Frataxin and mitochondrial carrier proteins, Mrs3p and Mrs4p, cooperate in providing iron for heme synthesis

Frataxin is a conserved mitochondrial protein implicated in cellular iron metabolism. Deletion of the yeast frataxin homolog (YFH1) was combined with deletions of MRS3 and MRS4, mitochondrial carrier proteins implicated in iron homeostasis. As previously reported, the Deltayfh1 mutant accumulated iron in mitochondria, whereas the triple mutant (DeltaDeltaDelta) did not. When wild-type, Deltamrs3/4, Deltayfh1, and DeltaDeltaDelta strains were incubated anaerobically, all strains were devoid of heme and protected from iron and oxygen toxicity. The cultures were then shifted to air for a short time (4-5 h) or a longer time (15 h), and the evolving mutant phenotypes were analyzed (heme-dependent growth, total heme, cytochromes, heme proteins, and iron levels). A picture emerges from these data of defective heme formation in the mutants, with a markedly more severe defect in the DeltaDeltaDelta than in the individual Deltamrs3/4 or Deltayfh1 mutants (a "synthetic" defect in the genetic sense). The defect(s) in heme formation could be traced to lack of iron. Using a real time assay of heme biosynthesis, porphyrin precursor and iron were presented to permeabilized cells, and the appearance and disappearance of fluorescent porphyrins were followed. The Mrs3/4p carriers were required for rapid iron transport into mitochondria for heme synthesis, whereas there was also evidence for an alternative slower system. A different role for Yfh1p was observed under conditions of low mitochondrial iron and aerobic growth (revealed in the DeltaDeltaDelta), acting to protect bioavailable iron within mitochondria and to facilitate its use for heme synthesis.     

Mutant Strains of Rhodopseudomonas spheroides Lacking δ-Aminolevulinate Synthase: Growth, Heme, and Bacteriochlorophyll Synthesis

Two mutant strains of Rhodopseudomonas spheroides were described which lacked delta-aminolevulinate synthase activity. They required delta-aminolevulinate for growth; they did not respond to protoporphyrin or magnesium photoporphyrin, and only poorly to hemin. Synthesis of cytochromes and heme by mutant H-4 was dependent upon delta-aminolevulinate; this strain did not form bacteriochlorophyll either with or without delta-aminolevulinate and, consequently, grew only under aerobic conditions. Mutant H-5 formed bacteriochlorophyll in response to delta-aminolevulinate and grew both anaerobically in the light and aerobically in the dark; the amount of delta-aminolevulinate needed for optimal anaerobic growth was higher than that required aerobically. Synthesis of bacteriochlorophyll and heme by suspensions of mutant H-5 incubated anaerobically in the light was dependent upon delta-aminolevulinate; bacteriochlorophyll production was completely inhibited by high aeration and by puromycin. The mutants differed in their ability to take up radioactive delta-aminolevulinate from the external environment; mutant H-5 was less active than mutant H-4 or the wild type. It was suggested that R. spheroides made only one form of delta-aminolevulinate synthase, which provided delta-aminolevulinate for bacteriochlorophyll and heme synthesis.     

Oxygen‐dependent copper toxicity: targets in the chlorophyll biosynthesis pathway identified in the copper efflux ATPase CopA deficient mutant

Characterization of a copA^? mutant in the purple photosynthetic bacterium Rubrivivax gelatinosus under low oxygen or anaerobic conditions, as well as in the human pathogen Neisseria gonorrhoeae identified HemN as a copper toxicity target enzyme in the porphyrin synthesis pathway. Heme synthesis is, however, unaffected by copper under high oxygen tension because of the aerobic coproporphyrinogen III oxidase HemF. Nevertheless, in the copA^? mutant under aerobiosis, we show that the chlorophyll biosynthesis pathway is affected by excess copper resulting in a substantial decrease of the photosystem. Analyses of pigments and enzyme activity showed that under low copper concentrations, the mutant accumulated protochlorophyllide, suggesting that the protochlorophyllide reductase activity is affected by excess copper. Increase of copper concentration led to a complete lack of chlorophyll synthesis as a result of the loss of Mg‐chelatase activity. Both enzymes are widely distributed from bacteria to plants; both are [4Fe‐4S] proteins and oxygen sensitive; our data demonstrate their in vivo susceptibility to copper in the presence of oxygen. Additionally, our study provides the understanding of molecular mechanisms that may contribute to chlorosis in plants when exposed to metals. The role of copper efflux systems and the impact of copper on heme and chlorophyll biosynthesis in phototrophs are addressed.     

The genes required for heme synthesis in Salmonella typhimurium include those encoding alternative functions for aerobic and anaerobic coproporphyrinogen oxidation.

Insertion mutagenesis has been used to isolate Salmonella typhimurium strains that are blocked in the conversion of 5-aminolevulinic acid (ALA) to heme. These mutants define the steps of the heme biosynthetic pathway after ALA. Insertions were recovered at five unlinked loci: hemB, hemCD, and hemE, which have been mapped previously in S. typhimurium, and hemG and hemH, which have been described only for Escherichia coli. No other simple hem mutants were found. However, double mutants are described that are auxotrophic for heme during aerobic growth and fail to convert coproporphyrinogen III to protoporphyrinogen IX. These mutant strains are defective in two genes, hemN and hemF. Single mutants defective only in hemN require heme for anaerobic growth on glycerol plus nitrate but not for aerobic growth on glycerol. Mutants defective only in hemF have no apparent growth defect. We suggest that these two genes encode alternative forms of coproporphyrinogen oxidase. Anaerobic heme synthesis requires hemN function, while either hemN or hemF is sufficient for aerobic heme synthesis. These phenotypes are consistent with the requirement of a well-characterized class of coproporphyrinogen oxidase for molecular oxygen.     

Mutant strains of Rhodopseudomonas spheroides which form photosynthetic pigments aerobically in the dark. Growth characteristics and enzymic activities

Mutant strains of Rhodopseudomonas spheroides have been isolated which contain 5–50 times more bacteriochlorophyll and carotenoids than the wild type when grown under highly aerobic conditions in the dark. Their pigment content is similar to the wild type when grown in the light. One of the mutants (TA-R) grew more slowly than its parent strain under aerobic conditions but formed pigments at about 60% of the rate observed under photosynthetic conditions. The other mutants grew at rates similar to the wild type under all conditions. Synthesis of bacteriochlorophyll by suspensions of the mutants began without delay upon transfer from conditions of high to low aeration. In contrast to the wild type, magnesium protoporphyrin-S-adenosylmethionine methyltransferase (EC 2.1.1.11) activity in particulate preparations from the mutants was not repressed by growth under aerobic conditions in the light or dark. Ribulose diphosphate carboxylase (EC 4.1.1.39) activity was repressed by O₂ in the mutants as in the wild type. Other enzyme activities were compared in mutant TA-R and its parent strain grown under the same conditions. NADH oxidase activity in particles from aerobically grown TA-R was about one third that found in the parent strain. However, the respiration rates of the intact cells did not differ. Light inhibited the respiration of aerobically grown TA-R, indicating that the bacteriochlorophyll formed under these conditions had photochemical activity. It is concluded that the insensitivity of the mutants to O₂ repression is due to defects in the regulatory system which controls formation of the enzymes concerned in pigment synthesis.     

Inactivation of Mg chelatase during transition from anaerobic to aerobic growth in Rhodobacter capsulatus

The facultative photosynthetic bacterium Rhodobacter capsulatus can adapt from an anaerobic photosynthetic mode of growth to aerobic heterotrophic metabolism. As this adaptation occurs, the cells must rapidly halt bacteriochlorophyll synthesis to prevent phototoxic tetrapyrroles from accumulating, while still allowing heme synthesis to continue. A likely control point is Mg chelatase, the enzyme that diverts protoporphyrin IX from heme biosynthesis toward the bacteriochlorophyll biosynthetic pathway by inserting Mg(2+) to form Mg-protoporphyrin IX. Mg chelatase is composed of three subunits that are encoded by the bchI, bchD, and bchH genes in R. capsulatus. We report that BchH is the rate-limiting component of Mg chelatase activity in cell extracts. BchH binds protoporphyrin IX, and BchH that has been expressed and purified from Escherichia coli is red in color due to the bound protoporphyrin IX. Recombinant BchH is rapidly inactivated by light in the presence of O(2), and the inactivation results in the formation of a covalent adduct between the protein and the bound protoporphyrin IX. When photosynthetically growing R. capsulatus cells are transferred to aerobic conditions, Mg chelatase is rapidly inactivated, and BchH is the component that is most rapidly inactivated in vivo when cells are exposed to aerobic conditions. The light- and O(2)-stimulated inactivation of BchH could account for the rapid inactivation of Mg chelatase in vivo and provide a mechanism for inhibiting the synthesis of bacteriochlorophyll during adaptation of photosynthetically grown cells to aerobic conditions while still allowing heme synthesis to occur for aerobic respiration.     

The Chlorite Dismutase (HemQ) from Staphylococcus aureus Has a Redox-sensitive Heme and Is Associated with the Small Colony Variant Phenotype

The chlorite dismutases (C-family proteins) are a widespread family of heme-binding proteins for which chemical and biological roles remain unclear. An association of the gene with heme biosynthesis in Gram-positive bacteria was previously demonstrated by experiments involving introduction of genes from two Gram-positive species into heme biosynthesis mutant strains of Escherichia coli, leading to the gene being renamed hemQ. To assess the gene product''s biological role more directly, a Staphylococcus aureus strain with an inactivated hemQ gene was generated and shown to be a slow growing small colony variant under aerobic but not anaerobic conditions. The small colony variant phenotype is rescued by the addition of exogenous heme despite an otherwise wild type heme biosynthetic pathway. The ΔhemQ mutant accumulates coproporphyrin specifically under aerobic conditions. Although its sequence is highly similar to functional chlorite dismutases, the HemQ protein has no steady state reactivity with chlorite, very modest reactivity with H₂O₂ or peracetic acid, and no observable transient intermediates. HemQ''s equilibrium affinity for heme is in the low micromolar range. Holo-HemQ reconstituted with heme exhibits heme lysis after <50 turnovers with peroxide and <10 turnovers with chlorite. The heme-free apoprotein aggregates or unfolds over time. IsdG-like proteins and antibiotic biosynthesis monooxygenases are close sequence and structural relatives of HemQ that use heme or porphyrin-like organic molecules as substrates. The genetic and biochemical data suggest a similar substrate role for heme or porphyrin, with possible sensor-regulator functions for the protein. HemQ heme could serve as the means by which S. aureus reversibly adopts an SCV phenotype in response to redox stress.     

Ubiquinone concentrations in Athiorhodaceae grown under various environmental conditions

1. The nature and concentration of ubiquinone in six species of Athiorhodaceae have been examined after growth under aerobic and photosynthetic conditions. 2. Increase in ubiquinone concentration during adaptive synthesis of photosynthetic pigments by Rhodopseudomonas spheroides incubated under low-aeration conditions was observed. 3. The nature of the carbon source was found to have a marked effect on ubiquinone, as well as bacteriochlorophyll, concentrations.     

Impact of aeration and heme-activated respiration on Lactococcus lactis gene expression: identification of a heme-responsive operon

Lactococcus lactis is a widely used food bacterium mainly characterized for its fermentation metabolism. However, this species undergoes a metabolic shift to respiration when heme is added to an aerobic medium. Respiration results in markedly improved biomass and survival compared to fermentation. Whole-genome microarrays were used to assess changes in L. lactis expression under aerobic and respiratory conditions compared to static growth, i.e., nonaerated. We observed the following. (i) Stress response genes were affected mainly by aerobic fermentation. This result underscores the differences between aerobic fermentation and respiration environments and confirms that respiration growth alleviates oxidative stress. (ii) Functions essential for respiratory metabolism, e.g., genes encoding cytochrome bd oxidase, menaquinone biosynthesis, and heme uptake, are similarly expressed under the three conditions. This indicates that cells are prepared for respiration once O(2) and heme become available. (iii) Expression of only 11 genes distinguishes respiration from both aerobic and static fermentation cultures. Among them, the genes comprising the putative ygfCBA operon are strongly induced by heme regardless of respiration, thus identifying the first heme-responsive operon in lactococci. We give experimental evidence that the ygfCBA genes are involved in heme homeostasis.     

Bacteriochlorophyll and Heme Synthesis in Rhodopseudomonas spheroides: Possible Role of Heme in Regulation of the Branched Biosynthetic Pathway

Synthesis of heme, measured by incorporation of iron-59, and of bacteriochlorophyll was studied with wild-type and mutant strains of Rhodopseudomonas spheroides. The wild type formed heme from glycine and succinate at one-fortieth the rate of bacteriochlorophyll under anaerobic-light conditions. Added delta-aminolevulinate stimulated heme synthesis 10-fold without increasing bacteriochlorophyll production. Heme synthesis from glycine and succinate was increased when the magnesium branch of the biosynthetic path was curtailed by mutation or by p-fluorophenylalanine or 8-azaguanine. Synthesis of bacteriochlorophyll by the wild type from glycine and succinate stopped immediately after addition of puromycin, but heme production continued for a period. Porphyrins and other precursors did not appear upon addition of puromycin alone, but simultaneous addition of o-phenanthroline resulted in the accumulation of coproporphyrin. Production of this porphyrin by a mutant strain with impaired ability to form heme was unaffected by puromycin. Heme synthesis from glycine and succinate or from delta-aminolevulinate was decreased by limitation of methionine; it is suggested that coproporphyrin accumulation from glycine and succinate under conditions of methionine deficiency results from relief of feedback inhibition of delta-aminolevulinate synthase by heme. The development of delta-aminolevulinate synthase activity in response to low aeration is prevented by addition of delta-aminolevulinate. This repressive action of the latter is abolished when its conversion to heme is impeded by mutation or by methionine deficiency. It is suggested that heme, the quantitatively minor end product of the branched biosynthetic pathway, may regulate the flow of common intermediates when utilization of protoporphyrin by the magnesium branch is diminished. This regulation may be exerted by feedback inhibition of delta-aminolevulinate synthase and also by repression of enzyme formation.     

Growth of an Escherichia coli mutant deficient in respiration

An Escherichia coli mutant deficient in genes for heme biosynthesis grew in medium of initial pH 8 containing 1% tryptone and glucose under aerobic growth conditions, and its doubling time was approximately 60 min at 37°C. The growth rate was not increased under O₂-limiting conditions. When the mutant was grown in medium of initial pH 6, growth stopped at the middle of the exponential growth phase. This could be overcome and the growth yield increased by the addition of 20 mM lysine to the growth medium. Lysine did not prevent the decrease in the medium pH as growth proceeded, making it unlikely that lysine decarboxylation stimulates growth by the alkalinization of the medium. These results indicate that respiration is not obligatory for growth under aerobic conditions, but growth without respiration at low pH requires a large amount of lysine.     

Involvement of heme biosynthesis in control of sterol uptake by Saccharomyces cerevisiae.

Wild-type Saccharomyces cerevisiae do not accumulate exogenous sterols under aerobic conditions, and a mutant allele conferring sterol auxotrophy (erg7) could be isolated only in strains with a heme deficiency. delta-Aminolevulinic acid (ALA) fed to a hem1 (ALA synthetase-) erg7 (2,3-oxidosqualene cyclase-) sterol-auxotrophic strain of S. cerevisiae inhibited sterol uptake, and growth was negatively affected when intracellular sterol was depleted. The inhibition of sterol uptake (and growth of sterol auxotrophs) by ALA was dependent on the ability to synthesize heme from ALA. A procedure was developed which allowed selection of strains which would take up exogenous sterols but had no apparent defect in heme or ergosterol biosynthesis. One of these sterol uptake control mutants possessed an allele which allowed phenotypic expression of sterol auxotrophy in a heme-competent background.     

Characterization of the Late Steps of Microbial Heme Synthesis: Conversion of Coproporphyrinogen to Protoporphyrin

Cell-free extracts of various cytochrome-containing, heterotrophic microorganisms were examined for ability to convert coproporphyrinogen to protoporphyrin. Extracts of Escherichia coli and Pseudomonas denitrificans readily accumulated large amounts of protoporphyrin when assayed under aerobic conditions. However, protoporphyrin did not accumulate under either aerobic or anaerobic conditions of assay or in the presence of various supplements in extracts of the aerobe Micrococcus lysodeikticus, the facultative anaerobe Staphylococcus aureus, or the anaerobe Vibrio succinogenes. Protoporphyrin also accumulated when extracts of E. coli and P. denitrificans were incubated aerobically with the early heme precursor, delta-amino levulinic acid (ALA). This protoporphyrin accumulation was markedly stimulated by the iron chelator, o-phenanthroline. Extracts of S. aureus and M. lysodeikticus accumulated coproporphyrin, but not protoporphyrin when incubated with ALA. The enzyme system in extracts of E. coli which converts coproporphyrinogen to protoporphyrin under aerobic conditions of assay was also partially characterized. This conversion was stimulated by the iron chelator, o-phenanthroline, the respiratory inhibitor, cyanide, and the reducing agent, thioglycolate. Dialysis of the extract did not diminish enzyme activity. Certain alternate electron acceptors and nitrite caused a marked inhibition of the conversion. These results indicate that this late step in heme synthesis, the conversion of coproporphyrinogen to protoporphyrin, can be readily demonstrated in extracts of some, but not all, cytochrome-containing bacteria and that the aerobic conversion in E. coli exhibits many characteristics similar to those demonstrated for the aerobic conversion previously studied in liver mitochondria.     

The role of high-potential iron protein and cytochrome c(8) as alternative electron donors to the reaction center of Chromatium vinosum

Under anaerobic conditions, intact cells of the purple sulfur bacterium Chromatium vinosum exhibit rapid photooxidation of the two low-potential hemes of the c-type cytochrome associated with the reaction center, after exposure to two short light flashes separated by a dark interval. Reduction of the photooxidized low-potential hemes is very slow under these conditions. On subsequent flashes, rapid photooxidation of a high-potential reaction center heme occurs and is followed by its rereduction on the millisecond time scale. Cells maintained under aerobic conditions exhibit the millisecond time scale reduction of the photooxidized high-potential heme after each flash. Cells grown autotrophically in the presence of Na(2)S and Na(2)S(2)O(3) appear to use the soluble [4Fe-4S]-containing protein, HiPIP, as the only direct electron donor to the reaction center heme under aerobic conditions. In contrast, cells grown in the presence of organic compounds, but in the absence of Na(2)S and Na(2)S(2)O(3), appear to use a soluble c-type cytochrome (most likely cytochrome c(8)) as the only electron donor to the reaction center heme under aerobic conditions. Cells grown autotrophically, in the presence of Na(2)S and Na(2)S(2)O(3), have a slightly higher ratio of HiPIP to cytochrome c(8) and a ratio of Rieske iron-sulfur protein to reaction center that is approximately one-half that of cells grown in the absence of Na(2)S and Na(2)S(2)O(3) but in the presence of organic compounds.     

Accumulation of pre-apocytochrome f in a Synechocystis sp. PCC 6803 mutant impaired in cytochrome c maturation.

Cytochrome c maturation involves heme transport and covalent attachment of heme to the apoprotein. The 5' end of the ccsB gene, which is involved in the maturation process and resembles the ccs1 gene from Chlamydomonas reinhardtii, was replaced by a chloramphenicol resistance cartridge in the cyanobacterium Synechocystis sp. PCC 6803. The resulting Delta(M1-A24) mutant lacking the first 24 ccsB codons grew only under anaerobic conditions. The mutant retained about 20% of the wild-type amount of processed cytochrome f with heme attached, apparently assembled in a functional cytochrome b(6)f complex. Moreover, the mutant accumulated unprocessed apocytochrome f in its membrane fraction. A pseudorevertant was isolated that regained the ability to grow under aerobic conditions. The locus of the second-site mutation was mapped to ccsB, and the mutation resulted in the formation of a new potential start codon in the intergenic region, between the chloramphenicol resistance marker and ccsB, in frame with the remaining part of ccsB. In this pseudorevertant the amount of holocyt f increased, whereas that of unprocessed apocytochrome f decreased. We suggest that the original deletion mutant Delta(M1-A24) expresses an N-terminally truncated version of the protein. The stable accumulation of unprocessed apocytochrome f in membranes of the Delta(M1-A24) mutant may be explained by its association with truncated and only partially functional CcsB protein resulting in protection from degradation. Our attempt to delete the first 244 codons of ccsB in Synechocystis sp. PCC 6803 was not successful, suggesting that this would lead to a lack of functional cytochrome b(6)f complex. The results suggest that the CcsB protein is an apocytochrome chaperone, which together with CcsA may constitute part of cytochrome c lyase.     

Evidence for the lack of oxygen repression of Fe−Mo protein in mutants ofAnabaena variabilis

Mutants ofAnabaena variabilis, unable to fix nitrogen under aerobic conditions, were used to determine whether nitrogenase synthesis is subject to O₂ repression, as is the case in some heterotrophic bacteria. Nitrogenase activity in the mutants was induced as heterocysts matured under microaerophilic conditions. However, addition of 5% O₂ to the assay system inhibited activity by 95%. Under aerobic conditions, nitrogenase activity in the mutants could not be detected, but an activity-independent, immunological assay showed that the Fe-Mo protein was present at levels similar to those found in wild-type and mutant strains induced microaerophilically. Reducing the O₂ tension of an aerobically induced mutant resulted in a rate of nitrogenase activity induction twice the rate under continuous microaerophilic conditions. These results indicate that O₂ does not repress Fe-Mo protein synthesis in these mutants.     

Elucidation of the heme binding site of heme-regulated eukaryotic initiation factor 2alpha kinase and the role of the regulatory motif in heme sensing by spectroscopic and catalytic studies of mutant proteins

Heme-regulated eukaryotic initiation factor 2alpha (eIF2alpha) kinase (HRI) functions in response to the heme iron concentration. At the appropriate heme iron concentrations under normal conditions, HRI function is suppressed by binding of the heme iron. Conversely, upon heme iron shortage, HRI autophosphorylates and subsequently phosphorylates the substrate, eIF2alpha, leading to the termination of protein synthesis. The molecular mechanism of heme sensing by HRI, including identification of the specific binding site, remains to be established. In the present study we demonstrate that His-119/His-120 and Cys-409 are the axial ligands for the Fe(III)-protoporphyrin IX complex (hemin) in HRI, based on spectral data on site-directed mutant proteins. Cys-409 is part of the heme-regulatory Cys-Pro motif in the kinase domain. A P410A full-length mutant protein displayed loss of heme iron affinity. Surprisingly, inhibitory effects of the heme iron on catalysis and changes in the heme dissociation rate constants in full-length His-119/His-120 and Cys-409 mutant proteins were marginally different to wild type. In contrast, heme-induced inhibition of Cys-409 mutants of the isolated kinase domain and N-terminal-truncated proteins was substantially weaker than that of the full-length enzyme. A pulldown assay disclosed heme-dependent interactions between the N-terminal and kinase domains. Accordingly, we propose that heme regulation is induced by interactions between heme and the catalytic domain in conjunction with global tertiary structural changes at the N-terminal domain that accompany heme coordination and not merely by coordination of the heme iron with amino acids on the protein surface.