Crystal structure of human nicotinic acid phosphoribosyltransferase.

Nicotinic acid phosphoribosyltransferase (EC 2.4.2.11) (NaPRTase) is the rate-limiting enzyme in the three-step Preiss-Handler pathway for the biosynthesis of NAD. The enzyme catalyzes the conversion of nicotinic acid (Na) and 5-phosphoribosyl-1-pyrophosphate (PRPP) to nicotinic acid mononucleotide (NaMN) and pyrophosphate (PPi). Several studies have underlined the importance of NaPRTase for NAD homeostasis in mammals, but no crystallographic data are available for this enzyme from higher eukaryotes. Here, we report the crystal structure of human NaPRTase that was solved by molecular replacement at a resolution of 2.9 Å in its ligand-free form. Our structural data allow the assignment of human NaPRTase to the type II phosphoribosyltransferase subfamily and reveal that the enzyme consists of two domains and functions as a dimer with the active site located at the interface of the monomers. The substrate-binding mode was analyzed by molecular docking simulation and provides hints into the catalytic mechanism. Moreover, structural comparison of human NaPRTase with the other two human type II phosphoribosyltransferases involved in NAD biosynthesis, quinolinate phosphoribosyltransferase and nicotinamide phosphoribosyltransferase, reveals that while the three enzymes share a conserved overall structure, a few distinctive structural traits can be identified. In particular, we show that NaPRTase lacks a tunnel that, in nicotinamide phosphoribosiltransferase, represents the binding site of its potent and selective inhibitor FK866, currently used in clinical trials as an antitumoral agent.

The enzymology of cytosolic pyrimidine 5'-nucleotidases: functional analysis and physiopathological implications.

In mammals, cellular 5'-nucleotidase (5'-NT) activity (EC 3.1.3.5) encompasses a number of genetically and structurally distinct enzyme forms, either membrane-bound or soluble, mainly cytosolic, that are characterized by broad specificity towards nucleoside 5'-monophosphate substrates differing in base (purine/pyrimidine) and/or sugar (oxy/deoxy-ribose) moieties. In particular, among the cytosolic 5'-NTs active towards pyrimidine nucleotides are cN-III and cdN, ubiquitously distributed in mammalian tissues and treated as a single entity in the early days. cN-III was first linked to a genetic defect , hereditary pyrimidine nucleotidase deficiency, associated to a nonspherocyt ic hemolytic anemia disorder of still unclear mechanism but metabolically characterized by abnormally high levels of pyrimidine compounds and ribonucleoproteins in erythrocytes, as evidenced by occurrence of basophilic stippling on blood smearings. Since the first review on pyrimidine-specific nucleotidases (Amici, A.; Magni, G., Arch. Biochem. Biophys., 2002, 397(2), 184- 190), excellent overviews on the topic appeared in the literature. In the present contribution, the major findings on these two enzymatic proteins, cN-III and cdN, will be described with particular emphasis on the relationships between their structure and function, as well as on their roles in normal and pathological conditions. The catalytic mechanism of both specific hydrolytic and phosphotransferase activities, possessed by both enzymes, will be discussed also in the light of recent solution of both cN-III and cdN three-dimensional structures. This review also focuses on possible therapeutic approaches involving cellular 5'-NTs in detoxifying common antiviral and antineoplastic drugs.

Characterization of human nicotinate phosphoribosyltransferase: Kinetic studies, structure prediction and functional analysis by site-directed mutagenesis.

Nicotinate phosphoribosyltransferase (NaPRT, EC 2.4.2.11) catalyzes the conversion of nicotinate (Na) to nicotinate mononucleotide, the first reaction of the Preiss-Handler pathway for the biosynthesis of NAD(+). Even though NaPRT activity has been described to be responsible for the ability of Na to increase NAD(+) levels in human cells more effectively than nicotinamide (Nam), so far a limited number of studies on the human NaPRT have appeared. Here, extensive characterization of a recombinant human NaPRT is reported. We determined its major kinetic parameters and assayed the influence of different compounds on its enzymatic activity. In particular, ATP showed an apparent dual stimulation/inhibition effect at low/high substrates saturation, respectively, consistent with a negative cooperativity model, whereas inorganic phosphate was found to act as an activator. Among other metabolites assayed, including nucleotides, nucleosides, and intermediates of carbohydrates metabolism, some showed inhibitory properties, i.e. CoA, several acyl-CoAs, glyceraldehyde 3-phosphate, phosphoenolpyruvate, and fructose 1,6-bisphosphate, whereas dihydroxyacetone phosphate and pyruvate exerted a stimulatory effect. Furthermore, in light of the absence of crystallographic data, we performed homology modeling to predict the protein three-dimensional structure, and molecular docking simulations to identify residues involved in the recognition and stabilization of several ligands. Most of these residues resulted universally conserved among NaPRTs, and, in this study, their importance for enzyme activity was validated through site-directed mutagenesis.

Selective inhibition of nicotinamide adenine dinucleotide kinases by dinucleoside disulfide mimics of nicotinamide adenine dinucleotide analogues.

Diadenosine disulfide (5) was reported to inhibit NAD kinase from Listeria monocytogenes and the crystal structure of the enzyme-inhibitor complex has been solved. We have synthesized tiazofurin adenosine disulfide (4) and the disulfide 5, and found that these compounds were moderate inhibitors of human NAD kinase (IC(50)=110 microM and IC(50)=87 microM, respectively) and Mycobacterium tuberculosis NAD kinase (IC(50)=80 microM and IC(50)=45 microM, respectively). We also found that NAD mimics with a short disulfide (-S-S-) moiety were able to bind in the folded (compact) conformation but not in the common extended conformation, which requires the presence of a longer pyrophosphate (-O-P-O-P-O-) linkage. Since majority of NAD-dependent enzymes bind NAD in the extended conformation, selective inhibition of NAD kinases by disulfide analogues has been observed. Introduction of bromine at the C8 of the adenine ring restricted the adenosine moiety of diadenosine disulfides to the syn conformation making it even more compact. The 8-bromoadenosine adenosine disulfide (14) and its di(8-bromoadenosine) analogue (15) were found to be the most potent inhibitors of human (IC(50)=6 microM) and mycobacterium NAD kinase (IC(50)=14-19 microM reported so far. None of the disulfide analogues showed inhibition of lactate-, and inosine monophosphate-dehydrogenase (IMPDH), enzymes that bind NAD in the extended conformation.

Wld S protein requires Nmnat activity and a short N-terminal sequence to protect axons in mice.

The slow Wallerian degeneration (Wld(S)) protein protects injured axons from degeneration. This unusual chimeric protein fuses a 70-amino acid N-terminal sequence from the Ube4b multiubiquitination factor with the nicotinamide adenine dinucleotide-synthesizing enzyme nicotinamide mononucleotide adenylyl transferase 1. The requirement for these components and the mechanism of Wld(S)-mediated neuroprotection remain highly controversial. The Ube4b domain is necessary for the protective phenotype in mice, but precisely which sequence is essential and why are unclear. Binding to the AAA adenosine triphosphatase valosin-containing protein (VCP)/p97 is the only known biochemical property of the Ube4b domain. Using an in vivo approach, we show that removing the VCP-binding sequence abolishes axon protection. Replacing the Wld(S) VCP-binding domain with an alternative ataxin-3-derived VCP-binding sequence restores its protective function. Enzyme-dead Wld(S) is unable to delay Wallerian degeneration in mice. Thus, neither domain is effective without the function of the other. Wld(S) requires both of its components to protect axons from degeneration.

Enzymology of mammalian NAD metabolism in health and disease.

Mounting evidence attests to the paramount importance of the non-redox NAD functions. Indeed, NAD homeostasis is related to the free radicals-mediated production of reactive oxygen species responsible for irreversible cellular damage in infectious disease, diabetes, inflammatory syndromes, neurodegeneration and cancer. Because the cellular redox status depends on both the absolute concentration of pyridine dinucleotides and their respective ratios of oxidized and reduced forms (i.e., NAD/NADH and NADP/NADPH), it is conceivable that an altered regulation of the synthesis and degradation of NAD impairs the cell redox state and likely contributes to the mechanisms underlying the pathogenesis of the above mentioned diseases. Taking into account the recent appearance in the literature of comprehensive reviews covering different aspects of the significance of NAD metabolism, with particular attention to the enzymes involved in NAD cleavage, this monograph includes the most recent results on NAD biosynthesis in mammals and humans. Due to recent findings on nicotinamide riboside as a nutrient, its inclusion under "niacins" is proposed. Here, the enzymes involved in the de novo and reutilization pathways are overviewed.

Bifunctional NMN adenylyltransferase/ADP-ribose pyrophosphatase: structure and function in bacterial NAD metabolism.

Bacterial NadM-Nudix is a bifunctional enzyme containing a nicotinamide mononucleotide (NMN) adenylyltransferase and an ADP-ribose (ADPR) pyrophosphatase domain. While most members of this enzyme family, such as that from a model cyanobacterium Synechocystis sp., are involved primarily in nicotinamide adenine dinucleotide (NAD) salvage/recycling pathways, its close homolog in a category-A biodefense pathogen, Francisella tularensis, likely plays a central role in a recently discovered novel pathway of NAD de novo synthesis. The crystal structures of NadM-Nudix from both species, including their complexes with various ligands and catalytic metal ions, revealed detailed configurations of the substrate binding and catalytic sites in both domains. The structure of the N-terminal NadM domain may be exploited for designing new antitularemia therapeutics. The ADPR binding site in the C-terminal Nudix domain is substantially different from that of Escherichia coli ADPR pyrophosphatase, and is more similar to human NUDT9. The latter observation provided new insights into the ligand binding mode of ADPR-gated Ca2+ channel TRPM2.

Initial-rate kinetics of human NMN-adenylyltransferases: substrate and metal ion specificity, inhibition by products and multisubstrate analogues, and isozyme contributions to NAD+ biosynthesis.

Initial-rate and product inhibition studies revealed distinctive ordered ternary complex kinetic mechanisms, substrate specificities, and metal ion preferences for the three isozymes of human nicotinamide mononucleotide adenylyl-transferase (NMNAT, EC 2.7.7.1). ATP binds before NMN with nuclear isozyme NMNAT1 and Golgi apparatus NMNAT2, but the opposite order is observed with the mitochondrial isozyme NMNAT3. Only the latter utilizes ITP efficiently in place of ATP, and while NMNH conversion to NADH by NMNAT1 and NMNAT3 occurs at similar rates, conversion by NMNAT2 is much slower. These isozymes can also be discriminated by their action on tiazofurin monophosphate (TrMP), a metabolite of the antineoplastic prodrug tiazofurin. Our finding that TrMP is only a substrate with NMNAT1 and NMNAT3 reveals for the first time an organelle selectivity in the metabolism of this important drug. In search of additional ways to discriminate these isozymes, we synthesized and tested the P1-(nicotinamide/nicotinate-riboside-5')-Pn-(adenosine-5') dinucleotides Np3AD, Np4AD, and Nap4AD. In addition to being highly effective inhibitors, these multisubstrate geometric inhibitors gave inhibition patterns that are consistent with the aforementioned isozyme differences in substrate binding order. Distinctive differences in their substrate specificity and metal ion selectivity also permitted us to quantify individual isozyme contributions to NAD+ formation in human cell extracts.

Probing binding requirements of NAD kinase with modified substrate (NAD) analogues.

Synthesis of novel NAD(+) analogues that cannot be phosphorylated by NAD kinase is reported. In these analogues the C2' hydroxyl group of the adenosine moiety was replaced by fluorine in the ribo or arabino configuration (1 and 2, respectively) or was inverted into arabino configuration to give compound 3. Compounds 1 and 2 showed inhibition of human NAD kinase, whereas analogue 3 inhibited both the human and Mycobacterium tuberculosis NAD kinase. An uncharged benzamide adenine dinucleotide (BAD) was found to be the most potent competitive inhibitor (K(i)=90 microM) of the human enzyme reported so far.

Synthesis and biological evaluation of NAD analogs as human pyridine nucleotide adenylyltransferase inhibitors.

NAD analogs modified at the ribose adenylyl moiety, named N-2'-MeAD and Na-2'-MeAD, were synthesized as ligands of pyridine nucleotide (NMN/NaMN) adenylyltransferase (NMNAT). Both dinucleotides resulted selective inhibitors against human NMNAT-3 isoenzyme.

Characterization of Mycobacterium tuberculosis NAD kinase: functional analysis of the full-length enzyme by site-directed mutagenesis.

NAD kinase is the only known enzyme catalyzing the formation of NADP, a coenzyme implicated in most reductive biosynthetic reactions and in many antioxidant defense systems. Despite its importance, nothing is known regarding its structure or mechanism of catalysis. Mycobacterium tuberculosis NAD kinase has been overexpressed in Escherichia coli and purified to homogeneity. The molecular and kinetic properties of the enzyme resulted in significant differences from those reported by others on a proteolytically degraded form of the protein. Indeed the full-length enzyme displays an allosteric behavior and shows a strict preference for inorganic polyphosphate as the phosphate donor. It is inhibited by the reaction product NADP and by both NADH and NADPH. The mycobacterial enzyme shares with all other known NAD kinases a highly conserved region (spanning residues 189-210), particularly rich in glycines, which differs from the primary sequences of all previously identified nucleotide-binding sites. Alanine-scanning mutagenesis performed on 11 conserved residues within this domain revealed its importance in catalysis. A total of 6 of 11 mutated proteins completely lost the enzymatic activity while retaining the same oligomeric state of the wild-type protein, as demonstrated by gel-filtration analysis. Substitutions of S199 and G208 with alanine rendered enzyme versions with reduced activity. Their kinetic characterization, performed on purified proteins, revealed kinetic parameters toward ATP and polyphosphate similar to those of the wild-type enzyme. On the contrary, when the kinetic analysis was performed by using NAD as the variable substrate, significant differences were observed with respect to both the allosteric behavior and the catalytic efficiency, suggesting that the mutated region is likely involved in NAD binding.

Identification and characterization of a second NMN adenylyltransferase gene in Saccharomyces cerevisiae.

The enzyme nicotinamide mononucleotide (NMN) adenylyltransferase (NMNAT) (EC 2.7.7.1) catalyzes the transfer of the adenylyl moiety of ATP to NMN to form NAD(+). On the basis of a remarkable structural similarity with previously described Saccharomyces cerevisiae NMNAT (yNMNAT-1), the YGR010-encoded protein was identified as a second isoform of yeast NMNAT (yNMNAT-2). The YGR010 gene was isolated, cloned into a T7-based vector, and successfully expressed in Escherichia coli BL21 cells, yielding high level of NMN adenylyltransferase activity. The purification procedure reported in this paper, consisting of two chromatographic steps, allowed the isolation of 3mg of electrophoretically homogeneous yNMNAT-2 from 1 liter of E. coli culture. Under SDS/PAGE, the recombinant protein resulted in a single polypeptide of 46 kDa, in agreement with the molecular mass of the hypothetical protein encoded by YGR010 gene. The N-terminal sequence of the purified recombinant yNMNAT-2 exactly corresponds to the predicted sequence. Molecular and kinetic properties of recombinant yNMNAT-2 are reported and compared with those already known for yNMNAT-1.

Human erythrocyte pyrimidine 5'-nucleotidase, PN-I.

Erythrocyte maturation is accompanied by RNA degradation and release of mononucleotides. Pyrimidine 5'-nucleotidase, PN-I, has been purified and characterized. The molecular and enzymatic properties determined for the enzyme shows a 36-kDa and 5.1 pI monomeric protein with no disulfide bridges and no phosphate content. The activity is dependent on Mg(2+), while it is inactivated by heavy metals and by thiol-reactive reagents. PN-I is specific for pyrimidine nucleoside monophosphates, including the antineoplastic agents 5'-AZTMP and 5'-Ara-CMP. PN-I possess phosphotransferase activity able to exchange phosphate between pyrimidine nucleoside monophosphates and pyrimidine nucleosides, including AZT and Ara-Cyd. Amino acid sequence has been obtained from tryptic and CNBr peptides. PN-I cDNA sequence, coding for a 286-residue protein, has been retrieved from tag database, amplified by PCR, and expressed in Escherichia coli. The recombinant protein was fully active and showed identical properties with respect to PN-I. Substantial identity has been revealed with the partial sequences reported for p36, an alpha-interferon-induced protein. The significance of this identity is discussed.

Structure of human NMN adenylyltransferase. A key nuclear enzyme for NAD homeostasis.

Nicotinamide mononucleotide adenylyltransferase (NMNAT), a member of the nucleotidyltransferase alpha/beta-phosphodiesterases superfamily, catalyzes a universal step (NMN + ATP = NAD + PP(i)) in NAD biosynthesis. Localized within the nucleus, the activity of the human enzyme is greatly altered in tumor cells, rendering it a promising target for cancer chemotherapy. By using a combination of single isomorphous replacement and density modification techniques, the human NMNAT structure was solved by x-ray crystallography to a 2.5-A resolution, revealing a hexamer that is composed of alpha/beta-topology subunits. The active site topology of the enzyme, analyzed through homology modeling and structural comparison with other NMNATs, yielded convincing evidence for a substrate-induced conformational change. We also observed remarkable structural conservation in the ATP-recognition motifs GXXXPX(T/H)XXH and SXTXXR, which we take to be the universal signature for NMNATs. Structural comparison of human and prokaryotic NMNATs may also lead to the rational design of highly selective antimicrobial drugs.