Effect of substitution of a lysyl residue that binds pyridoxal phosphate in thermostable D-amino acid aminotransferase by arginine and alanine

Lys-145 of the thermostable D-amino acid aminotransferase, which binds pyridoxal phosphate, was replaced by Ala or Arg by site-directed mutagenesis. Both mutant enzymes were purified to homogeneity; their absorption spectra indicated that both mutant enzymes contained pyridoxal phosphate bound non-covalently. Even though the standard assay method did not indicate any activity with either mutant, addition of an amino donor, D-alanine, to the Arg-145 mutant enzyme led to a slow decrease in absorption at 392 nm with a concomitant increase in absorption at 333 nm. This result suggests that the enzyme was converted into the pyridoxamine phosphate form. The amount of pyruvate formed was almost equivalent to that of the reactive pyridoxal phosphate in the mutant enzyme. Thus, the Arg-145 mutant enzyme is able to catalyze slowly the half-reaction of transamination. Exogenous amines, such as methylamine, had no effect on the half-reaction with the Arg-145 mutant enzyme. In contrast, the Ala-145 mutant enzyme neither underwent the spectral change by addition of D-alanine nor catalyzed pyruvate formation, in the absence of added amine. However, the Ala-145 mutant enzyme catalyzed the half-reaction significantly in the presence of added amine. These findings suggest that a basic amino acid residue, such as lysine or arginine, is required at position 145 for catalysis of the half-reaction. The role of the exogenous amines differs with various active-site mutant enzymes.     

Thermostable D-amino acid aminotransferase from a thermophilic Bacillus species. Purification, characterization, and active site sequence determination

D-Amino acid aminotransferase was found in several thermophilic Bacillus species and purified to homogeneity from the best producer, Bacillus sp. YM-1, which was newly isolated from a sauna dust. The enzyme has a molecular weight of about 62,000 and consists of two subunits identical in molecular weight (30,000). It catalyzes transamination between various D-amino acids and alpha-keto acids, although the substrate specificity is narrower than the enzyme from the mesophile, Bacillus sphaericus (Yonaha, K., Misono, H., Yamamoto, T., and Soda, K. (1975) J. Biol. Chem. 250, 6983-6989). The Bacillus sp. YM-1 enzyme is most active at 60 degrees C and stable at high temperatures. Automated Edman degradation provided the N-terminal sequence of the first 20 amino acids, and carboxypeptidase Y digestion provided the C-terminal sequence of the last 3 amino acids. The amino acid sequence in the vicinity of the lysyl residue, Lys(Pxy), that binds pyridoxal 5'-phosphate was determined as Cys-Asp-Ile-Lys(Pxy)-Ser-Leu-Asn-Leu-Leu-Gly-Ala-Val-Leu-Ala-Lys- from the pyridoxyl peptide obtained by digestion with trypsin. The active site sequence is markedly different from those of L-amino acid aminotransferases and other pyridoxal 5'-phosphate-dependent enzymes.     

Crystal structure of pyridoxamine-pyruvate aminotransferase from Mesorhizobium loti MAFF303099

Pyridoxamine-pyruvate aminotransferase (PPAT; EC 2.6.1.30) is a pyridoxal 5'-phosphate-independent aminotransferase and catalyzes reversible transamination between pyridoxamine and pyruvate to form pyridoxal and L-alanine. The crystal structure of PPAT from Mesorhizobium loti has been solved in space group P4(3)2(1)2 and was refined to an R factor of 15.6% (R(free) = 20.6%) at 2.0 A resolution. In addition, the structures of PPAT in complexes with pyridoxamine, pyridoxal, and pyridoxyl-L-alanine have been refined to R factors of 15.6, 15.4, and 14.5% (R(free) = 18.6, 18.1, and 18.4%) at 1.7, 1.7, and 2.0 A resolution, respectively. PPAT is a homotetramer and each subunit is composed of a large N-terminal domain, consisting of seven beta-sheets and eight alpha-helices, and a smaller C-terminal domain, consisting of three beta-sheets and four alpha-helices. The substrate pyridoxal is bound through an aldimine linkage to Lys-197 in the active site. The alpha-carboxylate group of the substrate amino/keto acid is hydrogen-bonded to Arg-336 and Arg-345. The structures revealed that the bulky side chain of Glu-68 interfered with the binding of the phosphate moiety of pyridoxal 5'-phosphate and made PPAT specific to pyridoxal. The reaction mechanism of the enzyme is discussed based on the structures and kinetics results.     

D-amino acid aminotransferase of Bacillus sphaericus. Enzymologic and spectrometric properties.

D-Amino acid aminotransferase, purified to homogeneity and crystallized from Bacillus sphaericus, has a molecular weight of about 60,000 and consists of two subunits identical in molecular weight (30,000). The enzyme exhibits absorption maxima at 280, 330, and 415 nm, which are independent of the pH (5.5 to 10.0), and contains 2 mol of pyridoxal 5'-phosphate per mol of enzyme. One of the pyridoxal-5'-P, absorbing at 415 nm, is bound in an aldimine linkage to the epsilon-amino group of a lysine residue of the protein, and is released by incubation with phenylhydrazine to yield the catalytically inactive form. The inactive form, which is reactivated by addition of pyridoxal 5'phosphate, still has a 330 nm peak and contains 1 mol of pyridoxal 5'-phosphate. Therefore, this form is regarded as a semiapoenzyme. The holoenzyme shows negative circular dichroic bands at 330 and 415 nm. D-Amino acid aminotransferase catalyzes alpha transamination of various D-amino acids and alpha-keto acids. D-Alanine, D-alpha-aminobutyrate and D-glutamate, and alpha-ketoglutarate, pyruvate, and alpha-ketobutyrate are the preferred amino donors and acceptors, respectively. The enzyme activity is significantly affected by both the carbonyl and sulfhydryl reagents. The Michaelis constants are as follows: D-alanine (1.3 and 4.2 mM with alpha-ketobutyrate and alpha-ketoglutarate, respictively), alpha-ketobutyrate (14 mM withD-alanine), alpha-ketoglutarate (3.4 mM with D-alanine), pyridoxal 5'-phosphate (2.3 muM) and pyridoxamine 5'-phosphate (25 muM).     

Stereochemistry and mechanism of a new single-turnover, half-transamination reaction catalyzed by the tryptophan synthase alpha 2 beta 2 complex

Tryptophan synthase is a versatile enzyme that catalyzes a wide variety of pyridoxal phosphate dependent reactions that are also catalyzed in model systems. These include beta-replacement, beta-elimination, racemization, and transamination reactions. We now show that the apo-alpha 2 beta 2 complex of tryptophan synthase will bind two unnatural substrates, pyridoxamine phosphate and indole-3-pyruvic acid, and will convert them by a single-turnover, half-transamination reaction to pyridoxal phosphate and L-tryptophan, the natural coenzyme and a natural product, respectively. This enzyme-catalyzed reaction is more rapid and more stereospecific than an analogous model reaction. The pro-S 4'-methylene proton of pyridoxamine phosphate is removed during the reaction, and the product is primarily L-tryptophan. We conclude that pyridoxal phosphate enzymes may be able to catalyze some unnatural reactions involving bound reactants and bound coenzyme since the coenzyme itself has the intrinsic ability to promote a variety of reactions.     

Occurrence of D-amino acid aminotransferase in pea seedlings

Aminotransferase reacting between D-amino acids and α-keto acids was found in the germinating pea seedlings. With partial purification, it was evident that the enzyme preparation contained no racemase and L-amino acid aminotransferase and was only specific for D-amino acid transamination. Large amounts of D-alanine found in the germinating pea seedlings were assumed to be formed by this enzyme action.     

Tyrosine 265 of alanine racemase serves as a base abstracting alpha-hydrogen from L-alanine: the counterpart residue to lysine 39 specific to D-alanine.

Alanine racemase of Bacillus stearothermophilus has been proposed to catalyze alanine racemization by means of two catalytic bases: lysine 39 (K39) abstracting specifically the alpha-hydrogen of D-alanine and tyrosine 265 (Y265) playing the corresponding role for the antipode L-alanine. The role of K39 as indicated has already been verified [Watanabe, A., Kurokawa, Y., Yoshimura, T., Kurihara, T., Soda, K., and Esaki, N. (1999) J. Biol. Chem. 274, 4189-4194]. We here present evidence for the functioning of Y265 as the base catalyst specific to L-alanine. The Y265-->Ala mutant enzyme (Y265A), like Y265S and Y265F, was a poor catalyst for alanine racemization. However, Y265A and Y265S catalyzed transamination with D-alanine much more rapidly than the wild-type enzyme, and the bound coenzyme, pyridoxal 5'-phosphate (PLP), was converted to pyridoxamine 5'-phosphate (PMP). The rate of transamination catalyzed by Y265F was about 9% of that by the wild-type enzyme. However, Y265A, Y265S, and Y265F were similar in that L-alanine was inert as a substrate in transamination. The apo-form of the wild-type enzyme catalyzes the abstraction of tritium non-specifically from both (4'S)- and (4'R)-[4'-(3)H]PMP in the presence of pyruvate. In contrast, apo-Y265A abstracts tritium virtually from only the R-isomer. This indicates that the side-chain of Y265 abstracts the alpha-hydrogen of L-alanine and transfers it supra-facially to the pro-S position at C-4' of PMP. Y265 is the counterpart residue to K39 that transfers the alpha-hydrogen of D-alanine to the pro-R position of PMP.     

Molecular cloning, expression and characterization of pyridoxamine-pyruvate aminotransferase

Pyridoxamine-pyruvate aminotransferase is a PLP (pyridoxal 5'-phosphate) (a coenzyme form of vitamin B6)-independent aminotransferase which catalyses a reversible transamination reaction between pyridoxamine and pyruvate to form pyridoxal and L-alanine. The gene encoding the enzyme has been identified, cloned and overexpressed for the first time. The mlr6806 gene on the chromosome of a symbiotic nitrogen-fixing bacterium, Mesorhizobium loti, encoded the enzyme, which consists of 393 amino acid residues. The primary sequence was identical with those of archaeal aspartate aminotransferase and rat serine-pyruvate aminotransferase, which are PLP-dependent aminotransferases. The results of fold-type analysis and the consensus amino acid residues found around the active-site lysine residue identified in the present study showed that the enzyme could be classified into class V aminotransferases of fold type I or the AT IV subfamily of the alpha family of the PLP-dependent enzymes. Analyses of the absorption and CD spectra of the wild-type and point-mutated enzymes showed that Lys197 was essential for the enzyme activity, and was the active-site lysine residue that corresponded to that found in the PLP-dependent aminotransferases, as had been suggested previously [Hodsdon, Kolb, Snell and Cole (1978) Biochem. J. 169, 429-432]. The K(d) value for pyridoxal determined by means of CD was 100-fold lower than the K(m) value for it, suggesting that Schiff base formation between pyridoxal and the active-site lysine residue is partially rate determining in the catalysis of pyridoxal. The active-site structure and evolutionary aspects of the enzyme are discussed.     

L-Histidinol phosphate aminotransferase from Salmonella typhimurium. Kinetic behavior and sequence at the pyridoxal-P binding site

A coupled assay with alpha-hydroxyglutarate dehydrogenase was used to analyze the kinetic behavior of histidinol phosphate aminotransferase from Salmonella typhymurium. Data obtained from studies of initial velocity, inhibition by products or substrate analogues, isotope exchange rates, and the determination of the equilibrium constant were consistent only with a Ping-Pong Bi Bi mechanism. Variations in inhibition patterns by different substrate analogues indicate that the microenvironment about the pyridoxal phosphate and the pyridoxamine phosphate forms of histidinol phosphate amino-transferase are different, and favor the presence of one active site with partially overlapping substrate-binding subsites for these 2 forms of the enzyme. Histidinol phosphate aminotransferase also catalyzes decomposition of beta-chloro-L-alanine to pyruvate, NH3 and Cl-; no transamination of this substrate occurs and inactivation of the enzyme accompanies this reaction. After reduction of histidinol-P aminotransferase with [3H]NaBH4, carboxymethylation, and tryptic digestion, one major radioactive peptide absorbing at 325 nm was isolated. Its primary structure was determined to be TLSK*AFALAGLR, where K* is the P-pyridoxyllysine residue. Although this peptide is only 30-40% homologous with the corresponding segment reported for other transaminases, all of these peptides are similar in placement of an hydroxyamino acid residue three residues upstream from the lysine residue, and in the cluster of hydrophobic amino acid residues immediately following the lysine residue.     

Structural studies of the catalytic reaction pathway of a hyperthermophilic histidinol-phosphate aminotransferase

In histidine biosynthesis, histidinol-phosphate aminotransferase catalyzes the transfer of the amino group from glutamate to imidazole acetol-phosphate producing 2-oxoglutarate and histidinol phosphate. In some organisms such as the hyperthermophile Thermotoga maritima, specific tyrosine and aromatic amino acid transaminases have not been identified to date, suggesting an additional role for histidinol-phosphate aminotransferase in other transamination reactions generating aromatic amino acids. To gain insight into the specific function of this transaminase, we have determined its crystal structure in the absence of any ligand except phosphate, in the presence of covalently bound pyridoxal 5'-phosphate, of the coenzyme histidinol phosphate adduct, and of pyridoxamine 5'-phosphate. The enzyme accepts histidinol phosphate, tyrosine, tryptophan, and phenylalanine, but not histidine, as substrates. The structures provide a model of how these different substrates could be accommodated by histidinol-phosphate aminotransferase. Some of the structural features of the enzyme are more preserved between the T. maritima enzyme and a related threonine-phosphate decarboxylase from S. typhimurium than with histidinol-phosphate aminotransferases from different organisms.     

Stereochemistry of the hydrogen abstraction from pyridoxamine phosphate catalyzed by alanine racemase of Bacillus stearothermophilus

Alanine racemase of Bacillus stearothermophilus catalyzes transamination as a side reaction. Stereospecificity for the hydrogen abstraction from C-4′ of pyridoxamine 5′-phosphate occurring in the latter half transamination was examined. Both apo-wild-type and apo-fragmentary alanine racemases abstracted approximately 20 and 80% of tritium from the stereospecifically-labeled (4′S)- and (4′R)-[4′-³H]PMP, respectively, in the presence of pyruvate. Alanine racemase catalyzes the abstraction of both 4′S- and 4′R-hydrogen like amino acid racemase with broad substrate specificity. However, R-isomer preference is a characteristic property of alanine racemase.     

Characterization and sequence of Escherichia coli pabC, the gene encoding aminodeoxychorismate lyase, a pyridoxal phosphate-containing enzyme.

In Escherichia coli, p-aminobenzoate (PABA) is synthesized from chorismate and glutamine in two steps. Aminodeoxychorismate synthase components I and II, encoded by pabB and pabA, respectively, convert chorismate and glutamine to 4-amino-4-deoxychorismate (ADC) and glutamate, respectively. ADC lyase, encoded by pabC, converts ADC to PABA and pyruvate. We reported that pabC had been cloned and mapped to 25 min on the E. coli chromosome (J. M. Green and B. P. Nichols, J. Biol. Chem. 266:12971-12975, 1991). Here we report the nucleotide sequence of pabC, including a portion of a sequence of a downstream open reading frame that may be cotranscribed with pabC. A disruption of pabC was constructed and transferred to the chromosome, and the pabC mutant strain required PABA for growth. The deduced amino acid sequence of ADC lyase is similar to those of Bacillus subtilis PabC and a number of amino acid transaminases. Aminodeoxychorismate lyase purified from a strain harboring an overproducing plasmid was shown to contain pyridoxal phosphate as a cofactor. This finding explains the similarity to the transaminases, which also contain pyridoxal phosphate. Expression studies revealed the size of the pabC gene product to be approximately 30 kDa, in agreement with that predicted by the nucleotide sequence data and approximately half the native molecular mass, suggesting that the native enzyme is dimeric.     

Purification of phosphodiesterase II from rat and guinea-pig intestinal mucosa.

After glucagon injection, rats showed virtually identical percentage increases in hepatic histidine-pyruvate aminotransferase and serine-pyruvate aminotransferase activities, both in the mitochondria and in the cytosol. Histidine-pyruvate aminotransferase isoenzyme 1, with pI8.0, was purified to homogeneity from the mitochondrial fraction of liver from glucagon-injected rats. The purified enzyme catalysed transamination between a number of amino acids and pyruvate or phenylpyruvate. For transamination with pyruvate, the activity with serine reached a constant ratio to that with histidine during purification, which was unchanged by a variety of treatments of the purified enzyme. Serine was found to act as a competitive inhibitor of histidine transamination, and histidine of serine transamination. These results suggest that histidine-pyruvate amino-transferase isoenzymes 1 is identical with serine-pyruvate aminotransferase. The enzyme is probably composed of two identical subunits with mol. wt. approx. 38000. The absorbance maximum at 410 nm and the inhibition by carbonyl reagents strongly indicate the presence of pyridoxal phosphate.     

Effects of D-serine on bacterial D-amino acid transaminase: accumulation of an intermediate and inactivation of the enzyme

Incubation of pure bacterial D-amino acid transaminase with D-serine or erythro-beta-hydroxy-DL-aspartic acid, which are relatively poor substrates, leads to generation of a new absorbance band at 493 nm that is probably the quinonoid intermediate. The 420-nm absorbance band (due to the pyridoxal phosphate coenzyme) decreases, and the 338-nm absorbance band (due to the pyridoxamine phosphate or some other form of the coenzyme) increases. A negative Cotton effect at 493 nm in the circular dichroism spectra is also generated. Closely related D amino acids do not lead to generation of this new absorption band, which has a half-life of the order of several hours. Treatment of the enzyme with the good substrate D-alanine leads to a small but detectable amount of the same absorbance band. D-Serine but not erythro-beta-hydroxyaspartate leads to inactivation of D-amino acid transaminase, and D-alanine affords partial protection. The results indicate that D-serine is a unique type of inhibitor in which the initial steps of the half-reaction of transamination are so slow that a quinonoid intermediate with a 493-nm absorption band accumulates. A derivative formed from this intermediate inactivates the enzyme.     

Inducible and constitutive kynureninases. Control of the inducible enzyme activity by transamination and inhibition of the constitutive enzyme by 3-hydroxyanthranilate.

The inducible kynureninase from Neurospora crassa is inactivated by incubation with L-alanine or L-ornithine. The inactivated enzyme is resolved to the apoenzyme by dialysis. Reactivation of the apoenzyme is achieved by incubation with pyridoxamine 5'-phosphate plus pyruvate, as well as with pyridoxal 5'-phosphate. The kynurenine hydrolysis proceeds linearly in the presence of added pyridoxal 5'-phosphate, or pyridoxamine 5'-phosphate plus pyruvate. These findings indicate that the fungal inducible kynureninase can act as an amino-transferase to control the enzyme activity, and that the control mechanism is similar to that reported for the bacterial kynureninase (Moriguchi, M. & Soda, K. (1973) Biochemistry 12, 2974-2980). The ratio of kynureninase activity to aminotransferase activity was determined with bacterial and fungal enzymes. All the inducible kynureninases from various fungal species examined are also controlled by the transamination. In contrast, the pig liver kynureninase and the fungal constitutive enzymes are little or not at all affected by preincubation with amino acids. Thus, the present regulatory mechanism does not operate in these constitutive-type enzymes. The rate of hydrolysis of L-3-hydroxykynurenine by the pig liver enzyme decreases with increase in the incubation time; the enzyme is inhibited by 3-hydroxyanthranilate produced from L-3-hydroxykynurenine. The inhibition is found in all the constitutive-type enzymes, suggesting that 3-hydroxyanthranilate plays a regulatory role in NAD biosynthesis from tryptophan.     

Transamination catalysed by tyrosine phenol-lyase from Citrobacter intermedius

The interactions of tyrosine phenol-lyase with its substrates: L-tyrosine and L-serine, and the competitive inhibitors: L-alanine, L-phenylalanine, L-m-tyrosine, were studied. It was demonstrated that the enzyme catalyzed a half-transamination reaction between substrates or inhibitors and the protein-bound pyridoxal phosphate. The products of this side-reaction, pyridoxamine phosphate and the respective keto acids, were identified. The kinetic parameters were determined for beta-elimination of L-tyrosine and of L-serine, and for the transamination of L-serine and the inhibitors used. The transfer of the amino group to the coenzyme takes place in the direction from amino acid to pyridoxal phosphate, but not in the opposite direction, i.e. the transamination is irreversible.     

Selective proteolysis of cytosolic aspartate aminotransferase by a new microbial protease

A protease from Streptomyces violaceochromogenes (Murao, S., Nishino, Y., & Maeda, Y. (1984) Agric. Biol. Chem. 48, 2163-2166) is known to inactivate pig heart aspartate aminotransferase [EC 2.6.1.1]. Chemical analysis of the core proteins and peptide fragments produced upon proteolysis of the aminotransferase revealed that peptide bond cleavage occurred specifically at Leu 20 with concomitant inactivation. Neither inactivation nor peptide bond cleavage was observed with the mitochondrial isoenzyme. The proteolytically produced derivative 21-412 of the cytosolic isoenzyme retained approximately 0.1% enzymic activity for transamination with natural dicarboxylic substrates. The pyridoxal form of the derivative 21-412 was fully converted by cysteinesulfinate or alanine to the pyridoxamine form and conversely the pyridoxamine form of the derivative was also fully converted by 2-oxoglutarate or pyruvate into the pyridoxal form, indicating that the derivative was still catalytically competent. However, the rates of reaction with dicarboxylic substrates were much reduced whereas the rates with monocarboxylic substrates remained at an order of magnitude similar to that observed with the native enzyme. Thus the NH2-terminal segment appears to be an import structural component which determines the substrate specificity of aspartate aminotransferase for dicarboxylic keto and amino acids. A substantial alteration in the molecular structure accompanying the loss of the NH2-terminal 20 residues was also reflected by the decrease in heat stability and in the lowering of the pKa value for His 68, which is involved in the intersubunit interaction of this dimeric enzyme.     

Fern L-methionine decarboxylase: kinetics and mechanism of decarboxylation and abortive transamination

L-Methionine decarboxylase from Dryopteris filix-mas catalyzes the decarboxylation of L-methionine and a range of straight- and branched-chain L-amino acids to give the corresponding amine products. The deuterium solvent isotope effects for the decarboxylation of (2S)-methionine are D(V/K) = 6.5 and DV = 2.3, for (2S)-valine are D(V/K) = 1.9 and DV = 2.6, and for (2S)-leucine are D(V/K) = 2.5 and DV = 1.0 at pL 5.5. At pL 6.0 and above, where the value of kcat for all of the substrates is low, the solvent isotope effects on Vmax for methionine are 1.1-1.2 whereas the effects on V/K remain unchanged, indicating that the solvent-sensitive transition state occurs before the first irreversible step, carbon dioxide desorption. The enzyme also catalyzes an abortive decarboxylation-transamination reaction in which the coenzyme is converted to pyridoxamine phosphate [Stevenson, D. E., Akhtar, M., & Gani, D. (1990a) Biochemistry (first paper of three in this issue)]. At very high concentration, the product amine can promote transamination of the coenzyme. However, the reaction occurs infrequently and does not influence the partitioning between decarboxylation and substrate-mediated abortive transamination under steady-state turnover conditions. The partition ratio, normal catalytic versus abortive events, can be determined from the amount of substrate consumed by a known amount of enzyme at infinite time, and the rate of inactivation can be determined by measuring the decrease in enzyme activity with respect to time. For methionine, the values of Km as determined from double-reciprocal plots of concentration versus inactivation rate are the same as those calculated from initial catalytic (decarboxylation) rate data, indicating that a single common intermediate partitions between product formation and slow transamination. The partition ratio is sensitive to changes in pH and is also dependent upon the structure of the substrate; methionine causes less frequent inactivation than either valine or leucine. The pH dependence of the partition ratio with methionine as substrate is very similar to that for V/K. Both curves show a sharp increase at approximately pH 6.25, indicating that a catalytic group on the enzyme simultaneously suppresses the abortive reaction and enhances physiological reaction in its unprotonated state. Experiments conducted in deuterium oxide allowed the solvent isotope effects for the partition ratio and the abortive reaction to be determined.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mechanism of reactions catalyzed by selenocysteine beta-lyase

The reaction mechanism of selenocystine beta-lyase has been studied and it was found that elemental selenium is released enzymatically from selenocysteine, and reduced to H2Se nonenzymatically with dithiothreitol or some other reductants that are added to prepare selenocysteine from selenocystine in the anaerobic reaction system. 1H and 13C NMR spectra of L-alanine formed in 2H2O have shown that an equimolar amount of [beta-2H1]- and [beta-2H2]alanines are produced. The deuterium isotope effect at the alpha position was observed; kH/kD = 2.4. These results indicated that the alpha hydrogen of selenocysteine was removed by a base at the active site, and was incorporated into the alpha position of alanine, a product, without exchange of a solvent deuterium. When the enzyme was incubated with L-selenocysteine in the absence of added pyridoxal 5'-phosphate, the activity decreased with prolonged incubation time. However, the activity was recovered by addition of 5'-phosphate. The spectrophotometric study showed that the inactivated enzyme was the apo form. The apoenzyme was activated by a combination of pyridoxamine 5'-phosphate and various alpha-keto acids such as alpha-ketoglutarate and pyruvate. Thus, the enzyme is inactivated through transamination between selenocysteine and the bound pyridoxal 5'-phosphate to produce pyridoxamine 5'-phosphate and a keto acid derived from selenocysteine. The pyridoxal enzyme, an active form, is regenerated by addition of alpha-keto acids. This regulatory mechanism is analogous to those of aspartate beta-decarboxylase [EC 4.1.1.12], arginine racemase [EC 5.1.1.9], and kynureninase [EC 3.7.1.3] [K. Soda and K. Tanizawa (1979) Adv. Enzymol. 49, 1].