Identification of coenzyme aldimine proton in 1H NMR spectra of pyridoxal 5'-phosphate dependent enzymes: aspartate aminotransferase isoenzymes

The pyridoxal form of the alpha subform of cytosolic aspartate aminotransferase (EC 2.6.1.1) is fully active and binds pyridoxal 5'-phosphate via an aldimine formation with Lys-258 whereas the gamma subform is virtually inactive and lacks the aldimine linkage. Comparison of 1H NMR spectra between the alpha and gamma subforms suggested that peak 1 of the alpha subform at 8.89 ppm contains a resonance assignable to the internal aldimine 4'-H. Reaction with a reagent that cleaves or modifies the internal aldimine bond [(amino-oxy)acetate, L-cysteinesulfinate, NH2OH, NaBH4, or NaCNBH3] caused the disappearance of a resonance line at 8.89 ppm that possessed a broad line width and corresponded in intensity to a single proton. These reagents were also used successfully for the identification of the aldimine 4'-H resonance in the mitochondrial isoenzyme. In contrast to the cytosolic isoenzyme whose resonance for the 4'-H did not show any detectable change in chemical shift with pH, the corresponding resonance in the mitochondrial isoenzyme exhibited pH-dependent chemical shift change (8.84 ppm at pH 5 and 8.67 ppm at pH 8) with a pK value of 6.3, reflecting the interisozymic difference in the microenvironment provided for the internal aldimine. Validity of the signal assignment was further shown by the two findings: the resonance assigned to the 4'-H emerged upon conversion of the pyridoxamine into the pyridoxal form, and the resonance appeared upon reconstitution of the apoenzyme with [4'-1H]pyridoxal phosphate but not with [4'-2H]pyridoxal phosphate.     

The active site of Sulfolobus solfataricus aspartate aminotransferase

Aspartate aminotransferase from the archaebacterium Sulfolobus solfataricus binds pyridoxal 5' phosphate, via an aldimine bond, with Lys-241. This residue has been identified by reducing the enzyme in the pyridoxal form with sodium cyanoboro[3H]hydride and sequencing the specifically labeled peptic peptides. The amino acid sequence centered around the coenzyme binding site is highly conserved between thermophilic aspartate aminotransferases and differs from that found in mesophilic isoenzymes. An alignment of aspartate aminotransferase from Sulfolobus solfataricus with mesophilic isoenzymes, attempted in spite of the low degree of similarity, was confirmed by the correspondence between pyridoxal 5' phosphate binding residues. Using this alignment it was possible to insert the archaebacterial aspartate aminotransferase into a subclass, subclass I, of pyridoxal 5' phosphate binding enzymes comprising mesophilic aspartate aminotransferases, tyrosine aminotransferases and histidinol phosphate aminotransferases. These enzymes share 12 invariant amino acids most of which interact with the coenzyme or with the substrates. Some enzymes of subclass I and in particular aspartate aminotransferase from Sulfolobus solfataricus, lack a positively charged residue, corresponding to Arg-292, which in pig cytosolic aspartate aminotransferase interacts with the distal carboxylate of the substrates (and determines the specificity towards dicarboxylic acids). It was confirmed that aspartate aminotransferase from Sulfolobus solfataricus does not possess any arginine residue exposed to chemical modifications responsible for the binding of omega-carboxylate of the substrates. Furthermore, it has been found that aspartate aminotransferase from Sulfolobus solfataricus is fairly active when alanine is used as substrate and that this activity is not affected by the presence of formate. The KM value of the thermophilic aspartate aminotransferase towards alanine is at least one order of magnitude lower than that of the mesophilic analogue enzymes.     

The enantiomeric error frequency of aspartate aminotransferase

The enantiomeric error frequency of aspartate aminotransferase (mitochondrial isoenzyme from chicken) was assessed by adding the enzyme in high concentration (0.89 mM) to a mixture of L-glutamate and 2-oxoglutarate (12 and 1.2 mM, respectively, at pH 7.5 and 25 degrees C). The substrates continuously undergo the transamination cycle under these conditions. Thereby, L-glutamate is progressively racemized, a 1:1 ratio of two enantiomers being reached within 240 h. The enantiomeric error frequency, i.e. the ratio of the rate of D-glutamate production and the rate of the transamination reaction with glutamate and 2-oxoglutarate as substrates, is 1.5 x 10(-7). D-Glutamate is also converted to a 1:1 racemic mixture. The racemizing activity of a mixture of free pyridoxal 5'-phosphate and pyridoxamine 5'-phosphate is about two orders of magnitude lower than that of aspartate aminotransferase. The error frequency of the enzyme in the case of the C4 substrate pair aspartate and oxalacetate is 3.4 x 10(-8), i.e. 4 times lower than that with the C5 substrate pair.     

Interaction of aspartate aminotransferase with amino acids

1. The capacity of various amino acids to convert the pyridoxal form of aspartate aminotransferase into the pyridoxamine form has been investigated. 2. Glutamate has the highest converting capacity; aspartate, α-aminopimelate, α-aminoadipate and other amino acids follow. 3. The converting capacity of the various amino acids assayed is connected with their structural features. 4. A possible role of amino acids as secondary substrates of aspartate aminotransferase is suggested.     

Reversible modification of amino groups in aspartate aminotransferase.

Amino groups in the pyridoxal phosphate, pyridoxamine phosphate, and apo forms of pig heart cytoplasmic aspartate aminotransferase (L-aspartate: 2-oxoglutarate aminotransferase, EC .2.6.1.1) have been reversibly modified with 2,4-pentanedione. The rate of modification has been measured spectrophotometrically by observing the formation of the enamine produced and this rate has been compared with the rate of loss of catalytic activity for all three forms of the enzyme. Of the 21 amino groups per 46 500 molecular weight, approx. 16 can be modified in the pyridoxal phosphate form with less than a 50% change in the catalytic activity of the enzyme. A slow inactivation occurs which is probably due to reaction of 2,4-pentanedione with the enzyme-bound pyridoxal phosphate. The pyridoxamine phosphate enzyme is completely inactivated by reaction with 2,4-pentanedione. The inactivation of the pyridoxamine phosphate enzyme is not inhibited by substrate analogs. A single lysine residue in the apoenzyme reacts approx. 100 times faster with 2,4-pentanedione than do other amino groups. This lysine is believed to be lysine-258, which forms a Schiff base with pyridoxal phosphate in the holoenzyme.     

Effect of vitamin B6 on the synthesis and degradation of aspartate aminotransferase in chicken embryo fibroblasts

The effect of pyridoxal depletion and supplementation on the intracellular level of mitochondrial and cytosolic aspartate aminotransferase in cultured chicken embryo fibroblasts was examined. No apoenzyme was detected in cells grown in the presence of pyridoxal, and the specific activity of total enzyme did not vary profoundly from primary to quaternary cultures. Under pyridoxal depletion, up to 40% apoenzyme was found in tertiary cultures which was entirely due to the mitochondrial isoenzyme. Cytosolic apoenzyme was never detected. Total aspartate aminotransferase relative to total protein was increased 2-fold in secondary cultures; only the mitochondrial isoenzyme contributed to the increased specific activity. The cytosolic isoenzyme decreased steadily and was below the limit of detection in quaternary cultures. The changes are attributed to an increased and decreased synthesis of mitochondrial and cytosolic isoenzyme, respectively. No induction of either isoenzyme was observed after incubating the cells with different hormones and substrates. In secondary cultures, no degradation of mitochondrial isoenzyme could be detected under pyridoxal deficiency or supplementation during 4.4 days, an interpassage duration. The cytosolic aspartate aminotransferase was degraded initially with an apparent half-life of approximately 0.9 day under both sets of conditions. The pronounced stability of mitochondrial aspartate aminotransferase, even though one-third of it was present as apoenzyme, excludes the formation of the apoform to be the rate-limiting step in its degradation. The present results show that pyridoxal affects the synthesis of mitochondrial and cytosolic aspartate aminotransferase, but differently.     

Spectroscopic characterization of true enzyme-substrate intermediates of aspartate aminotransferase trapped at subzero temperatures

Absorption and circular dichroism spectra of stable enzyme-substrate intermediates of aspartate aminotransferase were recorded at subzero temperatures (down to -65 degrees C) in the cryosolvent water/methanol. The intermediates were formed either between the pyridoxal form of the enzyme and its amino acid substrates, or between the pyridoxamine form and its oxo acid substrates. Kd values determined by spectroscopic titration were very close to the Km values reported for the different substrates. The adsorption complex of the pyridoxal form was probably obtained on addition of cysteine sulfinate. This complex is characterized by an increased absorption at 430 nm together with a positive Cotton effect, as also observed in the case of the complex with the competitive inhibitor maleate indicating protonation of the internal aldimine. Addition of the substrates aspartate or glutamate to the pyridoxal form seemed to result in the direct accumulation of the external aldimine which showed a slight decrease in both the absorbance and the Cotton effect at 360 nm. Additionally, a bathochromic shift of 5 nm was observed in the case of glutamate. At 430 nm, only a minor increase in absorbance, but not in circular dichroism, was observed with aspartate, and no changes were found with glutamate and the substrate analog 2-methylaspartate, indicating a deprotonated external aldimine. Presumably, the ketimine intermediate was obtained on addition of the oxo acids 2-oxoglutarate or oxalacetate to the pyridoxamine form. The intermediate showed a slight bathochromic shift (2 nm) of the absorption band and decreased circular dichroism. On formation of the ketimine, a tyrosine residue, probably active-site Tyr225, becomes partly ionized. The finding that the external aldimine can probably be accumulated in the conversion of the pyridoxal to the pyridoxamine form with the natural substrates would confirm the proton abstraction at C alpha to be the rate-limiting step in the tautomerization, although with cysteine sulfinate, the formation of the external aldimine might contribute to the rate limitation. Accumulation of the ketimine in the reverse direction would indicate that the proton abstraction at C4' is rate-limiting in this half-reaction. The results demonstrate the feasibility of further structural investigations of true enzyme-substrate intermediates.     

Mitochondrial and cytosolic aspartate aminotransferase from chicken: Activity toward aromatic amino acids

The mitochondrial and cytosolic isoenzymes of aspartate aminotransferase from chicken heart accept as substrates L-phenylalanine, L-tyrosine and L-tryptophan. The specific activities of the mitochondrial isoenzyme toward these substrates are between 0.1 to 0.5% of that toward aspartate and two orders of magnitude higher than that toward alanine. The specific activities of the cytosolic isoenzyme toward the aromatic substrates are 10 to 70% of the respective values of the mitochondrial isoenzyme. The activities of both isoenzymes toward aromatic amino acids are increased two- to threefold by 1 M formate. Larger increases by formate were observed for the alanine aminotransferase activity of both isoenzymes whereas their aspartate aminotransferase activity was inhibited by formate. The opposite effects of formate on the activities toward the aromatic and aliphatic monocarboxylic substrates on the one hand and the dicarboxylic substrate on the other are consonant with the notion of formate occupying the binding site of the distal carboxylate group of the substrate (Morino Y., Osman A.M., and Okamoto M. (1974) J. Biol. Chem. $\text{249}$, 6684–6692). Apparently, in the ternary complex of aspartate aminotransferase with formate and aromatic amino acids, the aromatic rings of the latter bind to a site which does not overlap with the binding site for the distal carboxylate.     

Recombinant rat guanidinoacetate methyltransferase: structure and function of the NH2-terminal region as deduced by limited proteolysis

Recombinant rat liver guanidinoacetate methyltransferase, a monomeric protein with Mr 26,000, is inactivated upon incubation with low concentrations of trypsin. Examination of the reaction products by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and high-performance liquid chromatography followed by amino acid analysis and sequencing of isolated peptides reveals that the inactivation is due to the cleavage of the NH2-terminal segment after Arg20. The cleaved peptide is not tightly associated with the rest of the protein. The rate of inactivation is not affected by the presence of either S-adenosylmethionine (AdoMet) or guanidinoacetate, but a substantial retardation of inactivation is observed when both substrates are present. The cleavage at Arg20 is also slowed by cross-linking Cys15 and Cys90 by a disulfide bond. An equilibrium binding study shows that guanidinoacetate methyltransferase in the free form binds AdoMet but not guanidinoacetate. The trypsin-modified enzyme, despite having no catalytic activity, can weakly bind AdoMet and guanidinoacetate in the presence of AdoMet. Chymotrypsin rapidly hydrolyzes the peptide bond after Trp19, and elastase cleaves the bond after Ala24, leading in both cases to loss of activity. The results obtained in this study suggest that the portion of the methyltransferase around residues 19-24 is highly exposed to the solvent and flexible. The results also indicate that the NH2-terminal region is not directly involved in substrate binding but plays a role in catalysis.     

Inactivation of aspartate aminotransferase during transamination with chloropyruvate. Evidence against modification of Cys390 in cytosolic isoenzyme.

Both the cytosolic and mitochondrial isoenzyme of aspartate aminotransferase from pig heart were inactivated during transamination with chloropyruvate. Inactivation occurred with L-alanine as the amino group donor in the presence of potassium formate. When L-glutamate or L-aspartate was employed as the amino group donor in the transamination reaction with chloropyruvate, no inactivation occurred. This is in contrast to the case of inactivation by bromopyruvate (Okamoto, M. &; Morino, Y. (1973) J. Biol. Chem. $\text{248}$, 82–90) where these natural dicarboxylic amino acid substrates were effective in the transamination reaction leading to syncatalytic inactivation (Birchmeier, W. &; Christen, P. (1974) J. Biol. Chem. $\text{249}$, 6311–6315). The Cys₃₉₀ in the cytosolic isoenzyme which was modified in the syncatalytic inactivation was not modified under the present condition for inactivation with either chloropyruvate or bromopyruvate.     

Some kinetic and other properties of the isoenzymes of aspartate aminotransferase isolated from sheep liver.

A method for the purification of mitochondrial isoenzyme of sheep liver aspartate aminotransferase (EC 2.6.1.1) is described. The final preparation is homogeneous by ultracentrifuge analyses and polyacrylamide-gel electrophoresis and has a high specific activity (182 units/mg). The molecular weight determined by sedimentation equilibrium is 87,100 +/- 680. The amino acid composition is presented; it is similar to that of other mitochondrial isoenzymes, but with a higher content of tyrosine and threonine. Subforms have been detected. On isoelectric focusing a broad band was obtained, with pI 9.14. The properties of the mitochondrial aspartate aminotransferase are compared with those of the cytoplasmic isoenzyme. The Km for L-aspartate and 2-oxoglutarate for the cytoplasmic enzyme were 2.96 +/- 0.20 mM and 0.093 +/- 0.010 mM respectively; the corresponding values for the mitochondrial form were 0.40 +/- 0.12 mM and 0.98 +/- 0.14 mM. Cytoplasmic aspartate aminotransferase showed substrate inhibition by concentrations of 2-oxoglutarate above 0.25 mM in the presence of aspartate up to 2mM. The mitochondrial isoenzyme was not inhibited in this way. Pi at pH 7.4 inhibited cytoplasmic holoenzyme activity by up to about 60% and mitochondrial holoenzyme activity up to 40%. The apparent dissociation constants for pyridoxal 5'-phosphate were 0.23 micrometer (cytoplasmic) and 0.062 micrometer (mitochondrial) and for pyridoxamine 5'-phosphate they were 70 micrometer (cytoplasmic) and 40 micrometer (mitochondrial). Pi competitively inhibited coenzyme binding to the apoenzymes; the inhibition constants at 37 degree C were 32 micrometer for the cytoplasmic isoenzyme and 19.5 micrometer for the mitochondrial form.     

The substrate activation process in the catalytic reaction of Escherichia coli aromatic amino acid aminotransferase

Aromatic amino acid aminotransferase is active toward both aromatic and dicarboxylic amino acids, and the mechanism for this dual substrate recognition has been an issue in the enzymology of this enzyme. Here we show that, in the reactions with aromatic and dicarboxylic ligands, the pK(a) of the Schiff base formed between the coenzyme pyridoxal 5'-phosphate and Lys258 or the substrate increases successively from 6.6 in the unliganded enzyme to approximately 8.8 in the Michaelis complex and to >10.5 in the external Schiff base complex. Mutations of Arg292 and Arg386 to Leu, which mimic neutralization of the positive charges of the two arginine residues by the ligand carboxylate groups, increased the Schiff base pK(a) by 0.1 and 0.7 unit, respectively. In contrast to these moderate effects of the Arg mutations, the cleavage of the Lys258 side chain of the Schiff base, which was brought about by preparing a mutant enzyme in which Lys258 was changed to Ala and the Schiff base was reconstituted with methylamine, produced the Schiff base pK(a) value of 10.2, that being 3.6 units higher than that of the wild-type enzyme. The observation indicates that the Schiff base pK(a) in the enzyme is lowered by the torsion around the C4-C4' axis of the Schiff base and suggests that the pK(a) is mainly controlled by changing the torsion angle during the course of catalysis. This mechanism, first observed for the reaction of aspartate aminotransferase with aspartate [Hayashi, H., Mizuguchi, H., and Kagamiyama, H. (1998) Biochemistry 37, 15076-15085], does not require the electrostatic contribution from the omega-carboxylate group of the substrate, and can explain why in aromatic amino acid aminotransferase the aromatic substrates can increase the Schiff base pK(a) during catalysis to the same extent as the dicarboxylic substrates. This is the first example in which the torsion pK(a) coupling of the pyridoxal 5'-phosphate Schiff base has been demonstrated in pyridoxal enzymes other than aspartate aminotransferase, and suggests the generality of the mechanism in the catalysis of aminotransferases related to aspartate aminotransferase.     

The sequences of the coenzyme-binding peptide in the cytoplasmic and the mitochondrial aspartate aminotransferases from sheep liver.

The sequences of the coenzyme-binding peptide of both cytoplasmic and mitochondrial aspartate aminotransferases from sheep liver were determined. The holoenzymes were treated with NaBH4 and digested with chymotrypsin; peptides containing bound pyridoxal phosphate were then isolated. One phosphopyridoxyl peptide was obtained from sheep liver cytoplasmic aspartate aminotransferase. Its sequence was Ser-Ne-(phosphopyridoxyl)-Lys-Asn-Phe. This sequence is identical with that reported for the homologous peptide from pig heart cytoplasmic aspartate aminotransferase. Two phosphopyridoxyl peptides with different RF values were isolated from the sheep liver mitochondrial isoenzyme. They had the same N-terminal amino acid and similar amino acid composition. The mitochondrial phosphopyridoxyl peptide of highest yield and purity had the sequence Ala-Ne-(phosphopyridoxyl)-Lys-Asx-Met-Gly-Leu-Tyr. The sequence of the first four amino acids is identical with that already reported for the phosphopyridoxyl tetrapeptide from the pig heart mitochondrial isoenzyme. The heptapeptide found for the sheep liver mitochondrial isoenzyme closely resembles the corresponding sequence taken from the primary structure of the pig heart cytoplasmic aspartate aminotransferase.     

Pre-steady-state kinetics of Escherichia coli aspartate aminotransferase catalyzed reactions and thermodynamic aspects of its substrate specificity

The four half-transamination reactions [the pyridoxal form of Escherichia coli aspartate aminotransferase (AspAT) with aspartate or glutamate and the pyridoxamine form of the enzyme with oxalacetate or 2-oxoglutarate] were followed in a stopped-flow spectrometer by monitoring the absorbance change at either 333 or 358 nm. The reaction progress curves in all cases gave fits to a monophasic exponential process. Kinetic analyses of these reactions showed that each half-reaction is composed of the following three processes: (1) the rapid binding of an amino acid substrate to the pyridoxal form of the enzyme; (2) the rapid binding of the corresponding keto acid to the pyridoxamine form of the enzyme; (3) the rate-determining interconversion between the two complexes. This mechanism was supported by the findings that the equilibrium constants for half- and overall-transamination reactions and the steady-state kinetic constants (Km and kcat) agreed well with the predicted values on the basis of the above mechanism using pre-steady-state kinetic parameters. The significant primary kinetic isotope effect observed in the reaction with deuterated amino acid suggests that the withdrawal of the alpha-proton of the substrates is rate determining. The pyridoxal form of E. coli AspAT reacted with a variety of amino acids as substrates. The Gibbs free energy difference between the transition state and the unbound state (unbound enzyme plus free substrate), as calculated from the pre-steady-state kinetic parameters, showed a linear relationship with the accessible surface area of amino acid substrate bearing an uncharged side chain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Microbial oxidation of amines. Spectral and kinetic properties of the primary amine dehydrogenase of Pseudomonas AM 1

1. An improved procedure is reported for purification of the amine dehydrogenase from methylamine-grown Pseudomonas AM1 which yielded a product homogeneous by sedimentation and disc-electrophoretic analysis, with molecular weight of 133000. 2. The purified enzyme had absorption maxima at 280 and 430nm. On aging, a third peak appeared at 325nm, and the 430nm peak decreased in intensity. This spectrum was independent of pH. 3. Addition of 2.5mm-semicarbazide, phenylhydrazine, hydrazine or hydroxylamine produced modified spectra with maxima respectively at 400, 440, 395 and 425nm. 4. Aerobic addition of methylamine resulted in a bleaching of the 430nm peak and the appearance of a new one at 325nm. This spectral change was retained after removal of the methylamine by dialysis. The original spectrum could be restored on addition of phenazine methosulphate. 5. Addition of borohydride partially inactivated the enzyme and produced spectral changes similar to those observed with methylamine. Pre-treatment with methylamine prevented the inactivation by borohydride. The degree of inactivation could be increased by alternate phenazine methosulphate and borohydride treatments. 6. The addition of methylamine or borohydride each caused shifts in the fluorescence emission maximum from 348 to 380nm. 7. Lineweaver-Burk plots of reciprocal activity against reciprocal concentration of either of the substrates n-butylamine or phenazine methosulphate were consistent with a mechanism that involves interconversion of two free forms of the enzyme by the two substrates. 8. The enzyme, although spectrally modified, was not inactivated by dialysis against diethyldithiocarbamate, and contained about 0.27 g-atom of copper/mol, with small traces of cobalt, iron and zinc. 9. Conventional methods of resolution did not release the prosthetic group. Heat denaturation after treatment of the enzyme with methylamine liberated a yellow chromophore which did not reactivate resolved aspartate aminotransferase, and whose spectral, electrophoretic and fluorescence properties did not agree with any recognizable pyridoxal derivatives. 10. Despite the inconclusive results with the isolated chromophore, the observations on the enzyme suggest that it may contain a pyridoxal derivative bound as a Schiff's base which is converted into the pyridoxamine form on aerobic treatment with methylamine and reconverted into the pyridoxal form with phenazine methosulphate. 11. The copper detected is probably not involved in the enzyme mechanism, since most copper-chelating agents are not inhibitory, and since the enzyme does not react with oxygen.     

Syncatalytic sulfhydryl group modification in mitochondrial aspartate aminotransferase from chicken and pig heart

One sulfhydryl group of the mitochondrial isoenzyme of aspartate aminotransferase from both chicken and pig heart exhibits syncatalytic reactivity changes similar to those found previously in the cytosolic isoenzyme from pig heart (Birchmeier, W., Wilson, K.J., and Christen, P. (1973) J. Biol. Chem. $\text{248}$, 1751–1759). The reactivity of the only titratable sulfhydryl group toward 5,5′-dithiobis-(2-nitrobenzoate) is at a minimum in the free pyridoxal and pyridoxamine form of the enzyme and is increased by approximately one order of magnitude when covalent enzyme-substrate intermediates are formed. The modification of the sulfhydryl group does not affect enzymatic activity. This finding supports the earlier conclusion that the syncatalytic reactivity changes are not due to a direct participation of this group in the active site but rather to conformational adaptations of the enzyme-coenzyme-substrate compound occurring in the catalytic mechanism of aspartate aminotransferases.     

Chemical structure of the active site of pig heart mitochondrial aspartate aminotransferase labeled with beta-chloro-l-alanine

Formate-induced inactivation of pig heart mitochondrial aspartate aminotransferase by beta-chloro-L-alanine resulted in the modification of the epsilon-amino group of the lysyl residue which is involved in the formation of an aldimine bond with 4-formyl group of the coenzyme, pyridoxal 5'-phosphate. The tryptic peptide isolated from the labeled site of the enzyme was composed of 25 residues and exhibited positive circular dichroism at 325 and 254 nm where the pyridoxyl chromophore of the labeled site peptide absorbs, while the phosphopyridoxyl peptide isolated from the boro-hydride-reduced enzyme did not show any ellipticity in this spectral region. Its comparison with the analogous tryptic peptide from the labeled site of the cytosolic isoenzyme revealed a high degree of homology in their primary structures as well as in spectral properties. Structural analysis of the labeled site peptide and mechanistic consideration of the labeling process indicated that with both isoenzymes the phosphopyridoxyl group is covalently bound to the alpha amino group of the alanyl moiety derived from beta-chloro-L-alanine, the beta carbon of which is covalently linked to the epsilon-amino group of the lysyl residue.     

Intracellular predominance of the pyridoxal 5'-phosphate form of aspartate aminotransferase in Escherichia coli B and reversible transformation of this form by extracellular substances

The intracellular proportion of the pyridoxal 5'-phosphate form of aspartate aminotransferase to the total enzyme in E. coli B cells was determined by a newly devised method, dependent on selective inactivation of the intracellular pyridoxal 5'-phosphate form of the enzyme by extracellularly added sodium borohydride. A large portion (80-99%) of the intracellular aspartate aminotransferase was in pyridoxal 5'-phosphate form in both natural and synthetic medium-grown bacterial cells. The intracellular predominancy of pyridoxal 5'-phosphate did not vary during the growth of bacteria and during incubation of bacterial cells in various kinds of buffers with different pH values. In contrast, the saturation levels generally used to describe in vivo the proportions of the apo and holo vitamin B6-dependent enzymes did not reflect the intracellular amount of the pyridoxal 5'-phosphate (holo) form of aspartate aminotransferase probably because the intracellular pyridoxal 5'-phosphate form was changed to an apo form by the disruption of bacterial cells for preparing crude extract. Various extracellularly-added vitamin B6 antagonists decreased the intracellular amount of pyridoxal 5'-phosphate without decrease in the total intracellular activity of the enzyme. The modified forms were stable in E. coli B cells and reversed into pyridoxal 5'-phosphate form by incubation of the antagonist-treated cells in the buffer containing pyridoxal. The present results showed that the sodium borohydride reduction method can be used for further analysis of the in vivo interaction of pyridoxal 5'-phosphate and apoaspartate aminotransferase. The fact that about 50% of the intracellular pyridoxal 5'-phosphate form was changed to a modified form without impairment of cell growth in the presence of 4-deoxypyridoxine, and that about 50% of intracellular modified aspartate aminotransferase was reversed to pyridoxal 5'-phosphate by the removal of antagonist followed by incubation suggested that there exists characteristically 2 different fractions of pyridoxal 5'-phosphate forms of aspartate aminotransferase in E. coli cells.     

Similarity between pyridoxal/pyridoxamine phosphate-dependent enzymes involved in dideoxy and deoxyaminosugar biosynthesis and other pyridoxal phosphate enzymes.

A multiple sequence alignment among aspartate aminotransferase, dialkylglycine decarboxylase, and serine hydroxymethyltransferase (DAS) was used for profile databank search. The DAS profile could detect similarities to other pyridoxal or pyridoxamine phosphate-dependent enzymes, like several gene products involved in dideoxysugar and deoxyaminosugar synthesis. The alignment among DAS and such gene products shows the conservation of aspartate 222 and lysine 258, which, in aspartate aminotransferase, interacts with the N1 of the coenzyme pyridine ring and forms the internal Schiff base, respectively. The lysine is replaced by histidine in the pyridoxamine phosphate-dependent gene products. The alignment indicates also that the region encompassing the coenzyme binding site is the most conserved.     

The precursor of mitochondrial aspartate aminotransferase is translocated into mitochondria as apoprotein

Mitochondrial aspartate aminotransferase is synthesized on free polysomes as a higher molecular weight precursor (Sonderegger, P., Jaussi, R., Christen, P., and Gehring, H. (1982) J. Biol. Chem. 257, 3339-3345). The present study examines whether the coenzyme pyridoxal phosphate or pyridoxamine phosphate is required for the uptake of the precursor into mitochondria. Chicken embryo fibroblasts were cultured in medium prepared with and without pyridoxal. In cells grown in the presence of pyridoxal only holoform of aspartate aminotransferase and no apoenzyme was detected. Cells cultured under pyridoxal deficiency contained about 30% of apoenzyme in secondary cultures. All of this apoform was identified as mitochondrial isoenzyme. In order to differentiate whether this apoenzyme corresponded to newly synthesized protein or originated from pre-existing holoenzyme, double isotope-labeling experiments were performed. Secondary cultures of chicken embryo fibroblasts grown under pyridoxal depletion were labeled with [3H]methionine, and then pulsed with [35S]methionine. In another series of experiments, the 3H-labeled cells were pulsed with [35S]methionine in the presence of the protonophore carbonyl cyanide m-chlorophenylhydrazone in order to accumulate the precursor. Subsequently, the accumulated precursor was chased into the mitochondria by addition of the carbonyl cyanide m-chlorophenylhydrazone antagonist cysteamine. The holo- and apoenzyme from the ultrasonic extract of the double-labeled cells were separated by affinity chromatography on a phosphopyridoxyl-AH-Sepharose column, immunoprecipitated, and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorography. Under both experimental conditions, the 3H/35S ratio of the apoenzyme was less than half of that of the holoenzyme. Therefore, the apoenzyme and not the holoenzyme is the first product of the precursor in the mitochondria. Apparently, the precursor of mitochondrial aspartate aminotransferase is transported into mitochondria as apoprotein and is processed there independently of the coenzyme.