NAD(P) biosynthesis enzymes as potential targets for selective drug design.

NAD(P) biosynthetic pathways can be considered a generous source of enzymatic targets for drug development. Key reactions for NAD(P) biosynthesis in all organisms, common to both de novo and salvage routes, are catalyzed by NMN/NaMN adenylyltransferase (NMNAT), NAD synthetase (NADS), and NAD kinase (NADK). These reactions represent a three-step pathway, present in the vast majority of living organisms, which is responsible for the generation of both NAD and NADP cellular pools. The validation of these enzymes as drug targets is based on their essentiality and conservation among a large variety of pathogenic microorganisms, as well as on their differential structural features or their differential metabolic contribution to NAD(P) homeostasis between microbial and human cell types. This review describes the structural and functional properties of eubacterial and human enzymes endowed with NMNAT, NADS, and NADK activities, as well as with nicotinamide phosphoribosyltransferase (NamPRT) and nicotinamide riboside kinase (NRK) activities, highlighting the species-related differences, with emphasis on their relevance for drug design. In addition, since the overall NMNAT activity in humans is accounted by multiple isozymes differentially involved in the metabolic activation of antineoplastic compounds, their individual diagnostic value for early therapy optimization is outlined. The involvement of human NMNAT in neurodegenerative disorders and its role in neuroprotection is also discussed.

A rise in NAD precursor nicotinamide mononucleotide (NMN) after injury promotes axon degeneration.

NAD metabolism regulates diverse biological processes, including ageing, circadian rhythm and axon survival. Axons depend on the activity of the central enzyme in NAD biosynthesis, nicotinamide mononucleotide adenylyltransferase 2 (NMNAT2), for their maintenance and degenerate rapidly when this activity is lost. However, whether axon survival is regulated by the supply of NAD or by another action of this enzyme remains unclear. Here we show that the nucleotide precursor of NAD, nicotinamide mononucleotide (NMN), accumulates after nerve injury and promotes axon degeneration. Inhibitors of NMN-synthesising enzyme NAMPT confer robust morphological and functional protection of injured axons and synapses despite lowering NAD. Exogenous NMN abolishes this protection, suggesting that NMN accumulation within axons after NMNAT2 degradation could promote degeneration. Ectopic expression of NMN deamidase, a bacterial NMN-scavenging enzyme, prolongs survival of injured axons, providing genetic evidence to support such a mechanism. NMN rises prior to degeneration and both the NAMPT inhibitor FK866 and the axon protective protein Wld(S) prevent this rise. These data indicate that the mechanism by which NMNAT and the related Wld(S) protein promote axon survival is by limiting NMN accumulation. They indicate a novel physiological function for NMN in mammals and reveal an unexpected link between new strategies for cancer chemotherapy and the treatment of axonopathies.

Structure and function of nicotinamide mononucleotide adenylyltransferase.

The enzyme nicotinamide mononucleotide adenylyltransferase (NMNAT), a member of the nucleotidyltransferase alpha/beta phosphodiesterase superfamily, catalyzes the reaction NMN + ATP = NAD + PPi, representing the final step in the biosynthesis of NAD, a molecule playing a fundamental role as a cofactor in cellular redox reactions. NAD also serves as the substrate for reactions involved in important regulatory roles, such as protein covalent modifications, like ADP-ribosylation reactions, as well as Sir2 histone deacetylase, a recently discovered class of enzymes involved in the regulation of gene silencing. This overview describes the most recent findings on NMNATs from bacteria, archaea, yeast, animal and human sources, with detailed consideration of their major kinetic, molecular and structural features. On this regard, the different characteristics exhibited by the enzyme from the various species are highlighted. The possibility that NMNAT may represent an interesting candidate as a target for the rational design of selective chemotherapeutic agents has been suggested.

NAD+ catabolism in pheochromocytoma rat cells.

The catabolic pathway of nicotinamide adenin dinucleotide (NAD) in cultured pheochromocytoma rat cells (PC12) was investigated. The first evidence obtained in these studies was that, despite inducing cell differentiation, NGF treatment did not modify NAD catabolism. Following incubation of PC12 homogenate with NAD, ADP-ribose, AMP, IMP, and HYP was produced. The catabolic fate of AMP and ADPR so obtained was followed by monitoring to a final production of inosine and hypoxanthine through several enzymatic steps. When intact PC12 cells were incubated with NAD in the culture medium AMP, IMP and HYP were found but, no ADPR and cADPR were present in the growth medium. "Nucleotides analyses" carried out on the homogenate obtained from these cells, confirmed the absence of cADPR and an increase of intracellular ADPR. These results led us to believe that in PC12 cells the ADP ribosyl cyclase activity is absent and that NADase is an ecto-enzyme able to transfer the ADPR, produced from NAD catabolism, inside the cells.

NAD(P)(+)-glycohydrolase from human spleen: a multicatalytic enzyme.

NAD(P)(+)-glycohydrolase (NADase, EC 3.2.2.6) was partially purified from microsomal membranes of human spleen after solubilization with Triton X-100. In addition to NAD+ and NADP+, the enzyme catalyzed the hydrolysis of several NAD+ analogues and the pyridine base exchange reaction with conversion of NAD+ into 3-acetylpyridine adenine dinucleotide. The enzyme also catalyzed the synthesis of cyclic ADP-ribose (cADPR) from NAD+ and the hydrolysis of cADPR to adenosine diphosphoribose (ADPR). Therefore, this enzyme is a new member of multicatalytic NADases recently identified from mammals, involved in the regulation of intracellular cADPR concentration. Human spleen NADase showed a subunit molecular mass of 45 kDa, a pI of 4.9 and a Km value for NAD+ of 26 microM. High activation of ADPR cyclase activity was observed in the presence of Ag+ ions, corresponding to NADase inhibition.

Enzymology of NAD+ homeostasis in man.

This review describes the enzymes involved in human pyridine nucleotide metabolism starting with a detailed consideration of their major kinetic, molecular and structural properties. The presentation encompasses all the reactions starting from the de novo pyridine ring formation and leading to nicotinamide adenine dinucleotide (NAD(+)) synthesis and utilization. The regulation of NAD(+) homeostasis with respect to the physiological role played by the enzymes both utilizing NAD(+) through the nonredox NAD(+)-dependent reactions and catalyzing the recycling of the common product, nicotinamide, is discussed. The salient features of other enzymes such as NAD(+) pyrophosphatase, nicotinamide mononucleotide 5'-nucleotidase, nicotinamide riboside kinase and nicotinamide riboside phosphorylase, described under 'miscellaneous', are likewise presented.

Phytotoxic protein PcF, purification, characterization, and cDNA sequencing of a novel hydroxyproline-containing factor secreted by the strawberry pathogen Phytophthora cactorum.

A novel protein factor, named PcF, has been isolated from the culture filtrate of Phytophthora cactorum strain P381 using a highly sensitive leaf necrosis bioassay with tomato seedlings. Isolated PcF protein alone induced leaf necrosis on its host strawberry plant. The primary structure and cDNA sequence of this novel phytotoxic protein was determined, and BLAST searches of Swiss-Prot, EMBL, and GenBank(TM)/EBI data banks showed that PcF shared no significant homology with other known sequences. The 52-residue PcF protein, which contains a 4-hydroxyproline residue along with three S-S bridges, exhibits a high content of acidic sidechains, accounting for its isoelectric point of 4.4. The molecular mass of isolated PcF is 5,622 +/- 0.5 Da as determined by mass spectrometry and matches that calculated from the deduced amino acid sequence with cDNA sequencing. The cDNA sequence indicates that PcF is first produced as a larger precursor, comprising an additional N-terminal, 21-residue secretory signal peptide. Maturation of this protein involves the hydroxylation of proline 49, a feature that is unique among other known secreted fungal phytopathogenic proteins.

PcF protein from Phytophthora cactorum and its recombinant homologue elicit phenylalanine ammonia lyase activation in tomato.

The phytotoxic protein PcF (Phytophthora cactorum-Fragaria) is a 5.6-kDa cysteine-rich, hydroxyproline-containing protein that is secreted in limited amounts by P. cactorum, an oomycete pathogen of tomato, strawberry and other relevant crop plants. Although we have shown that pure PcF triggers plant reactivity, its mechanism of action is not yet understood. Here we show that PcF, like other known fungal protein elicitors involved in pathogen-plant interaction, stimulates the activity of the defense enzyme phenylalanine ammonia lyase (EC 4.3.1.5) in tomato seedlings. Recognizing that a key step in understanding the mechanism of action of PcF at a molecular level is knowledge of its three-dimensional structure, we overexpressed this protein extracellularly in Pichia pastoris. The preliminary structural and functional characterization of a recombinant PcF homologue, N4-rPcF, is reported. Interestingly, although N4-rPcF is devoid of proline hydroxylation and has four additional amino acid residues attached to its N terminus, its secondary structure and biological activity are indistinguishable from wild-type PcF.

NMN adenylyltransferase from bull testis: purification and properties.

The purification procedure of NMN adenylyltransferase from bull testis presented here consists of a heat step and an acidic precipitation followed by four chromatographic steps, including dye ligand, adsorption and hydrophobic chromatography. The final enzyme preparation subjected to non-denaturing and denaturating PAGE with silver nitrate staining exhibited a single band. At this step the enzyme appeared to be homogeneous. The M(r) value of the native enzyme calculated by gel filtration was about 133,000. The protein appeared to possess a quaternary structure with four subunits of apparent M(r) 33,000 without disulphide interchain bonds. Isoelectric experiments gave a pI of 6.2, and pH studies showed the possible presence of an acidic group in the active site having a pKa of 4.9. Analysis of the amino acid composition showed the presence of more acidic residues than basic ones, according to the pI value calculated by Mono P FPLC. The Ea calculated by Arrhenius plot gave an apparent value of 55.7 kJ/mol. The Km values for NMN, ATP, NAD+ and PPi were 0.11, 0.023, 0.37 and 0.16 nM respectively. The polyclonal antiserum produced against the NMN adenylyltransferase reacted with the purified enzyme at different dilutions and recognized the enzyme in the homogenate as well.

Assay methods for nicotinamide mononucleotide adenylyltransferase of wide applicability.

NMN adenylyltransferase (NMNAT) reversibly catalyzes the synthesis of NAD+ or NaAD+ from ATP and NMN or NaMN. In this work, we describe a continuous coupled spectrophotometric assay that can be rapidly and routinely used in place of the previous cumbersome two-step assay. The reaction rates measured with the coupled assay display a linear dependence with respect to enzyme concentration over the range investigated. The method yields accurate and reliable estimates of the enzyme activity in the direction of NAD+ synthesis. Furthermore, we developed an HPLC-based method suitable for the assay activity both in the forward and reverse directions of the enzymatic reaction. The method appears particularly useful for measuring the NMNAT activity when the product is not NAD+ (e.g., in studies using alternative substrates), and offers the possibility of monitoring simultaneously both the NMNAT-catalyzed reaction and interfering side reactions. This is achieved through the HPLC identification and quantitation of metabolites and derivatives produced in the reaction mixture during the assay. The two methods described here should cover most needs for the assay of NMNAT activity.