Irreversible inactivation of rat liver tyrosine aminotransferase

Homogenates prepared from rat livers irreversibly inactivate tyrosine aminotransferase, both endogenous and purified exogenous enzyme, in the presence of certain compounds which bind to pyridoxal 5′-P. The rate of inactivation ranged from a half-life of 0.72 to greater than 15 hr. The pyridoxal 5′-P binding compounds may be considered to be structural analogs for α-ketoglutarate or l-tyrosine, both of which are substrates for the enzyme. l-Cysteine and l-DOPA are the most effective compounds tested of each of the two structural analog classes, respectively. Absence of the carboxyl group from l-cysteine or l-DOPA has little effect on the half-life of the enzyme, whereas absence or substitution of the amino group results in an increased enzyme half-life. Absence of the —SH group from l-cysteine or of the 3′-OH group from l-DOPA results in little or no inactivation of the enzyme ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ increased to greater than 15 hr). Semicarbazide and hydroxylamine have little effect on the stability of the enzyme. Addition of pyridoxal 5′-P to homogenates incubated with l-cysteine or l-DOPA inhibits the inactivation of the enzyme. However, the addition of cofactor to inactivated enzyme does not restore lost activity.There is a disappearance of antigenic cross-reacting material during inactivation of the enzyme. This loss of specific cross-reacting material occurs at a slower rate than the loss of enzyme activity, indicating that enzymatic activity is lost prior to loss of antigenic recognition. A three-step proposal is presented to explain the data observed in which the first step is a reversible loss of pyridoxal 5′-P from the enzyme, followed by a specific irreversible inactivation of the enzyme, and ending with nonspecific proteolysis or degradation of the inactivated enzyme molecules.     

Immobilization of nucleoside diphosphatase at its allosteric site using immobilized derivatives of pyridoxal 5'-phosphate

3-O-Immobilized and 6-immobilized pyridoxal 5′-phosphate analogs of Sepharose were bound to the allosteric site of nucleoside diphosphatase with very high affinity. Active immobilized nucleoside diphosphatase was prepared by reduction of the Schiff base linkage between the enzyme and pyridoxal 5′-phosphate bound to Sepharose with NaBH₄. 3-O-Immobilized pyridoxal 5′-phosphate analog gave more active immobilized enzyme than the 6-analog; the immobilized enzyme on the 3-O-immobilized pyridoxal 5′-phosphate analog showed about 90% of activity of free enzyme. The immobilized enzyme thus prepared was less sensitive to ATP, an allosteric effector, and showed a higher heat stability than the free enzyme. When an assay mixture containing inosine diphosphate and MgCl₂ was passed through a column of the immobilized enzyme at 37 °C, inosine diphosphate liberated inorganic phosphate almost quantitatively. Properties of the immobilized enzyme on the pyridoxal 5′-phosphate analog were compared with those of the immobilized enzyme on CNBr-activated Sepharose.     

Pyridoxal 5' phosphate: a selective inhibitor of oncornaviral DNA polymerases.

Pyridoxal 5′ phosphate at concentrations < 0.5 mM inhibits $\text{polymerization}$ of deoxynucleoside triphosphate catalysed by variety of DNA polymerases isolated from type C RNA tumor viruses, as well as $\text{E.}\text{coli}$, but $\text{does}\text{not}$ affect the polymerase associated RNase H activity. Both phosphate and aldehyde groups of pyridoxal phosphate are essential for the inhibition which appears to be mediated through the reversible Schiff base.     

Evidence for the regulation of pyridoxal 5′-phosphate formation in liver by pyridoxamine (pyridoxine) 5′-phosphate oxidase

Pyridoxamine (pyridoxine) 5′-phosphate oxidase (EC 1.4.3.5) purified from rabbit liver is competitively inhibited by the reaction product, pyridoxal 5′-phosphate. The K_i, 3 μM, is considerably lower than the K_m for either natural substrate (18 and 24 μM for pyridoxamine 5′-phosphate and 25 and 16 μM for pyridoxine 5′-phosphate in 0.2 M potassium phosphate at pH 8 and 7, respectively). The K_i determined using a 10% rabbit liver homogenate is the same as that for the pure enzyme; hence, product inhibition $\text{in}\text{vivo}$ is probably not diminished significantly by other cellular components. Similar determinations for a 10% rat liver homogenate also show strong inhibition by pyridoxal 5′-phosphate. Since the reported liver content of free or loosely bound pyridoxal 5′-phosphate is greater than K_i, the oxidase in liver is probably associated with pyridoxal 5′-phosphate. These results also suggest that product inhibition of pyridoxamine-P oxidase may regulate the $\text{in}\text{vivo}$ rate of pyridoxal 5′-phosphate formation.     

Inactivation of phosphofructokinase by dialdehyde-ATP.

Rabbit muscle phosphofructokinase (PFK) is rapidly inactivated by a 2′,3′-dialdehyde derivative of adenosine triphosphate (dialdehyde-ATP). When allowed to react with 0.6 mm dialdehyde-ATP in 0.1 m borate buffer (pH 8.6) containing 0.2 mm EDTA and 0.5 mm dithiothreitol, PFK loses essentially all activity (99%) in 30 min. The modified PFK remains inactive following dialysis of the reaction mixture against sodium borate (pH 8.0) containing fructose diphosphate, EDTA, and dithiothreitol. Experiments with [¹⁴C]dialdehyde-ATP show that 99% inactivation of PFK corresponds to incorporation of 3 to 4 mol of the ATP analog per PFK protomer. The inactivation of PFK with dialdehyde reagent is not caused by dissociation of the 340,000 M_r, tetramer to the 170,000 M_r dimer, as determined by analytical ultracentrifugation. Adenosine diphosphate or ATP protect PFK from inactivation by dialdehyde-ATP at pH 8.6, but fructose 6-phosphate, cyclic 3′,5t$\text{-}\text{?}$adenosine monophosphate, or fructose diphosphate, which protect PFK from modification by pyridoxal phosphate, provide little protection from inactivation. Amino acid analyses of dialdehyde-inactivated PFK and of a control sample of the enzyme were compared following reaction of each with 2,4-dinitrofluorobenzene. The results show that three or four lysine residues per PFK protomer are modified by dialdehyde-ATP. Additional data indicate that these lysine residues react with dialdehyde-ATP to form dihydroxymorpholine-like adducts rather than Schiff bases.     

Reaction of pyridoxal 5'-phosphate with Escherichia coli CoA transferase: evidence for an essential lysine residue.

The acetyl-CoA:acetoacetate CoA-transferase of Escherichia coli was reversibly inactivated by pyridoxal 5′-phosphate. The residual activity of the enzyme was dependent on the concentration of the modifying reagent to a concentration of 5 mm. The maximum level of inactivation was 89%. Kinetic and equilibrium analyses of inactivation were consistent with a two-step process (Chen and Engel, 1975, Biochem. J.149, 619) in which the extent of inactivation was limited by the ratio of first-order rate constants for the reversible formation of an inactive Schiff base of pyridoxal 5′-phosphate and the enzyme from a noncovalent, dissociable complex of the enzyme and modifier. The calculated minimum residual activity was in close agreement with the experimentally determined value. The conclusion that the loss of catalytic activity resulted from modification of a lysine residue at the active site was based on the following data, (a) After incubation with 5 mm pyridoxal 5′-phosphate, 3.95 mol of the reagent was incorporated per mole of free enzyme with 89% loss of activity, while 2.75 mol of pyridoxal 5′-phosphate was incorporated into the enzyme-CoA intermediate with a loss of 10% of catalytic activity; the intermediate was formed in the presence of acetoacetyl-CoA; (b) acid hydrolysis of the modified, reduced enzyme-CoA intermediate yielded a single fluorescent compound that was identified as N⁶-pyridoxyllysine by chromatography in two solvent systems; (c) the enzyme was also protected from inactivation by saturating concentrations of free CoA and ADP but not by adenosine. The results suggested that a lysine residue is involved in the electrostatic binding of the pyrophosphate group of CoA. Carboxylic acid substrate did not protect the enzyme from inactivation.     

Chemical modification of an essential lysine at the active site of enoyl-CoA reductase in fatty acid synthetase

Fatty acid synthetase from goose uropygial gland was inactivated by treatment with pyridoxal 5′-phosphate. Malonyl-CoA and acetyl-CoA did not protect the enzyme whereas NADPH provided about 70% protection against this inactivation. 2′-Monophospho-ADP-ribose was nearly as effective as NADPH while 2′-AMP, 5′-AMP, ADP-ribose, and NADH were ineffective suggesting that pyridoxal 5′-phosphate modified a group that interacts with the 5′-pyrophosphoryl group of NADPH and that the 2′-phosphate is necessary for the binding of the coenzyme to the enzyme. Of the seven component activities catalyzed by fatty acid synthetase only the enoyl-CoA reductase activity was inhibited. Inactivation of both the overall activity and enoyl-CoA reductase of fatty acid synthetase by this compound was reversed by dialysis or dilution but not after reduction with NaBH₄. The modified protein showed a characteristic Schiff base absorption (maximum at 425 nm) that disappeared on reduction with NaBH₄ resulting in a new absorption spectrum with a maximum at 325 nm. After reduction the protein showed a fluorescence spectrum with a maximum at 394 nm. Reduction of pyridoxal phosphate-treated protein with NaB³H₄ resulted in incorporation of ³H into the protein and paper chromatography of the acid hydrolysate of the modified protein showed only one fluorescent spot which was labeled and ninhydrin positive and had an R_f identical to that of authentic N⁶-pyridoxyllysine. When [4-³H]pyridoxal phosphate was used all of the ³H, incorporated into the protein, was found in pyridoxyllysine. All of these results strongly suggest that pyridoxal phosphate inhibited fatty acid synthetase by forming a Schiff base with the ?-amino group of lysine in the enoyl-CoA reductase domain of the enzyme. The number of lysine residues modified was estimated with [4-³H]pyridoxal-5′-phosphate/NaBH₄ and by pyridoxal-5′-phosphate/NaB³H₄. Scatchard analysis showed that modification of two lysine residues per subunit resulted in complete inactivation of the overall activity and enoyl-CoA reductase of fatty acid synthetase. NADPH prevented the inactivation of the enzyme by protecting one of these two lysine residues from modification. The present results are consistent with the hypothesis that each subunit of the enzyme contains an enoyl-CoA reductase domain in which a lysine residue, at or near the active site, interacts with NADPH.     

Pyridoxylation of essential lysine residues of mitochondrial adenosine triphosphatase

1. Soluble beef-heart mitochondrial ATPase (F₁) was incubated with [³H]pyridoxal 5′-phosphate and the Schiffbase complex formed was reduced with sodium borohydride. Spectral measurements indicate that lysine residues are modified and gel electrophoresis in the presence of detergent shows the tritium label to be associated with the two largest subunits, α and β. 2. In the absence of protecting ligands, the loss of ATP hydrolysis activity is linearly dependent on the level of pyridoxylation with complete inactivation correlating to 10 mol pyridoxamine phosphate incorporated per mol enzyme. Partial inactivation of F₁ with pyridoxal phosphate has no effect on either the K_m for ATP or the ability of bicarbonate to stimulate residual hydrolysis activity, suggesting a mixed population of fully active and fully inactive enzyme. 3. In the presence of excess magnesium, the addition of ADP or ATP, but not AMP, decreases the rate and extent of modification of F₁ by pyridoxal phosphate. The non-hydrolyzable ATP analog, 5′-adenylyl-β, γ-imidodiphosphate, is particularly effective in protecting F₁ against both modification and inactivation. Efrapeptin and P_i have no effect on the modification reaction. 4. Prior modification of F₁ with pyridoxal phosphate decreases the number of exchangeable nucleotide binding sites by one. However, pyridoxylation of F₁ is ineffective in displacing endogenous nucleotides bound at non-catalytic sites and does not affect the stoichiometry of P_i binding. 5. The ability of nucleotides to protect against modification and inactivation by pyridoxal phosphate and the loss of one exchangeable nucleotide site with the pyridoxylation of F₁ suggest the presence of a positively charged lysine residue at the catalytic site of an enzyme that binds two negatively charged substrates.     

Changes in the intracellular levels of pyridoxal 5'-phosphate affect the induction of tyrosine aminotransferase by glucocorticoids

In the present study a cell culture system was used to correlate the intracellular levels of pyridoxal 5′-phosphate with the induction of the hepatic enzyme, tyrosine aminotransferase, by glucocorticoids. Increased intracellular levels of pyridoxal 5′-phosphate produced antiglucocorticoid effects whereas a reduction in pyridoxal 5′-phosphate content increased the sensitivity of cells to glucocorticoids. The data strongly implicate pyridoxal 5′-phosphate as an $\text{in}\text{vivo}$ modulator of the glucocorticoid receptor. The mechanism by which pyridoxal 5′-phosphate modulates the receptor is presumably through its binding to the DNA-binding site of the “activated” form of the receptor complex.     

Inhibition of D-ribulose 1,5-bisphosphate carboxylase by pyridoxal 5′-phosphate

Homogeneous D-ribulose 1,5-bisphosphate carboxylase from $\text{Rhodospirillum rubrum}$, $\text{Chlamydomonas reinhardtii}$, and $\text{Hydrogenomonas eutropha}$ are inhibited by low concentrations of pyridoxal 5′-phosphate. In the case of the enzyme from $\text{Rhodospirillum rubrum}$, this inhibition is strongly antagonized by the substrate, D-ribulose 1,5-bisphosphate. These results suggest that pyridoxal 5′-phosphate may act close to or at the ribulose 1,5-bisphosphate binding site of the enzyme from $\text{Rhodospirillum rubrum}$.     

Control of 5-aminolaevulinate synthetase activity in Rhodopseudomonas spheroides. Binding of pyridoxal phosphate to 5-aminolaevulinate synthetase.

1. Pyridoxal 5'-phosphate is a cofactor essential for the enzymic activity of aminolaevulinate synthetase from Rhodopseudomonas spheroides. It also aids activation of the low-activity enzyme by trisulphides such as cystine trisulphide, whereas inactivation of enzyme is facilitated by its absence. 2. The fluorescence spectrum of purified high-activity enzyme is that expected for a pyridoxal phosphate--Schiff base, but the firmly bound cofactor does not appear to be at the active centre. In dilute solutions of enzyme this grouping is inaccessible to nucleophiles such as glycine, hydroxylamine, borohydride and cyanide, at pH 7.4. 3. An active-centre Schiff base is formed between enzyne and added pyridoxal phosphate, which is accessible to nucleophiles. Concentrated solutions of this enzyme--Schiff base on treatment with glycine yield apo- and semi-apoenzyme, which can re-bind pyridoxal phosphate. 4. Two types of binding of pyridoxal phosphate are distinguishable in dilute solution of enzyme, but these become indistinguishable when concentrated solutions are treated with cofactor. A change occurs in the susceptibility towards borohydride of the fluorescence of the "structural" pyridoxal phosphate. 5. One or two molecules of cofactor are bound per subunit of mol. wt. 50 000 in semiapo- or holo-enzyme. The fluorescence of pyridoxamine phosphate covalently bound to enzyme also indicates one to two nmol of reducible Schiff base per 7000 units of activity in purified and partially purified samples of enzyme. 6. Cyanide does not convert high-activity into low-activity enzyme, but with the enzyme-pyridoxal phosphate complex it forms a yellow fluorescent derivative that is enzymically active.     

A steady-state kinetic study of the ribonuclease A catalyzed hydrolysis of uridine-2′:3′(cyclic)-5′-diphosphate

Initial velocity measurements were made on the ribonuclease A catalyzed hydrolysis of P-5′-Urd-2′:3′-P in the pH range 4.0–8.0 at 25 °C in 0.1 m Tris-acetate/0.1 m KCl. The pH dependence of the Michaelis constant, K_m, the turnover number k_s, and $\text{k}{}_{\mathrm{s}}\text{K}{}_{\mathrm{m}}$ for P-5′-Urd-2′:3′-P were similar to those reported for Urd-2′:3′-P (5). When P-5′-Urd-2,3-P and Urd-2′:3′-P were compared under similar conditions the average difference in k_s and K_m indicated that these parameters were 5-fold and 23-fold lower, respectively, for P-5′-Urd-2′:3′-P. The slight difference in the pH dependence of $\text{k}{}_{\mathrm{s}}\text{K}{}_{\mathrm{m}}$ for these two substrates can be interpreted in terms of a specific interaction of the enzyme at the 5′ position of P-5′-Urd-2′:3′-P, which permits a less exclusive dependence on the ionized state of the free enzyme in binding this substrate. The nature of the interaction of the substrate 5′-phosphomonoester group with the enzyme is discussed in terms of possible interactions with Lys-41 and His-119.     

The glycine-rich region of Escherichia coli D-serine dehydratase. Altered interactions with pyridoxal 5'-phosphate produced by substitution of aspartic acid for glycine

Replacement of glycine by aspartic acid at either of two sites in a conserved, glycine-rich region inactivates the pyridoxal 5'-phosphate-dependent enzyme D-serine dehydratase (DSD) from Escherichia coli. To investigate why aspartic acid at position 279 or 281 causes a loss of activity, we measured the affinity of the G----D variants for pyridoxal 5'-phosphate and a cofactor:substrate analog complex and compared the UV, CD, and fluorescence properties of wild-type D-serine dehydratase and the inactive variants. The two G----D variants DSD(G279D) and DSD (G281D) displayed marked differences from wild-type D-serine dehydratase and from each other with respect to their affinity for pyridoxal 5'-phosphate and for a pyridoxal 5'-phosphate:glycine Schiff base. Compared to the wild-type enzyme, the cofactor affinity of DSD(G279D) and DSD(G281D) was decreased 225- and 50-fold, respectively, and the ability to retain a cofactor:glycine complex was decreased 765- and 1970-fold. The spectral properties of the inactive variants suggest that they form a Schiff base linkage with pyridoxal 5'-phosphate but do not hold the cofactor in a catalytically competent orientation. Moreover, the amount of cofactor aldamine in equilibrium with cofactor Schiff base is increased in DSD(G279D) and DSD(G281D) relative to that in wild-type DSD. Collectively, our findings indicate that introduction of a carboxymethyl side chain at G-279 or G-281 directly or indirectly disrupts catalytically essential protein-cofactor and protein-substrate interactions and thereby prevents processing of the enzyme bound cofactor:substrate complex. The conserved glycine-rich region is thus either an integral part of the D-serine dehydratase active site or conformationally linked to it.     

Crystal and molecular structure of [Cu(5'-inosine monophosphate) (dipyridylamine) (H2O)]2.4H2O.

The ternary complex [Cu(5′-IMP)(dpa)(H₂O)]₂ has been prepared and its structure analyzed by x-ray diffraction. It has a dimeric structure in which the 5′-IMP ligands coordinate solely through their phosphate groups. This geometry is in marked contrast to that of another $\text{Cu}\text{5′-}\text{IMP}$ ternary complex, [Cu(5′-IMPH)(bipy)(H₂O)₂]⁺, which shows metal binding through the purine base rather than the phosphate group.     

KINETICS OF BRAIN GLUTAMATE DECARBOXYLASE. INTERACTIONS WITH GLUTAMATE,PYRIDOXAL 5-PHOSPHATE AND GLUTAMATE-PYRIDOXAL 5-PHOSPHATE SCHIFF BASE1

Abstract— The kinetic behavior of glutamate decarboxylase from mouse brain was analyzed in a wide range of glutamate and pyridoxal 5′-phosphate concentrations, approaching three limit conditions: (I) in the absence of glutamate-pyridoxal phosphate Schiff base; (II) when all glutamate is trapped in the form of Schiff base; (III) when all pyridoxal phosphate is trapped in the form of Schiff base. The experimental results in limit condition (I) are consistent with the existence of two different enzyme activities, one dependent and the other independent of free pyridoxal phosphate. The results obtained in limit conditions (II) and (III) give further support to this postulation. These data show that the free pyridoxal phosphate-dependent activity can be abolished when either all substrate or all cofactor are in the form of Schiff base. The free pyridoxal phosphate-independent activity is also abolished when all substrate is trapped as Schiff base, but it is not affected by the conversion of free pyridoxal phosphate into the Schiff base. A kinetic and mechanistic model for brain glutamate decarboxylase activity, which accounts for these observations as well as for the results of previous dead end-inhibition studies, is postulated. Computer simulations of this model, using the experimentally obtained kinetic constants, reproduced all the observed features of the enzyme behavior. The possible implications of the kinetic model for the regulation of the enzyme activity are discussed.     

Evidence that the essential, photosensitive histidyl residue in the beta2 subunit of tryptophan synthetase is in the pyridoxyl peptide

The β₂ subunit of tryptophan synthetase of Escherichia coli is photoinactivated in the presence of pyridoxal 5′-phosphate and L-serine as a result of the destruction of one histidyl residue per chain (1). Two tryptic peptides are found in much lower amounts in the photoinactivated enzyme than in the control enzyme. These peptides have been identified from their amino acid composition as the 9 or 10 residue peptides which terminate with the lysyl residue which forms a Schiff base with pyridoxal 5′-phosphate. These peptides contain two histidyl residues, one of which appears to be photosensitive. Thus pyridoxal 5′-phosphate sensitizes the photooxidation of a nearby, essential histidyl residue.     

Inactivation of E. coli RNA polymerase by pyridoxal 5'-phosphate: identificationof a low pKa lysine as the modified residue.

The inactivation of E. coli RNA polymerase (3.3 × 10^?7M) by pyridoxal 5′-phosphate (1 × 10^?4M to 5 × 10^?4M) is a first order process with respect to the remaining active enzyme. Studies of the variation of the first order rate constant with the concentration of pyridoxal 5′-phosphate show that the inactivation reaction follows saturation kinetics. The formation of a reversible enzyme-inhibitor intermediate is postulated. Kinetic studies at different pH values indicate that the inactivation rate constant depends on the mole fraction of one conjugate base with pK_a 7.9. The apparent equilibrium constant (association) for the inactivation reaction is independent of the pH and is 1.8 × 10⁴ M^?1. By electrophoretic and chromatographic analysis of enzyme hydrolyzates after pyridoxal 5′-phosphate and NaBH₄ treatment only N-ε-pyridoxyllysine was found. It is postulated that a lysine ε-amino group with a low pK_a is critical for the activity of the enzyme.     

Alliin lyase: preparation and characterization of the homogeneous enzyme from onion bulbs.

Alliin lyase (alliin alkyl-sulfenate-lyase, EC 4.4.1.4; alliinase) of onion bulbs has been purified to homogeneity. The enzyme catalyzes the following β-elimination reaction.

Based on sedimentation equilibrium centrifugation data, the enzyme has a molecular weight of 150,000. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) showed a single subunit of M_r 50,000. Urea-polyacrylamide gel electrophoresis also yielded a single band after staining with Coomassie blue. The enzyme was shown to be a glycoprotein by the use of a periodic acid-Schiff base staining technique on SDS-PAGE-treated preparations. The carbohydrate moiety was 5.8% of the total protein molecular weight. It consisted of simple sugars, hexoseamines, and methyl pentose, but no sialic acid was found. The enzyme activity showed no requirement for exogenous pyridoxal 5′-phosphate. Inhibition and spectrophotometric studies indicated this cofactor was already bound to the enzyme. Chemical analysis revealed that there were 3 mol of pyridoxal 5′-phosphate per 150,000 g of enzyme.     

Inactivation of avian progesterone receptor binding to ATP-Sepharose by pyridoxal 5'-phosphate

The affinity of progesterone receptor from hen oviduct for ATP-Sepharose was diminished by preincubation with pyridoxal 5′-phosphate. This effect was specific for pyridoxal 5′-phosphate since the related compounds, pyridoxal, pyridoxine, pyridoxamine and pyridoxamine 5′-phosphate, were not effectors. The inactivation was easily reversed by the addition of the primary amine, Tris. However, in the presence of the reducing agent NaBH₄, the inhibitory effect of pyridoxal 5′-phosphate was irreversible. The results suggest that pyridoxal 5′-phosphate forms a Schiff base with a critical amino group, presumably at the nucleotide binding site of the progesterone receptor.