Fluorometric assays for coproporphyrinogen oxidase and protoporphyrinogen oxidase

We describe fluorometric assays for two enzymes of the heme pathway, coproporphyrinogen oxidase and protoporphyrinogen oxidase. Both assays are based on measurement of protoporphyrin IX fluorescence generated from coproporphyrinogen III by the two consecutive reactions catalyzed by coproporphyrinogen oxidase and protoporphyrinogen oxidase. Both enzymatic activities are measured by recording protoporphyrin IX fluorescence increase in air-saturated buffer in the presence of EDTA (to inhibit ferrochelatase that can further metabolize protoporphyrin IX) and in the presence of dithiothreitol (that prevents nonenzymatic oxidation of porphyrinogens to porphyrins). Coproporphyrinogen oxidase (limiting) activity is measured in the presence of a large excess of protoporphyrinogen oxidase provided by yeast mitochondrial membranes isolated from commercial baker's yeast. These membranes are easy to prepare and are stable for at least 1 year when kept at -80 degrees C. Moreover they ensure maximum fluorescence of the generated protoporphyrin (solubilization effect), avoiding use of a detergent in the incubation medium. The fluorometric protoporphyrinogen oxidase two-step assay is closely related to that already described (J.-M. Camadro, D. Urban-Grimal, and P. Labbe, 1982, Biochem. Biophys. Res. Commun. 106, 724-730). Protoporphyrinogen is enzymatically generated from coproporphyrinogen by partially purified yeast coproporphyrinogen oxidase. The protoporphyrinogen oxidase reaction is then initiated by addition of the membrane fraction to be tested. However, when very low amounts of membrane are used, low amounts of Tween 80 (less than 1 mg/ml) have to be added to the incubation mixture to solubilize protoporphyrin IX in order to ensure optimal fluorescence intensity. This detergent has no effect on the rate of the enzymatic reaction when used at concentrations less than 2 mg/ml. Activities ranging from 0.1 to 4-5 nmol protoporphyrin formed per hour per assay are easily and reproducibly measured in less than 30 min.     

Comparison of two assay methods for activities of uroporphyrinogen decarboxylase and coproporphyrinogen oxidase

Uroporphyrinogen decarboxylase (UROD) and coproporphyrinogen oxidase (copro'gen oxidase) are two of the least well understood enzymes in the heme biosynthetic pathway. In the fifth step of the pathway, UROD converts uroporphyrinogen III to coproporphyrinogen III by the decarboxylation of the four acetic acid side chains. Copro'gen oxidase then converts coproporphyrinogen III to protoporphyrinogen IX via two sequential oxidative decarboxylations. Studies of these two enzymes are important to increase our understanding of their mechanisms. Assay comparisons of UROD and copro'gen oxidase from chicken blood hemolysates (CBH), using a newly developed micro-assay, showed that the specific activity of both enzymes is increased in the micro-assay relative to the large-scale assay. The micro-assay has distinct advantages in terms of cost, labor intensity, amount of enzyme required, and sensitivity.     

The enzymic conversion of protoporphyrinogen IX to protoporphyrin IX. Protoporphyrinogen oxidase activity in mitochondrial extracts of Saccharomyces cerevisiae.

The oxidation of protoporphyrinogen IX to protoporphyrin IX in yeast cells is enzyme-dependent. The enzyme, protoporphyrinogen oxidase, associated with purified mitochondria isolated from Saccharomyces cerevisiae was solubilized by sonic treatment in the presence of detergent and partially purified. The molecular weight of the enzyme was 180,000 plus or minus 18,000. The purified preparation could be stored at -20 degrees in the presence of 20% glycerol for several months without loss of activity. Enzyme activity was destroyed by heating above 40 degrees and by proteolytic digestion and irreversible inactivation occurred outside the pH range of 4.0 to 9.5. The pH optimum of the enzymic reaction was 7.45 and the value of the Michaelis constant was approximately 4.8 muM. Protoporphyrinogen oxidase did not catalyse the oxidation of coproporphyrinogen I or III or uroporphyrinogen I or III and the rate of enzymic oxidation of mesoporphyrinogen IX was less than 20% of that observed with protoporphyrinogen IX. The presence of thiol groups in the enzyme system was indicated but no metal ion or other cofactor requirement was demonstrated. Enzyme activity was insensitive to cyanide, 2,4-dinitrophenol, and azide whereas it was inhibited in the presence of Cu-2+ or Co-2+ ions, high ionic strength, heme, or hemin.     

Evidence that the coproporphyrinogen oxidase activity of rat liver is situated in the intermembrane space of mitochondria.

Preferential rupture of the outer membrane of mitochondria from rat liver releases coproporphyrinogen oxidase in parallel with components of the intermembrane space. Coproporphyrinogen III enters the mitochondrion through the freely-permeable outer membrane. Either protoporphyrinogen IX or protoporphyrin IX must then cross the inner membrane before haem synthesis can be completed.     

A radiochemical method for the measurement of coproporphyrinogen oxidase and the utilization of substrates other than coproporphyrinogen III by the enzyme from rat liver.

[14C2]Coproporphyrin III, 14C-labelled in the carboxyl carbon atoms of the 2- and 4-propionate substituents, was prepared by stepwise modification of the vinyl groups of protoporphyrin IX. The corresponding porphyrinogen was used as substrate in a specific sensitive assay for coproporphyrinogen oxidase (EC 1.3.3.3) in which the rate of production of 14CO2 is measured. With this method, the Km of the enzyme from rat liver for coproporphyrinogen III is 1.2 micron. Coproporphyrin III is a competitive inhibitor of the enzyme (Ki 7.6 micron). Apparent Km values for other substrates were measured by a mixed-substrate method: that for coproporphyrinogen IV is 0.9 micron and that for harderoporphyrinogen 1.6 micron. Rat liver mitochondria convert pentacarboxylate porphyrinogen III into dehydroisocoproporphyrinogen at a rate similar to that for the formation of protoporphyrinogen IX from coproporphyrinogen III. Mixed-substrate experiments indicate that this reaction is catalysed by coproporphyrinogen oxidase and that the Km for this substrate is 29 micron. It is suggested that the ratio of the concentration of pentacarboxylate porphyrinogen III to coproporphyrinogen III in the hepatocyte determines the relative rates of formation of dehydroisocoproporphyrinogen and protoporphyrinogen IX.     

Mouse protoporphyrinogen oxidase. Kinetic parameters and demonstration of inhibition by bilirubin.

The penultimate step of haem biosynthesis, the oxidation of protoporphyrinogen to protoporphyrin, was examined with purified murine hepatic protoporphyrinogen oxidase (EC 1.3.3.4) in detergent solution. The kinetic parameters for the two-substrate (protoporphyrinogen and oxygen) reaction were determined. The limiting Km for protoporphyrinogen when oxygen is saturating is 6.6 microM, whereas the Km for oxygen with saturating concentrations of protoporphyrinogen is 125 microM. The kcat. for the overall reaction is 447 h-1. The ratio of kcat. to the Km for protoporphyrinogen is approx. 20-fold greater than the kcat./Km,O2 ratio. The ratio of protoporphyrin formed to dioxygen consumed is 1:3. Ubiquinone-6, ubiquinone-10 and dicoumarol stimulate protoporphyrinogen oxidase activity at low concentrations (less than 15 microM), whereas coenzyme Q0 and menadione show no activation at these concentrations. Above 30 microM, all five quinones inhibit the enzyme activity. FAD does not significantly affect the activity of the enzyme. Bilirubin, a product of haem catabolism, is shown to be a competitive inhibitor of the penultimate enzyme of the haem-biosynthetic pathway, protoporphyrinogen oxidase, with a calculated Ki of 25 microM. The terminal enzyme of haem-biosynthetic pathway, namely ferrochelatase, is not inhibited by bilirubin at concentrations over double the Ki value for the oxidase. In contrast with other enzymic systems, the toxicity of bilirubin is not reversed by binding to albumin.     

In situ conversion of coproporphyrinogen to heme by murine mitochondria: terminal steps of the heme biosynthetic pathway.

Coproporphyrinogen oxidase (EC 1.3.3.3), protoporphyrinogen oxidase (EC 1.3.3.4), and ferrochelatase (EC 4.99.1.1) catalyze the terminal three steps of the heme biosynthetic pathway. All three are either bound to or associated with the inner mitochondrial membrane in higher eukaryotic cells. A current model proposes that these three enzymes may participate in some form of multienzyme complex with attendant substrate channeling (Grand-champ, B., Phung, N., & Nordmann, Y., 1978, Biochem. J. 176, 97-102; Ferreira, G.C., et al., 1988, J. Biol. Chem. 263, 3835-3839). In the present study we have examined this question in isolated mouse mitochondria using two experimental approaches: one that samples substrate and product levels during a timed incubation, and a second that follows dilution of radiolabeled substrate by pathway intermediates. When isolated mouse mitochondria are incubated with coproporphyrinogen alone there is an accumulation of free protoporphyrin. When Zn is added as a substrate for the terminal enzyme, ferrochelatase, along with coproporphyrinogen, there is formation of Zn protoporphyrin with little accumulation of free protoporphyrin. When EDTA is added to this incubation mixture with Zn, Zn protoporphyrin formation is eliminated and protoporphyrin is formed. We have examined the fate of radiolabeled substrates in vitro to determine if exogenously supplied pathway intermediates can compete with the endogenously produced compounds. The data demonstrate that while coproporphyrinogen is efficiently converted to heme in vitro when the pathway is operating below maximal capacity, exogenous protoporphyrinogen can compete with endogenously formed protoporphyrinogen in heme production.(ABSTRACT TRUNCATED AT 250 WORDS)     

Oxygen-dependent coproporphyrinogen III oxidase (HemF) from Escherichia coli is stimulated by manganese

During heme biosynthesis in Escherichia coli two structurally unrelated enzymes, one oxygen-dependent (HemF) and one oxygen-independent (HemN), are able to catalyze the oxidative decarboxylation of coproporphyrinogen III to form protoporphyrinogen IX. Oxygen-dependent coproporphyrinogen III oxidase was produced by overexpression of the E. coli hemF in E. coli and purified to apparent homogeneity. The dimeric enzyme showed a Km value of 2.6 microm for coproporphyrinogen III with a kcat value of 0.17 min-1 at its optimal pH of 6. HemF does not utilize protoporphyrinogen IX or coproporphyrin III as substrates and is inhibited by protoporphyrin IX. Molecular oxygen is essential for the enzymatic reaction. Single turnover experiments with oxygen-loaded HemF under anaerobic conditions demonstrated electron acceptor function for oxygen during the oxidative decarboxylation reaction with the concomitant formation of H2O2. Metal chelator treatment inactivated E. coli HemF. Only the addition of manganese fully restored coproporphyrinogen III oxidase activity. Evidence for the involvement of four highly conserved histidine residues (His-96, His-106, His-145, and His-175) in manganese coordination was obtained. One catalytically important tryptophan residue was localized in position 274. None of the tested highly conserved cysteine (Cys-167), tyrosine (Tyr-135, Tyr-160, Tyr-170, Tyr-213, Tyr-240, and Tyr-276), and tryptophan residues (Trp-36, Trp-123, Trp-166, and Trp-298) were found important for HemF activity. Moreover, mutation of a potential nucleotide binding motif (GGGXXTP) did not affect HemF activity. Two alternative routes for HemF-mediated catalysis, one metal-dependent, the other metal-independent, are proposed.     

Purification of bovine protoporphyrinogen oxidase: immunological cross-reactivity and structural relationship to ferrochelatase

Protoporphyrinogen oxidase, the penultimate enzyme in the haem biosynthetic pathway has been purified to apparent homogeneity from bovine liver mitochondria, by a published method (Dailey, H.A. and Fleming, J.E., (1983)), with an additional ion-exchange chromatography step, using a Mono Q column on an FPLC-system. This gave a product with a 68% yield and 870-fold purification. Protoporphyrinogen oxidase (EC 1.3.3.4) has an apparent Mr of 57,000 and the Km for protoporphyrinogen IX was 16.6 microM. Activity of the isolated enzyme was increased by 66% in the presence of oleic acid, and evidence was obtained for a FAD prosthetic group. Ferrochelatase (EC 4.99.1.1) was purified and antibodies were raised in rabbits against ferrochelatase and protoporphyrinogen oxidase, respectively. Anti-protoporphyrinogen oxidase IgG showed marked cross-reactivity with ferrochelatase and anti-ferrochelatase IgG cross-reacted with protoporphyrinogen oxidase. In addition, radiolabelled peptides of both enzymes, generated by chymotrypsin, demonstrated common peptides when analysed by two-dimensional chromatography.     

Bacillus subtilis HemY is a peripheral membrane protein essential for protoheme IX synthesis which can oxidize coproporphyrinogen III and protoporphyrinogen IX.

The hemY gene of the Bacillus subtilis hemEHY operon is essential for protoheme IX biosynthesis. Two previously isolated hemY mutations were sequenced. Both mutations are deletions affecting the hemY reading frame, and they cause the accumulation of coproporphyrinogen III or coproporphyrin III in the growth medium and the accumulation of trace amounts of other porphyrinogens or porphyrins intracellularly. HemY was found to be a 53-kDa peripheral membrane-bound protein. In agreement with recent findings by Dailey et al. (J. Biol. Chem. 269:813-815, 1994) B. subtilis HemY protein synthesized in Escherichia coli oxidized coproporphyrinogen III and protoporphyrinogen IX to coproporphyrin and protoporphyrin, respectively. The protein is not a general porphyrinogen oxidase since it did not oxidize uroporphyrinogen III. The apparent specificity constant, kcat/Km, for HemY was found to be about 12-fold higher with coproporphyrinogen III as a substrate compared with protoporphyrinogen IX as a substrate. The protoporphyrinogen IX oxidase activity is consistent with the function of HemY in a late step of protoheme IX biosynthesis, i.e., HemY catalyzes the penultimate step of the pathway. However, the efficient coproporphyrinogen III to coproporphyrin oxidase activity is unexplained in the current view of protoheme IX biosynthesis.     

Simple and rapid method for the determination of coproporphyrinogen oxidase activity

Coproporphyrinogen oxidase, the sixth enzyme in the biosynthetic heme pathway, catalyzes the oxidative decarboxylation of coproporphyrinogen III to protoporphyrinogen IX. A reversed-phase high pressure liquid chromatography method was developed to measure coproporphyrinogen oxidase enzymatic activity in rat liver. With this method, the separation, identification and quantification of coproporphyrin III (oxidized substrate) and protoporphyrin IX (oxidized product) present in the assays could be carried out with no need of derivatization and in less than 15 min. Rat and human liver coproporphyrinogen oxidase basal activities determined using this method were 0.41+/-0.05 nmol of protoporphyrin IX/h per mg of hepatic protein and 0.87+/-0.06 protoporphyrin IX/h per mg of hepatic protein, respectively. Kinetic studies showed that optimum pH for rat CPGox is 7.3, and that its activity is linear in the range of protein concentrations and incubation times assayed. The present paper describes a sensitive, specific and rapid fluorometric high performance liquid chromatography method to measure coproporphyrinogen oxidase, which could be applied to the diagnosis of human coproporphyria, and which is also suitable for the study of lead and other metal poisoning that produce alterations in this enzymatic activity.     

A high-performance-liquid-chromatographic method for the assay of coproporphyrinogen oxidase activity in rat liver.

An h.p.l.c. method was developed for the assay of coproporphyrinogen oxidase activity in rat liver. The protoporphyrinogen IX formed is completely oxidized to protoporphyrin IX for separation and quantification by reversed-phase chromatography with mesoporphyrin as the internal standard. The Km of coproporphrinogen oxidase is 1.01 +/- 0.23 microM. The activities are 4.07 +/- 0.40 nmol of protoporphyrin IX/h per mg of mitochondrial protein and 224 +/- 19 nmol of protoporphyrin IX/h per g of liver tissue homogenate. The method is sensitive enough for measuring enzyme activity in small amounts of human tissue from needle biopsy.     

Effects of Oxygen Limitation on the Biosynthesis of Photo Pigments in the Red Microalgae Galdieria sulphuraria Strain 074G

As a consequence of the inhibition of one of the steps in the biosynthesis of the photopigments chlorophyll and phycobilin, the red microalga Galdieria partita excretes coproporphyrinogen III in the medium when growing on glucose. No coproporphyrinogen III was found when the closely related red microalgae G. sulphuraria strain 074G was grown on glucose and excessive amounts of oxygen. When under the same conditions oxygen was limiting, coproporphyrinogen III was present in the medium. We conclude that not glucose but the amount of oxygen in the medium results in the accumulation of coproporphyrinogen III. This is explained by the inactivition of the oxygen-dependent coproporphyrinogen III oxidase that converts coproporhyrinogen III to protoporphyrinogen IX, one of the intermediate steps in the biosynthesis of chlorophyl and phycobilin.     

A soybean coproporphyrinogen oxidase gene is highly expressed in root nodules

In plants the enzyme coproporphyrinogen oxidase catalyzes the oxidative decarboxylation of coproporphyrinogen III to protoporphyrinogen IX in the heme and chlorophyll biosynthesis pathway(s).We have isolated a soybean coproporphyrinogen oxidase cDNA from a cDNA library and determined the primary structure of the corresponding gene. The coproporphyrinogen oxidase gene encodes a polypeptide with a predicted molecular mass of 43 kDa. The derived amino acid sequence shows 50% similarity to the corresponding yeast amino acid sequence. The main difference is an extension of 67 amino acids at the N-terminus of the soybean polypeptide which may function as a transit peptide.A full-length coproporphyrinogen oxidase cDNA clone complements a yeast mutant deleted of the coproporphyrinogen oxidase gene, thus demonstrating the function of the soybean protein.The soybean coproporphyrinogen oxidase gene is highly expressed in nodules at the stage where several late nodulins including leghemoglobin appear. The coproporphyrinogen oxidase mRNA is also detectable in leaves but at a lower level than in nodules while no mRNA is detectable in roots.The high level of coproporphyrinogen oxidase mRNA in soybean nodules implies that the plant increases heme production in the nodules to meet the demand for additional heme required for hemoprotein formation.     

Crystal structure of coproporphyrinogen III oxidase reveals cofactor geometry of Radical SAM enzymes

'Radical SAM' enzymes generate catalytic radicals by combining a 4Fe-4S cluster and S-adenosylmethionine (SAM) in close proximity. We present the first crystal structure of a Radical SAM enzyme, that of HemN, the Escherichia coli oxygen-independent coproporphyrinogen III oxidase, at 2.07 A resolution. HemN catalyzes the essential conversion of coproporphyrinogen III to protoporphyrinogen IX during heme biosynthesis. HemN binds a 4Fe-4S cluster through three cysteine residues conserved in all Radical SAM enzymes. A juxtaposed SAM coordinates the fourth Fe ion through its amide nitrogen and carboxylate oxygen. The SAM sulfonium sulfur is near both the Fe (3.5 A) and a neighboring sulfur of the cluster (3.6 A), allowing single electron transfer from the 4Fe-4S cluster to the SAM sulfonium. SAM is cleaved yielding a highly oxidizing 5'-deoxyadenosyl radical. HemN, strikingly, binds a second SAM immediately adjacent to the first. It may thus successively catalyze two propionate decarboxylations. The structure of HemN reveals the cofactor geometry required for Radical SAM catalysis and sets the stage for the development of inhibitors with antibacterial function due to the uniquely bacterial occurrence of the enzyme.