Division of Microbiology, National Center for Toxicological Research, US FDA, 3900 NCTR Road, Jefferson, AR 72079-9502, USA
Correspondence
Huizhong Chen
hchen{at}nctr.fda.gov
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ABSTRACT |
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The GenBank/EMBL/DDBJ accession number for the nucleotide sequence of azo1 of S. aureus ATCC 25923 reported in this paper is AY545994.
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INTRODUCTION |
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Human skin contains a characteristic complement of microbial species, which do no harm by their presence under usual circumstances. The microflora of the human skin is variable with regard to bacterial strains and species. The quantity varies in the range of 6x102 to 2x106 bacterial cells cm2, which depends on age and colonization site (Kloos & Schleifer, 1975). Staphylococcus aureus is widespread in nature and commonly found on human skin, skin glands and mucous membranes (Nagase et al., 2002
). The skin microbiota plays a very important role in preventing many pathogens from colonizing the skin and causing disease, in a similar manner to the barrier effect produced by intestinal microbes.
Dermal exposure of consumers to azo dyes by injection of tattoo ink and the topical application of colourants as well as wearing coloured textiles should be evaluated for safety, since, potentially, aromatic amines metabolized from aromatic amine-based dyes by the microflora are easily absorbed by the skin (Levine, 1991; Chung et al., 1992
; Platzek et al., 1999
). There is little information about the ability of the skin microflora to metabolize azo dyes. Platzek et al. (1999)
found that skin bacteria were able to cleave azo dyes under in vitro conditions. However, to our knowledge, azoreductases or their corresponding genes have not been identified or described in the skin microflora. It has been suggested that S. aureus may serve as a model strain for measuring the ability of human skin flora to reduce azo dyes (Platzek et al., 1999
). To better understand the metabolism of tattoo pigments, topically applied cosmetics and textile colourants by skin microflora and the potential toxicity of the reaction products to the human body, it is essential to discover the relevant genes and characterize their products within skin microflora.
In this study, we describe for the first time the cloning and identification of the gene, azo1, encoding a novel aerobic tetrameric FMN-dependent azoreductase, from S. aureus. Characterization of the purified Azo1 overexpressed in Escherichia coli demonstrated that this azoreductase was able to decolorize a wide range of structurally complex sulfonated azo dyes.
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METHODS |
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Twenty millilitres of S. aureus from BHI broth was inoculated into 200 ml BHI medium supplemented with individual azo dye at a final concentration of 0·2 mM and incubated at 37 °C for various times in air without shaking. The supernatants were used to assay azo dye reduction by measuring residual absorption at the appropriate wavelength for each azo dye, as described in the enzyme assay description below.
Cloning of S. aureus azo1 gene and expression of Azo1 in E. coli.
Genomic DNA of S. aureus was isolated essentially as described by Wang et al. (2002). Plasmids from E. coli Top10F' and NovaBlue (DE3) were isolated using a Qiaprep Spin Miniprep kit (Qiagen). A DNA fragment containing the putative S. aureus azo1 was obtained by PCR with the genomic DNA of S. aureus used as template. The forward primer included a NcoI site before the start codon: 5'-catgccatggctatgaaaggattaattattattggc-3' (Saa-forward). The reverse primer included a BamHI site downstream of the azo1 stop codon, beginning at 660 bp: 5'-gcggatccgcttactattggtgcattag-3' (Saa-reverse). PCR was performed in a Mastercycler gradient (Eppendorf). The amplification conditions were one cycle at 95 °C for 3 min, 30 cycles with each cycle including 30 s of melting at 95 °C, 30 s of annealing at 50 °C and 60 s of extension at 72 °C, and one final extension cycle at 72 °C for 5 min. The PCR products were examined by 1 % agarose gel electrophoresis.
The PCR products were directly cloned into the pCR2.1-TOPO vector and sequenced. Both strands of the DNA inserts were sequenced by walking from the ends of the inserts by using plasmid- and insert-specific primers. For overexpression of Azo1 in E. coli, the PCR products were cleaved with NcoI and BamHI (New England BioLabs). The digested DNA was purified from the agarose gel and ligated into pET-11d with a rapid DNA ligation kit (Roche). E. coli NovaBlue (DE3) was transformed with the resulting plasmids. The plasmids (pAZO1) were subsequently isolated and introduced into E. coli BL21-Gold(DE3)pLysS by transformation. DNA sequence analysis, translation and alignment with related genes and proteins were carried out using the Lasergene program (Version 5, DNASTAR). The GenBank program BLAST was utilized to find similar genes or proteins.
Enzyme assays.
Azoreductase activity was assayed by measuring the decrease in optical density at suitable wavelengths with a Hewlett Packard 8453 UVvisible spectrophotometer at 23 °C. The reaction mixture (2 ml) contained 25 mM potassium phosphate buffer (pH 7·1), 25 µM azo dye, 0·1 mM NADPH and a suitable amount of enzyme. The reaction was initiated by addition of the enzyme. Initial velocity was determined by monitoring the change in the amount of substrate in the first 2 min in a glass cuvette of 1 cm light path. The following molar absorption coefficients were used: 23 360 M1 cm1 (Methyl Red at 430 nm), 18 200 M1 cm1 (Orange II at 482 nm), 22 600 M1 cm1 (Amaranth at 520 nm), 20 700 M1 cm1 (Orange G at 477 nm), 22 900 M1 cm1 (Ponceau BS at 502 nm) (Nakanishi et al., 2001; Blumel et al., 2002
) and 33 470 M1 cm1 (Ponceau S at 520 nm). One unit (U) of enzyme activity was defined as the amount of enzyme required to degrade one µmol azo dye per minute. Proteins were quantified using the bicinchoninic acid assay (Pierce) with BSA as standard.
RNA isolation and RT-PCR.
RNA was isolated from S. aureus grown overnight in BHI, BHI+Methyl Red (0·2 mM), or BHI+Orange II (0·2 mM), essentially using the RNAzol B procedure (Chapes et al., 1994). The RT-PCR reaction mixture (25 µl) consisted of 50 pmol each primer (Sas1-forward, 5'-ggcagtgcacaagtgaattc-3' and Sas1-reverse, 5'-ccatgatagtttggcgttcc-3'), 4 µg RNA, 0·1 mM (each) deoxynucleoside triphosphate, 1 U Taq DNA polymerase and 10 U AMV reverse transcriptase in PCR buffer with MgCl2. cDNA synthesis by reverse transcription was accomplished at 37 °C for 1 h. The PCR was performed under the following conditions: initial denaturation (95 °C, 2 min), 40 cycles of denaturation (94 °C, 1 min), annealing (55 °C, 1·5 min) and extension (72 °C, 1 min), followed by a 10 min final extension (72 °C). The reaction products were analysed by 2 % agarose gel electrophoresis.
Enzyme purification.
Induction of target protein and preparation of cell extracts were performed using a similar procedure to that described previously (Chen et al., 2004). Protein purification was performed at 4 °C by using an AKTApurifier 10 system with UNICORN 4.10 software (Amersham Biosciences). Sixty millilitres of the supernatant (549 mg protein) was applied to a HiPrep 16/10 Q XL anion-exchange column (Amersham Biosciences) equilibrated with 25 mM Tris/HCl (pH 7·5) buffer. The peak fractions of azoreductase activity eluted at around 0·3 M NaCl (21 ml) were pooled. One volume of 10 mM potassium phosphate (pH 7·1) containing 2·0 M (NH4)2SO4 was mixed with one volume of the pooled fractions. Forty millilitres of the sample was applied to a HiPrep 16/10 Phenyl FF hydrophobic interaction column (Amersham Biosciences) equilibrated with the same buffer plus 1·0 M (NH4)2SO4. A linear gradient of 400 ml (NH4)2SO4 sulfate from 1·0 to 0 M in the same buffer was applied, followed by further elution with 100 ml buffer. Fractions with azoreductase activity (30 ml) were pooled and concentrated to a volume of about 8 ml by using an Amicon Ultra-15 (Millipore). The sample was dialysed and buffered with 25 mM Tris/HCl (pH 8·0). The sample was then applied in 2 ml portions to a Mono Q HR 5/5 column (Amersham Biosciences) equilibrated with the same buffer. Fractions of 0·5 ml were collected and those containing major enzyme activity were pooled (1·0 ml, 0·35 M NaCl). Final purification was achieved by gel filtration on a HiLoad 26/60 Superdex 200 pre grade column (Amersham Biosciences) equilibrated and eluted with 25 mM potassium phosphate (pH 7·1) plus 0·1 M NaCl (Chen et al., 2004
).
Identification of the prosthetic group.
One hundred microlitres of the purified enzyme (3 mg ml1) in 10 mM potassium phosphate buffer (pH 7·0) was heated at 100 °C for 10 min in the dark. After cooling on ice, the denatured protein was removed by centrifugation at 14 500 g for 10 min in a microfuge at 4 °C. The resulting yellow supernatant (5 µl) was analysed by TLC employing a silica gel 60 F-254 plate (2 mm thickness; Merck) and chloroform, glacial acetic acid and water (6 : 7 : 1 by vol.) as the solvent phase (Lake & Goodwin, 1976). FAD and FMN (1 µl, 0·2 mM each) were used as standards, and the migration of the compounds was monitored by the characteristic fluorescence in UV light (312 nm).
SDS-PAGE and N-terminal amino acid sequencing of the protein.
SDS-PAGE (12·5 %, w/v) was conducted under normal conditions. Protein markers (Novagen) were used as standards. Gels were stained for the presence of proteins using Coomassie brilliant blue R-250 (Bio-Rad). The proteins were transferred onto a PVDF membrane in a Hoefer TE77 Semi-Dry Transfer Unit (Amersham Biosciences). The transferred proteins were visualized by Coomassie staining and excised with a razor blade. N-terminal amino acid sequencing was performed by an Applied Biosystems model 477A gas-phase sequencer equipped with an automatic on-line phenylthiohydantoin analyser.
Preparation of apoenzyme and reconstruction of flavoprotein.
Eight millilitres of 25 mM potassium phosphate (pH 7·1) containing 1 M (NH4)2SO4, 1 M KBr and 1 mM EDTA was mixed with 2 ml purified enzyme (5 mg). The sample was applied to the HiPrep 16/10 Phenyl FF column equilibrated with the same buffer. The column was washed with 40 ml starting buffer. Flavin was eluted with 60 ml of the same buffer adjusted to pH 4·0 with 1 M phosphoric acid. After flavin elution, the column was immediately washed with 40 ml starting buffer, omitting 1 M KBr. Four hundred millilitres of a linear gradient of (NH4)2SO4 from 1 to 0 M in the same buffer was applied. This was followed by further elution with 100 ml starting buffer. The fractions (30 ml) containing apoenzyme were concentrated (Van Berkel et al., 1988).
The protein was reconstructed directly on the column. After the release of the original flavin from the column, the pH of the column was equilibrated back to 7·1, as described above. Forty millilitres of the starting buffer containing 1 mM FMN, FAD, or riboflavin was passed through the column at a flow rate of 0·5 ml min1. The column was placed at 4 °C overnight and then washed with 40 ml starting buffer, omitting 1 M KBr, to remove the unbound excess flavin. The elution of the protein was done as above (Van Berkel et al., 1988).
Identification of Methyl Red and its metabolites.
Two assay mixtures containing 0·4 mM NADPH and 50 µM Methyl Red in 20 ml of 25 mM sodium phosphate buffer (pH 7·1) with or without the purified enzyme were prepared. Methyl Red, N,N-dimethyl-p-phenylenediamine and 2-aminobenzoic acid (Sigma) solutions (50 mg l1), using acetonitrile as solvent, were prepared. The assay mixture containing the enzyme was then incubated at room temperature until no decrease in optical density at 430 nm was noted. The two assay mixtures were extracted three times with equal volumes of ethyl acetate, subsequent to adjusting the pH to 3 with 1 M HCl. The extracts were evaporated in a rotary evaporator at 40 °C and the remaining trace solvent was removed by evaporation at room temperature overnight. Each residue was dissolved in 1 ml acetonitrile and filtered through a 0·2 µm pore-size syringe filter. Forty microlitres of the samples was analysed with a Hewlett Packard HPLC 1050 equipped with a model variable-wavelength detector (detection wavelength was 250 nm) and a reverse-phase Inertsil 5µ ODS-2 column (4·6x250 mm, MetaChem Technologies). The mobile phase was composed of 25 mM phosphate buffer (pH 3·0) and acetonitrile (4 : 6, v/v) with a flow rate of 0·5 ml min1 (Moutaouakkil et al., 2003; Nakanishi et al., 2001
; Wong & Yuen, 1998
).
Enzyme characterization.
Each data point was analysed three times with a standard deviation of less than 10 %. The effects of pH on the activity and the optimum pH of S. aureus Sa-Azo1 were determined at room temperature with the following buffers: 0·1 M sodium acetate (pH 4·25·4), sodium phosphate (pH 5·87·8) and HEPES/NaOH (pH 8·2 and 8·6). The effects of temperature on Azo1 were determined by assaying the enzyme at temperatures ranging from 10 to 65 °C. Thermostability was measured by incubating the enzyme samples in 25 mM potassium phosphate buffer, pH 7·1, for 1 h at temperatures from 30 to 70 °C. The initial velocities of the enzymic reaction were obtained by varying the concentrations of one substrate, Methyl Red (from 0·005 to 0·04 mM) or NADPH (from 0·05 to 0·4 mM), while the concentration of the other substrate was kept constant (NADPH, 0·4 mM or Methyl Red, 0·04 mM). Apparent Km and Vmax values were obtained from LineweaverBurk plots.
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RESULTS |
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Identification of the S. aureus azo1 gene
Although the ability of the skin microflora to metabolize azo dyes was demonstrated, the corresponding genes or their corresponding gene products have not been characterized (Platzek et al., 1999). Therefore we searched the S. aureus Mu50 genome sequence (Kuroda et al., 2001
) in GenBank by a BLAST search using the entire protein sequence of 178 amino acids deduced from a main azoreductase gene of Bacillus sp. OY1-2 as the query (Suzuki et al., 2001
). The search identified a single gene encoding a 188 amino acid residue (Fig. 1
), which displayed moderate primary structure identity (32 %) and was similar in size to the Bacillus azoreductase. There were five place deletion and/or insertion differences between these two protein sequences. This putative azoreductase gene was amplified from the purified genomic DNA of S. aureus ATCC 25923 by PCR using a pair of primers (Saa-forward and Saa-reverse), yielding a DNA band of about 700 bp on agarose gel. The amplified DNA fragment contained a putative ORF as well as a short sequence downstream of the stop codon. The fragment was directly ligated into a TA cloning vector, pCR2.1-TOPO. Sequencing of the insert revealed that it contained a 567 bp DNA fragment with a complete ORF encoding a protein (Azo1). There are only three base pair differences between sa-azo1 from S. aureus ATCC 25923 and the corresponding gene from S. aureus Mu50. However, both protein sequences translated from the genes were identical.
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Analysis of azo1 expression by S. aureus
To determine whether the azo1 gene is expressed by S. aureus ATCC 25923, transcription of azo1 was examined by RT-PCR. A 233 bp transcript of azoA was detected in all three RNA samples (not shown). Control reactions, in which reverse transcription from DNase- and RNase-treated RNA samples yielded no products, confirmed the absence of contaminating DNA. These results demonstrated that the azo1 gene was constitutively expressed in S. aureus.
Purification of the recombinant S. aureus Azo1 expressed in E. coli
The purification procedure is summarized in Table 1. The enzyme was purified at about 9·3-fold with a yield of 20 %, which allows the proportion of the enzyme to be estimated at 10·8 % of the protein present in the crude cell extract. The specific activity of the final purified S. aureus Azo1 was 0·14 U (mg protein)1 using Methyl Red as substrate. The molecular mass of the purified azoreductase was found to be 20 kDa as shown by SDS-PAGE (Fig. 2
). However, when determined by gel filtration chromatography on a HiLoad Superdex 200 column, it had an approximate size of 85 kDa. The purified protein on SDS-PAGE was transferred onto a PVDF membrane and subjected to N-terminal sequence. The first 10 amino acid residues (AMKGLIIIGS) were determined and found to be identical to the 10 residues shown for the polypeptide sequence, beginning with the second position in the N-terminal sequence, translated from the modified azoreductase ORF of S. aureus.
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The activity of Azo1 was determined from pH 4·28·6 with Methyl Red as substrate. A typical bell-shaped pH profile was obtained with an optimum between pH 6·0 and 6·6. The effect of temperature on azoreductase activity was determined from 10 to 65 °C. Maximum activity was observed between 35 and 40 °C. Thermal stability was investigated by incubating the enzyme at different temperatures for 1 h. The enzyme was stable at temperatures up to 55 °C. Inactivation occurred at 60 °C, with 67 % of the enzyme activity remaining after 1 h pre-incubation and a half-life of 1·6 h. Enzymic reactions were performed by varying the concentrations of one substrate (Methyl Red or NADPH) and fixing the other substrate concentration. Apparent Km and Vmax values were obtained from LineweaverBurk plots. Km values of 0·074 and 0·057 mM and Vmax values of 0·39 and 0·41 U (mg protein)1 for NADPH and Methyl Red, respectively, were obtained. In addition, a number of synthetic model azo compounds were used to determine the substrate specificity of the enzyme. The enzyme displayed the highest activity with Methyl Red [0·14 U (mg protein)1]. The enzyme also degraded the sulfonated azo dyes Orange II [0·11 U (mg protein)1], Amaranth [0·055 U (mg protein)1], Ponceau BS [0·13 U (mg protein)1] and Ponceau S [0·13 U (mg protein)1]. No enzymic activity was observed when Orange G was used as substrate.
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DISCUSSION |
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Our studies demonstrated that S. aureus was able to grow and reduce azo dyes, indicating that azoreductase was functionally expressed in the bacterium. Unlike adapted soil bacteria isolated from azo dye-contaminated wastewater (Suzuki et al., 2001), as a skin bacterium, S. aureus presumably does not produce highly active azoreductase. It is an extremely difficult and very time-consuming process to purify sufficient amounts of protein from the bacterium for biological characterization of the enzyme. A novel approach was adapted by using homology comparison, direct cloning and overexpression of the genes encoding hypothetical proteins. We were able to identify and express a functional azoreductase gene from S. aureus in E. coli. The N-terminal methionine of the recombinant S. aureus Azo1 was cleaved by methionine aminopeptidase in the E. coli cells, as is common for heterologous proteins expressed in the E. coli host (Ben-Bassat et al., 1987
). The N-terminal sequence of the purified enzyme started from the second position of the deduced protein sequence, indicating that the purified recombinant Azo1 was an intact protein when expressed in E. coli and could be similar to the corresponding native enzyme produced in S. aureus. Gel filtration chromatography revealed that AzoA exists as a tetramer (Figs 2 and 5
) which was different from the dimeric azoreductases from E. coli (AcpD) (Nakanishi et al., 2001
) and Enterococcus faecalis (Chen et al., 2004
). Some other flavin-binding proteins, however, do exist as tetramers. This is the case for Sulfolobus shibatae type 2 isopentenyl diphosphate isomerase (Yamashita et al., 2004
) and Bacillus subtilis glycine oxidase (Mortl et al., 2004
). The prosthetic FMNs in the tetrameric enzyme may hold the subunits together (Van Berkel et al., 1988
). During hydrophobic interaction chromatography in the presence of high concentrations of KBr and ammonium sulfate, the yellow flavin compound was eluted with decreasing pH, indicating a non-covalent association with the protein (Hefti et al., 2003
). Azoreductases from Bacillus sp. OY1-2 (Suzuki et al., 2001
), Xenophilus azovorans (Blumel et al., 2002
) and Pigmentiphaga kullae (Blumel & Stolz, 2003
) exist as monomers and enzyme-bound FMN or FAD have not been reported.
Azo1 was further annotated and searched for homologues from other organisms in the DNA and protein databases. We found that Azo1 has the highest homology (80 %) to a hypothetical protein from another more closely related skin bacterium Staphylococcus epidermidis. However, it has moderate homology (range 3035 %) with other azoreductases and hypothetical proteins from other bacteria. Based on the multiple alignments of Azo1, protein sequences of the related azoreductases, and related hypothetical protein sequences, an unrooted phylogenetic tree was generated. Fig. 6 shows that Azo1 was clustered with hypothetical proteins from the skin bacteria S. epidermidis and Bartonella henselae. Azo1 has 32 % homology to a hypothetical FMN-dependent azobenzene reductase (Yhda protein) from B. subtilis, whose crystal structure has been newly discovered (PDB coordinate: 1NNI). More recently, the three-dimensional structure of a homodimer NAD(P)H-dependent FMN reductase of a Saccharomyces cerevisiae YLR011w gene product, which has minor azoreductase activity to cleave Ethyl Red, has shown structural homology to B. subtilis Yhda protein (Liger et al., 2004
). Both B. subtilis Yhda and Sac. cerevisiae YLR011W have conserved amino acid residues at several crucial positions that contribute to FMN binding. These same residues are conserved in Azo1 and other real and hypothetical azoreductases from various bacteria (Figs 1 and 6
). It was suggested that the azoreductase from Bacillus sp. strain OY1-2 contains an NAD(P)H-binding motif (GXGXXG) at positions 106111 within the protein (Fig. 1
). This motif was not conserved in the protein sequences of Azo1 or other members of this azoreductase family (Figs 1 and 6
). The vast majority of flavodoxin domains whose structure is known have a six-residue flavodoxin key fingerprint motif (T/S-X-T-G-X-T) in common (Liger et al., 2004
). However, the hypothetical FMN phosphate-binding loop sequences (T/S-X-T-G-X-T) were not found in the B. subtilis Yhda protein, the Sac. cerevisiae YLR011 wp, or Azo1. Instead of this, several amino acid residues in the sequences (P-X-Y-H/N-2X-P/S-G/A-X-L-K-N-A/S-D-L/I-D) form another loop between the
3 and
3 helix in the Sac. cerevisiae YLR011 wp that interacts with both parts of FMN, and these residues are conserved in this enzyme family. This indicates that this conserved sequence may serve as a new signature sequence for these novel flavin enzymes.
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Two further azoreductases belonging to the same family, from E. coli (Nakanishi et al., 2001) and Ent. faecalis (Chen et al., 2004
), are FMN-dependent enzymes. No information is available regarding other azoreductases from Bacillus sp. OY1-2 (Suzuki et al., 2001
) and R. sphaeroides AS1.1737 (Yan et al., 2004
). In this study, we discovered that Azo1 contained a tightly bound flavin and that its activity was strictly dependent on that flavin, indicating that it is a flavin-dependent azoreductase. Dissociation and reconstitution of the enzyme demonstrated that the flavin prosthetic group was required for its function. Since azoreductases from Bacillus sp. OY1-2 (Suzuki et al., 2001
) and R. sphaeroides AS1.1737 (Yan et al., 2004
) fall into the same enzyme family as Azo1, presumptively they are also flavin-dependent enzymes. Besides these flavin-dependent azoreductases, two monomeric flavin-free azoreductases from X. azovorans and P. kullae K24 have also been described (Zimmermann et al., 1982
, 1984
; Blumel et al., 2002
; Blumel & Stolz, 2003
), indicating that there are at least two different types of azoreductase in bacteria.
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ACKNOWLEDGEMENTS |
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Received 2 December 2004;
revised 13 January 2005;
accepted 17 January 2005.
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