Zinc chelatase in human lymphocytes: detection of the enzymatic defect in erythropoietic protoporphyria

We describe a fluorometric assay for heme synthetase, the enzyme that is genetically deficient in erythropoietic protoporphyria. The method, which can readily detect activity in 1 microliter of packed human lymphocytes, is based on the formation of zinc protoheme from protoporphyrin IX. That zinc chelatase and ferrochelatase activities reside in the same enzyme was shown by the competitive action of ferrous ions and the inhibitory effects of N-methyl protoporphyrin (a specific inhibitor of heme synthetase) on zinc chelatase. The Km for zinc was 11 micrograms and that for protoporphyrin IX was 6 microM. The Ki fro ferrous ions was 14 microM. Zinc chelatase was reduced to 15.3% of the mean control activity in lymphocytes obtained from patients with protoporphyria, thus confirming the defect of heme biosynthesis in this disorder. The assay should prove to be useful for determining heme synthetase in tissues with low specific activity and to investigate further the enzymatic defect in protoporphyria.     

Interaction between the bacterial iron response regulator and ferrochelatase mediates genetic control of heme biosynthesis.

The heme biosynthetic pathway culminates with the insertion of iron into protoporphyrin catalyzed by ferrochelatase. The Bradyrhizobium japonicum iron response regulator (Irr) protein represses the pathway at an early step under iron limitation to prevent protoporphyrin synthesis from exceeding iron availability. Here, we show that Irr interacts directly with ferrochelatase and responds to iron via the status of heme and protoporphyrin localized at the site of heme synthesis. In the presence of iron, ferrochelatase inactivates Irr, followed by heme-dependent Irr degradation to derepress the pathway. Under iron limitation, protoporphyrin relieves the inhibition of Irr by ferrochelatase, probably by promoting protein dissociation, allowing genetic repression. Thus, metabolic control of the heme pathway involves a regulatory function of a biosynthetic enzyme to affect gene expression. Furthermore, heme can serve as a signaling molecule without accumulating freely in cells.     

Binding of protoporphyrin IX and metal derivatives to the active site of wild-type mouse ferrochelatase at low porphyrin-to-protein ratios

Resonance Raman (RR) spectroscopy is used to examine porphyrin substrate, product, and inhibitor interactions with the active site of murine ferrochelatase (EC 4.99.1.1), the terminal enzyme in the biosynthesis of heme. The enzyme catalyzes in vivo Fe(2+) chelation into protoporphyrin IX to give heme. The RR spectra of native ferrochelatase show that the protein, as isolated, contains varying amounts of endogenously bound high- or low-spin ferric heme, always at much less than 1 equiv. RR data on the binding of free-base protoporphyrin IX and its metalated complexes (Fe(III), Fe(II), and Ni(II)) to active wild-type protein were obtained at varying ratios of porphyrin to protein. The binding of ferric heme, a known inhibitor of the enzyme, leads to the formation of a low-spin six-coordinate adduct. Ferrous heme, the enzyme's natural product, binds in the ferrous high-spin five-coordinate state. Ni(II) protoporphyrin, a metalloporphyrin that has a low tendency toward axial ligation, becomes distorted when bound to ferrochelatase. Similarly for free-base protoporphyrin, the natural substrate of ferrochelatase, the RR spectra of porphyrin-protein complexes reveal a saddling distortion of the porphyrin. These results corroborate and extend our previous findings that porphyrin distortion, a crucial step of the catalytic mechanism, occurs even in the absence of bound metal substrate. Moreover, RR data reveal the presence of an amino acid residue in the active site of ferrochelatase which is capable of specific axial ligation to metals.     

Refolding and Enzyme Kinetic Studies on the Ferrochelatase of the Cyanobacterium Synechocystis sp. PCC 6803

Heme is a cofactor for proteins participating in many important cellular processes, including respiration, oxygen metabolism and oxygen binding. The key enzyme in the heme biosynthesis pathway is ferrochelatase (protohaem ferrolyase, EC 4.99.1.1), which catalyzes the insertion of ferrous iron into protoporphyrin IX. In higher plants, the ferrochelatase enzyme is localized not only in mitochondria, but also in chloroplasts. The plastidic type II ferrochelatase contains a C-terminal chlorophyll a/b (CAB) motif, a conserved hydrophobic stretch homologous to the CAB domain of plant light harvesting proteins and light-harvesting like proteins. This type II ferrochelatase, found in all photosynthetic organisms, is presumed to have evolved from the cyanobacterial ferrochelatase. Here we describe a detailed enzymological study on recombinant, refolded and functionally active type II ferrochelatase (FeCh) from the cyanobacterium Synechocystis sp. PCC 6803. A protocol was developed for the functional refolding and purification of the recombinant enzyme from inclusion bodies, without truncation products or soluble aggregates. The refolded FeCh is active in its monomeric form, however, addition of an N-terminal His₆-tag has significant effects on its enzyme kinetics. Strikingly, removal of the C-terminal CAB-domain led to a greatly increased turnover number, k_cat, compared to the full length protein. While pigments isolated from photosynthetic membranes decrease the activity of FeCh, direct pigment binding to the CAB domain of FeCh was not evident.     

Purification and properties of ferrochelatase from the yeast Saccharomyces cerevisiae. Evidence for a precursor form of the protein

Ferrochelatase was purified to homogeneity from yeast mitochondrial membranes and found to be a 40-kDa polypeptide with a pI at 6.3. Fatty acids were absolutely necessary to measure the activity in vitro. The Michaelis constants for protoporphyrin IX (9 x 10(-8) M), ferrous iron (1.6 x 10(-7) M), and zinc (9 x 10(-6) M) were determined on purified enzyme preparations in the presence of dithiothreitol. However, the Km for zinc was lower when measured in the absence of dithiothreitol (K-m(Zn2+) = 2.5 x 10(-7) M, Km(protoporphyrin) unchanged). The maximum velocities of the enzyme were 35,000 nmol of heme/h/mg of protein and 27,000 nmol of zinc-protoporphyrin/h/mg of protein. Antibodies against yeast ferrochelatase were raised in rabbits and used in studies on the biogenesis of the enzyme. Ferrochelatase is synthesized as a higher molecular weight precursor (Mr = 44,000) that is very rapidly matured in vivo to the Mr = 40,000 membrane-bound form. This precursor form of ferrochelatase was immunoprecipitated from in vitro translation (in a rabbit reticulocyte lysate system) of total yeast RNAs. The antibodies were used to characterize two yeast mutant strains deficient in ferrochelatase activity as being devoid of immunodetectable protein in vivo and ferrochelatase mRNA in vitro translation product. The N-terminal amino acid sequence of the purified protein has been established and was found to be frayed.     

Factors influencing the stability of heme and ferrochelatase: role of oxygen

Ferrochelatase (EC 4.99.1.1) catalyzed heme synthesis is best accomplished in an anaerobic environment. Factors responsible for this phenomenon are not fully understood. Oxygen sensitivity of this reaction may be due to (a) oxidation of essential thiol groups on the enzyme, (b) oxidation of ferrous ions, or (c) the formation of hydrogen peroxide. These possibilities were investigated using rat liver ferrochelatase preparations and a continuous, dual-wavelength assay. Dithiothreitol and ascorbic acid stimulated the ferrochelatase reaction whereas GSH was not as effective. Addition of GSSG had little influence on the enzyme reaction. Total ferrochelatase activity in the assay remained unaffected at the end of the incubation and inclusion of glutathione peroxidase did not alter these results. Thus, ferrochelatase itself was not inactivated by oxidation. In selenium-deficient rats, the mitochondrial ferrochelatase levels were maintained even when glutathione peroxidase activity was significantly depleted. However, glutathione peroxidase very effectively inhibited the thiol-dependent aerobic degradation of heme. These results suggested that autoxidation of heme and of ferrous ions to the unusable ferric form largely contribute toward the oxygen sensitivity of the ferrochelatase reaction in vitro.     

Reactions of ferrous neuroglobin and cytoglobin with nitrite under anaerobic conditions

Recent evidence suggests that the reaction of nitrite with deoxygenated hemoglobin and myoglobin contributes to the generation of nitric oxide and S-nitrosothiols in vivo under conditions of low oxygen availability. We have investigated whether ferrous neuroglobin and cytoglobin, the two hexacoordinate globins from vertebrates expressed in brain and in a variety of tissues, respectively, also react with nitrite under anaerobic conditions. Using absorption spectroscopy, we find that ferrous neuroglobin and nitrite react with a second-order rate constant similar to that of myoglobin, whereas the ferrous heme of cytoglobin does not react with nitrite. Deconvolution of absorbance spectra shows that, in the course of the reaction of neuroglobin with nitrite, ferric Fe(III) heme is generated in excess of nitrosyl Fe(II)-NO heme as due to the low affinity of ferrous neuroglobin for nitric oxide. By using ferrous myoglobin as scavenger for nitric oxide, we find that nitric oxide dissociates from ferrous neuroglobin much faster than previously appreciated, consistently with the decay of the Fe(II)-NO product during the reaction. Both neuroglobin and cytoglobin are S-nitrosated when reacting with nitrite, with neuroglobin showing higher levels of S-nitrosation. The possible biological significance of the reaction between nitrite and neuroglobin in vivo under brain hypoxia is discussed.     

Purification and characterization of heme oxygenase from chick liver. Comparison of the avian and mammalian enzymes

A major inducible form of heme oxygenase (EC 1.14.99.3) was purified from liver microsomes of chicks pretreated with cadmium chloride. The purification involved solubilization of microsomes with Emulgen 913 and sodium cholate, followed by DEAE-Sephacel, carboxymethyl-cellulose (CM-52) and hydroxyapatite chromatography, and FPLC through Superose 6 and 12 columns operating in series. The final product gave a single band on silver-stained SDS/polyacrylamide gels (Mr = 33,000). Optimal conditions for measurement of activity of solubilized heme oxygenase were studied. In a reconstituted system containing purified heme oxygenase, NADPH-cytochrome reductase, biliverdin reductase and NADPH, the Km for free heme was 3.8 +/- 0.5 microM; for heme in the presence of bovine serum albumin (5 mol heme/3 mol albumin) the Km was 5.0 +/- 0.8 microM; and the Km for NADPH was 6.1 +/- 0.4 microM (all values mean +/- SD, n = 3). Oxygen concentration as low as 15 microM, with saturating concentrations of heme and NADPH, did not affect the reaction rate, indicating that the supply of oxygen is not involved in the physiological regulation of activity of the enzyme. The pH optimum of the reaction was 7.4; at 37 degrees C, the apparent Vmax was 580 +/- 44 nmol biliverdin.(mg protein)-1.min-1 and the molecular activity was 19.2 min-1. Biliverdin IXa was the sole biliverdin isomer formed. In the presence of purified biliverdin reductase, biliverdin was converted quantitatively to bilirubin. Addition of catalase to the reconstituted system decreased the breakdown of heme to non-biliverdin products and led to nearly stoichiometric conversion of heme to biliverdin. Activity of the enzyme in the reconstituted system was inhibited by metalloporphyrins in the following order of decreasing potency: tin mesoporphyrin greater than tin protoporphyrin greater than zinc protoporphyrin greater than manganese protoporphyrin greater than cobalt protoporphyrin. Protoporphyrin (3.3 or 6.6 microM) (and several other porphyrins) and metallic ions (100 microM) alone had little if any inhibitory effect, except for Hg2+ which inhibited by 67% at 10 microM and totally at 15 microM. Following partial cleavage, fragments of the purified enzyme were sequenced. Comparison of sequences to those derived from cDNA sequences for the major inducible rat and human heme oxygenase showed 69% and 76% similarities, respectively. The histidine residue at position 132 of rat heme oxygenase-1 and the residues (Lys128-Arg136) flanking His132 were conserved in all three enzymes, as well as in the corresponding portion of a fourth less highly similar rat enzyme, heme oxygenase-2.(ABSTRACT TRUNCATED AT 400 WORDS)     

Ferrochelatase activity and protoporphyrin IX utilization in Haemophilus influenzae.

Previous research showed that the heme-requiring human pathogen Haemophilus influenzae lacks the first six of the seven enzymes required for heme synthesis, starting with the precursor, 5-amino levulinic acid. In this study, I demonstrated either directly or by reasonable inference that all 57 strains of H. influenzae examined, including 2 unable to grow on protoporphyrin IX, possess ferrochelatase, which catalyzes heme formation by insertion of Fe2+ into the protoporphyrin IX nucleus and which is the last enzyme in the heme synthetic pathway. Further, I showed that this enzyme can also function in the reverse direction, releasing Fe2+ from heme.     

The ferrochelatase gene structure and molecular defects associated with erythropoietic protoporphyria

Ferrochelatase [heme synthase, protoheme ferrolyase (EC 4.99.1.1)], the terminal enzyme of the heme biosynthetic pathway, catalyzes the incorporation of ferrous ion into protoporphyrin IX to form protoheme IX. The genes and cDNAs for ferrochelatase from mammals and microorganisms have been isolated. The gene for human ferrochelatase has been mapped to chromosome 18q 21.3 and consists of 11 exons with a size of about 45 kilodaltons. The induction of ferrochelatase expression occurs during erythroid differentiation, and can be attributed to the existence of the promoter sequences of erythroid-related genes. Analysis of the ferrochelatase gene in patients with erythropoietic protoporphyria, an inherited disease caused by ferrochelatase defects, revealed that molecular anomalies of ferrochelatase from 11 patients were found in 9 patients as autosomal dominant type, and 2 patients as recessive type. Diversity of the mutations of the ferrochelatase gene is also briefly described.     

Fluctuation domains in myoglobin. Fluorescence quenching studies

The dynamics of two domains in the myoglobin molecule, close to the heme and inside the protein medium including the surface, are investigated through the study of the fluorescence oxygen quenching of two probes imbedded in the heme pocket: zinc protoporphyrin IX (with a fluorescence lifetime of 2.1 ns) and metal-free protoporphyrin IX (with a fluorescence lifetime of 17.8 ns).     

Ferrochelatase and N-alkylated porphyrins

Summary The final step in heme synthesis is catalyzed by the mitochondrial enzyme, ferrochelatase. Characterization of this enzyme has been complicated by a number of factors including the dependence of enzyme activity on lipids. Purification of ferrochelatase from rat and bovine sources has been achieved only relatively recently using blue Sepharose CL-6B chromatography. When 3,5-diethoxycarbonyl-1,4-dihydro-2,4,6-trimethylpyridine (DDC) is given to animals, it produces a hepatic porphyria resembling human variegate porphyria thus providing an experimental system in which to study this disease. DDC has been found to cause the accumulation of a green pigment, identified as N-methyl protoporphyrin IX (N-MePP), which is a potent inhibitor of ferrochelatase. The source of the N-methyl substituent of N-MePP was found to be the 4-methyl group of DDC. Considerable evidence indicates that the protoporphyrin IX moiety of N-MePP originates from the heme moiety of cytochrome P-450 and that DDC is a suicide substrate for this hemoprotein. Some studies suggest that cytochrome P-450 isozymes differ in their susceptibility to destruction by DDC and its 4-alkyl analogues. Griseofulvin has also been reported to inhibit hepatic ferrochelatase in rodents but not in the 17-day old chick embryo nor in hepatocyte culture systems. Thus, the mechanism by which griseofulvin produces an experimental porphyria in chick embryo liver cell culture is different from that for rodents.     

Direct measurement of metal ion chelation in the active site of human ferrochelatase

The final step in heme biosynthesis, insertion of ferrous iron into protoporphyrin IX, is catalyzed by protoporphyrin IX ferrochelatase (EC 4.99.1.1). We demonstrate that pre-steady state human ferrochelatase (R115L) exhibits a stoichiometric burst of product formation and substrate consumption, consistent with a rate-determining step following metal ion chelation. Detailed analysis shows that chelation requires at least two steps, rapid binding followed by a slower (k approximately 1 s-1) irreversible step, provisionally assigned to metal ion chelation. Comparison with steady state data reveals that the rate-determining step in the overall reaction, conversion of free porphyrin to free metalloporphyrin, occurs after chelation and is most probably product release. We have measured rate constants for significant steps on the enzyme and demonstrate that metal ion chelation, with a rate constant of 0.96 s-1, is approximately 10 times faster than the rate-determining step in the steady state (kcat = 0.1 s-1). The effect of an additional E343D mutation is apparent at multiple stages in the reaction cycle with a 7-fold decrease in kcat and a 3-fold decrease in kchel. This conservative mutation primarily affects events occurring after metal ion chelation. Further evaluation of structure-function data on site-directed mutants will therefore require both steady state and pre-steady state approaches.     

The myoglobin protein radical. Coupling of Tyr-103 to Tyr-151 in the H2O2-mediated cross-linking of sperm whale myoglobin

Sperm whale metmyoglobin, which has tyrosine residues at positions 103, 146, and 151, dimerizes in the presence of H2O2. Equine metmyoglobin, which lacks Tyr-151, and red kangaroo metmyoglobin, which lacks Tyr-103 and Tyr-151, do not dimerize in the presence of H2O2. The dityrosine content of the sperm whale myoglobin dimer shows that it is primarily held together by dityrosine cross-links, although more tyrosine residues are lost than are accounted for by dityrosine formation. Digestion of the myoglobin dimer with chymotrypsin yields a peptide with the fluorescence spectrum of dityrosine. The amino acid composition, amino acid sequence, and mass spectrum of the peptide show that cross-linking involves covalent bond formation between Tyr-103 of one myoglobin chain and Tyr-151 of the other. Replacement of the prosthetic group of sperm whale myoglobin with zinc protoporphyrin IX prevents H2O2-induced dimerization even when intact horse metmyoglobin is present in the incubation. This suggests that the tyrosine radicals required for the dimerization reaction are generated by intra- rather than intermolecular electron transfer to the ferryl heme. Rapid electron transfer from Tyr-103 to the ferryl heme followed by slower electron transfer from Tyr-151 to Tyr-103 is most consistent with the present results.     

Identification and characterization of solvent-filled channels in human ferrochelatase

Ferrochelatase catalyzes the formation of protoheme from two potentially cytotoxic products, iron and protoporphyrin IX. While much is known from structural and kinetic studies on human ferrochelatase of the dynamic nature of the enzyme during catalysis and the binding of protoporphyrin IX and heme, little is known about how metal is delivered to the active site and how chelation occurs. Analysis of all ferrochelatase structures available to date reveals the existence of several solvent-filled channels that originate at the protein surface and continue to the active site. These channels have been proposed to provide a route for substrate entry, water entry, and proton exit during the catalytic cycle. To begin to understand the functions of these channels, we investigated in vitro and in vivo a number of variants that line these solvent-filled channels. Data presented herein support the role of one of these channels, which originates at the surface residue H240, in the delivery of iron to the active site. Structural studies of the arginyl variant of the conserved residue F337, which resides at the back of the active site pocket, suggest that it not only regulates the opening and closing of active site channels but also plays a role in regulating the enzyme mechanism. These data provide insight into the movement of the substrate and water into and out of the active site and how this movement is coordinated with the reaction mechanism.     

Amino acid residues His183 and Glu264 in Bacillus subtilis ferrochelatase direct and facilitate the insertion of metal ion into protoporphyrin IX

Ferrochelatase catalyzes the terminal step in the heme biosynthetic pathway, i.e., the incorporation of Fe(II) into protoporphyrin IX. Various biochemical and biophysical methods have been used to probe the enzyme for metal binding residues and the location of the active site. However, the location of the metal binding site and the path of the metal into the porphyrin are still disputed. Using site-directed mutagenesis on Bacillus subtilis ferrochelatase we demonstrate that exchange of the conserved residues His183 and Glu264 affects the metal affinity of the enzyme. We also present the first X-ray crystal structure of ferrochelatase with iron. Only a single iron was found in the active site, coordinated in a square pyramidal fashion by two amino acid residues, His183 and Glu264, and three water molecules. This iron was not present in the structure of a His183Ala modified ferrochelatase. The results strongly suggest that the insertion of a metal ion into protoporphyrin IX by ferrochelatase occurs from a metal binding site represented by His183 and Glu264.     

Nucleotide sequence of the Rhodobacter capsulatus hemH gene

The last step in heme synthesis is the insertion of iron into the ring of protoporphyrin IX. The enzyme which catalyzes this reaction, ferrochelatase (FC), is encoded by the hemH gene. A clone containing this gene from Rhodobacter capsulatus, a purple non-sulfur photosynthetic bacterium, has been sequenced. A single open reading frame was found which could encode a protein of 351 amino acids. This putative protein is very similar to other FC and contains the FC signature sequence     

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 inEscherichia coli and in baculovirusinfected 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.     

Reaction of the microsomal heme oxygenase with cobaltic protoporphyrin IX, and extremely poor substrate.

A reconstituted heme oxygenase system which was composed of a purified heme oxygenase from pig spleen microsomes and a partially purified NADPH-cytochrome c reductase from pig liver microsomes could not catalyze the conversion of cobaltic protoporphyrin IX (Co-heme) to biliverdin, although Co-heme could bind with the heme oxygenase protein to form a complex. The heme oxygenase system in the microsomes from pig spleen, rat spleen, and rat kidney also failed to oxidize Co-heme to biliverdin. Properties of the complex of Co-heme and heme oxygenase closely resembled those of cobalt myoglobin and cobalt hemoglobin; the Co-heme bound to the heme oxygenase protein did not react with cyanide and azide, the Co-heme moiety was reduced but only slowly with sodium dithionite, and the reduced form of the Co-heme did not appear to bind carbon monoxide. The co-heme bound to heme oxygenase was not reduced with the NADPH-cytochrome c reductase system in air. These findings further support the views that heme oxygenase may have a heme-binding crevice similar to those of myoglobin and hemoglobin and that reduction of heme is the prerequisite for the oxidative degradation of heme in the heme oxygenase reaction.