Department of Biochemistry and Witebsky Center for Microbial Pathogenesis, State University of New York at Buffalo, Buffalo, NY 14214, USA1
Author for correspondence: Mark R. OBrian. Tel: +1 716 829 3200. Fax: +1 716 829 2725. e-mail: mrobrian{at}buffalo.edu
Keywords: tetrapyrroles, porphyrins, Archaea, degenerate genomes
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Overview |
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Haem function |
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Cytochromes are quantitatively the predominant haem proteins in most prokaryotes, and are essential for respiration. Prokaryotes can carry out oxidative respiration in the absence of oxygen using nitrate, sulfate or other oxidants. Cytochromes mediate electron transfer and the final reduction of the terminal electron acceptor as occurs with O2-based respiration. Also, some prokaryotes respond to hypoxia by expressing cytochrome oxidases with high affinity for oxygen, and therefore oxygen limitation actually increases the demand for haem synthesis. Thus the need for haem is not restricted to aerobic metabolism at ambient O2 levels as it is in eukaryotes; rather, haem contributes to metabolic adaptation. Indeed, haems are found throughout the Bacteria and Archaea, and in most cases the demand is met by biosynthesis rather than by acquisition from the environment.
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Haem biosynthetic pathway |
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The two oxidative steps catalysed by coproporphyrinogen III oxidase and protoporphyrinogen IX oxidase use oxygen as a substrate in eukaryotes. Orthologues of those eukaryotic genes are found only in some prokaryotes, which in part reflects the fact that haem synthesis can occur in the absence of oxygen. Protoporphyrin chelates ferrous iron to form protohaem, which is catalysed by ferrochelatase. Protohaem is the prosthetic group of numerous haem proteins, and is modified further to synthesize other types of haems found in cytochrome c and terminal oxidases.
Gene designations
Table 1 lists the names of the genes encoding the enzymes of the haem biosynthetic pathway. The hemA designation has been ascribed to both the gene encoding ALA synthase and to that encoding the C5 pathway glutamyl-tRNA reductase. Although both enzymes are involved in ALA formation, they are structurally dissimilar proteins that have different substrates and products, and therefore should not have the same gene name. We recommend that the ALA synthase gene be designated hemA and the gene encoding glutamyl-tRNA reductase as gtrA. hemG and hemY encode distinct protoporphyrinogen oxidase proteins, but the porphyrin substrate and product are the same for both enzymes. The oxygen-dependent and oxygen-independent coproporphyrinogen oxidases are dissimilar proteins encoded by hemF and hemN, respectively. A second O2-independent coproporphyrinogen oxidase gene homologue has been identified in numerous bacteria and is called hemZ in Rhodobacter sphaeroides (Zeilstra-Ryalls & Kaplan, 1995
; Yeliseev & Kaplan, 1999
) and Bacillus subtilis (Homuth et al., 1999
). There is no evidence to suggest that the hemZ genes are functionally similar to each other, and thus the hemZ designation may be confusing.
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Prokaryotic ALA synthase is found only in the ![]() |
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In addition to ALA synthase, the -proteobacteria Agrobacterium tumefaciens, Caulobacter crescentus, Mesorhizobium loti and Sinorhizobium meliloti also contain a gene encoding a product with high similarity to the C5 pathway enzyme glutamate-1-semialdehyde aminotransferase (GSAT), and the C. crescentus and S. meliloti gene products are annotated as GSAT in the databases. However, these proteins are highly homologous to aminotransferases in general. For example, E. coli GSAT shares 48% similarity with the S. meliloti protein annotated as GSAT (ID no. 1560716), but it also shares 49% similarity with an S. meliloti 4-aminobutyrate aminotransferase and high homology with other aminotransferases as well. More importantly, none of the
-proteobacteria have the other C5 pathway gene encoding glutamyl-tRNA reductase. Finally, C5 pathway enzyme activity could not be found in the
-proteobacteria Bradyrhizobium japonicum (Sangwan & OBrian, 1991
) or Azorhizobium caulinodans (Avissar et al., 1989
). Therefore, it is very unlikely that the C5 pathway operates in those organisms.
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Structural heterogeneity of uroporphyrinogen III synthases |
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An intriguing hemD-like gene is found in the strict anaerobe Clostridium josui that is an apparent gene fusion of the cobA gene with hemD predicted to encode a hybrid protein (Fujino et al., 1995 ). The cobA gene encodes uroporphyrinogen III methyltransferase, an activity involved in cobalamin and sirohaem synthesis, but not in haem biosynthesis. The cobA/hemD fusion can complement an E. coli hemD mutant, showing that it has uroporphyrinogen III synthase activity. This unusual cobA/hemD fusion is also observed in the other clostridial species Clostridium acetobutylicum and Clostridium perfringens, as well as in Synechocystis sp. PCC 6803, Nostoc sp. PCC 7120 and in the Mycobacterium species.
Some organisms do not have a distinct CobA protein, but rather have a multifunctional protein called sirohaem synthase (CysG), which carries out the methyltransferase reaction as well as two additional reactions for sirohaem formation from uroporphyrinogen III. CysG has a C-terminal domain very homologous to CobA in accordance with its activity. The relevance of this to haem synthesis is noted below.
The cobA/hemD gene fusion originally described in C. josui has led to the incorrect annotation of other genes identified in genome sequencing projects. Some homologues of cysG or cobA have been annotated as hemD or as encoding uroporphyrinogen III synthase when there is no similarity to that protein. Some hemD genes have been annotated as encoding a synthase/methyltransferase as well. When these errors are taken into account, it is clear that some organisms predicted to synthesize tetrapyrroles do not contain a recognizable hemD gene. This issue was addressed systematically by searching the genomes for those that contain both the hemB and hemC gene, but not a hemD gene. The rationale for this is that the enzymes necessary for uroporphyrinogen III synthesis, including uroporphyrinogen III synthase, should be found in organisms that make tetrapyrroles since uroporphyrinogen is the branch point for all of them. Thus hemB, hemC and hemD genes should be present in all tetrapyrrole-synthesizing prokaryotes, even those that do not make haem (there are two ALA synthesis routes, thus those genes will not be universal).
BLAST searches of each genome containing hemB and hemC genes were carried out using bona fide uroporphyrinogen III synthases from E. coli, B. subtilis and mouse (protein id nos 41676, 399875 and 1363253, respectively). This search identified nine taxonomically diverse species from seven genera that contain no identifiable uroporphyrinogen III synthase (hemD) gene. Rickettsia prowazekii, Rickettsia conorii and Caulobacter crescentus are -proteobacteria. Aeropyrum pernix, Pyrobaculum aerophilum and Thermoplasma acidophilum are archaea. Chlamydophila pneumoniae (strains AR39, J138, CWL029), Chlamydia muridarum and Chlamydia trachomatis are chlamydiaceae.
The inability to identify hemD homologues in these prokaryotes indicates an enzyme or enzymes that differ substantially in primary structure from known uroporphyrinogen III synthases that carry out that reaction. We note that prokaryotic hemD gene products have been shown to be bona fide uroporphyrinogen III synthases only in a few species, and the model enzymes from E. coli and B. subtilis share only 25% identity to each other. Moreover, a uroporphyrinogen III synthase gene has not been identified in any plant, nor is a recognizable homologue found in the Arabidopsis thaliana genome. This is surprising considering the large chlorophyll requirement in plants and the successful purification of the protein from wheat (Higuchi & Bogorad, 1975 ).
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Oxygen-dependent coproporphyrinogen oxidase is restricted to few eubacterial groups |
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Absence of an identifiable protoporphyrinogen oxidase gene homologue in many prokaryotes |
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The light sensitivity of an E. coli hemH (ferrochelatase) gene was reversed by a second mutation in a gene named hemK (Nakayashiki et al., 1995 ), found in the putative hemAprfAhemK operon. The hemK mutant accumulates coproporphyrin and protoporphyrin when growth medium was supplemented with ALA, suggesting to the authors that hemK may be deficient in protoporphyrinogen oxidase activity. However, a mutation in a hemK homologue in yeast is not deficient in protoporphyrinogen oxidase, nor does overexpression of the hemK homologue confer activity (Le Guen et al., 1999
). Furthermore, HemK-related proteins have a consensus motif for S-adenosyl-methionine-dependent methyltransferases, and may be involved in that function. Finally, hemK homologues are found in many genomes, including those of Borrelia burgdorferi and Treponema pallidum, organisms that do not make haem or contain bona fide haem synthesis genes. From this, it is unlikely that hemK encodes a protoporphyrinogen oxidase, hence there must be another cause for the phenotype of the E. coli hemK strain. Nevertheless, many hemK homologues are annotated as encoding protoporphyrinogen oxidase.
We searched for hemG or hemY homologues in the genomes of organisms that contain the hemE, hemN and hemH genes, as would be expected in organisms that synthesize haem. The genomes of 34 species and 28 genera contain hemE, hemN and hemH and are either known to express haem proteins, or are predicted to based on identified genes (Table 2). hemG is found in six genera within the
-Proteobacteria, and in Mesorhizobium loti, an
-proteobacterium. The hemY gene is found in eight genera that are taxonomically more distributed than is observed for hemG.
Interestingly, of the 28 genera examined, 14 of them contain no recognizable protoporphyrinogen oxidase gene (Table 2). This suggests a major gap in our understanding of haem biosynthetic pathways, even in organisms that are well studied such as Pseudomonas aeruginosa, Caulobacter crescentus, Campylobacter jejuni and the rhizobia. In addition to numerous Gram-negative bacteria, organisms that contain haem biosynthesis genes but not protoporphyrinogen oxidase also include the cyanobacteria Synechocystis PCC 6803 and Nostoc sp. PCC 7120, and the archaeon Thermoplasma volcanium.
Unlike uroporphyrinogen III synthase, the reaction catalysed by protoporphyrinogen oxidase can proceed non-enzymically in vitro, formally raising the possibility that this enzyme is not required in organisms where the gene has not been found. However, protoporphyrinogen oxidase mutants of E. coli (Sasarman et al., 1993 ) and B. subtilis (Homuth et al., 1999
) are haem-defective. It seems more likely that a heretofore unidentified protoporphyrinogen oxidase exists in prokaryotes, or a known protein has an additional activity. In support of the latter idea, a secondary site suppressor mutant of a hemG strain has elevated promoter activity of hemF, the gene encoding the O2-dependent coproporphyrinogen oxidase (Narita et al., 1999
). Furthermore, overexpression of hemF rescues a hemG mutant. However, it remains to be established whether the hemF product normally participates in protoporphyrinogen oxidation in wild-type cells.
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Haem pathway genes corresponding to the branch from uroporphyrinogen III to protohaem are missing in some archaea that contain haem proteins |
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The archaea Sulfolobus acidocaldarius and Sulfolobus solfataricus respire aerobically, contain haem proteins (Becker & Schafer, 1991 ; Lübben & Morand, 1994
; Lübben et al., 1994
; Wright et al., 1996
; Yano et al., 2000
), and the genome of S. solfataricus indicates a plethora of haem-protein-encoding genes. However, our own homology searches as well as the author annotations find genes corresponding to the haem pathway only to uroporphyrinogen III formation. The final four genes, hemE, hemN, hemY (or hemG) and hemH, cannot be found. Similarly, the latter four enzymes of the pathway are unaccounted for in Thermoplasma acidophilum and in the extreme halophilic archaeon Halobacterium sp. NRC-1 despite the presence of haem proteins and haem protein gene homologues in those genera (Denda et al., 1991
, 1995
; Fujiwara et al., 1993
; Gartner, 1991
; Hallberg Gradin & Colmsjo, 1989
). Although we could find no literature citations that identify haem proteins from Aeropyrum pernix or Pyrobaculum aerophilum, they are aerobic thermophiles with many haem-protein-encoding genes, but they also lack identifiable genes that metabolize uroporphyrinogen III to haem.
The discrepancy between a haem protein requirement and the apparent lack of enzymes that metabolize uroporphyrinogen III to haem is thus far confined to aerobic extremophilic archaea. However, the haem genes are observed in the thermophilic proteobacterium Aquifex aeolicus and in the thermophilic archaeon Thermoplasma volcanium (except for protoporphyrinogen oxidase, but see above) and thus neither thermophily nor taxonomy places an intrinsic restriction upon the expression of a conventional haem biosynthetic pathway.
The ecological niches of these extremophiles do not provide an obvious source of exogenous haem for uptake, and therefore it is very probable that haem is synthesized de novo. Even if they possess the alternative route for coproporphyrinogen III synthesis from uroporphyrinogen III as described for Desulfovibrio vulgaris (Akutsu et al., 1993 ; Ishida et al., 1998
), the subsequent oxidations and iron chelation steps cannot be deduced based on homology. It seems likely that these organisms contain heretofore uncharacterized genes involved in haem biosynthesis. Further work is needed to determine whether the enzymology and intermediates differ from the conventional pathway.
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Degenerate genomes |
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Buchnera
Buchnera is an obligate endosymbiont of aphids (Baumann et al., 1995 ) with a genome of only 590 genes. The Buchnera sp. APS genome encodes the four subunits for the cytochrome o complex, as well as protohaem farnesyltransferase, the enzyme that places a farnesylethyl group on protohaem to form the cytochrome o prosthetic group. In addition, the genome encodes sulfite reductase, which has sirohaem as the prosthetic group, and also the enzymes that synthesize sirohaem from uroporphyrinogen. However, Buchnera contains only a homologue of hemC, the gene encoding porphobilinogen deaminase, and a truncated hemN homologue encoding O2-independent coproporphyrinogen oxidase. The exchange of nutrients between Buchnera and its aphid host is documented (Baumann et al., 1995
), and analysis of the bacterial genome raises the possibility that the aphid may provide Buchnera with haem or haem intermediates. Similarly, deletion of the hemA gene in Bradyrhizobium japonicum does not abolish haem synthesis when the organism is in association with soybean because the eukaryotic host can provide the endosymbiont with ALA (Sangwan & OBrian, 1991
).
Rickettsia
The Rickettsia are obligate intracellular bacteria responsible for epidemic typhus in humans. They belong to the -proteobacteria, and taxonomically are the closest known relatives of mitochondria. The genomes of R. prowazekii and R. conorii indicate the presence of a haem biosynthetic pathway, as well as respiratory haem proteins, superoxide dismutase, and TCA cycle enzymes, which are all consistent with aerobic metabolism and similar to the other known
-proteobacterial genomes. However, other aspects of iron metabolism are absent, most notably genes encoding proteins for iron transport and regulation.
The Fur protein is a global transcriptional regulator of iron metabolism that is prevalent in eubacteria, but is absent in Rickettsia. Fur controls many facets of iron homeostasis, including the hemA gene in B. japonicum (Hamza et al., 2000 ). Irr and PerR are structural homologues of Fur but are functionally distinct. Nevertheless, they also mediate iron control of haem synthesis in B. japonicum (Hamza et al., 1998
; Qi & OBrian, 2002
) and B. subtilis (Bsat et al., 1998
), respectively. The absence of Fur homologues in Rickettsia indicates the abandonment of the near universal bacterial-type iron regulation in that genus. However, this does not rule out other types of control by iron.
Most eubacteria have iron transport systems, utilizing either a permease system that can transport the metal directly, or siderophore-mediated transport. Siderophores are iron chelators which bind to a cognate cellular receptor for uptake. The Rickettsia genome appears to lack genes encoding these iron transport proteins despite the plethora of iron-containing proteins in that organism. However, Rickettsia does contain a highly conserved gene homologue of atm1, a mitochondrial iron transport protein prevalent in eukaryotes, and which is associated with X-linked sideroblastic anaemia and ataxia in humans (Allikmets et al., 1999 ). Atm1 is also found in other
-proteobacteria, and therefore it is likely a retained gene rather than one acquired from its eukaryotic host by horizontal gene transfer. The concomitant retention of atm1 and loss of the bacterial-type iron transporter genes in both Rickettsia and mitochondria are likely evolutionary consequences of an obligatory intracellular milieu.
Borrelia burgdorferi
For the most part genome reduction is not an adaptive response, but reflects a lack of selective pressure to maintain genes rendered non-essential by the obligate association with a eukaryotic host (Ochman & Moran, 2001 ). An exception to this is observed in B. burgdorferi, the causative agent of Lyme disease. Most microbial pathogens overcome iron limitation, or so-called nutritional immunity, created by the host by sequestering iron. B. burgdorferi has apparently circumvented this problem by eliminating the need for iron altogether (Posey & Gherardini, 2000
), which is reflected by a genome that does not encode most iron proteins. Accordingly, the haem pathway genes, as well as those for haem proteins, are absent. A fur gene homologue was identified (Posey & Gherardini, 2000
), but its product has greater similarity to PerR, which responds directly to manganese in B. subtilis, and only indirectly to iron (Bsat et al., 1998
). It is possible that B. burgdorferi represents the extreme case of a strategy employed by other pathogens with reduced genomes. Mycoplasma pneumoniae, a respiratory pathogen, and Treponema pallidum, the syphilis spirochaete, lack haem pathway enzymes, cytochromes, iron transport systems and most iron proteins. Exceptions to this are genes for rubredoxin, an ironsulfur protein, found in T. pallidum, and NifS, a protein required for ironsulfur cofactor synthesis. Both M. pneumoniae and T. pallidum have genes encoding dinucleotide reductase, an iron protein involved in nucleotide synthesis, which is missing in B. burgdorferi.
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Concluding remarks |
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ACKNOWLEDGEMENTS |
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REFERENCES |
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Allikmets, R., Raskind, W. H., Hutchinson, A., Schueck, N. D., Dean, M. & Koeller, D. M. (1999). Mutation of a putative mitochondrial iron transporter gene (ABC7) in X-linked sideroblastic anemia and ataxia (XLSA/A). Hum Mol Genet 8, 743-749.
Altschul, S. F., Gish, W., Miller, W., Myers, E. W. & Lipman, D. J. (1990). Basic local alignment tool. J Mol Biol 215, 403-410.[Medline]
Avissar, Y. J., Ormerod, J. G. & Beale, S. I. (1989). Distribution of delta-aminolevulinic acid biosynthetic pathways among phototrophic bacterial groups. Arch Microbiol 151, 513-519.[Medline]
Baumann, P., Baumann, L., Lai, C.-Y. & Rouhbakhsh, D. (1995). Genetics, physiology, and evolutionary relationships of the genus Buchnera: intracellular symbionts of aphids. Annu Rev Microbiol 49, 55-94.[Medline]
Becker, M. & Schafer, G. (1991). Purification and spectral characterization of a b-type cytochrome from the plasma membrane of the archaebacterium Sulfolobus acidocaldarius. FEBS Lett 291, 331-335.[Medline]
Bsat, N., Herbig, A., Casillas-Martinez, L., Setlow, P. & Helmann, J. D. (1998). Bacillus subtilis contains multiple Fur homologs: identification of the iron uptake (Fur) and peroxide regulon (PerR) repressors. Mol Microbiol 29, 189-198.[Medline]
Chen, J. J. & London, I. M. (1995). Regulation of protein synthesis by heme-regulated eIF-2 alpha kinase. Trends Biochem Sci 20, 105-108.[Medline]
Denda, K., Fujiwara, T., Seki, M., Yoshida, M., Fukumori, Y. & Yamanaka, T. (1991). Molecular cloning of the cytochrome aa3 gene from the archaeon (Archaebacterium) Halobacterium halobium. Biochem Biophys Res Commun 181, 316-322.[Medline]
Denda, K., Mogi, T., Anraku, Y., Yamanaka, T. & Fukumori, Y. (1995). Characterization of chimeric heme-copper respiratory oxidases using subunits I of Escherichia coli cytochrome b o and Halobacterium salinarium cytochrome aa3. Biochem Biophys Res Commun 217, 428-436.[Medline]
Fujino, E., Fujino, T., Karita, S., Sakka, K. & Ohmiya, K. (1995). Cloning and sequencing of some genes responsible for porphyrin biosynthesis from the anaerobic bacterium Clostridium josui. J Bacteriol 177, 5169-5175.[Abstract]
Fujiwara, T., Fukumori, Y. & Yamanaka, T. (1993). Halobacterium halobium cytochrome b-558 and cytochrome b-562: purification and some properties. J Biochem (Tokyo) 113, 48-54.[Abstract]
Gartner, P. (1991). Characterization of a quinole-oxidase activity in crude extracts of Thermoplasma acidophilum and isolation of an 18-kDa cytochrome. Eur J Biochem 200, 215-222.[Abstract]
Hach, A., Hon, T. & Zhang, L. (1999). A new class of repression modules is critical for heme regulation of the yeast transcriptional activator Hap1. Mol Cell Biol 19, 4324-4333.
Hallberg Gradin, C. & Colmsjo, A. (1989). Four different b-type cytochromes in the halophilic archaebacterium, Halobacterium halobium. Arch Biochem Biophys 272, 130-136.[Medline]
Hamza, I., Chauhan, S., Hassett, R. & OBrian, M. R. (1998). The bacterial Irr protein is required for coordination of heme biosynthesis with iron availability. J Biol Chem 273, 21669-21674.
Hamza, I., Qi, Z., King, N. D. & OBrian, M. R. (2000). Fur-independent regulation of iron metabolism by Irr in Bradyrhizobium japonicum. Microbiology 146, 669-676.
Hansson, M. & Hederstedt, L. (1992). Cloning and characterization of the Bacillus subtilis hemEHY gene cluster, which encodes protoheme IX biosynthetic enzymes. J Bacteriol 174, 8081-8093.[Abstract]
Higuchi, M. & Bogorad, L. (1975). The purification and properties of uroporphyrinogen I synthases and uroporphyrinogen III cosynthase. Ann N Y Acad Sci 244, 401-418.[Medline]
Homuth, G., Rompf, A., Schumann, W. & Jahn, D. (1999). Transcriptional control of Bacillus subtilis hemN and hemZ. J Bacteriol 181, 5922-5929.
Ishida, T., Yu, L., Akutsu, H., Ozawa, K., Kawanishi, S., Seto, A., Inubushi, T. & Sano, S. (1998). A primitive pathway of porphyrin biosynthesis and enzymology in Desulfovibrio vulgaris. Proc Natl Acad Sci USA 95, 4853-4858.
Keithly, J. H. & Nadler, K. D. (1983). Protoporphyrin formation in Rhizobium japonicum. J Bacteriol 154, 838-845.[Medline]
Lathrop, J. T. & Timko, M. P. (1993). Regulation by heme of mitochondrial protein transport through a conserved amino acid motif. Science 259, 522-525.[Medline]
Le Guen, L., Santos, R. & Camadro, J. M. (1999). Functional analysis of the hemK gene product involvement in protoporphyrinogen oxidase activity in yeast. FEMS Microbiol Lett 173, 175-182.[Medline]
Lübben, M. & Morand, K. (1994). Novel prenylated hemes as cofactors of cytochrome oxidases. Archaea have modified hemes A and O. J Biol Chem 269, 21473-21479.
Lübben, M., Warne, A., Albracht, S. P. & Saraste, M. (1994). The purified SoxABCD quinol oxidase complex of Sulfolobus acidocaldarius contains a novel haem. Mol Microbiol 13, 327-335.[Medline]
Nakajima, O., Takahashi, S., Harigae, H., Furuyama, K., Hayashi, N., Sassa, S. & Yamamoto, M. (1999). Heme deficiency in erythroid lineage causes differentiation arrest and cytoplasmic iron overload. EMBO J 18, 6282-6289.
Nakayashiki, T., Nishimura, K. & Inokuchi, H. (1995). Cloning and sequencing of a previously unidentified gene that is involved in the biosynthesis of heme in Escherichia coli. Gene 153, 67-70.[Medline]
Narita, S., Taketani, S. & Inokuchi, H. (1999). Oxidation of protoporphyrinogen IX in Escherichia coli is mediated by the aerobic coproporphyrinogen oxidase. Mol Gen Genet 261, 1012-1020.[Medline]
Ochman, H. & Moran, N. A. (2001). Genes lost and genes found: evolution of bacterial pathogenesis and symbiosis. Science 292, 1096-1098.
Ogawa, K., Sun, J., Taketani, S. & 8 other authors (2001). Heme mediates derepression of Maf recognition element through direct binding to transcription repressor Bach1. EMBO J 20, 28352843.
Posey, J. E. & Gherardini, F. C. (2000). Lack of a role for iron in the Lyme disease pathogen. Science 288, 1651-1653.
Qi, Z. & OBrian, M. R. (2002). Interaction between the bacterial iron response regulator and ferrochelatase mediates genetic control of heme biosynthesis. Mol Cell 9, 155-162.[Medline]
Qi, Z., Hamza, I. & OBrian, M. R. (1999). Heme is an effector molecule for iron-dependent degradation of the bacterial iron response regulator (Irr) protein. Proc Natl Acad Sci USA 96, 13056-13061.
Reddy, S. V., Alcantara, G., Roodman, D. & Boldt, D. H. (1996). Inhibition of tartrate-resistant acid phosphatase gene expression by hemin and protoporphyrin IX. Identification of a hemin-responsive inhibitor of transcription. Blood 88, 2288-2297.
Rodgers, K. R. (1999). Heme-based sensors in biological systems. Curr Opin Chem Biol 3, 158-167.[Medline]
Sangwan, I. & OBrian, M. R. (1991). Evidence for an inter-organismic heme biosynthetic pathway in symbiotic soybean root nodules. Science 251, 1220-1222.
Sasarman, A., Chartrand, P., Lavoie, M., Tardif, D., Proschek, R. & Lapointe, C. (1979). Mapping of a new hem gene in Escherichia coli K12. J Gen Microbiol 113, 297-303.[Medline]
Sasarman, A., Letowski, J., Czaika, G., Ramirez, V., Nead, M. A., Jacobs, J. M. & Morais, R. (1993). Nucleotide sequence of the hemG gene involved in the protoporphyrinogen oxidase activity of Escherichia coli K12. Can J Microbiol 39, 1155-1161.[Medline]
Schmitt, M. P. (1999). Identification of a two-component signal transduction system from Corynebacterium diphtheriae that activates gene expression in response to the presence of heme and hemoglobin. J Bacteriol 181, 5330-5340.
Seehra, J. S., Jordan, P. M. & Akhtar, M. (1983). Anaerobic and aerobic coproporphyrinogen III oxidases of Rhodopseudomonas spheroides. Mechanism and stereochemistry of vinyl group formation. Biochem J 209, 709-718.[Medline]
Wang, L., Elliott, M. & Elliott, T. (1999). Conditional stability of the HemA protein (glutamyl-tRNA reductase) regulates heme biosynthesis in Salmonella typhimurium. J Bacteriol 181, 1211-1219.
Wright, R. L., Harris, K., Solow, B., White, R. H. & Kennelly, P. J. (1996). Cloning of a potential cytochrome P450 from the archaeon Sulfolobus solfataricus. FEBS Lett 384, 235-239.[Medline]
Xu, K. & Elliott, T. (1994). Cloning, DNA sequence, and complementation analysis of the Salmonella typhimurium hemN gene encoding a putative oxygen-independent coproporphyrinogen III oxidase. J Bacteriol 176, 3196-3203.[Abstract]
Yano, J. K., Koo, L. S., Schuller, D. J., Li, H., Ortiz de Montellano, P. R. & Poulos, T. L. (2000). Crystal structure of a thermophilic cytochrome P450 from the archaeon Sulfolobus solfataricus. J Biol Chem 275, 31086-31092.
Yeliseev, A. A. & Kaplan, S. (1999). A novel mechanism for the regulation of photosynthesis gene expression by the TspO outer membrane protein of Rhodobacter sphaeroides 2.4.1. J Biol Chem 274, 21234-21243.
Zeilstra-Ryalls, J. H. & Kaplan, S. (1995). Aerobic and anaerobic regulation in Rhodobacter sphaeroides 2.4.1: the role of the fnrL gene. J Bacteriol 177, 6422-6431.[Abstract]