Studies on the ferrochelatase activity of isolated rat liver mitochondria with special reference to the effect of oxidizable substrates and oxygen concentration

The mitochondrial ferrochelatase activity has been studied in coupled rat liver mitochondria using deuteroporphyrin IX (incorporated into liposomes of lecithin) and Fe(III) or Co(II) as the substrates.

1. 1. It was found that respiring mitochondria catalyze the insertion of Fe(II) and Co(II) into deuteroporphyrin. When Fe(III) was used as the metal donor, the reaction revealed an absolute requirement for a supply of reducing equivalents supported by the respiratory chain.

2. 2. A close correlation was found between the disappearance of porphyrin and the formation of heme which allows an accurate estimate of the extinction coefficient for the porphyrin to heme conversion. The value Δ (mM⁻¹ · cm⁻¹) = 3.5 for the wavelength pair 498 509 nm, is considerably lower than previously reported.

3. 3. The maximal rate of deuteroheme synthesis was found to be approx. 1 nM · min⁻¹ · mg⁻¹ of protein at 37 °C, pH 7.4 and optimal substrate concentrations, i.e. 75 μM Fe(III) and 50 μM deuteroporphyrin.

4. 4. Provided the mitochondria are supplemented with an oxidizable substrate, the presence of oxygen has no effect on the rate of deuteroheme synthesis.

Mitochondrial iron not bound in heme and iron-sulfur centers and its availability for heme synthesis in vitro

Rat liver mitochondrial fractions have previously been shown to contain a pool of iron which was bound neither in cytochromes nor in iron-sulfur centers (Tanger?s, A., Flatmark, T., B?ckstr?m, D. and Ehrenberg, A. (1980) Biochim. Biophys. Acta 589, 162-175), and in the present study the availability of this iron pool for heme synthesis has been studied in isolated mitochondria. A minor fraction of this iron is here shown to originate from iron-rich lysosomes present as a contaminant in mitochondrial fractions isolated by differential centrifugation, and a method for the selective quantitation of this iron pool was developed. The availability of the mitochondrial iron pool for heme synthesis by mitochondria in vitro was studied using a recently developed HPLC method for the assay of ferrochelatase activity. When deuteroporphyrin was used as the substrate, 1.04 +/- 0.13 nmol/mg protein of deuteroheme was formed after 6 h incubation at 37 degrees C when a plateau was approached, and the initial rate of heme synthesis was 0.3 nmol/h per mg protein. Heme formation from the physiological substrate protoporphyrin was also seen. The heme synthesis increased with the amount of mitochondria used and was blocked by both Fe(II) and Fe(III) chelators. The heme synthesis was independent of mitochondrial oxidizable substrates and no difference was observed between pH 7.4 and 6.5. FMN slightly stimulated the formation of heme from endogenous iron, probably by mobilization of a small amount of contaminating lysosomal iron present in the preparations. The possibility that the mitochondrial iron pool functions as the proximate iron donor for heme synthesis by ferrochelatase in vivo is discussed.     

Mitochondrial iron not bound in heme and iron-sulfur centers and its availability for heme synthesis in vitro

Rat liver mitochondrial fractions have previously been shown to contain a pool of iron which was bound neither in cytochromes nor in iron-sulfur centers (Tangerås, A., Flatmark, T., Bäckström, D. and Ehrenberg, A. (1980) Biochim. Biophys. Acta 589, 162–175), and in the present study the availability of this iron pool for heme synthesis has been studied in isolated mitochondria. A minor fraction of this iron is here shown to originate from iron-rich lysosomes present as a contaminant in mitochondrial fractions isolated by differential centrifugation, and a method for the selective quantitation of this iron pool was developed. The availability of the mitochondrial iron pool for heme synthesis by mitochondria in vitro was studied using a recently developed HPLC method for the assay of ferrochelatase activity. When deuteroporphyrin was used as the substrate, 1.04±0.13 nmol/mg protein of deuteroheme was formed after 6 h incubation at 37°C when a plateau was approached, and the initial rate of heme synthesis was 0.3 nmol/h per mg protein. Heme formation from the physiological substrate protoporphyrin was also seen. The heme synthesis increased with the amount of mitochondria used and was blocked by both Fe(II) and Fe(III) chelators. The heme synthesis was independent of mitochondrial oxidizable substrates and no difference was observed between pH 7.4 and 6.5. FMN slightly stimulated the formation of heme from endogenous iron, probably by mobilization of a small amount of contaminating lysosomal iron present in the preparations. The possibility that the mitochondrial iron pool functions as the proximate iron donor for heme synthesis by ferrochelatase in vivo is discussed.     

Induction of ER stress protects gastric cancer cells against apoptosis induced by cisplatin and doxorubicin through activation of p38 MAPK

Porphyromonas gingivalis acquires heme through an outer-membrane heme transporter HmuR and heme-binding hemophore-like lipoprotein HmuY. Here, we compare binding of iron(III) mesoporphyrin IX (mesoheme) and iron(III) deuteroporphyrin IX (deuteroheme) to HmuY with that of iron(III) protoporphyrin IX (protoheme) and protoporphyrin IX (PPIX) using spectroscopic methods. In contrast to PPIX, mesoheme and deuteroheme enter the HmuY heme cavity and are coordinated by His134 and His166 residues in a fully analogous way to protoheme binding. However, in the case of deuteroheme two forms of HmuY–iron porphyrin complex were observed differing by a 180° rotation of porphyrin about the α-γ-meso-carbon axis. Since the use of porphyrins either as active photosensitizers or in combination with antibiotics may have therapeutic value for controlling bacterial growth in vivo, it is important to compare the binding of heme derivatives to HmuY.     

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.     

Equilibrium and kinetic studies of the aggregation of porphyrins in aqueous solution.

An investigation of the behavior of protoporphyrin IX, deuteroporphyrin IX, haematoporphyrin IX and coproporphyrin III in aqueous solution revealed extensive and complex aggregation processes. Protoporphyrin appears to be highly aggregated under all conditions studied. At concentrations below 4 muM, aggregation of deutero-, haemato- and coproporphyrin is probably restricted to dimerization. At approx. 4muM each of these three porphyrins exhibits sharp changes in spectra consistent with a "micellization" process to form large aggregates of unknown size. This critical concentration increases with increasing temperature and pH, but is not very sensitive to variation in ionic strength. Temperature-jump kinetic studies on deuteroporphyrin also imply an initial dimerization process, the rate constants for which are comparable with those for various synthetic porphyrins, followed by a further extensive aggragation. The ability of a particular porphyrin to dimerize appears to parallel that of the corresponding iron(III) complexes (ferrihaems), although it is thought that ferrihaems do not exhibit further aggregation under these conditions.     

Chemical properties of water-soluble porphyrins. 4. The reaction of a 'picket-fence-like' iron (III) complex with the superoxide oxygen couple

Solution properties of the iron-(III) 'picket-fence-like' porphyrin, Fe(III)-alpha,alpha,alpha, beta-tetra-ortho (N-methyl-isonicotinamidophenyl) porphyrin, (Fe(III)PFP) were investigated. These were acid/base properties of the aquo complex with pKa of 3.9 and its aggregation (formation of dimer with K = 1 X 10(-10) dm3 mol-1), complex formation with cyanide ions and 1-methyl imidazole (1-MeIm), spectral properties of the three iron complexes in their ferric and ferrous form and the one-electron reduction potential of these complexes. Knowing these properties, the reaction of the ferric complexes, aquo, dicyano and bis (1-MeIm), with the superoxide radical and other reducing radicals were studied using the pulse radiolysis technique. The second-order reaction rate constant of O2- with the iron (III) aquo complex which governs the catalytic efficiency of the metalloporphyrin upon the disproportionation of the superoxide radical was 7.6 X 10(7) dm3 mol-1 s-1, two orders of magnitude faster when compared to the reaction of each of the other complexes. The reduction by other radicals with all iron (III) complexes had similar second-order rate constants (10(9) to 10(10) dm3 mol-1 s-1). The reduction reaction in all cases produced Fe(II)PEP and no intermediate was found. The oxidation reaction of Fe(II)PEP by O2- was one order of magnitude faster when compared to the reduction of Fe(III)PFP by the same radical. Since the reactivity of O2- toward the three iron (III) porphyrin complexes follows their reduction potentials, it is suggesting the formation of a peroxo Fe(II) porphyrin as an intermediate. The reactions of the Fe(II)PFP complexes with dioxygen were also studied. The aquo complex was found to be first order in O2 and second order in Fe(II)PFP, suggesting the formation of a peroxo Fe(II) porphyrin as an intermediate. The intermediate formation was corroborated by evidence of the rapid CO binding reaction to the aquo complex of Fe(II)PFP. The two other complexes reacted very slowly with O2 as well as with CO.     

Single-stranded DNA modification by an oligonucleotide-phthalocyanine Fe(II) conjugate: the kinetic features and the process mechanism

Catalytic oxidative modification of a single-stranded DNA with hydrogen peroxide and molecular oxygen in the presence of a conjugate containing an oligonucleotide complementary to the DNA fragment and tetra-4-carboxyphthalocyanine Fe(II) was studied. The conjugate examined was found to be active in the reaction of oxidative DNA cleavage in the presence of hydrogen peroxide, like the earlier studied oligonucleotide conjugates containing metallocomplexes tetra-4-carboxyphthalocyanine Co(II) and 2,4-di-[2-(2-hydroxyethyl)]deuteroporphyrin IX Fe(III) generating active oxygen forms. The new conjugate was more active in the case of oxidation with molecular oxygen. Kinetic features and optimal regimes of DNA oxidation with hydrogen peroxide were found.     

Studies on the utilization of ferritin iron in the ferrochelatase reaction of isolated rat liver mitochondria.

The utilization of ferritin as a source of iron for the ferrochelatase reaction has been studied in isolated rat liver mitochondria. 1. It was found that isolated rat liver mitochondria utilized ferritin as a source of iron for the ferrochelatase reaction in the presence of succinate plus FMN (or FAD). 2. Under optimal experimental conditions, i.e., approx. 50 micromol/1 FMN, 37 degrees C, pH 7.4 and 0.5 mmol/l Fe(III) (as ferritin iron), the release process, as shown by the formation of deuteroheme, amounted to approx. 0.5 nmol iron/min per mg protein. 3. The release process could not be elicited by ultrasonically treated mitochondria, lysosomes, microsomes or cytosol, i.e., the release of iron from ferritin was due to mitochondria and was a function of the in situ orientation of the mitochondrial inner membrane. 4. The release of iron from ferritin by the mitochrondria might be of relevance not only for the in situ synthesis of heme in the hepatocyte, but also with respect to the mechanism(s) by means of which iron is mobilized for transport to the erythroid tissue.     

Bovine ferrochelatase. Kinetic analysis of inhibition by N-methylprotoporphyrin, manganese, and heme

The terminal enzyme of the heme biosynthetic pathway, ferrochelatase (protoheme ferrolyase EC 4.99.1.1), has been purified to apparent homogeneity from bovine liver mitochondria using a scheme similar to that reported by Taketani and Tokunaga (Taketani, S. and Tokunaga, R. (1981) J. Biol. Chem. 256, 12748-12753) for purification of the enzyme from rat liver. The final yield was 49% with a 2000-fold purification. Ferrochelatase has an apparent molecular weight of approximately 40,000 by both sodium dodecyl sulfate-polyacrylamide gel electrophoresis and column chromatography on Sepharose CL-6B in the presence of 0.5% sodium cholate. The purified enzyme was only slightly stimulated by added lipid and was inhibited by Mn2+, Pb2+, and Hg2+. Bovine ferrochelatase utilized proto-, meso-, and deuteroporphyrin, but not disubstituted porphyrins (2,4-disulfonic and 2,4-bisglycol deuteroporphyrin). N-Methylprotoporphyrin, a toxic by-product of the metabolism of some drugs, was found to inhibit ferrochelatase in a competitive fashion with respect to porphyrin with a Ki of 7 nM and uncompetitive with respect to iron. Manganese inhibits ferrochelatase competitively with respect to iron (Ki = 15 microM) and noncompetitively with respect to the porphyrin substrate. Heme, one of the products, is a noncompetitive inhibitor with respect to iron. These findings lead to a sequential Bi Bi kinetic model for ferrochelatase with iron binding occurring prior to porphyrin binding and heme being released prior to the release of two protons.     

Characterization of heme-regulated eIF2alpha kinase: roles of the N-terminal domain in the oligomeric state, heme binding, catalysis, and inhibition

Heme-regulated eIF2alpha kinase [heme-regulated inhibitor (HRI)] plays a critical role in the regulation of protein synthesis by heme iron. The kinase active site is located in the C-terminal domain, whereas the N-terminal domain is suggested to regulate catalysis in response to heme binding. Here, we found that the rate of dissociation for Fe(III)-protoporphyrin IX was much higher for full-length HRI (1.5 x 10(-)(3) s(-)(1)) than for myoglobin (8.4 x 10(-)(7) s(-)(1)) or the alpha-subunit of hemoglobin (7.1 x 10(-)(6) s(-)(1)), demonstrating the heme-sensing character of HRI. Because the role of the N-terminal domain in the structure and catalysis of HRI has not been clear, we generated N-terminal truncated mutants of HRI and examined their oligomeric state, heme binding, axial ligands, substrate interactions, and inhibition by heme derivatives. Multiangle light scattering indicated that the full-length enzyme is a hexamer, whereas truncated mutants (truncations of residues 1-127 and 1-145) are mainly trimers. In addition, we found that one molecule of heme is bound to the full-length and truncated mutant proteins. Optical absorption and electron spin resonance spectra suggested that Cys and water/OH(-) are the heme axial ligands in the N-terminal domain-truncated mutant complex. We also found that HRI has a moderate affinity for heme, allowing it to sense the heme concentration in the cell. Study of the kinetics showed that the HRI kinase reaction follows classical Michaelis-Menten kinetics with respect to ATP but sigmoidal kinetics and positive cooperativity between subunits with respect to the protein substrate (eIF2alpha). Removal of the N-terminal domain decreased this cooperativity between subunits and affected the other kinetic parameters including inhibition by Fe(III)-protoporphyrin IX, Fe(II)-protoporphyrin IX, and protoporphyrin IX. Finally, we found that HRI is inhibited by bilirubin at physiological/pathological levels (IC(50) = 20 microM). The roles of the N-terminal domain and the binding of heme in the structural and functional properties of HRI are discussed.     

Nitric oxide interaction with insect nitrophorins and thoughts on the electron configuration of the {FeNO}6 complex

The nitrophorins are NO-carrying heme proteins that are found in the saliva of two species of blood-sucking insects, the kissing bug (Rhodnius prolixus) and the bedbug (Cimex lectularius). In both insects the NO is bound to the ferric form of the protein, which gives rise to Kds in the micromolar to nanomolar range, and thus upon injection of the saliva into the tissues of the victim the NO can dissociate to cause vasodilation and inhibition of platelet aggregation. The structures of the proteins from each of these insects are unique, and each has a large component of beta-sheet structure, which is unusual for heme proteins. While the Rhodnius nitrophorins increase the effectiveness of their NO-heme proteins by also binding histamine, secreted by the victim in response to the bite, to the heme, the Cimex nitrophorin does not bind histamine but rather binds two molecules of NO reversibly, one to the heme and the other to the cysteine thiolate which serves as the heme ligand in the absence of NO. This requires homolytic cleavage of the Fe-S-Cys bond, which produces an EPR-active Fe(II)-NO complex having the {FeNO}7 electron configuration. For the Rhodnius nitrophorins, the heme of the {FeNO}6 stable NO complex could have the limiting electron configurations Fe(III)-NO+ or Fe(II)-NO+. While vibrational spectroscopy suggests the latter and Mossbauer spectroscopy cannot differentiate between a purely diamagnetic Fe(II) center and a strongly antiferromagnetically coupled Fe(III)-NO* center, the strong ruffling of the heme (with alternate meso-carbons shifted significantly above and below the mean plane of the porphyrin, and concomitant shifts of the beta-pyrrole carbons above and below the mean plane of the porphyrin ring, to produce a very nonplanar porphyrin macrocycle) may suggest at least an important contribution of the latter. The strong ruffling would help to stabilize the (dxz, dyz)4(dxy)1 electron configuration of low-spin Fe(III) (but not low-spin Fe(II)), and the dxy orbital does not have correct symmetry for overlap with the half-filled pi* orbital of NO. This Fe(III)-NO* electron configuration would facilitate reversible dissociation of NO.     

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.     

Biophysical investigation of the ironome of human jurkat cells and mitochondria

The speciation of iron in intact human Jurkat leukemic cells and their isolated mitochondria was assessed using biophysical methods. Large-scale cultures were grown in medium enriched with (57)Fe citrate. Mitochondria were isolated anaerobically to prevent oxidation of iron centers. 5 K M?ssbauer spectra of cells were dominated by a sextet due to ferritin. They also exhibited an intense central quadrupole doublet due to S = 0 [Fe(4)S(4)](2+) clusters and low-spin (LS) Fe(II) heme centers. Spectra of isolated mitochondria were largely devoid of ferritin but contained the central doublet and features arising from what appear to be Fe(III) oxyhydroxide (phosphate) nanoparticles. Spectra from both cells and mitochondria contained a low-intensity doublet from non-heme high-spin (NHHS) Fe(II) species. A portion of these species may constitute the "labile iron pool" (LIP) proposed in cellular Fe trafficking. Such species might engage in Fenton chemistry to generate reactive oxygen species. Electron paramagnetic resonance spectra of cells and mitochondria exhibited signals from reduced Fe/S clusters, and HS Fe(III) heme and non-heme species. The basal heme redox state of mitochondria within cells was reduced; this redox poise was unaltered during the anaerobic isolation of the organelle. Contributions from heme a, b, and c centers were quantified using electronic absorption spectroscopy. Metal concentrations in cells and mitochondria were measured using inductively coupled plasma mass spectrometry. Results were collectively assessed to estimate the concentrations of various Fe-containing species in mitochondria and whole cells - the first "ironome" profile of a human cell.     

Tetrapyrrole utilization by Bacteroids ruminocola.

Reduced versus oxidized difference spectra of whole cells and pyridine hemochromogens of heme-requiring isolates of Bacteroides ruminicola are altered when deuteroporphyrin or mesoporphyrin replaces protoheme as a growth factor. During growth in the presence of either deuteroporphyrin or mesoporphyrin, whole cells exhibit peaks at 545 t547, 515 to 518, and 412 to 413 nm. Pyridine hemochromogen spectra confirm the presence of meso -or deuteroheme in cells grown in the presence of meso- or deuteroporphyrin. No evidence was found for the conversion of either meso- or deuteroporphyrin to protoheme. Cells grown in the presence of the manganese of magnesium chelates of protoheme form iron-containing hemes. Neither spontaneous decomposition of noniron metalloporphyrin chelates nor spontaneous formation of hemes from Fe2+ and metal-free porphyrins was detected. Protoheme-synthesizing isolates of B. ruminicola fail to use preformed metal-free porphyrins, but form both protoheme- and deuteroheme-containing cytochromes when grown in the presence of manganese deuteroheme. Versatility in tetrapyrrole utilization by B. ruminicola appears to reflect the ability of the organism to mediate the removal of nonferrous ions and to insert Fe2+ into the tetrapyrrole nucleus. The orgamism also forms functional b-type cytochromes with prosthetic groups other than protoheme.     

Gallium(III), cobalt(III) and copper(II) protoporphyrin IX exhibit antimicrobial activity against Porphyromonas gingivalis by reducing planktonic and biofilm growth and invasion of host epithelial cells

Porphyromonas gingivalis acquires heme for growth, and initiation and progression of periodontal diseases. One of its heme acquisition systems consists of the HmuR and HmuY proteins. This study analyzed the antimicrobial activity of non-iron metalloporphyrins against P. gingivalis during planktonic growth, biofilm formation, epithelial cell adhesion and invasion, and employed hmuY, hmuR and hmuY-hmuR mutants to assess the involvement of HmuY and HmuR proteins in the acquisition of metalloporphyrins. Iron(III) mesoporphyrin IX (mesoheme) and iron(III) deuteroporphyrin IX (deuteroheme) supported planktonic growth of P. gingivalis cells, biofilm accumulation, as well as survival, adhesion and invasion of HeLa cells in a way analogous to protoheme. In contrast, cobalt(III), gallium(III) and copper(II) protoporphyrin IX exhibited antimicrobial activity against P. gingivalis, and thus represent potentially useful antibacterial compounds with which to target P. gingivalis. P. gingivalis hmuY, hmuR and hmuY-hmuR mutants showed decreased growth and infection of epithelial cells in the presence of all metalloporphyrins examined. In conclusion, the HmuY protein may not be directly involved in transport of free metalloporphyrins into the bacterial cell, but it may also play a protective role against metalloporphyrin toxicity by binding an excess of these compounds.     

Air-stable,heme-like water-soluble iron(II) porphyrin: in situ preparation and characterization

Preparation of the water-soluble, kinetically labile, high-spin iron(II) tetrakis(4-sulfonatophenyl)porphyrin, Fe(II)TPPS⁴⁻, has been realized in neutral or weakly acidic solutions containing acetate buffer. The buffer played a double role in these systems: it was used for both adjusting pH and, via formation of an acetato complex, trapping trace amounts of iron(III) ions, which would convert the iron(II) porphyrins to the corresponding iron(III) species. Fe(II)TPPS⁴⁻ proved to be stable in these solutions even after saturation with air or oxygen. In the absence of acetate ions, however, iron(II) ions play a catalytic role in the formation of iron(III) porphyrins. While the kinetically inert iron(III) porphyrin, Fe(III)TPPS³⁻, is a regular one with no emission and photoredox properties, the corresponding iron(II) porphyrin displays photoinduced features which are typical of sitting-atop complexes (redshifted Soret absorption and blueshifted emission and Q absorption bands, photoinduced porphyrin ligand-to-metal charge transfer, LMCT, reaction). In the photolysis of Fe(II)TPPS⁴⁻ the LMCT process is followed by detachment of the reduced metal center and an irreversible ring-opening of the porphyrin ligand, resulting in the degradation of the complex. Possible oxygen-binding ability of Fe(II)TPPS⁴⁻ (as a heme model) has been studied as well. Density functional theory calculations revealed that in solutions with high acetate concentration there is very little chance for iron(II) porpyrin to bind and release O₂, deviating from heme in a hydrophobic microenvironment in hemoglobin. In the presence of an iron(III)-trapping additive that is much less strongly coordinated to the iron(II) center than the acetate ion, Fe(II)TPPS⁴⁻ may function as a heme model.     

Gangliosides mediate association of tetanus toxin with neural cells in culture

The effects of human serum albumin (HSA) on the rate of dithionite reduction of iron(III)deuteroporphyrin (iron(III)Dp) have been investigated in order to further characterize the porphyrin binding site and the changes manifested in this site under various conditions. These studies were performed under pseudo-first-order conditions, and in the presence of carbon monoxide as a "trapping agent" for the reduced iron(II)porphyrin. The rate of reduction of the free iron(III)Dp in phosphate buffer at pH 7.4 follows second-order kinetics with a rate constant (4.2 X 10(9) M-1 s-1) suggestive of a diffusion-controlled process. A six-orders of magnitude decrease in the rate of reduction was observed with iron(III)Dp was complexed with HSA. This result is consistent with HSA-bound porphyrin being less accessible to the aqueous environment. Additional studies demonstrated that both pH and anions induce various alterations in the complex that are reflected in the rate of reduction of iron(III)porphyrin.     

Effect of porphyrin ring ligands on the affinity of heme iron to axial ligands]

To clarify the influence of protein surrounding on the heme reactivity in heme proteins the effect of interaction between a porphyrin ring and pi-acceptor molecule, 1,2,4-trimethyl-pyridinium (TMP), on the affinity of deuteroheme to axial ligands (imidazole and cyanide) has been studied as a model system. It is shown that TMP induces the fourfold decrease in equilibrium constant of imidazole to deuteroheme. From the analysis of the two stages for cyanide binding it is concluded that TMP decreases the binding constant of the first cyanide by 40 times and does not apparently influence the second ligand binding. The effect of TMP on the reactivity of deuteroheme to axial ligands is interpreted as a result of a decrease in the electron density on the iron orbitals which is due to the altered pi-eleectron density in the porphyrin pi-system through the donor-acceptor interaction with TMP molecules. The possible significance of the contacts between the porphyrin and neighboring amino acid residues in determining heme affinity to axial ligands is discussed.     

The identification and biosynthesis of siderochromes formed by Micrococcus denitrificans.

1. Micrococcus denitrificans excretes three catechol-containing compounds, which can bind iron, when grown aerobically and anaerobically in media deficient in iron, and anaerobically in medium with a high concentration of Ca2+. 2. One of these compounds was identified as 2,3-dihydroxybenzoic acid (compound I), and the other two were tentatively identified as N1N8-bis-(2,3-dihydroxybenzoyl)spermidine (compound II) and 2-hydroxybenzoyl-N-L-threonyl-N4[N1N8-bis-(2,3-dihydroxybenzoyl)]spermidine (compound III). 3. The equimolar ferric complex of compound III was prepared; compound III also forms complexes with Al3+, Cr3+ and Co2+ ions. 4. Cell-free extracts from iron-deficient organisms catalyse the formation of compound II from 2,3-dihydroxybenzoic acid and spermidine, and of compound III from compound II, L-threonine and 2-hydroxybenzoic acid; both reactions require ATP and dithiothreitol, and Mg2+ stimulates activity. The enzyme system catalysing the formation of compound II has optimum activity at pH 8.8 Fe2+ (35muM), Fe3+ (35muM) and Al3+ (65muM) inhibit the reaction by 50 percent. The enzyme system forming compound III has optimum activity at pH 8.6. Fe2+ (110 muM), Fe3+ (110 muM) and Al3+ (135 muM) inhibit the reaction by 50 percent. 5. At least two proteins are required for the formation of compound II, and another two proteins for its conversion into compound III. 6. The changes in the activities of these two systems were followed after cultures became deficient in iron. 7. Ferrous 1,10-phenanthroline is formed when a cell-free extract from iron-deficient cells is incubated with the ferric complex of compound III, succinate, NADH and 1,10-phenanthroline under N2.