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.     

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

The 31P nuclear magnetic resonance (NMR) spectrum of the phosphate in free pyridoxal or pyridoxamine phosphate reveals a resonance signal that is coupled to the methylene protons of the 5-CH2 with JHP of 6.0 +/- 0.3 Hz. Proton noise decoupling results in a single signal with a pH-dependent chemical shift with deprotonation of the phosphate resulting in a shift of the 31P resonance to lower fields. A single 31P NMR signal at a frequency corresponding to fully ionized phosphate monoesters is observed in aspartate-transaminase-bound pyridoxal or pyridoxamine phosphate. The 31P resonance in the holotransaminase is pH-independent and is unaffected by saturating concentrations of substrates or inhibitors. Only denaturation with 6 M guanidine with HCl results in changes in the 31P of the holoenzyme. It appears that the phosphate group of pyridoxal phosphate is bound to a positive pocket in the holoenzyme and remains fully ionized in the pH range of 5.6 to 9.2. The phosphate-binding properties are present even in the apoenzyme which is able to bind inorganic phosphate which then can be displaced by pyridoxal or pyridoxamine phosphate in the process of holoenzyme formation.     

The structure and formation of the glucose 6-phosphate adduct of hemoglobin A: a 31P-NMR study

The glucose 6-phosphate adduct of hemoglobin formed on deoxy incubation of the sugar with hemoglobin is primarily present in solution as the unstable aldimine compound; in contrast, the percent ketoamine is higher if the adduct is formed in the presence of carbon monoxide. The adduct has a 31P nuclear magnetic resonance peak with a chemical shift which is 0.7 ppm up-field from the shift of unreacted glucose 6-phosphate at pH 7.0 and is constant between pH 6 and 8, while the unreacted sugar phosphate shows the characteristic change of chemical shift due to ionization of one of the phosphate protons. This suggests that, in the adduct, phosphate is involved in a salt bridge, probably at the 2,3-diphosphoglyceric acid binding site.     

Ionization state of pyridoxal 5'-phosphate in D-serine dehydratase, dialkylglycine decarboxylase and tyrosine phenol-lyase and the influence of monovalent cations as inferred by 31P NMR spectroscopy

The 31P NMR spectroscopy of three pyridoxal 5'-phosphate-dependent enzymes, monomeric D-serine dehydratase, tetrameric dialkylglycine decarboxylase and tetrameric tyrosine phenol-lyase, whose enzymatic activities are dependent on alkali metal ions, was studied. 31P NMR spectra of the latter two enzymes have never been reported, their 3D-structures, however, are available. The cofactor phosphate chemical shift of all three enzymes changes by approximately 3 ppm as a function of pH, indicating that the phosphate group changes from being monoanionic at low pH to dianionic at high pH. The 31P NMR signal of the phosphate group of pyridoxal 5'-phosphate provides a measure of the active site changes that occur when various alkali metal ions are bound. Structural information is used to assist in the interpretation of the chemical shift changes observed. For D-serine dehydratase, no structural data are available but nevertheless the metal ion arrangement in the PLP binding site can be predicted from 31P NMR data.     

Phosphorus nuclear magnetic resonance studies of phosphoglucomutase and its metal ion complexes.

The ³¹P nuclear magnetic resonance of the covalently bound phosphate group at the active site of phosphoglucomutase has been examined by means of Fourier transform nuclear magnetic resonance spectroscopy. At a pD of 7.9, the chemical shift of the ³¹P nucleus is 3.8 ± 0.1 ppm downfield from 85% H₃PO₄; this shift is close to that of phosphoserine (dianionic form). Proton decoupling experiments suggest that the phosphorus of the enzymic phosphate group is coupled to protons with chemical shifts similar to those of phosphoserine. In D₂O, with proton decoupling, the ratio of the longitudinal and transverse diamagnetic relaxation times in solutions of 1.6 mm phosphoenzyme yields an approximate correlation time of 10^?7s for the ³¹P nucleus of the enzyme. This is within the range of values expected for tumbling of the entire protein molecule and suggests that the covalently attached phosphate group is immobilized or “frozen” at the active site of the enzyme by means of noncovalent interactions with adjacent groups. Consistent with this, the pK_a of the enzymic phosphate is significantly lower than that of phosphoserine. Binding of the diamagnetic activator, Mg²⁺, causes little or no change in the chemical shift of the resonance of the enzymic phosphorus from pD = 5.3 to 7.6, a downfield shift (?0.5 ± 0.1 ppm) at pD = 8.6, but an upfield shift (0.8 ±0.1 ppm) for that of phosphoserine, suggesting that bound Mg²⁺ is not coordinated to the enzymic phosphate. Independent evidence against direct coordination is provided by the paramagnetic effects of Ni²⁺ bound at the active site on the relaxation rates of the enzymic phosphorus. By assessing the paramagnetic effect of bound Ni²⁺ on both the longitudinal and transverse relaxation rates of the observed resonance, and by using correlation times determined for water proton relaxation induced by the Ni²⁺ complex, a range of Ni²⁺ to phosphorus distances of 4 to 6 Å is calculated. These distances suggest a second sphere interaction between the enzyme-bound metal and the enzymic phosphate group. Bound Ni²⁺ also markedly decreases the integrated intensity of the ³¹P resonance. Although the reason for this intensity decrease is incompletely explained, the present data establish the close proximity of the bound metal ion and the active site phosphoserine on phosphoglucomutase.     

NMR studies and semi-empirical energy calculations for cyclic ADP-ribose

A possible pH-dependent conformational switch was investigated for cyclic ADP-ribose. NMR signals for the exchangeable protons were observed in H2O at low temperature, but there was no direct evidence for the protonation of N-3 at neutral pH that has previously been postulated. MNDO calculations indicated that pH dependent 31P chemical shift changes are attributable to protonation of the phosphate adjacent to the N-1 of adenine, and not due to trans-annular hydrogen bonding with a protonated N-3.     

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.     

Active-site serine phosphate and histidine residues of phosphoglucomutase: pH titration studies monitored by 1H and 31P NMR spectroscopy

1H and 31P NMR pH titrations were conducted to monitor changes in the environment and protonation state of the histidine residues and phosphoserine group of rabbit muscle phosphoglucomutase on binding of metal ions at the activating site and of substrate (glucose phosphate) at the catalytic site. Imidazole C epsilon-H signals from 8 of the 10 histidines present in the free enzyme were observed in 1H NMR spectra obtained by a spin-echo pulse sequence at 470 MHz; their pH (uncorrected pH meter reading of a 2H2O solution measured with a glass electrode standardized with H2O buffer) titration properties (in 99% 2H2O) were determined. Three of these histidine residues, which have pKa values ranging from 6.5 to 7.9, exhibited an atypical pH-dependent perturbation of their chemical shifts with a pHmid of 5.8 and a Hill coefficient of about 2. Since none of the observed histidines has a pKa near 5.8, it appears that these three histidines interact with a cluster consisting of two or more groups which become protonated cooperatively at this pH. Binding of Cd2+ at the activating site of the enzyme abolishes the pH-dependent transition of these histidines; hence, the putative anion cluster may constitute the metal ion binding site, or part of it. Two separate 31P NMR peaks from phosphoserine-116 of the phosphoenzyme were observed between pH 6 and 9. Apparently, the metal-free enzyme exists as a pH-dependent mixture of conformers that provide two different environments, I and II, for the enzymic phosphate group; the transition of the phosphate group between these two environments is slow on the NMR time scale.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Phosphorus-31 nuclear magnetic resonance studies of the two phosphoserine residues of hen egg white ovalbumin

Ovalbumin contains two phosphoserine residues that give rise to two well-resolved resonances in a 31P NMR spectrum. Ovalbumin samples that have been digested with a variety of phosphatases may give rise to only one phosphoserine resonance, indicating that one of the two phosphorylated sites is relatively inaccessible for phosphatase action. By comparison of the amino acid sequence of the peptide containing the nonsusceptible phosphate to the overall primary structure, we have assigned the resonances observed (pH 8.3) at 5.0 and 4.75 ppm to phosphoserines-68 and -344, respectively. pH titration behavior and susceptibility of the phosphoserine residues to phosphatases indicate that both are located on the surface of the protein. Both residues have a pKa = 6.00-6.04. Analysis of the Hill coefficients measured for the pH titrations and the JPH coupling constants indicate that neither residue interacts with other charged groups on the surface of the protein. Frequency dependence of 31P NMR parameters shows that at higher magnetic field strengths the contribution of chemical shift anisotropy to the line width becomes very significant. We have calculated from the field-dependent terms that phosphoserine-344 is mobile with respect to the protein surface but that phosphoserine-68 is more restricted in its motion. The latter is also involved in a pH-dependent conformational change, since it is shielded from hydrolysis by phosphatases at higher pH. A comparison of the amino acid sequence of the phosphoserine-68 site shows that it has a striking homology to the active-site peptides of a wide variety of hydrolytic enzymes. Moreover, a comparison with the primary sequences of casein suggests that both proteins are phosphorylated by a protein kinase that specifically recognizes a Ser-X-Glu peptide.     

Analysis of phosphate metabolites, the intracellular pH, and the state of adenosine triphosphate in intact muscle by phosphorus nuclear magnetic resonance.

31P nuclear magnetic resonance spectra recorded from intact muophosphate, and the sugar phosphates. Quantitation of these metabolites by 31P nuclear magnetic resonance was in good agreement with values obtained by chemical analyses. The spectra obtained from various muscles showed considerable variation in their phosphorus profile. Thus, differences could be detected between (a) normal and diseased muscle; (b) vertebrates and invertebrates; (c) different species of the same animal. The time course of change in phosphate metabolites in frog muscle showed that ATP level remains unchanged until phosphocreatine is nearly depleted. Comparative studies revealed that under anaerobic conditions the Northern frog maintains its ATP content for 7 hours, while other types of amphibian, bird, and mammalian muscles begin to show an appreciable decay in ATP after 2 hours. Several lines of evidence indicated that ATP forms a complex with magnesium in the muscle water: (a) the phosphate resonances of ATP in the muscle were shifted downfield as compared to those in the alkaline earth metal-free perchloric acid extract of the muscle; (b) the coupling constants of ATP measured in various live muscles closely corresponded to those for MgATP in a solution resembling the composition of the muscle water; (c) in the muscle the gamma-phosphate group of ATP exhibited no shift change over a period of 10 hours under conditions where resonances of other phosphate compounds could be titrated. This behavior is similar to that of MgATP in model solutions in the physiological pH range, and it is different from that of CaATP. The chemical shifts of the phosphate metabolites were determined in several relevant solutions as a function of pH. Under all conditions only inorganic orthophosphate showed an invariant titration curve. From the chemical shift of inorganic phosphate observed during aging of intact muscle the intracellular pH of frog muscle was estimated to be 7.2.     

31P NMR of phosphate and phosphonate complexes of metalloalkaline phosphatases.

31P NMR spectra of phosphate and phosphonate complexes of Escherichia coli alkaline phosphatase have been obtained by Fourier transform NMR methods. One equivalent of P1i, bound to Zn(II) alkaline phosphatase, pH 8, gives rise to a single 31P resonance 2 ppm downfield from that for Pi, and assignable to the noncovalent complex, E-P. Inorganic phosphate in excess of 1 eq per enzyme dimer gives rise to a resonance at the position expected for free Pi. At pH 5.1, a second resonance appears 8.5 ppm downfield from that for free Pi, and is assignable to the covalent complex, E-P. The large downfield shift suggests that the enzyme phosphoryl group is highly strained with an O-P-O bond angle of under 100 degrees.     

Phosphorus-31 nuclear magnetic resonance analysis of internal pH during photosynthesis in the cyanobacterium Synechococcus

Phosphorus-31 nuclear magnetic resonance (31P NMR) spectra were obtained from actively photosynthesizing and darkened suspensions of the unicellular cyanobacterium Synechococcus. These spectra show intracellular resonances belonging to inorganic phosphate (Pi), a sugar phosphate (sugar-P), nucleotide di- and triphosphates, and poly-phosphates. The pH-dependent chemical shifts of Pi and sugar-P allowed the estimation of intracellular pH. When irradiated with high-intensity tungsten-halogen light (100 x 10(4) ergs . cm-2 . s-1, measured in the visible range), concentrated cell suspensions in the NMR spectrometer incorporated NaH14CO3 at approximately two-thirds the rate shown by a dilute suspension of cells at saturating light intensity. On the basis of NaH14CO3 incorporation, the effective light intensity obtained under NMR conditions would support growth at approximately one-fourth the maximum rate in dilute suspensions of cells. Irradiated cells maintained a cytoplasmic pH of 7.1--7.3 when exposed to an external pH from 6.4 to 8.3. At an external pH of 6.7, a darkness to light shift caused a 0.4 pH unit alkalinization of the cytoplasm. Treatment of cell suspensions with the uncoupler, carbonyl cyanide m-chlorophenylhydrazone (CCCP), in light or darkness, collapsed the internal pH to the level of the external pH. The results suggest a strong light- or energy-dependent buffering of the cytoplasm over a range of external pH. The study demonstrates that 31P NMR can be used to investigate intracellular events in an actively photosynthesizing microorganism.     

31P NMR of covalent phosphorylated derivatives of alpha-chymotrypsin

The structures of various covalent phosphorylated derivatives of alpha-chymotrypsin (alpha-CT) have been studied by 31P NMR spectroscopy. Diisopropylphosphoryl-alpha-chymotrypsin (alpha-DIPCT) shows a single 31P signal at ca. 0.0 ppm (pH 4). At low pH, the 31P NMR spectrum of alpha-DIPCT gradually changed with the appearance of one or two additional peaks. The ratio of the peaks varied with pH, time, and concentration. One of these two new downfield peaks (both at ca. 2.0 ppm) has been previously identified by Markley and co-workers (Markley, 1979; Porubcan et al., 1979) and van der Drift et al. (1985) as an aged monoisopropylphosphoryl-alpha-chymotrypsin (alpha-MIPCT) and is confirmed by our studies. A new additional downfield signal, separate from the alpha-MIPCT signal, is attributed to a dimer of the phosphorylated alpha-DIPCT. Phosphorylation of the enzyme with diphenyl chlorophosphate yields a monophenylphosphoryl-alpha-chymotrypsin (alpha-MPPCT) that also showed a single 31P signal at -2.1 ppm (pH 7). However, the spectrum did not change as a function of pH, incubation time, or concentration. Comparison of the 31P chemical shifts of the native and denatured phosphorylated derivatives of alpha-chymotrypsin suggests changes in the conformation about the P-O ester bonds are at least partially responsible for the various 31P chemical shift differences.     

On the coordination of inhibitors to the metal ion of carboxypeptidase A. A 113Cd and 31P NMR study

113Cd and 31P NMR have been used to investigate the interactions of inhibitors with the metal ion of bovine carboxypeptidase A, using 113Cd as a replacement for the native zinc atom. In the absence of inhibitor and over the pH range 6-9, no 113Cd resonance is visible at room temperature. Upon lowering the temperature to 270 K, however, a broad resonance can be seen at 120 ppm. These results are discussed in terms of possible sources for this resonance modulation. Binding of low molecular weight inhibitors containing potential metal-coordinating moieties results in the appearance of a sharp 113Cd resonance. These inhibitors all bind to the metal ion, a fact which is reflected in the chemical shift of the cadmium resonance and, for L-phenylalanine phosphoramidate phenyl ester, by two-bond 113Cd-31P spin-spin coupling of 30 Hz in the 31P resonance of the bound inhibitor. For inhibitors that coordinate to the metal ion via oxygen, the 113Cd chemical shift is in the range 127-137 ppm, whereas for sulfur coordination there is a downfield shift of approximately 210 ppm. The complexes of 113Cd-substituted carboxypeptidase A with the D and L isomers of thiolactic acid are distinguished by a difference of 11 ppm in the chemical shift of their cadmium resonances. The enzyme complex formed with the macromolecular inhibitor from potatoes, which fills the S1 and S2 subsites, shows one or possibly two closely spaced broad 113Cd resonances. Both the chemical shift and the line width of the 113Cd resonances of the [113Cd]carboxypeptidase-inhibitor complexes give valuable structural and dynamic information about the enzyme active site.     

Phosphorus-31 nuclear magnetic resonance of double- and triple-helical nucleic acids. Phosphorus-31 chemical shifts as a probe of phosphorus-oxygen ester bond torsional angles

The temperature dependence to the 31P NMR spectra of poly[d(GC)] . poly [d(GC)],d(GC)4, phenylalanine tRNA (yeast) and mixtures of poly(A) + oligo(U) is presented. The 31P NMR spectra of mixtures of complementary RNA and of the poly d(GC) self-complementary DNA provide torsional information on the phosphate ester conformation in the double, triple, and "Z" helix. The increasing downfield shift with temperature of the single-strand nucleic acids provides a measure of the change in the phosphate ester conformation in the single helix to coil conversion. A separate upfield peak (20-60% of the total phosphates) is observed at lower temperatures in the oligo(U) . poly(A) mixtures which is assigned to the double helix/triple helix. Proton NMR and UV spectra confirm the presence of the multistrand forms. The 31P chemical shift for the double helix/triple helix is 0.2-0.5 ppm upfield from the chemical shift for the single helix which in turn is 1.0 ppm upfield from the chemical shift for the random coil conformation.     

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.     

Diastereomeric phosphonate ester adducts of chymotrypsin: 31P-NMR measurements

Generation of diastereomeric phosphonate ester adducts of chymotrypsin was evidenced for the first time by ³¹P NMR and spectrophotometric kinetic measurements. ³¹P NMR signals were recorded for 4-nitrophenyl 2-propyl methylphosphonate (IMN) at 32.2 ppm and for its hydrolysis product at 26.3 ppm downfield from phosphoric acid. The inhibition of α-chymotrypsin at pH > 8.0 by the faster reacting enantiomer of IMN or 2-propyl methylphosphonochloridate (IMCl), or other phosphonate ester analogs of these compounds, all caused a ～6.0 ppm downfield shift of the ³¹P signal to the 39–40 ppm region. IMN, when applied below the stoichiometric amount of chymotrypsin, under the same conditions, generated two signals, at 39.0 and at 37.4 ppm. Scans accumulated in hourly intervals showed the decomposition of both diastereomers, with approximate half-lives of 12 h at pH 8.0 and 22°C, into a species with a resonance at 35.5 ppm. The most likely reaction to account for the appearance of this new peak is the enzymic dealkylation of the isopropyl group from the covalently bound phosphonate ester. We base this conclusion mostly on the similarity of the upfield shift to the hydrolysis of phosphonate esters. Contrary to experience with phosphate ester adducts of serine proteases, no signal was detected higher than 25.0 ppm downfield from phosphoric acid for several phosphonate ester adducts of chymotrypsin and in no case did the resonance for the adduct shift further downfield in the course of the experiments. © 1993 Wiley-Liss, Inc.     

Characterization of the broad resonance in 31P NMR spectra of excised rat brain

31P NMR spectra of excised rat brain showed a broad resonance between-12 and -13 ppm. Subcellular fractions of brain, rich in membranes, exhibited the broad resonance and it was also present in isolated myelin, the major membrane component of brain. However, it was absent in brain cytosol (161,100 X g supernatant). Raising the temperature of the brain above 50 degrees C caused a gradual downfield chemical shift of the broad resonance, to about -1 ppm at 90 degrees C. An even larger downfield shift was produced by halothane or deoxycholate with concomitant narrowing of the line width of this resonance. Vesicles prepared from the phospholipids of excised brain or isolated myelin showed the broad resonance, and halothane produced the same downfield shift and peak sharpening in brain phospholipid vesicles as that in the intact brain. The chemical shift anisotropy was estimated to be 45 ppm for both myelin and the brain, as characteristic for biological membranes. The T1 and T2 relaxation times of the perpendicular 31P chemical shift tensor component of the broad resonance were 0.66 sec and 1.6 msec, respectively, in the same range as those for other biological membranes. Halothane-treatment of the brain increased both the T1 and T2 times considerably, as expected from the disruption of the phospholipid bilayer in a membrane. These data indicate that the broad resonance in the 31P NMR spectrum of excised rat brain originates exclusively from the phosphate head group of membrane bound phospholipids. Similar broad resonances were found in autopsied human brain and porcine spinal cord and to a lesser extent in excised rat liver and kidney.     

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.