The oxidation of Schiff bases of pyridoxamine with α-oxo acids by manganous ions and peroxidase

1. Oxygen was taken up rapidly when pyruvate was added to mixtures of pyridoxamine and Mn(2+) ions after lag periods that were shortened by peroxidase (donor-hydrogen peroxide oxidoreductase, EC 1.11.1.7). 2. The total oxygen uptake was proportional to the pyridoxamine added and was accompanied by the disappearance of pyridoxamine; the pyruvate acted catalytically and hydrogen peroxide was not formed. 3. At pH6 more than half the pyridoxamine that disappeared was accounted for as pyridoxal and ammonia; it is suggested that the primary reaction is the oxidative deamination of the pyridoxamine. 4. Results were similar when alpha-oxobutyrate or glyoxylate were substituted for pyruvate, except that the reactions were slower and the yield of pyridoxal less. 5. The oxidative decarboxylations of alpha-oxoglutarate and phenylpyruvate are catalysed by Mn(2+) ions and these reactions are activated by peroxidase; pyridoxamine increased both the rates and total oxygen uptakes in these reactions, and ammonia was produced. 6. The lag periods in the oxidation of mixtures of pyridoxamine and alpha-oxo acids, catalysed by Mn(2+) ions, were also shortened by traces of colloidal manganese dioxide. 7. It is suggested that the activating effect of peroxidase depends on its catalysis of manganese oxidation.     

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.     

How pyridoxal 5'-phosphate could function in glycogen phosphorylase catalysis.

A mechanism for the phosphorylase reaction is proposed which offers a plausible explanation for the essential role of pyridoxal 5'-phosphate in glycogen phosphorylases: in the forward direction, phosphorolysis of alpha-1,4-glycosidic bonds in oligo- or polysaccharides is started by protonation of the glycosidic oxygen by the substrate orthophosphate followed by stabilization of the incipient oxocarbonium ion and subsequent covalent binding to form alpha-glucose 1-phosphate. In the reverse direction, protonation of the phosphate of glucose 1-phosphate destabilizes the glycosidic bond and promotes formation of a glucosyl oxocarbonium ion-phosphate anion pair. In the subsequent step the phosphate anion facilitates the nucleophilic attack of a terminal glucosyl residue on the carbonium ion bringing about alpha-1,4-glycosidic bond formation and primer elongation. Both in the forward and reverse reactions, the phosphate of the cofactor pyridoxal 5'-phosphate acts as a general acid (PL-OPO3H- or PL-OPO3(2-) and protonates the substrate phosphate functioning as proton shuttle. Thus in glycogen phosphorylases, phosphates which directly interact with each other have replaced a pair of amino acid carboxyl groups functioning in catalysis of carbohydrases.     

Pea leaf glutamine synthetase: regulatory properties

Of a variety of purine and pyrimidine nucleotides tested, only ADP and 5'AMP significantly inhibited the Mg(2+)-dependent activity of pea leaf glutamine synthetase. They were less effective inhibitors where Mn(2+) replaced Mg(2+). They were competitive inhibitors with respect to ATP, with inhibition constant (Ki) values of 1.2 and 1.8 mm, respectively. The energy charge significantly affects the activity of glutamine synthetase, especially with Mg(2+). Of a variety of amino acids tested, l-histidine and l-ornithine were the most inhibitory, but significant inhibition was seen only where Mn(2+) was present. Both amino acids appeared to compete with l-glutamate, and the Ki values were 1.9 mm for l-histidine (pH 6.2) and 7.8 mm for l-ornithine (pH 6.2). l-Alanine, glycine, and l-serine caused slight inhibition (Mn(2+)-dependent activity) and were not competitive with ATP or l-glutamate.Carbamyl phosphate was an effective inhibitor only when Mn(2+) was present, and did not compete with substrates. Inorganic phosphate and pyrophosphate caused significant inhibition of the Mg(2+)-dependent activity.     

Interrelationships between pyridoxal phosphate and pyridoxal kinase in rabbit brain

—An inverse relationship was demonstrable between the concentration of pyridoxal phosphate and the activity of pyridoxal kinase in rabbit brain. The administration of pyridoxine elevated the concentration of pyridoxal phosphate and decreased the activity of pyridoxal kinase. Conversely, the administration of deoxypyridoxine decreased the concentration of pyridoxal phosphate and increased the activity of pyridoxal kinase. The increase in the activity of pyridoxal kinase by deoxypyridoxine was blocked by actinomycin D or puromycin. These results were interpreted to indicate that the tissue availability of pyridoxal phosphate regulated the activity of pyridoxal kinase.     

On the inhibitory activity of 4-vinyl analogues of pyridoxal: enzyme and cell culture studies.

Analogues of pyridoxal and of pyridoxal phosphate in which the 4-CHO group is replaced with CH = CH2 were synthesized and were found to be potent inhibitors of pyridoxal kinase and pyridoxine phosphate oxidase of rat liver. They also inhibited the growth of mouse Sarcoma 180 and mammary adenocarcinoma TA3 in cell culture. Saturation of the vinyl double bond, replacement of the 5-CH2OH with methyl, methylation of the phenolic hydroxyl, or conversion to the N-oxide resulted in diminution or loss of all these activities. Similarly, the introduction of a beta-methyl group into the vinyl analogues of pyridoxal reduced all these inhibitory activities. The 4-vinyl anatogue of pyridoxal was shown to be a substrate of pyridoxal kinase and the product a potent inhibitor of pyridoxine oxidase, competing with pyridoxal phosphate. The affinity of this phosphorylated pyridoxal analogue to some apoenzymes varied greatly, indicating striking differences among the cofactor binding sites of these enzymes. The growth inhibitory effects of these analogues on cells in culture correlated well with their effects on pyridoxal kinase and pyridoxine phosphate oxidase in cell-free systems.     

Role of pyridoxal phosphate in mammalian polyamine biosynthesis. Lack of requirement for mammalian S-adenosylmethionine decarboxylase activity.

1. Polyamine concentrations were decreased in rats fed on a diet deficient in vitamin B-6. 2. Ornithine decarboxylase activity was decreased by vitamin B-6 deficiency when assayed in tissue extracts without addition of pyridoxal phosphate, but was greater than in control extracts when pyridoxal phosphate was present in saturating amounts. 3. In contrast, the activity of S-adenosylmethionine decarboxylase was not enhanced by pyridoxal phosphate addition even when dialysed extracts were prepared from tissues of young rats suckled by mothers fed on the vitamin B-6-deficient diet. 4. S-Adenosylmethionine decarboxylase activities were increased by administration of methylglyoxal bis(guanylhydrazone) (1,1'-[(methylethanediylidine)dinitrilo]diguanidine) to similar extents in both control and vitamin B-6-deficient animals. 5. The spectrum of highly purified liver S-adenosylmethionine decarboxylase did not indicate the presence of pyridoxal phosphate. After inactivation of the enzyme by reaction with NaB3H4, radioactivity was incorporated into the enzyme, but was not present as a reduced derivative of pyridoxal phosphate. 6. It is concluded that the decreased concentrations of polyamines in rats fed on a diet containing vitamin B-6 may be due to decreased activity or ornithine decarboxylase or may be caused by an unknown mechanism responding to growth retardation produced by the vitamin deficiency. In either case, measurements of S-adenosylmethionine decarboxylase and ornithine decarboxylase activity under optimum conditions in vitro do not correlate with the polyamine concentrations in vivo.     

Structure-based development of pyridoxal propionate derivatives as specific inhibitors of cathepsin K in vitro and in vivo

We found that pyridoxal phosphate shows considerable inhibition of cathepsins. CLIK-071, in which the phosphate ester of position 3 of pyridoxal phosphate was replaced by propionate, strongly inhibited cathepsin B. Three new types of synthetic pyridoxal propionate derivatives showing specific inhibition of cathepsin K were developed. New synthetic pyridoxal propionate derivatives, -162, -163, and -164, in which the methyl arm of position 6 of CLIK-071 was additionally modified, strongly inhibited cathepsin K and cathepsin S weakly, but other cathepsins were not inhibited. CLIK-166, in which the position 4 aldehyde of CLIK-071 is replaced by a vinyl radical and position 5 is additionally modified, showed cathepsin K-specific inhibition at 10(-5) M. Pit formation due to bone collagen degradation by cathepsin K of rat osteoclasts was specifically suppressed by administration of CLIK-164, but not by inhibitors of cathepsin L or B.     

Observations on the pyridoxal 5'-phosphate inhibition of DNA polymerases.

Pyridoxal 5'-phosphate at concentrations greater than 0.5 mM inhibits polymerization of deoxynucleoside triphosphate catalyzed by a variety of DNA polymerases. The requirement for a phosphate as well as aldehyde moiety of pyridoxal phosphate for inhibition to occur is clearly shown by the fact that neither pyridoxal nor pyridoxamine phosphate are effective inhibitors. Since the addition of nonenzyme protein or increasing the amount of template primer exerted no protective effect, there appears to be specific affinity between pyridoxal phosphate and polymerase protein. The deoxynucleoside triphosphates, however, could reverse the inhibition. The binding of pyridoxal 5'-phosphate to enzyme appears to be mediated through classical Schiff base formation between the pyridoxal phosphate and the free amino group(s) present at the active site of the polymerase protein. Kinetic studies indicate that inhibition by pyridoxal phosphate is competitive with respect to substrate deoxynucleoside triphosphate(s).     

Activation and inactivation of horse liver alcohol dehydrogenase with pyridoxal compounds.

Pyridoxal compounds can either activate or inactivate horse liver alcohol dehydrogenase in differential labeling experiments. Amino groups outside of the active sites were modified with ethyl acetimidate, while the amino groups in the active sites were protected by the formation of the complex with NAD-plus and pyrazole. After removal of the NAD-plus and pyranzole, the partially acetimidylated enzyme was reductively alkylated with pyridoxal and NaBH4, with the incorporation of one pyridoxal group per subunit of the enzyme. The turnover numbers for the reaction of NAD-plus and ethanol increased by 15-fold, and for NADH and acetaldehyde by 32-fold. The Michaelis and inhibition constants increased 80-fold or more. Pyridoxal phosphate and NaBH4 also modified one group per subunit, but the turnover numbers decreased by 10-fold and the kinetic constants were intermediate between those obtained for pyridoxyl alcohol dehydrogenase and the partially acetimidylated enzyme. With native enzyme, the rates of dissociation of the enzyme-coenzyme complexes are rate-limiting in the catalytic reactions. The pyridoxyl enzyme is activated because the rates of dissociation of the enzyme-coenzyme complexes are increased. The rates of binding of coenzyme to phosphopyridoxyl enzyme have decreased due to the introduction of the negatively charged phosphate. The size of the group is not responsible for this decrease since these rates are not greatly decreased by the incorporation of pyridoxal. For both pyrodoxal and phosphopyridoxyl alcohol dehydrogenases, the interconversion of the ternary complex is at least partially rate-limiting. Chymotryptic-tryptic digestion of pryidoxyl enzyme produced a major peptide corresponding to residues 219 to 229, in which Lys 228 had reacted with pyridoxal. The same lysine residue reacted with pyridoxal phosphate.     

Polyamine biosynthesis and vitamin B6 deficiency Evidence for pyridoxal phosphate as coenzyme for S-adenosylmethionine decarboxylase

Extracts of liver from vitamin B₆-deficient rats had only 50% of the S-adenosylmethionine decarboxylase activity of extracts of liver from control rats when assayed with no exogenous pyridoxal phosphate. When pyridoxal phosphate was included in the reaction mixture, both extracts exhibited the same activity, indicating that pyridoxal phosphate is the coenzyme for S-adenosylmethionine decarboxylase. There was no similar decreased activity in extracts of brain from vitamin B₆-deficient rats.The activity of the pyridoxal phosphate-dependent enzyme, ornithine decarboxylase, was increased in extracts of liver from vitamin B₆-deficient rats: 1.6-fold when assayed with no pyridoxal phosphate and 4-fold when assayed with pyridoxal phosphate.The concentrations of putrescine and spermidine were decreased 50% in liver of vitamin B₆-deficient animals, but only putrescine was decreased in brain. Putreanine was barely detectable in liver of vitamin B₆-deficient animals, but was unchanged in brain.     

Inactivation of rhodanese by pyridoxal 5'-phosphate.

Pyridoxal 5'-phosphate and other aromatic aldehydes inactivate rhodanese. The inactivation reaches higher extents if the enzyme is in the sulfur-free form. The identification of the reactive residue as an amino group has been made by spectrophotometric determination of the 5'-phosphorylated pyridoxyl derivative of the enzyme. The inactivation increases with pyridoxal 5'-phosphate concentration and can be partially removed by adding thiosulfate or valine. Prolonged dialysis against phosphate buffer also leads to the enzyme reactivation. The absorption spectra of the pyridoxal phosphate - rhodanese complex show a peak at 410 nm related to the Schiff base and a shoulder in the 330 nm region which is probably due to the reaction between pyridoxal 5'-phosphate and both the amino and thiol groups of the enzyme that appear reasonably close to each other. The relationship betweenloss of activity and pyridoxal 5'-phosphate binding to the enzyme shows that complete inactivation is achieved when four lysyl residues are linked to pyridoxal 5'-phosphate.     

Mechanism of inhibition of thrombin-induced platelet aggregation by pyridoxal phosphate

Thrombin and ADP-induced platelet aggregation are reversibly inhibited by pyridoxal phosphate. Sodium borohydride converts Schiff bases formed between pyridoxal phosphate and amino groups to covalent bonds. When platelets treated with sodium borohydride and pyridoxal phosphate are resuspended in fresh platelet-poor plasma, they recover their response to thrombin, but not to ADP. Thus Schiff base formation between pyridoxal phosphate and platelet surface amino groups does not block thrombin aggregation. The loss of thrombin potency as an aggregating agent is due to interaction between pyridoxal phosphate and thrombin. This is evidenced by spectrophometric determination of adduct formation and loss of hydrolytic action on p-tosyl-L-arginine methyl ester.     

The inactivation of pea-seedling diamine oxidase by peroxidase and 1,5-diaminopentane

1. The rate of oxidative deamination of 1,5-diaminopentane by pea-seedling extracts, which contain diamine oxidase [diamine-oxygen oxidoreductase (deaminating), EC 1.4.3.6], was increased by adding pyridoxal or pyridoxal phosphate. 2. Evidence was obtained that pyridoxal does not activate the apoenzyme of diamine oxidase, but prevents the inactivation of the enzyme. 3. This inactivation only occurred when 1,5-diaminopentane was the substrate and depended on a second thermolabile factor in the extract besides the diamine oxidase. 4. Purified diamine oxidase, when catalysing the oxidation of 1,5-diaminopentane, was rapidly inactivated in the presence of peroxidase. 5. The inactivation was prevented not only by pyridoxal and pyridoxal phosphate but also by several unrelated compounds including alpha-oxoglutarate, catechol and o-aminobenzaldehyde. 6. It is suggested that peroxidase catalyses the further oxidation of the product of the oxidative deamination of 1,5-diaminopentane to a compound that inactivates diamine oxidase. 7. The results diminish the relevance of previous evidence that plant diamine oxidase contains pyridoxal phosphate.     

The conversion of pyridoxine phosphate into pyridoxal phosphate in Escherichia coli

1. Evidence is presented for the presence of pyridoxine phosphate oxidase in aqueous extracts of Escherichia coli. Some comparison is made with pyridoxamine phosphate oxidase. 2. Isoniazid and iproniazid were found to combine with pyridoxal phosphate, but isoniazid did not combine with either pyridoxamine phosphate or pyridoxine phosphate. Both oxidase activities were somewhat inhibited by benzylamine and putrescine, but not by phenethylamine or cadaverine. 3. The significance of pyridoxine phosphate oxidase in cell metabolism is discussed.     

Plants synthesize ethanolamine by direct decarboxylation of serine using a pyridoxal phosphate enzyme.

The established pathways from serine to ethanolamine are indirect and involve decarboxylation of phosphatidylserine. Here we show that plants can decarboxylate serine directly. Using a radioassay based on ethanolamine (Etn) formation, pyridoxal 5'-phosphate-dependent l-serine decarboxylase (SDC) activity was readily detected in soluble extracts from leaves of diverse species, including spinach, Arabidopsis, and rapeseed. A putative Arabidopsis SDC cDNA was identified by searching GenBank for sequences homologous to other amino acid decarboxylases and shown by expression in Escherichia coli to encode a soluble protein with SDC activity. This cDNA was further authenticated by complementing the Etn requirement of a yeast psd1 psd2 mutant. In a parallel approach, a cDNA was isolated from a rapeseed library by its ability to complement the Etn requirement of a yeast cho1 mutant and shown by expression in E. coli to specify SDC. The deduced Arabidopsis and rapeseed SDC polypeptides are 90% identical, lack obvious targeting signals, and belong to amino acid decarboxylase group II. Recombinant Arabidopsis SDC was shown to exist as a tetramer and to contain pyridoxal 5'-phosphate. It does not attack d-serine, l-phosphoserine, other l-amino acids, or phosphatidylserine and is not inhibited by Etn, choline, or their phosphoesters. As a soluble, pyridoxal 5'-phosphate enzyme, SDC contrasts sharply with phosphatidylserine decarboxylases, which are membrane proteins that have a pyruvoyl cofactor.     

Influence of magnesium and manganese on some biological and physical properties of tetracycline

Accumulation of (3)H-tetracycline in nonproliferating cells of susceptible and resistant strains of Escherichia coli and Staphylococcus aureus in tris(hydroxymethyl)aminomethane (Tris) buffer (10 mm, pH 7.5) was significantly decreased in the presence of 5 to 40 mm MgCl(2) and increased in the presence of 5 to 10 mm MnCl(2). When the bacteria first accumulated (3)H-tetracycline in plain Tris.HCl, and the metal salts were thereafter added, a prompt decrease or increase in radioactivity of the cells was observed after the addition of Mg(2+) or Mn(2+), respectively. In phosphate buffer (10 mm, pH 7.5), the effect of Mg(2+) was delayed. Three minutes after addition of (3)H-tetracycline, uptake was as in the control cell suspension, but thereafter it dropped rapidly. When (3)H-tetracycline was incubated with Mg(2+) before addition to the bacterial suspension, uptake was scarcely measurable. The addition of Mg(2+) to growing cultures of S. aureus and E. coli caused a marked decrease in susceptibility; in contrast, no increase in susceptibility could be demonstrated when Mn(2+) was added. It was also demonstrated that Mg(2+) and Mn(2+) had distinct influences on the absorption spectrum, the optical rotatory dispersion, the circular dichroism, and the lipid solubility of tetracycline.     

Ornithine transaminase from Cucurbita maxima cotyledons

During germination a marked increase in both soluble and particulate ornthine transaminase occurs in pumpkin cotyledons. Both enzymes had a pH optimum of 8.3 and a requirement for ornthine and α-ketoglutarate. Other keto acids or amino donors showed little activity. The enzymes required an active sulphydryl group for maximum activity. Exogenous pyridoxal phosphate was not required, but hydroxylamine inhibited the reaction and added pyridoxal phosphate overcame this inhibition. Proline inhibited the reaction and may play a role in the fate of ornithine in pumpkin cotyledons.     

Characterization of an active-site peptide modified by glyoxylate and pyridoxal phosphate from spinach ribulosebisphosphate carboxylase/oxygenase

Activated ribulosebisphosphate carboxylase/oxygenase from spinach was treated with glyoxylate plus or minus the transition-state analog, carboxyarabinitol bisphosphate, or the inactive enzyme with pyridoxal phosphate plus or minus the substrate, ribulose bisphosphate. Covalently modified adducts with glyoxylate or pyridoxal phosphate were formed following reduction with sodium borohydride. The derivatized enzymes were carboxymethylated and digested with trypsin; the labeled peptides which were unique to the unprotected samples were purified by ion-exchange chromatography and gel filtration. Both glyoxylate and pyridoxal phosphate were associated with only one major peptide, which in each case was subjected to amino acid analysis and sequencing. The sequence was -Tyr-Gly-Arg-Pro-Leu-Leu-Gly-Cys(Cm)-Thr-Ile-Lys-Lys*-Pro-Lys-, with both reagents exhibiting specificity for the same lysine residue as indicated by the asterisk. This peptide is identical to that previously isolated from spinach carboxylase labeled with either of two different phosphorylated affinity reagents and homologous to one from Rhodospirillum rubrum carboxylase modified by pyridoxal phosphate. The species invariance of this lysine residue, number 175, and the substantial conservation of adjacent sequence support the probability for a functional role in catalysis of the lysyl epsilon-amino group.