Metabolism of Pyridine Coenzymes in Microorganisms

NADP and NADP analog were phosphorylated to NAD diphosphate and NADP analog phosphate, respectively, by an enzyme preparation of Proteus mirabilis (IFO 3849). The degradation products from NAD-diphosphate and NADP analog phosphate by the snake venom nucleotide pyrophosphatase were identical with nicotinamide riboside diphosphate and adenosine 2′(3′), 5′-diphosphate.     

Distribution and Properties of NAD Phosphorylating Reaction

Distribution of NAD phosphorylating reactions, phosphorylation through NAD kinase and phosphotransferase, was investigated. NAD kinase activity was distributed rather widely in bacteria, whereas phosphotransferase activity with p-NPP and NAD was limited to a few genera. Proteus mirabilis showed strong activity of phosphotransferase besides NAD kinase activity.

Partial purification of the phosphotransferase was attempted. The enzyme preparation possessed phosphatase activity as well as phosphotransferase activity. Phosphorylation of NAD proceeded maximally under the conditions below pH 4.0. Cu²⁺ showed stimulating effect on the activity. Besides p-NPP and phenylphosphate, various nucleotides, especially 2′ (or 3′) isomers, served as excellent phosphoryl donors, and various kinds of nucleosides and nucleotides were phosphorylated to form nucleoside monophosphates and nucleoside diphosphates.     

Dehalogenation and Deamination of l-2-Amino-4-chloro-4-pentenoic Acid by Proteus mirabilis

Eighty-one strains of bacteria were tested for their ability to catalyze the release of chloride ion from Dl-2-amino-4-chloro-4-pentenoic acid. A dehalogenating enzyme was obtained from the cells of Proteus mirabilis IFO 3849, which can use the l-isomer. The enzyme was constitutively produced. The conversion of l-2-amino-4-chloro-4-pentenoic acid to 2-keto-4-pentenoic acid, ammonia, and chloride ion was demonstrated. The reaction product, 2-keto-4-pentenoic acid, was isolated as its 2,4-dinitrophenylhydrazone and identified by catalytic hydrogenolysis of the hydrazone to the corresponding amino acid, norvaline.     

Studies on Metabolic Pathway of NAD in Yeast

Quantitative studies on yeast 5′-nucIeotidase are presented.

K_m values for purine 5′-nucleotides were generally smaller than those for pyrimidine 5′-nucleotides and, among purine series, K_m value for 5′-AMP was the smallest, while their V values were almost same.

The enzyme activity was inhibited in the competitive type by bases, nucleosides, 3′- or 2′-nucleotides, and NMN and in the mixed type by NAD and NADP.

Base-, ribose-, 3′- or 5′-phosphate moiety of nucleoside and nucleotide had some effects on binding with enzyme; especially the structure of base moiety characterizes the K_m or K_i value.

The enzyme activity was accelerated by Ni⁺⁺ or Co⁺⁺, which increases V value but never affects K_m value.

The relationship between the structure of substrate and its affinity towards enzyme is discussed.     

Isocitrate Dehydrogenases and NADP-Alcohol Dehydrogenase of Euglena gracilis var. bacillaris*

SYNOPSIS. Nicotinamide adenine dinucleotide phosphate (NADP) and nicotinamide adenine dinucleotide (NAD) linked isocitrate dehydrogenase and NADP linked alcohol dehydrogenase have been detected in Euglena gracilis var. bacillaris. The NADP isocitrate dehydrogenase showed half-maximal activity at a concentration of 3 × 10^?5 M DL-isocitrate, but did not follow simple Michaelis-Menten kinetics with respect to substrate concentration. The optimal NADP concentration was about 0.06 mM, and activity fell off sharply on either side of this optimum. Fresh preparations of the enzyme migrated as single bands in disc electrophoresis, but two enzymatically active bands were present after frozen storage. The NAD isocitrate dehydrogenase followed Michaelis-Menten kinetics with respect to substrate. In crude extracts, no requirement for adenosine monophosphate, adenosine diphosphate, or sulfhydryl compounds could be found. NADP alcohol dehydrogenase activity could be found with either ethanol or propanol as substrate. Low concentrations of coenzyme A were moderately inhibitory. In tris(hydroxymethyl) aminomethane buffer (tris buffer), Euglena extracts reduced NAD slowly in the absence of exogenous substrate. In the absence of tris, no such reduction occurred. A similar phenomenon was observed with NADP.     

Interactions of nicotinamide-adenine dinucleotide phosphate analogues and fragments with pigeon liver malic enzyme. Synergistic effect between the nicotinamide and adenine moieties.

The structural requirements of the NADP+ molecule as a coenzyme in the oxidative decarboxylation reaction catalysed by pigeon liver malic enzyme were studied by kinetic and fluorimetric analyses with various NADP+ analogues and fragments. The substrate L-malate had little effect on the nucleotide binding. Etheno-NADP+, 3-acetylpyridine-adenine dinucleotide phosphate, and nicotinamide-hypoxanthine dinucleotide phosphate act as alternative coenzymes for the enzyme. Their kinetic parameters were similar to that of NADP+. Thionicotinamide-adenine dinucleotide phosphate, 3-aminopyridine-adenine dinucleotide phosphate, 5'-adenylyl imidodiphosphate, nicotinamide-adenine dinucleotide 3'-phosphate and NAD+ act as inhibitors for the enzyme. The first two were competitive with respect to NADP+ and non-competitive with respect to L-malate; the other inhibitors were non-competitive with NADP+. All NADP+ fragments were inhibitory to the enzyme, with a wide range of affinity, depending on the presence or absence of a 2'-phosphate group. Compounds with this group bind to the enzyme 2-3 orders of magnitude more tightly than those without this group. Only compounds with this group were competitive inhibitors with respect to NADP+. We conclude that the 2'-phosphate group is crucial for the nucleotide binding of this enzyme, whereas the carboxyamide carbonyl group of the nicotinamide moiety is important for the coenzyme activity. There is a strong synergistic effect between the binding of the nicotinamide and adenosine moieties of the nucleotide molecule.     

NAD kinase from Bacillus licheniformis: inhibition by NADP and other properties

NAD kinase was purified 180-fold from Bacillus licheniformis to determine the role it plays in NADP turnover in this organism. The enzyme was found to have a pH optimum of 6.8 and an apparent K _m for NAD of 2.7 mM. The ATP saturation curve was not hyperbolic; 5.5 mM ATP was required to reach half maximal activity. Both Mn²⁺ and Ca²⁺ could be substituted for Mg²⁺. Several compounds including nicotinic acid, nicotinamide, nicotinamide mononucleotide, quinolinic acid, NADPH, ADP, AMP and cyclic AMP did not affect NAD kinase activity. In contrast, the enzyme was inhibited by NADP at concentrations typically found in logarithmic cells of B. licheniformis. This inhibition was competitive with NAD and had a K _i of 0.13 mM. It is suggested that in vivo NAD kinase activity is highly dependent on the concentrations of NAD and ATP and the proportion of oxidized and reduced NADP.This paper is dedicated to Sydney C. Rittenberg on the occassion of his retirement, with respect and much affection, in appreciation for his friendship and years of distinguished service as a teacher and scientist     

Alteration of Coenzyme Specificity of Lactate Dehydrogenase from Thermus thermophilus by Introducing the Loop Region of NADP(H)-Dependent Malate Dehydrogenase

Previously we found that replacement of seven amino acid residues in a loop region markedly shifted the coenzyme specificity of malate dehydrogenase from NAD(H) toward NADP(H). In the present study, we replaced the seven amino acid residues in the corresponding region of an NAD(H)-dependent lactate dehydrogenase with those of NADP(H)-dependent malate dehydrogenase, and examined the coenzyme specificity of the resulting mutant enzyme. Coenzyme specificity was significantly shifted by 399-fold toward NADPH when k _cat?K _m ^coenzyme was used as the measure of coenzyme specificity. The effect of the replacements on coenzyme specificity is discussed based on in silico simulation of the three-dimensional structure of the lactate dehydrogenase mutant.     

Induction and Regulation of a Nicotinamide Adenine Dinucleotide-Specific 6-Phosphogluconate Dehydrogenase in Streptococcus faecalis

Streptococcus faecalis grown with glucose as the primary energy source contains a single, nicotinamide adenine dinucleotide phosphate (NADP)-specific 6-phosphogluconate dehydrogenase. Extracts of gluconate-adapted cells, however, exhibited 6-phosphogluconate dehydrogenase activity with either NADP or nicotinamide adenine dinucleotide (NAD). This was shown to be due to the presence of separate enzymes in gluconate-adapted cells. Although both enzymes catalyzed the oxidative decarboxylation of 6-phosphogluconate, they differed from one another with respect to their coenzyme specificity, molecular weight, pH optimum, K(m) values for substrate and coenzyme, and electrophoretic mobility in starch gels. The two enzymes also differed in their response to certain effector ligands. The NADP-linked enzyme was specifically inhibited by fructose-1,6-diphosphate, but was insensitive to adenosine triphosphate (ATP) and certain other nucleotides. The NAD-specific enzyme, in contrast, was insensitive to fructose-1,6-diphosphate, but was inhibited by ATP. The available data suggest that the NAD enzyme is involved primarily in the catabolism of gluconate, whereas the NADP enzyme appears to function in the production of reducing equivalents (NADPH) for use in various reductive biosynthetic reactions.     

Use of a bisubstrate inhibitor to distinguish between isocitrate dehydrogenase isozymes

Bisubstrate inhibitors, obtained by covalently linking 2-oxoglutarate with NAD+ and NADP+, were synthesized and tested for their ability to inhibit NAD+- and NADP+-dependent isocitrate dehydrogenases from pig heart mitochondria. The NADP+-dependent enzyme was specifically inhibited by the NADP oxoglutarate adduct and not by the NAD adduct. The NADP adduct was competitive with both coenzyme and substrate, isocitrate. In contrast, the NAD+-dependent enzyme was inhibited by both adducts. NAD oxoglutarate is competitive with both NAD+ and isocitrate while the NADP adduct is competitive with isocitrate but not with NAD+. Nevertheless conditions could be set up so that use of these inhibitors would be feasible for a metabolic study.     

Studies on the Metabolism of Pantothenic Acid in Microorganisms

The ability of the formation of coenzyme A from pantothenic acid and cysteine in the presence of AMP or ATP was searched in yeasts and bacteria. The result of screening showed that the activity was found in several yeasts and the bacteria belonging to the genera Sarcina, Corynebacterium and Brevibacterium. Particularly, Brevibacterium ammoniagenes IFO 12071 (ATCC 6871) accumulated a large amount of coenzyme A.

Isolation of the reaction products, which were synthesized by Brevibacterium ammoniagenes IFO 12071, were carried out. The isolates were identified as coenzyme A, dephosphocoenzyme A and phosphopantothenic acid.

The possibility for the formation of coenzyme A in a larger amount from pantothenic acid and cysteine was investigated with baker’s yeast under the condition coupled with ATP-generating system.

Effect of various factors affecting the accumulation of coenzyme A was investigated. Among them, glucose concentration and inorganic phosphorus concentration were the most important factors for its accumulation. Coenzyme A was not accumulated without the phosphorylation of AMP to ATP. Several cationic surfactants stimulated the accumulation of coenzyme A.

The amount of coenzyme A accumulated reached about 200 μg per ml of the reaction mixture under the suitable reaction conditions employed.     

Occurrence of meso-alpha, epsilon-diaminopimelate dehydrogenase in Bacillus sphaericus.

A new amino acid dehydrogenase catalyzing the oxidative deamination of meso-α,?-diaminopimelate was found in the crude extract of Bacillus sphaericus IFO 3525. This dehydrogenase requiring NADP was specific for meso-diaminopimelate and the other isomers were not substrates. The enzyme was optimally active at about pH 10.5. NAD could not replace NADP.     

Binding of coenzyme and substrate and coenzyme analogues to 6-phosphogluconate dehydrogenase from sheep liver. An X-ray study at 0.6 nm resolution.

The analogues of the coenzyme NADP+, nicotinamide--8-bromo-adenine dinucleotide phosphate (Nbr8ADP+) and 3-iodopyridine--adenine dinucleotide phosphate (io3PdADP+), were prepared. Nbr8ADP+ was found to be active in the hydrogen transfer adn io3PdADP+ is a coenzyme competitive inhibitor for 6-phosphogluconate dehydrogenase. The binding of NADP+, NADPH and NADPH together with 6-phosphogluconate as well as that of both analogues to crystals of the enzyme 6-phosphogluconate dehydrogenase has been investigated at 0.6-nm resolution using difference electron density maps. The molecules bind in a similar position in a cleft in the enzyme subunit distant from the dimer interface. The orientation of the coenzyme in the site has been determined from the io3PdADP+ -NADP+ difference density. The ternary complex difference density extends beyond that of the nicotinamide moiety of the coenzyme and tentatively indicates substrate binding. No clear identification of the bromine atom of Nbr8ADP+ can be made. However, the analogue is bound more deeply in the cleft than is NADP+. The NADPH density is the most clearly defined and has thus been used to fit a molecular model using an interactive graphics system, checking for preferred geometry. A possible conformation is presented which is significantly different from that of NAD+ in the lactate dehydrogenase ternary complex.     

Association of NADP- and NAD-linked malic enzyme acitivities in Zea mays: relation to C4 pathway photosynthesis.

Two of the three metabolic subtypes of species utilizing C₄-pathway photosynthesis are defined by high activities of either NADP malic enzyme (NADP malic enzyme type) or a coenzyme A (CoA)- and acetyl-CoA-activated NAD malic enzyme (NAD malic enzyme type). These enzymes function to decarboxylate malate as an integral part of the photosynthetic process. Leaves of NADP malic enzyme-type species also contain significant NAD-dependent malic enzyme activity. The purpose of the present study was to examine the nature and photosynthetic role of this activity. With Zea mays, this NAD-dependent activity was found to vary widely in fresh leaf extracts. Incubating extracts at 25 °C resulted in a disproportionate increase in NAD activity so that the final ratio of NADP to NAD activity was always about 5. Strong evidence was provided that the NADP and NAD malic enzyme activities in Z. mays extracts were catalyzed by the same enzyme. These activities remained associated during purification and were coincident after polyacrylamide gel electrophoresis. The pH optimum for NAD-dependent activity was about 7.1, compared with 8.3 for NADP malic enzyme activity. Other properties of the NAD-dependent activity are described, a particularly notable feature being the inhibition of this activity by less than 1 μm NADP and NADPH. Evidence is provided that the NADP malic enzyme of several other NADP malic enzyme-type C₄ species also has associated activity toward NAD. We concluded that the NAD-dependent malic enzyme activity would have no significant function in photosynthesis.     

The role of the nicotinamide and adenine subsites in the negative co-operativity of coenzyme binding to glyceraldehyde-3-phosphate dehydrogenase.

The interaction of 3-aminopyridine-adenine dinucleotide, an NAD ⁺ 2 analogue which is fluorescent at the pyridine end of the molecule, with rabbit muscle glyceraldehyde-3-phosphate dehydrogenase was investigated. The fluorescence properties of the AAD⁺ molecule were used to monitor the nicotinamide subsites ou the GPDHase tetramer, the fluorescent aminopyridine moiety of the molecule serving as an intrinsic probe. Although the binding of AAD⁺ wag found to be negatively co-operative, no conformational changes induced at the nicotinamide subsite upon coenzyme binding were found to be transmitted to neighboring subunits. These findings, in conjunction with our earlier findings and with the observation that different NAD⁺ analogues which differ in the chemistry of the pyridine moiety bind with different extents of co-operativity, enable us to offer specific roles for the nicotinamide and the adenine subsites in generating the negative co-operativity.It is suggested that the structure of the pyridine moiety of the coenzyme controls the mode of binding of the pyridine moiety to the nicotinamide subsite. This, in turn, controls the orientation of the adenine moiety with respect to its subsite, thereby determining the mode of the interactions between the adenine and its binding domain. As the propagation of conformational changes caused by these interactions to neighboring subunits is believed to be the cause of the negative co-operativity exhibited by this enzyme towards coenzyme binding, the structure of the pyridine moiety controls this phenomenon.     

Formation of Nicotinamide Ribose Diphosphate Ribose,a New Metabolite of NAD,by Aspergillus niger

Aspergillus niger (AKU 3302) degraded NAD to form Compound X. This compound was identified as nicotinamide ribose diphosphate ribose (NAmRDPR) by hydrolysis with alkaline or phosphodiesterase followed by chemical analysis of the products. NAmRDPR showed absorption maxima at 265~266 nm in 0.1 n HCI and 325 nm in 1.0 n KCN. Optimal pH for NAmRDPR formation by the enzyme preparation from this organism was around 4.0. Formation of NAmRDPR proceeded stoichiometrically with degradation of NAD. Some of other strains of A. niger formed NAmRDPR, but production of this compound was not demonstrated in other mold genera.     

Studies on Metabolic Pathway of NAD in Yeast Cells

A new method for preparing NMN (nicotinamide mononucleotide) by the use of yeast 5′-nucleotidase is presented. After hydrolysis of NAD into NMN, adenosine and P_i by yeast 5′-nucleotidase which is a single protein having nucleotide pyrophosphatase activity, NMN in the hydrolysate of NAD was purified on active carbon and subsequently on Amberlite IRC-50.

In the typical experiment, 0.74 g of NMN (88% purity) was obtained from 2g of NAD preparation, giving 76% recovery on the basis of the theoretical value.

The NMN preparation was identified as NMN by IR spectra, UV spectra, paper chromatography, and also by component analysis.     

Characterization of a pyridine nucleotide-nonspecific glutamate dehydrogenase from Bacteroides thetaiotaomicron.

An oxidized nicotinamide adenine dinucleotide phosphate/oxidized nicotinamide adenine dinucleotide (NADP+/NAD+) nonspecific L-glutamate dehydrogenase from Bacteroides thetaiotaomicron was purified 40-fold (NADP+ or NAD+ activity) over crude cell extract by heat treatment, (NH4)2SO2 fractionation, diethylaminoethyl-cellulose, Bio-Gel A 1.5m, and hydroxylapatite chromatography. Both NADP+- and NAD+-dependent activities coeluted from all chromatographic treatments. Moreover, a constant ratio of NADP+/NAD+ specific activities was demonstrated at each purification step. Both activities also comigrated in 6% nondenaturing polyacrylamide gels. Affinity chromatography of the 40-fold-purified enzyme using Procion RED HE-3B gave a preparation containing both NADP+- and NAD+-linked activities which showed a single protein band of 48,5000 molecular weight after sodium dodecyl sulfate-polyacrylamide gradient gel electrophoresis. The dual pyridine nucleotide nature of the enzyme was most readily apparent in the oxidative direction. Reductively, the enzyme was 30-fold more active with reduced NADP than with reduced NAD. Nonlinear concave 1/V versus 1/S plots were observed for reduced NADP and NH4Cl. Salts (0.1 M) stimulated the NADP+-linked reaction, inhibited the NAD+-linked reaction, and had little effect on the reduced NADP-dependent reaction. The stimulatory effect of salts (NADP+) was nonspecific, regardless of the anion or cation, whereas the degree of NAD+-linked inhibition decreased in the order to I- greater than Br- greater than Cl- greater than F-. Both NADP+ and NAD+ glutamate dehydrogenase activities were also detected in cell extracts from representative strains of other bacteroides deoxyribonucleic acid homology groups.     

NAD glycohydrolase activity in dog cardiac tissue.

1. Dog heart tissue suspension hydrolyzes NAD, NADP and NMN, and releases nicotinamide stoichiometrically. 2. Maximum activity was observed at 50 degrees C and the activation energy was 10 kcal/mol. 3. Optimum pH range was 6.2-7.6. 4. Compounds with adenine-ribose moiety increased the enzymatic activity. 5. Nicotinamide released during incubation produced reaction nonlinearity. 6. Km for NAD and NADP were about the same; Vmax was higher for NAD. Similar findings have been reported for rabbit heart. 7. Dog enzyme appears to be more sensitive than the rabbit enzyme to noncompetitive inhibitors. 8. Pyrophosphatase activity was not detected in dog heart in contrast to rabbit and rat heart preparations.     

An Improved Method for the Fermentative Production of Coenzyme A from Pantothenic Acid,Cysteine, and 5′-AMP

The cultivation of Brevibacterium ammoniagenes IFO 12071 with pantothenic acid, cysteine, and 5′-adenylic acid gave coenzyme A in a high yield. The organism was stabilized by repeated single colony isolations. The culture conditions optimal for the production of coenzyme A were investigated, and the yield of coenzyme A in the culture broth reached more than 3 mg/ml.

The advantages and disadvantages of the present method were discussed by comparing them with our original dried cell method.