Identification of lysine 74 in the pyruvate binding site of alanine dehydrogenase from Bacillus subtilis. Chemical modification with 2,4,6-trinitrobenzenesulfonic acid, n-succinimidyl 3-(2-pyridyldithio)propionate, and 5'-(p-(fluorosulfonyl)benzoyl)adenosine.

L-Alanine dehydrogenase from Bacillus subtilis was inactivated with two different lysine-directed chemical reagents, i.e. 2,4,6-trinitrobenzenesulfonic acid and N-succinimidyl 3-(2-pyridyldithio)propionate. In both cases, the inactivation followed pseudo first-order kinetics, with a 1:1 stoichiometric ratio between the reagent and the enzyme subunits. Partial protection of the active site from inactivation could be obtained by each of the substrates, NADH or pyruvate, but complete protection could only be achieved in the presence of the ternary complex E·;NADH·;pyruvate. The nucleotide analogue of NADH, 5′-(p-(fluorosulfonyl)benzoyl)adenosine was also used for affinity labeling of the enzyme active site. Differential peptide mapping, performed both in the presence and in the absence of the substrates, followed by reversed phase high performance liquid chromatography separation, diode-array analysis, mass spectrometry, and N-terminal sequencing of the resulting peptides, allowed the identification of lysine 74 in the active site of the enzyme. This residue, which is conserved among all L-alanine dehydrogenases, is most likely the residue previously postulated to be necessary for the binding of pyruvate in the active site. Surprisingly, this residue and the surrounding conserved residues are not found in amino acid dehydrogenases like glutamate, leucine, phenylalanine, or valine dehydrogenases, suggesting that A-stereospecific amino acid dehydrogenases such as L-alanine dehydrogenase could have evolved apart from the B-stereospecific amino acid dehydrogenases.

In Bacillus species this enzyme is known to play a key role in the generation of pyruvate as energy source during sporulation (5,6). The kinetic properties of the enzyme have been elucidated (7), together with the mechanism (8) and the limiting steps of the catalysis (9). These studies showed that the B. subtilis alanine dehydrogenase follows predominately an ordered mechanism in which NAD ϩ binds before L-alanine. The products are released in the order ammonia and pyruvate before NADH. The hydrogen transfer to NAD ϩ during catalysis has been shown to occur at the pro(R) position of the nicotinamide ring, indicating that B. subtilis AlaDH is a member of the A-stereospecific dehydrogenases (10).
The amino acid sequence of AlaDH has been first determined from the strains Bacillus sphaericus and Bacillus stearothermophilus (11). The sequence fingerprint characteristic of the ␤␣␤ Rossmann's fold responsible for the nucleotide binding (12,13) has been recognized. Alignment of AlaDH sequences with other amino acid dehydrogenases like glutamate dehydrogenase, leucine dehydrogenase, or phenylalanine dehydrogenase, and with hydroxyacid dehydrogenases like lactate dehydrogenase or malate dehydrogenase led Kuroda et al. (11) to propose His-153 and Lys-156 to be part of the catalytic site. However, the availability of a third AlaDH sequence, obtained from Mycobacterium tuberculosis (14) did not support this hypothesis and stressed the need to investigate the composition of the active site (15).
Sequence comparisons between AlaDH and other proteins available in data banks have shown high similarities between AlaDH and the N-terminal part of pyridine nucleotide transhydrogenase (15,16), for which a three-dimensional model of the NAD ϩ binding site has been proposed (17). However, no convincing sequence resemblance between AlaDH and the other enzymes of the amino acid dehydrogenase superfamily has been found. In that respect, AlaDH constitutes an exception from the other amino acid dehydrogenases, like glutamate dehydrogenase, whose three-dimensional structure has been elucidated (18), or leucine dehydrogenase, phenylalanine dehydrogenase, and valine dehydrogenase, which have been shown to share sequence and structure similarities with glutamate dehydrogenase (19,20). These similarities include an identical B-type stereospecificity with respect to NAD ϩ (21-23) and a common organization of the residues implicated in the catalytic chemistry (19).
We have much information on the active-site structure of B-stereospecific amino acid dehydrogenases, obtained by chemical modification studies (24 -28), by genetic engineering (27, 29 -32), and from x-ray crystallographic data (18,33,34). However, very scarce information is available for the A-stereospecific amino acid dehydrogenases such as alanine dehydrogenase. Little is known about the residues that might be involved in substrate binding and catalysis (8,35,36), and no catalytic amino acid residue has been identified. Recently, the amino acid sequence from B. subtilis alanine dehydrogenase has become available (6), allowing the interpretation of chemical modification studies performed on this enzyme. In this paper, we provide evidence that Lys-74 of B. subtilis alanine dehydrogenase is located at the active site of the enzyme. That residue is conserved among all alanine dehydrogenases sequenced so far and is likely the lysine residue that is required for the binding of pyruvate during the catalytic reaction.
Assays-Alanine dehydrogenase activity was assayed for alanine synthesis according to Yoshida et al. (3). In typical experiments, the assay mixture (0.6 ml) contained 0.5 mM NADH, 2 mM pyruvate, and 100 mM NH 4 Cl in 100 mM Tris-HCl, pH 8.5. The reaction was started by the addition of 1-2 g of protein to the mixture. The assay was carried out at 20°C by recording the decrease in absorbance of NADH at 340 nm, with a Kontron 930 variable wavelength spectrophotometer. Protein assay was performed by the Folin reagent method (37), using bovine serum albumin as standard. When the samples contained Tris-HCl as buffer, the protein concentration was determined by the dye binding assay (38), using the kit provided by Bio-Rad (Mü nchen, Germany).
Chemical Modification with TNBS-AlaDH was inactivated by incubating the enzyme (1 mg/ml) in the dark, at 40°C, in the presence of varying concentrations of TNBS (39) (stock solutions diluted in ice-cold distilled water), in 100 mM NaH 2 PO 4 , pH 8.0. Aliquots (2 l) were removed at regular time intervals and mixed with the assay solution to measure residual activity. Control experiment showed that the enzyme did not loose any activity in those conditions when TNBS was omitted.
Chemical Modification with SPDP-Inactivation by SPDP (40) was also performed at a protein concentration of 1 mg/ml, in 100 mM NaH 2 PO 4 , but the pH was adjusted to 7.5 and the experiment was carried out at 20°C during 10 min. SPDP at varying concentrations was dissolved in ethanol before addition to the protein solution. Residual activity was also assayed at different times as indicated above. A control experiment showed that the enzyme did not lose any activity when the experiment was performed in the same conditions as without SPDP. In the pH conditions mentioned, chemical modification by SPDP is known to be specific for primary amino groups (⑀-NH 2 group of lysines or N-terminal NH 2 -group of the protein) rather than for cysteines (40). However, we performed a control experiment by incubating SPDPinactivated AlaDH in 25 mM NaH 2 PO 4 , pH 7.8, in the presence of 5 mM dithiothreitol at 20°C (45 min), in order to check the possible reaction of SPDP with a putative active-site cysteine of the enzyme.
Chemical Modification with FSBA-AlaDH (1 mg/ml) was inactivated by FSBA (41) at varying reagent concentrations (stock solution dissolved in dimethyl sulfoxide) in 100 mM NaH 2 PO 4 , pH 7.5, at 40°C (in the dark), and the activity was measured at time intervals. Also here, the enzyme showed no loss of activity in the incubation conditions when FSBA was omitted.
Protection Studies-The ability of substrates to protect the active site of the enzyme from inactivation was estimated by testing the effect of NADH and/or pyruvate. Except when indicated otherwise in the text, alanine dehydrogenase was at 1 mg/ml and NADH⅐pyruvate was added at a final concentration of 0.44 mM (100 ϫ molar excess with respect to enzyme concentration) and 44 mM (10,000 ϫ molar excess), respec-tively, before the start of the chemical modification.
Proteolysis of Chemically Modified Alanine Dehydrogenase-Several samples of alanine dehydrogenase (1.2-2.0 mg; 1 mg/ml; 4.4 M) were modified separately with the chemical reagents TNBS, SPDP, or FSBA in the above mentioned conditions. Reagent concentrations and incubation times were, respectively, 0.88 mM (60 min), 0.44 mM (10 min), and 1.76 mM (30 min) for TNBS, SPDP, and FSBA modification. After the reaction, AlaDH was separated from the chemicals by chromatography on an Ultrogel AcA44 column (2.5 cm ϫ 15 cm; IBF Biotechnics, Villeneuve-la-Garenne, France) equilibrated with 25 mM NaH 2 PO 4 , pH 7.8. The enzyme was then reconcentrated over a PM10 ultrafiltration membrane in a Centricon concentration system from Amicon (Lexington, MA). Protein concentration was adjusted to 1.2 mg/ml, and 6 M guanidine HCl in 25 mM NaH 2 PO 4 , pH 7.8, was added to the solution at a ratio of 20:100 (v/v). Digestion was achieved using endoproteinase Glu-C (42) (1 mg/ml) at a ratio of 1:50 (w/w) relative to the enzyme, during 16 h at 25°C. The digest (400 l to 1 ml) was then analyzed on a reversed phase HPLC. A control experiment with native AlaDH was performed in parallel, in exactly the same conditions.
Separation and Detection of Peptides-Peptides resulting from enzymatic cleavage were separated by reversed phase HPLC on a C 18 Nucleosil column (Macherey-Nagel, Dü ren, Germany), using the HP1090 HPLC system (Hewlett-Packard, Palo Alto, CA) equipped with a 1040M Series II multiple wavelength diode-array detector. Samples (1 mg/ml, 500 l) were filtered through a 0.2-m membrane Nylon Acrodisc (Gelman Sciences, Ann Arbor, MI) before injection onto the column previously equilibrated with solvent A. The gradient used was 0 -20% B for 5 min (elution of guanidine HCl and buffer), followed by 20 -80% B for 72 min (elution of the peptides), and a wash by 100% B during 15 min. Solvent A was trifluoroacetic acid 0.1% (v/v) in water, solvent B was trifluoroacetic acid 0.1% (v/v) in water-acetonitrile (20:80). Elution was carried out at a flow rate of 1 ml/min, with the multiple wavelength detector, respectively, set at 220/280/346, 220/280/304, and 220/280/259 nm for TNBS-, SPDP-, and FSBA-labeled samples. Control experiments were also performed by injecting the reagents alone under the same chromatographic conditions. Eluted peptides were collected and either frozen at Ϫ70°C or lyophilized for further analysis.
Peptide Repurification-When necessary, peptides of interest were further purified by HPLC under the same chromatographic conditions, except that a linear gradient of 0.25% increase of solvent B/min was used. Alternatively, peptides were repurified on a C 18 column from Pharmacia (Uppsala, Sweden) using the Pharmacia Smart system with a linear gradient of 0 -70% solvent B over 45 min.
Mass Analysis of Peptides and Amino Acid Sequence Determination-Peptides of interest were dissolved in acetonitrile/1% acetic acid in water (50:50) and their mass determined in a VG Platform electrospray ionization mass spectrometer (Fisons Instruments, Manchester, United Kingdom). The amino acid sequence of peptides was determined on a model 475A peptide sequencer (Applied Biosystems, Foster City, CA) equipped with on-line phenylthiohydantoin-derivative analyzer.

Chemical Modification by TNBS and SPDP-TNBS
and Nhydroxysuccinimide esters like SPDP are known to be highly selective reagents at pH 7.5-8.0 for the modification of lysine residues (⑀-NH 2 group of the side chain) and/or N terminus of proteins (39,40). Incubation of L-alanine dehydrogenase with varying concentrations of TNBS and SPDP resulted in a timedependent loss of enzyme activity, suggesting the modification of a primary amino group located at or near the enzyme active site. Plots of the logarithm of remaining activity versus time at different reagent concentrations indicated in each case pseudo first-order kinetics (Figs. 1A and 2A). A straight line was also observed for the plot of pseudo first-order rate constants versus reagent concentration (Figs. 1B and 2B), indicating that the chemical modification is the result of a simple bimolecular reaction. The second-order rate constants (k inact ) obtained for the modification by TNBS and SPDP were 0.57 and 60.6 M Ϫ1 s Ϫ1 , respectively, and show a much higher reactivity of SPDP compared to TNBS toward the active-site lysine residue. Plotting log k inact versus log of reagent concentration, according to Levy et al. (43), yields an apparent reaction order of 0.88 and 1.00 for TNBS and SPDP, respectively, indicating that inactivation results from the reaction of approximately 1 mol of reagent with 1 mol of enzyme subunit (Figs. 1C and 2C). This observation is in agreement with the result obtained for the stoichiometry of the reaction with SPDP, which indicates that the modification of no more than 1.4 lysine residues/monomer is required for the complete inactivation of AlaDH (Fig. 3).
SPDP is a bifunctional reagent that can also react with cysteine residues to form a disulfide link (40). In order to estimate the possible involvement of cysteine reaction, we incubated SPDP-inactivated AlaDH in the presence of 5 mM dithiothreitol (45 min, 20°C) to determine whether reduction of the enzyme could restore its activity. Only 17.5% of activity could be restored by this treatment, assessing that inactivation with SPDP was mainly the result of modification of a lysine rather than a cysteine residue.
Chemical Modification with FSBA-In a third series of experiments, we used the structural analog of NADH, FSBA, for specific modification of the alanine dehydrogenase cofactor binding site. This reagent has proved to be appropriate for active-site affinity labeling of other dehydrogenases like malate dehydrogenase, 20␤-hydroxysteroid dehydrogenase, or 17␤-estradiol dehydrogenase (41). The time course of AlaDH inactivation in the presence of FSBA followed pseudo first-order kinetics (Fig. 4A), but, in this case, complete inactivation of the enzyme could not be obtained even at high reagent concentration. The activity declined to a non-zero value after a relatively long period (60 min of incubation). A minimum residual activity of about 25% was obtained with 10 mM FSBA (Fig. 5A). The rate of inactivation increased according to the initial FSBA concentration, showing typical saturation kinetics. This is observed in the plot of pseudo first-order rate constants k inact versus FSBA concentration (Fig. 4B) and in the plot of log k inact versus log FSBA concentration (Fig. 4C), where a deviation from linearity is observed at high reagent concentrations. Fitting straight lines by linear regression on the linear portion of data points gave values of 5.47 ϫ 10 Ϫ2 M Ϫ1 s Ϫ1 and 0.76 for the second-order rate constant and the apparent order of reaction, respectively, but a polynomial second-order curve best fitted the data points in Fig. 4B with a correlation coefficient of R 2 ϭ 1.00. These results clearly show that chemical modification of AlaDH with FSBA does not follow a simple bimolecular mechanism as observed for TNBS or SPDP but proceeds through a two-step reaction. This is in agreement with a mechanism where FSBA first binds to the adenosine binding site of the enzyme to form a reversible non-covalent complex (inhibition) and subsequently reacts in an irreversible covalent way with an amino acid residue of the active site (inactivation) (Reaction 2). For this reason, results were analyzed according to the method of Kitz and Wilson (44) for irreversible inhibitors, where the observed rate constant for inactivation is as shown in Equation 1.
K I and k 3 were calculated as being 2.26 mM and 2.36 ϫ 10 Ϫ4 s Ϫ1 , respectively (R 2 ϭ 0.96). Protection Studies-In order to assess that the chemical modification by TNBS, SPDP, and FSBA is active-site directed, we tested the ability of substrates to protect the enzyme active site from inactivation (Fig. 6). The mechanism of reaction of AlaDH is known to be ordered with first the binding of NADH, followed by pyruvate and ammonium (7). We could not assay the protection by L-alanine or NH 4 Cl since they can react with the chemical reagents used. We tested the protecting effect of NADH, pyruvate, and pyruvate analogues. In the case of TNBS and SPDP, only little or no protecting effect was observed when the substrates NADH or pyruvate were used alone. However, the k inact was dramatically reduced when NADH and pyruvate were used together. This result clearly shows that the lysine residue reacting with these chemicals is located in the active site of the enzyme and can only be protected in the presence of the ternary complex E⅐NADH⅐pyruvate. The inability of NADH alone to protect the enzyme from inactivation suggest that it does not occur at the NADH binding site itself but more likely at or near the pyruvate binding site of the enzyme as the presence of pyruvate is also required for good protection. The inability of pyruvate alone to protect from inactivation can be understood by the ordered mechanism of reaction in which pyruvate can only bind to the enzyme when NADH is first fixed at the active site.
We then tested the ability of several pyruvate analogues in combination with NADH to protect AlaDH from inactivation, in order to see whether there was a correlation between the ability of these compounds to act as substrates and to afford protection against the lysine modification (Table I). The results show that increasing the length of the aliphatic chain of ketoacids from methyl (in pyruvate) to propyl (in ␣-ketovalerate) gradually reduces the protecting effect of the substrates. Replacing the methyl group of pyruvate by a hydrogen (in glyoxylate) or a carboxylic acid chain (in the dicarboxylic acid series) completely abolishes the protecting effect, except for oxalacetate, which exhibits a strikingly high protecting effect. These results confirm the presence of the lysine residue near the pyruvate binding site since oxalacetate is a good substrate for the enzyme, the product of the reaction being D-aspartate and not L-aspartate as it could be expected (data not shown). This is in contrast to the other dicarboxylic acids which are not accepted as substrates. Finally, replacing the methyl group of pyruvate by -NH 2 in oxamate gave some protection against inactivation. This is also in agreement with the fact that oxamate is an isosteric and isoelectronic substrate analogue of pyruvate and is known to be a competitive inhibitor of alanine dehydrogenase (7).
Similar results for substrate protection were obtained for FSBA inactivation, except that here a greater effect was obtained for the protection by NADH alone (Fig. 6C). This observation is in agreement with the fact that, because of its structural similarity to NADH, FSBA is expected to bind at the NADH binding site before its covalent reaction with an amino acid of the active site. Nevertheless, here again the simultaneous presence of both NADH and pyruvate is required for a complete protection against inactivation.
Identification of Modified Amino Acid Residues-L-Alanine dehydrogenase was chemically modified using TNBS, SPDP, and FSBA as described under "Experimental Procedures." Samples were passed through a desalting column, reconcentrated, and submitted to proteolysis using endoproteinase Glu-C (42). For TNBS and SPDP inactivation, experiments were carried out in parallel both in the presence of NADH and pyruvate (protection of the whole active site) or in the presence of NADH alone (protection of the NADH binding site only). The HPLC profiles obtained for TNBS-modified alanine dehydrogenase are presented in Fig. 7. The comparison of the profiles shows that the peak eluting at 32.5 min disappears when pyruvate is absent from the active site (Fig. 7, A and B, peak I), while another peak eluting at 46.0 min increases (peak II). This increase is particularly obvious at 346 nm (Fig. 7D), which is a specific wavelength for TNBS chemical modification. Diode-array detection analysis of these compounds indicated that peak II was labeled with TNBS, while peak I was not, as shown by its characteristic absorbance profile with a maximum at 346 and 420 nm (Fig. 8A). Peptides from peaks I and II were collected and submitted to mass determination and to N-terminal sequencing (over 6 -10 residues) by automated Edman degradation. For the peak eluting at 32.5 min, the sequence MVMKVK could be identified (Table II). This result, together with the mass determination obtained (M r ϭ 2286.8) indicates that peptide I corresponds to Met-69 to Lys-86 (Table III). Interestingly, a similar sequence was found in the peptidic fragments identified in peak II, where the mass observed for one of these two fragments was consistent with the TNBS labeling of the peptide Met-69 -Lys-86 (Table II, fragment IIa). Unfortunately, only a few phenylthiohydantoin-derivatives of this fragment could be identified due to the low amount of material available, but they all corresponded to the expected sequence. Another peptidic fragment (Table II, fragment IIb), starting with a proline corresponding to Pro-76 in the AlaDH sequence, contaminated peak II.
The HPLC profile of the peptides obtained after chemical modification of alanine dehydrogenase with SPDP is presented in Fig. 9. Similarly to the results obtained in Fig. 7, the peak eluting at R t ϭ 32.5 min (peak I) decreases when pyruvate is absent from the active site, while another peak increases, which absorbs at 304 nm (Fig. 8B) and elutes at R t ϭ 39.8 min (Fig. 9, peak III). This result suggests that the SPDP chemical labeling modified the same peptidic fragment of alanine dehy- drogenase as the one modified with TNBS, i.e. Met-69 to Lys-86. This was also confirmed by the mass analysis and sequence determination of the peptides contained in peak III (Table II), where masses of 2484.8 and 2374.2 are in agreement with the SPDP-labeling of peptide I (in the oxidized and reduced states), while the mass of 3912.1 is consistent with a longer SPDPlabeled fragment from Met-69 to Glu-99. The N-terminal sequencing of the peptide from peak III gave the consensus sequence MVMKV*EP, with an unidentified phenylthiohydantoin-derivative at the 6th cycle, corresponding to Lys-74 in L-alanine dehydrogenase (Table II). The elution pattern of the peptides resulting from endoproteinase Glu-C digest of FSBA-labeled alanine dehydrogenase (Fig. 10) was obtained similarly to those obtained after the TNBS and SPDP chemical modification, except that the experiment was performed both in the presence of NADH and pyruvate (protection of the whole active site) and without any substrate (no protection). This reagent, which potentially can react with several residues of the active site, also reacted with the same peptidic fragment as indicated by the decrease of peak I when the substrates were omitted (Fig. 10, A and B). Peak IV appearing in those conditions highly absorbs at 259 nm ( Fig.  8C and 10D) and gave the sequence MVMKV*EPLP, with masses of 2721.0 and 3883.0 (Table II). DISCUSSION L-Alanine dehydrogenase from B. subtilis was completely inactivated using TNBS and SPDP. In both cases, the inactivation of the enzyme was the result of a simple bimolecular reaction, with the modification of about one lysine residue/ monomer. This result suggests the presence of an essential lysine residue at or near the active site of the enzyme. A different pattern of inactivation was obtained for the modification of AlaDH with the structural analogue of NADH, i.e. FSBA. In this case, saturation kinetics were obtained, indicating a two-step mechanism where FSBA binds to the NADH binding site of the enzyme before irreversible chemical modification of an active-site residue. Results obtained for the chemical modification of the enzyme in the presence of the substrates indicate that NADH or pyruvate alone do not allow a good protection, and that the enzyme can only be effectively protected when the ternary complex E⅐NADH⅐pyruvate is formed. Given the ordered mechanism of AlaDH where NADH binds before pyruvate (7), the fact that both NADH and pyruvate are required for a good protection of the active site suggests that the chemical modification occurs at the pyruvate binding site, rather than at the NADH binding site.
Differential peptide mapping, both in the presence and in the absence of the substrates, and monitoring at a wavelength specific for the label, allowed the identification of active-site peptide fragments. For both TNBS and SPDP, the same peptidic fragment from Met-69 to Lys-86 was found to be labeled, with a concomitant retention time modification and increase of   (42). On the other hand, the absence of cleavage after Glu-75, Glu-79, and Glu-80 is probably due to the presence of two proline residues, respectively, at position 76 and 78 of the sequence. These residues are known to form secondary structures that often prevent the recognition of pro-TABLE III Alignment of the active-site peptide fragment with the sequences of L-alanine dehydrogenase and pyridine nucleotide transhydrogenase The asterisk indicates the lysine residue modified during the chemical labeling of the L-alanine dehydrogenase active site. Outlined letters denote residues conserved among all alanine dehydrogenases sequenced to date. The number of the first and last residue of each sequence is given, respectively, at the beginning and end of each line. Residues EEGTD, PTLGVH, PTLGAH, and PTLGVH, are, respectively, in the original sequences of Rhodospirillum rubrum, Bos taurus, Mus musculus, and Homo sapiens pyridine nucleotide transhydrogenases before the conserved glutamate residue. teases with their substrates. More surprising was the aspecific cleavage of endoproteinase Glu-C after a lysine residue in position 86, which was obtained for several independent experiments. This unusual cleavage after a lysine residue is not in the list of the several aspecific cleavages that have been reported for endoproteinase Glu-C, for example after Gly and Ala (45), Asn and Tyr (46), or Gln and Ser (47). To our knowledge, cleavage after a lysine had not yet been observed.
Mass and sequence determinations of the isolated peptides were consistent with the chemical labeling of lysine 74 of the L-alanine dehydrogenase, implying the presence of this residue at or near the active site of the enzyme. Interestingly, the active-site affinity labeling using FSBA also modified the same Met-69 -Lys-86 peptidic fragment at the position of lysine 74, although FSBA can react with several residues other than lysine. Sequence alignment of this peptide with the known sequences of B. subtilis AlaDH (6), B. sphaericus (11), B. stearothermophilus (11), M. tuberculosis (14), and Synechocystis sp. (48) indicates that the modified lysine residue is conserved among all the alanine dehydrogenases sequenced to date, and that it is located in an important stretch of five conserved residues KVKEP from Lys-72 to Pro-76 (Table III). According to the sequence analysis of the enzyme (15), these residues are most likely located outside of the NADH binding site, which is supposed to expand around and after the characteristic GXGXXG(X 17 )D motif of the ␤␣␤ Rossmann's fold. This observation is in agreement with a localization of Lys-74 at the pyruvate binding site but in close vicinity of the NADH binding site, since the same Lys-74 is also modified by FSBA. The presence of Lys-74 in the NADH binding site itself is not completely excluded. In this case, the protection obtained for the enzyme inactivation by TNBS and SPDP, only when both NADH and pyruvate are present, would implicate that Lys-74 would still be accessible to these chemicals when NADH alone is bound to the active site, but that a conformational change occurs when pyruvate is bound, so that only in this situation, Lys-74 would be part of the NADH binding site. This possibility cannot be ruled out, but all the arguments presented here above argue against this explanation.
According to Grimshaw et al. (8), a cationic acid group on the enzyme (probably a lysine) is required for effective binding of the substrate and the inhibitors, while another cationic acid group (probably a histidine), acts as an acid-base catalyst of the reaction. In an attempt to locate these residues in the sequence of B. sphaericus and B. stearothermophilus, Kuroda et al. (11) performed sequence comparisons with other amino acid dehydrogenases (glutamate dehydrogenase, phenylalanine dehydrogenase, and leucine dehydrogenase) and with hydroxyacid dehydrogenase, which share some substrate and catalytic features with alanine dehydrogenase (lactate dehydrogenase and malate dehydrogenase). In their conclusions, the authors proposed His-153 and Lys-156 from B. sphaericus to be part of the active site (11,27). However, the availability of a third alanine dehydrogenase obtained from M. tuberculosis (14) ruled out this hypothesis, since the proposed residues were not conserved in this new sequence (15). The experimental results obtained by us clearly identify Lys-74 as part of the enzyme active site, and support its role in the catalytic mechanism of the L-alanine dehydrogenase.
In a previous paper the sequence of B. sphaericus alanine dehydrogenase was compared with the protein sequences of the Swissprot, GenBank, and EMBL data bases (15). Surprisingly, no other amino acid dehydrogenase or hydroxyacid dehydrogenase was found to be significantly similar to alanine dehydrogenase, but the enzyme was found to be similar to the N-terminal sequence of pyridine nucleotide transhydrogenase, suggesting a similar folding of these two protein segments (15). However, no alanine dehydrogenase activity was detected in M. tuberculosis pyridine nucleotide transhydrogenase (56), suggesting that even if they have a similar structure, their active site is different. In agreement with this active-site difference, pyridine nucleotide transhydrogenase also lacks lysine 74, which was found to be essential for the activity of alanine dehydrogenase (Table III).
L-Alanine dehydrogenases appear as very unique enzymes among the amino acid dehydrogenases. Alanine dehydrogenase has been shown to be a member of A-stereospecific dehydrogenases (10,57), unlike the other amino acid dehydrogenases studied to date, which are B-stereospecific (21)(22)(23). In this paper, we showed that alanine dehydrogenases from B. subtilis posses a lysine at the position 74 that is essential for the enzyme activity, and that this residue is conserved among the other alanine dehydrogenases sequenced so far (Table III). This lysine and the surrounding conserved sequence region are not found in other dehydrogenases. Furthermore, the characteristic active-site motif K(X 8 )GGXK identified in glutamate, leucine, phenylalanine, and valine dehydrogenases (19,20) is not found in L-alanine dehydrogenases, suggesting a separate evolution of these two groups of amino acid dehydrogenases. The only similarity of sequence was found with one part of the pyridine nucleotide transhydrogenase, which suggests that Lalanine dehydrogenase, contrary to the B-stereospecific amino acid dehydrogenases, may have evolved along with pyridine nucleotide transhydrogenases rather than with the other dehydrogenases of the amino acid dehydrogenase superfamily.