Mammalian ferrochelatase. Overexpression in Escherichia coli as a soluble protein, purification and characterization

Ferrochelatase π-helix: Implications from examining the role of the conserved π-helix glutamates in porphyrin metalation and product release

Protoporphyrin ferrochelatase catalyzes the insertion of Fe²⁺ into protoporphyrin IX to form heme. To determine whether a conserved, active site π-helix contributes to the translocation of the metal ion substrate to the ferrochelatase-bound porphyrin substrate, the invariant π-helix glutamates were replaced with amino acids with non-negatively charged side chains, and the kinetic mechanisms of the generated variants were examined. Analysis of yeast wild-type ferrochelatase-, E314Q- and E318Q-catalyzed reactions, under multi- and single-turnover conditions, demonstrated that the mutations of the π-helix glutamates hindered both protoporphyrin metalation and release of the metalated porphyrin, by slowing each step by approximately 30-50%. Protoporphyrin metalation occurred with an apparent pK_a of 7.3 ± 0.1, which was assigned to binding of Fe²⁺ by deprotonated Glu-314 and Glu-314-assisted Fe²⁺ insertion into the porphyrin ring. We propose that unwinding of the π-helix concomitant with the adoption of a protein open conformation positions the deprotonated Glu-314 to bind Fe²⁺ from the surface of the enzyme. Transition to the closed conformation, with π-helix winding, brings Glu-314-bound Fe²⁺ to the active site for incorporation into protoporphyrin.

The conserved active site histidine-glutamate pair of ferrochelatase coordinately catalyzes porphyrin metalation

Ferrochelatase catalyzes the insertion of ferrous iron into protoporphyrin IX to generate heme. Despite recent research on the reaction mechanism of ferrochelatase, the precise roles and localization of individual active site residues in catalysis, particularly those involved in the insertion of the ferrous iron into the protoporphyrin IX substrate, remain controversial. One outstanding question is from which side of the macrocycle of the bound porphyin substrate is the ferrous iron substrate inserted. Pre-steady state kinetic experiments done under single-turnover conditions conclusively demonstrate that metal ion insertion is pH-dependent, and that the conserved active site His-Glu pair coordinately catalyzes the metal ion insertion reaction. Further, p[Formula: see text] calculations and molecular dynamic simulations indicate that the active site His is deprotonated and the protonation state of the Glu relates to the conformational state of ferrochelatase. Specifically, the conserved Glu in the open conformation of ferrochelatase is deprotonated, while it remains protonated in the closed conformation. These findings support not only the role of the His-Glu pair in catalyzing metal ion insertion, as these residues need to be deprotonated to bind the incoming metal ion, but also the importance of the relationship between the protonation state of the Glu residue and the conformation of ferrochelatase. Finally, the results of this study are consistent with our previous proposal that the unwinding of the [Formula: see text]-helix, the major structural determinant of the closed to open conformational transition in ferrochelatase, is associated with the Glu residue binding the Fe[Formula: see text] substrate from a mitochondrial Fe[Formula: see text] donor.

The Structure of the Complex between Yeast Frataxin and Ferrochelatase: CHARACTERIZATION AND PRE-STEADY STATE REACTION OF FERROUS IRON DELIVERY AND HEME SYNTHESIS

Frataxin is a mitochondrial iron-binding protein involved in iron storage, detoxification, and delivery for iron sulfur-cluster assembly and heme biosynthesis. The ability of frataxin from different organisms to populate multiple oligomeric states in the presence of metal ions, e.g. Fe(2+) and Co(2+), led to the suggestion that different oligomers contribute to the functions of frataxin. Here we report on the complex between yeast frataxin and ferrochelatase, the terminal enzyme of heme biosynthesis. Protein-protein docking and cross-linking in combination with mass spectroscopic analysis and single-particle reconstruction from negatively stained electron microscopic images were used to verify the Yfh1-ferrochelatase interactions. The model of the complex indicates that at the 2:1 Fe(2+)-to-protein ratio, when Yfh1 populates a trimeric state, there are two interaction interfaces between frataxin and the ferrochelatase dimer. Each interaction site involves one ferrochelatase monomer and one frataxin trimer, with conserved polar and charged amino acids of the two proteins positioned at hydrogen-bonding distances from each other. One of the subunits of the Yfh1 trimer interacts extensively with one subunit of the ferrochelatase dimer, contributing to the stability of the complex, whereas another trimer subunit is positioned for Fe(2+) delivery. Single-turnover stopped-flow kinetics experiments demonstrate that increased rates of heme production result from monomers, dimers, and trimers, indicating that these forms are most efficient in delivering Fe(2+) to ferrochelatase and sustaining porphyrin metalation. Furthermore, they support the proposal that frataxin-mediated delivery of this potentially toxic substrate overcomes formation of reactive oxygen species.

Nickel(II) chelatase variants directly evolved from murine ferrochelatase: porphyrin distortion and kinetic mechanism

The heme biosynthetic pathway culminates with the ferrochelatase-catalyzed ferrous iron chelation into protoporphyrin IX to form protoheme. The catalytic mechanism of ferrochelatase has been proposed to involve the stabilization of a nonplanar porphyrin to present the pyrrole nitrogens to the metal ion substrate. Previously, we hypothesized that the ferrochelatase-induced nonplanar distortions of the porphyrin substrate impose selectivity for the divalent metal ion incorporated into the porphyrin ring and facilitate the release of the metalated porphyrin through its reduced affinity for the enzyme. Using resonance Raman spectroscopy, the structural properties of porphyrins bound to the active site of directly evolved Ni(2+)-chelatase variants are now examined with regard to the mode and extent of porphyrin deformation and related to the catalytic properties of the enzymes. The Ni(2+)-chelatase variants (S143T, F323L, and S143T/F323L), which were directly evolved to exhibit an enhanced Ni(2+)-chelatase activity over that of the parent wild-type ferrochelatase, induced a weaker saddling deformation of the porphyrin substrate. Steady-state kinetic parameters of the evolved variants for Ni(2+)- and Fe(2+)-chelatase activities increased compared to those of wild-type ferrochelatase. In particular, the reduced porphyrin saddling deformation correlated with increased catalytic efficiency toward the metal ion substrate (Ni(2+) or Fe(2+)). The results lead us to propose that the decrease in the induced protoporphyrin IX saddling mode is associated with a less stringent metal ion preference by ferrochelatase and a slower porphyrin chelation step.

Identification and characterization of an inhibitory metal ion-binding site in ferrochelatase

Ferrochelatase catalyzes the insertion of ferrous iron into protoporphyrin IX to form heme. The severe metal ion substrate inhibition observed during in vitro studies of the purified enzyme is almost completely eliminated by mutation of an active site histidine residue (His-287, murine ferrochelatase numbering) to leucine and reduced over 2 orders of magnitude by mutation of a nearby conserved phenylalanine residue (Phe-283) to leucine. Elimination of substrate inhibition had no effect on the apparent V(max) for Ni(2+), but the apparent K(m) was increased 100-fold, indicating that the integrity of the inhibitory binding site is important for the enzyme to turn over substrates rapidly at low micromolar metal ion concentrations. The inhibitory site was observed to have a pK(a) value of 8.0, and this value was reduced to 7.5 by the F283L mutation and to 7.4 in a naturally occurring positional variant observed in most bacterial ferrochelatases, murine ferrochelatase H287C. A H287N variant was also found to be substrate-inhibited, but unlike the H287C variant, pH dependence of substrate inhibition was largely eliminated. The data indicate that the inhibitory metal ion-binding site is composed of multiple residues but primarily defined by His-287 and Phe-283 and is crucial for optimal activity at low metal ion concentrations. It is proposed that this binding site may be important for ferrous iron acquisition and desolvation in vivo.

Metal ion substrate inhibition of ferrochelatase

Ferrochelatase catalyzes the insertion of ferrous iron into protoporphyrin IX to form heme. Robust kinetic analyses of the reaction mechanism are complicated by the instability of ferrous iron in aqueous solution, particularly at alkaline pH values. At pH 7.00 the half-life for spontaneous oxidation of ferrous ion is approximately 2 min in the absence of metal complexing additives, which is sufficient for direct comparisons of alternative metal ion substrates with iron. These analyses reveal that purified recombinant ferrochelatase from both murine and yeast sources inserts not only ferrous iron but also divalent cobalt, zinc, nickel, and copper into protoporphyrin IX to form the corresponding metalloporphyrins but with considerable mechanistic variability. Ferrous iron is the preferred metal ion substrate in terms of apparent k(cat) and is also the only metal ion substrate not subject to severe substrate inhibition. Substrate inhibition occurs in the order Cu(2+) > Zn(2+) > Co(2+) > Ni(2+) and can be alleviated by the addition of metal complexing agents such as beta-mercaptoethanol or imidazole to the reaction buffer. These data indicate the presence of two catalytically significant metal ion binding sites that may coordinately regulate a selective processivity for the various potential metal ion substrates.

Recombinant cytochromes c biogenesis systems I and II and analysis of haem delivery pathways in Escherichia coli

Genetic analysis has indicated that the system II pathway for c-type cytochrome biogenesis in Bordetella pertussis requires at least four biogenesis proteins (CcsB, CcsA, DsbD and CcsX). In this study, the eight genes (ccmA-H) associated with the system I pathway in Escherichia coli were deleted. Using B. pertussis cytochrome c4 as a reporter for cytochromes c assembly, it is demonstrated that a single fused ccsBA polypeptide can replace the function of the eight system I genes in E. coli. Thus, the CcsB and CcsA membrane complex of system II is likely to possess the haem delivery and periplasmic cytochrome c-haem ligation functions. Using recombinant system II and system I, both under control of IPTG, we have begun to study the capabilities and characteristics of each system in the same organism (E. coli). The ferrochelatase inhibitor N-methylprotoporphyrin was used to modulate haem levels in vivo and it is shown that system I can use endogenous haem at much lower levels than system II. Additionally, while system I encodes a covalently bound haem chaperone (holo-CcmE), no covalent intermediate has been found in system II. It is shown that this allows system I to use holo-CcmE as a haem reservoir, a capability system II does not possess.

Porphyrin-substrate binding to murine ferrochelatase: effect on the thermal stability of the enzyme

Ferrochelatase (EC 4.99.1.1), the terminal enzyme of the haem biosynthetic pathway, catalyses the chelation of Fe(II) into the protoporphyrin IX ring. The energetics of the binding between murine ferrochelatase and mesoporphyrin were determined using isothermal titration calorimetry, which revealed a stoichiometry of one molecule of mesoporphyrin bound per protein monomer. The binding is strongly exothermic, with a large intrinsic enthalpy (DeltaH=-97.1 kJ x mol(-1)), and is associated with the uptake of two protons from the buffer. This proton transfer suggests that hydrogen bonding between ferrochelatase and mesoporphyrin is a key factor in the thermodynamics of the binding reaction. Differential scanning calorimetry thermograms indicated a co-operative two-state denaturation process with a single transition temperature of 56 degrees C for wild-type murine ferrochelatase. An increase in the thermal stability of ferrochelatase is dependent upon mesoporphyrin binding. Similarly, murine ferrochelatase variants, in which the active site Glu-289 was replaced by either glutamine or alanine and, when purified, contained specifically-bound protoporphyrin, exhibited enhanced protein stability when compared with wild-type ferrochelatase. However, in contrast with the wild-type enzyme, the thermal denaturation of ferrochelatase variants was best described as a non-co-operative denaturation process.

Probing the Active Site Loop Motif of Murine Ferrochelatase by Random Mutagenesis

Ferrochelatase catalyzes the terminal step of the heme biosynthetic pathway by inserting ferrous iron into protoporphyrin IX. A conserved loop motif was shown to form part of the active site and contact the bound porphyrin by molecular dynamics calculations and structural analysis. We applied a random mutagenesis approach and steady-state kinetic analysis to assess the role of the loop motif in murine ferrochelatase function, particularly with respect to porphyrin interaction. Functional substitutions in the 10 consecutive loop positions Gln(248)-Leu(257) were identified by genetic complementation in Escherichia coli strain Deltavis. Lys(250), Val(251), Pro(253), Val(254), and Pro(255) tolerated a variety of replacements including single substitutions and contained low informational content. Gln(248), Ser(249), Gly(252), Trp(256), and Leu(257) possessed high informational content, since permissible replacements were limited and only observed in multiply substituted mutants. Selected active loop variants exhibited k(cat) values comparable with or higher than that of wild-type murine ferrochelatase. The K(m) values for porphyrin increased, except for the single mutant V251L. Other than a moderate increase observed in the triple mutant S249A/K250Q/V251C, the K(m) values for Fe(2+) were lowered. The k(cat)/K(m) for porphyrin remained largely unchanged, with the exception of a 10-fold reduction in the triple mutant K250M/V251L/W256Y. The k(cat)/K(m) for Fe(2+) was improved. Molecular modeling of these active loop variants indicated that loop mutations resulted in alterations of the active site architecture. However, despite the plasticity of the loop primary structure, the relative spatial positioning of the loop in the active site appeared to be maintained in functional variants, supporting a role for the loop in ferrochelatase function.

A continuous anaerobic fluorimetric assay for ferrochelatase by monitoring porphyrin disappearance

A continuous spectrofluorimetric assay for determining ferrochelatase activity has been developed using the physiological substrates ferrous iron and protoporphyrin IX under strictly anaerobic conditions. In contrast to heme, the product of the ferrochelatase-catalyzed reaction, protoporphyrin IX is fluorescent, and therefore the progress of the reaction can be monitored by following the decrease in protoporphyrin fluorescence intensity (with excitation and emission wavelengths at 505 and 635 nm, respectively). This continuous fluorimetric assay detects activities as low as 0.01 nmol porphyrin consumed min(-1), representing an increase in sensitivity of up to two orders of magnitude over the currently used, discontinuous assays. The determination of the steady-state kinetic parameters of ferrochelatase yielded K(m)(PPIX)=1.4+/-0.2 microM, K(m)(Fe(2+))=1.9+/-0.3 microM, and k(cat)=4.0+/-0.3 min(-1). In addition to its applicability for acquisition of kinetic data to characterize ferrochelatase and recombinant variants, this new method should permit detection of low concentrations of ferrochelatase in biological samples.

Heme deficiency selectively interrupts assembly of mitochondrial complex IV in human fibroblasts: revelance to aging

Heme deficiency was studied in young and old normal human fibroblasts (IMR90). Regardless of age, heme deficiency increased the steady-state level of oxidants and lipid peroxidation and sensitized the cells to fluctuations in intracellular Ca(2+). Heme deficiency selectively decreased the activity and protein content of mitochondrial complex IV (cytochrome c oxidase) by 95%, indicating a decrease in successful assembly. Complexes I-III and catalase remained intact under conditions of heme deficiency, whereas ferrochelatase was up-regulated. Complex IV is the only hemeprotein in the cell that contains heme a, which may account for its susceptibility. The rate of removal and assembly of complex IV declines with age. These findings are relevant to worldwide iron deficiency in women and children and to an age-related decline in complex IV in Alzheimer's disease patients.

Activity and cellular location in Saccharomyces cerevisiae of chimeric mouse/yeast and Bacillus subtilis/yeast ferrochelatases

We have constructed a series of chimeric yeast/mouse and yeast/Bacillus subtilis ferrochelatase genes in order to investigate domains of the ferrochelatase that are important for activity and/or association with the membrane. These genes were expressed in a Saccharomyces cerevisiae mutant in which the endogenous ferrochelatase gene (HEM15) had been deleted, and the phenotypes of the transformants were characterized. Exchanging the approximately 40-amino-acid C-terminus between the yeast and mouse ferrochelatases caused a total loss of activity and the hybrid proteins were unstable when overproduced in Escherichia coli. The water-soluble ferrochelatase of B. subtilis did not complement the yeast mutant, although a large amount of active protein accumulated in the cytosol. Addition of the N-terminal leader sequence of yeast ferrochelatase to the B. subtilis enzyme targeted the fusion protein to mitochondria, but both the precursor and the mature forms of the enzyme were inactive in vivo and had residual activity when measured in vitro. An internal approximately 45-amino-acid segment located at the N-terminus of yeast ferrochelatase was identified, which, when replaced with the corresponding 30-amino-acid segment of the B. subtilis enzyme, caused the yeast enzyme to be located in the mitochondrial matrix as a soluble protein. The fusion protein was inactive in vivo and had residual activity in vitro. We speculate that this segment, which shows the greatest variability between species, is responsible for the association of the enzyme with the membrane.

Two different genes encode ferrochelatase in Arabidopsis: mapping, expression and subcellular targeting of the precursor proteins

Ferrochelatase is the last enzyme of haem biosynthesis. We have isolated 27 independent ferrochelatase cDNAs from Arabidopsis thaliana by functional complementation of a yeast mutant. Twenty-two of these cDNAs were similar to a previously isolated clone, AF3, and although they varied in length at the 5' and 3' ends, their nucleotide sequences were identical, indicating that they were derived from the same gene (ferrochelatase-I). The remaining five cDNAs all encoded a separate ferrochelatase isoform (ferrochelatase-II), which was 69% identical at the amino acid level to ferrochelatase-I. Using RFLP analysis in recombinant inbred lines, the ferrochelatase-I gene was mapped to chromosome V and that for ferrochelatase-II to chromosome II. Northern analysis showed that both ferrochelatase genes are expressed in leaves, stems and flowers, and expression in the leaves is higher in the light than in the dark. However, in roots only ferrochelatase-I transcripts were detected. High levels of sucrose stimulated expression of ferrochelatase-I, but had no effect, or repressed slightly, the expression of the ferrochelatase-II isoform. Import experiments into isolated chloroplasts and mitochondria showed that the ferrochelatase-II gene encodes a precursor which is imported solely into the chloroplast, in contrast to ferrochelatase-I which is targeted to both organelles. The significance of these results for haem biosynthesis and the production of haemoproteins, both within the plant cell and in different plant tissues, is discussed.

Probing the active-site residues in Saccharomyces cerevisiae ferrochelatase by directed mutagenesis. In vivo and in vitro analyses

Ferrochelatase is a mitochondrial inner membrane-bound enzyme that catalyzes the insertion of ferrous iron into protoporphyrin, the terminal step in protoheme biosynthesis. The functional/structural roles of 10 invariant amino acid residues were investigated by site-directed mutagenesis in the yeast Saccharomyces cerevisiae ferrochelatase. The mutant enzymes were expressed in a yeast strain lacking the ferrochelatase gene HEM15 and in Escherichia coli. The kinetic parameters of the mutant enzymes were determined for the enzymes associated with the yeast membranes and the enzymes in the bacterial soluble fraction. They were compared with the in vivo functioning of the mutant enzymes. The main conclusions are the following. Glu-314 is critical for catalysis, and we suggest that it is the base responsible for abstracting the N-pyrrole proton(s). His-235 is essential for metal binding. Asp-246 and Tyr-248 are also involved in metal binding in a synergistic manner. The Km for protoporphyrin was also increased in the H235L, D246A, and Y248L mutants, suggesting that the binding sites of the two substrates are not independent of each other. The R87A, Y95L, Q111E, Q273E, W282L, and F308A mutants had 1.2-2-fold increased Vm and 4-10-fold increased Km values for protoporphyrin, but the amount of heme made in vivo was 10-100% of the normal value. These mutations probably affected the geometry of the active center, resulting in improper positioning of protoporphyrin.

Purification, crystallization, and preliminary X-ray analysis of Bacillus subtilis ferrochelatase

Bacillus subtilis ferrochelatase (EC 4.99.1.1), the final enzyme in protoheme IX biosynthesis, was produced with an inducible T7 RNA polymerase expression system in Escherichia coli and purified from the soluble cell fraction. It was crystallized from polyethylene glycol solution using the microseeding technique. The crystals diffract to a minimum Bragg spacing of 2.1 A. The space group is P4(2) with unit cell dimensions a = b = 50.2 A, c = 120.1 A.

Characterization of the iron-binding site in mammalian ferrochelatase by kinetic and Mössbauer methods

All organisms utilize ferrochelatase (protoheme ferrolyase, EC 4.99.1.1) to catalyze the terminal step of the heme biosynthetic pathway, which involves the insertion of ferrous ion into protoporphyrin IX. Kinetic methods and Mössbauer spectroscopy have been used in an effort to characterize the ferrous ion-binding active site of recombinant murine ferrochelatase. The kinetic studies indicate that dithiothreitol, a reducing agent commonly used in ferrochelatase activity assays, interferes with the enzymatic production of heme. Ferrochelatase specific activity values determined under strictly anaerobic conditions are much greater than those obtained for the same enzyme under aerobic conditions and in the presence of dithiothreitol. Mössbauer spectroscopy conclusively demonstrates that, under the commonly used assay conditions, dithiothreitol chelates ferrous ion and hence competes with the enzyme for binding the ferrous substrate. Mössbauer spectroscopy of ferrous ion incubated with ferrochelatase in the absence of dithiothreitol shows a somewhat broad quadrupole doublet. Spectral analysis indicates that when 0.1 mM Fe(II) is added to 1.75 mM ferrochelatase, the overwhelming majority of the added ferrous ion is bound to the protein. The spectroscopic parameters for this bound species are delta = 1.36 +/- 0.03 mm/s and delta EQ = 3.04 +/- 0.06 mm/s, distinct from the larger delta EQ of a control sample of Fe(II) in buffer only. The parameters for the bound species are consistent with an active site composed of nitrogenous/oxygenous ligands and inconsistent with the presence of sulfur ligands. This finding is in accord with the absence of conserved cysteines among the known ferrochelatase sequences. The implications these results have with regard to the mechanism of ferrochelatase activity are discussed.

Structure and function of ferrochelatase

Ferrochelatase is the terminal enzyme of the heme biosynthetic pathway in all cells. It catalyzes the insertion of ferrous iron into protoporphyrin IX, yielding heme. In eukaryotic cells, ferrochelatase is a mitochondrial inner membrane-associated protein with the active site facing the matrix. Decreased values of ferrochelatase activity in all tissues are a characteristic of patients with protoporphyria. Point-mutations in the ferrochelatase gene have been recently found to be associated with certain cases of erythropoietic protoporphyria. During the past four years, there have been considerable advances in different aspects related to structure and function of ferrochelatase. Genomic and cDNA clones for bacteria, yeast, barley, mouse, and human ferrochelatase have been isolated and sequenced. Functional expression of yeast ferrochelatase in yeast strains deficient in this enzyme, and expression in Escherichia coli and in baculovirus-infected insect cells of different ferrochelatase cDNAs have been accomplished. A recently identified (2Fe-2S) cluster appears to be a structural feature shared among mammalian ferrochelatases. Finally, functional studies of ferrochelatase site-directed mutants, in which key amino acids were replaced with residues identified in some cases of protoporphyria, will be summarized in the context of protein structure.

Site-directed mutagenesis of human ferrochelatase: identification of histidine-263 as a binding site for metal ions

In nature, ferrochelatase catalyzes the insertion of ferrous ion into the porphyrin macrocycle of protoporphyrin IX to exclude two protons to form protoheme IX: other porphyrin substrates, including mesoporphyrin IX may be used in vitro. Based on the deduced amino-acid sequences, one histidine residue (H263 of human enzyme) is conserved among all ferrochelatases cloned from human to bacterial cells, and three histidine residues (H157, H341 and H388 of human enzyme) are conserved among eukaryotic ferrochelatases; no cysteine residue is conserved. To attempt to clarify the binding site of ferrous ion, we converted four highly conserved histidine residues in human ferrochelatase to alanine, using site-directed mutagenesis. The mutant enzymes were expressed in Escherichia coli, and iron- and zinc-chelating activities were examined. Mutants H157A and H388A lost most of their activities and concomitantly the enzyme became susceptible to proteolytic degradation. Kinetic studies with the residual activities showed no significant change of Km values for metal ions or for mesoporphyrin IX. Mutation at H341 did not alter the enzyme activities. Iron- and zinc-chelating activities of mutant H263A were reduced to 30% and 21% of the activities of the wild type, respectively. Moreover, this mutation resulted in 18- and 3.4-fold increases in Km values toward ferrous and zinc ions, respectively, while the Km value for mesoporphyrin remained unchanged. These results indicate that the binding site for metal ions in ferrochelatase is distinct from that for the porphyrin, and suggest that histidine-263 contributes significantly to the binding of metal ions. Maintenance of the structure of the protein molecule may involve functions related to histidine-157 and -388.