The ubiquitous mitochondrial protein unfoldase CLPX regulates erythroid heme synthesis by control of iron utilization and heme synthesis enzyme activation and turnover

Heme plays a critical role in catalyzing life-essential redox reactions in all cells, and its synthesis must be tightly balanced with cellular requirements. Heme synthesis in eukaryotes is tightly regulated by the mitochondrial AAA+ unfoldase CLPX (caseinolytic mitochondrial matrix peptidase chaperone subunit X), which promotes heme synthesis by activation of δ-aminolevulinate synthase (ALAS/Hem1) in yeast and regulates turnover of ALAS1 in human cells. However, the specific mechanisms by which CLPX regulates heme synthesis are unclear. In this study, we interrogated the mechanisms by which CLPX regulates heme synthesis in erythroid cells. Quantitation of enzyme activity and protein degradation showed that ALAS2 stability and activity were both increased in the absence of CLPX, suggesting that CLPX primarily regulates ALAS2 by control of its turnover, rather than its activation. However, we also showed that CLPX is required for PPOX (protoporphyrinogen IX oxidase) activity and maintenance of FECH (ferrochelatase) levels, which are the terminal enzymes in heme synthesis, likely accounting for the heme deficiency and porphyrin accumulation observed in Clpx^−/− cells. Lastly, CLPX is required for iron utilization for hemoglobin synthesis during erythroid differentiation. Collectively, our data show that the role of CLPX in yeast ALAS/Hem1 activation is not conserved in vertebrates as vertebrates rely on CLPX to regulate ALAS turnover as well as PPOX and FECH activity. Our studies reveal that CLPX mutations may cause anemia and porphyria via dysregulation of ALAS, FECH, and PPOX activities, as well as of iron metabolism.     

Probing protein-cofactor interactions in the terminal oxidases by second derivative spectroscopy: study of bacterial enzymes with cofactor substitutions and heme A model compounds.

Second derivative absorption spectra are reported for the aa3-cytochrome c oxidase from bovine cardiac mitochondria, the aa3-600 ubiquinol oxidase from Bacillus subtilis, the ba3-cytochrome c oxidase from Thermus thermophilis, and the aco-cytochrome c oxidase from Bacillus YN-2000. Together these enzymes provide a range of cofactor combinations that allow us to unequivocally identify the origin of the 450-nm absorption band of the terminal oxidases as the 6-coordinate low-spin heme, cytochrome a. The spectrum of the aco-cytochrome c oxidase further establishes that the split Soret band of cytochrome a, with features at 443 and 450 nm, is common to all forms of the enzyme containing ferrocytochrome a and does not depend on ligand occupancy at the other heme cofactor as previously suggested. To test the universality of this Soret band splitting for 6-coordinate low-spin heme A systems, we have reconstituted purified heme A with the apo forms of the heme binding proteins, hemopexin, histidine-proline-rich glycoprotein and the H64V/V68H double mutant of human myoglobin. All 3 proteins bound the heme A as a (bis)histidine complex, as judged by optical and resonance Raman spectroscopy. In the ferroheme A forms, none of these proteins displayed evidence of Soret band splitting. Heme A-(bis)imidazole in aqueous detergent solution likewise failed to display Soret band splitting. When the cyanide-inhibited mixed-valence form of the bovine enzyme was partially denatured by chemical or thermal means, the split Soret transition of cytochrome a collapsed into a single band at 443 nm.(ABSTRACT TRUNCATED AT 250 WORDS)     

The role of heme and iron-sulfur clusters in mitochondrial biogenesis, maintenance, and decay with age.

Mitochondria decay with age from oxidative damage and loss of protective mechanisms. Resistance, repair, and replacement mechanisms are essential for mitochondrial preservation and maintenance. Iron plays an essential role in the maintenance of mitochondria, through its two major functional forms: heme and iron-sulfur clusters. Both iron-based cofactors are formed and utilized in the mitochondria and then distributed throughout the cell. This is an important function of mitochondria that is not directly related to the production of ATP. Heme and iron-sulfur clusters are important for the normal assembly and for the optimal activity of the electron transfer complexes. Loss of mitochondrial cytochrome c oxidase (complex IV), integrity of mtDNA, and function can result from abnormal homeostasis of iron. We review the physiological role of iron-sulfur clusters and heme in the integrity of the mitochondria and the generation of oxidants.     

A mechanism of oxygen sensing in yeast. Multiple oxygen-responsive steps in the heme biosynthetic pathway affect Hap1 activity

Heme plays central roles in oxygen sensing and utilization in many living organisms. In yeast, heme mediates the effect of oxygen on the expression of many genes involved in using or detoxifying oxygen. However, a direct link between intracellular heme level and oxygen concentration has not been vigorously established. In this report, we have examined the relationships among oxygen levels, heme levels, Hap1 activity, and HAP1 expression. We found that Hap1 activity is controlled in vivo by heme and not by its precursors and that heme activates Hap1 even in anoxic cells. We also found that Hap1 activity exhibits the same oxygen dose-response curves as Hap1-dependent aerobic genes and that these dose-response curves have a sharp break at approximately 1 microM O2. The results show that the intracellular signaling heme level, reflected as Hap1 activity, is closely correlated with oxygen concentration. Furthermore, we found that bypass of all heme synthetic steps but ferrochelatase by deuteroporphyrin IX does not circumvent the need for oxygen in Hap1 full activation by heme, suggesting that the last step of heme synthesis, catalyzed by ferrochelatase, is also subjected to oxygen control. Our results show that multiple heme synthetic steps can sense oxygen concentration and provide significant insights into the mechanism of oxygen sensing in yeast.     

Metabolism of pentacarboxylate porphyrinogens by highly purified human coproporphyrinogen oxidase: further evidence for the existence of an abnormal pathway for heme biosynthesis

An abnormal series of porphyrin tetracarboxylic acids known as the isocoproporphyrins, are commonly excreted by patients suffering from the disease porphyria cutanea tarda (PCT). These porphyrins appear to arise by bacterial degradation of dehydroisocoproporphyrinogen that is generated by the premature metabolism of the normal pentacarboxylate intermediate (5dab) by coproporphyrinogen oxidase (copro'gen oxidase). This porphyrinogen can be further metabolized by uroporphyrinogen decarboxylase to give harderoporphyrinogen, one of the usual intermediates in heme biosynthesis. Therefore, it is possible that some of the heme formed under abnormal conditions may originate from the 'isocopro-type' porphyrinogen intermediate. In order to investigate the feasibility of alternative pathways for heme biosynthesis, the four type III pentacarboxylate isomeric porphyrinogens were incubated with purified, cloned human copro'gen oxidase at 37 degrees C with various substrate concentrations under initial velocity conditions. Of the four isomers, only 5dab was a substrate for copro'gen oxidase and this gave dehydroisocoproporphyrin. The structure of the related porphyrin tetramethyl ester was confirmed by proton NMR spectroscopy and mass spectrometry. The K(m) value for proto'gen-IX formation from copro'gen, an indicator of molecular recognition, was similar to the K(m) value for monovinyl product formation with 5dab, although copro'gen-III has an approximately twofold higher K(cat) value. Although 5dab is a slightly poorer substrate than copro'gen-III, these results support the hypothesis that an abnormal route for heme biosynthesis is possible in humans suffering from PCT or related syndromes such as hexachlorobenzene poisoning.     

Import of cytochrome c heme lyase into mitochondria: a novel pathway into the intermembrane space.

Cytochrome c heme lyase (CCHL) catalyses the covalent attachment of the heme group to apocytochrome c during its import into mitochondria. The enzyme is membrane-associated and is located within the intermembrane space. The precursor of CCHL synthesized in vitro was efficiently translocated into isolated mitochondria from Neurospora crassa. The imported CCHL, like the native protein, was correctly localized to the intermembrane space, where it was membrane-bound. As with the majority of mitochondrial precursor proteins, CCHL uses the MOM19-GIP receptor complex in the outer membrane for import. In contrast to proteins taking the general import route, CCHL was imported independently of both ATP-hydrolysis and an electrochemical potential as external energy sources. CCHL which lacks a cleavable signal sequence apparently does not traverse the inner membrane to reach the intermembrane space; rather, it translocates through the outer membrane only. Thus, CCHL represents an example of a novel, 'non-conservative' import pathway into the intermembrane space, thereby also showing that the import apparatus in the outer membrane acts separately from the import machinery in the inner membrane.     

Replacement of a terminal cytochrome c oxidase by ubiquinol oxidase during the evolution of acetic acid bacteria

The bacterial aerobic respiratory chain has a terminal oxidase of the heme-copper oxidase superfamily, comprised of cytochrome c oxidase (COX) and ubiquinol oxidase (UOX); UOX evolved from COX. Acetobacter pasteurianus, an α-Proteobacterial acetic acid bacterium (AAB), produces UOX but not COX, although it has a partial COX gene cluster, ctaBD and ctaA, in addition to the UOX operon cyaBACD. We expressed ctaB and ctaA genes of A. pasteurianus in Escherichia coli and demonstrated their function as heme O and heme A synthases. We also found that the absence of ctaD function is likely due to accumulated mutations. These COX genes are closely related to other α-Proteobacterial COX proteins. However, the UOX operons of AAB are closely related to those of the β/γ-Proteobacteria (γ-type UOX), distinct from the α/β-Proteobacterial proteins (α-type UOX), but different from the other γ-type UOX proteins by the absence of the cyoE heme O synthase. Thus, we suggest that A. pasteurianus has a functional γ-type UOX but has lost the COX genes, with the exception of ctaB and ctaA, which supply the heme O and A moieties for UOX. Our results suggest that, in AAB, COX was replaced by β/γ-Proteobacterial UOX via horizontal gene transfer, while the COX genes, except for the heme O/A synthase genes, were lost.     

The Content of Alternative Oxidase of Euglena Mitochondria is Increased by Growth in the Presence of Cyanide and is not Cytochrome o.

ABSTRACT A study of the effect of respiratory inhibitors on O₂ uptake of Euglena gracilis mitochondria, isolated from cells grown in the presence of cyanide or with ethanol as carbon source, was undertaken. The contents of cytochrome c oxidase and alternative oxidase were also determined. Inhibition of respiration by antimycin and cyanide was only partial and it was dependent on the oxidizable substrate used. Succinate oxidation was the most sensitive to cyanide whereas lactate oxidation was the most resistant. Cell growth in the presence of cyanide or with ethanol as carbon source brought about an enhanced content of alternative oxidase without a concomitant increase in cytochrome aa₃ content. However, a correlation between cyanide-resistant respiration and alternative oxidase content was not found. Analysis of heme types in mitochondrial membranes revealed the absence of heme O. The data suggest the presence of an inducible alternative oxidase in Euglena mitochondria which has high resistance to cyanide and contains heme B. A close relationship between Euglena alternative oxidase and bacterial quinol oxidases containing B-type heme is proposed.     

Microassay of heme oxygenase by high-performance liquid chromatography: Application to assay of needle biopsies of human liver

We developed a microassay for heme oxygenase, in which bilirubin (BR) production was measured by HPLC, and compared it to previously reported spectrophotometric methods. The microassay required as little as 5 mg wet human, rat, or chick embryo liver. Using the HPLC assay, values for heme oxygenase activity in extracts (10,000 g supernatant) of normal human liver obtained by needle biopsies were 44 +/- 7 (pmol BR.min-1.mg protein-1). Spectrophotometric assays of homogenates of human liver resulted in low values for heme oxygenase, due to unknown sources of interference. Comparative values of microsomal heme oxygenase activity were 294 +/- 25, 95 +/- 3, and 87 +/- 9 pmol BR.min-1.mg protein-1 for chick, rat, and human livers, respectively.     

Variations of ganglioside biosynthetic pathways in the phenotype conversion from myofibroblasts to lipocytes in murine hepatic stellate cell line

GRX cell line represents hepatic stellate cell and can be transformed from an actively proliferation myofibroblast phenotype into a quiescent fat-storing lipocyte phenotype. Both express the same gangliosides (GM3, GM2, GM1 and GD1a), which are resolved as doublets on HPTLC. Upper/lower band ratio is increased in lipocyte-like cells and the upper band is composed by ceramides with long-chain fatty acids. This study evaluated the contribution of de novo synthesis, sphingosine and Golgi recycling pathways on ganglioside biosynthesis, in both phenotypes. Cells were preincubated with 5 mM β-chloroalanine (SPT: serine palmitoyltransferase inhibitor) or with 25 μM fumonisin B1 (ceramide synthase inhibitor) and then radiolabeled with [U-¹⁴C]galactose in the continued presence of inhibitors. Gangliosides were extracted, purified and analyzed by HPTLC. In myofibroblast-like cells, simple gangliosides use the de novo pathway while complex gangliosides are mainly synthesized by recycling pathways. In lipocyte-like cells, de novo pathway has a lesser contribution and this is in agreement with the lower activity of the committed enzyme of sphingolipid synthesis (SPT) detected in this phenotype. SPT mRNA has an identical expression in both phenotypes. It was also observed that gangliosides doublets from myofibroblast-like cells have the same distribution between triton soluble and insoluble fractions (upper band > lower band) while the gangliosides doublets from lipocyte-like cells show an inversion in the insoluble fraction (lower band > upper band) in comparison to soluble fraction. These results indicate that myofibroblast- and lipocyte-like cells have important differences between the glycosphingolipid biosynthetic pathways, which could contribute with the respective glycosphingolipid-enriched membrane microdomain’s composition.     

Involvement of the alternative oxidase in respiration of Yarrowia lipolytica mitochondria is controlled by the activity of the cytochrome pathway

The degree of involvement of cyanide-resistant alternative oxidase in the respiration of Yarrowia lipolytica mitochondria was evaluated by comparing the rate of oxygen consumption in the presence of cyanide, which shows the activity of the cyanide-resistant alternative oxidase, and the oxidation rate of cytochrome c by ferricyanide, which shows the activity of the main cytochrome pathway. The oxidation of succinate by mitochondria in the presence of ferricyanide and cyanide was associated with oxygen consumption due to the functioning of the alternative oxidase. The subsequent addition of ADP or FCCP (an uncoupler of oxidative phosphorylation) completely inhibited oxygen consumption by the mitochondria. Under these conditions, the inhibition of the alternative oxidase by benzohydroxamic acid (BHA) failed to affect the reduction of ferricyanide at the level of cytochrome c. BHA did not influence the rate of ferricyanide reduction by the cytochrome pathway occurring in controlled state 4, nor could it change the phosphorylation quotient ATP/O upon the oxidation of various substrates. These data indicate that the alternative system is unable to compete with the cytochrome respiratory chain for electrons. The alternative oxidase only transfers the electrons that are superfluous for the cytochrome respiratory chain.     

In situ assay of the intramitochondrial enzymes: use of alamethicin for permeabilization of mitochondria

The channel-forming antibiotic alamethicin was used to permeabilize mitochondrial membranes for the low molecular mass hydrophilic substrates NADH and ATP. Alamethicin-treated mitochondria show high rotenone-sensitive NADH oxidase, NADH-quinone reductase, and oligomycin-sensitive and carboxyatractylate-insensitive ATPase activities. Alamethicin does not affect Complex I and ATPase activities in inside-out submitochondrial particles. Permeabilized mitochondria quantitatively retain their aconitase and iso-citrate dehydrogenase activities. Electron microscopy of alamethicin-treated mitochondria reveals no disruption of their outer and inner membranes. From the results obtained it is recommended, that alamethicin be used for the in situ catalytic assay of intramitochondrially located enzymes.     

Feedfoward inhibition in biosynthetic pathways: inhibition of the aminoacyl-tRNA synthetase by intermediates of the pathway.

The stability of an amino acid biosynthetic pathway controlled by end-product inhibition is significantly improved if, in addition, the corresponding aminoacyl-tRNA synthetase is inhibited by an intermediate in the pathway. The more proximal the feedforward modifier is to the initial substrate, the more stable is the system. The temporal responsiveness of a system having both feedback and feedforward inhibition also is improved by having the feedforward modifier located at the beginning of the pathway. According to all other criteria that have been used previously to determine the functional effectiveness of biosynthetic pathways, the behavior of such a system essentially is unaffected by the position of the feedforward modifier in the pathway.     

Leishmania spp.: delta-aminolevulinate-inducible neogenesis of porphyria by genetic complementation of incomplete heme biosynthesis pathway

To further develop the Leishmania model for porphyria based on their deficiencies in heme biosynthesis, three Old World species were doubly transfected as before for Leishmania amazonensis with cDNAs, encoding the 2nd and 3rd enzymes in the pathway. Expression of the transgenes was verified immunologically at the protein level and functionally by uroporphyrin neogenesis that occurs only after exposure of the double-transfectants to delta-aminolevulinate. All species examined were equally deficient in heme biosynthesis, as indicated by the accumulation of uroporphyrin as the sole porphyrin and the production of coproporphyrin upon further transfection of one representative species with the downstream gene. The results obtained thus demonstrate that at least the first five enzymes for heme biosynthesis are absent in all species examined, rendering their transfectants inducible with aminolevulinate to accumulate porphyrins and thus useful as cellular models for human porphyrias.     

Mechanisms of neuroprotection by hemopexin: modeling the control of heme and iron homeostasis in brain neurons in inflammatory states

Hemopexin provides neuroprotection in mouse models of stroke and intracerebral hemorrhage and protects neurons in vitro against heme or reactive oxygen species (ROS) toxicity via heme oxygenase‐1 (HO1) activity. To model human brain neurons experiencing hemorrhages and inflammation, we used human neuroblastoma cells, heme–hemopexin complexes, and physiologically relevant ROS, for example, H₂O₂ and HOCl, to provide novel insights into the underlying mechanism whereby hemopexin safely maintains heme and iron homeostasis. Human amyloid precursor protein (hAPP), needed for iron export from neurons, is induced ~twofold after heme–hemopexin endocytosis by iron from heme catabolism via the iron‐regulatory element of hAPP mRNA. Heme–hemopexin is relatively resistant to damage by ROS and retains its ability to induce the cytoprotective HO1 after exposure to tert‐butylhydroperoxide, although induction is impaired, but not eliminated, by exposure to high concentrations of H₂O₂ in vitro. Apo‐hemopexin, which predominates in non‐hemolytic states, resists damage by H₂O₂ and HOCl, except for the highest concentrations likely in vivo. Heme–albumin and albumin are preferential targets for ROS; thus, albumin protects hemopexin in biological fluids like CSF and plasma where it is abundant. These observations provide strong evidence that hemopexin will be neuroprotective after traumatic brain injury, with heme release in the CNS, and during the ensuing inflammation. Hemopexin sequesters heme, thus preventing unregulated heme uptake that leads to toxicity; it safely delivers heme to neuronal cells; and it activates the induction of proteins including HO1 and hAPP that keep heme and iron at safe levels in neurons.     

The oxygenase-peroxidase theory of Bach and Chodat and its modern equivalents: Change and permanence in scientific thinking as shown by our understanding of the roles of water,peroxide, and oxygen in the functioning of redox enzymes

Alexander Bach was both revolutionary politician and biochemist. His earliest significant publication, “Tsargolod” (“The Tsar of Hunger”), introduced Marxist thought to Russian workers. In exile for 30 years, he moved to study the dialectic of the oxidases. When his theory of oxidases as combinations of oxygenases and peroxidases was developed (circa 1900) the enzyme concept was not fully formulated, and the enzyme/substrate distinction not yet made. Peroxides however were then and remain now significant intermediates, when either free or bound, in oxidase catalyses. The aerobic dehydrogenase/peroxidase/catalase coupled systems which were studied slightly later clarified the Bach model and briefly became an oxidase paradigm. Identification of peroxidase as a metalloprotein, a key step in understanding oxidase and peroxidase mechanisms, postdated Bach’s major work. Currently we recognize catalytic organic peroxides in flavoprotein oxygenases; such organic peroxides are also involved in lipid oxidation and tryptophan radical decay. But most physiologically important peroxides are now known to be bound to transition metals (either Fe or Cu) and formed both directly and indirectly (from oxygen). The typical stable metalloprotein peroxide product is the ferryl state. When both peroxide oxidizing equivalents are retained the second equivalent is held as a protein or porphyrin radical. True metal peroxide complexes are unstable. But often water molecules mark the spot where the original peroxide decayed. The cytochrome c oxidase Fe-Cu center can react with either peroxide or oxygen to form the intermediate higher oxidation states P and F. In its resting state water molecules and hydroxyl ions can be seen marking the original location of the oxygen or peroxide molecule. Published in Russian in Biokhimiya, 2007, Vol. 72, No. 10, pp. 1278–1288.