Orotate phosphoribosyltransferase and hypoxanthine/guanine phosphoribosyltransferase from yeast: kinetic analysis with chromium (III) pyrophosphate.

The reactions catalyzed by orotate phosphoribosyltransferase (OPRTase) and hypoxanthine/guanine phosphoribosyltransferase (HGPRTase) from yeast differ in the kinetic mechanisms by which they are activated by divalent metal ions. Moreover, whereas OPRTase is activated specifically by Mg(II) or Mn(II), the reactions catalyzed by HGPRTase can utilize a wider range of divalent metal ions, including Mg(II), Mn(II), Co(II), and Zn(II). In this report we describe the results of a kinetic analysis of the effects of the addition of Cr(III) pyrophosphate (Cr-PPi) to the OPRTase and HGPRTase assay solutions, which delineates further the differences between these enzyme activations by metal ions. (1) Cr-PPi is an effective competitive inhibitor of the OPRTase catalysis, when the steady-state forward velocity of orotidine monophosphate (OMP) formation is examined over a range of phosphoribosyl alpha-pyrophosphate (PRibPP) concentrations, whereas pyrophosphate (PPi) has been reaffirmed to be a noncompetitive product inhibitor under the same conditions. (2) Cr-PPi itself serves as a substrate for the OPRTase-catalyzed reverse pyrophosphorolysis of OMP and does not inhibit the utilization of PPi as substrate during this reaction. (3) In contrast, Cr-PPi, at concentrations as high as 6 mM, has no effect on the HGPRTase-catalyzed formation of inosine monophosphate, whereas the inhibition exhibited by PPi during this reaction is noncompetitive but defined by two sets of lines in the double reciprocal plot of the initial velocity versus 1/PRibPP. (4) Cr-PPi is not a substrate for the HGPRTase-catalyzed pyrophosphorolysis of IMP under the conditions of these assay procedures.

Activation of hypoxanthine/guanine phosphoribosyltransferase from yeast by divalent zinc and nickel ions.

We have observed previously that the reactions catalyzed by hypoxanthine/guanine phosphoribosyltransferase (HGPRTase) are activated by Mg(II), Mn(II), and Co(II), and we have defined the mechanism by which these activations proceed [Biochemistry 22, 3419-3424 (1983)]. A more extensive survey of the kinds of metal ions that will activate the HGPRTase catalysis now has been completed through the use of an HPLC assay procedure. Although Fe(II) and Ca(II) are unable to activate this reaction, a significant activation was achieved with the addition of spectroscopically pure Zn(II) to the assay solution. In addition some IMP synthesis resulted from the addition of Ni(II) to the assay mixture. Both the Zn(II) and Ni(II) kinetic effects on HGPRTase over a limited metal ion concentration range have been analyzed through the use of curve-fitting exercises. These results, in addition to the similar pH profiles for the activations by Mg(II), Mn(II), Co(II), and Zn(II), suggest that all of these metal ions activate the HGPRTase-catalyzed synthesis of IMP by way of the same mechanism [model II as defined by London and Steck, Biochemistry 8, 1767-1779 (1969)], during which two divalent ions bind to the HGPRTase active site per molecule of PRibPP.

Enzymatic coupled assay procedures that employ high-performance liquid chromatography: the synthesis of orotidylate from ribose.

High-performance liquid chromatographic assay procedures have been designed to monitor the catalytic activities of ribokinase and phosphoribosyl alpha-1-pyrophosphate (PRibPP) synthetase. These methods are only of qualitative value, when crude protein extracts are to be examined, because of the presence of myokinase. However, the product of the PRibPP synthetase reaction, can be detected quantitatively even in crude protein extracts through the addition of two enzymes (orotate phosphoribosyltransferase and inorganic pyrophosphatase) that catalyze the conversion of PRibPP into a spectroscopically detectable nucleotide product (orotidylate).

Enzymatic kinetic analyses that employ high-performance liquid chromatography. Competition between orotate- and hypoxanthine/guanine-phosphoribosyltransferases for a common substrate.

Enzymatic assay procedures that employ high-performance liquid chromatography (HPLC) have been proven to be sensitive and versatile methods for accomplishing kinetic analyses of enzyme-catalyzed reactions, with nucleotides as substrates or products. Both orotate phosphoribosyltransferase (OPRTase) and hypoxanthine/guanine phosphoribosyltransferase (HGPRTase) have been purified from Baker's yeast and analyzed kinetically using a modification of published HPLC procedures. Because these two enzymes exist in the cytosol of yeast and might compete for the limiting (approximately equal to 15 microM) concentration of phosphoribosyl alpha-1-pyrophosphate (PRibPP), we elected to examine both equilibrium and steady-state effects of one enzymatic reaction on the other with HPLC. First, under the condition of equivalent mass concentrations of OPRTase and HGPRTase, the initial rate of orotidine monophosphate synthesis and the equilibrium state were greatly affected by the presence of HGPRTase activity. In contrast, the presence of the OPRTase activity had no effect on the HGPRTase-catalyzed reaction under these conditions. Second, to examine a competition by these enzymes for PRibPP in vivo, we have established that the total activities (units/ml) of OPRTase and HGPRTase in yeast cell extracts were 740 units/ml and 450 units/ml, respectively (a 1.7:1 ratio). These relative activities were then employed in an in vitro reaction competition analysis. The results were similar to the those obtained from experiments where equivalent OPRTase and HGPRTase activities were employed and reveal profound initial velocity and equilibrium effects of one reaction on the other. Thus a real competition between these enzymes for PRibPP may occur in the yeast cell cytosol, as determined by this unique HPLC competition assay procedure.

Nuclear magnetic relaxation studies of the conformation of adenosine 5'-triphosphate on pyruvate kinase from rabbit muscle.

The conformation of adenosine 5'-triphosphate in the manganese complex of pyruvate kinase from rabbit muscle was determined from six metal to nucleus distances derived by nuclear magnetic relaxation techniques. On the enzyme, no direct metal-ATP coordination exists. The phosphorous atoms of ATP are 4.9 to 5.1 A away from manganese, a distance which indicates either a predominantly (greater than or equal to 94%) second sphere complex or, less likely, a highly distorted inner sphere complex. Thus, water ligands or ligands from the protein might intervene between the ATP molecule and the divalent metal ion and facilitate their interaction. The metal-gammaP distance of 5 A for pyruvate kinase-bound ATP is equal to that found for the phosphorous atom of phosphoenolpyruvate and cobalt(II) on pyruvate kinase (Melamud, E., and Mildvan, A. S. (1975) J. Biol. Chem. 250, 8193-8201), which is consistent with the overlap in space of the P-enolpyruvate-phosphorus and the gammaP of ATP at the active site. This observation explains the competitive binding of these two substrates to the enzyme, as detected by NMR and by early kinetic studies. From the phosphorus data and from measurements of the relaxation rates of 3 protons of ATP in the pyruvate kinase-metal-ATP complex, the conformation of ATP was characterized as extended with distances of 6.0, 9.1, and 7.5 A from manganese to the H8, H2, and H'1 protons, respectively. The torsion angle about the glycosidic bond (chi) which defines the conformation of the enzyme-bound riboside and adenine rings was determined to be 30 degrees. In contrast, the conformation of the binary Mn(II)-ATP complex in solution is folded around the metal with direct manganese coordination of the alpha-, beta-, and gamma-phosphorus atoms, and with metal to proton distances of 4.5, 6.4, and 6.2 A for the H8, H2, and H'1 protons, suggesting a second sphere manganese-adenine interaction. The chi angle equals 90 degrees for the binary complex primarily because of the metal-base interaction. Thus, a profound change in the conformation and structure of Mn(II)-ATP from a folded chelate to an extended second sphere complex results when the nucleotide binds to pyruvate kinase.

Studies of the kinetic mechanism of hypoxanthine-guanine phosphoribosyltransferase from yeast.

An assay procedure, utilizing high pressure liquid chromatography, has been designed which allows both reactions catalyzed by hypoxanthine-guanine phosphoribosyltransferase to be monitored simultaneously. Using this procedure and the theories described by Huang (Huang, C. V. (1979) Methods. Enzymol. 63, 486-500) for alternate substrate kinetic analysis, we have determined that purified hypoxanthine-guanine phosphoribosyltransferase from yeast catalyzes the formations of both IMP and GMP through the use of an Ordered Bi Bi kinetic mechanism, and that guanine is highly preferred over hypoxanthine as substrate in the forward reaction. This proposed kinetic mechanism has been confirmed using flow dialysis experiments in which a binary enzyme-5-phosphoribosyl-alpha-1-pyrophosphate complex was characterized but where enzymic complexes, with either guanine or hypoxanthine, were not detected. Also consistent with this kinetic mechanism was our observation that an exchange of label between [14C]guanine or [14C]hypoxanthine and their respective nucleotides (GMP and IMP) was not catalyzed by hypoxanthine-guanine phosphoribosyltransferase. However, a significant exchange of label between [32P]pyrophosphate and 5-phosphoribosyl-alpha-1-pyrophosphate is observed upon incubation with this enzyme, suggesting that hypoxanthine-guanine phosphoribosyltransferase may exist, in part, as a phosphoribosyl-enzyme complex in the presence of 5-phosphoribosyl-alpha-1-pyrophosphate.

Purification and characterization of nicotinamide deamidase from yeast.

Nicotinamide deamidase (YNDase) has been purified from yeast through the use of a six-step procedure that includes molecular-sieve high performance liquid chromatography. The final preparation was homogeneous by the criteria of sodium dodecyl sulfate-gel electrophoresis, and the enzyme specific activity was determined to be 175 mumol of nicotinate formed per min/mg enzyme. Gel electrophoresis and molecular-sieve high performance liquid chromatography were employed also to characterize YNDase as a monomeric protein with a molecular weight of 34,000. A Km value for nicotinamide of 33 microM was determined for the deamidase activity at pH 6, and a pH range for optimal stability of 6-8.5 was established for this enzyme. The YNDase activity was also examined over a pH range at several substrate concentrations and both the log Vmax and log Vmax/Km plots versus pH suggested that a protonated amino acid residue with an apparent pKb value of 7.8 was essential to this activity. During an in vitro assay of the YNDase-catalyzed formation of nicotinate, ammonia was generated and detected chemically. Inhibition of the YNDase activity by nicotinaldehyde suggested the presence of either an essential lysine (Schiff's base formation) or cysteine residue (thiohemiacetal intermediate) at the YNDase active site. The relatively large value of the nicotinaldehyde inhibition constant (Ki = 68 microM), the observation that this analogue is a noncompetitive inhibitor of nicotinate formation, and the fact that this inhibition can be rendered irreversible through incubation with sodium borohydride, indicates that a Schiff's base intermediate is more likely to occur upon incubation of YNDase with nicotinaldehyde. However, YNDase is inactivated completely and irreversibly by N-ethylmaleimide at pH 6, and the enzyme is protected against this modification by either nicotinamide or nicotinate. These results suggest that both nicotinate and nicotinamide bind to YNDase, even though the enzymatic reaction is essentially irreversible, and that a cysteine residue may be present at the YNDase active site.

Conformation of deoxynucleoside triphosphate substrates on DNA polymerase I from Escherichia coli as determined by nuclear magnetic relaxation.

A unique conformation of deoxynucleoside triphosphate substrates bound to Escherichia coli DNA polymerase I has been determined by nuclear magnetic resonance techniques. The effects of Mn(II) bound at the active site of the enzyme on the longitudinal (T1p-1) and transverse (T2p-1) relaxation rates of the alpha, beta, and gamma phosphorus atoms and 5 protons of enzyme-bound thymidine 5'-triphosphate (dTTP) were measured at 40.5 MHz (31P), 100 and 220 MHz (1H). From frequency dependence of T1p-1, a correlation time of 7 X 10(-10) s and Mn(II) to proton distances of 10.4, 9.9, 10.3, 10.8, and 8.4 A were calculated for the --CH3, H6, H'1, H'2, and H'4 protons. The calculated Mn(II) to phosphorus distances of 4.2, 4.8, and 3.2 A for the alpha, beta, and gamma phosphorus atoms indicates that Mn(II) corrdinates directly only with the gamma-phosphoryl group and that a puckered triphpsphate conformation exists for the enzyme-bound dTTP. This differs from the binary Mn(II)-dTTP complex in which alpha, beta, and gamma phosphoryl coordination occurs, and a thymine-deoxyribose torsion angly (chi) about the glycosidic bond of 40 degrees is detected. The eight manganese-substrate distances on the enzyme are fit by a unique Mn-dTTP conformation, with a torsion angle equal to 90 degrees, indistinguishable from that found for a deoxynucleotidyl unit in double helical DNA-B. Hence, binding to DNA polymerase appears to adjust the conformation of dTTP for Watson-Crick basepairing. Similarly, the binding of Mn-dATP to DNA polymerase I increased the distances from Mn(II) to the H2, H8, H'1, and H'4 protons of dATP but the adenine-deoxyribose torsion angle of 90 degrees was preserved. Such preorientation of substrates could facilitate incorporation of the complementary nucleotide. When positioned within the DNA structure, the conformation of enzyme-bound Mn-dTTP requires an inline nucleophilic attack on the alpha phosphorus with Mn(II) promoting pyrophosphate departure.

Nuclear magnetic resonance studies of substrate interaction with cobalt substituted alcohol dehydrogenase from liver.

The role of zinc in liver alcohol dehydrogenase has been studied by replacement of 1.3 and 3.5 of the four Zn(II) ions with Co(II) and measuring the effects of the paramagnetic Co(II) on the relaxation rates of the protons of water, ethanol, and isobutyramide. Water relaxation studies at 8, 24, 100, and 220 MHz indicate two classes of bound Co(II). The similar to 2 readily replaced Co(II) ions retain one fast exchanging water proton in their inner coordination spheres, while the similar to 2 slowly exchanging Co(II) ions coordinate no detectable water protons, indicating that the former replaced Zn(II) at the "catalytic sites" and the latter replaced Zn(II) at the "structural sites" detected crystallographically. Ethanol, acetaldehyde, and isobutyramide bind with appropriate affinities to the Co(II) substituted alcohol dehydrogenases decreasing the number of fast exchanging protons at the catalytic Co(II) site by greater than or equal to 54 percent. Coenzyme binding causes smaller changes in the water relaxation rate which may be due to local conformation changes. The paramagnetic effects of Co(II) at the catalytic site on the relaxation rates of the methyl protons of isobutyramide at 100 and 220 MHz indicate that this analog binds at a site 9.1 A from the catalytic Co(II). This distance decreases to 6.9 A when NADH is bound, and a Co(II) to methyne proton distance of 6.6 A is determined indicating a conformation change leading to the formation of a second sphere enzyme-Co(II)-isobutyramide complex in which a hydroxyl or water ligand intervenes between the metal and the substrate analog. Similar behavior is observed in the enzyme-ethanol complexes. The paramagnetic effects of Co(II), at the catalytic site, on the relaxation rates of the protons of ethanol at 100 and 220 MHz, indicate that this substrate bind at a site 12-14 A distant from the catalytic Co(II) but that this distancedecreases to 6.3 A in the abortive enzyme-NADH-ethanol complex. The role of the catalytic Co(II) thus appears to be the activation of a hydroxyl or water ligand which polarizes the aldehyde carbonyl group by hydrogen bonding. The role of the structural Co(II), which is more distant from isobutyramide (9-11 A), may be that of a template for protein conformation changes. By combining the present distances with those from previous magnetic resonance studies on the liver enzyme, the arrangement of coenzyme, metal, and substrate at the active site in solution can be constructed. This arrangement is consistent with that of ADP-ribose and zinc in the crystalline complex of liver alcohol dehydrogenase as determined by X-ray crystallography (Branden et al., (1973), Proc. Natl. Acad. Sci. U.S.A.70, 2439).

Kinetic analysis of nicotinate phosphoribosyltransferase from yeast using high pressure liquid chromatography.

A new procedure has been designed for the purification of nicotinate phosphoribosyltransferase and orotate phosphoribosyltransferase from the same baker's yeast extract. Using purified nicotinate phosphoribosyltransferase, the enzyme-catalyzed formation of nicotinate mononucleotide was analyzed using a new high pressure liquid chromatographic assay (Hanna, L., and Sloan, D. L. (1980) Anal. Biochem. 103, 230-234). Initial velocity measurements and product inhibition studies, with pyrophosphate, were performed. In addition, this assay procedure was used to demonstrate that purified nicotinate phosphoribosyltransferase possesses an ATPase activity in the presence of either product (pyrophosphate or nicotinate mononucleotide (NaMN] but in the absence of 5-phosphoribosyl alpha-1-pyrophosphate (P-Rib-PP). Moreover, exchanges of radioactivity between specific substrate/product pairs [( 14C]nicotinate/NaMN and [32P]PPi/P-Rib-PP) in the absence of other substrates were not observed when these pairs were incubated with nicotinate phosphoribosyltransferase, and binding of [14C] nicotinate to nicotinate phosphoribosyltransferase was not detected in the presence of ATP. In contrast, an exchange of label between ATP and [14C]ADP was characterized in the absence of other substrates and in the presence of either P-Rib-PP or PPi. These results indicate that nicotinate phosphoribosyltransferase proceeds through the use of an ordered Uni Uni Bi Ter Ping Pong kinetic mechanism during which ATP reacts with nicotinate phosphoribosyltransferase to form ADP and a previously described phosphorylated enzyme (Kosaka, A., Spivey, H. O., and Gholson, R. K. (1977) Arch. Biochem. Biophys. 179, 334-341). Thereafter, P-Rib-PP and nicotinate bind in order to the active site, to produce PPi and NaMN which are released in a random order followed by Pi. The Km values for ATP, P-Rib-PP, and nicotinate were calculated to be 70 +/- 10, 24 +/- 3, and 23 +/- 4 microM, respectively, whereas a value for Ki(PRPP) of 5 +/- 1 microM was determined.

Orotate phosphoribosyltransferase and hypoxanthine/guanine phosphoribosyltransferase from yeast: nuclear magnetic relaxation studies of the structures of enzyme-bound phosphoribosyl 1-pyrophosphate.

Nuclear magnetic relaxation rate measurements have been performed on the protons and phosphorus atoms of phosphoribosyl 1-pyrophosphate (PRibPP) in the presence and absence of paramagnetic chromium(III), cobalt(II), and manganese(II) ions. The longitudinal relaxation rates were then used to calculate interatomic distances between the magnetic nuclei and these paramagnetic probes, from which was devised a conformation of the PRibPP-metal ion complex in solution. Thereafter, the experiments were accomplished in the presence of Mn(II) and a series of orotate phosphoribosyltransferase (OPRTase) and hypoxanthine/guanine phosphoribosyltransferase (HGPRTase) concentrations, and from these data were estimated the distances between Mn(II) and the PRibPP nuclei at the active sites of these two enzymes from yeast. Comparisons between the Mn(II)-PRibPP conformation in solution and this structure at the active sites of OPRTase and HGPRTase revealed that the metal ion remained coordinated with the pyrophosphate group of PRibPP in all instances, whereas the overall distances between the ribose ring and Mn(II) at the enzyme active sites were approximately 1 A further from the metal ion. Model building studies also revealed that the 5'-phosphate group of PRibPP is positioned directly over the ribose ring in solution and at the OPRTase and HGPRTase active sites and may protect the 1'-carbon of PRibPP against on-line displacements of pyrophosphate under these conditions, where the PRibPP-to-Mn(II) concentration ratio is greater than 2000.(ABSTRACT TRUNCATED AT 250 WORDS)

Orotate phosphoribosyltransferase from yeast: studies of the structure of the pyrimidine substrate binding site.

The pH dependencies of both the forward and reverse orotate phosphoribosyltransferase (ORPTase)-catalyzed reactions have been examined and determined to be dissimilar, with maximal activity for the forward reaction near to pH 8. The maximal activity of the reverse pyrophosphorolysis was observed between pH 6.5 and 7.5. Appropriate pK values were determined using computer fitting exercises. One such pK value (equal to 8.6) suggested the presence of lysine residues at the OPRTase active site. Incubations of OPRTase with the substrate analog, uracil 6-aldehyde, in the presence of sodium borohydride, suggested that this compound is a covalent modifier of OPRTase lysine residues, and substrate protection studies provided evidence that the affected lysine residues were located near to both the phosphoribosyl 1-pyrophosphate (PRibPP) and the orotate binding sites. Similar studies with pyridoxal 5-phosphate and labeled sodium borohydride as modifiers have revealed that two modified active site lysine residues per OPRTase subunit account for the loss of 90% of the enzymatic activity with this reagent. We suggest that essential lysine residues, along with divalent metal ions, are located at the OPRTase active site, and form ion-pair bonds with anionic PRibPP and orotate as these substrates bind to the enzyme. We also report that 5-azaorotate is an alternate substrate for OPRTase (Km = 75.5 +/- 0.1 microM) leading to formation of an unstable nucleotide product).

Enzymatic assay procedures that employ high-performance liquid chromatography: competition between phosphoribosyltransferases for a common substrate.

A survey of the phosphoribosyltransferase (PRTase) activities in yeast has been accomplished using reversed-phase high-performance liquid chromatographic assay procedures. The following bases were observed to be utilized during phosphoribosyl pyrophosphate (PRibPP)-dependent nucleotide syntheses: adenine, xanthine, hypoxanthine, guanine, uracil, orotate, nicotinamide, nicotinate and quinolinate. Gradient elution procedures have also been perfected that allow the separation of the two following sets of PRTase assay components: (1) adenosine monophosphate, nicotinate mononucleotide, orotate, adenosine triphosphate, nicotinate, adenosine diphosphate, inosine monophosphate and hypoxanthine, and (2) nicotinate mononucleotide, nicotinamide mononucleotide, adenosine triphosphate, nicotinate, adenosine diphosphate and nicotinamide. Separation 1 has been employed to examine the PRibPP allocation among the hypoxanthine PRTase, orotate PRTase and nicotinate PRTase catalyzed reactions, whereas separation 2 has been employed to define the role that ATP plays in the nicotinamide PRTase-catalyzed reaction along with the allocation of nicotinamide between the reactions catalyzed by nicotinamide PRTase and nicotinamide deamidase.

Arrangement and conformations of substrates at the active site of pyruvate kinase from model building studies based on magnetic resonance data.

Seventeen distances from two paramagnetic reference points, as determined by nuclear relaxation studies of six active complexes of rabbit muscle pyruvate kinase, have been used to construct molecular models of two composite enzyme complexes. In the model of the hypothetical pyruvate kinase-M(I)-M(II)-ATP-Cr(III)-P-enolpyruvate complex, overlap of the transferred phosphoryl groups of the two substrates, which is required to explain the observed competition, is incomplete, allowing greater than or equal to 1 A for the transition state to form. In the active enzyme-M(I)-M(II)-ATP-Cr(III)-pyruvate complex, the gamma-phosphoryl phosphorus of ATP is in molecular contact (3.0 +/- 0.5 A) with the carbonyl oxygen of pyruvate, consistent with direct phosphoryl transfer, indicating no need for intermediate phosphorylation of the enzyme. The enzyme-bound divalent cation, which forms second sphere complexes with the phosphoryl groups of P-enolpyruvate and ATP, may activate the transferred phosphoryl group indirectly, through a water ligand. By analogy with the position of Cr(III), a second divalent cation may participate more directly by coordination of the triphosphate chain of ATP.

Raman study of reduced nicotinamide adenine dinucleotide bound to liver alcohol dehydrogenase.

We report the first Raman spectra of reduced nicotinamide adenine dinucleotide (NADH) when bound to an enzymatic active site, that of liver alcohol dehydrogenase (LADH). This was obtained by subtracting the Raman spectrum of LADH from that of the binary LADH/NADH complex. There are significant changes in the spectrum of bound NADH as compared to that in solution. The data indicate that both the nicotinamide moiety and the adenine moiety are involved in the binding. At least one of the two NH2 moieties of NADH also participates.

Raman spectroscopy of liver alcohol dehydrogenase.

We report the Raman spectrum of liver alcohol dehydrogenase in solution. The enzyme's secondary structure as determined from an examination of the Raman bands is slightly different than that found in crystals by X-ray diffraction.

Raman spectroscopy of oxidized and reduced nicotinamide adenine dinucleotides.

We have measured the Raman spectra of oxidized nicotinamide adenine dinucleotide, NAD+, and its reduced form, NADH, as well as a series of fragments and analogues of NAD+ and NADH. In addition, we have studied the effects of pH as well as deuteration of the exchangeable protons on the Raman spectra of these molecules. In comparing the positions and intensities of the peaks in the fragment and analogue spectra with those of NADH and NAD+, we find that it is useful to consider these large molecules as consisting of component parts, namely, adenine, two ribose groups, two phosphate groups, and nicotinamide, for the purpose of assigning their spectral features. The Raman bands of NADH and NAD+ are found generally to arise from molecular motions in one or another of these molecular moieties, although some peaks are not quite so easily identified in this way. This type of assignment is the first step in a detailed understanding of the Raman spectra of NAD+ and NADH. This is needed to understand the binding properties of NADH and NAD+ acting as coenzymes with the NAD-linked dehydrogenases as deduced recently by using Raman spectroscopy.