocket. A heterogeneous mixture of products was obtained, and it was not established whether the covalent bond formation was catalyzed or spontaneous. Here, we show that coexpression from plasmids of a variant of cytochrome b562 containing a CXXCH heme-binding motif with the E. coli cytochrome c maturation (Ccm) proteins results in an essentially homogeneous product that is a correctly matured c-type cytochrome. Formation of the holocytochrome was accompanied by substantial production of its apo form, in which, for the protein as isolated, there is a disulfide bond between the two cysteines in the CXXCH motif. Following addition of heme to reduced CXXCH apoprotein, spontaneous covalent addition of heme to polypeptide occurred in vitro. Strikingly, the spectral properties were very similar to those of the material obtained from cells in which presumed uncatalyzed addition of heme (i.e. in the absence of Ccm) had been observed. The major product from uncatalyzed heme attachment was an incorrectly matured cytochrome with the heme rotated by 180 degrees relative to its normal orientation. The contrast between Ccm-dependent and Ccm-independent covalent attachment of heme indicates that the Ccm apparatus presents heme to the protein only in the orientation that results in formation of the correct product and also that heme does not become covalently attached to the apocytochrome b562 CXXCH variant without being handled by the Ccm system in the periplasm. The CXXCH variant of cytochrome b562 was also expressed in E. coli strains deficient in the periplasmic reductant DsbD or oxidant DsbA. In the DsbA- strain under aerobic conditions, c-type cytochromes were made abundantly and correctly when the Ccm proteins were expressed. This contrasts with previous reports indicating that DsbA is essential for cytochrome c biogenesis in E. coli.     

Control of DegP-dependent degradation of c-type cytochromes by heme and the cytochrome c maturation system in Escherichia coli

c-Type cytochromes are located partially or completely in the periplasm of gram-negative bacteria, and the heme prosthetic group is covalently bound to the protein. The cytochrome c maturation (Ccm) multiprotein system is required for transport of heme to the periplasm and its covalent linkage to the peptide. Other cytochromes and hemoglobins contain a noncovalently bound heme and do not require accessory proteins for assembly. Here we show that Bradyrhizobium japonicum cytochrome c550 polypeptide accumulation in Escherichia coli was heme dependent, with very low levels found in heme-deficient cells. However, apoproteins of the periplasmic E. coli cytochrome b562 or the cytosolic Vitreoscilla hemoglobin (Vhb) accumulated independently of the heme status. Mutation of the heme-binding cysteines of cytochrome c550 or the absence of Ccm also resulted in a low apoprotein level. These levels were restored in a degP mutant strain, showing that apocytochrome c550 is degraded by the periplasmic protease DegP. Introduction of the cytochrome c heme-binding motif CXXCH into cytochrome b562 (c-b562) resulted in a c-type cytochrome covalently bound to heme in a Ccm-dependent manner. This variant polypeptide was stable in heme-deficient cells but was degraded by DegP in the absence of Ccm. Furthermore, a Vhb variant containing a periplasmic signal peptide and a CXXCH motif did not form a c-type cytochrome, but accumulation was Ccm dependent nonetheless. The data show that the cytochrome c heme-binding motif is an instability element and that stabilization by Ccm does not require ligation of the heme moiety to the protein.     

Amino-acid sequence of the cytochrome-b5-like heme-binding domain from Hansenula anomala flavocytochrome b2

Flavocytochrome b2 (L-lactate dehydrogenase) from baker's yeast is composed of two structural and functional domains. Its first 100 residues constitute the heme-binding core, which is homologous to cytochrome b5 [B. Guiard, O. Groudinsky & F. Lederer (1974) Proc. Natl Acad. Sci. USA 71, 2539-2543]. We report here the amino acid sequence of the heme-binding domain isolated by tryptic proteolysis of Hansenula anomala flavocytochrome b2. The sequence was established by automated degradation of the whole fragment and of peptides obtained by CNBr cleavage at the unique tryptophan and by proteolysis with thermolysin and endoproteinase Lys C. As isolated, the domain consists of 84 residues without any sulfur amino acids. It shows 49 identities with the heme-binding domain from Saccharomyces cerevisiae and 28 with beef microsomal cytochrome b5. Using the recently published three-dimensional structure of S. cerevisiae flavocytochrome b2 [Z-x. Xia, N. Shamala, P. H. Bethge, L. W. Lim, H. D. Bellamy, N. H. Xuong, F. Lederer and F. S. Mathews (1987) Proc. Natl Acad. Sci. USA 84, 2629-2633], it can be seen that there are only positively charged side chains close to the accessible heme edge, the only negative charges in that area being those of the heme propionates. The implications of this result are discussed in the light of Salemme's model for the cytochrome b5/cytochrome c complex [F. R. Salemme (1976) J. Mol. Biol. 102, 563-568].     

A relationship between heme binding and protein stability in cytochrome b5

Conformational changes and long-range effects are often observed in proteins when they associate with their ligands. In many cases, these structural perturbations are essential to function, and they are the result of complex networks of interactions. Here we used cytochrome b(5), a protein that undergoes extensive structural rearrangement upon heme binding, to seek a relationship between affinity for the cofactor and extent of refolding induced by its binding. Three variants of the water-soluble domain of the rat microsomal protein were chosen to affect the stability of the apoprotein or the holoprotein. Sequence alterations were introduced in the heme binding loop (type I mutations, D60R and (55)TENFED --> (55)TEPFEED, or PE), which is largely unstructured in the apoprotein state, and in the folded core of the apoprotein (type II mutation, P81A). Thermal and chemical denaturation experiments and heme transfer experiments were performed on these proteins. Type I mutations left the thermodynamic stability of the apoprotein unchanged. The first mutation (D60R) stabilized the holoprotein in a probable manifestation of enhanced helical propensity or improved electrostatic interactions. The second mutation (PE) decreased heme affinity and holoprotein stability in concert. For this protein, heme transfer experiments could be used to estimate the rate constant of heme loss from each of the heme orientational isomers. In contrast, the type II mutation resulted in a marked destabilization of the apoprotein but an intermediate effect on the holoprotein stability and heme affinity. These data supported that heme affinity could be modulated by the apoprotein stability and by specific residues remote from the heme binding site.     

A comparison of the heme binding pocket in globins and cytochrome b5.

Of the 85 three-dimensionally characterized residues of cytochrome b5, 51 are found to be structurally and topologically equivalent to the globin fold. When these proteins have been superimposed, the heme irons are found to be less than 1.4 A separated and the heme normals are inclined by less than 9.5 degrees. The proximal histidine of the globins and two adjacent helices are equivalent to the sixth iron ligand and adjacent helices of cytochrome b5. Larger differences in structure are observed on the distal side of the heme, coincident with the most changeable part of the globin structures. The heme itself is rotated by 53 degrees about its normal but such a change is energetically minimal and conservative as the heme side groups are not directly involved in the function of the molecules. The beta-sheet of cytochrome b5 is inserted into a corresponding cavity of the globins forming an additional lining to the heme pocket. The roughly 50 residues missing at the carboxy end of the known cytochrome b5 fragment could correspond in part to the H helix in the globins. While it would seem probable that these similarities represent divergent evolution from a primordial heme-binding protein, the possibility of structural convergence to a functionally satisfactory protein cannot be excluded.     

Design and synthesis of de novo cytochromes c

Natural c-type cytochromes are characterized by the consensus Cys-X-X-Cys-His heme-binding motif (where X is any amino acid) by which the heme is covalently attached to protein by the addition of the sulfhydryl groups of two cysteine residues to the vinyl groups of the heme. In this work, the consensus sequence was used for the heme-binding site of a designed four-helix bundle, and the apoproteins with either a histidine residue or a methionine residue positioned at the sixth coordination site were synthesized and reacted with iron protoporphyrin IX (protoheme) under mild reducing conditions in vitro. These polypeptides bound one heme per helix-loop-helix monomer via a single thioether bond and formed four-helix bundle dimers in the holo forms as designed. They exhibited visible absorption spectra characteristic of c-type cytochromes, in which the absorption bands shifted to lower wavelengths in comparison with the b-type heme binding intermediates of the same proteins. Unexpectedly, the designed cytochromes c with bis-His-coordinated heme iron exhibited oxidation-reduction potentials similar to those of their b-type intermediates, which have no thioether bond. Furthermore, the cytochrome c with His and Met residues as the axial ligands exhibited redox potentials increased by only 15-30 mV in comparison with the cytochrome with the bis-His coordination. These results indicate that highly positive redox potentials of natural cytochromes c are not only due to the heme covalent structure, including the Met ligation, but also due to noncovalent and hydrophobic environments surrounding the heme. The covalent attachment of heme to the polypeptide in natural cytochromes c may contribute to their higher redox potentials by reducing the thermodynamic stability of the oxidized forms relatively against that of the reduced forms without the loss of heme.     

Functional interpretation and structural insights of Arabidopsis lyrata cytochrome P450 CYP71A13 involved in auxin synthesis

Cytochrome P450 CYP71A13 of Arabidopsis lyrata is a heme protein involved in biosynthesis of indole-3-acetonitrile which leads to the formation of indolyl-3-acetic acid. It catalyzes a unique reaction: formation of a carbon-nitrogen triple bond and dehydration of indolyl-3-acetaldoxime. Homology model of this 57 kDa polypeptide revealed that the heme existed between H-helix and J- helix in the hydrophobic pocket, although both helixes are involved in catalytic activity, where Gly305 and Thr308, 311 of H- helix were involved in its stabilization. The substrate indole-3-acetaldoxime was tightly fitted into the substrate pocket with the aromatic ring being surrounded by amino acid residues creating a hydrophobic environment. The smaller size of the substrate binding pocket in cytochrome P450 CYP71A13 was due to the bulkiness of the two amino acid residues Phe182 and Trp315 pointing into the substrate binding cavity. The apparent role of the heme in cytochrome P450 CYP71A13 was to tether the substrate in the catalysis by indole-3-acetaldoxime dehydratase. Since the crystal structure of cytochrome P450 CYP71A13 has not yet been solved, the modeled structure revealed mechanism of substrate recognition and catalysis.     

House fly cytochrome b5 exhibits kinetically trapped hemin and selectivity in hemin binding

We report that cytochrome b(5) (cyt b(5)) from Musca domestica (house fly) is more thermally stable than all other microsomal (Mc) cytochromes b(5) that have been examined to date. It also exhibits a much higher barrier to equilibration of the two isomeric forms of the protein, which differ by a 180 degrees rotation about the alpha-gamma-meso axis of hemin (ferric heme). In fact, hemin is kinetically trapped in a nearly statistical 1.2:1 ratio of rotational forms in freshly expressed protein. The equilibrium ratio (5.5:1) is established only upon incubation at temperatures above 37 degrees C. House fly Mc cyt b(5) is only the second b-hemoprotein that has been shown to exhibit kinetically trapped hemin at room temperature or above, the first being cyt b(5) from the outer membrane of rat liver mitochondria (rat OM cyt b(5)). Finally, we show that the small excess of one orientational isomer over the other in freshly expressed protein results from selective binding of hemin by the apoprotein, a phenomenon that has not heretofore been established for any apocyt b(5).     

Structural propensities in the heme binding region of apocytochrome b5. II. Heme conjugates

In the absence of heme cofactor, the water-soluble domain of rat microsomal cytochrome b5 (cyt b5) contains a long flexible region within its 42-residue heme-binding loop. Heme capture induces this region to fold into a well-defined structure containing helices H3-H5, each separated by a turn, with His39 and His63 serving as axial ligands to the heme iron. We have shown that the H4 region of the apoprotein has the greatest tendency for disorder within the isolated binding loop. Here, the effect of the His63-iron bond and proximity of heme plane on the population of helical conformation in H4 and H5 was investigated by synthesis and characterization of a peptide-sandwiched mesoheme construct in which two H4-H5 peptides were covalently attached to a single cofactor. Spectroscopic data indicated that a holoprotein-like bis-histidine coordination state was achieved over a pH range from 7 to 9. Trifluoroethanol titrations of the construct and the analogous free peptide under these pH conditions revealed that heme proximity and iron ligation were insufficient to promote helix formation in H4 and H5. These observations were used to assess the role of disordered regions in heme capture and the loop-scaffold interface in holoprotein folding and stability.     

CCME, a nuclear-encoded heme-binding protein involved in cytochrome c maturation in plant mitochondria

The maturation of c-type cytochromes requires the covalent attachment of the heme cofactor to the apoprotein. For this process, plant mitochondria follow a pathway distinct from that of animal or yeast mitochondria, closer to that found in alpha- and gamma-proteobacteria. We report the first characterization of a nuclear-encoded component, namely AtCCME, the Arabidopsis thaliana orthologue of CcmE, a periplasmic heme chaperone in bacteria. AtCCME is targeted to mitochondria, and its N-terminal signal peptide is cleaved upon import. AtCCME is a peripheral protein of the mitochondrial inner membrane, and its major hydrophilic domain is oriented toward the intermembrane space. Although a AtCCME (Met(79)-Ser(256)) is not fully able to complement an Escherichia coli CcmE mutant strain for bacterial holocytochrome c production, it is able to bind heme covalently through a conserved histidine, a feature previously shown for E. coli CcmE. Our results suggest that AtCCME is important for cytochrome c maturation in A. thaliana mitochondria and that its heme-binding function has been conserved evolutionary between land plant mitochondria and alpha-proteobacteria.     

Two heme-binding domains of heme-regulated eukaryotic initiation factor-2alpha kinase. N terminus and kinase insertion

In heme deficiency, protein synthesis in reticulocytes is inhibited by activation of heme-regulated alpha-subunit of eukaryotic initiation factor-2alpha (eIF-2alpha) kinase (HRI). Previous studies indicate that HRI contains two distinct heme-binding sites per HRI monomer. To study the role of the N terminus in the heme regulation of HRI, two N-terminally truncated mutants, Met2 and Met3 (deletion of the first 103 and 130 amino acids, respectively), were prepared. Met2 and Met3 underwent autophosphorylation and phosphorylated eIF-2alpha with a specific activity of approximately 50% of that of the wild type HRI. These mutants were significantly less sensitive to heme regulation both in vivo and in vitro. In addition, the heme contents of purified Met2 and Met3 HRI were less than 5% of that of the wild type HRI. These results indicated that the N terminus was important but was not the only domain involved in the heme-binding and heme regulation of HRI. Heme binding of the individual HRI domains showed that both N terminus and kinase insertion were able to bind hemin, whereas the C terminus and the catalytic domains were not. Thus, both the N terminus and the kinase insertion, which are unique to HRI, are involved in the heme binding and the heme regulation of HRI.