Abstract
The pyridoxal-5′-phosphate (PLP)-dependent amino acid racemases occur in almost every bacterium but may differ considerably with respect to substrate specificity. We here isolated the cloned broad substrate specificity racemase ArgR of Pseudomonas taetrolens from Escherichia coli by classical procedures. The racemase was biochemically characterized and amongst other aspects it was confirmed that it is mostly active with lysine, arginine and ornithine, but merely weakly active with alanine, whereas the alanine racemase of the same organism studied in comparison acts on alanine only. Unexpectedly, sequencing the amino-terminal end of ArgR revealed processing of the protein, with a signal peptide cleaved off. Subsequent localization studies demonstrated that in both P. taetrolens and E. coli ArgR activity was almost exclusively present in the periplasm, a feature so far unknown for any amino acid racemase. An ArgR-derivative carrying a carboxy-terminal His-tag was made and this was demonstrated to localize even in an E. coli mutant devoid of the twin-arginine translocation (Tat) pathway in the periplasm. These data indicate that ArgR is synthesized as a prepeptide and translocated in a Tat-independent manner. We therefore propose that ArgR translocation depends on the Sec system and a post-translocational insertion of PLP occurs. As further experiments showed, ArgR is necessary for the catabolism of d-arginine and d-lysine by P. taetrolens.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
The pyridoxal-5′-phosphate (PLP)-dependent amino acid racemases catalyze the racemerization of their substrate by removal of an α-hydrogen bound from a chiral carbon followed by the nonspecific return of a hydrogen to the same carbon. A number of different amino acid racemases of this type has been studied, and the racemases differ remarkably with respect to their substrate specificity. An example for a highly specific amino acid racemase is the alanine racemase, like that of Bacillus psychrosaccharolyticus (Okubo et al. 1999) or that of Corynebacterium glutamicum (Oikawa et al. 2006) which is active with alanine only, but not with the structurally related serine, aminobutyrate, not to mention aspartate, glutamate, methionine, or lysine. These enzymes, encoded by alr, act on l-alanine to provide d-alanine for cell wall synthesis and they are therefore widespread among bacteria to ensure provision of d-alanine as a cell wall building block. In addition to this anabolic alanine racemase, a catabolic alanine racemase is also known. This latter enzyme is less frequently distributed and encoded by dadX (but also annotated as alr). Thus, E. coli has both alr and dadX (Wild et al. 1985). Another example of a highly specific amino acid racemase is the catabolic ornithine racemase of Clostridium sticklandii. The latter is active with ornithine only, but not with l-lysine, l-arginine, l-methionine, or other amino acids (Chen et al. 2000). In contrast to these specific racemases, the broad substrate specificity racemases are less frequent. An example for such a racemase with broad substrate specificity is an arginine racemase isolated from Pseudomonas taetrolens as early as 1971 (Yorifuji and Ogata 1971; Yorifuji et al. 1971). Its analysis revealed activity with the basic amino acids d-arginine, l-lysine, and l-ornithine, and further amino acids, but almost no activity with hydrophobic, acidic or aromatic amino acids. It was designated ArgR, but proteins with similar enzymological features and termed BsRC (for broad specificity racemase) are also present in Pseudomonas putida ATCC 17642 (Lim et al. 1993; Roise et al. 1984), or Aeromonas punctata (Inagaki et al. 1984), suggesting a close relationship of the proteins. Recently, the gene sequence of P. putida ATCC 17642 became available, and the rather weak racemase activity of wild-type BsRC with l-tryptophan as substrate was evolved to increase its activity with this specific substrate about 20-fold (Kino et al. 2007). Although there is some information on the enzymological features of broad substrate specificity racemases, which is in part due to their relaxed substrate specificity for preparing d-amino acids, there is only limited information on the physiological function of these enzymes. We therefore started to clone the gene encoding the broad substrate specificity racemase of P. taetrolens but noticed that the open reading frame was apparently larger than the peptide sequence of P. putida ATCC 17642 found in the literature (Kino et al. 2007). Moreover, we found distracting that in P. putida KT2440 (ATCC 47054) which is one of the fully sequenced P. putida strains currently available, there are two genes annotated alanine racemases (Nelson et al. 2002). Based on this information, we started to analyze in detail the corresponding genes and enzymes, respectively, of P. taetrolens leading to the first identification of a PLP-containing amino acid racemase located in the periplasm.
Materials and methods
Strains and growth
The P. taetrolens strain used was obtained from the NITE Biological Resource Center, National Institute of Technology and Evaluation, Chiba, Japan as strain NBRC 3460. Aliases of this strain are P. graveolens IFO 3460, and P. taetrolens ATCC 4683. The further strains and plasmids used are given in Table 1.
The medium used for cultivation of P. taetrolens was usually LB. For carbon source utilization studies, minimal medium No. 154 was used (Stalon et al. 1967). Cells were grown in 50 ml medium in a 500-ml baffled Erlenmeyer flask at 30 °C and 160 rpm on a rotary shaker. Growth was followed by measuring the optical density at 600 nm.
Gene isolation and cloning
Chromosomal DNA was isolated using the FastPure kit of TaKaRa (TaKaRa, Kyoto, Japan). Primers A and B, 0.2 pmol of each, were used together with 1.4 µg chromosomal DNA from P. taetrolens as a template to generate an amplification product at an annealing temperature of 40 °C. This was used as the template in a second PCR at an annealing temperature of 52 °C with primers C and D. The product was purified, cloned in pT7 Blue T, and sequenced using the DNA sequencer SQ5500E (Hitachi High-Technologies Corp., Tokyo, Japan). Based on the partial sequence obtained, new primers were designed to perform genome-walking PCR with the LA PCR™ in vitro cloning kit supplying HindIII and EcoRI cassettes (TaKaRa, Kyoto, Japan). Based on the 5′- and 3′- ends of argR obtained, primers E, F were designed to amplify the entire argR gene from genomic DNA of P. taetrolens. The product obtained was digested with NdeI and BamHI, and ligated into NdeI/BamHI digested pET11b to form pET11b-argR. Cloning of alr was similarly achieved, involving a final amplification step with the primer pair G and H, digestion of the amplification product with NdeI and BamHI, and ligation with the accordingly treated vector to yield pET21b-alr. To generate the inactivation vector pK18mob-argR-int, an internal HincII fragment of argR derived by restriction was prepared from pET11b-argR, which was ligated with SmaI-cleaved pK18mob. Subsequently, pK18mob-argR-int was used to transform P. taetrolens NBRC 3460 by electroporation to kanamycin resistance. One colony was isolated and PCR analyses used to confirm disruption of argR.
Isolation of ArgR
Cells of E. coli BL21 (DE3) (pET11b-argR) were harvested from 1.2 l LB medium and washed twice with cold 0.85% (w/v) NaCl, followed by resuspension in 74 mM Tris–HCl (pH 8.0) buffer containing 0.5 M sucrose and 1 mM EDTA (buffer A). After centrifugation at 8,000×g for 20 min, the cells were resuspended in ice-chilled water, and after brief incubation centrifuged at 5,500×g for 10 min. The supernatant was collected and used as a cell-free extract. This was dialyzed against a 10 mM potassium phosphate buffer (pH 7.3) containing 0.01% 2-mercaptoethanol and 20 µM pyridoxal-5′-phosphate (PLP; buffer B). The enzyme solution was applied to a column of DEAE-Toyopearl 650 M (2.5 × 30 cm) equilibrated with buffer B, and washed with the same buffer containing 40 mM KCl. Proteins were eluted with a linear gradient of KCl at a concentration of 40 to 80 mM in buffer B, and active fractions combined and dialyzed against buffer B containing 1.2 M (NH4)2SO4. The resulting solution was applied to a column of Butyl-Toyopearl 650 M (1.25 × 15 cm) equilibrated with the same buffer, and the column washed with buffer B containing 0.9 M (NH4)2SO4. Proteins were eluted with a linear gradient of (NH4)2SO4 at a concentration of 0.9 to 0.7 M in buffer B, and active fractions combined and dialyzed against buffer B. Finally, the enzyme solution obtained was applied a second time to DEAE-Toyopearl 650 M chromatography under identical conditions as described to yield pure ArgR which was dialyzed and stored frozen in buffer B.
Alr was prepared from E. coli BL21 (DE3) harboring pET21b-alr which was disrupted by sonification. The cell-free extract was dialyzed against a 10 mM potassium phosphate buffer (pH 7.5) containing 300 mM NaCl and 10 mM imidazole (buffer C), and the protein solution applied to a Ni-NTA agarose column (1.0 × 10 cm) equilibrated with the same buffer. The column was washed with buffer C but containing 50 mM imidazole, and eluted by increasing the imidazole concentration to 250 mM. Alr was finally dialyzed and stored in buffer B.
Analysis of phosphopyridoxyl peptide
ArgR was reduced with sodium borohydride, digested with trypsin and the peptides were separated by HPLC on a Wakosil-II 5C-18 AR column (Wako, Osaka, Japan). Fluorescence detection was at 330 nm excitation and 390 nm emission. The fluorescent phosphopyridoxyl peptide was isolated and subjected to Edman degradation using an automated protein sequencer (PPSQ-21, Shimadzu Co., Kyoto, Japan).
Enzyme assays
Amino acid racemase activities with arginine or lysine as a substrate were in part measured in coupled assays with l-arginase (Yorifuji and Ogata 1971; Yorifuji et al. 1971) or lysine 6-aminotransferase (Yagi et al. 1980). However, generally, amino acid racemase activities were measured via HPLC quantification of the respective enantiomer formed (Ono et al. 2006). The assay mixtures contained a 0.6 M CHES–NaOH buffer, pH 10.0 (130 µl), 0.1 M l-amino acid (80 µl), 0.1 mM PLP (200 µl), and enzyme. Reactions were carried out at 37 °C for different time intervals, stopped by heat treatment at 100 °C for 2 min, and subjected to HPLC analysis. Protein was determined with bovine serum albumin as standard, with one unit being defined as the amount of enzyme producing one µmol of enantiomer per min.
Localization studies
Fractionation of P. taetrolens and E. coli BL21 (DE3) harboring pET11b-argR was essentially as described (Morita et al. 2006). Both bacteria were pre-cultured at 30 °C in 5 ml LB and 100 µl of this pre-culture transferred into four Sakaguchi flasks (500 ml) containing 100 ml LB and cultivated at 30 °C aerobically. Per data point, cells of one flask were harvested by centrifugation at 14,000×g for 20 min. The supernatant was collected as the extracellular fraction. The pelleted cells were washed twice with 0.85% NaCl. Washed cells were subsequently resuspended in buffer (40 ml per 1 g wet weight) containing 500 mM sucrose and 1 mM EDTA in a 30 mM Tris–HCl buffer (pH 8.0) for disruption by osmotic pressure. After centrifugation at 14,000×g for 20 min, the cell debris was resuspended in deionized water and centrifuged again. The supernatant obtained was collected as periplasmic fraction. The residual cell debris was disrupted by ultrasonication and the supernatant obtained after centrifugation used as cytosolic fraction. Alkaline phosphatase and β-galactosidase activities were quantified as marker enzymes present in the periplasm and cytosol, respectively, as described (Craven et al. 1965; Schlesinger and Olsen 1968).
Translocation studies
Fractionation of E. coli into a fraction containing the cytoplasm together with membranes (CP/M) and a periplasmic fraction (PP) was done by using an EDTA-lysozyme spheroplasting method as described earlier (Kreutzenbeck et al. 2007). Also SDS-PAGE and Western blotting of fractions which correspond to an identical number of cells is described in the reference. For the detection of the His-tagged ArgR protein, a penta-His-antibody (Qiagen, Hilden, Germany) was used as the primary antibody in a dilution of 1:1,000. The detection of transaldolase B protein (TalB) was carried out using an anti- transaldolase B antibody in a dilution of 1:1,000. Further processing was done by use of the ECL Western blotting detection kit (GE Healthcare, Munich, Germany) according to the manufacturer’s instructions. The chemiluminescent protein bands were recorded using the Fujifilm LAS-3000 Mini CCD camera and image analyzing system together with the software AIDA 4.15 (raytest Inc., Willmington, USA).
Accession numbers
The nucleotide sequence for P. taetrolens NBRC 3436 argR is deposited at DDBJ/EMBL/GenBank as AB096176, that for alr as AB296103.
Results
Cloning of argR and alr
Sequences of the broad specificity amino acid racemases of Pseudomonas striata (Roise et al. 1984) and Pseudomonas putida (Kino et al. 2007) were used as the basis to enable isolation of argR from P. taetrolens. Primers A and B (Table 1) close to the conserved PLP binding site were designed and used to amplify argR by PCR applying chromosomal DNA of P. taetrolens as the template. Two subsequent amplifications were made with increasing annealing temperature, the resulting fragments cloned, and one of them was shown by sequencing to possess the expected PLP motif. This fragment was used for isolation of the entire argR by genome-walking which was done with the LA PCRTM in vitro cloning kit to result in pET11b-argR containing a 3,160-bp genomic fragment of P. taetrolens, with the open reading frame termed argR. The argR gene of P. taetrolens consists of 1,227 bp and encodes a protein of 408 amino acids.
In order to study also the alanine racemase gene of P. taetrolens for comparison, we used the genome sequence of P. putida KT2440 (Nelson et al. 2002) to design primers G and H within the gene annotated alr. Using PCR amplification and genome-walking in a procedure similar to that described above the alr gene from P. taetrolens was obtained in pET21b-alr. The gene consists of 1,074 bp and encodes a protein of 357 amino acids.
Isolation of ArgR and Alr proteins
ArgR was isolated from E. coli BL21 (DE3) harboring pET11b-argR enabling expression of the native enzyme without any tag. As shown in Table 2, the isolation procedure based on ion exchange and hydrophobic interaction chromatography yielded 16-fold enriched enzyme with a high specific activity of 1,120 µmol−1 min mg−1. After dialysis of the protein against a 10 mM potassium phosphate buffer (pH 7.3) containing 10 mM hydroxylamine for 12 h activity was lost. However, the activity was restored to 80% of its initial value upon incubation of the apoenzyme with 10 mM PLP, indicating reconstitution of the protein by PLP addition. The apoenzyme and the PLP-enzyme were reduced with sodium borohydride, and digested with trypsin. Separation of the peptides by reversed-phase liquid column chromatography yielded one strong fluorescent peak in the PLP-enzyme preparation, which was absent in the apoenzyme treated identically. This phosphopyridoxyl peptide was isolated and sequenced, yielding the sequence SQIX1AVLX2ADAYGHGIGL corresponding to amino acyl residues 73–83 of the protein as derived from the nucleotide sequence. The X-residues could not be determined. According to the DNA sequence X1 is a cysteine and X2 a lysine, the latter lysine apparently serving to establish the aldimine linkage between its epsilon-amino group and the carbonyl group of PLP. The isolated ArgR was furthermore subjected to Edman degradation and the amino-terminal sequence APPLSMTDGV determined. This is at variance with the peptide sequence derived from the argR open reading frame used and as present in the P. taetrolens genome. It corresponds to amino acids 24 to 33 of the deduced peptide sequence, suggesting that native ArgR is made as a preprotein processed by cleavage (see below).
Alr was isolated from E. coli BL21 (DE3) pET21b-alr as a carboxy-terminal His6-tagged protein. The homogeneous protein was dialyzed against buffer B and stored at −20 °C, as was the ArgR protein.
Enzyme properties of ArgR and Alr proteins
Using gel filtration on a calibrated column a mass of 84 ± 11 kDa was determined for ArgR, and one of 79 ± 16 kDa for Alr (data not shown). Since the calculated monomer mass of mature ArgR is 41.5 kDa and of Alr 38.8 kDa, both native enzymes adopt a dimeric structure. The optimum activity of the Alr was at pH 8.0 and this was similar the case for ArgR (Yorifuji and Ogata 1971). Whereas Alr showed maximal activity at 35 °C, this was the case for ArgR only at 65 °C (data not shown). The activation energy as calculated from Arrhenius plots was 126 kJ mol−1 for Alr with l-Ala and 61.8 kJ mol−1 for ArgR with l-Arg as a substrate.
The specificity of both racemases was determined with l-amino acids as substrates by quantification of the formed enantiomers via HPLC (Ono et al. 2006). ArgR was most active with Lys and Arg, whereas with Ala only a minor activity was obtained (Table 3), and these values largely agree with that described (Yorifuji and Ogata 1971). With Phe as substrate only a trace activity was detectable, and with Glu the enzyme was inactive. Interestingly, the BsRC of P. putida exhibits subtle but significant differences in its specificity (Kino et al. 2007). In contrast to ArgR of P. taetrolens with its broad substrate specificity, the alanine racemase Alr of this organism exhibited activity with Ala only and acted neither on Arg nor on any other of the amino acids tested (Table 3).
Localization of ArgR in P. taetrolens
Following the observation that ArgR was 23 amino acids shorter than expected from the gene sequence, and that SignalP predicted a cleavage site for the full-length protein (Bendtsen et al. 2004), we studied the localization of the protein in P. taetrolens. Supernatants of cell suspensions yielded the extracellular enzyme fraction, whereas osmotically shocked cells yielded periplasmic and cytoplasmic fractions (Morita et al. 2006). As shown in Fig. 1, the greatest racemase activities of cultures grown to different optical densities were always localized in the periplasm, whereas significantly lower activities were present in the cytosol and the supernatant.
Localization of ArgR in E. coli
In addition, localization in E. coli BL21 (DE3) harboring pET11b-argR used for protein isolation was studied. For this purpose, E. coli was grown in 100 ml volumes to four different time points, fractionated, and the ArgR activity together with that of alkaline phosphatase and β-galactosidase determined, the latter enzymes serving as lead enzymes for either periplasmic or cytoplasmic localizations. As shown in Table 4, the largest fractions of ArgR activity were present in the periplasmic fraction, and the contribution of the cytoplasmic fraction plus the medium fraction to the total activity was at best 16%. The periplasmic alkaline phosphatase and the cytosolic β-galactosidase quantified as control localized as expected. This confirms that the broad substrate specificity racemase ArgR also localizes in E. coli in the periplasm and means processing of ArgR in the heterologous host.
Transport of ArgR in E. coli
As shown above, enzymatically active ArgR can be detected in the periplasm when argR is expressed in E. coli. The ArgR signal peptide lacks a typical Tat-consensus motif and possesses only one arginine at the boundary between the n- and the h-region of the deduced signal peptide, suggesting that ArgR might be exported into the E. coli periplasm separately from its PLP cofactor via the Sec pathway. However, since it is possible that ArgR may be a Tat-substrate with an atypical Tat-consensus motif, the subcellular localization of a C-terminal His-tagged version of ArgR (ArgR-His) was determined in an E. coli wild-type strain and its isogenic Tat-defective mutant derivative, in which all known tat genes were deleted (Blaudeck et al. 2003).
E. coli (GSJ100) and E. coli∆tat (GSJ101) cells expressing either untagged ArgR or ArgR-His were fractionated into a cytoplasm/membrane (CP/M) fraction and a periplasmic (PP) fraction by EDTA-lysozyme spheroplasting. The fractions were subsequently analyzed by SDS-PAGE and Western blotting, using anti-5His antibody for the detection of ArgR (Fig. 2a). As a control for the quality of the fractionation experiments, the subcellular distribution of the cytoplasmic enzyme transaldolase B was analyzed in parallel (Blaudeck et al. 2003). As expected, transaldolase B was found exclusively in the CP/M fraction of all cells examined (Fig. 2b). As shown in Fig. 2a, various polypeptides were detected with the anti-5His antibody in the subcellular fractions of the strains expressing the ArgR-His (lanes 1 to 4), but not in the strain expressing the untagged ArgR (lanes 5 and 6). In the CP/M fraction of both the E. coli wild-type (lane 1) and the ∆tat strain (lane 3) expressing ArgR-His, a band (p) is detected by the anti-5His antibody that corresponds in molecular weight to the unprocessed precursor of ArgR. In addition, a smaller migrating form (*) of ArgR-His is detected in the same fraction of both strains. Most likely, this ArgR-His-derived polypeptide corresponds to a cytosolic degradation product. Importantly, however, in both the E. coli wild-type strain (lane 2) and the E. coli∆tat strain (lane 4), a band (m) of identical intensity is detected by the anti-5His antibody in the periplasmic fraction. This ArgR-His-derived polypeptide corresponds in size to the correctly processed mature form of ArgR-His. Since no difference in the subcellular distribution of ArgR-His-derived polypeptides (nor in the enzymatic activities of the corresponding subcellular fractions, data not shown) is detected between the Tat-proficient wild-type strain and the Tat-defective Δtat mutant strain, our results clearly demonstrate that membrane translocation of ArgR occurs independently of a functional Tat system in E. coli.
Utilization of amino acids due to ArgR
To permit studies to be made on the physiological function of ArgR, the non-replicative vector pK18mob-argR-int was constructed to enable disruption of argR by homologous recombination (see “Materials and methods” section). The vector was used to transform P. taetrolens to kanamycin resistance and the correct integration was verified by PCR (data not shown). The resulting strain was named P. taetrolens::argR. An enzyme assay using l-Lys as a substrate yielded an activity below 0.01 µmol min−1 mg(protein)−1, whereas it was 0.43 µmol min−1 mg(protein)−1 for the wild type, thus confirming absence of racemase activity in the mutant.
In minimal medium (Stalon et al. 1967), we studied the utilization of 10 mM l-, and d-amino acids as a carbon source. Figure 3 shows that the basic amino acids d-Lys, l-Lys, d-Arg, l-Arg, and l-Orn were used to roughly the same extent by P. taetrolens wild type, whereas d-Orn enabled rather slow growth. Also, the enantiomers of Ala could be utilized as carbon source, whereas this was not the case with Met (data not shown). In contrast to this, P. taetrolens::argR was no longer able to utilize d-Lys, and also the utilization of d-Arg was strongly reduced, showing that ArgR plays a key role in the metabolization of these basic d-amino acids. The slightly influenced l-Orn utilization also observed remains unexplained but could indicate, for instance, regulatory interactions of the unknown amino acid degradation pathways. In addition to growth on the synthetic medium, also LB was assayed. It was observed that growth of P. taetrolens::argR was slightly retarded to a growth rate of 0.36 h−1 as compared to 0.59 h−1 for the wild type, which might indicate that ArgR is also generally involved in amino acid degradation. The addition of d-Ala did not influence the growth of the wild type or that of the mutant.
Discussion
The fractionation data obtained with the P. taetrolens arginine racemase clearly show that ArgR is located in the periplasm. Also, in E. coli transport of the ArgR protein into the periplasm and processing into its mature form takes place. The signal sequence present shows the typical tripartite structure characteristic of signal peptides, consisting of a positively-charged ‘n-region’, a central hydrophobic ‘h region’, and a polar ‘c-region that contains the signal peptidase cleavage site’. However, the sequence itself does not allow translocation to be attributed either via the twin-arginine translocation (Tat) pathway, or the general secretion (Sec) pathway (Palmer et al. 2005). We first suggested that ArgR is translocated via the Tat pathway, in particular since it requires pyridoxal-5′-phosphate (PLP) for activity and the Tat pathway translocates its substrates in their fully folded form, including integrated cofactors. One feature of Tat substrates is the eponymous twin-arginine motif at the boundary between the n- and the h-region. However, the ArgR signal peptide possesses only one arginine, suggesting that ArgR might be exported via the Sec pathway. Indeed, we experimentally confirmed that ArgR is translocated into the periplasm of E. coli independent of the Tat pathway and, therefore, must have been translocated via the Sec route. Generally, this pathway is used to transport proteins devoid of an attached cofactor through the membrane in an unfolded manner, whereas the Tat pathway is mainly used by cofactor-containing proteins. However, it has been demonstrated that some heme-cofactor-containing proteins are in fact translocated into the periplasm via the Sec pathway, followed by further post-translocational modifications, including heme-cofactor insertion. For example, the cytochromes MtrC and OmcA of the Gram-negative bacterium Shewanella oneidensis are first translocated across the cytoplasmic membrane using the Sec pathway, and undergo an extensive post-translocational maturation process inside the periplasm to become the heme-containing lipoproteins (Shi et al. 2008). Due to the Tat-independence of ArgR export and the incompatibility of the Sec pathway with transport of folded structures, our findings imply that the PLP cofactor of ArgR must have been added to the apoprotein in the periplasm. Otherwise, also the high activity in the periplasm is difficult to explain. Therefore, ArgR represents a new class of enzymes utilizing the Sec pathway, where protein and cofactor use different pathways to arrive in the periplasm, but details on these particular events are completely unknown yet.
As the growth experiments with P. taetrolens demonstrate, ArgR is a catabolic enzyme. It is necessary for efficient utilization of the two basic d-amino acids d-Lys, and d-Arg, and for d-Lys utilization it is even essential. For d-Arg utilization an additional activity might be present to compensate for the absence of ArgR, but this is not Alr. Alr is very specific, just utilizing d,l-Ala as a substrate. The localization of ArgR within the periplasm of P. taetrolens is surprising; but this could be related to its catabolic function. It might give the cell an advantage for substrate utilization. Since racemization occurs in the periplasm, the bacterium would then be equipped with fewer specific import systems. However, little is known about the import and catabolism of basic amino acids in Pseudomonas (Revelles et al. 2005; Yamanishi et al. 2007), and it should also be mentioned that according to genome information argR sequences exist which do not have a signal sequence and could be arginine racemases. For instance Q9KSE5 of Vibrio cholerae might be a cytosolic ArgR (Heidelberg et al. 2000). In P. taetrolens the genes adjacent to argR exhibit similarities to an N-acyl amino acid amidohydrolase and a protease (pfam: PF01546), respectively, which could indicate a relation of the entire gene cluster with catabolic activities.
As mentioned, the alanine racemase Alr of P. taetrolens is highly specific and acts on Ala only, as do all the other alanine racemases studied (Strych et al. 2000). Interestingly, Alr of P. taetrolens has slightly greater identity to the catabolic alanine racemase Alr2 of E. coli, also termed DadX, than to the biosynthetic alanine racemase Alr1. Due to this fact and the fact that in P. taetrolens alr is located adjacent to dadA, the latter gene predicted to encode the small subunit of a d-amino acid dehydrogenase, we initially thought that Alr served only catabolic purposes. However, in an attempt to inactivate alr of P. taetrolens we obtained only very poor growing colonies (data not shown). The possibility exists that the single alanine racemase in Pseudomonas serves both anabolic and catabolic purposes, as we found growth of P. taetrolens on d-alanine. The interaction of Alr with catabolism and anabolism deserves further study.
Due to the apparent similarity of the alanine racemases Alr and DadX and the fact that also ArgR sequences are annotated as alanine racemases, we inspected selected genomes of gammaproteobacteria for the occurrence and similarities of such racemases. We found only two genes in P. putida KT2440, one corresponding to alr of P. taetrolens, and the other to argR. A similar situation prevails in the P. putida strains GB-1, F1, W619, and further Pseudomonas species like P. aeruginosa PAO1. From these genomic data and our experimental analysis, it appears that the Pseudomonas strains mentioned have the arginine racemase with broad substrate specificity and just one alanine racemase. Whereas, a similar situation exists for V. cholerae O1 biovar eltor str. N16961 and Yersinia pestis CO92, the situation in Aeromonas salmonicida subsp. salmonicida A449 is different. This bacterium has the arginine racemase, together with two alanine racemases. These two alanine racemases have 67% identity, with that encoded by ASA_3286 (gi: 4995230) probably serving anabolic purposes due to its genomic context. Thus, with respect to the two paraloguous alanine racemases, the situation in A. salmonicida resembles that in E. coli which has the two alanine racemases dadX (alr2) and alr (alr1) (Yamanishi et al. 2007), both specific for alanine, and one for anabolism and one for catabolism, with alr2 probably expressed on demand. A distinction between the catabolic and anabolic alanine racemases based on sequence identities only is less evident, and this is probably not surprising due to the identical substrate and mechanism they use.
References
Bendtsen JD, Nielsen H, von Heijne G, Brunak S (2004) Improved prediction of signal peptides: SignalP 3.0. J Mol Biol 340:783–795
Blaudeck N, Kreutzenbeck P, Freudl R, Sprenger GA (2003) Genetic analysis of pathway specificity during posttranslational protein translocation across the Escherichia coli plasma membrane. J Bacteriol 185:2811–2819
Chen HP, Lin CF, Lee YJ, Tsay SS, Wu SH (2000) Purification and properties of ornithine racemase from Clostridium sticklandii. J Bacteriol 182:2052–2054
Craven GR, Steers E Jr, Anfinsen CB (1965) Purification, composition, and molecular weight of the beta-galactosidase of Escherichia coli K12. J Biol Chem 40:2468–2477
Heidelberg JF, Eisen JA, Nelson WC, Clayton RA, Gwinn ML, Dodson RJ, Haft DH, Hickey EK, Peterson JD, Umayam L, Gill SR, Nelson KE, Read TD, Tettelin H, Richardson D, Ermolaeva MD, Vamathevan J, Bass S, Qin H, Dragoi I, Sellers P, McDonald L, Utterback T, Fleishmann RD, Nierman WC, White O, Salzberg SL, Smith HO, Colwell RR, Mekalanos JJ, Venter JC, Fraser CM (2000) DNA sequence of both chromosomes of the cholera pathogen Vibrio cholerae. Nature 406:477–483
Inagaki K, Tanizawa K, Tanaka H, Soda K (1984) Purification and properties of amino acid racemase from Aeromonas punctata subsp. caviae. Prog Clin Biol Res 144A:355–363
Kino K, Sato M, Yoneyama M, Kirimura K (2007) Synthesis of DL-tryptophan by modified broad specificity amino acid racemase from Pseudomonas putida IFO 12996. Appl Microbiol Biotechnol 73:1299–1305
Kovach ME, Elzer PH, Hill DS, Robertson GT, Farris MA, Roop RM 2nd, Peterson KM (1995) Four new derivatives of the broad-host-range cloning vector pBBR1MCS, carrying different antibiotic-resistance cassettes. Gene 166:175–176
Kreutzenbeck P, Kröger C, Lausberg F, Blaudeck N, Sprenger GA, Freudl R (2007) Escherichia coli twin arginine (Tat) mutant translocases possessing relaxed signal peptide recognition specificities. J Biol Chem 282:7903–7911
Lim YH, Yokoigawa K, Esaki N, Soda K (1993) A new amino acid racemase with threonine alpha-epimerase activity from Pseudomonas putida: purification and characterization. J Bacteriol 175:4213–4217
Morita YS, Sena CB, Waller RF, Kurokawa K, Sernee MF, Nakatani F, Haites RE, Billman-Jacobe H, McConville MJ, Maeda Y, Kinoshita T (2006) PimE is a polyprenol-phosphate-mannose-dependent mannosyltransferase that transfers the fifth mannose of phosphatidylinositol mannoside in mycobacteria. J Biol Chem 281:25143–25155
Nelson KE, Weinel C, Paulsen IT, Dodson RJ, Hilbert H, Martins dos Santos VA, Fouts DE, Gill SR, Pop M, Holmes M, Brinkac L, Beanan M, DeBoy RT, Daugherty S, Kolonay J, Madupu R, Nelson W, White O, Peterson J, Khouri H, Hance I, Chris Lee P, Holtzapple E, Scanlan D, Tran K, Moazzez A, Utterback T, Rizzo M, Lee K, Kosack D, Moestl D, Wedler H, Lauber J, Stjepandic D, Hoheisel J, Straetz M, Heim S, Kiewitz C, Eisen JA, Timmis KN, Düsterhöft A, Tümmler B, Fraser CM (2002) Complete genome sequence and comparative analysis of the metabolically versatile Pseudomonas putida KT2440. Environ Microbiol 4:799–808
Oikawa T, Tauch A, Schaffer S, Fujioka T (2006) Expression of alr gene from Corynebacterium glutamicum ATCC 13032 in Escherichia coli and molecular characterization of the recombinant alanine racemase. J Biotechnol 125:503–512
Okubo Y, Yokoigawa K, Esaki N, Soda K, Kawai H (1999) Characterization of psychrophilic alanine racemase from Bacillus psychrosaccharolyticus. Biochem Biophys Res Commun 256:333–340
Ono K, Yanagida K, Oikawa T, Ogawa T, Soda K (2006) Alanine racemase of alfalfa seedlings (Medicago sativa L.): first evidence for the presence of an amino acid racemase in plants. Phytochemistry 67:856–860
Palmer T, Sargent F, Berks BC (2005) Export of complex cofactor-containing proteins by the bacterial Tat pathway. Trends Microbiol 13:175–180
Revelles O, Espinosa-Urgel M, Fuhrer T, Sauer U, Ramos JL (2005) Multiple and interconnected pathways for l-lysine catabolism in Pseudomonas putida KT2440. J Bacteriol 187:7500–7510
Roise D, Soda K, Yagi T, Walsh CT (1984) Inactivation of the Pseudomonas striata broad specificity amino acid racemase by d and l isomers of beta-substituted alanines: kinetics, stoichiometry, active site peptide, and mechanistic studies. Biochemistry 23:5195–5201
Schlesinger MJ, Olsen R (1968) Expression and localization of Escherichia coli alkaline phosphatase synthesized in Salmonella typhimurium cytoplasm. J Bacteriol 96:1601–1605
Shi L, Deng S, Marshall MJ, Wang Z, Kennedy DW, Dohnalkova AC, Mottaz HM, Hill EA, Gorby YA, Beliaev AS, Richardson DJ, Zachara JM, Fredrickson JK (2008) Direct involvement of type II secretion system in extracellular translocation of Shewanella oneidensis outer membrane cytochromes MtrC and OmcA. J Bacteriol 190:5512–5516
Stalon V, Ramos F, Piérard A, Wiame JM (1967) The occurrence of a catabolic and an anabolic ornithine carbamoyltransferase in Pseudomonas. Biochim Biophys Acta 139:91–97
Strych U, Huang HC, Krause KL, Benedik MJ (2000) Characterization of the alanine racemases from Pseudomonas aeruginosa PAO1. Curr Microbiol 41:290–294
Wild J, Hennig J, Lobocka M, Walczak W, Kłopotowski T (1985) Identification of the dadX gene coding for the predominant isozyme of alanine racemase in Escherichia coli K12. Mol Gen Genet 198:15–22
Yagi T, Misono H, Kurihara N, Yamamoto T, Soda K (1980) l-Lysine: 2-oxoglutarate 6-aminotransferase. Subunit structure composed of non-identical polypeptides and pyridoxal 5'-phosphate-binding subunit. J Biochem 87:1395–1402
Yamanishi Y, Mihara H, Osaki M, Muramatsu H, Esaki N, Sato T, Hizukuri Y, Goto S, Kanehisa M (2007) Prediction of missing enzyme genes in a bacterial metabolic network. Reconstruction of the lysine-degradation pathway of Pseudomonas aeruginosa. FEBS J 274:2262–2273
Yorifuji T, Ogata K (1971) Arginine racemase of Pseudomonas graveolens. I. Purification, crystallization, and properties. J Biol Chem 246:5085–5092
Yorifuji T, Misono H, Soda K (1971) Arginine racemase of Pseudomonas graveolens. II. Racemization and transamination of ornithine catalyzed by arginine racemase. J Biol Chem 246:5093–5101
Acknowledgement
We thank A. Tauch (Bielefeld University, Germany) for support with preparation of integration mutants, Y. Gougami (Kansai University) for support with sequencing, and T. Polen (Forschungszentrum Juelich) for help with automatic blast analyses.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Matsui, D., Oikawa, T., Arakawa, N. et al. A periplasmic, pyridoxal-5′-phosphate-dependent amino acid racemase in Pseudomonas taetrolens . Appl Microbiol Biotechnol 83, 1045–1054 (2009). https://doi.org/10.1007/s00253-009-1942-7
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00253-009-1942-7