Evidence for involvement of the electron transport system at a late step of anaerobic microbial heme synthesis

The penultimate step in heme biosynthesis, the oxidation of protoporphyrinogen to protoporphyrin, can be anaerobically coupled to the reduction of fumarate in extracts of anaerobically-grown Escherichia coli. This coupling is approximately 90% inhibited by 2-heptyl-4-hydroxy quinoline-N-oxide (HQNO), a known inhibitor of the electron transport chain. This observation suggests that the mechanism of the anaerobic oxidation of protoporphyrinogen in E. coli involves a coupling into the anaerobic electron transport system. In contrast, the aerobic oxidation of protoporphyrinogen, which occurs in mammalian and yeast mitochondria, is known to be linked directly to oxygen without the mediation of an electron transport system.     

Nitrate,fumarate, and oxygen as electron acceptors for a late step in microbial heme synthesis

Nitrate can serve as anaerobic electron acceptor for the oxidation of protoporphyrinogen to protoporphyrin in cell-free extracts of Escherichia coli grown anaerobically in the presence of nitrate. Two kinds of experiments indicated this: anaerobic protoporphyrin formation from protoporphyrinogen, followed spectrophotometrically, was markedly stimulated by addition of nitrate; and anaerobic protoheme formation from protoporphyrinogen, determined by extraction procedures, was markedly stimulated by addition of nitrate. In contrast, anaerobic protoheme formation from protoporphyrin was not dependent upon addition of nitrate. This was the first demonstration of the ability of nitrate to serve as electron acceptor for this late step of heme synthesis. Previous studies with mammalian and yeast mitochondria had indicated an obligatory requirement for molecular oxygen at this step.In confirmation of our previous preliminary report, fumarate was also shown to be an electron acceptor for anaerobic protoporphyrinogen oxidation in extracts of E. coli grown anaerobically on fumarate. For the first time, anaerobic protoheme formation from protoporphyrinogen, but not from protoporphyrin, was shown to be dependent upon the addition of fumarate.The importance of these findings is 2-fold. First, they establish that enzymatic protoporphyrinogen oxidation can occur in the absence of molecular oxygen, in contrast to previous observations using mammalian and yeast mitochondria. Secondly, these findings help explain the ability of some facultative and anaerobic bacteria to form very large amounts of heme compounds, such as cytochrome pigments, when grown anaerobically in the presence of nitrate or fumarate. In fact, denitrifying bacteria are known to form more cytochromes when grown anaerobically than during aerobic growth.An unexpected finding was that extracts of another bacterium, Staphylococcus epidermidis, exhibited very little ability to oxidize protoporphyrinogen to protoporphyrin as compared to E. coli extracts. This finding suggests some fundamental differences in these two organisms in this key step in heme synthesis. It is known that these two facultative organisms also differ in that E. coli synthesizes cytochrome during both aerobic and anaerobic growth, while Staphylococcus only synthesizes cytochromes when grown aerobically.     

Quinones as hydrogen carriers for a late step in anaerobic heme biosynthesis in Escherichia coli.

A late step in anaerobic heme synthesis, the oxidation of protoprophyrinogen with fumarate as electron acceptor, was studied in extracts and particles of Escherichia coli mutants deficient in quinones or cytochromes. Mutants specifically deficient in menaquinone did not couple protoporphyrinogen oxidation to fumarate reduction, whereas mutants containing menaquinone but deficient in either ubiquinone or cytochromes exhibited this activity. These findings indicate that this coupled reaction is dependent upon menaquinone as hydrogen carrier but independent of ubiquinone and cytochromes. Other characteristics of this coupled reaction were also studied. The activity was located exclusively in the membrane fraction of cell-free extracts. Coproporphyrinogen III could not replace protoporphyrinogen as substrate. Methylene blue, triphenyl tetrazolium and nitrate, but not nitrite, could replace fumarate as anaerobic hydrogen acceptor. These findings have implications for the mechanism and regulation of microbial heme and chlorophyll synthesis and for the physiology of cytochrome synthesis in anaerobic microorganisms.     

Microbial oxidation of protoporhydrinogen, an intermediate in heme and chlorphyll biosynthesis.

The oxidation of protoporphyrinogen to protoporphyrin, a late step in heme and chlorophyll synthesis, is catalyzed aerobically by a particulate fraction of Escherichia coli at a rate significantly higher than the rate of autooxidation. This activity is heat labile and is markedly inhibited by addition of respiratory substrates such as NADH. NADH is oxidized at a rate 100-fold higher than protoporphyrinogen. Particles from a cytochrome-less mutant of E. coli were markedly deficient in protoporphyrinogen oxidizing activity. Particles from a quinone-deficient mutant were also deficient. These findings suggest a possible role for the electron transport system in aerobic protoporphyrinogen oxidation. This activity was also examined in a variety of other bacteria. Particles from Streptococcus faecalis, which does not synthesize heme, were unable to oxidize protoporphyrinogen, confirming the specificity of this activity. Particles from aerobically grown Staphylococcus aureus exhibited protoporphyrinogen oxidizing activity, but particles from anaerobically grown cells had no activity above that of the nonenzymatic control. This indicates the repressible nature of this activity, and may also explain why Staphylococci synthesize cytochromes during aerobic, but not during anaerobic growth. Particles from photosynthetically grown Rhodopseudomonas spheroides, which contain both chlorophyll and heme, oxidized protoporphyrinogen at a rate no higher than the nonenzymic control. However, particles from cells grown aerobically, when bacteriochlorophyll synthesis is markedly repressed, readily exhibited protoporphyrinogen oxidizing activity. These initial findings suggest that this activity is detectable in cells primarily synthesizing heme, but not in cells primarily synthesizing bacteriochlorophyll, and could have implications both for the mechanism and regulation of the heme and bacteriochlorophyll pathways.     

The late steps of anaerobic heme biosynthesis in E. coli: role for quinones in protoporphyrinogen oxidation.

The anaerobic oxidation of protoporphyrinogen with fumarate as electron acceptor in cell-free extracts of $\text{E. coli}$ is inhibited by ultra-violet irradiation. The activity of irradiated extracts is restored by addition of menadione and the restored activity is blocked by the electron-transport inhibitor 2-heptyl-4-hydroxy quinoline-N-oxide. These observations suggest that quinones are required as electron transport carriers at this late step in the pathway of anaerobic heme biosynthesis. These findings have important implications both for the mechanism of anaerobic heme synthesis and for the physiology of cytochrome biosynthesis in anaerobic microorganisms.     

Quinones as hydrogen carriers for a late step in anaerobic heme biosynthesis in Escherichia coli

A late step in anaerobic heme synthesis, the oxidation of protoporphyrinogen with fumarate as electron acceptor, was studied in extracts and particles of Escherichia coli mutants deficient in quinones or cytochromes. Mutants specifically deficient in menaquinone did not couple protoporphyrinogen oxidation to fumarate reduction, whereas mutants containing menaquinone but deficient in either ubiquinone or cytochromes exhibited this activity. These findings indicate that this coupled reaction is dependent upon menaquinone as hydrogen carrier but independent of ubiquinone and cytochromes. Other characteristics of this coupled reaction were also studied. The activity was located exclusively in the membrane fraction of cell-free extracts. Coproporphyrinogen III could not replace protoporphyrinogen as substrate. Methylene blue, triphenyl tetrazolium and nitrate, but not nitrite, could replace fumarate as anaerobic hydrogen acceptor. These findings have implications for the mechanism and regulation of microbial heme and chlorophyll synthesis and for the physiology of cytochrome synthesis in anaerobic microorganisms.     

Respiration and growth of Shewanella decolorationis S12 with an Azo compound as the sole electron acceptor

The ability of Shewanella decolorationis S12 to obtain energy for growth by coupling the oxidation of various electron donors to dissimilatory azoreduction was investigated. This microorganism can reduce a variety of azo dyes by use of formate, lactate, pyruvate, or H(2) as the electron donor. Furthermore, strain S12 grew to a maximal density of 3.0 x 10(7) cells per ml after compete reduction of 2.0 mM amaranth in a defined medium. This was accompanied by a stoichiometric consumption of 4.0 mM formate over time when amaranth and formate were supplied as the sole electron acceptor and donor, respectively, suggesting that microbial azoreduction is an electron transport process and that this electron transport can yield energy to support growth. Purified membranous, periplasmic, and cytoplasmic fractions from S12 were analyzed, but only the membranous fraction was capable of reducing azo dyes with formate, lactate, pyruvate, or H(2) as the electron donor. The presence of 5 microM Cu(2+) ions, 200 microM dicumarol, 100 microM stigmatellin, and 100 microM metyrapone inhibited anaerobic azoreduction activity by both whole cells and the purified membrane fraction, showing that dehydrogenases, cytochromes, and menaquinone are essential electron transfer components for azoreduction. These results provide evidence that the microbial anaerobic azoreduction is linked to the electron transport chain and suggest that the dissimilatory azoreduction is a form of microbial anaerobic respiration. These findings not only expand the number of potential electron acceptors known for microbial energy conservation but also elucidate the mechanisms of microbial anaerobic azoreduction.     

Oxidation of protoporphyrinogen in the obligate anaerobe Desulfovibrio gigas.

The anaerobic oxidation of protoporphyrinogen to protoporphyrin was demonstrated in extracts of Desulfovibrio gigas. Protoporphyrin formation occurred in the presence of nitrite, hydroxylamine, sulfite, thiosulfate, ATP plus sulfate, NAD+, NADP+, flavin adenine dinucleotide, flavin mononucleotide, fumarate, 2,6-dichlorophenol-indophenol, methyl viologen, and 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide. With dialyzed cell extracts, highest activities were observed with sulfite, NAD+, and NADP+ as electron acceptors. The enzyme for protoporphyrinogen oxidation was localized in the membrane of D. gigas and displayed optimal activity at pH 7.3 and 28 degrees C.     

Anaerobic fumarate transport in Escherichia coli by an fnr-dependent dicarboxylate uptake system which is different from the aerobic dicarboxylate uptake system.

Escherichia coli grown anaerobically with fumarate as electron acceptor is able to take up C4-dicarboxylates by a specific transport system. The system differs in all tested parameters from the known aerobic C4-dicarboxylate transporter. The anaerobic transport system shows higher transport rates (95 mumol/g [dry weight] per min versus 30 mumol/g/min) and higher Kms (400 versus 30 microM) for fumarate than for the aerobic system. Mutants lacking the aerobic dicarboxylate uptake system are able to grow anaerobically at the expense of fumarate respiration and transport dicarboxylates with wild-type rates after anaerobic but not after aerobic growth. Transport by the anaerobic system is stimulated by preloading the bacteria with dicarboxylates. The anaerobic transport system catalyzes homologous and heterologous antiport of dicarboxylates, whereas the aerobic system operates only in the unidirectional mode. The anaerobic antiport is measurable only in anaerobically grown bacteria with fnr+ backgrounds. Additionally, the system is inhibited by incubation of resting bacteria with physiological electron acceptors such as O2, nitrate, dimethyl sulfoxide, and fumarate. The inhibition is reversed by the presence of reducing agents. It is suggested that the physiological role of the system is a fumarate/succinate antiport under conditions of fumarate respiration.     

Characterization of a novel tetracycline resistance that functions only in aerobically grown Escherichia coli.

A tetracycline resistance (Tcr) gene that was found originally on two Bacteroides plasmids (pBF4 and pCP1) confers tetracycline resistance on Escherichia coli, but only when it is grown aerobically. Using maxicells, we have identified a 44-kilodalton protein which is encoded by the region that carries the Tcr gene and which may be the Tcr gene product. Localization experiments indicate that this 44-kilodalton protein is cytoplasmic. To determine whether the tetracycline resistance gene is expressed under anaerobic conditions, we have constructed a protein fusion between the Tcr gene and lacZ. In strains of E. coli carrying the fusion, beta-galactosidase activity was the same when the cells were grown under anaerobic conditions as when the cells were grown under aerobic conditions. This indicates that the tetracycline resistance gene product is made under anaerobic conditions but does not work. The failure of the Tcr protein to function under anaerobic conditions was not due to a requirement for function of the anaerobic electron transport system, because neither nitrate nor fumarate added to anaerobic media restored tetracycline resistance. Inhibition of the aerobic electron transport system with potassium cyanide did not prevent growth on tetracycline of cells containing the Tcr gene. A heme-deficient mutant, E. coli SHSP19, which carries the Tcr gene, was still resistant to tetracycline even when grown in heme-free medium. These results indicate that functioning of the Tcr gene product is not dependent on the aerobic electron transport system. Thus the requirement for aerobic conditions appears to reflect a requirement for oxygen. Spent medium from an E. coli strain carrying the Tcr gene, which was grown in medium containing tetracycline (50 micrograms/ml), did not inhibit growth of a tetracycline-susceptible strain of E. coli. Thus, the Tcr gene product may be detoxifying tetracycline.     

Terminal steps of haem biosynthesis

The terminal three steps in haem biosynthesis are the oxidative decarboxylation of coproporphyrinogen III to protoporphyrinogen IX, followed by the six-electron oxidation of protoporphyrinogen to protoporphyrin IX, and finally the insertion of ferrous iron to form haem. Interestingly, Nature has evolved distinct enzymic machinery to deal with the antepenultimate (coproporphyrinogen oxidase) and penultimate (protoporphyrinogen oxidase) steps for aerobic compared with anaerobic organisms. The terminal step is catalysed by the enzyme ferrochelatase. This enzyme is clearly conserved with regard to a small set of essential catalytic residues, but varies significantly with regard to size, subunit composition, cellular location and the presence or absence of a [2Fe-2S] cluster. Coproporphyrinogen oxidase and protoporphyrinogen oxidase are reviewed with regard to their enzymic and physical characteristics. Ferrochelatase, which is the best characterized of these three enzymes, will be described with particular emphasis paid to what has been learned from the crystal structure of the Bacillus subtilis and human enzymes.     

Energy coupling to active transport in anaerobically grown mutants of Escherichia Coli K12.

1. Anaerobic uptake of proline requires either the presence of a coupled Mg2+-stimulated adenosine triphosphatase or anaerobic electron transport. 2. Anaerobic uptake of glutamine does not require anaerobic electron transport even in the absence of a coupled Mg+2-stimulated adenosine triphosphatase. 3. These results support previous suggestions [Berger (1973) Proc. Natl. Acad. Sci. U.S.A. 70, 1514--1518; Berger & Heppel (1974) J. Biol. Chem. 249, 7747-7755; Kobayashi, Kin & Anraku (1974) J. Biochem. (Tokyo) 76, 251-261] that two distinct mechanisms of energy coupling to active transport exist in Escherichia coli in that energization of anaerobic proline uptake requires the 'high-energy membrane state', whereas the energization of anaerobic glutamine uptake does not.     

Respiration and Growth of Shewanella decolorationis S12 with an Azo Compound as the Sole Electron Acceptor

The ability of Shewanella decolorationis S12 to obtain energy for growth by coupling the oxidation of various electron donors to dissimilatory azoreduction was investigated. This microorganism can reduce a variety of azo dyes by use of formate, lactate, pyruvate, or H₂ as the electron donor. Furthermore, strain S12 grew to a maximal density of 3.0 × 10⁷ cells per ml after compete reduction of 2.0 mM amaranth in a defined medium. This was accompanied by a stoichiometric consumption of 4.0 mM formate over time when amaranth and formate were supplied as the sole electron acceptor and donor, respectively, suggesting that microbial azoreduction is an electron transport process and that this electron transport can yield energy to support growth. Purified membranous, periplasmic, and cytoplasmic fractions from S12 were analyzed, but only the membranous fraction was capable of reducing azo dyes with formate, lactate, pyruvate, or H₂ as the electron donor. The presence of 5 μM Cu²⁺ ions, 200 μM dicumarol, 100 μM stigmatellin, and 100 μM metyrapone inhibited anaerobic azoreduction activity by both whole cells and the purified membrane fraction, showing that dehydrogenases, cytochromes, and menaquinone are essential electron transfer components for azoreduction. These results provide evidence that the microbial anaerobic azoreduction is linked to the electron transport chain and suggest that the dissimilatory azoreduction is a form of microbial anaerobic respiration. These findings not only expand the number of potential electron acceptors known for microbial energy conservation but also elucidate the mechanisms of microbial anaerobic azoreduction.     

Anaerobic electron transport in anaerobic flagellum formation in Escherichia coli.

Flagellum formation by ubiquinone- and menaquinone-deficient mutant strains of Escherichia coli K-12 was studied under both aerobic and anaerobic growth conditions. Ubiquinone was found to be obligatory for aerobic flagellum formation but could be replaced by menaquinone for anaerobic flagellum formation. A mutant devoid of both quinones was immotile aerobically as well as anaerobically. Hence, the respective electron transport system is obligatory for flagellum formation in Escherichia coli.     

Interaction between the fumarate reductase system of Escherichia coli and the nitrogen fixation genes of Klebsiella pneumoniae.

For phenotypic expression of nif+Kp genes in Escherichia coli K-12, the anaerobic electron transport system to fumarate must be functional. The role of the fumarate reduction system is to energize the membrane and thus provide the energy necessary for nitrogen fixation.     

Functional analysis of the hemK gene product involvement in protoporphyrinogen oxidase activity in yeast

The Escherichia coli hemK gene has been described as being involved in protoporphyrinogen oxidase activity; however, there is no biochemical evidence for this. In the context of characterizing the mechanisms of protoporphyrinogen oxidation in the yeast Saccharomyces cerevisiae, we investigated the yeast homolog of HemK, which is encoded by the ORF YNL063w, to find out whether it has any protoporphyrinogen oxidase activity and/or whether it modulates protoporphyrinogen oxidase activity. Phenotype analysis and enzyme activity measurements indicated that the yeast HemK homolog is not involved in protoporphyrinogen oxidase activity. Complementation assays in which the yeast HemK homolog is overproduced do not restore wild-type phenotypes in a yeast strain with deficient protoporphyrinogen oxidase activity. Protein sequence analysis of HemK-related proteins revealed consensus motif for S-adenosyl-methionine-dependent methyltransferase.     

Anaerobic transport of amino acids coupled to the glycerol-3-phosphate-fumarate oxidoreductase system in a cytochrome-deficient mutant of Escherichia coli.

The uptake of proline and glutamine by cytochrome-deficient cells of Escherichia coli SASX76 grown aerobically on glucose or anaerobically on pyruvate was stimulated by these two substrates. Pyruvate could not stimulate transport in the glucose-grown cells. Uptake of these amino acids energized by glucose was inhibited by inhibitors of the Ca2+, Mg2+-stimulated ATPase such as DCCD, pyrophosphate, and azide, and by the uncouplers CCCP and 2,4-dinitrophenol. Glycerol (or glycerol 3-phosphate) in the presence of fumarate stimulated the transport of proline and glutamine under anaerobic conditions in cytochrome-deficient cells but not in membrane vesicles prepared from these cells although glycerol 3-phosphate-fumarate oxidoreductase activity could be demonstrated in the vesicle preparation. In contrast, in vesicles prepared from cytochrome-containing cells of E. coli SASX76 amino acid transport was energized under anaerobic conditions by this system. Inhibitors of the Ca2+, Mg2+-activated ATPase and uncoupling agents inhibited the uptake of proline and glutamine in cytochrome-deficient cells dependent on the glycerol-fumarate oxidoreductase system. Ferricyanide could replace fumarate as an electron acceptor to permit transport of phenylalanine in cytochrome-deficient or cytochrome-containing cells under anaerobic conditions. It is concluded that in cytochrome-deficient cells using glucose, pyruvate, or glycerol in the presence of fumarate, transport of both proline and glutamine under under anaerobic conditions is energized by ATP through the Ca2+, Mg2+-activated ATPase. In cytochrome-containing cells under anaerobic conditions electron transfer between glycerol and fumarate can also drive transport of these amino acids.     

The anaerobic oxidation of dihydroorotate by Escherichia coli K-12.

The oxidation of dihydroorotate under anaerobic conditions has been examined using various mutant strains of Escherichia coli K-12. This oxidation in cells grown anaerobically in a glucose minimal medium is linked via menaquinone to the fumarate reductase enzyme coded for by the frd gene and is independent of the cytochromes. The same dihydroorotate dehydrogenase protein functions in both the anaerobic and aerobic oxidation of dihydroorotate. Ferricyanide can act as an artificial electron acceptor for dihydroorotate dehydrogenase and the dihydroorotate-menaquinone-ferricyanide reductase activity can be solubilised by 2 M guanidine-HCl with little loss of activity.     

Energy transduction in Escherichia coli. The effect of chaotropic agents on energy coupling in everted membrane vesicles from aerobic and anaerobic cultures.

1. The transduction of energy from the oxidation of substrates by the electron transport chain or from the hydrolysis of ATP by the Mg2+-ATPase was measured in everted membrane vesicles of Escherichia coli using the energy-dependent quenching of quinacrine fluorescence and the active transport of calcium. 2. Treatment of everted membranes derived from a wild-type strain with the chaotropic agents guanidine-HC1 and urea caused a loss of energy-linked functions and an increase in the permeability of the membrane to protons, as measured by the loss of respiratory-linked proton uptake. 3. The coupling of energy to the quenching of quinacrine fluorescence and calcium transport could be restored by treatment of the membranes with N,N'-dicyclohyexylcarbodiimide. 4. Chaotrope-treated membranes were found to lack Mg2+-ATPase activity. Binding of crude soluble Mg2+-ATPase to treated membranes restored energy-linked functions. 5. Membranes prepared from a wild-type strain grown under anaerobic conditions in the presence of nitrate retained respiration-linked quenching of quinacrine fluorescence and active transport of calcium after treatment with chaotropic agents. 6. Everted membrane vesicles prepared from an Mg2+-ATPase deficient strain lacked respiratory-driven functions when the cells were grown aerobically but were not distinguishable from membranes of the wild-type when both were grown under anaerobic conditions in the presence of nitrate. 7. It is concluded (a) that chaotropic agents solubilize a portion of the Mg2+-ATPase, causing an increase in the permeability of the membrane to protons and (b) that growth under anaerobic conditions in the presence of nitrate prevents the increase in proton permeability caused by genetic or chemical removal of the catalytic portion of the Mg2+-ATPase.