31P nuclear-magnetic-resonance studies of pyridoxal and pyridoxamine phosphates. Interaction with cytoplasmic aspartate transaminase

The Methanosarcina mazei MM2060 Gene Encodes a Bifunctional Kinase/Decarboxylase Enzyme Involved in Cobamide Biosynthesis

Cobamides (Cbas) are synthesized by many archaea, but some aspects of Cba biosynthesis in these microorganisms remain unclear. Here, we demonstrate that open reading frame MM2060 in the archaeum Methanosarcina mazei strain Gö1 encodes a bifunctional enzyme with l-threonine- O-3-phosphate (l-Thr-P) decarboxylase (EC 4.1.1.81) and l-Thr kinase activities (EC 2.7.1.177). In Salmonella enterica, where Cba biosynthesis has been extensively studied, the activities mentioned above are encoded by separate genes, namely, cobD and pduX, respectively. The activities associated with the MM2060 protein ( MmCobD) were validated in vitro and in vivo. In vitro, MmCobD used ATP and l-Thr as substrates and generated ADP, l-Thr-P, and ( R)-1-aminopropan-2-ol O-phosphate as products. Notably, MmCobD has a 111-amino acid C-terminal extension of unknown function, which contains a putative metal-binding motif. This C-terminal domain alone did not display activity either in vivo or in vitro. Although the C-terminal MmCobD domain was not required for l-Thr-P decarboxylase or l-Thr kinase activities in vivo, its absence negatively affected both activities. In vitro results suggested that this domain may have a regulatory or substrate-gating role. When purified under anoxic conditions, MmCobD displayed Michaelis-Menten kinetics and had a 1000-fold higher affinity for ATP and a catalytic efficiency 1300-fold higher than that of MmCobD purified under oxic conditions. To the best of our knowledge, MmCobD is the first example of a new class of l-Thr-P decarboxylases that also have l-Thr kinase activity. An archaeal protein with l-Thr kinase activity had not been identified prior to this work.

NMR studies of coupled low- and high-barrier hydrogen bonds in pyridoxal-5'-phosphate model systems in polar solution

The 1H and 15N NMR spectra of several 15N-labeled pyridoxal-5'-phosphate model systems have been measured at low temperature in various aprotic and protic solvents of different polarity, i.e., dichloromethane-d2, acetonitrile-d3, tetrahydrofuran-d8, freon mixture CDF3/CDClF2, and methanol. In particular, the 15N-labeled 5'-triisopropyl-silyl ether of N-(pyridoxylidene)-tolylamine (1a), N-(pyridoxylidene)-methylamine (2a), and the Schiff base with 15N-2-methylaspartic acid (3a) and their complexes with proton donors such as triphenylmethanol, phenol, and carboxylic acids of increasing strength were studied. With the use of hydrogen bond correlation techniques, the 1H/15N chemical shift and scalar coupling data could be associated with the geometries of the intermolecular O1H1N1 (pyridine nitrogen) and the intramolecular O2H2N2 (Schiff base) hydrogen bonds. Whereas O1H1N1 is characterized by a series of asymmetric low-barrier hydrogen bonds, the proton in O2H2N2 faces a barrier for proton transfer of medium height. When the substituent on the Schiff base nitrogen is an aromatic ring, the shift of the proton in O1H1N1 from oxygen to nitrogen has little effect on the position of the proton in the O2H2N2 hydrogen bond. By contrast, when the substituent on the Schiff base nitrogen is a methyl group, a proton shift from O to N in O1H1N1 drives the tautomeric equilibrium in O2H2N2 from the neutral O2-H2...N2 to the zwitterionic O2-...H2-N(2+) form. This coupling is lost in aqueous solution where the intramolecular O2H2N2 hydrogen bond is broken by solute-solvent interactions. However, in methanol, which mimics hydrogen bonds to the Schiff base in the enzyme active site, the coupling is preserved. Therefore, the reactivity of Schiff base intermediates in pyridoxal-5'-phosphate enzymes can likely be tuned to the requirements of the reaction being catalyzed by differential protonation of the pyridine nitrogen.

15N nuclear magnetic resonance studies of acid-base properties of pyridoxal-5'-phosphate aldimines in aqueous solution

By use of 15N NMR spectroscopy, we have measured the pKa values of the aldimines 15N-(pyridoxyl-5'-phosphate-idine)-methylamine (2a), N-(pyridoxyl-5'-phosphate-15N-idine)-methylamine (2b), and 15N-(pyridoxyl-idine)-methylamine (3). These aldimines model the cofactor pyridoxal-5'-phosphate (PLP, 1) in a variety of PLP-dependent enzymes. The acid-base properties of the aldimines differ substantially from those of the free cofactor in the aldehyde form 1a or in the hydrated form 1b, which were also investigated using 15N NMR for comparison. All compounds contain three protonation sites, the pyridine ring, the phenol group, and the side chain phosphate (1, 2) or hydroxyl group (3). In agreement with the literature, 1a exhibits one of several pKas at 2.9 and 1b at 4.2. The 15N chemical shifts indicate that the corresponding deprotonation occurs partially in the pyridine and partially in the phenolic site, which compete for the remaining proton. The equilibrium constant of this ring-phenolate tautomerism was measured to be 0.40 for 1a and 0.06 for 1b. The tautomerism is essentially unaltered above pH 6.1, where the phosphate group is deprotonated to the dianion. This means that the pyridine ring is more basic than the phenolate group. Pyridine nitrogen deprotonation occurs at 8.2 for 1a and at 8.7 for 1b. By contrast, above pH 4 the phosphate site of 2 is deprotonated, while the pyridine ring pKa is 5.8. The Schiff base nitrogen does not deprotonate below pH 11.4. When the phosphate group is removed, the pKa of the Schiff base nitrogen decreases to 10.5. The phenol site cannot compete for the proton of the Schiff base nitrogen and is present in the entire pH range as a phenolate, preferentially hydrogen bonded to the solvent. The intrinsic 15N chemical shifts provide information about the hydrogen bond structures of the protonated and unprotonated species involved. Evidence is presented that the intramolecular OHN hydrogen bond of PLP aldimines is broken in aqueous solution. The coupling between the inter- and intramolecular OHN hydrogen bonds is also lost in this environment. The pyridine ring of the PLP aldimines is not protonated in aqueous solution near neutral pH. The basicity of the aldimine nitrogens would be even lower without the doubly negatively charged phosphate group. Protonation of both the Schiff base and pyridine nitrogens has been discussed as a prerequisite for catalytic activity, and the implications of the present findings for PLP catalysis are discussed.

Crystal structure of rabbit cytosolic serine hydroxymethyltransferase at 2.8 A resolution: mechanistic implications

Serine hydroxymethyltransferase (SHMT) catalyzes the reversible cleavage of serine to form glycine and single carbon groups that are essential for many biosynthetic pathways. SHMT requires both pyridoxal phosphate (PLP) and tetrahydropteroylpolyglutamate (H4PteGlun) as cofactors, the latter as a carrier of the single carbon group. We describe here the crystal structure at 2.8 A resolution of rabbit cytosolic SHMT (rcSHMT) in two forms: one with the PLP covalently bound as an aldimine to the Nepsilon-amino group of the active site lysine and the other with the aldimine reduced to a secondary amine. The rcSHMT structure closely resembles the structure of human SHMT, confirming its similarity to the alpha-class of PLP enzymes. The structures reported here further permit identification of changes in the PLP group that accompany formation of the geminal diamine complex, the first intermediate in the reaction pathway. On the basis of the current mechanism derived from solution studies and the properties of site mutants, we are able to model the binding of both the serine substrate and the H4PteGlun cofactor. This model explains the properties of several site mutants of SHMT and offers testable hypotheses for a more detailed mechanism of this enzyme.

Role of Arg-277 in the binding of pyridoxal 5'-phosphate to Trypanosoma brucei ornithine decarboxylase

The pyridoxal 5'-phosphate (PLP) binding site in Trypanosoma brucei ornithine decarboxylase (ODC) has been studied by site-directed mutagenesis and spectroscopy. The beta/alpha barrel model proposed for the eukaryotic ODC structure predicts that the phosphate group of PLP is stabilized by interactions with a Gly-rich loop (residues 235-237) and by a salt bridge to Arg-277 [Grishin, N. V., Phillips, M. A., & Goldsmith, E. J. (1995) Protein Sci. 4, 1291-1304]. Mutation of Arg-277 to Ala increases the K(m) for PLP by 270-fold compared to that of wild-type ODC while reducing k(cat) by only 2-fold at pH 8. PLP binding affinity was measured directly by ultrafiltration; the K(d) for PLP is at least 20-fold higher in the mutant enzyme at pH 8. In addition, R277A ODC also has weaker binding affinities for a series of cofactor analogs than the wild-type enzyme. These results demonstrate that Arg-277 is necessary for high-affinity PLP binding by ODC. The 31P NMR spectra of ODC suggest that the phosphate is bound in a strained conformation as a dianion to both wild-type and R277A ODC. However, the 31P chemical shift for R277A ODC (6.7 ppm) is 0.5 ppm downfield from that observed for the wild-type enzyme, indicating that the environment of the enzyme-bound phosphate is altered in the mutant enzyme. The binding affinity of PLP for both wild-type and R277A ODC is weaker at high pH, corresponding to the titration of a protonated species with a pK(a) of approximately 8.5. Concomitant with these changes are a decreased k(cat) and an altered absorption spectra which arises from bound PLP. PLP bound to wild-type ODC has a 31P chemical shift and a CD signal observable over the entire tested pH range (7-9). In contrast, for R277A ODC between pH 8 and 9, the 31P chemical shift becomes solution-like and the CD signal is abolished. The data suggest that for R277A ODC the rigid PLP binding mode which characterizes the wild-type enzyme is lost at high pH. Thus, multiple interactions between the wild-type active site and PLP maintain the cofactor in a constrained conformation that is essential for efficient catalysis, tempering the consequence of the removal of any single interaction.

Inorganic phosphate binding and electrostatic effects in the active center of aspartate aminotransferase apoenzyme

The ionization state of the phosphate group bound at the aspartate aminotransferase apoenzyme's active site has been investigated utilizing Fourier-transform infrared spectroscopy following the band corresponding to the symmetric stretching of the dianionic phosphate. Unlike free phosphate, when inorganic phosphate is bound at the enzyme's active site, the integrated intensity value of the dianionic band does not change with pH within the studied range, and this value is similar to that for free dianionic phosphate at pH 8.3. From these results, we propose a dianionic state for the phosphate ion bound to cytosolic aspartate aminotransferase throughout the pH range of 5.7-8.3. The presence of other anions such as acetate and chloride or the substrate aspartate and its analogues produces a pH-dependent phosphate removal from the active site which is favored at low pH values. Elimination of the charged primary amine at the active-site Lys-258, through formation of a Schiff base with pyridoxal or chemical modification by carbamylation, also produces a pH-independent phosphate release. These results are interpreted as Lys-258 together with the active-site alpha-helix and other residues may be involved in stabilizing phosphate as a dianion in the apoenzyme phosphate pocket which anchors the phosphate ester of pyridoxal phosphate in the holoenzyme. It is proposed that the dianionic phosphate contributes to the apoenzyme's thermal stability through formation of strong hydrogen bond and salt bridges with the amino acid residues forming the phosphate binding pocket with assistance of Lys-258, and other active-site cationic components.

The ionization states of the 5'-phosphate group in the various coenzyme forms bound to mitochondrial aspartate aminotransferase

We have carried out a Fourier transform infrared spectroscopic study of mitochondrial aspartate aminotransferase in the spectral region where phosphate monoesters give rise to absorption. Infrared spectra in the above-mentioned region are dominated by protein absorption. Yet, below 1020 cm-1 protein interferences are minor, permitting the detection of the band arising from the symmetric stretching of dianionic phosphate monoesters [T. Shimanouchi, M. Tsuboi, and Y. Kyogoku (1964) Adv. Chem. Phys. 8, 435-498]. The integrated intensity of this band in several enzyme forms (pyridoxal phosphate, pyridoxamine phosphate, and sodium borohydride-reduced, pyridoxyl phosphate form) does not change with pH in the range 5-9. This behavior contrasts that of free pyridoxal phosphate (PLP) and pyridoxamine phosphate (PMP) in solution, where the dependence of the same infrared band intensity with pH can be correlated to the known pK values for the 5'-phosphate ester in solution. The integrated intensity value of this infrared band for the PLP enzyme form before and after reduction with sodium borohydride is close to that given by free PLP at pH 8-9. These results are taken as evidence that in the active site of mitochondrial aspartate aminotransferase the 5'-phosphate group of PLP remains mostly dianionic even at a pH near 5. Thus, it is suggested that the chemical shift changes associated with pH titrations of various PLP forms reported in a previous 31P NMR study of this enzyme [M. E. Mattingly, J. R. Mattingly, and M. Martinez-Carrion (1982) J. Biol. Chem. 257, 8872] are due to the fact that the phosphorus chemical shift senses the O-P-O bond distortions induced by the ionization of a nearby residue. Since no chemical shift changes were observed in pH titrations of the PMP forms (lacking an ionizable internal aldimine) of this isozyme, the Schiff base between PLP and Lys-258 at the active site is the most likely candidate for the ionizing group influencing the phosphorus chemical shift in this 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.

Reactions of phosphonate analogs of pyridoxal phosphate with apo-aspartate aminotransferase

We have investigated reactions of the 5-phosphonoethyl and 5-phosphonoethenyl analogs of pyridoxal 5'-phosphate in the coenzyme site of cytosolic aspartate aminotransferase. Acid dissociation constants and equilibrium constants for hydration and for tautomerization have been evaluated for these compounds. In confirmation of previous results, both compounds are partially active. They bind to apoenzyme well and undergo conversion in the presence of glutamate to amine forms which show induced circular dichroism comparable to that of native enzyme. A normal "external" Schiff base is evidently formed with 2-methylaspartate, but the amounts of quinonoid intermediate formed with erythro-3-hydroxyaspartate are less than those formed with pyridoxal phosphate. The pKa of the imine group of the enzyme reconstituted with the phosphonoethyl analog is more than two units lower than that in the native enzyme. Binding of the dicarboxylates glutarate, 2-oxoglutarate, and succinate shifts the pKa upward. The absorption spectra of the resulting complexes indicate the existence of at least three low pH species. A shift of 2.3 to 2.9 ppm to a lower frequency was observed for the 31P NMR signal upon binding of these dicarboxylates or of 2-methylaspartate. Enzyme containing the analogs crystallizes. Polarized absorption spectra suggest that the coenzyme has an orientation similar to that of pyridoxal phosphate in the native enzyme.

31P NMR investigations on free and enzyme bound thiamine pyrophosphate

Pyruvate decarboxylase (PDC) contains thiamine pyrophosphate (TPP) and Mg2+ as cofactors. 31P NMR studies with PDC in the presence of added Mn2+ reveal the pyrophosphate moiety of TPP to be a nonaccessible area for the external Mn2+ and thus proving the Mg-P-complex (taking part in the binding of the coenzyme to the protein) to be a nonaccessible area for the medium. Glyoxylic acid, acting as an inhibitor of PDC by forming a noncleavable bond with the catalytic center of TPP causes a steric immobilization of the coenzyme indicated by a line broadening of the pyrophosphate moiety.

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.

Phosphorus-31 nuclear magnetic resonance of aspartate aminotransferase from chicken heart cytosol

31P-nuclear magnetic resonance and absorption spectra of cytosolic chicken aspartate aminotransferase (L-aspartate:2-oxoglutarate aminotransferase, EC 2.6.1.1) have been recorded in the pH range from 5 to 8.5. The 31P chemical shift was found to be pH-dependent with a pK of 6.85; the chemical shift change was 0.35 ppm. The pK value found by spectrophotometric titration of the enzyme proved to be about 6.0. The monoanion-dianion transition of the 5'-phosphate group of a model Schiff base of pyridoxal phosphate with 2-aminobutanol in methanol is accompanied by a change in the 31P chemical shift of 5.2 ppm. It is inferred that the phosphate group of the protein-bound coenzyme is in a dianionic form throughout the investigated pH range; the pH-dependence of the 31P chemical shift may be due to a conformational change at the active site. In the presence of 100 mM succinate, 6 mM aminooxyacetate or 25 mM cycloserine, the 31P chemical shift is insensitive to pH variations.

Ionization state of the coenzyme 5'-phosphate ester in cytosolic aspartate aminotransferase. A Fourier transform infrared spectroscopic study

In order to determine the ionization state of the 5'-phosphate of bound pyridoxal phosphate, a Fourier transform infrared spectroscopic study of cytosolic aspartate aminotransferase has been carried out. Dianionic and monoanionic phosphate monoesters give rise to two bands each in the infrared spectrum [Shimanouchi, T., Tsuboi, M., & Kyogoku, Y. (1964) Adv. Chem. Phys. 8, 435-498]. These bands can be identified in infrared spectra of the free coenzyme in solution. Due to interfering bands arising from the protein, only the band assigned to the symmetric stretching of the dianionic phosphate is observed in holoenzyme solutions. The integrated intensity of this band does not change with pH in the range 5.3-8.6, while for free pyridoxal phosphate, the integrated intensity of the same band changes with pH according to the pK value expected for the 5'-phosphate group in solution. Moreover, the value of the integrated intensity for the bound cofactor is close to the value given by free cofactor at pH 8-9. These results suggest that the 5'-phosphate of the bound cofactor remains mostly dianionic throughout the investigated pH range and disfavor other interpretations in terms of ionization of the phosphate group on the basis of the nuclear magnetic resonance 31P chemical shift-pH titration curve of holoenzyme [Schnackerz, K. D. (1984) in Chemical and Biological Aspects of Vitamin B6 Catalysis (Evangelopoulos, E. A., Ed.) Part A, pp 195-208, Alan R. Liss, New York].(ABSTRACT TRUNCATED AT 250 WORDS)

Phosphorus-31 nuclear magnetic resonance study on cytoplasmic aspartate aminotransferase from pig heart. A reinvestigation

Striking differences of the environment of the phosphate group of pyridoxal-P in cytoplasmic and mitochondrial aspartate aminotransferase have been reported. Since most details of the three-dimensional structure of the active sites of these isozymes are identical, it seemed difficult to rationalize the reported differences. Therefore, the cytoplasmic isozyme was reinvestigated using 31P-NMR at 72.86 MHz. The 31P chemical shift of the cofactor of this isozyme was found to be pH-dependent with a pKa of 6.2. In the presence of 100 mM succinate or 100 mM glutarate, the 31P chemical shift of bound pyridoxal-P remains at 4.71 or 4.79 ppm, respectively, in the pH range from 5.0 to 8.0, indicating that the phosphate group of the cofactor appears to be in its dianionic form. Reduction of the internal pyridoxal-P Schiff's base dramatically increases the pKa of the phosphate group of the phosphopyridoxyl moiety of the protein to 8.3. Hence, our results on the cytoplasmic isozyme are similar to those reported for the mitochondrial isozyme.

Mechanism of action of aspartate aminotransferase proposed on the basis of its spatial structure

Aspartate aminotransferase is a pyridoxal phosphate-dependent enzyme that catalyses the transamination reaction: L-aspartate + 2-oxoglutarate----oxaloacetate + L-glutamate. The enzyme shuttles between its pyridoxal and pyridoxamine forms in a double-displacement process. This paper proposes a mechanism of action that delineates the dynamic role of the protein moiety of this enzyme. It is based on crystallographically determined spatial structures (at 2.8 A resolution) of the mitochondrial isoenzyme in its unliganded forms and in complexes with substrate analogues, as well as on model building studies. The enzyme is composed of two identical subunits, which consist of two domains. The coenzyme is bound to the larger domain and is situated in a pocket near the subunit interface. The proximal and distal carboxylate group of dicarboxylic substrates are bound to Arg386 and Arg292 , respectively, the latter residue belonging to the adjacent subunit. These interactions largely determine the substrate specificity of the enzyme. They not only position the substrate efficient catalysis but also bring about a bulk movement of the small domain that closes the active site crevice and moves Arg386 about 3 A closer to the coenzyme. The replacement of the epsilon-amino group of Lys258 by the alpha-amino group of the substrate in the aldimine bond to pyridoxal phosphate is accompanied by a tilting of the coenzyme by approximately 30 degrees. The released epsilon-amino group of Lys258 serves as a proton acceptor/donor in the 1,3- prototropic shift producing the ketimine intermediate. At this stage, or after hydrolysis of the ketimine bond, the coenzyme rotates back to an orientation between that in the "external" aldimine intermediate and that in the pyridoxal form. Throughout this process, the protonated pyridine nitrogen atom maintains a hydrogen bond to the beta-carboxylate group of Asp222 . Upon formation of the pyridoxamine form, the small domain moves back to its original position. The proposed mechanism is compatible with the known kinetic and stereochemical features of enzymic transamination.

Rotational dynamics of 4-aminobutyrate aminotransferase

The fluorescence dye 1-anilinonaphthalene-8-sulfonate (ANS) was used as a probe of non-polar binding sites in 4-aminobutyrate aminotransferase. ANS binds to a single binding site of the dimeric protein with a Kd of 6 microM. Nanosecond emission anisotropy measurements were performed on the ANS-enzyme in an effort to detect independent rotation of the subunits in the native enzyme. The observed rotational correlation time (phi = 65 ns) corresponds to the rotation of a rather rigid dimeric structure. The microenvironment surrounding the natural probe pyridoxal-5-P covalently bound to the dimeric structure was explored using 31P-NMR at 72.86 MHz. In the native enzyme, the pyridoxal-5-P 31P-chemical shift is pH-independent, indicating that the phosphate group is well protected from the solvent. The correlation time determined from the 31P-spectrum of the aminotransferase exceeds the value calculated for the hydrated spherical model (phi = 40 ns). It is concluded that the phosphate of the pyridoxal-5-P molecule is rigidly bound to the active site of 4-aminobutyrate aminotransferase.

Three-dimensional structure of a pyridoxal-phosphate-dependent enzyme, mitochondrial aspartate aminotransferase

X-ray diffraction studies to 2.8-A resolution have yielded the three-dimensional structure of mitochondrial aspartate aminotransferase (L-aspartate:2-oxoglutarate aminotransferase, EC 2.6.1.1), an isologous alpha 2 dimer (Mr = 2 x 45,000). The subunits are rich in secondary structure and contain two domains, one of which anchors the coenzyme, pyridoxal 5'-phosphate. Each active site lies between the subunits and is composed of residues from both of them.

31P NMR studies on the interaction of deoxyuridylate with thymidylate synthase

The 31P nuclear magnetic resonance signal of deoxyuridylate was studied in the presence and absence of thymidlate synthase. In the absence of enzyme the chemical shift of deoxyuridylate is pH dependent with a pKa of 6.25. In the presence of enzyme, a peak corresponding to the dianioinc form of deoxyuridylate is observed which is independent of pH between pH 5.7 and pH 7.4. The pKa of the phosphate in the deoxyuridylate-thymidylate synthase complex is therefore less than 5. The release of inorganic phosphate from deoxyuridylate catalyzed by contaminating phosphatase was also observed.

The pyridoxal 5' -phosphate site in rabbit skeletal muscle glycogen phosphorylase b: an ultraviolet and 1H and 31P nuclear magnetic resonance spectroscopic study

1 H NMR spectra of the 3-0-methylpyridoxal 5'-phosphate-n-butylamine reaction product indicated that this analogue forms a Schiff base in aprotic solvent. The uv spectral properties of 3-0-methylpyridoxal-5'-phosphate phosphorylase b correspond to those of the n-butylamine Schiff base derivative in dimethyl sulfoxide. On the basis of that and auxiliary uv and 1H NMR spectra of pyridoxal and pyridoxal 5'-phosphate and the corresponding Schiff base derivatives we have verified that pyridoxal 5' -phosphate is also bound as a Schiff base to phosphorylase and not as an aldamine. Since 3-0-methylpyridoxal-5'-phosphate phosphorylase is active, a proton shuttle between the 3-hydroxyl group and the pyridine nitrogen is excluded. This directs attention to the 5' -phosphate group of the cofactor as a candidate for a catalytic function. 31P NMR spectra of pyridoxal 5' -phosphate in phosphorylase b indicated that deprotonation of the 5' -phosphate group was unresponsive to external pH. Interaction of phosphorylase b with adenosine 5' -monophosphate, the allosteric effector required activity, and arsenate, which substitutes for phosphate as substrate, triggered a conformational change which resulted in deprotonation of the 5' -phosphate group of pyridoxal 5' at pH 7.6. It now behaved like in the pyridoxal-phosphate-epsilon-aminocaproate Schiff base in aqueous buffer, where the diionized form is dominant at this pH. Differences of line widths of the adenosine 5' -monophosphate signal point to different life times of the allosteric effector- enzyme complexes in the presence and absence of substrate (arsenate).