Pyridine nucleotide cycle of Salmonella typhimurium: in vitro demonstration of nicotinamide adenine dinucleotide glycohydrolase, nicotinamide mononucleotide glycohydrolase, and nicotinamide adenine dinucleotide pyrophosphatase activities.

Extracts of Salmonella typhimurium were chromatographed by using Sephadex G-150 to separate the various enzymes involved with pyridine nucleotide cycle metabolism. This procedure revealed a previously unsuspected nicotinamide adenine dinucleotide (NAD) glycohydrolase (EC 3.2.2.5) activity, which was not observed in crude extracts. In contrast to NAd glycohydrolase, NAD pyrophosphatase (EC 3.6.1.22) was readily measured in crude extracts. This enzyme possessed a native molecular weight of 120,000. Other enzymes examined included nicotinamide mononucleotide (NMN) deamidase (EC 3.5.1.00), molecular weight of 43,000; NMN glycohydrolase (EC 3.2.2.14), molecular weight of 67,000; nicotinic acid phosphoribosyl transferase (EC 2.4.2.11), molecular weight of 47,000; and nicotinamide deamidase (EC 3.5.1.19), molecular weight of 35,000. NMN deamidase and NMN glycohydrolase activities were both examined for end product repression by measuring their activities in crude extracts prepared from cells grown with and without 10(-5) M nicotinic acid. No repression was observed with either activity. Both activities were also examined for feedback inhibition by NAD, reduced NAD, and NADP. NMN deamidase was unaffected by any of the compounds tested. NMN glycohydrolase was greatly inhibited by NAD and reduced NAD, whereas NADP was much less effective. Inhibition of NMN glycohydrolase was found to level off at an NAD concentration of ca. 1 mN, the approximate intracellular concentration of NAD.     

The concentration and biosynthesis of nicotinamide nucleotides in the livers of rats treated with carcinogens

1. The oxidoreduction state and concentration of both NAD and NADP as well as the maximum potential activities of NMN adenylyltransferase and NAD(+) kinase have been measured in the livers of rats treated for 14-28 days with 4-dimethylamino-3'-methylazobenzene, 4-dimethylamino-4'-fluoroazobenzene, alpha-naphthyl isothiocyanate or ethionine and in primary hepatomas induced by 4-dimethylamino-3'-methylazobenzene. 2. The total NAD and total NADP both decreased in the livers of rats treated with either azo-dyes or alpha-naphthyl isothiocyanate but not in those treated with ethionine. The activities of NMN adenylyltransferase and NAD(+) kinase did not alter appreciably after such treatments. 3. In the primary hepatomas the concentrations of both NAD and NADP fell drastically and the activities of NMN adenylyltransferase and NAD(+) kinase fell to about 50% of the control activities. 4. No correlation could be established between the concentrations of the nucleotides and the activities of the enzymes synthesizing them. It appears, however, that a relationship exists between the NAD content of the tissue and the amount of NADP present. 5. The results are discussed with respect to the control of NAD and NADP synthesis by ATP. At the concentrations of NAD normally present in the cell it is suggested that NAD may be a rate-limiting substrate in NADP synthesis.     

Nicotinamide methylation and its relation to NAD synthesis in rat liver tissue culture: Biochemical basis fro the physiological activities of 1-methylnicotinamide

The mode of [¹⁴C]lnicotinamide conversion to NAD and 1-methylnicotinamide and the effects of exogenous 1-methylnicotinamide on this metabolic conversion were studied using rat livers slices incubated in a chemically defined culture medium. It was shown that at the physiological nicotinamide concentrations tested (11–500 μM), 1-methylnicotinamide is preferentially produced, rather than NAD. Upon increasing nicotinamide concentration to the levels that cause cytotoxicity (1–10 mM and higher), the rate of NAD synthesis dramatically increased and reached a level 6-fold higher than that of 1-methylnicotinamide. A dose-dependent inhibition (up to 60%) of NAD synthesis was seen by the exogenous addition of 1-methylnicotinamide; the degree of inhibition is affected also by the concentrations of nicotinamide present as a precursor. A large depletion of intracellular ATP, associated with a marked accumulation of NAD, occurred in slices in response to the addition of high amounts of nicotinamide. However, loss of ATP was overcome, when nicotinamide was given together with 1-methylnicotinamide. Finally, 1-methylnicotinamide per se was proven active in regulating cell growth by comparing the cytosolic activity of 1-methylnicotinamide oxidation of cultured RLC cells with that of rat liver. Thus, the previously observed growth stimulation of hepatic cells by 1-methylnicotinamide can reasonably been explained by its ATP-sparing effect due to the inhibition of NAD synthesis, a reaction which requires ATP.     

Nicotinamide methylation and its relation to NAD synthesis in rat liver tissue culture. Biochemical basis for the physiological activities of 1-methylnicotinamide

The mode of [14C]nicotinamide conversion to NAD and 1-methylnicotinamide and the effects of exogenous 1-methylnicotinamide on this metabolic conversion were studied using rat liver slices incubated in a chemically defined culture medium. It was shown that at the physiological nicotinamide concentrations tested (11-500 microM), 1-methylnicotinamide is preferentially produced, rather than NAD. Upon increasing nicotinamide concentration to the levels that cause cytotoxicity (1-10 mM and higher), the rate of NAD synthesis dramatically increased and reached a level 6-fold higher than that of 1-methylnicotinamide. A dose-dependent inhibition (up to 60%) of NAD synthesis was seen by the exogenous addition of 1-methylnicotinamide; the degree of inhibition is affected also by the concentration of nicotinamide present as a precursor. A large depletion of intracellular ATP, associated with a marked accumulation of NAD, occurred in slices in response to the addition of high amounts of nicotinamide. However, the loss of ATP was overcome, when nicotinamide was given together with 1-methylnicotinamide. Finally, 1-methylnicotinamide per se was proven active in regulating cell growth by comparing the cytosolic activity of 1-methylnicotinamide oxidation of cultured RLC cells with that of rat liver. Thus, the previously observed growth stimulation of hepatic cells by 1-methylnicotinamide can reasonably been explained by its ATP-sparing effect due to the inhibition of NAD synthesis, a reaction which requires ATP.     

Influence of ADP-ribosyltransferase inhibitors on the intracellular NAD and ATP levels in Ehrlich ascites tumor cells: implication for the altered NAD + ATP-dependent cellular sensitivity to the cytotoxic agents.

Exposure of Ehrlich ascites tumor cells to 3-aminobenzamide for 60 min resulted in a dose-dependent increase of cellular NAD and ATP levels at a concentration range of 0.3-5 mM. In the cells exposed to 5-methylnicotinamide there was a decrease of both nucleotide levels. As a possible cause for these changes we found a marked inhibition of microsomal NAD glycohydrolase activity by 3-aminobenzamide and a moderate stimulation of this enzyme by 5-methylnicotinamide. Furthermore, 3-aminobenzamide significantly enhanced the cellular uptake of nicotinamide and NAD synthesis, probably by the stimulation of nuclear ATP-NMN adenylyltransferase activity. We show also that the cells containing elevated NAD and ATP levels by the exposure to 3-aminobenzamide became resistant to the 5-azacytidine cytotoxicity.     

Metabolism of NAD and N1-methylnicotinamide in growing and growth-arrested cells

Nicotinamide is metabolized primarily into NAD and N1-methylnicotinamide in cultured cells of normal rat kidney. The metabolic pathways for the nicotinamide metabolites are independently regulated and are influenced by the growth stage of the cells. N1-Methylnicotinamide levels are 1.5--2-fold elevated in cells growth-arrested by treatment with histidinol, thymidine, or picolinic acid, or by serum starvation. This increase is due to a more rapid rate of synthesis rather than decrease in excretion. The rates of both synthesis and degradation of NAD are increased in serum-starved cells so that the NAD concentration is the same as it is in growing cells. NAD and N1- methylnicotinamide levels are not significantly increased when the intracellular nicotinamide concentration is increased 20-fold by addition of excess nicotinamide to the culture medium, demonstrating that the size of the nicotinamide pool does not limit synthesis of these compounds. In medium containing normal amounts of nicotinamide, the apparent first-order rate constant for the decay of NAD, radioactively labeled in the nicotinamide moiety, is about 4 h-1. Labeled N1-methylnicotinamide is not metabolized, but rather is excreted into the medium with a first-order rate constant of 3.9 h-1. The rate of loss of label from NAD, but not from N1-methylnicotinamide, is increased about twofold by addition of excess nicotinamide to the culture medium. This could be explained by a dilution of a labeled nicotinamide pool which is formed during NAD degradation and which is recycled into NAD but not into N1-methylnicotinamide. The results demonstrate a rapid turnover of NAD at the bond joining nicotinamide and ADP-ribose, in agreement with previous studies. In addition, the results show that nicotinamide is metabolized into N1-methylnicotinamide with what appears to be a carefully regulated synthetic mechanism. The existence of significant amounts of N1-methylnicotinamide in cultured cells raises the question of the physiological importance of this compound.     

Transport of nicotinamide adenine dinucleotide in an unc mutant of Escherichia coli.

The presence and some properties of an NAD+ transport system were examined in PA5, a Mg, Ca-ATPase [EC 3.6.1.3]-defective mutant strain of Escherichia coli W2252. NAD+ uptake was stimulated by exogenous energy sources and dependent on external substrate concentrations with an apparent Km of about 25 micrometer. Most of the radioactivity from [14C]-NAD+ accumulated in the cells was identified as NAD+. [14C]NAD+ uptake was competively inhibited by unlabeled NAD+, NADP+, NMN+ or nicotinamide. Similar uptake activity was also observed in W2252.     

NAD(P)+ analogues: tools for the investigation of the active site of oestradiol 17beta-dehydrogenase from human placenta.

Oestradiol-17beta:NAD+ 17-oxidoreductase from human placenta can accept coenzyme analogues of NAD+ and NADP+ where the amide group is replaced by methyl ketone, nitrile or thioamide. The inhibition with analogues of NAD+ has been studied. The presence of a substituent at C-3 of the pyridinium ring is necessary for the binding. The inhibition by C-4 methylated analogues is very poor, and the effect of a methyl group at C-5 depends on the substituent at C-3. The 1,4,5,6-tetrahydronicotinamide adenine dinucleotide is a competitive inhibitor. Nicotinamide 8-bromoadenine dinucleotide and nicotinamide 8-thioadenine dinucleotide are efficient hydrogen acceptors.     

Nicotinamide–adenine dinucleotides in acute liver injury induced by ethionine, and a comparison with the effects of salicylate

1. The effects of single doses of ethionine or sodium salicylate on the nicotinamide-adenine dinucleotide content of rat liver have been studied. 2. There was no significant change in the sum of NAD+NADH(2) during the early period (0-2hr.) of the liver injury induced by ethionine but there was a decrease in this value of approx. 30% by 4hr. after administration. 3. Ethionine had no significant effect on the NADP+NADPH(2) during the first 2hr. period after administration. The sum then decreased to a value approx. 70% of the control by 3hr. after dosing but showed a partial recovery at the 4hr. period before decreasing again in later stages of the poisoning. 4. Salicylate produced a very rapid decrease in the NADP+NADPH(2) in the liver after intraperitoneal injection. After 1hr. the decrease was approx. 30% of the initial value; the sum slowly returned towards the normal range during the following 4hr. 5. A high parenteral dose of salicylate was found to cause only a small depression in the concentration of ATP in rat liver in contrast with the rapid depletion produced by ethionine. 6. These results are discussed in terms of the liver disturbances produced by ethionine and salicylate.     

The control of nucleic acid and nicotinamide nucleotide synthesis in regenerating rat liver

1. The effect of injecting nicotinamide on the incorporation of [(14)C]orotate into the hepatic nucleic acids of rats after partial hepatectomy was investigated. 2. At 3h after partial hepatectomy the rapid incorporation of [(14)C]orotate into RNA, and at 20h after partial hepatectomy the incorporation of [(14)C]orotate into both RNA and DNA, were inhibited in a dose-dependent fashion by the previous injection of nicotinamide. 3. The injection of nicotinamide at various times before the injection of [(14)C]orotate at 20h after partial hepatectomy revealed an inhibition of the incorporation of orotate into RNA and DNA which was non-linear with respect to the duration of nicotinamide pretreatment. 4. The induction of a hepatic ATP depletion by ethionine demonstrated that the synthesis of hepatic NAD and NADP in partially hepatectomized rats was more susceptible to an ATP deficiency than in control rats. 5. The total hepatic activity of ribose phosphate pyrophosphokinase (EC 2.7.6.1) was assayed at various times after partial hepatectomy and found to be only marginally greater than the maximum rate of hepatic NAD synthesis induced in vivo by nicotinamide injection between 12 and 24h after partial hepatectomy. 6. It is suggested that a competition exists between NAD synthesis and purine and pyrimidine nucleotide synthesis for available ATP and particularly 5-phosphoribosyl 1-pyrophosphate. In regenerating liver the competition is normally in favour of the synthesis of nucleic acid precursors, at the expense of NAD synthesis. This situation may be reversed by the injection of nicotinamide with a subsequent inhibition of nucleic acid synthesis.     

Slow-binding inhibition of NAD+ glycohydrolase by arabino analogues of beta-NAD.

Modifications at the 2'-position of the nicotinamide-ribosyl moiety influence dramatically the nature of the interactions of the modified beta-NAD+ with calf spleen NAD+ glycohydrolase (EC 3.2.2.6), an enzyme that cleaves the nicotinamide-ribose bound in NAD(P)+. Nicotinamide arabinoside adenine dinucleotide (ara-NAD+) and nicotinamide 2'-deoxy-2'-fluoroarabinoside adenine dinucleotide (araF-NAD+) are not hydrolyzed at measurable rates and are the first documented examples of reversible slow binding inhibitors of this class of enzyme. The kinetic data obtained are consistent with both slow kon and koff rate constants in the formation of an enzyme-inhibitor complex, i.e. the association rate constants are about 10(4) and 10(6) slower than diffusion rates, respectively, for araF-NAD+ and ara-NAD+, and the half-life of the complex is about 3-10 min for both analogues. The kinetic model does not account for a slow turnover of an ADP-ribosyl-enzyme intermediary complex. AraF-NAD+ is one of the most potent inhibitors described for NAD+ glycohydrolase.     

Enhancement of DNA synthesis and cell proliferation by 1-methylnicotinamide in rat liver cells in culture: Implication for its in vivo role

1-Methylnicotinamide, a direct methylation product of nicotinamide, stimulates the DNA synthesis and proliferation of rat liver cells (RLC) in culture at concentrations higher than 20 μM. The effect of nicotinamide, which is a potent inhibitor of DNA synthesis and proliferation, is counteracted by 1-methylnicotinamide. The intracellular NAD concentration decreases within 2 h under 1-methylnicotinamide, whereas it increases in the presence of nicotinamide. The poly(ADP-ribose) synthesizing activity in the isolated nuclei remained unchanged. These results suggest a physiological role of 1-methylnicotinamide in the cell growth through a lowering of intracellular NAD level.     

Purification and properties of the soluble NAD glycohydrolase from Bungarus fasciatus venom

The NAD glycohydrolase (NADase) (EC 3.2.2.5) from Bungarus fasciatus (banded krait) venom was purified (1000-fold) to electrophoretic homogeneity through a 3-step purification procedure, the last step being affinity chromatography on Cibacron blue agarose. The purified NADase is a glycoprotein containing two subunits of Mr = 62,000 each. Nicotinamide and adenosine diphosphoribose were produced in a 1:1 stoichiometry and were the only products formed when the purified NADase was incubated with NAD. These results were confirmed by high performance liquid chromatography. The enzyme exhibited a brod pH profile with optimum pH for hydrolysis at 7.5 with very little change in Km from pH 6.0 to pH 8.5. The NADase is only slightly affected by changes in ionic strength. The enzyme studied titrimetrically at pH 7.5 and 38 degrees C exhibited a Km of 14 microM and a Vmax of 1380 mumol of NAD cleaved/min/mg of protein. The activation energy for the enzyme-catalyzed hydrolysis of NAD was 15.7 kcal/mol. In addition to NAD and NADP, a number of NAD analogs were shown to function as substrates for the enzyme. Product inhibition studies demonstrated nicotinamide to be a noncompetitive inhibitor with a KI of 1.5 mM and adenosine diphosphoribose a competitive inhibitor with a KI of 0.36 mM. Procion blue HB (Cibacron blue F3GA) was shown to be a competitive inhibitor with a KI of 33 nmol. The purified NADase catalyzed the pyridine base exchange reaction between 3-acetylpyridine and the nicotinamide moiety of NAD.     

Asymmetric reassociation of calf spleen NAD+ glycohydrolase into liposomes.

NAD+ glycohydrolase (NAD+ nucleosidase, EC 3.2.2.6) can be solubilized from calf spleen microsomes (microsomal fractions) by steapsin or by detergents to yield respectively a hydrophilic (i.e. water-soluble) and a hydrophobic form of the enzyme. The detergent-solubilized enzyme was successfully reassociated into phosphatidylcholine liposomes either by a cholate-dialysis or by a gel-filtration procedure. In both cases the incorporation of NAD+ glycohydrolase was found to be completely asymmetric, i.e. the active site of the enzyme was exposed only at the outer surface of the vesicles. By contrast, as judged by flotation experiments, the hydrophilic form of NAD+ glycohydrolase could not be reassociated into liposomes. These results are in agreement with the hypothesis that calf spleen NAD+ glycohydrolase is an amphipathic protein. When incorporated into large unilamellar vesicles composed of phosphatidylcholine, NAD+ glycohydrolase was not found to catalyse vectorial transfer of NAD+ by transglycosidation with nicotinamide as acceptor.     

Binding of NAD+ by cholera toxin.

1. The Km for NAD+ of cholera toxin working as an NAD+ glycohydrolase is 4 mM, and this is increased to about 50 mM in the presence of low-Mr ADP-ribose acceptors. Only molecules having both the adenine and nicotinamide moieties of NAD+ with minor alterations in the nicotinamide ring can be competitive inhibitors of this reaction. 2. This high Km for NAD+ is also reflected in the dissociation constant, Kd, which was determined by a variety of methods. 3. Results from equilibrium dialysis were subject to high error, but showed one binding site and a Kd of about 3 mM. 4. The A1 peptide of the toxin is digested by trypsin, and this digestion is completely prevented by concentrations of NAD+ above 50 mM. Measurement (by densitometric scanning of polyacrylamide-gel electrophoretograms) of the rate of tryptic digestion at different concentrations of NAD+ allowed a more accurate determination of Kd = 4.0 +/- 0.4 mM. Some analogues of NAD+ that are competitive inhibitors of the glycohydrolase reaction also prevented digestion.     

Topography, purification and characterization of thyroidal NAD+ glycohydrolase

Subcellular fractionation of bovine thyroid tissue by differential pelleting and isopycnic gradient centrifugation in a zonal rotor indicated that NAD(+) glycohydrolase is predominantly located and rather uniformly distributed in the plasma membrane. Comparison of NAD(+) glycohydrolase activities of intact thyroid tissue slices, functional rat thyroid cells in culture (FRT(l)) and their respective homogenates indicated that most if not all of the enzyme (catalytic site) is accessible to extracellular NAD(+). The reaction product nicotinamide was predominantly recovered from the extracellular medium. The diazonium salt of sulphanilic acid, not penetrating into intact cells, was able to decrease the activity of intact thyroid tissue slices to the same extent as in the homogenate. Under the same conditions this reagent almost completely abolished NAD(+) glycohydrolase activity associated with intact thyroid cells in culture. The triazine dye Cibacron Blue F3GA and its high-M(r) derivative Blue Dextran respectively completely eliminated or caused a severe depression in the NAD(+) glycohydrolase activity of FRT(l) cells. The enzyme could be readily solubilized from bovine thyroid membranes by detergent extraction, and was further purified by gel filtration and affinity chromatography on Blue Sepharose CL-6B. The overall procedure resulted in a 1940-fold purification (specific activity 77.6mumol of nicotinamide released/h per mg). The purified enzyme displays a K(m) of 0.40mm for beta-NAD(+), a broad pH optimum around pH7.2 (0.1 m-potassium phosphate buffer) and an apparent M(r) of 120000. Nicotinamide is an inhibitor (K(i) 1.9mm) of the non-competitive type. The second reaction product ADP-ribose acts as a competitive inhibitor (K(i) 2.7mm). The purified enzyme splits beta-NAD(+), beta-NADP(+), beta-NADH and alpha-NAD(+) at rates in the relative proportions 1:0.75:<0.02:<0.02 and exhibits transglycosidase (pyridine-base exchange) activity. Anionic phospholipids such as phosphatidylinositol and phosphatidylserine inhibit the partially purified enzyme. A stimulating effect was observed upon the addition of histones.     

Changes in Nicotinamide Nucleotide Coenzymes in Cucumber Leaves during Ammonium Toxicity

Nicotinamide nucleotide coenzymes were estimated enzymatically in cucumber leaves (Cucumis sativus L. cv. Suisei No. 2) during ammonium toxicity. The contents of all the coenzymes (NAD(H) and NADP(H)) were found to be higher in the ammonium-treated plants than in the control plants, and the difference attained a maximum at 5 days after the initiation of ammonium treatment. Thereafter, the contents of NAD and NADH returned towards the control level, but NADP and NADPH levels were lowered in injured plants. The ratios of NAD/NAD + NADH and NADP/NADP ++ NADPH were little altered by the ammonium treatment. Changes of nicotinamide nucleotide coenzymes are discussed in relation to respiratory metabolism in cucumber leaves during ammonium toxicity.     

Synthesis and properties of photoaffinity labels for the pyridine dinucleotide binding site of NAD glycohydrolase.

Two new photoactive analogues of oxidized nicotinamide adenine dinucleotide (NAD+) which are resistant to cleavage by NAD glycohydrolase were synthesized and characterized. The beta-D-ribonucleotide ring of the nicotinamide riboside moiety of NAD+ was replaced with a 2,3-dihydroxycyclopentane ring forming a carbocyclic dinucleotide analogue. Photoreactivity was achieved by the incorporation of an azido group at the 8-position of the adenosyl ring. The previously published synthesis of carbocyclic pyridine dinucleotide analogues [Slama, J. T., & Simmons, A. M. (1988) Biochemistry 27, 183] was modified by resolving the carbocyclic 1-aminoribose analogues and producing optically pure (+)-(1S)- or (-)-(1R)-4 beta-amino-2 alpha,3 alpha-dihydroxy-1 beta-cyclopentanemethanol. Each of these was converted to the corresponding carbocyclic nicotinamide 5'-nucleotide analogue and coupled with 8-azidoadenosine 5'-monophosphate. Two photoactive and isomeric NAD+ analogues were thus prepared. 8-Azidoadenosyl carba-NAD is the analogue in which D-dihydroxycyclopentane is substituted for the D-ribose of the nicotinamide nucleoside moiety. 8-Azido-adenosyl pseudocarba-NAD contains the L-carbocycle in place of the D-ribotide ring. 8-Azidoadenosyl carba-NAD was shown to inhibit the NAD glycohydrolase from Bungarus fasciatus venom competitively with an inhibitor dissociation constant of 187 microM. 8-Azidoadenosyl pseudocarba-NAD was shown to inhibit the same enzyme competitively with a Ki of 73 microM. The superior NADase inhibitor, 8-azidoadenosyl pseudocarba-NAD, was characterized kinetically and shown to fulfill the criteria required of a specific active site directed photoaffinity probe. Irradiation of mixtures of the photoprobe and NAD glycohydrolase with short-wave ultraviolet light resulted in the rapid and irreversible loss of enzyme activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

The levels of nicotinamide nucleotides in liver microsomes and their possible significance to the function of hexose phosphate dehydrogenase.

The concentrations of NAD and NADP have been determined in detergent extracts of washed rat liver microsomes. Precautions were taken during the preparation of the microsomes to remove nicotinamide nucleotides from their external surface both by hydrolysis by nucleotide pyrophosphatase (EC 3.6.1.9) and by washing them three times in 0.15 M-Tris/HCl, pH 8.0, to remove soluble proteins which bind these nucleotides. The mannose phosphatase was essentially completely latent, indicating that the microsomes were intact. Assuming these nucleotides are in the cisternae of the microsomes, the concentrations in the cisternae are 240 +/- 25 microM-NAD and 55 +/- 12 microM-NADP. These levels of nucleotides are compatible with both the glucose:NAD+ and the glucose 6-phosphate:NADP+ oxidoreductase activities of hexose phosphate dehydrogenase (EC 1.1.1.47). Since the organ and subcellular distributions of this dehydrogenase and glucose-6-phosphatase are similar, and Pi stimulates the glucose:NAD+ oxidoreductase activity, it is proposed that the combined action of these two enzymes leads to the reduction of both coenzymes in the lumen of the endoplasmic reticulum. A modification of the colorimetric method of Nisselbaum & Green [(1969) Anal. Biochem. 27, 212-217] for the determination of NADP+ is described. Colour formation is linear with the concentration of NADP+ and is sensitive to less than 0.3 nmol of NADP+.     

The activities of nicotinamide mononucleotied adenylyltransferase and of nicotinamide–adenine dinucleotide kinase in the livers of rats subjected to different hormonal treatments

1. The activities of NMN adenylyltransferase and of NAD(+) kinase have been measured in the livers of adrenalectomized or alloxan-diabetic rats and in the livers of rats treated with glucagon, pituitary growth hormone or thyroxine. 2. The activities of these enzymes have been compared with the effects of the same treatments on the nicotinamide nucleotide concentrations in the liver. 3. Alloxandiabetes (+37%) and thyroxine (+27%) both increased the activity of NMN adenylyltransferase. The other treatments were without effect on this enzyme. 4. Only thyroxine increased the activity of NAD(+) kinase significantly (+26%) although both adrenalectomy and glucagon tended to increase its activity. 5. The activity of NAD(+) glycohydrolase was measured in the livers of diabetic rats, and in the livers of rats treated with either growth hormone or thyroxine. Of these treatments, only growth hormone altered the enzyme activity (+26%, calculated on a total hepatic activity basis). 6. Female rats had a greater hepatic NAD(+)-kinase activity than males but there was no sex difference with respect to NMN adenylyltransferase. 7. The lack of correlation between the maximum potential activity of these three enzymes and the known changes of the nicotinamide nucleotides in each of the hormone conditions is discussed.