Quantitative description of absorption spectra of a pyridoxal phosphate-dependent enzyme using lognormal distribution curves

Ultraviolet-visible absorption spectra of cytosolic aspartate aminotransferase of pig hearts have been analyzed by resolution with lognormal distribution curves. These have been compared with spectra of reference Schiff bases of pyridoxal 5'-phosphate. Spectra of the free enzyme in two different states of protonation and of complexes with monoanions, dicarboxylates, the substrates L-glutamate, L-aspartate, and L-erythro-3-hydroxyaspartate, and the quasi-substrate 2-methylaspartate have been analyzed. Relative amounts of three tautomeric species have been estimated, as have amounts of various enzyme-substrate intermediates. Bandshape parameters which can be used as a guide to analysis of spectra of other pyridoxal phosphate-dependent enzymes are tabulated. Some formation constants and pKa values, which were evaluated at the same time as the spectra of the complexes, are also reported.     

Pyridoxal 5'-phosphate and analogs as probes of coenzyme-protein interaction in Baccillus alvei tryptophanase.

Trytophanase from Bacillus alvei was resolved from its coenzyme, pyridoxal phosphate, by treatment with cysteine followed by column chromatography. Spectrophotometric titration of apoenzyme with pyridoxal-P showed 1 mol of pyridoxal-P bound per 52,000 g of enzyme. Kinetic analysis of coenzyme binding showed hyperbolic activation curves with a Km of 1.6 muM. Pyridoxal-P was used as a natural active site probe in spectrophotometric studies to distinguish differences in the active center of holotryptophanase and reconstituted enzyme that were not apparent by other techniques. The pKa for holotryptophanase is 7.9 while the pKa for reconstituted apoenzyme is 8.4. Apotryptophanase binds 2-nor, 2'-methyl, 2'-hydroxy, 6-methyl, and N-oxide pyridoxal-P to form analog enzymes distinguishable on the basis of absorption spectra and relative activity in catalyzing both the alpha, beta-elimination and beta-replacement reactions of tryptophanase. Apoenzyme also binds pyridoxal but pyridoxal analog enzyme is not active.     

Conformational properties of pig-heart cytoplasmic aspartate aminotransferase. Circular-dichroism and absorption-spectroscopic study of dicarboxylate binding.

1. The interaction between aspartate aminotransferase and dicarboxylates of various chain lengths and geometries has been studied from pH 6.5 TO 8.5 by circular dichroism (CD) and absorption spectroscopy. Liganding causes protonation of the pyridoxal phosphate-enzyme Schiff's base complex; the consequent changes in optical properties deltaAlambda, deltaCDlambda at the coenzyme maxima (lambda = 363 or 430 nm) are analysed for binding constants and the degree of perturbation of the coenzyme protonic dissociation constant, pKa. 2. Aliphate dicarboxylates follow linear binding functions for all optical parameters; in contrast, m and p-phthalates follow non-linear binding functions for both deltaAlambda and deltaCDlambda, implying that successive phthalate ligands bind with decreasing affinity. The ratio detlaCDlambda is effectively constant for a given ligand and the characteristic values for aromatic ligands indicate a changed environment for the coenzyme. 3. Inspection of the non-linear process for phthalates suggests that initially, binding occurs with high affinity, but with characteristically small effects on pKa. It is inferred that alipathic and aromatic dicarboxylates bind at different subsites in the active site region, perturbing the coenzyme pKa by an indirect protein-mediated mechanism. 4. Non-linearity of binding could derive from multiple binding to an individual subunit. Alternatively, different single sites may exist on adjacent subunits of the dimer, implying non-equivalence between otherwise identical subunits, expressed in properties involving groups close to the active site.     

Tyr225 in aspartate aminotransferase: contribution of the hydrogen bond between Tyr225 and coenzyme to the catalytic reaction

Tyr225 in the active site of Escherichia coli aspartate aminotransferase (AspAT) was replaced by phenylalanine or arginine by site-directed mutagenesis. X-ray crystallographic analysis of Y225F AspAT showed that the benzene ring of Phe225 was situated at the same position as the phenol ring of Tyr225 in wild-type AspAT. The mutations resulted in a great decrease in the rate of the transamination reaction, suggesting that Tyr225 is important for efficient catalysis. The kinetic analysis of half-transamination reactions of Y225F AspAT with four substrates (aspartate, glutamate, oxalacetate, and 2-oxoglutarate) and some analogues (2-methylaspartate, succinate, and glutarate) revealed a considerable increase in the affinities for all these compounds. In contrast, affinity for the amino acid substrates was decreased by mutation to arginine, but affinities for the keto acid substrates and the two dicarboxylates (succinate and glutarate) were increased. The electrostatic interaction between O(3') of the coenzyme [pyridoxal 5'-phosphate (PLP)] and the residue at position 225 affected the pKa value of the Schiff base, which is formed between the epsilon-amino group of Lys258 and the aldehyde group of PLP; based on the spectrophotometric titration the pKa values were determined to be 6.8 for wild-type AspAT, 8.5 for Y225F AspAT, and 6.1 for Y225R AspAT in the absence of substrate. The absorption spectra of the three AspATs were almost identical in the acidic pH region, but the spectrum of Y225F AspAT differed from that of wild-type or Y225R AspAT in the alkaline pH region.(ABSTRACT TRUNCATED AT 250 WORDS)     

Properties of 4-ethenyl and 4-ethynyl analogs of pyridoxal phosphate and their reactions with the apo form of asparatate aminotransferase.

The binding to apoaspartate aminotransferase of analogs of pyridoxal phosphate bearing vinyl, cis- and trans-methylvinyl, and ethynyl groups in place of the fomyl group of the coenzyme has been studied. Details of synthesis of the ethynyl compound are given. The absorption spectra of all of the compounds have been analyzed and pKa values have been determined. The positions of the absorption bands can be related to those of pyridoxine but with bathochromic shifts induced by the ethenyl and ethynyl groups. However, this shift is almost completely lacking for the cis-methylvinyl compound suggesting nonplanarity of the molecule. Binding of the analogs to the apoenzyme is accompanied by a strong bathochromic shift which, from a study of solvent effects on the free analogs, appears to indicate a hydrophobic environment on the enzyme. Nevertheless, the analogs are bound as dipolar ions exclusively. Binding is accompanied by a distinct perturbation of the protein spectrum in the aromatic region. An effect on the spectrum of 1 or more tryptophan residues is indicated. Bands of the bound analogs exhibit positive circular dichroism except for that of the 4-vinyl analog. The 4-ethynyl analog reacts in a more complex way, giving at least two successive products in addition to the initial complex. The final product is reducible by sodium borohydride, is released from the enzyme by boiling, and appears to have the properties of a Schiff base. We postulate that the addition of an amino group of the enzyme to the ethynyl group is followed by tautomeric rearrangement to a Schiff base in which the ring is in a p-quinonoid structure.     

13C NMR spectroscopy of labeled pyridoxal 5'-phosphate. Model studies, D-serine dehydratase, and L-glutamate decarboxylase.

Pyridoxal 5'-phosphate labeled to the extent of 90% with 13C in the 4' (aldehyde) and 5' (methylene) positions has been synthesized. 13C NMR spectra of this material and of natural abundance pyridoxal 5'-phosphate are reported, as well as 13C NMR spectra of the Schiff base formed by reaction of pyridoxal 5'-phosphate with n-butylamine, the secondary amine formed by reduction of this Schiff base, the thiazolidine formed by reaction of pyridoxal 5'-phosphate with cysteine, the hexahydropyrimidine formed by reaction of pyridoxal 5'-phosphate with 1,3-diaminobutane, and pyridoxamine 5'-phosphate. The range of chemical shifts for carbon 4' in these compounds is more than 100 ppm, and thus this chemical shift is expected to be a sensitive indicator of structure in enzyme-bound pyridoxal 5'-phosphate. The chemical shift of carbon 5', on the other hand, is insensitive to these structure changes. 13C NMR spectra have been obtained at pH 7.8 and 9.4 for D-serine dehydratase (Mr = 46,000) containing natural abundance pyridoxal 5'-phosphate and containing 13C-enriched pyridoxal 5'-phosphate. The enriched material contains two new resonances not present in the natural abundance material, one at 167.7 ppm with a linewidth of approximately 24 Hz, attributed to carbon 4' of the Schiff base in the bound coenzyme, and one at 62.7 Hz with a linewidth of approximately 48 Hz attributed to carbon 5' of the bound Schiff base. A large number of resonances due to individual amino acids are assigned. The NMR spectrum changes only slightly when the pH is raised to 9.4. The widths of the two enriched coenzyme resonances indicate that the coenzyme is rather rigidly bound to the enzyme but probably has limited motional freedom relative to the protein. 13C NMR spectra have been obtained for L-glutamate decarboxylase containing natural abundance pyridoxal 5'-phosphate and 13C-enriched pyridoxal 5'-phosphate. Under conditions where the two enriched 13C resonances are clearly visible in D-serine dehydratase, no resonances are visible in enriched L-glutamate decarboxylase, presumably because the coenzyme is rigidly bound to the protein and the 300,000 molecular weight of this enzyme produces very short relaxation times for the bound coenzyme and thus very broad lines.     

Complexes of aspartate aminotransferase with hydroxylamine derivatives: spectral studies in solution and in the crystalline state

Hydroxylamine and its derivatives of general formula H2NOR react with aldehydes and aldimines to produce oximes. If R corresponds to the side chain of a natural amino acid, such compounds can be thought of as analogs of the corresponding amino acids, lacking the alpha-carboxylate group. Oximes formed between such compounds and pyridoxal phosphate in the active site of aspartate amino-transferase mimic external aldimine intermediates that occur during catalysis by this enzyme. The properties of oxime derivatives of mitochondrial aspartate aminotransferase with hydroxylamine and 6 compounds H2NOR were studied by absorption spectroscopy and circular dichroism in solution and by linear dichroism in crystals. Stable oximes, absorbing at lambda max congruent to 380 nm and exhibiting a negative Cotton effect, were obtained with the carboxylate-containing compounds. The oximes formed with carboxylate-free compounds showed somewhat different properties and stability. With H-Tyr a stable complex absorbing at lambda max congruent to 370 nm rather than at 380 nm, was obtained, H-Ala and H-Phe produced unstable oximes with the initial absorption band at lambda max congruent to 380 nm that was gradually replaced by a band at lambda max congruent to 340 nm. The species absorbing at 340 nm were shown to be coenzyme-inhibitor complexes which were gradually released from the enzyme. A similar 330-340 nm absorption band was observed upon reaction of the free coenzyme with all hydroxylamine inhibitors at neutral pH-values. The results of the circular dichroism experiments in solution and the linear dichroism studies in microcrystals of mAspAT indicate that the coenzyme conformation in these inhibitor/enzyme complexes is similar to that occurring in an external aldimine analogue, the 2-MeAsp/mAspAT complex. Co-crystallizations of the enzyme with the H2NOR compounds were also carried out. Triclinic crystals were obtained in all cases, suggesting that the "closed" structure cannot be stabilized by a single carboxylate group.     

Circular dichroism studies of the coenzyme environment in the active sites of mutant forms of the beta-subunit in the tryptophan synthase alpha 2 beta 2 complex.

The circular dichroism has been used to evaluate the effect of mutation on the environment of the pyridoxal phosphate coenzyme in the active site of the beta-subunit in the tryptophan synthase alpha 2 beta 2 complex from Salmonella typhimurium. Seven mutant forms of the alpha 2 beta 2-complex with single amino acid replacements at residues 87, 109, 188, 306, and 350 of the beta-subunit have been prepared by site-directed mutagenesis, purified to homogeneity, and characterized by absorption and circular dichroism spectroscopy. Since the wild type and mutant alpha 2 beta 2 complexes all exhibit positive circular dichroism in the coenzyme absorption band, pyridoxal phosphate must bind asymmetrically in the active site of these enzymes. However, the coenzyme may have an altered orientation or active site environment in five of the mutant enzymes that display less intense ellipticity bands. The mutant enzyme in which lysine 87 is replaced by threonine has very weak ellipticity at 400 nm. Since lysine 87 forms a Schiff base with pyridoxal phosphate in the wild type enzyme, our results demonstrate the importance of the Schiff base linkage for rigid or asymmetric binding. Although the mutant enzymes display spectra in the presence of L-serine that differ from that of the wild type enzyme, addition of alpha-glycerol 3-phosphate converts the spectra of two of the mutant enzymes to that of the wild type enzyme. We conclude that this alpha-subunit ligand may produce a conformational change in the alpha-subunit that is transmitted to the mutant beta-subunits and partially corrects conformational alterations in the mutant enzymes.     

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.     

Interaction of phosphorylase B with SH-reagents and properties of the modified enzyme

The interaction of phosphorylase B with the SH-reagents, i.e. 2-chloromercuri-4-nitrophenol and ethylmercurichloride was studied. It was shown that phosphorylase B inhibition obeys the pseudo-first-order kinetics, the inactivation rate constants being equal to 11 M-1 s-1 and 17,5 M-1 s-1, respectively. Data from the SH-group titration with 2-chloromercuri-4-nitrophenol and p-chloromercuri benzoate suggest that the number of modified cysteine residues and the amount of bound 2-chloromercuri-4-nitrophenol in the phosphorylase B dimer is equal to 2. In the modified phosphorylase B the absorption maximum of pyridoxal phosphate is decreased at 330 nm and is increased at 410 nm. The binding of 2-chloromercuri-4-nitrophenol is accompanied by quenching of the protein and coenzyme fluorescence. Upon interaction with ethylmercurichloride only the pyridoxalphosphate fluorescence is quenched. The increase of the spin label mobility in the modified enzyme calculated from the EPR spectra of the spin-labelled preparations is indicative of the changes in the protein conformation coupled with the blocking of one SH-group in the enzyme monomer. The rate of enzyme inactivation under effects of the SH-reagents is a function of pH and is considerably increased within the pH range of 5.7-6.7. The pH-optimum of activity of partly modified enzyme remains practically unchanged; however, at the pH shift towards the acidic values the activity is drastically decreased as compared to that of the native enzyme. The data obtained suggest that the enzyme inactivation is due to modification of one SH-group in the phosphorylase B monomer vicinal to the pyridoxal phosphate binding site and probably involved in the enzymatic reaction.     

Use of 6-fluoroderivatives of pyridoxal and pyridoxal phosphate in the study of the coenzyme function in glycogen phosphorylase

6-Fluoropyridoxal phosphate (6-FPLP) has been synthesized. Its properties were studied, and it was used, along with 6-fluoropyridoxal (6-FPAL), to reconstitute apophosphorylase b. Kinetic studies of the resulting enzymes showed that phosphorylases reconstituted with 6-FPLP and 6-FPAL have characteristics similar to those of native and pyridoxal enzymes, respectively, except that the former two enzymes have lower Vmax values. 19F NMR and UV spectra of 6-FPLP phosphorylase showed that the coenzyme forms a neutral enolimine Schiff base. Because the UV and fluorescence spectra of 6-FPLP phosphorylase are comparable to those obtained with native phosphorylase, it further confirms the postulate that pyridoxal phosphate forms a neutral enolimine Schiff base in phosphorylase. The results suggest that the 3-OH group is protonated and the pyridine nitrogen unprotonated in both 6-FPLP phosphorylase and native enzyme. 19F NMR study of 6-FPLP- and 6-FPAL-reconstituted phosphorylases in the inactive and active states indicates that the protein structure near the coenzyme binding site undergoes certain changes when these enzymes are activated by the substrates and AMP. The comparison of the properties of 6-FPLP-reconstituted and native phosphorylases implies that the ring nitrogen of the coenzyme PLP in phosphorylase may interact with the protein during catalysis, and this interaction is important for efficient catalysis by phosphorylase.     

Phosphorus-31 nuclear magnetic resonance study of D-serine dehydratase: pryridoxal phosphate binding site.

The pyridoxal phosphate dependent enzyme D-serine dehydratase has been investigated using 31P nuclear magnetic resonance (NMR) at 72.86 MHz. In the native enzyme, the pyridoxal phosphate 31P chemical shift is pH dependent with pKa = 6.4, indicating exposure of the phosphate group to solvent. Binding of the competitive inhibitor isoserine results in the formation of the isoserine-pyridoxal phosphate complex. This transaldimination complex is fixed to the enzyme via the phosphate group of the cofactor as the dianion, independent of pH. At pH 6.6 the dissociation constant KD for isoserine determined by NMR is 0.43 mM. Reconstitution of the apoenzyme with pyridoxal phosphate monomethyl ester produces an inactive enzyme. NMR and fluorescence measurements show that this enzyme does not form the transaldimination complex, indicating that the fixation of the dianionic phosphate (probably via a salt bridge with an arginine residue) observed in the native enzyme is required for the transaldimination step of the catalytic mechanism.     

Catalytic function of a tyrosyl residue in tryptophanase

Tryptophanase has an essential tyrosyl residue/active site which can be modified by tetranitromethane. Pyridoxal 5'-phosphate can prevent this modification efficiently, whereas pyridoxal 5'-phosphate N-oxide cannot, indicating that the free pyridinium N is required for the interaction of the coenzyme with the tyrosyl residue, probably via a hydrogen bond. The weakened binding of the coenzyme to the modified enzyme was confirmed on gel filtration, the modified enzyme being dissociated from the coenzyme seven-fold faster than the native enzyme. Furthermore, absorption spectral analyses demonstrated that the modified enzyme can catalyze the transaldimination step, but fails to abstract the alpha-H of substrates. The tyrosyl residue, therefore, not only participates in coenzyme binding, but also contributes to alpha-H labilization.     

Study of the reorientation of coenzyme in active sites of aspartate-aminotransferase isoenzymes using linear dichroism method

Cytosolic and mitochondrial pig aspartate aminotransferases (cAAT and mAAT) and chicken cAAT were oriented in a compressed slab of polyacrylamide gel. Linear dichroism (LD) spectra of the pyridoxal and pyridoxamine forms of AATs and of complexes of the pyridoxal form with substrate analogues have been recorded. The tilt angles of the coenzyme at the intermediary steps of the transamination reaction have been calculated on the basis of reduced LD values (delta A/A), atomic coordinates of the coenzyme and directions of the transition dipole moments in the coenzyme ring. It was assumed that rotation of the coenzyme ring occurs around the C2-C5 axis in all cases except the enzyme complex with glutarate: in the latter case the direction N1-C4 was assumed to be a rotation axis. It has been found that formation of the enzyme complex with glutarate and protonation of the internal aldimine induce dissimilar reorientations of the coenzyme. As a result of protonation, the coenzyme tilts by 27 degrees in cAAT and 13 degrees in mAAT. Formation of the external aldimine with 2-methylaspartate is accompanied by tilting of the coenzyme ring by 44 degrees in cAAT and 39 degrees in mAAT. For the quinonoid complex with erythro-3-hydroxyaspartate, the tilt angles were found to be 63 degrees in cAAT and 53 degrees in mAAT. It was inferred that the basic features of the active site dynamics are similar in three AATs studied. The differences in the coenzyme tilt angles between cAAT and mAAT might be linked to catalytic peculiarities of the isoenzymes.     

The antibody-enzyme analogy. Characterization of antibodies to phosphopyridoxyltyrosine derivatives.

Stable analogs of the crucial Schiff base intermediate of enzymatic and nonenzymatic pyridoxal phosphate catalysis have been used as haptens for induction of specific antibodies. N-(5-phosphopyridoxyl)-3'-amino-L-tyrosine and its conformationally distinct cyclized derivative resemble the Schiff base formed upon mixing tyrosine with pyridoxal phosphate. These compounds were covalently coupled to a protein carrier via the 3'-amino group so as to confer a prescribed orientation, with the coenzyme region farthest removed from the carrier. A third antigen, with the phosphopyridoxyl group alone as the hapten, was prepared by linkage of pyridoxal phosphate directly to free amino groups on the carrier protein. Antibodies elicited for each determinant were purified by means of appropriate affinity columns. Antibody heterogeneity was observed in that different species could be separated from a given serum by sequential elution from the affinity columns with 1 M sodium phosphate buffers of pH 7.6, 5.2, 2.6 and 1.5. In assays of quantitative precipitation, inhibition of precipitation, equilibrium dialysis, and fluorescence quenching, antibodies to the phosphopyridoxyltyrosine haptens showed specificity for the phosphorylated form of the coenzyme and binding activity for both the coenzyme and tyrosine portions of the hapten. Antibodies to the phosphopyridoxyl groups alone did not display a similar reactivity toward the tyrosine portion of the complex haptens. The cyclic and noncyclic conformations of the hapten were serologically distinct, as antibody to each reacted preferentially with the homologous form.     

Biochemical characterization of a thermostable cysteine synthase from Geobacillus stearothermophilus V

The cysK gene encoding a cysteine synthase of Geobacillus stearothermophilus V was overexpressed in E. coli and the recombinant protein was purified and characterized. The enzyme is a thermostable homodimer (32 kDa/monomer) belonging to the beta family of pyridoxal phosphate (PLP)-dependent enzymes. UV-visible spectra showed absorption bands at 279 and 410 nm. The band at 279 nm is due to tyrosine residues as the enzyme lacks tryptophan. The 410 nm band represents absorption of the coenzyme bound as a Schiff base to a lysine residue of the protein. Fluorescence characteristics of CysK's Schiff base were influenced by temperature changes suggesting different local structures at the cofactor binding site. The emission of the Schiff base allowed the determination of binding constants for products at both 20 degrees C and 50 degrees C. At 50 degrees C and in the absence of sulphide the enzyme catalyzes the decomposition of O-acetyl-l-serine to pyruvate and ammonia. At 20 degrees C, however, a stable alpha-aminoacrylate intermediate is formed.     

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.     

Evidence that 31P NMR is a sensitive indicator of small conformational changes in the coenzyme of aspartate aminotransferase

The pH dependence of 31P-NMR spectra of pig cytosolic aspartate aminotransferase, containing either N-(5'-phosphopyridoxyl)-L-aspartate or pyridoxal 5'-deoxymethylenephosphonate in place of the normal coenzyme pyridoxal 5'-phosphate, has been analysed. The chemical shifts of phosphopyridoxylaspartate and of pyridoxal 5'-deoxymethylenephosphonate model Schiff base in free solution show pK values of 6.3 and 7.4, attributable to the second deprotonation step of phosphate and phosphonate, respectively. However, these compounds behave very differently when bound to apoaspartate aminotransferase. 31P-NMR spectra of these enzyme derivatives indicate that the phosph(on)ate group remains dianionic throughout the pH range 4-8.5. A clear correlation between apparent pK values obtained from spectrophotometric titration of the coenzyme chromophore and those obtained by 31P NMR indicates that the same ionisation is being reported by both methods. The data are interpreted, on the basis of available crystallographic structures of chicken mitochondrial aspartate aminotransferase, to indicate that in each case the alteration in 31P chemical shift results from a conformational change in the coenzyme 5' side chain, in which one of the structures involves a near-eclipsed pair of bonds. Such a stressed conformation produces slight alterations in bond angles around the phosphorus atom, which in turn cause the observed change in 31P chemical shift. The evidence is taken to indicate that in this case 31P NMR is a sensitive reporter of stress in enzyme-bound pyridoxal 5'-phosphate and its derivatives.     

Characterization of tryptophan and coenzyme luminescence in tryptophan synthase from Salmonella typhimurium.

Tryptophan synthase from Salmonella typhimurium is a bifunctional alpha 2 beta 2 complex that catalyzes the formation of L-tryptophan. We have characterized over the temperature range from 160 to 293 K the fluorescence and phosphorescence properties of the single tryptophan present at position 177 of the beta-subunit and of the pyridoxal 5'-phosphate bound through a Schiff's base in the beta-active site. The comparison between the fluorescence of the pyridoxal phosphate bound either to the protein or to valine free in solution indicates substantial protection for the coenzyme against thermal quenching and a greater intensity of the ketoenamine tautomer band. Trp-177 is highly luminescent, and its proximity to the pyridoxal moiety leads to an over 50% quenching of its fluorescence with both reduced and native coenzyme. The Trp phosphorescence spectrum possesses a narrow, well-defined, 0-0 vibrational band centered at 418.5 nm, a wavelength that indicates strong polar interactions with neighboring charges. The observation of delayed fluorescence in the native complex implies that the excited triplet state is involved in a process of triplet-singlet energy transfer to the ketoenamine tautomer. The rate of energy transfer, heterogeneous in low-temperature glasses with rate constants of 2.26 and 0.07 s-1, becomes homogeneous in fluid solutions as the coenzyme tautomer interconversion is likely faster than the phosphorescence decay. In both apo- and holo-alpha 2 beta 2, the phosphorescence from Trp-177 is long-lived even at ambient temperature.(ABSTRACT TRUNCATED AT 250 WORDS)