Metabolism of the pyridine nucleotides involved in nicotinamide adenine dinucleotide biosynthesis by Clostridium butylicum

In order to elucidate the mechanism of the accumulation of considerable amounts of free nicotinic acid (NA) in the culture medium of Clostridium butylicum, this organism was investigated with regard to its ability to metabolize nicotinamide adenine dinucleotide (NAD) and its immediate biosynthetic precursors, nicotinic acid mononucleotide (NAMN) and nicotinic acid adenine dinucleotide (deamido-NAD). Cell-free extracts of C. butylicum were found to degrade NAMN and deamido-NAD to NA. NAMN, in the presence of adenosine triphosphate (ATP), was converted to deamido-NAD, but only at high concentrations of ATP (20 mM) was significant synthetic activity observed in competition with NAMN degradation. Degradation of both NAMN and deamido-NAD was activated by ATP at concentrations of 5 and 10 mm. Anaerobiosis markedly enhanced the degradation of the nucleotides. The data indicate that the synthesis of NAMN and deamido-NAD prevails over their degradation only in the presence of high concentrations of ATP. NAD was degraded to nicotinamide mononucleotide (NMN) by a pyrophosphatase. Phosphate markedly inhibited both the deamido-NAD and NAD pyrophosphatases. Under anaerobic conditions there was practically no further degradation of NMN to NA, whereas barely measurable amounts of NA were formed under aerobic conditions. All of these observations suggest that, under the given conditions of anaerobiosis and physiological phosphate concentrations, there is very little degradation of NAD to NMN and practically no degradation to NA by C. butylicum. Thus, NAD represents an insignificant source of the NA accumulated in the culture medium. The intermediates in the biosynthetic pathway (NAMN and deamido-NAD) have been shown to be the major source of the NA which is accumulated by C. butylicum.     

Generation,Release, and Uptake of the NAD Precursor Nicotinic Acid Riboside by Human Cells

NAD is essential for cellular metabolism and has a key role in various signaling pathways in human cells. To ensure proper control of vital reactions, NAD must be permanently resynthesized. Nicotinamide and nicotinic acid as well as nicotinamide riboside (NR) and nicotinic acid riboside (NAR) are the major precursors for NAD biosynthesis in humans. In this study, we explored whether the ribosides NR and NAR can be generated in human cells. We demonstrate that purified, recombinant human cytosolic 5′-nucleotidases (5′-NTs) CN-II and CN-III, but not CN-IA, can dephosphorylate the mononucleotides nicotinamide mononucleotide and nicotinic acid mononucleotide (NAMN) and thus catalyze NR and NAR formation in vitro. Similar to their counterpart from yeast, Sdt1, the human 5′-NTs require high (millimolar) concentrations of nicotinamide mononucleotide or NAMN for efficient catalysis. Overexpression of FLAG-tagged CN-II and CN-III in HEK293 and HepG2 cells resulted in the formation and release of NAR. However, NAR accumulation in the culture medium of these cells was only detectable under conditions that led to increased NAMN production from nicotinic acid. The amount of NAR released from cells engineered for increased NAMN production was sufficient to maintain viability of surrounding cells unable to use any other NAD precursor. Moreover, we found that untransfected HeLa cells produce and release sufficient amounts of NAR and NR under normal culture conditions. Collectively, our results indicate that cytosolic 5′-NTs participate in the conversion of NAD precursors and establish NR and NAR as integral constituents of human NAD metabolism. In addition, they point to the possibility that different cell types might facilitate each other''s NAD supply by providing alternative precursors.     

Pyridine nucleotide synthesis in 3T3 cells.

The biosynthesis of NAD has been examined in 3T3 cells. The net synthesis of pyridine nucleotides does not occur when cells are cultured in the absence of performed pyridine ring compounds; however, growth continues normally for up to four cell doublings resulting in cells with a total pyridine nucleotide content that is reduced by as much as 12-fold. The mechanism that adjust the relative amounts of NADP and NAD are also altered such that the amount of NADP relative to NAD increases 5-fold. Both nicotinate and nicotinamide can be used as a precursor for NAD biosynthesis, however nicotinate is utilized less efficiently than nicotinamide. The presence of functional pathways for the biosynthesis of NAD from nicotinate via nicotinate mononucleotide and nicotinate adenine dinucleotide and from nicotinamide via nicotinamide mononucleotide has been demonstrated by identification of biosynthetic intermediates following short term exposure of cells to radiolabelled precursors. When cells are grown in Dulbecco's modified Eagle's medium which contains 33 μM nicotinamide the biosynthesis of NAD proceeds by a single pathway with nicotinamide mononucleotide as the only intermediate. Nicotinamide ribonucleoside which previously has been postulated to be an intermediate in the conversion of nicotinamide to NAD is not an intermediate in NAD biosynthesis.     

Formation of the N'-methylnicotinamide adenine dinucleotide derivative of NAD in intact rat pituitary tumor GH3 and human promyelocytic leukemia HL-60 cells

The NAD analog N'-methylnicotinamide adenine dinucleotide (N'AD) is formed in intact human promyelocytic leukemia HL-60 and in rat pituitary tumor GH3 cells during treatment of the cultured cells with the nicotinamide derivative N'-methylnicotinamide (N'CH3NAm). N'AD formation is associated with the induced maturation of HL-60 cells and increased hormone production by GH3 cells during treatment with the nicotinamide derivative. N'AD is detected by HPLC analysis of cytoplasmic extracts as a peak which elutes near NAD. Four facts indicate that this compound is N'AD. First, a compound which elutes with identical time retention is produced by transglycosylation during reaction of NAD with pig brain NAD glycohydrolase in the presence of excess N'CH3NAm. Second, the putative N'AD is degraded by prolonged digestion with the NAD glycohydrolase to ADP-ribose. Third, N'AD formation is prevented by addition of nicotinamide along with N'CH3NAm to compete with binding of N'CH3NAm to the NAD glycohydrolase. Fourth, radioactive precursor labeling demonstrates that it contains adenosine, but it is not labeled by radioactive nicotinamide. The biological relevance of N'AD formation was evaluated. The appearance of N'AD precedes development of HL-60 maturation, and NAD levels increase, not decrease, as observed in other cell types, during treatment with N'CH3NAm. Therefore, we propose that N'AD, not the pyridine base itself, is the active species in inducing maturation. The results provide support of a role for NAD metabolism, probably ADP-ribosylation, in the regulation of HL-60 maturation and in hormone production by pituitary cells.     

Genetic characterization of pyridine nucleotide uptake mutants of Salmonella typhimurium

Two classes of pyridine nucleotide uptake mutants isolated previously in a strain of Salmonella typhimurium defective in both de novo NAD biosynthesis (nad) and pyridine nucleotide recycling (pncA) were analysed in terms of their genetic relationship to each other and their roles in the transport of nicotinamide mononucleotide as a precursor to NAD. The first class of uptake mutants, pnuA (99 units), failed to grow on nicotinamide mononucleotide (NMN) as a precursor for NAD. The second class, pnuB, grew on lower than normal levels of NMN and suppressed pnuA mutations. A third class of uptake mutant, pnuC, isolated in a nadB pncA pnuB background, also failed to grow on NMN. Transport studies and enzyme analyses confirmed these strains as defective in NMN uptake. A fourth locus, designated pnuD, was found to diminish NMN utilization in a nad pncA+ background. Tn10 insertions near pnuA, pnuC and pnuD were isolated and utilized in mapping studies. pnuA was found to map between thr and serB near trpR. The pnuC locus was cotransducible with nadA at 17 units while pnuD mapped at approximately 60 units. The biochemical and genetic data suggest that the pnuA and pnuC gene products cooperate in the utilization of NMN under normal conditions. A pnuB mutant, however, does not require the pnuA gene product for NMN uptake but does rely on the pnuC product. Fusion studies indicate that pnuC is regulated by internal NAD concentrations.     

Nicotinamide modulation of rat pancreatic islet cell responsiveness in vitro.

The influence of nicotinamide (NA), a highly suitable precursor substrate for NAD synthesis in various tissues, on islet cell responsiveness was determined. After a 30 minute perifusion with this compound, nicotinamide, in a dose-dependent manner, potentiated glucose-induced insulin secretion. Maximal potentiation (approximately 250%) was observed at 20 mM NA and the threshold for potentiation was 3 mM. In the absence of glucose, NA did not affect basal secretion rates. Mannoheptulose blocked the primary stimulant action of glucose and the potentiating effects of NA. NA did not alter the rate of glucose usage by isolated islets. These results further underscore the possible importance of pyridine nucleotides in stimulated secretion.     

Amplification of pyridine nucleotide pools in mitogen-stimulated human lymphocytes

NAD⁺ levels in resting human lymphocytes obtained from 20 donors were found to be 69.9 ± 21.7 pmols/10⁶ cells. After 3 days of phytohemagglutinin (PHA) stimulation the NAD⁺ levels rose to 452 ± 198 pmols/10⁶ cells. NADH, NADP⁺ and NADPH also increased in mitogen-stimulated lymphocytes, but the major portion of the increase in total pyridine nucleotide pools was accounted for by the increase in NAD⁺. When PHA-stimulated lymphocytes were incubated in nicotinamide-deficient growth medium, there was no significant increase in their total pyridine nucleotide pools; however, the ratios of oxidized to reduced pyridine nucleotides changed in a similar fashion to cells grown in medium containing nicotinamide. When lymphocytes in nicotinamide-deficient medium were stimulated with PHA they increased their levels of DNA synthesis and cell replication in a similar fashion to cells growing in nicotinamide-supplemented media. Human lymphocytes were able to synthesize pyridine nucleotides from nicotinamide or nicotinic acid; however, in the absence of a preformed pyridine ring they did not efficiently use tryptophan for the synthesis of NAD. Uptake of [carbonyl-¹⁴C]nicotinamide and conversion to NAD was markedly increased in PHA-stimulated lymphocytes; these cells also showed a marked increase in activity of the enzyme adenosine-triphosphate-nicotinamide mononucleotide (ATP-NMN) adenylyl transferase.     

Pyridine nucleotide cycle of Salmonella typhimurium: in vitro demonstration of nicotinamide mononucleotide deamidase and characterization of pnuA mutants defective in nicotinamide mononucleotide transport.

The enzyme nicotinamide mononucleotide deamidase, an integral component of the proposed four-membered pyridine nucleotide cycle (PNC IV), has been demonstrated in extracts of Salmonella typhimurium LT2. The enzyme has an optimum pH of 8.7 and deamidates nicotinamide mononucleotide, forming nicotinic acid mononucleotide. Sigmoidal kinetic data suggest that this enzyme may be allosteric and therefore an important regulatory component of pyridine nucleotide cycle metabolism. Mutants previously designated pncC in anticipation of their lacking nicotinamide mononucleotide deamidase were examined and found to have normal levels of this enzyme. [14C]nicotinamide mononucleotide uptake studies, however, revealed a defect in the transport of this compound. Accordingly, the genetic designation for this locus was changed to pnuA to reflect its involvement in pyridine nucleotide uptake. Evidence is presented for the existence of two separate nicotinamide mononucleotide transport systems.     

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.     

Assimilation of nicotinamide mononucleotide requires periplasmic AphA phosphatase in Salmonella enterica

Salmonella enterica can obtain pyridine from exogenous nicotinamide mononucleotide (NMN) by three routes. In route 1, nicotinamide is removed from NMN in the periplasm and enters the cell as the free base. In route 2, described here, phosphate is removed from NMN in the periplasm by acid phosphatase (AphA), and the produced nicotinamide ribonucleoside (NmR) enters the cell via the PnuC transporter. Internal NmR is then converted back to NMN by the NmR kinase activity of NadR. Route 3 is seen only in pnuC* transporter mutants, which import NMN intact and can therefore grow on lower levels of NMN. Internal NMN produced by either route 2 or route 3 is deamidated to nicotinic acid mononucleotide and converted to NAD by the biosynthetic enzymes NadD and NadE.     

NadN and e (P4) are essential for utilization of NAD and nicotinamide mononucleotide but not nicotinamide riboside in Haemophilus influenzae

Haemophilus influenzae has an absolute requirement for NAD (factor V) because it lacks almost all the biosynthetic enzymes necessary for the de novo synthesis of that cofactor. Factor V can be provided as either nicotinamide adenosine dinucleotide (NAD), nicotinamide mononucleotide (NMN), or nicotinamide riboside (NR) in vitro, but little is known about the source or the mechanism of uptake of these substrates in vivo. As shown by us earlier, at least two gene products are involved in the uptake of NAD, the outer membrane lipoprotein e (P4), which has phosphatase activity and is encoded by hel, and a periplasmic NAD nucleotidase, encoded by nadN. It has also been observed that the latter gene product is essential for H. influenzae growth on media supplemented with NAD. In this report, we describe the functions and substrates of these two proteins as they act together in an NAD utilization pathway. Data are provided which indicate that NadN harbors not only NAD pyrophosphatase but also NMN 5'-nucleotidase activity. The e (P4) protein is also shown to have NMN 5'-nucleotidase activity, recognizing NMN as a substrate and releasing NR as its product. Insertion mutants of nadN or deletion and site-directed mutants of hel had attenuated growth and a reduced uptake phenotype when NMN served as substrate. A hel and nadN double mutant was only able to grow in the presence of NR, whereas no uptake of NMN was observed.     

The hydrolysis of nicotinamide adenine nucleotide by brush border membranes of rat intestine.

The hydrolysis of NAD by rat intestine was studied to determine the subcellular site of this hydrolysis and to identify the niacin-containing products that are formed. Using [nicotinamide-14C]NAD as substrate, and high pressure liquid chromatography for identification and quantification of products, the present study demonstrates two independent reactions for the hydrolysis of NAD; one that forms nicotinamide through hydrolysis of the ribosyl-pyridinium bond and one that forms nicotinamide mononucleotide through the hydrolysis of the pyrophosphate bond. The nicotinamide mononucleotide is subsequently dephosphorylated to nicotinamide riboside. Enzymes which release nicotinamide mononucleotide and nicotinamide riboside are associated with the brush border membrane as determined by analysis of fractionated intestinal homogenates. The enzyme activity which releases nicotinamide from NAD is associated with the brush border membrane fraction and also with a second cellular particulate fraction. Between pH5 and pH6 NAD is hydrolysed principally to nicotinamide. At pH 7.0 rates of nicotinamide and nicotinamide mononucleotide formation are the same. Above pH 7.0 the formation of nicotinamide mononucleotide is preferred.     

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.     

Reactivation of NAD(H) biosynthetic pathway by exogenous NAD+ in Nil cells severely depleted of NAD(H)

The culture of Nil hamster fibroblasts in MEM lacking nicotinamide (NAm-MEM) leads to: (1) the rapid loss of intracellular total nicotinamide adenine dinucleotide (NAD(H)) content in these cells from a level of 150-200 pmoles/10(5) cells to less than 20 pmoles/10(5) cells; (2) the cessation of cell division and inhibition of DNA synthesis; and (3) a reduction of glucose consumption and lactic acid production. In most situations, following nicotinamide starvation, the restoration of intracellular NAD(H) follows rapidly the readdition of NAD+ (oxidized), nicotinamide mononucleotide (NMN), nicotinamide, or nicotinic acid. Resumption of cell division occurs after only a lag of about 24 hours. Nil cells subcultured for three consecutive times in the absence of nicotinamide (3(0) NAm- cells) exhibit different behavior. These severely starved cells are incapable of quickly restoring their intracellular NAD(H) content to normal levels when provided with any pyridine ring compound except NAD+. One-hour exposure of such cells to NAD+ allows utilization of nicotinamide to rapidly restore intracellular NAD(H). This short incubation with NAD+ does not result in any significant restoration of intracellular NAD(H) or lead to the accumulation of an intracellular pool of some precursor. This function of NAD+ as a stimulatory signal to the NAD(H)-biosynthetic pathway in severely starved Nil cells is a previously unreported role of NAD+, and does not require protein synthesis.     

Salmonella typhimurium mutants lacking NAD pyrophosphatase.

NAD can serve as both a purine and a pyridine source for Salmonella typhimurium. Exogenous NAD is rapidly broken down into nicotinamide mononucleotide and AMP by an NAD pyrophosphatase, the first step in the pathway for the assimilation of exogenous NAD. We isolated and characterized mutants of S. typhimurium lacking NAD pyrophosphatase activity; such mutants were identified by their failure to use exogenous NAD as a purine source. These mutants carry mutations that map at a new locus, designated pnuE, between 86 and 87 min on the Salmonella chromosome.     

Pyridine nucleotide cycle of Salmonella typhimurium: isolation and characterization of pncA, pncB, and pncC mutants and utilization of exogenous nicotinamide adenine dinucleotide.

Mutants of Salmonella typhimurium LT-2 deficient in nicotinamidase activity (pncA) or nicotinic acid phosphoribosyltransferase activity (pncB) were isolated as resistant to analogs of nicotinic acid and nicotinamide. Information obtained from interrupted mating experiments placed the pncA gene at 27 units and the pncB gene at 25 units on the S. typhimurium LT-2 linkage map. A major difference in the location of the pncA gene was found between the S. typhimurium and Escherichia coli linkage maps. The pncA gene is located in a region in which there is a major inversion of the gene order in S. typhimurium as compared to that in E. coli. Growth experiments using double mutants blocked in the de novo pathway to nicotinamide adenine dinucleotide (NAD) (nad) and in the pyridine nucleotide cycle (pnc) at either the pncA or pncB locus, or both, have provided evidence for the existence of an alternate recycling pathway in this organism. Mutants lacking this alternate cycle, pncC, have been isolated and mapped via cotransduction at 0 units. Utilization of exogenous NAD was examined through the use of [14C]carbonyl-labeled NAD and [14C]adenine-labeled NAD. The results of these experiments suggest that NAD is degraded to nicotinamide mononucleotide at the cell surface. A portion of this extracellular nicotinamide mononucleotide is then transported across the cell membrane by nicotinamide mononucleotide glycohydrolase and degraded to nicotinamide in the process. The remaining nicotinamide mononucleotide accumulates extracellularly and will support the growth of nadA pncB mutants which cannot utilize the nicotinamide resulting from the major pathway of NAD degradation. A model is presented for the utilization of exogenous NAD by S. typhimurium LT-2.     

NAD metabolism in Vibrio cholerae.

Extracts of Vibrio cholerae were assayed for various enzymatic activities associated with pyridine nucleotide cycle metabolism. The activities measured include NAD glycohydrolase, nicotinamide deamidase, nicotinamide mononucleotide deamidase, and nicotinic acid phosphoribosyltransferase. The results obtained demonstrate the existence in V. cholerae of the five-membered pyridine nucleotide cycle and the potential for a four-membered pyridine nucleotide cycle. The data presented also suggest that most of the NAD glycohydrolase in V. cholerae extracts is not directly related to cholera toxin.     

Phosphate-responsive signaling pathway is a novel component of NAD+ metabolism in Saccharomyces cerevisiae

Nicotinamide adenine dinucleotide (NAD(+)) is an essential cofactor involved in various cellular biochemical reactions. To date the signaling pathways that regulate NAD(+) metabolism remain unclear due to the dynamic nature and complexity of the NAD(+) metabolic pathways and the difficulty of determining the levels of the interconvertible pyridine nucleotides. Nicotinamide riboside (NmR) is a key pyridine metabolite that is excreted and re-assimilated by yeast and plays important roles in the maintenance of NAD(+) pool. In this study we establish a NmR-specific reporter system and use it to identify yeast mutants with altered NmR/NAD(+) metabolism. We show that the phosphate-responsive signaling (PHO) pathway contributes to control NAD(+) metabolism. Yeast strains with activated PHO pathway show increases in both the release rate and internal concentration of NmR. We further identify Pho8, a PHO-regulated vacuolar phosphatase, as a potential NmR production factor. We also demonstrate that Fun26, a homolog of human ENT (equilibrative nucleoside transporter), localizes to the vacuolar membrane and establishes the size of the vacuolar and cytosolic NmR pools. In addition, the PHO pathway responds to depletion of cellular nicotinic acid mononucleotide (NaMN) and mediates nicotinamide mononucleotide (NMN) catabolism, thereby contributing to both NmR salvage and phosphate acquisition. Therefore, NaMN is a putative molecular link connecting the PHO signaling and NAD(+) metabolic pathways. Our findings may contribute to the understanding of the molecular basis and regulation of NAD(+) metabolism in higher eukaryotes.     

Activity of NMN+, nicotinamide ribose and analogs in alcohol oxidation promoted by horse-liver alcohol dehydrogenase. Improvement of this activity and structural requirements of the pyridine nucleotide part of the NAD+ coenzyme

Kinetic constants of horse-liver alcohol-dehydrogenase-mediated oxidation of alcohol by nicotinamide mononucleotide and nicotinamide ribose were determined and the role of different adenine moieties complementing the reaction mixtures was investigated. Five nicotinamide ribose analogs were synthesized and their activities as NAD+ inhibitors and as cofactors in this dehydrogenase-mediated oxidation of alcohol were assayed. In the light of these results, structural requirements of the pyridine ribofuranosyl part of the NAD+ are discussed.