Nicotinamide deamidase released by neuroblastoma cell cultures.

Abstract— An enzymic activity which catalyses the deamidation of nicotinamide to nicotinic acid has been found in the growth media of neuroblasts and glioblasts cultivated in vitro. Some properties of the crude nicotinamide deamidase from the growth medium of neuroblastoma M1 cells have been studied.     

Properties and Structure of a Novel Peptide Antibiotic No. 1907

There are three NAD biosynthetic pathways: the nicotinic acid-NAD, nicotinamide-NAD, and quinolinic acid (derived from tryptophan)-NAD pathways. To discover the main pathways of NAD biosyntheses in various tissues of the rat, the tissue distribution of nicotinamidase, quinolinate phosphoribosyltransferase, nicotinate phosphoribosyltransferase, nicotinamide phosphoribosyl-transferase, nicotinamide mononucleotide adenylyltransferase, and NAD⁺ synthetase were investigated. All of the tissues could synthesize NAD from nicotinamide, judging from that the activities of nicotinamide phosphoribosyltransferase and NMN adenylyltransferase detected in all of the tissues. From nicotinic acid, only liver, kidneys, and heart could. Liver and kidney can also synthesize NAD de novo from quinolinic acid.     

Nicotinic acid and nicotinamide metabolism and promotion of cell arrest in G2 in Pisum sativum

Nicotinic acid and nicotinamide are immediate precursors of trigonelline, a hormone present in cotyledons of Pisum sativum L. which promotes cell arrest in G2 during cell maturation in roots and shoots. All three compounds are members of the pyridine nucleotide pathway for the synthesis of NAD and NADP. Concentrations of nicotinic acid and nicotinamide in excised roots grown for 3 days in White's medium with sucrose were determined by HPLC. Results suggest that nicotinamide is rapidly converted first to nicotinic acid and then trigonelline. High nicotinic acid concentrations may occur in excised roots. Conversion of trigonelline to nicotinic acid in excised roots did not occur in these experiments. The concentrations of either nicotinamide or nicotinic acid in roots are not related to the proportions of cells arrested in G2. Trigonelline promotes cell arrest in G2, and nicotinic acid and nicotinamide are active only because they are converted to trigonelline.     

Nrt1 and Tna1-independent export of NAD+ precursor vitamins promotes NAD+ homeostasis and allows engineering of vitamin production

NAD(+) is both a co-enzyme for hydride transfer enzymes and a substrate of sirtuins and other NAD(+) consuming enzymes. NAD(+) biosynthesis is required for two different regimens that extend lifespan in yeast. NAD(+) is synthesized from tryptophan and the three vitamin precursors of NAD(+): nicotinic acid, nicotinamide and nicotinamide riboside. Supplementation of yeast cells with NAD(+) precursors increases intracellular NAD(+) levels and extends replicative lifespan. Here we show that both nicotinamide riboside and nicotinic acid are not only vitamins but are also exported metabolites. We found that the deletion of the nicotinamide riboside transporter, Nrt1, leads to increased export of nicotinamide riboside. This discovery was exploited to engineer a strain to produce high levels of extracellular nicotinamide riboside, which was recovered in purified form. We further demonstrate that extracellular nicotinamide is readily converted to extracellular nicotinic acid in a manner that requires intracellular nicotinamidase activity. Like nicotinamide riboside, export of nicotinic acid is elevated by the deletion of the nicotinic acid transporter, Tna1. The data indicate that NAD(+) metabolism has a critical extracellular element in the yeast system and suggest that cells regulate intracellular NAD(+) metabolism by balancing import and export of NAD(+) precursor vitamins.     

Profiles of the biosynthesis and metabolism of pyridine nucleotides in potatoes (<Emphasis Type="Italic">Solanum tuberosum</Emphasis> L.)

As part of a research program on nucleotide metabolism in potato tubers (Solanum tuberosum L.), profiles of pyridine (nicotinamide) metabolism were examined based on the in situ metabolic fate of radio-labelled precursors and the in vitro activities of enzymes. In potato tubers, [³H]quinolinic acid, which is an intermediate of de novo pyridine nucleotide synthesis, and [¹⁴C]nicotinamide, a catabolite of NAD, were utilised for pyridine nucleotide synthesis. The in situ tracer experiments and in vitro enzyme assays suggest the operation of multiple pyridine nucleotide cycles. In addition to the previously proposed cycle consisting of seven metabolites, we found a new cycle that includes newly discovered nicotinamide riboside deaminase which is also functional in potato tubers. This cycle bypasses nicotinamide and nicotinic acid; it is NAD → nicotinamide mononucleotide → nicotinamide riboside → nicotinic acid riboside → nicotinic acid mononucleotide → nicotinic acid adenine dinucleotide → NAD. Degradation of the pyridine ring was extremely low in potato tubers. Nicotinic acid glucoside is formed from nicotinic acid in potato tubers. Comparative studies of [carboxyl-¹⁴C]nicotinic acid metabolism indicate that nicotinic acid is converted to nicotinic acid glucoside in all organs of potato plants. Trigonelline synthesis from [carboxyl-¹⁴C]nicotinic acid was also found. Conversion was greater in green parts of plants, such as leaves and stem, than in underground parts of potato plants. Nicotinic acid utilised for the biosynthesis of these conjugates seems to be derived not only from the pyridine nucleotide cycle, but also from the de novo synthesis of nicotinic acid mononucleotide.     

Nucleoside salvage pathway for NAD biosynthesis in Salmonella typhimurium

A previously undescribed nucleoside salvage pathway for NAD biosynthesis is defined in Salmonella typhimurium. Since neither nicotinamide nor nicotinic acid is an intermediate in this pathway, this second pyridine nucleotide salvage pathway is distinct from the classical Preiss-Handler pathway. The evidence indicates that the pathway is from nicotinamide ribonucleoside to nicotinamide mononucleotide (NMN) and then to nicotinic acid mononucleotide, followed by nicotinic acid adenine dinucleotide and NAD. The utilization of exogenous NMN for NAD biosynthesis has been reexamined, and in vivo evidence is provided that the intact NMN molecule traverses the membrane.     

Autoradiographic studies of nicotinic acid utilization in human-mouse heterokaryons and inhibition of utilization in newly-formed hybrid cells

Although most mammalian cell lines can utilize either nicotinic acid or nicotinamide for the biosynthesis of nicotinamide adenine dinucleotide (NAD), thymidine kinase-deficient, mouse 3T3–4F cells are unable to utilize nicotinic acid. When 3T3–4E cells were fused with human D98/AH2 cells, autoradiography showed that the resultant heterokaryons synthesized NAD from nicotinic acid at rates comparable to the human parental cell. The rate of nicotinic acid utilization in heterokaryons remained unchanged over the fourday period of study following cell fusion. In contrast to the results observed with heterokaryons, nicotinic acid utilization was markedly reduced in hybrid cells. Of 100 hybrid clones examined at four or five days following cell fusion, 60 utilized nicotinic acid at rates less than one tenth that of the parental human cell. Similar results were observed in hybrid clones at nine or ten days following fusion. Uniformly high rates of NAD biosynthesis were observed in hybrid clones with nicotinamide as the precursor. This excludes the possibility that the reduction in nicotinic acid utilization in hybrid cells is due to a general metabolic dysfunction. The biochemical mechanism by which nicotinic acid utilization is markedly reduced has not been determined with certainty, however, several observations suggest genetic suppression.     

Metabolic fate of nicotinamide in higher plants

Metabolism of [carbonyl-¹⁴C]nicotinamide was surveyed in various plant materials including the model plants, Arabidopsis thaliana , Oryza sativa and Lotus japonicus . In all plants studied, nicotinamide was used for the pyridine (nicotinamide adenine) nucleotide synthesis, probably after conversion to nicotinic acid. Radioactivity from [carbonyl-¹⁴C]nicotinamide was incorporated into trigonelline (1- N -methylnicotinic acid) and/or into nicotinic acid 1 N -glucoside (Na-Glc). Trigonelline is formed mainly in leaves and cell cultures of O. sativa and L. japonicus and in seedlings of Trifolium incarnatum , Medicago sativa and Raphanus sativus . Trigonelline synthesis from nicotinamide is generally greater in leaves than in roots. Na-Glc was formed as the major nicotinic acid conjugate in A. thaliana and in tobacco Bright Yellow-2 cells. In seedlings of Chrysanthemum coronarium and Theobroma cacao , both trigonelline and Na-Glc were synthesized from [carbonyl-¹⁴C]nicotinamide. Trigonelline is accumulated in some seeds, mainly Leguminosae species. The pattern of formation of the nicotinic acid conjugates differs between species and organs.     

Effects of excess nicotinamide administration on the urinary excretion of nicotinamide N-oxide and nicotinuric acid by rats

We investigated a useful chemical index for an excessive nicotinamide intake and how this excessive nicotinamide intake affects the tryptophan-nicotinamide metabolism in rats. Weaning rats were fed on a tryptophan-limited and nicotinic acid-free diet containing no, 0.003%, 0.1%, 0.2%, or 0.3% nicotinamide for 21 days. Urine samples were collected on the last day and analyzed the intermediates and metabolites on the tryptophan-nicotinamide pathway. Nicotinamide N-oxide, nicotinic acid and nicotinuric acid, metabolites of nicotinamide, were detected when nicotinamide at more than 0.1% had been taken. An intake of nicotinamide of more than 0.1% increased the urinary excretion of quinolinic acid, an intermediate on the pathway. Nicotinamide N-oxide and nicotinuric acid increased with increasing dietary concentration of nicotinamide. These results show that the measurements of nicotinamide N-oxide and nicotinuric acid in urine would be useful indices for an excessive nicotinamide intake.     

Pyridine nucleotide cycle and trigonelline (N-methylnicotinic acid) synthesis in developing leaves and fruits of Coffea arabica

We examined the biosynthesis of trigonelline in leaves and fruits of Arabica coffee ( Coffea arabica ) plants. [³H]Quinolinic acid, which is an intermediate of de novo pyridine nucleotide synthesis, and [¹⁴C]nicotinamide and [¹⁴C]nicotinic acid, which are degradation products of NAD, were converted to trigonelline and pyridine nucleotides. These tracer experiments suggest that the pyridine nucleotide cycle, nicotinamide → nicotinic acid → nicotinic acid mononucleotide (NaMN) → nicotinic acid adenine dinucleotide (NaAD) → NAD → nicotinamide mononucleotide (NMN) → nicotinamide, operates in coffee plants, and trigonelline is synthesized from nicotinic acid formed in the cycle. Trigonelline accumulated up to 18 µmol per leaf in developed young leaves, and then decreased with age. Although the biosynthetic activity of trigonelline from exogenously supplied [¹⁴C]nicotinamide was observed in aged leaves, the endogenous supply of nicotinamide may be limited, reducing the contents in these leaves. Trigonelline is synthesized and accumulated in fruits during development. The trigonelline synthesis in pericarps is much higher than that in seeds, but its content in seeds is higher than pericaps, so that some of the trigonelline synthesized in the pericarps may be transported to seeds. Trigonelline in seeds may be utilized during germination, as its content decreases. Trigonelline synthesis from [¹⁴C]nicotinamide was also found in Theobroma cacao plants, but instead of trigonelline, nicotinic acid-glucoside was synthesized from [¹⁴C]nicotinamide in Camellia sinensis plants.     

Niacin activates the G protein estrogen receptor (GPER)-mediated signalling

Nicotinic acid, also known as niacin, is the water soluble vitamin B3 used for decades for the treatment of dyslipidemic diseases. Its action is mainly mediated by the G protein-coupled receptor (GPR) 109A; however, certain regulatory effects on lipid levels occur in a GPR109A-independent manner. The amide form of nicotinic acid, named nicotinamide, acts as a vitamin although neither activates the GPR109A nor exhibits the pharmacological properties of nicotinic acid. In the present study, we demonstrate for the first time that nicotinic acid and nicotinamide bind to and activate the GPER-mediated signalling in breast cancer cells and cancer-associated fibroblasts (CAFs). In particular, we show that both molecules are able to promote the up-regulation of well established GPER target genes through the EGFR/ERK transduction pathway. As a biological counterpart, nicotinic acid and nicotinamide induce proliferative and migratory effects in breast cancer cells and CAFs in a GPER-dependent fashion. Moreover, nicotinic acid prevents the up-regulation of ICAM-1 triggered by the pro-inflammatory cytokine TNF-α and stimulates the formation of endothelial tubes through GPER in HUVECs. Together, our findings concerning the agonist activity for GPER displayed by both nicotinic acid and nicotinamide broaden the mechanisms involved in the biological action of these molecules and further support the potential of a ligand to induce different responses mediated in a promiscuous manner by distinct GPCRs.     

Pyridine metabolism in tea plants: salvage, conjugate formation and catabolism

Pyridine compounds, including nicotinic acid and nicotinamide, are key metabolites of both the salvage pathway for NAD and the biosynthesis of related secondary compounds. We examined the in situ metabolic fate of [carbonyl-¹⁴C]nicotinamide, [2-¹⁴C]nicotinic acid and [carboxyl-¹⁴C]nicotinic acid riboside in tissue segments of tea (Camellia sinensis) plants, and determined the activity of enzymes involved in pyridine metabolism in protein extracts from young tea leaves. Exogenously supplied ¹⁴C-labelled nicotinamide was readily converted to nicotinic acid, and some nicotinic acid was salvaged to nicotinic acid mononucleotide and then utilized for the synthesis of NAD and NADP. The nicotinic acid riboside salvage pathway discovered recently in mungbean cotyledons is also operative in tea leaves. Nicotinic acid was converted to nicotinic acid N-glucoside, but not to trigonelline (N-methylnicotinic acid), in any part of tea seedlings. Active catabolism of nicotinic acid was observed in tea leaves. The fate of [2-¹⁴C]nicotinic acid indicates that glutaric acid is a major catabolite of nicotinic acid; it was further metabolised, and carbon atoms were finally released as CO₂. The catabolic pathway observed in tea leaves appears to start with the nicotinic acid N-glucoside formation; this pathway differs from catabolic pathways observed in microorganisms. Profiles of pyridine metabolism in tea plants are discussed.     

A comparative study of the effects of nicotinamide and diethylnicotinamid on hepatic monooxygenase, glucuronyl and glutathione conjugating systems

The nicotinamide administration to rats (50 mg/kg, subcutaneously, over 5 days) increased the concentration of liver cytochrome b5, the activities of cytosol and microsomal glutathione S-transferase, UDP-glucuronosyltransferase and urinary excretion of bound glucuronic acid by 26.7, 33.1, 33.3, 53.0 and 31.0%, respectively. The chloral hydrate-induced sleep time in mice was reduced by 65%. Under similar experimental conditions the administration of equimolar amounts of diethylamide of nicotinic acid (75 mg/kg) exerted a more pronounced enzyme-stimulating effect. The cytochrome P-450 concentration, the activities of cytosol and microsomal glutathione S-transferase, UDP-glucuronosyltransferase as well as the sulphobromophthalein elimination from blood plasma and urinary excretion of bound glucuronic acid were increased by 37.0, 33.1, 54.6, 80.5, 24.5 and 49.0%, whereas the chloral hydrate-induced sleep time decreased by 75%. The nicotinamide and diethylamide of nicotinic acid stimulating effects on xenobiotic biotransformation in rat liver are assumed to be due to enhanced NADPH, glutathione and UDP-glucuronic acid biosynthesis as well as their antioxidant properties.     

Pyridine nucleotide metabolism in mammalian cells in culture

The biosynthesis of pyridine nucleotides has been examined in a number of mammalian cell lines in culture. In all lines examined, nicotinamide is incorporated by a biochemical pathway distinct from the Preiss-Handler pathway for nicotinic acid. In at least the human cell line D98/AH2, there is no detectable endogenous synthesis of the pyridine ring from tryptophan. Although most cell lines examined (hamster BHK 21/13, mouse L929 and human D98/AH2) use either nicotinic acid or nicotinamide as a precursor for DPN and TPN, two mouse cell lines, 3T3-4E and LM CIID, are unable to utilize nicotinic acid as a source of the pyridine ring. If nicotinic acid is present in the medium, substantial amounts of intracellular desamido DPN accumulate suggesting that the last step (desamido DPN→DPN) is limiting in the Preiss-Handler pathway. With nicotinamide, the only compound which accumulates in substantial amounts apart from DPN and TPN is nicotinamide ribose; there is no detectable NMN. The results of pulse-labeling experiments suggest that nicotinamide ribose may be an intermediate in the nicotinamide pathway. Following growth of D98/AH2 cells in high concentrations of niacin, biosynthesis of DPN from nicotinamide was completely inhibited for at least six hours. The converse experiment revealed no inhibition of niacin incorporation. This observation suggests that a niacin pathway intermediate, which present evidence indicates is desamido-DPN. can inhibit nicotinamide utilization. Newly synthesized DPN turns over with a half-life of two hours in azaserine-treated D98/AH2 cells. In the absence of azaserine, the nicotinamide moiety of newly synthesized DPN is lost from D98/AH2 cells to the medium with a half-life of eight hours. About 80% of the nicotinamide is lost to medium as nicotinamide ribose.     

Nitrile Hydratase-Catalyzed Production of Nicotinamide from 3-Cyanopyridine in Rhodococcus rhodochrous J1

Nitrile hydratase, which occurs abundantly in cells of Rhodococcus rhodochrous J1 isolated from soil samples, catalyzes the hydration of 3-cyanopyridine to nicotinamide. By using resting cells, the reaction conditions for nicotinamide production were optimized. Under the optimum conditions, 100% of the added 12 M 3-cyanopyridine was converted to nicotinamide without the formation of nicotinic acid, and the highest yield achieved was 1,465 g of nicotinamide per liter of reaction mixture containing resting cells (1.48 g as dry cell weight) in 9 h. The nicotinamide produced was crystallized and then identified physicochemically. The further conversion of the nicotinamide to nicotinic acid was due to the low activity of nicotinamide as a substrate for the amidase(s) present in this organism.     

Potential for use of nicotinic acid as a selective agent for isolation of high nicotine-producing lines of Nicotiana rustica hairy root cultures

The addition of exogenous nicotinic acid, nicotinamide or nicotine was studied with reference to their effects on growth and alkaloid production by hairy root cultures of Nicotiana rustica. Nicotinic acid and nicotinamide were toxic (50% phytostatic dose being 2.4 and 9 mM respectively) while nicotine was not toxic below 10 mM. Nicotinic acid (up to 5 mM) was found to be phytostatic rather than phytotoxic. Roots exposed to increasing nicotinic acid or nicotinamide levels had altered alkaloid accumulation patterns relative to the controls. The principal effects were to increase the intracellular and extracellular levels of anatabine and nicotine, with a markedly greater proportion of anatabine being produced. The use of nicotinic acid as a selection agent for the recovery of higher alkaloid-producing lines is identified and discussed.     

Identification of Isn1 and Sdt1 as Glucose- and Vitamin-regulated Nicotinamide Mononucleotide and Nicotinic Acid Mononucleotide 5��-Nucleotidases Responsible for Production of Nicotinamide Riboside and Nicotinic Acid Riboside

Recently, we discovered that nicotinamide riboside and nicotinic acid riboside are biosynthetic precursors of NAD⁺, which are utilized through two pathways consisting of distinct enzymes. In addition, we have shown that exogenously supplied nicotinamide riboside is imported into yeast cells by a dedicated transporter, and it extends replicative lifespan on high glucose medium. Here, we show that nicotinamide riboside and nicotinic acid riboside are authentic intracellular metabolites in yeast. Secreted nicotinamide riboside was detected with a biological assay, and intracellular levels of nicotinamide riboside, nicotinic acid riboside, and other NAD⁺ metabolites were determined by a liquid chromatography-mass spectrometry method. A biochemical genomic screen indicated that three yeast enzymes possess nicotinamide mononucleotide 5′-nucleotidase activity in vitro. Metabolic profiling of knock-out mutants established that Isn1 and Sdt1 are responsible for production of nicotinamide riboside and nicotinic acid riboside in cells. Isn1, initially classified as an IMP-specific 5′-nucleotidase, and Sdt1, initially classified as a pyrimidine 5′-nucleotidase, are additionally responsible for dephosphorylation of pyridine mononucleotides. Sdt1 overexpression is growth-inhibitory to cells in a manner that depends on its active site and correlates with reduced cellular NAD⁺. Expression of Isn1 protein is positively regulated by the availability of nicotinic acid and glucose. These results reveal unanticipated and highly regulated steps in NAD⁺ metabolism.     

Pyridine nucleotide cycle of Salmonella typhimurium: in vivo recycling of nicotinamide adenine dinucleotide

The relative contribution of the two known pyridine nucleotide cycles of Salmonella typhimurium towards the intracellular recycling of nicotinamide adenine dinucleotide was determined. The results indicate that intracellular nicotinamide adenine dinucleotide is recycled by both the four-membered pyridine nucleotide cycle (PNC IV) and the six-membered pyridine nucleotide cycle (PNC VI) with a relative contribution of 60 to 69% and 31 to 40%, respectively. These studies also revealed a nicotinic acid mononucleotide-degradative activity which converts nicotinic acid mononucleotide to nicotinic acid. This represents the first demonstration of a functional PNC IV pathway in S. typhimurium.     

Vitamin PP, nicotinamide nucleotides and neuro-muscular transmission in guinea pig cecum longitudinal muscle (taenia coli)

The membrane potential, inhibition postsynaptic potentials, resistance of the guinea pig taenia coli membrane were studied as affected by exogenic vitamin PP and its derivatives of nucleotide nature. It is shown that nicotinic acid, nicotinamide, NAD+, NADH, NADP+, NADPH evoke the membrane hyperpolarization and a decrease in the amplitude of the inhibition postsynaptic potentials. Nicotinamid dinucleotides cause a decrease in the membrane resistance, whereas nicotinic acid and nicotinamide do not affect this parameter. The character of the observed effects does not depend on the degree of nicotinamide dinucleotides oxidation.     

Pyridine nucleotide biosynthesis in Claviceps

Claviceps purpurea grown on synthetic medium incorporated labeled [7-¹⁴]nicotinic acid and [7-¹⁴C]nicotinamide into NaMN, des-NAD, NAD, and NADP. Label also appeared in NMN and N-methyl nicotinamide. The specific activities of NAD, NADP, and NMN are compatible with the operation of the Preiss-Handler pathway of NAD biosynthesis (nicotinic acid → NaMN → des-NAD → NAD → NADP). The relative amounts of NaMN:des-NAD:NAD and NADP were about 8:1:36:10 on incubation of Claviceps with nicotinic acid for 6 hr. The incorporation of nicotinamide into NAD proceeds mainly by conversion to nicotinic acid catalyzed by nicotinamide deamidase.Tryptophan ([U-¹⁴C]benzene ring) was incorporated into NAD demonstrating the presence of the tryptophan-nicotinic acid pathway. No qualitative difference in pyridine nucleotide intermediates was noted in C. purpurea CPM, which does not produce clavine alkaloids, and Claviceps 47A which does produce clavine alkaloids.