Rat liver ferrochelatase. Purification, properties, and stimulation by fatty acids

Characterization of ferrochelatase in kidney and erythroleukemia cells

Ferrochelatase from bovine kidney mitochondria has been purified 1600-fold with a 6.5% yield, exhibiting a specific activity of 490 nmol mesoheme formed/mg of protein per min. The Km values for mesoporphyrin IX and protoporphyrin IX with iron were 12.5 and 12.7 microM, respectively. The Km values for iron and zinc with mesoporphyrin IX were 3.51 and 3.17 microM, respectively. The purified enzyme showed a single band with an apparent molecular mass of 42,000 daltons (42 kDa) on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The rabbit antibody against the purified enzyme markedly inhibited activities of the enzyme from both the kidney and liver. Immunoblot analysis showed that the antibody reacted with the renal as well as the hepatic enzymes showing the same molecular weight. Peptide mapping with trypsin or alpha-chymotrypsin showed that digested peptides of renal enzyme were similar to those of hepatic enzyme. Ferrochelatase activity in mouse erythroleukemia (MEL) cells increased in parallel with an increase of heme synthesis by treatment with dimethylsulfoxide. Using immunoblotting techniques, the amount of the enzyme in the MEL cells has been shown to increase by the induction, showing a molecular mass of 41 kDa which was the same as that of the mouse hepatic enzyme. Comparative structural analysis of the enzyme of MEL cells and that of mouse liver by peptide mapping showed that the partial digestive peptides of both enzymes exhibited a similar pattern. These results strongly suggest that ferrochelatase in kidney, liver and erythroid cells can be of one type.

Interaction of free porphyrins and metalloporphyrins with mouse ferrochelatase. A model for the active site of ferrochelatase

The ability of purified mouse ferrochelatase (protoheme ferro-lyase, EC 4.99.1.1) to bind and catalytically utilize a variety of porphyrins has been examined. In all, the kd, Km or Ki values for eleven different porphyrins, the Ki values for four metalloporphyrins and the kd values for two metalloporphyrins were determined. The data obtained demonstrate that mouse ferrochelatase binds a wide variety of porphyrins and metalloporphyrins with kd values ranging from 6 nM for N-methylprotoporphyrin to 1.08 microM for coproporphyrin III. However, the enzyme shows a degree of catalytic specificity for the substituents at the 2.4 positions and utilizes only proto-, hemato-, meso-, deutero-, 2,4-monohydroxy-ethylmonovinyl- and 2,4-monohydroxymethylmonovinyl deuteroporphyrin as substrates. The data show that the magnitude of the kd is not an accurate indicator of the ability of the porphyrin to serve as a substrate or inhibitor and, with the exception of N-methylprotoporphyrin, the size of the kd is several orders of magnitude less than that of the Km or Ki. Of the metalloporphyrins examined (Fe, Co, Zn and Sn) all inhibited ferrochelatase at micromolar concentrations, although tin protoporphyrin was the least effective. These data are discussed in terms of an active site model for mammalian ferrochelatase.

Characteristics of purified protoporphyrinogen oxidase from barley

The membrane bound enzyme oxidizing protoporphyrinogen to protoporphyrin, a step in heme and chlorophyll synthesis, was purified to a single prominent polypeptide band on SDS/PAGE from barley mitochondrial fractions. It contained a variety of lipids including 0.66 mg of phosphatidyl ethanolamine and 0.46 mg of free fatty acid per mg of protein. Iron, but no flavins or cytochromes, was detected. In the presence of glutathione, enzymatic oxidation was inhibited by the iron chelator o-phenanthroline but was stimulated by iron EDTA. The purified enzyme was inhibited by reductants such as glutathione, ascorbate, NADH and NADPH. These findings are compatible with some direct or indirect involvement of lipids and iron in this oxidation in plants.

Purification and properties of mouse liver coproporphyrinogen oxidase

Coproporphyrinogen oxidase was purified to homogeneity from mouse liver. The specific activity of the pure enzyme was 3500 nmol.h-1.mg-1; its apparent molecular mass (35 kDa) was confirmed by immunological characterization of the enzyme in a trichloroacetic-acid-precipitated total-liver-protein extract. The native enzyme appeared to be a dimer of 70 kDa as determined by gel filtration under nondenaturating conditions. The Km value for coproporphyrinogen III was 0.3 microM. The purified enzyme was activated by neutral detergents and phospholipids (affecting both Vmax and Km) but inhibited by ionic detergents. Reactivity toward sulfhydryl agents suggested the possible involvement of (an) SH group(s) for the activity. When compared to the previously purified coproporphyrinogen oxidases (from bovine liver and yeast), the mouse liver coproporphyrinogen oxidase appears to share many common catalytic properties with both enzymes. However, its apparent molecular mass is very different from that of the bovine liver enzyme (71.6 kDa) but identical to that found for the yeast (Saccharomyces cerevisiae) enzyme.

Modulation of hepatic ferrochelatase activity by dietary manipulation of mitochondrial phospholipid fatty acyl groups

Ferrochelatase is an enzyme bound to the inner mitochondrial membrane, which is important in heme biosynthesis. Activity of purified ferrochelatase is affected by the presence of certain fatty acids. In the present study, we examined whether the activity of ferrochelatase is altered by dietary manipulation of the composition of mitochondrial membrane phospholipid fatty acyl groups. Rats were fed diets containing triolein, safflower or menhaden oil as 5% (w/w) of the diet. After 3 weeks, the animals were killed and liver mitochondria were isolated. Phospholipid fatty acid composition and ferrochelatase activity were assayed in the isolated mitochondria. Marked differences were seen. The proportion of oleic acid was highest in the triolein oil-fed group, that of linoleic and arachidonic acid was highest in the safflower oil-fed group and the proportion of eicosapentaenoic acid was highest in the menhaden oil-fed group. Ferrochelatase activity was greatest in the triolein oil-fed group and lowest in the menhaden oil-fed group regardless of whether the mitochondria were intact, sonicated or sonicated and treated with Tween 20. Mixing of mitochondria from menhaden oil-fed rats with triolein oil resulted in a significant increase in ferrochelatase activity. Membrane fluidity and activities of the mitochondrial membrane enzymes succinic dehydrogenase and cytochrome oxidase did not differ among the groups. We conclude that dietary manipulation of mitochondrial membrane phospholipid fatty acyl group composition can directly modulate hepatic ferrochelatase activity. This has potential application in the treatment of protoporphyria, the genetic disorder in which ferrochelatase activity is deficient.

Ferrochelatase activity in Azospirillum brasilense with reference to the influence of metal cations

Ferrochelatase in membrane preparations from Azospirillum brasilense displayed an activity of 2.17 mumol protoheme formed.h-1.mg protein-1 which is 10-fold greater than previous reports for other bacteria. This ferrochelatase showed an apparent Km of 20.9 microM for Fe2+, a pH optimum of 6.0-6.5, and stimulation by oleic or stearic acids. Co2+, Cu2+ and Zn2+ inhibited the incorporation of Fe2+ into protoporphyrin IX while Ni2+ and Mg2+ had no effect on protoheme synthesis. Activity with Fe2+ and mesoporphyrin IX was less than with protoporphyrin IX but deuteroporphyrin IX produced the highest rate of protoheme synthesis. The membrane fraction containing ferrochelatase activity was found to insert Cu2+, Ni2+, Zn2+ and Co2+ enzymatically into protoporphyrin IX to produce metalloporphyrins. Cu2+ incorporation into protoporphyrin IX proceeded at a rate greater than with Fe2+ and the Km for Cu2+ was 21.9 microM.

Liver ferrochelatase from normal and hexachlorobenzene porphyric rats. Studies on their properties

1. The aim of the present work is to shed light on the way of action of hexachlorobenzene (HCB) on hepatic ferrochelatase the mitochondrial enzyme which catalyzes the last step of haem biosynthetic pathway. 2. Some properties of this enzyme from normal and HCB porphyric rat liver were studied. 3. The present findings indicate that HCB treatment would modify the configuration of the enzyme perhaps allowing the active center of the porphyric ferrochelatase to be more exposed. 4. As a consequence it would show: (a) its higher affinity for the iron; (b) the shorter time necessary to form the intermediate enzyme-substrate, reflected both by the existence of a shorter lag and consequently a shorter pre incubation time. 5. However this modification elicited by the fungicide does not alter the submitochondrial distribution of the enzyme nor the optimal conditions for its measurement.

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.

Properties of membrane bound ferrochelatase purified from baboon liver mitochondria

1. Baboon ferrochelatase was purified to apparent homogeneity. 2. The pH optimum was 7.85 and the pI 5.3. 3. The estimated molecular weight was 205 K made up by two 50 + 60 K heterodimers. 4. The Km values for proto- and mesoporphyrin were 18.5 and 10.8 microM with iron as co-substrate. With cobalt as co-substrate the Km values were 34.5 and 10.4 microM, respectively. The mean Km value for iron was 2.2 microM while cobalt acted as a complete inhibitor. 5. Lead played a dual role that of both pseudo substrate and inhibitor. As shown by inhibitor kinetics, Pb acted as a two-step two-site parabolic competitive inhibitor. The mean Ki value at low Pb levels was 0.65 mM and at high levels 0.17 mM. 6. Substrate inhibition occurred above 36 microM for proto- and 44 microM for mesoporphyrin with iron as co-substrate. For iron, with mesoporphyrin as co-substrate it occurred above 29 microM.

Nonenzymatic synthesis of delta-aminolevulinate (ALA) by cobalt (Co++)

Cobalt, a metal known to modulate the heme biosynthetic enzymes, is shown to be capable of catalysing the formation of ALA through a transamination reaction. The transamination reaction follows a double-displacement reaction kinetics. Further, it has also been shown that the product of the reaction catalysed by cobalt can be used by the enzyme ALA dehydratase as the substrate in the formation of porphobilinogen. The formation of ALA by cobalt can be inhibited by the intermediates of the heme biosynthetic pathway, mainly protoporphyrin. Heme, on the other hand, does not have any effect on the reaction at all concentrations tested.

An HPLC assay for rat liver ferrochelatase activity

A rapid, reliable, sensitive and reproducible HPLC method was developed for the assay of ferrochelatase activity in rat liver. The assay was carried out aerobically with Zn2+ and mesoporphyrin or protoporphyrin IX as substrates. Zn-porphyrins formed were extracted with dimethyl sulphoxide/methanol (30:70, v/v) containing Zn-deuteroporphyrin as the internal standard for separation and quantification by reversed-phase chromatography. The Km for mesoporphyrin was 5.9 microM, for protoporphyrin IX 8.8 microM and for zinc 6.0 microM. The specific activities were 33.1 +/- 5.0 nmol Zn-mesoporphyrin or 13.4 +/- 2.0 nmol Zn-protoporphyrin formed per hour per mg of protein for mitochondria and 12.3 +/- 2.2 nmol Zn-mesoporphyrin or 4.6 +/- 0.9 nmol Zn-protoporphyrin per hour per mg of protein for liver homogenate.

HPLC determination of ferrochelatase activity in human liver

A method utilizing HPLC to estimate ferrochelatase activity in human liver cells is presented. A partially purified homogenate of liver cells is incubated with mesoporphyrin IX and cobalt(II)ion. The ferrochelatase in the homogenate incorporates the cobalt(II)ion into the mesoporphyrin. After a fixed time (90 min) the porphyrins are extracted into an ethyl acetate-acetic acid mixture. The porphyrins are then separated using reversed phase HPLC with a mobile phase of methanol-acetonitrile-phosphate buffer pH 3.0 (200:60:30 v/v). The enzyme activity is estimated by measuring the rate of utilization of mesoporphyrin. The optimum pH and substrate concentration for the reaction have been determined.

Association of ferrochelatase with Complex I in bovine heart mitochondria

The location of ferrochelatase in bovine heart mitochondria has been studied. When the mitochondria were fractionated into Complexes I, II and III, ferrochelatase activity was only found in Complex I. Complex I also showed heme synthesis from ferric ion in the presence of NADH as an electron donor. Immunoblot experiments confirmed the presence of ferrochelatase in Complex I, but not in Complexes II or III. Some phospholipids, including phosphatidylserine and cardiolipin, stimulated NADH-dependent heme synthesis from ferric ion. When purified ferrochelatase was incubated with the low molecular weight form of NADH dehydrogenase prepared from Complex I, heme synthesis from ferric ion occurred by the addition of NADH. FMN markedly elevated the synthesis. These results indicate that ferrous ion is produced by NADH oxidation in Complex I and is then utilized for heme synthesis by ferrochelatase.

Effect of decreased ferrochelatase activity on iron and porphyrin content in mitochondria of mice with porphyria induced by griseofulvin

The content of iron and protoporphyrin in liver mitochondria from mice with porphyria induced by griseofulvin was measured. The amount of porphyrin was 0.0076 +/- 0.0043, 4.11 +/- 0.58 and 22.2 +/- 6.8 nmol/mg protein (n = 5) in mitochondria from control animals and animals treated with griseofulvin for 3 days and 4-5 weeks, respectively. The energy coupling of the mitochondria was greatly diminished after 4-5 weeks of treatment, and the ferrochelatase activity was inhibited 80-90%, compared to that of control animals. Mitochondrial preparations isolated by differential centrifugation were contaminated with iron-containing lysosomes which could be removed by Percoll density-gradient centrifugation. In purified mitochondrial preparations no change in the amount of non-heme iron was found after griseofulvin feeding, representing 3.36 +/- 0.15, 3.97 +/- 0.40 and 3.59 +/- 0.23 nmol/mg protein for control animals, 3 days- and 4-5 weeks-treated animals, respectively (n = 4). A mitochondrial iron pool previously identified in rat liver mitochondria and shown to be available for heme synthesis in vitro (Tangerås, A. (1985) Biochim. Biophys. Acta 843, 199-207) was also present in mitochondria from mice. The magnitude of this iron pool, as well as its availability for heme synthesis, was not changed after treatment of the animals with griseofulvin. The fact that porphyrin, but not iron, accumulated in the mitochondria when ferrochelatase was inhibited is discussed with regard to our understanding of the process of heme synthesis and its regulation.

A comparative study on iron sources for mitochondrial haem synthesis including ferritin and models of transit pool species

The rates of reaction of various exogenic iron(III) complexes with deuteroporphyrin IX in isolated mitochondria to form deuterohaem were measured. Ferritin was shown to supply iron readily for haem synthesis if the ferritin iron was reductively mobilised by the mitochondrial respiratory chain with succinate as substrate and FMN as mediator. In contrast, polynuclear complexes of iron(III) were able to form deuterohaem without added FMN. Rates of haem formation are about five times higher for the lowest polynuclear units than for ferritin. Sorbitol, gluconate, and bovine serum albumin were used as scavengers for polynuclear complexes with restricted size. Strong chelators of iron(II) compete favourably for deuterohaem formation, which supports the multistep mechanism for haem formation suggested by a priori arguments. Rates of deuterohaem formation were measured in homologous and heterologous systems of ferritins and mitochondria. Slightly differing rates of haem formation were shown to originate in different rates of iron mobilisation from the ferritins. The lack of species specificity in the interaction of ferritin with mitochondria also shows up in the linear dependence of ferritin binding on its bulk concentration as measured using 3H-labeled ferritin. Rates of haem formation are virtually the same in mitoplasts and mitochondria which indicates insignificant influences of the outer membrane. The hypothesis of low polynuclears as major components of the intracellular transit iron pool implies that both ferritin and transit iron pool species are largely equivalent sources of iron for mitochondrial haem synthesis.

Ferrochelatase from Rhodopseudomonas sphaeroides: substrate specificity and role of sulfhydryl and arginyl residues

Purified ferrochelatase (protoheme ferrolyase; EC 4.99.1.1) from the bacterium Rhodopseudomonas sphaeroides was examined to determine the roles of cationic and sulfhydryl residues in substrate binding. Reaction of the enzyme sulfhydryl residues with N-ethylmaleimide or monobromobimane resulted in a rapid loss of enzyme activity. Ferrous iron, but not porphyrin substrate, had a protective effect against inactivation by these two reagents. Quantitation with 3H-labeled N-ethylmaleimide revealed that inactivation required one to two sulfhydryl groups to be modified. Modification of arginyl residues with either 2,3-butanedione or camphorquinone 10-sulfonate resulted in a loss of ferrochelatase activity. A kinetic analysis of the modified enzyme showed that the Km for ferrous iron was not altered but that the Km for the porphyrin substrate was increased. These data suggested that arginyl residues may be involved in porphyrin binding, possibly via charge pair interactions between the arginyl residue and the anionic porphyrin propionate side chain. Modification of lysyl residues had no effect on enzyme activity. We also examined the ability of bacterial ferrochelatase to use various 2,4-disubstituted porphyrins as substrates. We found that 2,4-bis-acetal- and 2,4-disulfonate deuteroporphyrins were effective substrates for the purified bacterial enzyme and that N-methylprotoporphyrin was an effective inhibitor of the enzyme. Our data for the ferrochelatase of R. sphaeroides are compared with previously published data for the eucaryotic enzyme.

Reconstitution of heme-synthesizing activity from ferric ion and porphyrins, and the effect of lead on the activity

We examined the activity of heme synthesis when ferrochelatase purified from rat liver mitochondria was incubated with ferric chloride and mesoporphyrin IX as substrates in the absence of reducing reagents. In the presence of the NADH dehydrogenase-rich fraction and NAD(P)H, mesoheme was synthesized; the addition of FMN or FAD markedly enhanced the activity. These results indicate that the NAD(P) H-oxidizing system reduces ferric ion to ferrous ion. This ferrous ion is then utilized for heme synthesis by ferrochelatase. The effect of lead on NAD(P)H-dependent heme synthesis was also examined. Lead reduced NAD(P)H-dependent heme synthesis by 50% at 10(-5) M, but had no effect when ferrous ion was used as substrate. Zn-Porphyrin synthesis was not changed in the presence of Pb2+ at 10(-5) M. Thus, heme synthesis from ferric ion was more susceptible to Pb2+ than heme synthesis from ferrous ion.

Kinetic properties of the membrane-bound human liver mitochondrial protoporphyrinogen oxidase

We studied the kinetic properties of the membrane-bound human liver mitochondrial protoporphyrinogen oxidase. The activity was monitored by direct recording of protoporphyrin fluorescence appearance in the incubation medium without extraction or dilution. The human liver enzyme shows some different catalytic properties than the rat enzyme since its optimum pH was found at 7.2. We also measured the optimum pH on partially purified protoporphyrinogen oxidase from solubilized human mitochondrial membranes. Like the rat enzyme, the human enzyme had a molecular weight of congruent to 32,000 as determined by gel filtration, but its optimum pH was the same as that of the membrane-bound enzyme. The apparent Km for protoporphyrinogen IX of the membrane-bound enzyme was a function of the pH; Km = 0.16 microM at pH 7.2, 0.33 microM at pH 8.0, and 0.55 microM at pH 8.5. Moreover, there was inhibition by excess protoporphyrinogen IX (KI = 5 microM at pH 7.2). The human enzyme was able to catalyze the oxidation of mesoporphyrinogen IX to mesoporphyrin IX. In this case, the Lineweaver-Burk plot of the data showed a biphasic curve with two different apparent Km's for mesoporphyrinogen IX of 0.5 microM (Vmax = 2.40 nmol h-1 mg-1) and 4 microM (Vmax = 5.7 nmol h-1 mg-1). Human liver protoporphyrinogen oxidase was sensitive to inhibition by some metalloporphyrins such as Mn- and Co-protoporphyrin, and to a lesser degree by Cd-, Ni- and Fe-protoporphyrin (heme). Cu-, Mg-, Sn-, and Zn-protoporphyrins were not inhibitors of the activity. A detailed study of the inhibition of protoporphyrinogen oxidase by cobalt-protoporphyrin shows a noncompetitive mechanism of inhibition with respect to protoporphyrinogen IX (KIapp = 0.8 microM).

The effects of lead on differentiation of the Friend leukemia cells and rat bone marrow cells

The effects of lead toxicity on differentiation of erythroid cells was examined using Friend leukemia cells induced with 2% dimethyl sulfoxide. By increasing the concentration of lead, these cells exhibited a lag before the onset of induction. When incorporation of [3H]-delta-aminolevulinic acid into heme was compared, the maximum incorporation into the cells without lead was on the third day after induction, while it was on the fifth day in the presence of lead (5 X 10(-4) M). However, these cells did reach similar differentiation stages by the seventh day. The amount of delta-aminolevulinic acid which was excreted into the medium increased in the presence of more than 10(-4) M lead. The amount of coproporphyrin III was slightly increased with 10(-6) M lead. Protoporphyrin IX content in the cells decreased slightly with increasing concentrations of lead. delta-Aminolevulinic acid dehydratase activity in cells which were cultured in the presence of lead was low, while synthesis of this enzyme increased in the presence of lead. The bone marrow cells from lead-poisoned rats exhibited a lag in onset of maturation, which was consistent with the effect of lead on Friend cells.

Spectroscopic examination of the active site of bovine ferrochelatase

Spectrofluorometric techniques have been employed to examine the active site of the terminal enzyme of the heme biosynthetic pathway, ferrochelatase (protoheme ferrolyase, EC 4.99.1.1). The fluorescence of both endogenous tryptophan and exogenous 2-(4-maleimidylanilino)naphthalene-6-sulfonic acid (MIANS) has been examined. The fluorescence emission of the enzyme's active site bound MIANS is at 428 nm while the enzyme tryptophan(s) yielded a single fluorescence emission maximum at 347 nm. These values are characteristic of a polar environment for tryptophan and a relatively nonpolar environment for the MIANS. The dynamic fluorescence quenching constants for acrylamide of MIANS and tryptophan are 3.00 M-1 and 1.85 M-1, respectively. Quenching constants for KI of both fluorescent centers were approximately 1 M-1. These data suggest that both fluorophores are poorly accessible to the external anionic contact quencher but that an unchanged quencher, while larger, is still better able to penetrate the enzyme's active site. The extrapolated anisotropies (r0) for ferrochelatase-bound MIANS and tryptophan are 0.198 and 0.307. The dissociation constant (KD) determined by fluorescence anisotropy of protoporphyrin was 1.5 microM with the calculated number of porphyrin binding sites as 1.0 per 40000 daltons. A model is presented for the active site of ferrochelatase based upon the data presented here and previously. This model proposes that the active site is a hydrophobic pocket similar in nature to the heme binding crevices found in many hemoproteins.

In vivo regulation of delta-aminolevulinate dehydratase activity

The interrelationships among purified delta-aminolevulinate dehydratase (ALA-D; EC 4.2.1.24) activity, Pb, and ALA-D concentrations were studied in vitro. The ratio of Pb to the ALA-D subunit, but not the Pb concentration, determined the relative activity of ALA-D, indicating the significance of the amount of ALA-D in studying the mechanism of enzyme inhibition by Pb. To elucidate the in vivo mechanisms of ALA-D regulation, male Wistar rats, 6 months old, were treated with Pb, Zn, and glutathione (GSH) separately or in combination for 130 days. After Pb administration, the amount of ALA-D, as determined by radioimmunoassay, increased in the presence and in the absence of the Zn-GSH pretreatment, even if the enzyme activity were higher (the Zn-GSH-Pb-treated rats) than that of the control. Zn and GSH restored the enzyme activity in vivo synergistically. Since immunochemical study showed the identity of the liver ALA-D with the erythroid ALA-D, the liver and erythroid data were pooled to quantify the interrelationship among ALA-D activity, and Pb, Zn, SH, and the enzyme concentrations. The equation was the relative activity of ALA-D (%) = 0.256.[Pb/ALA-D subunit]2 - 9.56.[Pb/ALA-D subunit] - 0.000281.[square root Zn.SH/ALA-D subunit]2 + 0.0898..[square root Zn.SH/ALA-D subunit] + 33.6 (multiple correlation coefficient = 0.909, n = 108, p less than 0.01). The result indicated that 83% of the in vivo regulation of ALA-D activity is explained when the four factors, Pb, Zn, SH, and ALA-D concentrations, are considered in combination.

Effect of unsaturated fatty acids on protoporphyrinogen oxidation, a step in heme and chlorophyll synthesis in plant organelles

Oleic acid stimulates enzymatic protoporphyrinogen oxidation by extracts of barley mitochondria and etioplasts. Greater stimulation occurred with Triton X-100 extracts which had been passed over a Sephacryl S-200 column than with crude Triton extracts, suggesting that purification may have removed a lipid factor required for optimal enzymatic activity. Palmitic acid, various phospholipids and detergents, or esters and alcohols of oleic acid did not substitute for free oleic acid. Linoleic acid caused a greater stimulation of protoporphyrinogen oxidation in both crude and purified barley organelle extracts and also caused a slow chemical oxidation of protoporphyrinogen. The stimulating effect of unsaturated fatty acids on enzymatic protoporphyrinogen oxidation may indicate a lipid requirement for this membrane bound enzyme or may also indicate involvement of unsaturated lipid oxidation in plant protoporphyrinogen oxidation.

Separation of haem compounds by reversed-phase ion-pair high-performance liquid chromatography and its application in the assay of ferrochelatase activity

The separation of haems and porphyrins was achieved in a reversed-phase ion-pair high-performance liquid chromatography system using tetrabutylammonium hydrogen sulphate as the pairing ion. The concentration of methanol and pH in the mobile phase were determinative parameters for the elution pattern of the compounds. Two isocratic systems--one for the assay of protohaem IX and one for deuterohaem IX--were developed. The chromatographic systems were applied to the assay of ferrochelatase activity in mitochondria using either protoporphyrin or deuteroporphyrin as the substrate. The ferrochelatase activity was also measured in reticulocytes, which contain high levels of endogenous haem.

Effect of glucose on the induction of delta-aminolevulinic acid synthase and ferrochelatase in isolated rat hepatocytes by allylisopropylacetamide

The present work shows that allylisopropylacetamide exerts an inducing effect on delta-aminolevulinic acid synthase and ferrochelatase activities in isolated rat hepatocytes of normal adult rats. Dibutyryl cyclic AMP enhances the inducing effect produced in both enzymes. Glucose inhibits the induction of delta-aminolevulinic acid synthase and ferrochelatase in this in vitro system. A similar effect was observed with fructose and 2-deoxyglucose. No glucose effect was observed with galactose, mannose, glycerol, pyruvate and lactate. The glucose effect can be reversed with increasing concentrations of dibutyryl cyclic AMP. The simple in vitro method used in the present work promises to be a very useful tool for studies of regulatory mechanisms of porphyrin and heme biosynthesis in hepatocytes under normal and pathological conditions (hepatic porphyrias).

Non-enzymatic heme formation in the presence of fatty acids and thiol reductants

Non-enzymatic heme formation from equimolar amounts of porphyrin and iron was investigated. When mesoporphyrin IX and iron citrate were incubated with oleic acid and dithiothreitol at 37 degrees C in vacuo, mesoheme was formed in a high yield. When protoporphyrin IX and deuteroporphyrin IX were used, protoheme and deuteroheme were formed, respectively. Cysteine or 2-mercaptoethanol instead of dithiothreitol also resulted in the formation of heme. Linoleic acid was as effective as oleic acid, but at 37 degrees C, saturated fatty acids and phospholipids gave low yields. When incubation was at 70 degrees C saturated fatty acids as well as unsaturated fatty acids produced a large amount of heme. The optimum pH was 8.8. By increasing the concentration of Triton X-100 to 0.1%, heme formation decreased, and at concentrations above this level, completely disappeared. The conditions of non-enzymatic heme reaction presented here seem to be useful in elucidation of the mechanism of metalloporphyrin formation.

Protoporphyrinogen oxidation, an enzymatic step in heme and chlorophyll synthesis: partial characterization of the reaction in plant organelles and comparison with mammalian and bacterial systems

High rates of oxidation of protoporphyrinogen to protoporphyrin were demonstrable in etioplasts, chloroplasts, and mitochondria from young barley shoots. Much lower rates were observed in chloroplasts from older barley or mature spinach, in mitochondria from potatoes or rat liver, and in membranes from the bacteria Escherichia coli and Rhodopseudomonas spheroides. The presence of high activity in cells capable of rapid synthesis of large amounts of chlorophyll suggests a role for this activity in chlorophyll synthesis. Characteristics of the plant protoporphyrinogen-oxidizing activity were compared to the activity in rat liver mitochondria. The activity in spinach chloroplasts exhibited a pH optimum of 7, which was lower than that of the mammalian enzyme. The plant activity was more sensitive to inhibition by glutathione or excess detergent, and was more readily inactivated at room temperature. The plant activity exhibited less specificity toward porphyrinogen substrates, oxidizing mesoporphyrinogen as rapidly as protoporphyrinogen. The mammalian enzyme oxidized mesoporphyrinogen slowly, and neither system oxidized coproporphyrinogen or uroporphyrinogen. Both the plant and the mammalian activity were bound to organelle membranes, but could be extracted with detergents. In contrast, activity from membranes of the bacteria E. coli and R. spheroides was inactivated by detergent treatment. The plant extracts could be fractionated with ammonium sulfate and retained activity after dialysis or Sephadex G-25 treatment, suggesting no readily dissociable cofactor. The activity extracted from spinach chloroplasts was mostly inactivated by trypsin digestion, which was additional evidence for the protein nature of the plant activity.

New developments in the regulation of heme metabolism and their implications

Various endogenous and exogenous chemicals, such as hormones, drugs, and carcinogens and other environmental pollutants are enzymatically converted to polar metabolites as a result of their oxidative metabolism by the mixed-function oxidase system. This enzyme complex constitutes the major detoxifying system of man and utilizes the hemoprotein--cytochrome P-450--as the terminal oxidase. Recent studies with trace metals have revealed the potent ability of these elements to alter the synthesis and to enhance the degradation of heme moiety of cytochrome P-450. An important consequence of these metal actions is to greatly impair the ability of cells to oxidatively metabolize chemicals because of the heme dependence of this metabolic process. In this report the effects of exposure to trace metals on drug oxidations is reviewed within the framework of metal alterations of heme metabolism, including both its synthesis and degradation, since these newly discovered properties of metals have made it possible to define a major dimension of metal toxicity in terms of a unified cellular mechanism of action.

Changes in urinary delta-aminolevulinic acid at low lead exposure level with special reference to production activity

A 7-year follow-up survey on 53 workers was carried out in a lead storage battery factory to evaluate the significance of urinary delta-aminolevulinic acid (ALA) and blood lead in a work environment where lead in the air was considered to be about or less than the current occupational exposure limit. While lead in the blood and ALA in the urine had a good correlation to each other cross-sectionally as well as longitudinally, geometric means of lead concentrations in the workroom air samples which were collected following grid sampling strategy, did not correlate with ALA in urine significantly. On the contrary, the semiannual production of batteries significantly correlated with changes in mean ALA in urine. The questionnaire survey proved that the prolongation in work hours, lead to an increase in the mean ALA in urine as well as a higher incidence of higher-than-normal urinary ALA. The results clearly demonstrated the importance of the biological indicators, such as lead in blood and urinary ALA, as well as the necessity of paying attention to non-industrial hygiene factors, such as the production rate of batteries and the length of the daily shift, for the protection of the workers' health when lead in the air is moderate.

Purification and substrate specificity of bovine liver-ferrochelatase

Bovine ferrochelatase from liver mitochondria was purified 1434-fold with a 31% yield to apparent homogeneity by a procedure involving solubilization, ammonium sulfate fractionation and blue Sepharose CL-6B chromatography. The molecular weight of the homogeneous protein was 42 500 when measured by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. A molecular weight of approximately 200 000 was obtained by Sepharose 6B gel filtration. The specific activity for mesoheme synthesis was 413 nmol x mg protein-1 x min-1 at 37 degrees C and for protoheme synthesis 88 nmol x mg-1 x min-1. The optimum pH was 8.0 and Km values for the substrates were: protoporphyrin IX, 54 microM; mesoporphyrin IX, 46 microM; iron with protoporphyrin IX, 46 microM, iron with mesoporphyrin IX, 44 microM. The purified enzyme inserted iron into the following dicarboxylic porphyrins in descending order: meso-, deutero-, 2,4-diacetyldeutero-, hemato-, and protoporphyrin IX. This did not take place in the case of 2,4-diformyldeuteroporphyrin IX. Porphyrin c was converted to only a negligible amount of heme c, and coproporphyrin III did not act as a substrate at all. When metal specificity was examined, the highest value was obtained with zinc, decreasing in order with iron, cobalt and nickel. The enzyme failed to catalyze the insertion of copper or manganese into porphyrin. An antibody specific for the purified bovine ferrochelatase was prepared, and studies confirmed that the synthetic activities of iron-porphyrin, zinc-porphyrin and cobalt-porphyrin are ascribable to ferrochelatase.