Thermotoga maritima 3-Deoxy-D-arabino-heptulosonate 7-Phosphate (DAHP) Synthase

THE ANCESTRAL EUBACTERIAL DAHP SYNTHASE?*

Jing Wu, David L. Howe and Ronald W. Woodard {ddagger}

From the Departments of Medicinal Chemistry and Chemistry, University of Michigan, Ann Arbor, Michigan 48109-1065

Received for publication, May 2, 2003


    ABSTRACT
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
The gene encoding the 3-deoxy-D-arabino-heptulosonate 7-phosphate (DAHP) synthase from the thermophilic microorganism Thermotoga maritima was cloned, and the enzyme was overexpressed in Escherichia coli. The purified DAHP synthase displays a homotetrameric structure and exhibits maximal activity at 90 °C. The enzyme is extremely thermostable, with 50% of its initial activity retained after incubation for ~5 h at 80 °C, 21 h at 70 °C, and 86 h at 60 °C. The enzyme appears to follow Michaelis-Menten kinetics with Km for phosphoenolpyruvate = 9.5–13 µM, Km for D-erythrose 4-phosphate = 57.3–350.1 µM, and kcat = 2.3–7.6 s1 between 50 °C and 70 °C. Metal analysis indicates that DAHP synthase as isolated contains Zn2+, and the enzyme is inactivated by treatment with EDTA. The apo-enzyme is partially reactivated by a variety of divalent metals including Zn2+, Cd2+, Mn2+, Cu2+, Co2+, and Ni2+. These observations suggest that T. maritima DAHP synthase is a metalloenzyme. The activity of T. maritima DAHP synthase is inhibited by two of the three aromatic amino acids (L-Phe and L-Tyr) formed in the Shikimate pathway. This report is the first description of a thermophilic eubacterial DAHP synthase.


    INTRODUCTION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
The enzyme 3-deoxy-D-arabino-heptulosonate 7-phosphate (DAHP)1 synthase (EC 4.1.2.15 [EC] ) catalyzes the condensation of phosphoenolpyruvate (PEP) and erythrose 4-phosphate (E4P) to form DAHP and inorganic phosphate. The formation of DAHP is the first committed step in the Shikimate pathway. This pathway is responsible for the biosynthesis of the intermediate compounds, chorismate and prephenate, which are precursors to the aromatic amino acids (Phe, Tyr, and Trp), catechols, and p-aminobenzoic acid (folic acid biosynthesis) as well as a number of other highly important microbial compounds (1).

DAHP synthases exist in most microorganisms and plants. Based on phylogenetic analysis, this protein family has been separated into two classes, Class I and Class II, by Birck and Woodard (2). Alternatively, Jensen and co-workers (3, 4) classified DAHP synthases into two distinct homology families (AroAI and AroAII). The AroAII family was defined as "plant-like" DAHP synthases that included the higher plant proteins and a cluster of microbial proteins (5). The AroAI family was further divided into subfamilies AroAI{alpha} and AroAI{beta}, which correspond to Class II and Class I, respectively (4). Escherichia coli expresses three DAHP synthase isoenzymes that are representative of Class II or the AroAI{alpha} family and require a divalent metal for activity (6). Each of the isoenzymes is specifically feedback-inhibited by only one of the three aromatic amino acids, Phe, Tyr, or Trp (7). The Bacillus subtilis DAHP synthase, which is representative of Class I or the AroAI{beta} family, is inhibited by the intermediates prephenate and chorismate in the Shikimate pathway and has been reported by Jensen and Nester (8, 9) to be insensitive to EDTA treatment and was thus proposed as a non-metalloenzyme (2).

Based on the total lack of any information of a DAHP synthase from a thermophile, an investigation of a DAHP synthase from a thermophilic eubacterium was initiated in order to provide further insight into the biochemical reason for the bifurcation in the DAHP synthase phylogenetic tree. The extreme thermophile Thermotoga maritima DAHP synthase, which belongs to Class I (or the AroAI{beta} subfamily), was chosen for this study. Evolutionary studies have placed this bacterium in one of the deepest and most slowly evolving branches of the domain Bacteria (10, 11). Thus, studies on the DAHP synthase from this bacterium should provide a better understanding of the divergence of the two classes of DAHP synthase and the evolution of the aldol-like condensation catalyzed by this enzyme family.

Herein the cloning, overexpression, purification, and biochemical characterization of the T. maritima DAHP synthase are reported. The metal requirements and feedback inhibition profile of the enzyme are also reported. This is the first description of a thermophilic eubacterial DAHP synthase.


    EXPERIMENTAL PROCEDURES
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Materials and General Methods—Genomic T. maritima DNA was purchased from ATCC (ATCC 43589D). The Promega Wizard DNA purification kit was utilized for plasmid isolation and purification. The E. coli cells, XL1-Blue and BL21(DE3), were obtained from Stratagene Cloning System and Novagen, respectively. Restriction enzymes and T4 DNA ligase were purchased from New England Biolabs. Thermal cycling was performed using an MJR Research Thermal Cycler. DNA sequencing and primer syntheses were performed by the University of Michigan Biomedical Resources Core Facility. The PEP mono(cyclo-hexylammonium) salt, E4P sodium salt, D-arabinose 5-phosphate disodium salt, 2-deoxyribose 5-phosphate sodium salt, D-ribose 5-phosphate disodium salt, reagent grade chorismate, shikimate, and prephenate were obtained from Sigma. Puratronic grade NiCl2, MgCl2, CoCl2, MnCl2, CdCl2, FeSO4, CuSO4, ZnSO4, and HCl (99.999%, metal basis) were purchased from Alfa Aesar. The 1,3-bis[tris(hydroxymethyl)methylamino]propane (BTP) was purchased from Research Organics. The EDTA disodium salt was obtained from Mallinckrodt. High grade Spectra/Por® 7 dialysis tubing (Mr 10,000 cutoff and metal-free) was obtained from VWR Scientific. The Mono Q (HR10/10), Phenyl Superose (HR10/10), Superose 12 (HR10/30), and FAST Desalting (HR10/10) chromatography columns were from Amersham Biosciences.

Protein concentrations were determined using the Bio-Rad Protein Assay Reagent, with bovine serum albumin (Sigma) serving as the standard. Optical spectroscopy was performed using a HP 8453 UV-visible spectrophotometer. Unless otherwise stated, the pH of all buffers was measured at 25 °C, and all purification steps were performed at 25 °C.

Construction of Plasmids—Standard polymerase chain reaction methodologies were used to amplify the aroG-like gene (gi:7448834) from T. maritima genomic DNA. The forward primer was GATTCTGAATTCATATGATAGTCGTTTTGAAACCCGG, and the reverse primer was GATTCTGAATTCGGATCCTCAATTCACCTTCACCCCC. The amplification product was isolated, restricted with NdeI and BamHI (underlined), and ligated into the similarly restricted expression vector, pT7-7. The ligation mixture was used to transform E. coli XL1-Blue cells. The presence of plasmids containing the desired gene from several transformants was verified by restriction analysis, and the gene sequence was confirmed by DNA sequencing. One plasmid with the correct sequence, pT7-aroG, was used to transform chemically competent E. coli BL21(DE3) cells.

Overexpression and Purification of DAHP Synthase—The E. coli BL21(DE3) cells harboring the pT7-aroG plasmid were grown in 2x YT medium containing ampicillin (100 mg/liter) at 37 °C with shaking (220 rpm). Isopropyl-{beta}-D-thiogalactoside was added to a final concentration of 0.4 mM when the culture reached an absorbance of 1.5. The cells were harvested 4 h after induction by centrifugation (29,000 x g, 20 min, 4 °C), the pellet was suspended in 20 mM Tris-HCl (pH 7.5), and the suspension was subjected to sonication on ice (30-s pulses with a 2-min rest between pulses, five times). The crude extract was centrifuged to remove cell debris (40,000 x g, 30 min, 4 °C).

Solid sodium chloride was added to the supernatant (typically, a solution of 40 ml containing 400 mg of total protein is obtained from a 1.0-liter culture) to a final concentration of 0.1 M, and the solution was heated at 80 °C for 1.5 min and then heated at 60 °C for 10 min with gentle continuous hand swirling. The suspension was allowed to cool to 25 °C and placed on ice for 15 min, and the precipitated protein was removed by centrifugation (29,000 x g, 20 min, 4 °C). The supernatant (32 ml; 64 mg of total protein) was dialyzed against 1 liter of buffer A (20 mM Tris-HCl, pH 7.5) overnight at 4 °C and then applied to a Mono Q column (HR 10/10) pre-equilibrated with buffer A. The column was developed at a flow rate of 1.0 ml/min using a linear gradient from 0 to 0.5 M potassium chloride in the same buffer over 50 min. The fractions containing DAHP synthase activity as determined by the discontinuous assay were pooled (14 ml; 48 mg of total protein). Solid (NH4)2SO4 was slowly added with stirring to the pooled fractions to a final concentration of 25% (w/v). The sample was filtered (0.22 µm) and loaded onto a Phenyl Superose column (HR 10/10) equilibrated with 25% (NH4)2SO4 in buffer A. A reverse gradient from 25% to 0% (NH4)2SO4 in buffer A was applied at a flow rate of 1.0 ml/min over 60 min, and elution was continued with buffer A for 20 min. The fractions containing DAHP synthase activity were pooled and dialyzed against 2 liters of buffer A overnight at 4 °C. The final preparation was homogeneous as determined by SDS-PAGE. The purified enzyme was aliquoted and stored at –80 °C.

DAHP Synthase Activity Assay—The DAHP synthase activity was determined by either discontinuous colorimetric assay or continuous spectrophotometric assay. One unit of enzyme activity is defined as the production of 1 µmol of DAHP or the disappearance of 1 µmol of PEP per minute. The standard discontinuous colorimetric assay was measured in a final volume of 50 µl containing PEP (3 mM), DAHP synthase (varying amounts), and Tris acetate buffer (100 mM, pH 7.5) using thin-walled PCR tubes as the reaction vessel. The assay solution was preincubated at the desired temperature (2 min) utilizing a thermal cycler as a heat block, and the reaction was initiated by the addition of E4P to a final concentration of 3 mM. After the appropriate incubation times, the reaction was quenched by the addition of 50 µl of 10% (w/v) ice-cold trichloroacetic acid. The amount of DAHP produced was quantitated using a modified Aminoff periodate-thiobarbituric acid assay (12). The continuous spectrophotometric assay measures the disappearance of the {alpha},{beta}-unsaturated carbonyl absorbance ({tau} = 232 nm, {epsilon} = 2,840 M–1 cm1) of PEP in an assay mixture containing 100 mM Tris acetate buffer (pH 7.5), 300 µM PEP, 600 µM E4P, and 20–80 nM DAHP synthase.

Molecular Weight Determinations—The subunit molecular weight of DAHP synthase was determined by SDS-PAGE. SDS-PAGE was performed under reducing conditions on a 12% polyacrylamide gel with a Mini-PROTEAN II electrophoresis unit (Bio-Rad) and visualized with 0.25% Coomassie Brilliant Blue R250 stain. The native molecular weight of DAHP synthase was determined by gel filtration utilizing a Superose 12 column (HR10/30) according to the manufacturer's instructions (Sigma). The elution volume was determined in triplicate for all samples and standards. pH Dependence of DAHP Synthase—The activity of the enzyme (1 µM) was measured between pH 4.5 and 8.5 at 60 °C by discontinuous assay described above using either 2-(N-morpholino)ethanesulfonic acid (pH 4.5–6.0), Tris acetate (pH 6.0–8.0), or glycylglycine (pH 8.0–8.5) at a concentration of 100 mM each. The pH values of the buffer solutions were measured at 60 °C. Reactions were carried out at the respective pH values for 30 s.

Temperature Dependence and Thermostability of DAHP Synthase— Temperature dependence of the enzyme activity was determined by measuring the activity between 30 °C and 100 °C in 3 mM PEP, 3 mM E4P, 1 µM enzyme, and 100 mM Tris-HCl buffer using the discontinuous colorimetric assay. Because the pH of Tris buffer is quite temperature-dependent, the pH of each buffer was adjusted to pH 7.0 at the desired temperatures. For each temperature, the enzyme activity was measured by preincubating the Tris-HCl buffer for 2 min to allow it to reach the final pH of 7.0. A mixture of PEP and DAHP synthase (held at 25 °C in a small volume relative to the main reaction mixture) was then added, and the entire reaction mixture was incubated for 1 min. The reaction was initiated by the addition of E4P and allowed to proceed for an additional 30 s. The thermostability of the enzyme was determined by incubating the purified enzyme (5.3 µM) in 100 mM Tris acetate (pH 7.5) at 60 °C, 70 °C, or 80 °C. At various times, aliquots of enzymes were removed, centrifuged, and assayed for residual activity at the respective incubation temperatures by the discontinuous colorimetric assay.

Kinetic Studies—Reactions were carried out separately by continuous assay at 50 °C, 60 °C, and 70 °C in 100 mM Tris acetate (pH 7.5) and 50 µM MnCl2. The concentration of one substrate was held constant (10 x Km), whereas the other was varied over the range of 0.1–10 x Km.

Feedback Inhibition—Feedback inhibition of DAHP synthase was determined by incubating 0.5 µM enzyme and 3 mM PEP with a fixed concentration of possible inhibitor (1 mM) in 100 mM Tris acetate (pH 7.5) on ice for 40 min. The enzymatic activity was measured at 60 °C by discontinuous assay. Reactions were carried out for 3 min. Addition of the inhibitor after the enzymatic reaction but before the assay served as a control for potential interference of the inhibitor with the colorimetric assay.

Preparation of Apo-DAHP Synthase—The DAHP synthase used for metal studies was purified by a modification of the method described above. The cells were suspended and sonicated in 10 mM BTP buffer (pH 7.0) instead of Tris-HCl buffer. The heat-treated supernatant containing the enzyme was diluted 2-fold with buffer B (10 mM BTP buffer, pH 7.0) containing 1 mM PEP and applied to a Mono Q column (HR 10/10) equilibrated with buffer B. The column was developed at a flow rate of 1.5 ml/min using a linear gradient from 0 to 0.3 M potassium chloride in buffer B over 80 min. PEP was added immediately to the fractions containing DAHP synthase to a final concentration of 0.5 mM. The pooled fractions were concentrated by ultrafiltration (Centriprep YM-10 concentrator) to 8 mg/ml and used immediately in the following studies.

The freshly purified DAHP synthase was treated with 10 mM EDTA in buffer B containing 0.5 mM PEP for 2 h at 25 °C and then dialyzed against 500 ml of buffer C (metal-free 10 mM BTP, pH 7.0, 0.5 mM PEP) for 24 h at 25 °C with two buffer changes. The metal-free BTP buffer was prepared from Chelex 100 Resin-treated 1 M BTP, metal-free HCl, and distilled deionized water (PURELAB Plus System).

Dependence of DAHP Synthase Activity on Metals—To investigate the metal dependence of DAHP synthase activity, divalent metal ions were added to the continuous assay mixture, and the assay was performed as described above with the following modification. A metal-free 20 mM BTP buffer solution (pH 7.0) in a 1-ml cuvette was first incubated at 60 °C for 5 min before the addition of PEP, apo-enzyme (78 nM), and metal salt (10 µM). The entire reaction mixture was held at 60 °C for an additional 5 min. The reaction was initiated by the addition of E4P, and the progress of the reaction was monitored for 2 min.

The stoichiometry of DAHP synthase metal binding was determined by adding a 4-fold molar excess of metal salt per enzyme subunit to the apo-enzyme (100 µM) in buffer C. Samples were incubated at 25 °C for 2 h, centrifuged, and then applied to a Fast Desalting column (HR 10/10), previously equilibrated with buffer C, to remove excess metal salts from the protein-metal complex. The column was developed at a flow rate of 0.75 ml/min using the same buffer. The fraction eluting between 2.5 and 3.3 min post-sample injection containing the protein was collected. The protein concentration and enzymatic activity of each protein-metal complex were determined immediately. The identity and quantity of metals in the enzyme preparations and buffer solutions were determined by high-resolution inductively coupled plasma mass spectrometry on a Finnigan MAT ELEMENT instrument at the W. M. Keck Elemental Geochemistry Laboratory (Department of Geology, University of Michigan) by Dr. Ted Huston. In a separate experiment, the apo-enzyme was incubated with a mixture of the metal salts containing 1 molar equivalent of each metal per enzyme subunit (see Table IV), desalted, and analyzed as described above.


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TABLE IV
Metal analysis of DAHP synthase

Apo-DAHP synthase (100 µM) was incubated with the metal salt (400 µM) at 25 °C for 2 h and then applied to gel filtration. The protein fraction was subjected to protein assay, continuous enzyme assay at 60 °C, and metal analysis as described under "Experimental Procedures."

 

To determine the metal content of the enzyme directly after purification, the enzyme as isolated was dialyzed against 1 liter of buffer B overnight at 25 °C. In another experiment, the enzyme as isolated was treated with a 4-fold molar excess of Zn2+ per subunit for 2 h at 25 °C and then dialyzed against 2 liters of buffer B overnight. The dialyzed enzyme samples were assayed for protein concentration and enzymatic activity and subjected to metal analysis as described above. As a control, the metal content of the dialysis buffer after dialysis was analyzed.

The time dependence of Cu2+ binding to T. maritima apo-DAHP synthase was determined by adding CuSO4 (400 µM, final concentration) to 100 µM apo-enzyme in buffer C that had been preincubated for 5 min at 37 °C. Spectra were taken 5, 10, and 30 min after addition of Cu2+ at 37 °C.

Sequence Alignments—Sequences were aligned using Clustal W (13).


    RESULTS
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Overexpression and Purification of the Enzyme—The T. maritima DAHP synthase was highly overexpressed in E. coli BL21(DE3) cells harboring the pT7-aroG plasmid. The purification procedure was developed by taking advantage of the expected thermal stability of the protein. Heat treatment of the cell extract resulted in substantial precipitation of the host cell proteins, whereas negligible loss of total enzymatic activity was observed. After two chromatographic steps, the recombinant protein was determined to be homogeneous by SDS-PAGE. The typical yield of purified protein was 30–40 mg/liter cell culture.

Physical Properties—The molecular weight of the purified enzyme as determined by SDS-PAGE was 38,000. The molecular weight of the native enzyme determined by analytical gel filtration chromatography was 134,000, 3.5 times the molecular weight determined by SDS-PAGE. For comparison, the Phe-sensitive E. coli DAHP synthase (David L. Howe, this laboratory) was subjected to similar analysis. The molecular weight of the native E. coli enzyme is 3.4 times that of its monomer. Based on its crystal structure, E. coli DAHP synthase (Phe-sensitive) has been assumed to be that of a tetramer (14). Therefore, T. maritima enzyme is likely to adopt a tetrameric structure.

pH Optimum—The purified enzyme exhibited the highest enzymatic activity (>90% of maximum) between pH 6.0 and 7.0, with an optimum of pH 6.3 at 60 °C (Fig. 1).



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FIG. 1.
Optimal pH of DAHP synthase. Enzymatic activity was measured at 60 °C in 100 mM 2-(N-morpholino)ethanesulfonic acid (pH 4.5–6.0), Tris acetate (pH 6.0–8.0), or glycylglycine (pH 8.0–8.5) by discontinuous assay. The pH of the buffer solutions was measured at the 60 °C. Error bars correspond to the standard deviation of three determinations.

 

Temperature Optimum and Thermostability—During preliminary experiments, it was determined that the substrate PEP is about 10 times more stable at higher temperatures than the other substrate, E4P (data not shown). Based on these findings, the enzyme assays were carried out by preincubation of PEP and enzyme at a desired temperature. The reaction was then initiated by the addition of E4P, and the substrates were allowed to react for 30 s after the addition of E4P. The reaction rates were measured under initial rate conditions between 30 °C and 80 °C (data not shown). Enzyme activities at higher temperatures could not be measured accurately due to the thermal instability of E4P. Under these restricting reaction conditions, the temperature optimum was found to be 90 °C (Fig. 2). An Arrhenius plot of the data (Fig. 2, inset) showed a transition point at 60 °C, resulting in activation energy values of 62 kJ/mol between 30 °C and 60 °C and 51 kJ/mol between 60 °C and 80 °C.



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FIG. 2.
Optimal temperature of DAHP synthase. Enzymatic activity was measured using 3 mM PEP, 3 mM E4P in 100 mM Tris-HCl buffer (pH 7.0 at each desired temperature) by the discontinuous colorimetric assay. Error bars correspond to the standard deviation of three determinations. Inset, Arrhenius plot of the data from 30 °C to 80 °C.

 

The thermostability of the purified DAHP synthase was determined at 60 °C, 70 °C, and 80 °C (Fig. 3). After 9 h of incubation at 60 °C, maximum DAHP synthase activity was reached as compared with that of the enzyme as isolated when assayed at 60 °C. Further incubation at 60 °C resulted in diminished activity. No significant gain or loss of enzyme activity was observed for the first 5 h at 70 °C; however, the enzyme activity appeared to decrease exponentially after 5 h. When incubated at 80 °C, a simple exponential decay was observed. As shown in Fig. 3, 50% of the enzyme activity was retained after ~5 h (80 °C), 21 h (70 °C), and 86 h (60 °C) of incubation.



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FIG. 3.
Thermal stability of DAHP synthase. Enzyme (5.3 µM) was incubated in 100 mM Tris acetate buffer (pH 7.5) at 60 °C ({blacksquare}, inset), at 70 °C (•), or at 80 °C ({diamondsuit}). At various intervals, aliquots of the samples were removed and assayed for residual activity at the respective incubation temperature by the discontinuous colorimetric assay. Error bars correspond to the standard deviation of three determinations.

 

Kinetic Studies—The kinetic constants of DAHP synthase were determined for E4P and PEP under saturating conditions at various temperatures (Table I). The enzyme exhibited Michaelis-Menten kinetics with Km for PEP = 9.5–13 µM, Km for E4P = 57.3–350.1 µM, and kcat = 2.3–7.6 s1 between 50 °C and 70 °C. The Km value for E4P increased with increasing temperature, whereas the Km for PEP was not greatly affected by temperature.


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TABLE I
Kinetic constants of DAHP synthase at various temperatures

The activities of the enzyme (26 nM) were measured in 100 mM Tris-acetate (pH 7.5) and 50 µM Mn2+ by the continuous assay at 50 °C, 60 °C, and 70 °C. The results are the averages of triplicate assays.

 

Feedback Inhibition—The data in Table II illustrate the effects of possible feedback inhibitors on DAHP synthase activity. The results showed that L-Phe and L-Tyr significantly inhibited T. maritima DAHP synthase with only 32% and 23% of activity remaining, respectively. The compounds L-Trp, chorismate, shikimate, prephenate, D-Phe, and L-His had no effect on enzymatic activity under the experimental conditions.


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TABLE II
Feedback inhibition of DAHP synthase

The enzyme (0.5 µM) was incubated with 3 mM PEP and a fixed concentration of possible inhibitor (1 mM) in 100 mM Tris-acetate (pH 7.5) on ice for 40 min. The reaction was initiated by the addition of 3 mM E4P at 60 °C. Activities were measured by the discontinuous assay. The results are the averages of triplicate assays.

 

Metal Requirement—The results from the metal analysis studies demonstrated that the enzyme as isolated contains ~0.20 mol equivalent of Zn2+ per subunit and trace amounts of other metals (Table IV). Furthermore, when the above-mentioned enzyme was incubated with a 4-fold molar excess of Zn2+ per subunit and then dialyzed to remove non-bound Zn2+, 70% more Zn2+ was incorporated, yet the specific activity was unchanged. To investigate the metal requirements for DAHP synthase activity, the enzyme as isolated was treated with EDTA. EDTA inactivated the enzyme in a concentration-dependent manner (data not shown).

Apo-DAHP synthase was prepared by treating enzyme with 10 mM EDTA followed by extensive dialysis against metal-free buffer. The enzymatic activity was reduced to 0.6 unit/mg or 7% that of the untreated enzyme. The apo-enzyme was reconstituted by adding a divalent metal ion directly to the assay mixture (Table III). The results from these experiments demonstrated that Mn2+, Zn2+, Cd2+, Ni2+, Co2+, and Cu2+ restored the enzymatic activity to 3–5 units/mg, whereas Fe2+ and Mg2+ had little effect on enzyme activity.


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TABLE III
Activation of apo-DAHP synthase after preincubation with metals

The apo-enzyme (78 nM) was incubated with 300 µM PEP and metal salt (10 µM) in 20 mM BTP (pH 7.0) at 60 °C for 5 min. The reaction was initiated by the addition of 600 µM E4P at 60 °C. Activities were measured by the continuous assay. The results are the averages of triplicate assays.

 

In order to determine the stoichiometry of the enzyme-metal complex, the apo-enzyme was incubated with a 4-fold molar excess of metal salt per subunit followed by the removal of free metal by gel filtration. The protein-metal fraction was analyzed for specific activity and metal content. As can be seen from Table IV, the DAHP synthase binds twice as much Cd2+ and Zn2+ as Mn2+, Cu2+, Co2+, and Ni2+. When apo-enzyme was incubated with a mixture of metals (1 mol equivalent of each of the above metals per subunit), the DAHP synthase bound mainly Zn2+ and Cd2+ as well as a trace amount of the other metals. As can also be seen in Table IV, DAHP synthase activity was only partially restored. Furthermore, the Zn2+ reconstituted apo-enzyme could bind twice as much Zn2+ but only regained 72% of the specific activity as compared with the original enzyme.

Because Cu2+ has been shown to bind to a number of DAHP synthases, leading to a spectral signature that provided insight into the nature/identity of the enzyme's metal ligands (6, 15, 16), the effect of Cu2+ on the UV-visible spectra of T. maritima apo-DAHP synthase was examined. The addition of Cu2+ to apo-enzyme resulted in the time-dependent appearance of a new peak at ~365 nm (Fig. 4), consistent with previous reports that assigned this peak to be a ligand-to-metal charge transfer interaction with an active site thiolate and/or imidazole ion(s) of the enzyme (6).



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FIG. 4.
Absorption spectra of T. maritima DAHP synthase. A solution of CuSO4 (400 µM, final concentration) was added to 100 µM apo-enzyme in 10 mM BTP (pH 7.0) containing 0.5 mM PEP that had been preincubated for 5 min at 37 °C. Spectra were taken 5, 10, and 30 min after addition of Cu2+. The dashed curve is that of apo-DAHP synthase.

 

These results indicate that T. maritima DAHP synthase has a requirement for a divalent metal cofactor that can be satisfied by a range of divalent metal ions. Because Mn2+ has been used as the activating metal in the kinetic studies of DAHP synthase from E. coli (17, 18), it was also chosen for use in the kinetic studies of the T. maritima DAHP synthase. The Mn2+ concentration dependence of DAHP synthase activity demonstrated that the enzyme maintained its highest activity between 10 and 100 µM Mn2+ (data not shown). Therefore, 50 µM Mn2+ was added to the reaction buffers in the kinetic studies.


    DISCUSSION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Based on phylogenetic analysis, the DAHP synthase family has been divided into two classes or subfamilies (24). Several hypotheses have suggested various enzymatic properties that lead to the bifurcation seen between these two subdivisions (2, 4). In order to provide further insight into the properties of a unique member of this family that might lead to a more thorough understanding of the phylogenetic analysis, DAHP synthase from T. maritima was cloned, overexpressed, and characterized.

T. maritima DAHP synthase has a native molecular weight of ~134,000 and appears to consist of four identical subunits of Mr 38,000. As expected for a thermophilic enzyme, T. maritima DAHP synthase reached maximum activity at 90 °C, was virtually inactive at 37 °C, and showed a high thermostability (19). DAHP synthase from T. maritima appears to follow Michaelis-Menten kinetics. The Km value for E4P increases with increasing temperature, whereas the Km for PEP is not greatly affected by temperature (Table I). These Km values compare favorably with those reported from other microorganisms (2023). Unlike the three isoforms of DAHP synthases from E. coli (aroG, aroF, and aroH, each of which is specifically feedback-inhibited by only one of the three aromatic amino acids, Phe, Tyr, and Trp, respectively) (7), T. maritima DAHP synthase is inhibited by both Phe and Tyr, but not by Trp (Table II).

The recombinant enzyme as isolated from E. coli contained only 0.20 Zn2+ ion/enzyme subunit (Table IV). Additional Zn2+ (0.14 Zn2+/subunit; total, 0.34 Zn2+/subunit) bound to the enzyme as isolated without further increase in specific activity. Zn2+ (0.28 and 0.29 Zn2+/subunit, respectively) has also been found to bind to the Trp- and Tyr-sensitive DAHP synthases from E. coli (6) in combination with 0.26 and 0.19 Fe2+/subunit, respectively. Only trace quantities of Zn2+ were found in the E. coli Phe-sensitive form (6). The recombinant 3-deoxy-D-manno-octulosonate 8-phosphate (KDO8P) synthase from Aquifex aeolicus (24) also contains both Zn2+ and Fe2+ (0.42 Zn2+/subunit and 0.31 Fe2+/subunit). In addition, the recombinant KDO8P synthase from Heliobacter pylori (25) was reported to contain 1 Zn2+/subunit. KDO8P synthase and DAHP synthase are structurally and mechanistically related and probably originated from a common ancestor (2, 14, 2628). It is possible that any Fe2+ present in the original T. maritima DAHP synthase was oxidized to Fe3+ that can bind in the Fe2+ site, thus allowing more Zn2+ to bind. Crystal structures suggest that the active site metal binds to the four same residues in A. aeolicus KDO8P synthase (Cys11, His185, Glu222, and Asp233 ligands to Cd2+) and E. coli Phe-sensitive DAHP synthase (Cys61, His268, Glu302, and Asp326 ligands to Pb2+ or Mn2+) (14, 28, 29) in an octahedral geometry. These same active site residues are absolutely conserved in T. maritima and E. coli DAHP synthases as well as H. pylori KDO8P synthase. At this time, however, there is no direct evidence that the Zn2+ is bound to the same conserved active site amino acid residues. Whereas Zn2+ normally occupies the center of a tetrahedral or trigonal bipyramidal arrangement (30), it is possible that it may bind to the conserved amino acid residues in a non-octahedral arrangement.

Treatment of the enzyme as isolated with EDTA resulted in inactive enzyme that did not contain any metal ions (Table IV), thus the enzyme requires a metal ion for activity. The reconstituted apo-DAHP synthase bound twice as much Zn2+ as isolated, yet the reconstituted enzyme exhibited only 72% of the specific activity of the enzyme as isolated (Table IV). No other metal ion or combination of metal ions, at any concentration tested, could restore the activity of the apo-enzyme to that of the enzyme as isolated. This could be due to the instability of the apo-enzyme. Park and Bauerle (31) reported that E. coli apo-DAHP synthase (Phe-sensitive) is unstable due to an oxidation process; however, inclusion of PEP in the presence of BTP buffer was found to stabilize the apo-DAHP synthase against this inactivation. The authors proposed that this stabilization resulted from the ability of PEP to protect the active site residue, Cys328, from oxidation (31). The activity of the apo-DAHP synthase from T. maritima, in the present study, could not be restored to that of the enzyme as isolated with the addition of PEP in BTP buffer during purification and/or manipulation. It should be noted that Cys328 of the Phe-sensitive E. coli DAHP synthase is not conserved in the T. maritima enzyme, thus the lack of stabilization by PEP was not unexpected. Similarly, Baasov and Knowles (15) observed that E. coli DAHP synthase (Tyr-sensitive) as isolated contained 0.5 Cu2+/enzyme subunit; however, copper-reconstituted apo-enzyme, which contained 1.0 Cu2+/enzyme subunit, exhibited only 70% of the specific activity of enzyme as isolated, even in the presence of PEP. As seen with E. coli DAHP synthase (Tyr-sensitive), the apo-DAHP synthase from T. maritima could be reconstituted by Cu2+ and showed the characteristic spectrum for copper binding (Fig. 4), and the activity with Cu2+ was less than that of the enzyme as isolated. Unlike the E. coli DAHP synthase (Tyr-sensitive), the reconstituted DAHP synthase from T. maritima contained only 0.23 Cu2+/subunit (Table IV). Thus, overall, the metal requirements of the T. maritima DAHP synthase are quite similar to those reported for DAHP synthase from other microbial sources, except it contains less metal, and the apo-enzyme seems more unstable and thus less able to rebind metals in a catalytically competent manner.

In summary, DAHP synthase from the hyperthermophile T. maritima is (i) a thermostable enzyme, (ii) inhibited by both Phe and Tyr, and (iii) a metalloenzyme, although the endogenous metal cofactor remains to be defined.

Birck and Woodard (2) separated DAHP and KDO8P synthases individually into two classes: Class I and Class II. The difference between Class I and Class II KDO8P synthases has been shown to be their metal requirements. The difference between Class I and Class II DAHP synthases was proposed by Birck and Woodard (2) to be their metal requirements. This hypothesis was based on the facts that the DAHP synthase from B. subtilis Marburg 168, which is ascribed to Class I, was insensitive to EDTA treatment according to Jensen and Nester (8), and the three E. coli isoenzymes, which are ascribed to Class II, were known to require divalent metal ions for activity according to Stephens and Bauerle (6).

An alternative phylogenetic analysis suggested by Jensen and co-workers (3, 4) divided DAHP synthases into two families (AroAI and AroAII). The AroAI family was further divided into two subfamilies, AroAI{alpha} (exemplified by the E. coli DAHP synthases) corresponding to Class II and AroAIb (exemplified by the B. subtilis DAHP synthase) corresponding to Class I. KDO8P synthases were assigned as a single second group in the I{beta} clade portion of AroAI{beta} subgroup. It was suggested that the division between the two subfamilies could possibly be due to substrate specificity (4).

Phylogenetic analyses have placed the two hyperthermophiles, A. aeolicus and T. maritima, basal to all other bacteria (10, 11, 32). However, no DAHP synthase gene has been found in A. aeolicus based on annotated genome and homology searches.2 Therefore, we believed that the information obtained from the investigation of the biochemical properties of the DAHP synthase from T. maritima, which represents the earliest known diverging bacterial DAHP synthase for which a sequence is known, would help clarify what biochemical properties account for the differences among the various subdivisions.

As a Class I DAHP synthase, the T. maritima enzyme would be predicted to be a non-metalloenzyme if metal requirements were indeed the property that distinguishes Class I and II DAHP synthases. However, in the present study, T. maritima DAHP synthase is identified as a metalloenzyme, which provides the first direct evidence for the existence of a metalloenzyme in Class I. This was not unexpected because sequence alignment of various DAHP synthases demonstrates that the four metal-chelating residues in E. coli DAHP synthase (Phesensitive) are absolutely conserved in both Class I and Class II enzymes (Fig. 5). The insensitivity of B. subtilis DAHP synthase (Class I) to EDTA treatment to remove any bound metal, originally reported by Jensen and Nester (8), does not necessarily rule out a metal requirement for enzymatic activity. It has been reported for other metalloenzymes that EDTA is not effective at removing tightly bound metals (25). Studies on the metal requirements of other Class I DAHP synthases as well as a reinvestigation of the B. subtilis DAHP synthase metal requirements should provide a better understanding on this issue.



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FIG. 5.
Sequence alignment of DAHP synthases. Sequences were aligned using Clustal W (13). Invariant residues that are putative metal-binding sites are shaded (Cys61, His268, Glu302, and Asp326 based on amino acid sequence for E. coli Phe-sensitive DAHP synthase) (14, 27). The sequences are followed by their NCBI accession numbers.

 

Other than the metal requirement, allosteric effects have been postulated as a possible difference between the two classes of DAHP synthases (2). A broad diversity of feedback inhibition patterns has been observed for this enzyme family. In Class I, the B. subtilis enzyme is sensitive to the downstream intermediates in the Shikimate pathway (8, 9), chorismate and prephenate. T. maritima DAHP synthase (Class I), as discussed above, is feedback-inhibited by two of the three aromatic amino acids, Phe and Tyr. In Class II, each of the three E. coli isoenzymes is feedback-regulated by only one of the aromatic amino acids (7), whereas the DAHP synthase from Corynebacterium glutamicum (Class II) has been shown to be feedback-inhibited by both Phe and Tyr (33). The difference between Class I and Class II DAHP synthases, therefore, does not appear to be due to differences in allosteric effectors.

Finally, Jensen et al. (4) suggested that the division between the two subfamilies could be due to substrate specificity. According to this hypothesis, ancient DAHP synthase generally had broad substrate specificities and evolved to have differentially narrow substrate specificities. This implies that the more ancient AroAI{beta} subfamily would have broad substrate specificities, and the more recent AroAI{alpha} subfamily would have narrow substrate specificities. However, it has been shown that the AroAI{alpha} DAHP synthase (Phe-sensitive) from E. coli can utilize D-arabinose 5-phosphate, D-ribose 5-phosphate, and 2-deoxyribose 5-phosphate as alternate substrates (12) and that the AroAI{alpha} DAHP synthase from Neisseria gonorrhoeae can utilize D-arabinose 5-phosphate as an alternate substrate (34). On the other hand, neither D-arabinose 5-phosphate nor D-ribose 5-phosphate can be used as an alternate substrate for the AroAI{beta} DAHP synthases from T. maritima (data not shown) or B. subtilis.3 These experimental results do not support the hypothesis of Jensen et al. Therefore, it is likely that other biochemical properties must account for the phylogenetic distribution observed among DAHP synthases. Only after further experimentation with purified DAHP synthases from multiple sources from each subfamily will the true property(ies) that leads to the division be known.

In summary, T. maritima DAHP synthase is the first thermophilic eubacterial DAHP synthase to be characterized. The enzyme exhibits maximum activity at 90 °C but displays functional characteristics similar to its mesophilic counterparts. This could be the earliest known diverging bacterial DAHP synthase and provides a model to study the structural/functional features and the evolution of the DAHP synthase family. Results obtained from this study have allowed us to test the various hypotheses on the division of this enzyme family. Additional studies will attempt to characterize the DAHP synthase from a member of the Archaea family, which will provide deeper insight into the evolution of this enzyme family. Efforts are currently under way to obtain an x-ray crystal structure and assign the metal binding ligands for the zinc ion.


    FOOTNOTES
 
* This work was supported by National Institutes of Health Grant GM 53069 (to R. W. W.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. Back

{ddagger} To whom correspondence should be addressed: College of Pharmacy, 428 Church St., Ann Arbor, MI 48109-1065. Tel.: 734-764-7366; Fax: 734-763-2022; E-mail: rww{at}umich.edu.

1 The abbreviations used are: DAHP, 3-deoxy-D-arabino-heptulosonate 7-phosphate; E4P, D-erythrose 4-phosphate; PEP, phosphoenolpyruvate; BTP, 1,3-bis[tris(hydroxymethyl)methylamino]-propane; KDO8P, 3-deoxy-D-manno-octulosonate 8-phosphate. Back

2 R. W. Woodard, unpublished observation. Back

3 G. Y. Sheflyan, personal communication. Back


    ACKNOWLEDGMENTS
 
We thank Dr. Ted Huston (Department of Geology, University of Michigan) for performing the metal analysis studies and Dr. Matthew Birck and other members of the Woodard group for helpful discussions.



    REFERENCES
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 

  1. Walsh, C. T., Benson, T. E., Kim, D. H., and Lees, W. J. (1996) Chem. Biol. 3, 93–91[Medline] [Order article via Infotrieve]
  2. Birck, M. R., and Woodard, R. W. (2001) J. Mol. Evol. 52, 205–214[Medline] [Order article via Infotrieve]
  3. Subramaniam, P. S., Xie, G., Xia, T., and Jensen, R. A. (1998) J. Bacteriol. 180, 119–127[Abstract/Free Full Text]
  4. Jensen, R. A., Xie, G., Calhoun, D. H., and Bonner, C. A. (2002) J. Mol. Evol. 54, 416–423[Medline] [Order article via Infotrieve]
  5. Gosset, G., Bonner, C. A., and Jensen, R. A. (2001) J. Bacteriol. 183, 4061–4070[Abstract/Free Full Text]
  6. Stephens, C. M., and Bauerle, R. (1991) J. Biol. Chem. 266, 20810–20817[Abstract/Free Full Text]
  7. Brown, K. D., and Doy, C. H. (1966) Biochim. Biophys. Acta 118, 157–172[Medline] [Order article via Infotrieve]
  8. Jensen, R. A., and Nester, E. W. (1966) J. Biol. Chem. 241, 3365–3372[Abstract/Free Full Text]
  9. Jensen, R. A., and Nester, E. W. (1966) J. Biol. Chem. 241, 3373–3380[Abstract/Free Full Text]
  10. Achenbach-Richter, L., Gupta, R., Stetter, K. O., and Woese, C. R. (1987) Syst. Appl. Microbiol. 9, 34–39[Medline] [Order article via Infotrieve]
  11. Bocchetta, M., Gribaldo, S., Sanangelantoni, A., and Cammarano, P. (2000) J. Mol. Evol. 50, 366–380[Medline] [Order article via Infotrieve]
  12. Sheflyan, G. Y., Howe, D. L., Wilson, T. L., and Woodard, R. W. (1998) J. Am. Chem. Soc. 120, 11027–11032[CrossRef]
  13. Thompson, J. D., Higgins, D. G., and Gibson, T. J. (1994) Nucleic Acids Res. 22, 4673–4680[Abstract]
  14. Shumilin, I. A., Kretsinger, R. H., and Bauerle, R. (1999) Structure Fold Des. 7, 865–875[Medline] [Order article via Infotrieve]
  15. Baasov, T., and Knowles, J. R. (1989) J. Bacteriol. 171, 6155–6160[Medline] [Order article via Infotrieve]
  16. Jordan, P. A., Bohle, D. S., Ramilo, C. A., and Evans, J. N. S. (2001) Biochemistry 40, 8387–8396[CrossRef][Medline] [Order article via Infotrieve]
  17. Akowski, J. P., and Bauerle, R. (1997) Biochemistry 36, 15817–15822[CrossRef][Medline] [Order article via Infotrieve]
  18. Howe, D. L., Duewel, H. S., and Woodard, R. W. (2000) J. Biol. Chem. 275, 40258–40265[Abstract/Free Full Text]
  19. Huber, R., Langworthy, T. A., Konig, H., Thomm, M., Woese, C. R., Sleytr, U. B., and Stetter, K. O. (1986) Archiv. Microbiol. 144, 324–333
  20. Schoner, R., and Herrmann, K. M. (1976) J. Biol. Chem. 251, 5440–5447[Abstract]
  21. Ray, J. M., and Bauerle, R. (1991) J. Bacteriol. 173, 1894–1901[Medline] [Order article via Infotrieve]
  22. DeLeo, A. B., Dayan, J., and Sprinson, D. B. (1973) J. Biol. Chem. 248, 2344–2353[Abstract/Free Full Text]
  23. Nimmo, G. A., and Coggins, J. R. (1981) Biochem. J. 199, 657–665[Medline] [Order article via Infotrieve]
  24. Duewel, H. S., and Woodard, R. W. (2000) J. Biol. Chem. 275, 22824–22831[Abstract/Free Full Text]
  25. Krosky, D. J., Alm, R., Berg, M., Carmel, G., Tummino, P. J., Xu, B., and Yang, W. (2002) Biochim. Biophys. Acta 1594, 297–306[Medline] [Order article via Infotrieve]
  26. Wang, J., Duewel, H. S., Woodard, R. W., and Gatti, D. L. (2001) Biochemistry 40, 15676–15683[CrossRef][Medline] [Order article via Infotrieve]
  27. Wagner, T., Shumilin, I. A., Bauerle, R., and Kretsinger, R. H. (2000) J. Mol. Biol. 301, 389–399[CrossRef][Medline] [Order article via Infotrieve]
  28. Duewel, H. S., Radaev, S., Wang, J., Woodard, R. W., and Gatti, D. L. (2001) J. Biol. Chem. 276, 8393–8402[Abstract/Free Full Text]
  29. Shumilin, I. A., Zhao, C., Bauerle, R., and Kretsinger, R. H. (2002) J. Mol. Biol. 320, 1147–1156[CrossRef][Medline] [Order article via Infotrieve]
  30. Auld, D. S. (2001) Biometals 14, 271–313[CrossRef][Medline] [Order article via Infotrieve]
  31. Park, O. K., and Bauerle, R. (1999) J. Bacteriol. 181, 1636–1642[Abstract/Free Full Text]
  32. Deckert, G., Warren, P. V., Gaasterland, T., Young, W. G., Lenox, A. L., Graham, D. E., Overbeek, R., Snead, M. A., Keller, M., Aujay, M., Huberk, R., Feldman, R. A., Short, J. M., Olsen, G. J., and Swanson, R. V. (1998) Nature 392, 353–358[CrossRef][Medline] [Order article via Infotrieve]
  33. Chen, C. C., Liao, C. C., and Hsu, W. H. (1993) FEMS Microbiol. Lett. 107, 223–229[Medline] [Order article via Infotrieve]
  34. Sundaram, A. K., and Woodard, R. W. (2001) Org. Lett. 3, 21–24[Medline] [Order article via Infotrieve]