Nitroreductase II involved in 2,4,6-trinitrotoluene degradation: Purification and characterization from <Emphasis Type="Italic">Klebsiella</Emphasis> sp. Cl

Three 2,4,6-trinitrotoluene (TNT) nitroreductases from Klebsiella sp. CI have different reduction capabilities that can degrade TNT by simultaneous utilization of two initial reduction pathways. Of these, nitroreductase II was purified to homogeneity by sequential chromatographies. Nitroreductase II is an oxygen-insensitive enzyme and reduces both TNT and nitroblue tetrazolium. The N-terminal amino acid sequence of the enzyme did not show any sequence similarity with those of other nitroreductases reported. However, it transformed TNT by the reduction of nitro groups like nitroreductase I. It had a higher substrate affinity and specific activity for TNT reduction than other nitroreductases, and it showed a higher oxidation rate of NADPH with the ortho-substituted isomers of TNT metabolites (2-hydroxylaminodinitrotoluene and 2-aminodinitrotoluene) than with para-substituted compounds (4-hydroxylaminodinitrotoluene and 4-amino-dinitrotoluene).     

Purification and characterization of the NAD(P)H-nitroreductase for the catabolism of 2,4,6-trinitrotoluene (TNT) in<Emphasis Type="Italic">Pseudomonas</Emphasis> sp. HK-6

The NAD(P)H-nitroreductase of thePseudomonas sp. HK-6 which is capable of catabolizing 2,4,6-trinitrotoluene (TNT), was purified and biochemically characterized. The specific activity of the purified TNT nitroreductase was approximately 1.47 units/mg, and was concentrated to 10.1-fold compared to the crude extract. The optimal temperature and pH of the highest nitroreductase activity was 30°C and 7.5, respectively. The substrate specificity test revealed that the nitroreductase exhibited the highest enzyme activity for the TNT substrate of the nitroaromatic compounds tested in this study. Moreover, the molecular weight of the TNT nitroreductase was approximately 27 kDa on the SDS-PAGE. The N-terminal amino acid sequence of the purified protein was 5′-MDTVSLAKRRYTTKAYDASR, which is identical topnrB ofPseudomonas putida JLR11, and is capable of TNT reduction. The molecular analysis of the approximately 650-bp PCR product, orginating from the HK-6, revealed that the oxygen-insensitive NAD(P)H-nitroreductase gene, which transforms TNT in strain HK-6 with five unique amino acid sequences and diverges from the nitroreductases identified so far inPseudomonas, Burkholderia, andRalstonia, is frequently found amidst the powerful degraders of aromatic compounds.     

Conversion of NfsA, the Major Escherichia coli Nitroreductase, to a Flavin Reductase with an Activity Similar to That of Frp, a Flavin Reductase in Vibrio harveyi, by a Single Amino Acid Substitution

NfsA is the major oxygen-insensitive nitroreductase of Escherichia coli, similar in amino acid sequence to Frp, a flavin reductase of Vibrio harveyi. Here, we show that a single amino acid substitution at position 99, which may destroy three hydrogen bonds in the putative active center, transforms NfsA from a nitroreductase into a flavin reductase that is as active as the authentic Frp and a tartrazine reductase that is 30-fold more active than wild-type NfsA.     

Biochemical characterization of NfsA, the Escherichia coli major nitroreductase exhibiting a high amino acid sequence homology to Frp, a Vibrio harveyi flavin oxidoreductase.

We identified the nfsA gene, encoding the major oxygen-insensitive nitroreductase in Escherichia coli, and determined its position on the E. coli map to be 19 min. We also purified its gene product, NfsA, to homogeneity. It was suggested that NfsA is a nonglobular protein with a molecular weight of 26,799 and is associated tightly with a flavin mononucleotide. Its amino acid sequence is highly similar to that of Frp, a flavin oxidoreductase from Vibrio harveyi (B. Lei, M. Liu, S. Huang, and S.-C. Tu, J. Bacteriol. 176:3552-3558, 1994), an observation supporting the notion that E. coli nitroreductase and luminescent-bacterium flavin reductase families are intimately related in evolution. Although no appreciable sequence similarity was detected between two E. coli nitroreductases, NfsA and NfsB, NfsA exhibited a low level of the flavin reductase activity and a broad electron acceptor specificity similar to those of NfsB. NfsA reduced nitrofurazone by a ping-pong Bi-Bi mechanism possibly to generate a two-electron transfer product.     

Purification and characterization of NAD(P)H-dependent nitroreductase I from Klebsiella sp. C1 and enzymatic transformation of 2,4,6-trinitrotoluene

Three NAD(P)H-dependent nitroreductases that can transform 2,4,6-trinitrotoluene (TNT) by two reduction pathways were detected in Klebsiella sp. C1. Among these enzymes, the protein with the highest reduction activity of TNT (nitroreductase I) was purified to homogeneity using ion-exchange, hydrophobic interaction, and size exclusion chromatographies. Nitroreductase I has a molecular mass of 27 kDa as determined by SDS-PAGE, and exhibits a broad pH optimum between 5.5 and 6.5, with a temperature optimum of 30–40°C. Flavin mononucleotide is most likely the natural flavin cofactor of this enzyme. The N-terminal amino acid sequence of this enzyme does not show a high degree of sequence similarity with nitroreductases from other enteric bacteria. This enzyme catalyzed the two-electron reduction of several nitroaromatic compounds with very high specific activities of NADPH oxidation. In the enzymatic transformation of TNT, 2-amino-4,6-dinitrotoluene and 2,2′,6,6′-tetranitro-4,4′-azoxytoluene were detected as transformation products. Although this bacterium utilizes the direct ring reduction and subsequent denitration pathway together with a nitro group reduction pathway, metabolites in direct ring reduction of TNT could not easily be detected. Unlike other nitroreductases, nitroreductase I was able to transform hydroxylaminodinitrotoluenes (HADNT) into aminodinitrotoluenes (ADNT), and could reduce ortho isomers (2-HADNT and 2-ADNT) more easily than their para isomers (4-HADNT and 4-ADNT). Only the nitro group in the ortho position of 2,4-DNT was reduced to produce 2-hydroxylamino-4-nitrotoluene by nitroreductase I; the nitro group in the para position was not reduced.     

Evaluation of NfsA-like nitroreductases from <Emphasis Type="Italic">Neisseria meningitidis</Emphasis> and <Emphasis Type="Italic">Bartonella henselae</Emphasis> for enzyme-prodrug therapy,targeted cellular ablation,and dinitrotoluene bioremediation

Objectives

To characterize the activities of two candidate nitroreductases, Neisseria meningitidis NfsA (NfsA_Nm) and Bartonella henselae (PnbA_Bh), with the nitro-prodrugs, CB1954 and metronidazole, and the environmental pollutants 2,4- and 2,6-dinitrotoluene.

Results

NfsA_Nm and PnbA_Bh were evaluated in Escherichia coli over-expression assays and as His₆-tagged proteins in vitro. With the anti-cancer prodrug CB1954, both enzymes were more effective than the canonical O₂-insensitive nitroreductase E. coli NfsB (NfsB_Ec), NfsA_Nm exhibiting comparable levels of activity to the leading nitroreductase candidate E. coli NfsA (NfsA_Ec). NfsA_Nm is also the first NfsA-family nitroreductase shown to produce a substantial proportion of 4-hydroxylamine end-product. NfsA_Nm and PnbA_Bh were again more efficient than NfsB_Ec at aerobic activation of metronidazole to a cytotoxic form, with NfsA_Nm appearing a promising candidate for improving zebrafish-targeted cell ablation models. NfsA_Nm was also more active than either NfsA_Ec or NfsB_Ec with 2,4- or 2,6-dinitrotoluene substrates, whereas PnbA_Bh was relatively inefficient with either substrate.

Conclusions

NfsA_Nm is a promising new nitroreductase candidate for several diverse biotechnological applications.

     

Oxygen-Insensitive Nitroreductases NfsA and NfsB of Escherichia coli Function under Anaerobic Conditions as Lawsone-Dependent Azo Reductases

Quinones can function as redox mediators in the unspecific anaerobic reduction of azo compounds by various bacterial species. These quinones are enzymatically reduced by the bacteria and the resulting hydroquinones then reduce in a purely chemical redox reaction the azo compounds outside of the cells. Recently, it has been demonstrated that the addition of lawsone (2-hydroxy-1,4-naphthoquinone) to anaerobically incubated cells of Escherichia coli resulted in a pronounced increase in the reduction rates of different sulfonated and polymeric azo compounds. In the present study it was attempted to identify the enzyme system(s) responsible for the reduction of lawsone by E. coli and thus for the lawsone-dependent anaerobic azo reductase activity. An NADH-dependent lawsone reductase activity was found in the cytosolic fraction of the cells. The enzyme was purified by column chromatography and the amino-terminal amino acid sequence of the protein was determined. The sequence obtained was identical to the sequence of an oxygen-insensitive nitroreductase (NfsB) described earlier from this organism. Subsequent biochemical tests with the purified lawsone reductase activity confirmed that the lawsone reductase activity detected was identical with NfsB. In addition it was proven that also a second oxygen-insensitive nitroreductase of E. coli (NfsA) is able to reduce lawsone and thus to function under adequate conditions as quinone-dependent azo reductase.     

Vibrio harveyi Nitroreductase Is Also a Chromate Reductase

The chromate reductase purified from Pseudomonas ambigua was found to be homologous with several nitroreductases. Escherichia coli DH5α and Vibrio harveyi KCTC 2720 nitroreductases were chosen for the present study, and their chromate-reducing activities were determined. A fusion between glutathione S-transferase (GST) and E. coli DH5α NfsA (GST-EcNfsA), a fusion between GST and E. coli DH5α NfsB (GST-EcNfsB), and a fusion between GST and V. harveyi KCTC 2720 NfsA (GST-VhNfsA) were prepared for their overproduction and easy purification. GST-EcNfsA, GST-EcNFsB, and GST-VhNFsA efficiently reduced nitrofurazone and 2,4,6-trinitrotoluene (TNT) as their nitro substrates. The K_m values for GST-EcNfsA, GST-EcNfsB, and GST-VhNfsA for chromate reduction were 11.8, 23.5, and 5.4 μM, respectively. The V_max values for GST-EcNfsA, GST-EcNfsB, and GST-VhNfsA were 3.8, 3.9, and 10.7 nmol/min/mg of protein, respectively. GST-VhNfsA was the most effective of the three chromate reductases, as determined by each V_max/K_m value. The optimal temperatures of GST-EcNfsA, GST-EcNfsB, and GST-VhNfsA for chromate reduction were 55, 30, and 30°C, respectively. Thus, it is confirmed that nitroreductase can also act as a chromate reductase. Nitroreductases may be used in chromate remediation. GST-EcNfsA, GST-EcNfsB, and GST-VhNfsA have a molecular mass of 50 kDa and exist as a monomer in solution. Thin-layer chromatography showed that GST-EcNfsA, GST-EcNfsB, and GST-VhNfsA contain FMN as a cofactor. GST-VhNfsA reduced Cr(VI) to Cr(III). Cr(III) was much less toxic to E. coli than Cr(VI).     

Residue Phe42 is critical for the catalytic activity of Escherichia coli major nitroreductase NfsA

The major O₂-insensitive nitroreductase (NfsA) of Escherichia coli shares low sequence homology but similar biochemical and structural features with NfsB, the E. coli minor O₂-insensitive nitroreductase. A structural comparison revealed Phe42 was present in the active site of NfsA but not NfsB. F42Y, F42N and F42A were generated and had decreased activity toward nitrofurazone by 52, 96, and 99 %, respectively. The kinetic parameters for other nitroaromatic substrates were also determined. Compared to wild type, the mutants did not have significantly altered K _ms, but had dramatically decreased k _cat and k _cat/K _m values. Far-UV CD spectral analysis of the mutants suggested that there were no significant conformational changes however F42A and F42N had changes from 208 to 222 nm, which was attributed to loss of helix content. These findings revealed that Phe42 is important for maintaining NfsA activity and structure.     

Expression and Characterization of the TNT Nitroreductase of <Emphasis Type="Italic">Pseudomonas</Emphasis> sp. HK-6 in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Pseudomonas sp. HK-6 is able to utilize 2,4,6-trinitrotoluene (TNT) as a sole nitrogen source. The pnrB gene of the HK-6 strain was cloned using degenerate primers synthesized on the basis of the sequence information of the terminal amino acids of a previously purified native TNT nitroreductase. The nucleotide sequence of pnrB was 654 bp long, and its deduced polypeptide sequence was composed of 217 amino acid residues with a predicted molecular mass of 24 kDa. To facilitate the purification and characterization of this enzyme, an Escherichia expression plasmid harboring six histidine residues fused to a pnrB gene was constructed (His6-PnrB) and designated pPSC1. The His6-PnrB induced in E. coli BL21 was purified using a nickel affinity column to homogeneity. Its enzymatic activity was assayed by measuring absorbance changes at 340 nm due to NADH oxidation. The V _max and K _m values of the enzyme for TNT were 12.6 μmol/min/mg protein and 2.9 mM, respectively. In addition, the pnrB knockout mutant was constructed via a single-crossover homologous recombination with a partial pnrB DNA fragment that lacked both start and stop codons. Eight days was required for complete degradation of 0.5 mM TNT by the wild-type HK-6 strain, whereas the pnrB mutant degraded only 10% of the TNT in the same time period. Even after 20 days, only approximately 50% of the 0.5 mM TNT was degraded by the pnrB mutant. These results illustrate that pnrB may perform a crucial role in the TNT degradation pathway of the HK-6 strain.     

Oxygen-Insensitive Nitroreductases: Analysis of the Roles of nfsA and nfsB in Development of Resistance to 5-Nitrofuran Derivatives in Escherichia coli

Nitroheterocyclic and nitroaromatic compounds constitute an enormous range of chemicals whose potent biological activity has significant human health and environmental implications. The biological activity of nitro-substituted compounds is derived from reductive metabolism of the nitro moiety, a process catalyzed by a variety of nitroreductase activities. Resistance of bacteria to nitro-substituted compounds is believed to result primarily from mutations in genes encoding oxygen-insensitive nitroreductases. We have characterized the nfsA and nfsB genes of a large number of nitrofuran-resistant mutants of Escherichia coli and have correlated mutation with cell extract nitroreductase activity. Our studies demonstrate that first-step resistance to furazolidone or nitrofurazone results from an nfsA mutation, while the increased resistance associated with second-step mutants is a consequence of an nfsB mutation. Inferences made from mutation about the structure-function relationships of NfsA and NfsB are discussed, especially with regard to the identification of flavin mononucleotide binding sites. We show that expression of plasmid-carried nfsA and nfsB genes in resistant mutants restores sensitivity to nitrofurans. Among the 20 first-step and 53 second-step mutants isolated in this study, 65 and 49%, respectively, contained insertion sequence elements in nfsA and nfsB. IS1 integrated in both genes, while IS30 and IS186 were found only in nfsA and IS2 and IS5 were observed only in nfsB. Insertion hot spots for IS30 and IS186 are indicated in nfsA, and a hot spot for IS5 insertion is evident in nfsB. We discuss potential regional and sequence-specific determinants for insertion sequence element integration in nfsA and nfsB.     

Azoreductase from <Emphasis Type="Italic">Rhodobacter sphaeroides</Emphasis> AS1.1737 is a flavodoxin that also functions as nitroreductase and flavin mononucleotide reductase

Previously reported azoreductase (AZR) from Rhodobacter sphaeroides AS1.1737 was shown to be a flavodoxin possessing nitroreductase and flavin mononucleotide (FMN) reductase activities. The structure model of AZR constructed with SWISS-MODEL displayed a flavodoxin-like fold with a three-layer α/β/α structure. With nitrofurazone as substrate, the optimal pH value and temperature were 7.0 and 50°C, respectively. AZR could reduce a number of nitroaromatic compounds including 2,4-dinitrotoluene, 2,6-dinitrotoluene, 3,5-dinitroaniline, and 2,4,6-trinitrotoluene (TNT). TNT resulted to be the most efficient nitro substrate and was reduced to hydroxylamino-dinitrotoluene. Both NADH and NADPH could serve as electron donors of AZR, where the latter was preferred. Externally added FMN was also reduced by AZR via ping-pong mechanism and was a competitive inhibitor of NADPH, methyl red, and nitrofurazone. AZR with broad substrate specificity is a member of a new nitro/FMN reductase family demonstrating potential application in bioremediation.     

Type I nitroreductases in soil enterobacteria reduce TNT (2,4,6,-trinitrotoluene) and RDX (hexahydro-1,3,5-trinitro-1,3,5-triazine)

Many enteric bacteria express a type I oxygen-insensitive nitroreductase, which reduces nitro groups on many different nitroaromatic compounds under aerobic conditions. Enzymatic reduction of nitramines was also documented in enteric bacteria under anaerobic conditions. This study indicates that nitramine reduction in enteric bacteria is carried out by the type I, or oxygen-insensitive nitroreductase, rather than a type II enzyme. The enteric bacterium Morganella morganii strain B2 with documented hexahydro-1,3,5-trinitro-1,3,5-triazine (RDX) nitroreductase activity, and Enterobacter cloacae strain 96-3 with documented 2,4,6-trinitrotoluene (TNT) nitroreductase activity, were used here to show that the explosives TNT and RDX were both reduced by a type I nitroreductase. Morganella morganii and E. cloacae exhibited RDX and TNT nitroreductase activities in whole cell assays. Type I nitroreductase, purified from E. cloacae, oxidized NADPH with TNT or RDX as substrate. When expression of the E. cloacae type I nitroreductase gene was induced in an Escherichia coli strain carrying a plasmid, a simultaneous increase in TNT and RDX nitroreductase activities was observed. In addition, neither TNT nor RDX nitroreductase activity was detected in nitrofurazone-resistant mutants of M. morganii. We conclude that a type I nitroreductase present in these two enteric bacteria was responsible for the nitroreduction of both types of explosive.     

Purification and characterization of 1-nitropyrene nitroreductases from Bacteroides fragilis.

We isolated four nitroreductases from Bacteroides fragilis GAI0624 and examined their physicochemical and functional properties. Two major enzyme activities were found in the adsorbed and unadsorbed fractions from DEAE-cellulose column chromatography. The adsorbed fraction was subjected to Sephadex G-200 column chromatography, and two further activities were separated. One has high nitroreductase activity (nitroreductase I), and the other has low activity and relatively high molecular weight (nitroreductase III). The nitroreductase I fraction was subjected to hydroxylapatite and chromatofocusing column chromatography, and nitroreductase I was purified about 416-fold with a yield of 6.77%. The unadsorbed fraction from DEAE-cellulose column chromatography was subjected to Sepharose 2B and Sepharose 6B column chromatography. Two enzyme activities were obtained by the Sepharose 6B column chromatography. One has high activity (nitroreductase II), and the other has low activity (nitroreductase IV). Nitroreductase II was rechromatographed by Sepharose 6B gel filtration and purified about 178-fold with a yield of 9.65%. The four enzymes (nitroreductases I, II, III, and IV) were shown to be different by several criteria. Their molecular weights, determined by gel filtration, were 52,000, 320,000, 180,000, and 680,000, respectively. The substrate specificity, the effect on mutagenicity of mutagenic nitro compounds, of nitroreductases I, III, and IV was relatively high for 1-nitropyrene, dinitropyrenes, and 4-nitroquinoline 1-oxide, respectively, but nitroreductase II had broad specificity. Nitroreductase activity required a coenzyme; nitroreductases II, III, and IV were NADPH linked, but nitroreductase I was NADH linked. All enzyme activity was enhanced by addition of flavin mononucleotide and inhibited significantly by dicumarol, p-chloromercuribenzoic acid, o-iodosobenzoic acid, sodium azide, and Cu2+.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification and characterization of 1-nitropyrene nitroreductases from Bacteroides fragilis

We isolated four nitroreductases from Bacteroides fragilis GAI0624 and examined their physicochemical and functional properties. Two major enzyme activities were found in the adsorbed and unadsorbed fractions from DEAE-cellulose column chromatography. The adsorbed fraction was subjected to Sephadex G-200 column chromatography, and two further activities were separated. One has high nitroreductase activity (nitroreductase I), and the other has low activity and relatively high molecular weight (nitroreductase III). The nitroreductase I fraction was subjected to hydroxylapatite and chromatofocusing column chromatography, and nitroreductase I was purified about 416-fold with a yield of 6.77%. The unadsorbed fraction from DEAE-cellulose column chromatography was subjected to Sepharose 2B and Sepharose 6B column chromatography. Two enzyme activities were obtained by the Sepharose 6B column chromatography. One has high activity (nitroreductase II), and the other has low activity (nitroreductase IV). Nitroreductase II was rechromatographed by Sepharose 6B gel filtration and purified about 178-fold with a yield of 9.65%. The four enzymes (nitroreductases I, II, III, and IV) were shown to be different by several criteria. Their molecular weights, determined by gel filtration, were 52,000, 320,000, 180,000, and 680,000, respectively. The substrate specificity, the effect on mutagenicity of mutagenic nitro compounds, of nitroreductases I, III, and IV was relatively high for 1-nitropyrene, dinitropyrenes, and 4-nitroquinoline 1-oxide, respectively, but nitroreductase II had broad specificity. Nitroreductase activity required a coenzyme; nitroreductases II, III, and IV were NADPH linked, but nitroreductase I was NADH linked. All enzyme activity was enhanced by addition of flavin mononucleotide and inhibited significantly by dicumarol, p-chloromercuribenzoic acid, o-iodosobenzoic acid, sodium azide, and Cu2+.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification and characterization of an oxygen-insensitive NAD(P)H nitroreductase from Enterobacter cloacae

The reductive products of several nitroaromatic compounds have been found to be toxic, mutagenic, and carcinogenic. The nitroreductases present in intestinal microflora have been implicated in the biotransformation of these compounds to their deleterious metabolites. A "classical" nitroreductase has been purified from Enterobacter cloacae 587-fold using a protocol which yields approximately 1 mg of purified nitroreductase from 10 liters of cell culture. An analysis of the physical properties of the nitroreductase indicates that the enzyme is active as a monomer with a calculated molecular mass of 27 kDa. FMN has been identified as a required flavin cofactor and is present at a stoichiometry of 0.88 mol of FMN bound/mol of active enzyme. The enzyme was found capable of reducing nitrofurazone under aerobic conditions indicating that the mechanism involves an obligatory two-electron transfer. Thus, this enzyme can be classified as an oxygen-insensitive nitroreductase. The purified nitroreductase can utilize either NADH or NADPH as a source of reducing equivalents and can reduce a variety of nitroaromatic compounds including nitrofurans and nitrobenzenes as well as quinones. Studies in which the rates of nitroreduction for a series of para substituted nitrobenzene derivatives were determined suggest that a linear free energy relationship exists between the rate and the redox midpoint potential of the substrate.     

Vibrio harveyi nitroreductase is also a chromate reductase

The chromate reductase purified from Pseudomonas ambigua was found to be homologous with several nitroreductases. Escherichia coli DH5alpha and Vibrio harveyi KCTC 2720 nitroreductases were chosen for the present study, and their chromate-reducing activities were determined. A fusion between glutathione S-transferase (GST) and E. coli DH5alpha NfsA (GST-EcNfsA), a fusion between GST and E. coli DH5alpha NfsB (GST-EcNfsB), and a fusion between GST and V. harveyi KCTC 2720 NfsA (GST-VhNfsA) were prepared for their overproduction and easy purification. GST-EcNfsA, GST-EcNFsB, and GST-VhNFsA efficiently reduced nitrofurazone and 2,4,6-trinitrotoluene (TNT) as their nitro substrates. The K(m) values for GST-EcNfsA, GST-EcNfsB, and GST-VhNfsA for chromate reduction were 11.8, 23.5, and 5.4 micro M, respectively. The V(max) values for GST-EcNfsA, GST-EcNfsB, and GST-VhNfsA were 3.8, 3.9, and 10.7 nmol/min/mg of protein, respectively. GST-VhNfsA was the most effective of the three chromate reductases, as determined by each V(max)/K(m) value. The optimal temperatures of GST-EcNfsA, GST-EcNfsB, and GST-VhNfsA for chromate reduction were 55, 30, and 30 degrees C, respectively. Thus, it is confirmed that nitroreductase can also act as a chromate reductase. Nitroreductases may be used in chromate remediation. GST-EcNfsA, GST-EcNfsB, and GST-VhNfsA have a molecular mass of 50 kDa and exist as a monomer in solution. Thin-layer chromatography showed that GST-EcNfsA, GST-EcNfsB, and GST-VhNfsA contain FMN as a cofactor. GST-VhNfsA reduced Cr(VI) to Cr(III). Cr(III) was much less toxic to E. coli than Cr(VI).     

Molecular cloning,characterization and expression of a nitrofuran reductase gene ofescherichia coli

Mini-mu derivatives carrying plasmid replicons can be used to clone genesin vivo. This method was adopted to generate phasmid clones which were later screened for their ability of restore nitrofurantoin sensitivity of a nitrofuran-resistant host by eliciting nitroreductase activity. One phasmid-derived clone (pAJ101) resulted in considerable increase in nitroreductase activity when introduced into a nitrofurantoin-resistant mutant ofEscherichia coli with reduced nitroreductase activity. Subsequently, a 1.8 kb fragment obtained from pAJ101 by partial digestion with 5au3A, was subcloned into pUC18 to yield pAJ102. The nitroreductase activity attributable to pAJ102 was capable of reducing both nitrofurantoin and nitrofurazone. The polypeptides encoded by pAJ102 were identified by the minicell method. A large, well-defined band corresponding to 37 kDa and a smaller, less-defined band corresponding to 35 kDa were detected. Tnl000 mutagenesis was used to delineate the coding segment of the 1.8 kb insert of pAJ102. A 0.8 kb stretch of DNA was shown to be part of the nitroreductase gene. The gene was mapped at 19 min on theEscherichia coli linkage map.     

Regulation and Characterization of Two Nitroreductase Genes, nprA and nprB, of Rhodobacter capsulatus

Among photosynthetic bacteria, strains B10 and E1F1 of Rhodobacter capsulatus photoreduce 2,4-dinitrophenol (DNP), which is stoichiometrically converted into 2-amino-4-nitrophenol by a nitroreductase activity. The reduction of DNP is inhibited in vivo by ammonium, which probably acts at the level of the DNP transport system and/or physiological electron transport to the nitroreductase, since this enzyme is not inhibited by ammonium in vitro. Using the complete genome sequence data for strain SB1003 of R. capsulatus, two putative genes coding for possible nitroreductases were isolated from R. capsulatus B10 and disrupted. The phenotypes of these mutant strains revealed that both genes are involved in the reduction of DNP and code for two major nitroreductases, NprA and NprB. Both enzymes use NAD(P)H as the main physiological electron donor. The nitroreductase NprA is under ammonium control, whereas the nitroreductase NprB is not. In addition, the expression of the nprB gene seems to be constitutive, whereas nprA gene expression is inducible by a wide range of nitroaromatic and heterocyclic compounds, including several dinitroaromatics, nitrofuran derivatives, CB1954, 2-aminofluorene, benzo[a]pyrene, salicylic acid, and paraquat. The identification of two putative mar/sox boxes in the possible promoter region of the nprA gene and the induction of nprA gene expression by salicylic acid and 2,4-dinitrophenol suggest a role in the control of the nprA gene for the two-component MarRA regulatory system, which in Escherichia coli controls the response to some antibiotics and environmental contaminants. In addition, upregulation of the nprA gene by paraquat indicates that this gene is probably a member of the SoxRS regulon, which is involved in the response to stress conditions in other bacteria.     

Structure and Function of CinD (YtjD) of Lactococcus lactis,a Copper-Induced Nitroreductase Involved in Defense against Oxidative Stress

In Lactococcus lactis IL1403, 14 genes are under the control of the copper-inducible CopR repressor. This so-called CopR regulon encompasses the CopR regulator, two putative CPx-type copper ATPases, a copper chaperone, and 10 additional genes of unknown function. We addressed here the function of one of these genes, ytjD, which we renamed cinD (copper-induced nitroreductase). Copper, cadmium, and silver induced cinD in vivo, as shown by real-time quantitative PCR. A knockout mutant of cinD was more sensitive to oxidative stress exerted by 4-nitroquinoline-N-oxide and copper. Purified CinD is a flavoprotein and reduced 2,6-dichlorophenolindophenol and 4-nitroquinoline-N-oxide with k_cat values of 27 and 11 s⁻¹, respectively, using NADH as a reductant. CinD also exhibited significant catalase activity in vitro. The X-ray structure of CinD was resolved at 1.35 Å and resembles those of other nitroreductases. CinD is thus a nitroreductase which can protect L. lactis against oxidative stress that could be exerted by nitroaromatic compounds and copper.Lactococcus lactis IL1403 is a Gram-positive lactic acid bacterium which is used for the manufacture of food and dairy products but also for an increasing number of biotechnological applications. Given the economical importance of this microorganism, it is often used as a model for molecular studies. Its genome has been sequenced (4), and its proteome has been extensively characterized (11). When applied to industrial processes, this bacterium has to face various stress conditions, such as low pH, high temperature, osmotic shock, and metal stress (44). For instance, in traditional cheese making in Switzerland, L. lactis is exposed to copper released from the copper vats.Copper is an essential micronutrient for both prokaryotes and eukaryotes. The two oxidation states of copper, Cu⁺ and Cu²⁺, allow its participation in many important biological functions. More than 30 enzymes are known to use copper as a cofactor, such as superoxide dismutase (SOD), cytochrome c oxidase, or lysyl oxidase (20). The redox activity of copper can also lead to the generation of free radicals, which cause cellular damage (42, 43). Recently, alternative copper toxicity mechanisms have been demonstrated in bacteria in which copper interferes with the formation of catalytic iron-sulfur clusters (6, 22). Whatever the mechanism of copper toxicity, maintenance of copper homeostasis by controlling the uptake, accumulation, detoxification, and removal of copper is critical for living organisms.Copper homeostasis in L. lactis has not yet been investigated in great detail but appears to resemble the well-characterized copper homeostatic system of Enterococcus hirae (34). L. lactis possesses a copRZA operon, which provides copper resistance. It encodes the CopA copper export ATPase, the CopR copper-inducible repressor, and the CopZ copper chaperone (23). CopR regulates not only the copRZA operon but also an additional 11 genes. This so-called CopR regulon also includes copB, encoding a second putative copper ATPase; lctO, encoding lactate oxidase; and the ydiDE, yahCD-yaiAB, and ytjDBA operons of unknown function. Of all the genes and operons constituting the CopR regulon, the ytjDBA operon was most strongly induced by copper (23). Based on sequence comparison, the first gene of this operon, ytjD, encodes an oxygen-insensitive nitroreductase, which we renamed cinD for copper-induced nitroreductase.Nitroreductases are called oxygen insensitive when they can catalyze the two-electron reduction of nitro compounds in the presence of oxygen. Such enzymes are widespread in nature and are able to reduce a wide range of substrates, such as furazones, nitroaromatic compounds, flavins, and ferricyanide, using NADH or NADPH as the reductant. They are flavoproteins of 22 to 24 kDa and form homodimers with one flavin mononucleotide cofactor per monomer. Although oxygen-insensitive nitroreductases have been extensively studied, their in vivo function remains largely unknown. The closest relative of CinD, which has functionally been studied, is FRP of Vibrio harveyi, with 29% sequence identity to CinD. FRP is not a typical nitroreductase but appears to function as an NADH flavin oxidoreductase which provides reduced flavin to luciferase (19). The next closest relative of CinD, NfsA of Escherichia coli, with 23% sequence identity, exhibits the broad substrate specificity typical of most nitroreductases (48). The structure of this enzyme has been solved at a resolution of 1.7 Å (17). It closely resembles the structures of other enzymes which belong to the oxygen-insensitive nitroreductase family. NfsA has recently been shown to participate in the degradation of 2,4,6-trinitrotoluene (10). This suggests that an important function of nitroreductases could be the metabolism of xenobiotics.We investigated here the structure and function of CinD of L. lactis. CinD was induced by copper, cadmium, and silver and protected L. lactis from oxidative stress exerted by 4-nitroquinoline-N-oxide (NQO). The purified enzyme is a flavoprotein and exhibited nitroreductase activity on NQO and a variety of other substrates, using NADH as the reductant. CinD also possesses catalase activity and is thus able to defend cells against oxidative stress exerted by hydrogen peroxide, xenobiotics, or copper. The three-dimensional structure of CinD was resolved at a 1.35-Å resolution and exhibits a typical nitroreductase structure.