Molecular cloning, characterization and regulation by cadmium of a superoxide dismutase from the ectomycorrhizal fungus Paxillus involutus.

The gene encoding a superoxide dismutase (PiSOD) was cloned by suppressive subtractive hybridization from cDNA library of the ectomycorrhizal fungus, Paxillus involutus, grown under cadmium-stress conditions. The encoded protein was presumed to be localized in the peroxisomes because it contained a C-terminal peroxisomal localization peptide (SKL) and lacked an N-terminal mitochondrial transit peptide. Complementation of an Escherichia coli SOD null strain that is unable to grow in the presence of paraquat or cadmium indicated that cloned Pisod encoded a functional superoxide dismutase. Sensitivity of PiSOD activity to H2O2 but not KCN, and sequence homologies to other SODs strongly suggest that it is a manganese-containing superoxide dismutase. Monitoring PiSOD transcript, immunoreactive polypeptide and superoxide dismutase activity following cadmium stress suggests that the principal level of control is post-translational. This is, to our knowledge, the first insight in the characterization of molecular events that take place in an ectomycorrhizal fungus during exposure to heavy metals.

Catalase-peroxidases of Legionella pneumophila: cloning of the katA gene and studies of KatA function.

Legionella pneumophila, the causative organism of Legionnaires' pneumonia, contains two enzymes with catalatic and peroxidatic activity, KatA and KatB. To address the issue of redundant, overlapping, or discrete in vivo functions of highly homologous catalase-peroxidases, the gene for katA was cloned and its function was studied in L. pneumophila and Escherichia coli and compared with prior studies of katB in this laboratory. katA is induced during exponential growth and is the predominant peroxidase in stationary phase. When katA is inactivated, L. pneumophila is more sensitive to exogenous hydrogen peroxide and less virulent in the THP-1 macrophage cell line, similar to katB. Catalatic-peroxidatic activity with different peroxidatic cosubstrates is comparable for KatA and KatB, but KatA is five times more active towards dianisidine. In contrast with these examples of redundant or overlapping function, stationary-phase survival is decreased by 100- to 10,000-fold when katA is inactivated, while no change from wild type is seen for the katB null. The principal clue for understanding this discrete in vivo function was the demonstration that KatA is periplasmic and KatB is cytosolic. This stationary-phase phenotype suggests that targets sensitive to hydrogen peroxide are present outside the cytosol in stationary phase or that the peroxidatic activity of KatA is critical for stationary-phase redox reactions in the periplasm, perhaps disulfide bond formation. Since starvation-induced stationary phase is a prerequisite to acquisition of virulence by L. pneumophila, further studies on the function and regulation of katA in stationary phase may give insights on the mechanisms of infectivity of this pathogen.

Identification of a regulator that controls stationary-phase expression of catalase-peroxidase in Caulobacter crescentus.

Expression of the catalase-peroxidase of Caulobacter crescentus, a gram-negative member of the alpha subdivision of the Proteobacteria, is 50-fold higher in stationary-phase cultures than in exponential cultures. To identify regulators of the starvation response, Tn5 insertion mutants were isolated with reduced expression of a katG::lacZ fusion on glucose starvation. One insertion interrupted an open reading frame encoding a protein with significant amino acid sequence identity to TipA, a helix-turn-helix transcriptional activator in the response of Streptomyces lividans to the peptide antibiotic thiostrepton, and lesser sequence similarity to other helix-turn-helix regulators in the MerR family. The C. crescentus orthologue of tipA was named skgA (stationary-phase regulation of katG). Stationary-phase expression of katG was reduced by 70% in the skgA::Tn5 mutant, and stationary-phase resistance to hydrogen peroxide decreased by a factor of 10. Like the wild type, the skgA mutant exhibited starvation-induced cross-resistance to heat and acid shock, entered into the helical morphology that occurs after 9 to 12 days in stationary phase, and during exponential growth induced katG in response to hydrogen peroxide challenge. Expression of skgA increased 5- to 10-fold in late exponential phase. skgA is the first regulator of a starvation-induced stress response identified in C. crescentus. SkgA is not a global regulator of the stationary-phase stress response; its action encompasses the oxidative stress-hydrogen peroxide response but not acid or heat responses. Moreover, SkgA is not an alternative sigma factor, like RpoS, which controls multiple aspects of starvation-induced cross-resistance to stress in enteric bacteria. These observations raise the possibility that regulation of stationary-phase gene expression in this member of the alpha subdivision of the Proteobacteria is different from that in Escherichia coli and other members of the gamma subdivision.

Legionella pneumophila catalase-peroxidases: cloning of the katB gene and studies of KatB function.

Legionella pneumophila, the causative organism of Legionnaires' pneumonia, is spread by aerosolization from man-made reservoirs, e.g. , water cooling towers and air conditioning ducts, whose nutrient-poor conditions are conducive to entrance into stationary phase. Exposure to starvation conditions is known to induce several virulence traits in L. pneumophila. Since catalase-peroxidases have been extremely useful markers of the stationary-phase response in many bacterial species and may be an avenue for identifying virulence genes in L. pneumophila, an investigation of these enzymes was initiated. L. pneumophila was shown to contain two bifunctional catalase-peroxidases and to lack monofunctional catalase and peroxidase. The gene encoding the KatB catalase-peroxidase was cloned and sequenced, and lacZ fusion and null mutant strains were constructed. Null mutants in katB are delayed in the infection and lysis of cultured macrophage-like cell lines. KatB is similar to the KatG catalase-peroxidase of Escherichia coli in its 20-fold induction during exponential growth and in playing a role in resistance to hydrogen peroxide. Analysis of the changes in katB expression and in the total catalase and peroxidase activity during growth indicates that the 8- to 10-fold induction of peroxidase activity that occurs in stationary phase is attributable to KatA, the second L. pneumophila catalase-peroxidase.

Changes in cochlear antioxidant enzyme activity after sound conditioning and noise exposure in the chinchilla.

Exposure to low level noise prior to a high level exposure reduces noise-induced hearing loss in mammals. This phenomenon is known as sound conditioning or 'toughening'. Reactive oxygen intermediates have been implicated in noise-induced cochlear damage. To evaluate if in situ antioxidant processes may play a role in the toughening phenomenon initiated by low level noise exposure we analyzed glutathione reductase, gamma-glutamyl cysteine synthetase, and catalase in stria vascularis and organ of Corti fractions from cochleae of chinchillas exposed to a sound conditioning paradigm. Chinchillas were either (A) kept in quiet cages (control), (B) exposed to conditioning noise of a 0.5 kHz octave band (90 dB for 6 h/day for 10 days), (C) exposed to high level noise (105 dB for 4 h) or (D) exposed to conditioning noise (B) followed by exposure to the higher level noise (C). Each of the noise exposure conditions (B, C, D) induced changes in the levels of these three antioxidant enzymes. The enzyme-specific activity data for the four subject groups support the following two hypotheses. (1) Changes in glutathione reductase, gamma-glutamyl cysteine synthetase, and catalase play a role in attenuating hearing loss associated with sound conditioning followed by high level noise. (2) Hair cells in the organ of Corti are protected from noise-induced damage by increasing stria vascularis levels of catalase, a hydrogen peroxide scavenging enzyme, and of enzymes involved in maintaining glutathione in the reduced state. The model formulated by these hypotheses suggests that agents that protect or augment the glutathione system in the cochlea may be protective against noise-induced hearing loss.

Catalase-peroxidase of Caulobacter crescentus: function and role in stationary-phase survival.

Caulobacter crescentus is an obligate aerobe which is exposed to high concentrations of photosynthetic oxygen and low levels of nutrients in its aquatic environment. Physiological studies of oxidative and starvation stresses in C. crescentus were undertaken through a study of lacZ fusion and null mutant strains constructed from the cloned 5' end of katG, encoding a catalase-peroxidase. The katG gene was shown to be solely responsible for catalase and peroxidase activity in C. crescentus. Like the katG of Escherichia coli, C. crescentus katG is induced by hydrogen peroxide and is important in sustaining the exponential growth rate. However, dramatic differences are seen in growth stage induction. E. coli KatE catalase and KatG catalase-peroxidase activities are induced 15- to 20-fold during exponential growth and then approximately halved in the stationary phase. In contrast, C. crescentus KatG activity is constant throughout exponential growth and is induced 50-fold in the stationary phase. Moreover, the survival of a C. crescentus katG null mutant is reduced by more than 3 orders of magnitude after 24 h in stationary phase and more than 6 orders of magnitude after 48 h, a phenotype not seen for E. coli katE and katG null mutants. These results indicate a major role for C. crescentus catalase-peroxidase in stationary-phase survival and raise questions about whether the peroxidatic activity as well as the protective catalatic activity of the dual-function enzyme is important in the response to starvation stress.

Novel dimeric interface and electrostatic recognition in bacterial Cu,Zn superoxide dismutase.

Eukaryotic Cu,Zn superoxide dismutases (CuZnSODs) are antioxidant enzymes remarkable for their unusually stable beta-barrel fold and dimer assembly, diffusion-limited catalysis, and electrostatic guidance of their free radical substrate. Point mutations of CuZnSOD cause the fatal human neurodegenerative disease amyotrophic lateral sclerosis. We determined and analyzed the first crystallographic structure (to our knowledge) for CuZnSOD from a prokaryote, Photobacterium leiognathi, a luminescent symbiont of Leiognathid fish. This structure, exemplifying prokaryotic CuZnSODs, shares the active-site ligand geometry and the topology of the Greek key beta-barrel common to the eukaryotic CuZnSODs. However, the beta-barrel elements recruited to form the dimer interface, the strategy used to forge the channel for electrostatic recognition of superoxide radical, and the connectivity of the intrasubunit disulfide bond in P. leiognathi CuZnSOD are discrete and strikingly dissimilar from those highly conserved in eukaryotic CuZnSODs. This new CuZnSOD structure broadens our understanding of structural features necessary and sufficient for CuZnSOD activity, highlights a hitherto unrecognized adaptability of the Greek key beta-barrel building block in evolution, and reveals that prokaryotic and eukaryotic enzymes diverged from one primordial CuZnSOD and then converged to distinct dimeric enzymes with electrostatic substrate guidance.

Periplasmic copper-zinc superoxide dismutase of Legionella pneumophila: role in stationary-phase survival.

Copper-zinc superoxide dismutases (CuZnSODs) are infrequently found in bacteria although widespread in eukaryotes. Legionella pneumophila, the causative organism of Legionnaires' disease, is one of a small number of bacterial species that contain a CuZnSOD, residing in the periplasm, in addition to an iron SOD (FeSOD) in their cytoplasm. To investigate CuZnSOD function, we purified the enzyme from wild-type L. pneumophila, obtained amino acid sequence data from isolated peptides, cloned and sequenced the gene from a L. pneumophila library, and then constructed and characterized a CuZnSOD null mutant. In contrast to the cytoplasmic FeSOD, the CuZnSOD of L. pneumophila is not essential for viability. However, CuZnSOD is critical for survival during the stationary phase of growth. The CuZnSOD null mutant survived 10(4)- to 10(6)-fold less than wild-type L. pneumophila. In wild-type L. pneumophila, the specific activity of CuZnSOD increased during the transition from exponential to stationary-phase growth while the FeSOD activity was constant. These data support a role of periplasmic CuZnSOD in survival of L. pneumophila during stationary phase. Since L. pneumophila survives extensive periods of dormancy between growth within hosts. CuZnSOD may contribute to the ability of this bacterium to be a pathogen. In exponential phase, wild-type and CuZnSOD null strains grew with comparable doubling times. In cultured HL-60 and THP-1 macrophage-like cell lines and in primary cultures of human monocytes, multiplication of the CuZnSOD null mutant was comparable to that of wild type. This indicated that CuZnSOD is not essential for intracellular growth within macrophages or for killing of macrophages in those systems.

Function and stationary-phase induction of periplasmic copper-zinc superoxide dismutase and catalase/peroxidase in Caulobacter crescentus.

Although cytosolic superoxide dismutases (SODs) are widely distributed among bacteria, only a small number of species contain a periplasmic SOD. One of these is Caulobacter crescentus, which has a copper-zinc SOD (CuZnSOD) in the periplasm and an iron SOD (FeSOD) in the cytosol. The function of periplasmic CuZnSOD was studied by characterizing a mutant of C. crescentus with an insertionally inactivated CuZnSOD gene. Wild-type and mutant strains showed identical tolerance to intracellular superoxide. However, in response to extracellular superoxide, the presence of periplasmic CuZnSOD increased survival by as much as 20-fold. This is the first demonstration that periplasmic SOD defends against external superoxide of environmental origin. This result has implications for those bacterial pathogens that contain a CuZnSOD. C. crescentus was shown to contain a single catalase/peroxidase which, like Escherichia coli KatG catalase/peroxidase, is present in both the periplasmic and cytoplasmic fractions. The growth stage dependence of C. crescentus catalase/peroxidase and SOD activity was studied. Although FeSOD activity was identical in exponential- and stationary-phase cultures, CuZnSOD was induced nearly 4-fold in stationary phase and the catalase/peroxidase was induced nearly 100-fold. Induction of antioxidant enzymes in the periplasm of C. crescentus appears to be an important attribute of the stationary-phase response and may be a useful tool for studying its regulation.

The Bcl-2 oncoprotein functions as a pro-oxidant.

The mechanism by which the bcl-2 oncogene exerts its anti-apoptotic and antioxidant action is unknown. We found that expression of bcl-2 in superoxide dismutase-deficient (SOD-) Escherichia coli resulted in increased transcription of the KatG catalase-peroxidase, a 13-fold increase in KatG activity and a 100-fold increase in resistance to hydrogen peroxide. In addition, mutation rate was increased 3-fold, and katG and oxyR, a transcriptional regulator of katG induction, were required for aerobic survival. These data indicate that Bcl-2 acts as a pro-oxidant in E. coli, i.e. Bcl-2 generates reactive oxygen intermediates. In support of a pro-oxidant mechanism in eukaryotic cells, we found a 73% increase in superoxide dismutase activity in a murine B-cell line overexpressing Bcl-2. Increases in reduced glutathione and in oxyradical damage to DNA, previously observed in other overexpressing cell lines, are additional evidence for a pro-oxidant mechanism. Thus, Bcl-2 does not appear to be an antioxidant. Instead, Bcl-2 appears to influence levels of reactive oxygen intermediates that induce endogenous cellular antioxidants. This activity of Bcl-2 may control entry into apoptosis.

The manganese superoxide dismutase of Escherichia coli K-12 associates with DNA.

Superoxide dismutases (SODs) are vital components in the resistance of aerobic organisms to the toxicity of oxygen. Escherichia coli contains two highly homologous cytoplasmic SODs, a manganese- and an iron-containing enzyme (MnSOD, FeSOD). We previously demonstrated that MnSOD and FeSOD have different physiological functions and that MnSOD is more effective in preventing oxidative damage to DNA. In this report, purified E. coli MnSOD was shown to bind nonspecifically to DNA by electrophoretic mobility shift assay and nitrocellulose-filter binding methodologies. From electrophoretic mobility shift assay, the equilibrium dissociation constants for interaction with a variety of double-stranded and single-stranded oligonucleotides ranged from 1.5 +/- 0.2 to 8.4 +/- 1.3 microM at 20 degrees C. This range of concentrations corresponds to MnSOD concentrations in aerobically grown E. coli. In vivo binding of MnSOD to DNA was supported by colocalization of MnSOD and the E. coli nucleoid in immunoelectron microscopy. Both MnSOD and DNA were inhomogeneously distributed in the cytosol, the concentration of each being higher in the center of the cell and relatively low near the inner membrane. In contrast, there was no evidence for physiologically relevant interaction of FeSOD with DNA. Binding to DNA in vitro was weak, Kd > 40-220 microM, concentrations 7-40 times higher than found in vivo. In addition, the cytoplasmic distribution of FeSOD did not correlate with DNA. FeSOD concentration was higher near the inner membrane and lower in the center of the cytosol. These results demonstrate that E. coli MnSOD associates with DNA in vitro and in vivo. Combined with prior data demonstrating that MnSOD preferentially protects DNA in vivo while an equal enzymatic activity of FeSOD does not (Hopkin, K. A., Papazian, M. A., and Steinman, H. M. (1992) J. Biol. Chem. 267, 24253-24258), our data suggest that E. coli MnSOD acts as a "tethered antioxidant"; association of MnSOD with DNA localizes dismutase activity near a target of oxidative stress and increases protection of DNA from oxidative damage. This model has implications for the therapeutic use of SODs as antioxidants.

The iron superoxide dismutase of Legionella pneumophila is essential for viability.

Legionella pneumophila, the causative agent of Legionnaires' disease, contains two superoxide dismutases (SODs), a cytoplasmic iron enzyme (FeSOD) and a periplasmic copper-zinc SOD. To study the role of the FeSOD in L. pneumophila, the cloned FeSOD gene (sodB) was inactivated with Tn903dIIlacZ, forming a sodB::lacZ gene fusion. By using this fusion, expression of sodB was shown to be unaffected by a variety of conditions, including several that influence sod expression in Escherichia coli: aeration, oxidants, the redox cycling compound paraquat, manipulation of iron levels in the medium, and the stage of growth. A reproducible twofold decrease in sodB expression was found during growth on agar medium containing charcoal, a potential scavenger of oxyradicals, in comparison with growth on the same medium without charcoal. No induction was seen during growth in human macrophages. Additional copies of sodB+ in trans increased resistance to paraquat. Construction of a sodB mutant was attempted by allelic exchange of the sodB::lacZ fusion with the chromosomal copy of sodB. The mutant could not be isolated, and the allelic exchange was possible only if wild-type sodB was present in trans. These results indicate that the periplasmic copper-zinc SOD cannot replace the FeSOD. The data strongly suggest that sodB is an essential gene and that FeSOD is required for the viability of L. pneumophila. In contrast, Sod- mutants of E. coli and Streptococcus mutans grow aerobically and SOD is not required for viability in these species.

Function of periplasmic copper-zinc superoxide dismutase in Caulobacter crescentus.

Caulobacter crescentus is one of a small number of bacterial species that contain a periplasmic copper-zinc superoxide dismutase (CuZnSOD). A C. crescentus mutant, with the CuZnSOD gene interrupted by a promoterless cat gene, was constructed and characterized to analyze CuZnSOD function. Periplasmic SOD does not protect against oxyradical damage in the cytosol or play a major role in maintaining the integrity of the cell envelope. Studies of the effect of sodium citrate on plating efficiency suggest that CuZnSOD protects a periplasmic or membrane function(s) requiring magnesium or calcium.

Functional differences between manganese and iron superoxide dismutases in Escherichia coli K-12.

Superoxide dismutases are enzymes that defend against oxidative stress through decomposition of superoxide radical. Escherichia coli contains two highly homologous superoxide dismutases, one containing manganese (MnSOD) and the other iron (FeSOD). Although E. coli Mn and FeSOD catalyze the dismutation of superoxide with comparable rate constants, it is not known if they are physiologically equivalent in their protection of cellular targets from oxyradical damage. To address this issue, isogenic strains of E. coli containing either Mn or FeSOD encoded on a plasmid and under the control of tac promoter were constructed. SOD specific activity in the Mn and FeSOD strains could be controlled by the concentration of isopropyl beta-thiogalactoside in the medium. The tolerance of these strains to oxidative stress was compared at equal Mn and FeSOD specific activities. Our results indicate that E. coli Mn and FeSOD are not functionally equivalent. The MnSOD is more effective than FeSOD in preventing damage to DNA, while the FeSOD appears to be more effective in protecting a cytoplasmic superoxide-sensitive enzyme. These data are the first demonstration that Mn and FeSOD are adapted to different antioxidant roles in E. coli.

Construction of an Escherichia coli K-12 strain deleted for manganese and iron superoxide dismutase genes and its use in cloning the iron superoxide dismutase gene of Legionella pneumophila.

An Escherichia coli K-12 strain deleted for sodA and sodB (manganese and iron superoxide dismutases) was constructed and characterized by Southern blotting, enzyme assays, and physiological analyses. The sod deletion strain was used to clone the iron superoxide dismutase gene of Legionella pneumophila by complementation to paraquat resistance.

Copper-zinc superoxide dismutase of Caulobacter crescentus: cloning, sequencing, and mapping of the gene and periplasmic location of the enzyme.

Although widely found in the cytoplasm of eucaryotes, the copper-zinc form of superoxide dismutase (CuZnSOD) has been identified in only a small number of bacterial species. One species is the freshwater bacterium Caulobacter crescentus, which also contains an SOD with iron as the metal cofactor (FeSOD). To investigate the function of this CuZnSOD and its structural relationship to the eucaryotic CuZnSODs, the gene encoding CuZnSOD (sodC) of C. crescentus CB15 was cloned and sequenced. By hybridization to pulsed-field electrophoresis gels, sodC was mapped near cysE in the C. crescentus chromosome. Through analysis of spheroplasts, the two SODs of C. crescentus were shown to be differently localized, CuZnSOD in the periplasm and FeSOD in the cytoplasm. In its natural habitat, C. crescentus is frequently associated with blue-green algae (cyanobacteria). The oxygen evolved by these photosynthetic algae may create an extracellular oxidative stress against which the periplasmic CuZnSOD may defend more effectively than the cytoplasmic FeSOD. Amino acid sequence alignments of C. crescentus CuZnSOD with eucaryotic CuZnSODs and with CuZnSOD of Photobacterium leiognathi (the only other bacterium from which CuZnSOD has been isolated and sequenced) suggest similar supersecondary structures for bacterial and eucaryotic CuZnSODs but reveal four novel substitutions in C. crescentus CuZnSOD: a phenylalanine critical to intrasubunit hydrophobic bonding replaced by alanine, a histidine ligand of zinc replaced by aspartate, and substitutions of two other previously invariant residues that stabilize zinc or both copper and zinc. These amino acid substitutions in C. crescentus CuZnSOD may have implications for its catalysis and stability.

Crystallographic characterization of a Cu,Zn superoxide dismutase from Photobacterium leiognathi.

Crystals of a copper-zinc superoxide dismutase from Photobacterium leiognathi, a luminescent marine bacterium that is the species-specific symbiont of the ponyfish, have been obtained from 2-methyl-2,4-pentanediol solutions. The space group was determined using screenless small-angle precession photographs, and was confirmed by analyzing area detector diffraction data with the XENGEN programs for indexing and refinement. The crystals are monoclinic, space group C2 (a = 126.4 A, b = 87.0 A, c = 44.4 A, beta = 92.8 A), and have two 32,000 Mr dimers per asymmetric unit. The crystals diffract to at least 2.7 A resolution, are resistant to radiation damage, and are suitable for determination of the structure by X-ray diffraction.

Iron superoxide dismutase. Nucleotide sequence of the gene from Escherichia coli K12 and correlations with crystal structures.

The nucleotide sequence of the iron superoxide dismutase gene from Escherichia coli K12 has been determined. Analysis of the DNA sequence and mapping of the mRNA start reveal a unique promoter and a putative rho-independent terminator, and suggest that the Fe dismutase gene constitutes a monocistronic operon. The gene encodes a polypeptide product consisting of 192 amino acid residues with a calculated Mr of 21,111. The published N-terminal amino acid sequence of E. coli B Fe dismutase (Steinman, H. M., and Hill, R. L. (1973) Proc. Natl. Acad. Sci. U.S.A. 70, 3725-3729), along with the sequences of seven other peptides reported here, was located in the primary structure deduced from the K12 E. coli gene sequence. A new molecular model for iron dismutase from E. coli, based on the DNA sequence and x-ray data for the E. coli B enzyme at 3.1 A resolution, allows detailed comparison of the structure of the iron enzyme with manganese superoxide dismutase from Thermus thermophilus HB8. The structural similarities are more extensive than indicated by earlier studies and are particularly striking in the vicinity of the metal-ligand cluster, which is surrounded by conserved aromatic residues. The combined structural and sequence information now available for a series of Mn and Fe superoxide dismutases identifies variable regions in these otherwise very similar molecules; the principal variable site occurs in a surface region between the two long helices which dominate the N-terminal domain.

Bacteriocuprein superoxide dismutase of Photobacterium leiognathi. Isolation and sequence of the gene and evidence for a precursor form.

The gene encoding the bacteriocuprein superoxide dismutase from Photobacterium leiognathi, American Type Culture Collection strain 25521, was cloned in a pUC12 vector and sequenced. The nucleotide sequence predicted a 22-residue leader peptide amino-terminal to the known bacteriocuprein sequence. The expected precursor bacteriocuprein was directly identified in the in vitro translation products of the cloned gene by polyacrylamide gel electrophoresis and automated Edman degradation. Enzymatically active bacteriocuprein that lacked the leader peptide was identified in sonic extracts of Escherichia coli hosts containing the cloned gene. A single transcript of 580 nucleotides was observed in blots of total P. leiognathi RNA, and a unique site of transcriptional initiation was identified by primer extension analysis. P. leiognathi bacteriocuprein is the first bacteriocuprein whose gene has been isolated and sequenced and the first copper-zinc superoxide dismutase in which a leader peptide has been found. The presence of a leader peptide suggests that the bacteriocuprein is localized in the membrane or periplasm, in contrast to the eukaryotic copper-zinc superoxide dismutases, which are cytoplasmic enzymes. Such a difference in intracellular location could be important for understanding the presence and function of the uncommon, bacteriocuprein superoxide dismutase in P. leiognathi.