Dual emission fluorescent silver nanoclusters for sensitive detection of the biological coenzyme NAD+/NADH

Fluorescent silver nanoclusters (Ag NCs) displaying dual-excitation and dual-emission properties have been developed for the specific detection of NAD⁺ (nicotinamide adenine dinucleotide, oxidized form). With the increase of NAD⁺ concentrations, the longer wavelength emission (with the peak at 550 nm) was gradually quenched due to the strong interactions between the NAD⁺ and Ag NCs, whereas the shorter wavelength emission (peaking at 395 nm) was linearly enhanced. More important, the dual-emission intensity ratio (I₃₉₅/I₅₅₀), fitting by a single-exponential decay function, can efficiently detect various NAD⁺ levels from 100 to 4000 μM, as well as label NAD⁺/NADH (reduced form of NAD) ratios in the range of 1–50.     

Extracellular NAD induces a rise in [Ca]i in activated human monocytes via engagement of P2Y1 and P2Y11 receptors

Extracellular nicotinamide adenine dinucleotide (NAD⁺) is known to increase the intracellular calcium concentration [Ca²⁺]_i in different cell types and by various mechanisms. Here we show that NAD⁺ triggers a transient rise in [Ca²⁺]_i in human monocytes activated with lipopolysaccharide (LPS), which is caused by a release of Ca²⁺ from IP₃-responsive intracellular stores and an influx of extracellular Ca²⁺. By the use of P2 receptor-selective agonists and antagonists we demonstrate that P2 receptors play a role in the NAD⁺-induced calcium response in activated monocytes. Of the two subclasses of P2 receptors (P2X and P2Y) the P2Y receptors were considered the most likely candidates, since they share calcium signaling properties with NAD⁺. The identification of P2Y₁ and P2Y₁₁ as receptor subtypes responsible for the NAD⁺-triggered increase in [Ca²⁺]_i was supported by several lines of evidence. First, specific P2Y₁ and P2Y₁₁ receptor antagonists inhibited the NAD⁺-induced increase in [Ca²⁺]_i. Second, NAD⁺ was shown to potently induce calcium signals in cells transfected with either subtype, whereas untransfected cells were unresponsive. Third, NAD⁺ caused an increase in [cAMP]_i, prevented by the P2Y₁₁ receptor-specific antagonist NF157.     

PARP-1 inhibition does not restore oxidant-mediated reduction in SIRT1 activity

Sirtuin1 (SIRT1) deacetylase and poly(ADP-ribose)-polymerase-1 (PARP-1) respond to environmental cues, and both require NAD⁺ cofactor for their enzymatic activities. However, the functional link between environmental/oxidative stress-mediated activation of PARP-1 and SIRT1 through NAD⁺ cofactor availability is not known. We investigated whether NAD⁺ depletion by PARP-1 activation plays a role in environmental stimuli/oxidant-induced reduction in SIRT1 activity. Both H₂O₂ and cigarette smoke (CS) decreased intracellular NAD⁺ levels in vitro in lung epithelial cells and in vivo in lungs of mice exposed to CS. Pharmacological PARP-1 inhibition prevented oxidant-induced NAD⁺ loss and attenuated loss of SIRT1 activity. Oxidants decreased SIRT1 activity in lung epithelial cells; however increasing cellular NAD⁺ cofactor levels by PARP-1 inhibition or NAD⁺ precursors was unable to restore SIRT1 activity. SIRT1 was found to be carbonylated by CS, which was not reversed by PARP-1 inhibition or selective SIRT1 activator. Overall, these data suggest that environmental/oxidant stress-induced SIRT1 down-regulation and PARP-1 activation are independent events despite both enzymes sharing the same cofactor.     

Conserved water-mediated recognition and dynamics of NAD+ (carboxamide group) to hIMPDH enzyme: water mimic approach toward the design of isoform-selective inhibitor

Inosine monophosphate dehydrogenase (IMPDH) enzyme involves in GMP biosynthesis pathway. Type I hIMPDH is expressed at lower levels in all cells, whereas type II is especially observed in acute myelogenous leukemia, chronic myelogenous leukemia cancer cells, and 10?ns simulation of the IMP–NAD⁺ complex structures (PDB ID. 1B3O and 1JCN) have revealed the presence of a few conserved hydrophilic centers near carboxamide group of NAD⁺. Three conserved water molecules (W1, W, and W1′) in di-nucleotide binding pocket of enzyme have played a significant role in the recognition of carboxamide group (of NAD⁺) to D274 and H93 residues. Based on H-bonding interaction of conserved hydrophilic (water molecular) centers within IMP–NAD⁺-enzyme complexes and their recognition to NAD⁺, some covalent modification at carboxamide group of di-nucleotide (NAD⁺) has been made by substituting the –CONH₂group by –CONHNH₂ (carboxyl hydrazide group) using water mimic inhibitor design protocol. The modeled structure of modified ligand may, though, be useful for the development of antileukemic agent or it could be act as better inhibitor for hIMPDH-II.     

Involvement of P2X receptors in the NAD+-induced rise in [Ca2+]i in human monocytes

In the present study, we show that the extracellular addition of nicotinamide adenine dinucleotide (NAD⁺) induces a transient rise in [Ca²⁺]_i in human monocytes caused by an influx of extracellular calcium. The NAD⁺-induced Ca²⁺ response was prevented by adenosine triphosphate (ATP), suggesting the involvement of ATP receptors. Of the two subtypes of ATP receptors (P2X and P2Y), the P2X receptors were considered the most likely candidates. By the use of subtype preferential agonists and antagonists, we identified P2X₁, P2X₄, and P2X₇ receptors being engaged in the NAD⁺-induced rise in [Ca²⁺]_i. Among the P2X receptor subtypes, the P2X₇ receptor is unique in facilitating the induction of nonselective pores that allow entry of ethidium upon stimulation with ATP. In monocytes, opening of P2X₇ receptor-dependent pores strongly depends on specific ionic conditions. Measuring pore formation in response to NAD⁺, we found that NAD⁺ unlike ATP lacks the ability to induce this pore-forming response. Whereas as little as 100 μM ATP was sufficient to activate the nonselective pore, NAD⁺ at concentrations up to 2 mM had no effect. Taken together, these data indicate that despite similarities in the action of extracellular NAD⁺ and ATP there are nucleotide-specific variations. So far, common and distinct features of the two nucleotides are only beginning to be understood.     

Isolation and characterization of an NAD+-degrading bacterium PTX1 and its role in chromium biogeochemical cycle

Microorganisms can reduce toxic chromate to less toxic trivalent chromium [Cr(III)]. Besides Cr(OH)₃ precipitates, some soluble organo-Cr(III) complexes are readily formed upon microbial, enzymatic, and chemical reduction of chromate. However, the biotransformation of the organo-Cr(III) complexes has not been characterized. We have previously reported the formation of a nicotinamide adenine dinucleotide (NAD⁺)-Cr(III) complex after enzymatic reduction of chromate. Although the NAD⁺-Cr(III) complex was stable under sterile conditions, microbial cells were identified as precipitates in a non-sterile NAD⁺-Cr(III) solution after extended incubation. The most dominant bacterium PTX1 was isolated and assigned to Leifsonia genus by phylogenetic analysis of 16S rRNA gene sequence. PTX1 grew slowly on NAD⁺ with a doubling time of 17 h, and even more slowly on the NAD⁺-Cr(III) complex with an estimated doubling time of 35 days. The slow growth suggests that PTX1 passively grew on trace NAD⁺ dissociated from the NAD⁺-Cr(III) complex, facilitating further dissociation of the complex and formation of Cr(III) precipitates. Thus, organo-Cr(III) complexes might be an intrinsic link of the chromium biogeochemical cycle; they can be produced during chromate reduction and then further mineralized by microorganisms.     

Metabolism of NAD+ in Nuclei of Saccharomyces cerevisiae during Stimulation of Its Biosynthesis by Nicotinamide

The activities of nuclear enzymes involved in NAD⁺ metabolism in Saccharomyces cerevisiae strain 913a-1 and its mutant 110 previously selected as an NAD⁺ producer were investigated. The presence of extracellular nicotinamide increased the total NAD⁺ pool in the cells and increased [³H]nicotinic acid incorporation; however, NAD⁺ concentration in isolated nuclei decreased slightly. The stimulating effect of nicotinamide on intracellular synthesis of NAD⁺ correlated with increases in ADP-ribosyl transferase, NAD⁺-pyrophosphorylase, and NAD⁺ ase activities.     

Tankyrase-1 overexpression reduces genotoxin-induced cell death by inhibiting PARP1

Poly(ADP-ribose) polymerases or PARPs are a family of NAD⁺-dependent enzymes that modify themselves and other substrate proteins with ADP-ribose polymers. The founding member PARP1 is localized predominantly in the nucleus and is activated by binding to DNA lesions. Excessive PARP1 activation following genotoxin treatment causes NAD⁺ depletion and cell death, whereas pharmacological PARP1 inhibition protects cells from genotoxicity. This study investigates whether cellular viability and NAD⁺ metabolism are regulated by tankyrase-1, a PARP member localized predominantly in the cytosol. Using a tetracycline-sensitive promoter to regulate tankyrase-1 expression in Madin–Darby canine kidney (MDCK) cells, we found that a 40-fold induction of tankyrase-1 (from 1500 to 60,000 copies per cell) lowers steady-state NAD⁺ levels but does not affect basal cellular viability. Moreover, the induction confers protection against the oxidative agent H₂O₂ and the alkylating agent MNNG, genotoxins that kill cells by activating PARP1. The cytoprotective effect of tankyrase-1 is not due to enhanced scavenging of oxidants or altered expression of Mcl-1, an anti-apoptotic molecule previously shown to be down-regulated by tankyrase-1 in CHO cells. Instead, tankyrase-1 appears to protect cells by preventing genotoxins from activating PARP1-mediated reactions such as PARP1 automodification and NAD⁺ consumption. Our findings therefore indicate a cytoprotective function of tankyrase-1 mediated through altered NAD⁺ homeostasis and inhibition of PARP1 function.     

Skeletal muscle hexokinase: regulation in mammalian hibernation

The perfused rat liver responds in several ways to NAD⁺ infusion (20–100 μM). Increases in portal perfusion pressure and glycogenolysis and transient inhibition of oxygen consumption and gluconeogenesis are some of the effects that were observed. Extracellular NAD⁺ is also extensively transformed in the liver. The purpose of the present work was to determine the main products of extracellular NAD⁺ transformation under various conditions and to investigate the possible contribution of these products for the metabolic effects of the parent compound. The experiments were done with the isolated perfused rat liver. The NAD⁺ transformation was monitored by HPLC. Confirming previous findings, the single-pass transformation of 100 μM NAD⁺ ranged between 75% at 1.5 min after starting infusion to 95% at 8 min. The most important products of single-pass NAD⁺ transformation appearing in the outflowing perfusate were nicotinamide, ADP-ribose, uric acid, and inosine. The relative proportions of these products presented some variations with the time after initiation of NAD⁺ infusion and the perfusion conditions, but ADP-ribose was always more abundant than uric acid and inosine. Cyclic ADP-ribose (cADP-ribose) as well as adenosine were not detected in the outflowing perfusate. The metabolic effects of ADP-ribose were essentially those already described for NAD⁺. These effects were sensitive to suramin (P2_XY purinergic receptor antagonist) and insensitive to 3,7-dimethyl-1-(2-propargyl)-xanthine (A2 purinergic receptor antagonist). Inosine, a known purinergic A3 agonist, was also active on metabolism, but uric acid and nicotinamide were inactive. It was concluded that the metabolic and hemodynamic effects of extracellular NAD⁺ are caused mainly by interactions with purinergic receptors with a highly significant participation of its main transformation product ADP-ribose.     

Structures of iron-dependent alcohol dehydrogenase 2 from Zymomonas mobilis ZM4 with and without NAD+ cofactor

The ethanologenic bacterium Zymomonas mobilis ZM4 is of special interest because it has a high ethanol yield. This is made possible by the two alcohol dehydrogenases (ADHs) present in Z. mobilis ZM4 (zmADHs), which shift the equilibrium of the reaction toward the synthesis of ethanol. They are metal-dependent enzymes: zinc for zmADH1 and iron for zmADH2. However, zmADH2 is inactivated by oxygen, thus implicating zmADH2 as the component of the cytosolic respiratory system in Z. mobilis. Here, we show crystal structures of zmADH2 in the form of an apo-enzyme and an NAD⁺-cofactor complex. The overall folding of the monomeric structure is very similar to those of other functionally related ADHs with structural variations around the probable substrate and NAD⁺ cofactor binding region. A dimeric structure is formed by the limited interactions between the two subunits with the bound NAD⁺ at the cleft formed along the domain interface. The catalytic iron ion binds near to the nicotinamide ring of NAD⁺, which is likely to restrict and locate the ethanol to the active site together with the oxidized Cys residue and several nonpolar bulky residues. The structures of the zmADH2 from the proficient ethanologenic bacterium Z. mobilis, with and without NAD⁺ cofactor, and modeling ethanol in the active site imply that there is a typical metal-dependent catalytic mechanism.     

Pocket analysis of the full-length cholix toxin. An assessment of the structure–dynamics of the apo catalytic domain

Cholix toxin from Vibrio cholerae is the third member of the diphtheria toxin (DT) group of mono-ADP-ribosyltransferase (mART) bacterial toxins. It shares structural and functional properties with Pseudomonas aeruginosa exotoxin A and Corynebacterium diphtheriae DT. Cholix toxin is an important model for the development of antivirulence approaches and therapeutics against these toxins from pathogenic bacteria. Herein, we have used the high-resolution X-ray structure of full-length cholix complexed with NAD⁺ to describe the properties of the NAD⁺-binding pocket at the residue level, including the role of crystallographic water molecules in the NAD⁺ substrate interaction. The full-length apo cholix structure is used to describe the putative NAD⁺-binding site(s) and to correlate biochemical with crystallographic data to study the stoichiometry and orientation of bound NAD⁺ molecules. We quantitatively describe the NAD⁺ substrate interactions on a residue basis for the main 22 pocket residues in cholix_f, a glycerol and 5 contact water molecules as part of the recognition surface by the substrate according to the conditions of crystallization. In addition, the dynamic properties of an in silico version of the catalytic domain were investigated in order to understand the lack of electronic density for one of the main flexible loops (R-loop) in the pocket of X-ray complexes. Implications for a rational drug design approach for mART toxins are derived.     

NAD+ metabolism and oxidative stress: the golden nucleotide on a crown of thorns

Abstract

In the twentieth century, NAD⁺ research generated multiple discoveries. Identification of the important role of NAD⁺ as a cofactor in cellular respiration and energy production was followed by discoveries of numerous NAD⁺ biosynthesis pathways. In recent years, NAD⁺ has been shown to play a unique role in DNA repair and protein deacetylation. As discussed in this review, there are close interactions between oxidative stress and immune activation, energy metabolism, and cell viability in neurodegenerative disorders and ageing. Profound interactions with regard to oxidative stress and NAD⁺ have been highlighted in the present work. This review emphasizes the pivotal role of NAD⁺ in the regulation of DNA repair, stress resistance, and cell death, suggesting that NAD⁺ synthesis through the kynurenine pathway and/or salvage pathway is an attractive target for therapeutic intervention in age-associated degenerative disorders. NAD⁺ precursors have been shown to slow down ageing and extend lifespan in yeasts, and protect severed axons from degeneration in animal models neurodegenerative diseases.     

Reverse Reaction of Malic Enzyme for HCO3 − Fixation into Pyruvic Acid to Synthesize L-Malic Acid with Enzymatic Coenzyme Regeneration

Malic enzyme [L-malate: NAD(P)⁺ oxidoreductase (EC 1.1.1.39)] catalyzes the oxidative decarboxylation of L-malic acid to produce pyruvic acid using the oxidized form of NAD(P) (NAD(P)⁺). We used a reverse reaction of the malic enzyme of Pseudomonas diminuta IFO 13182 for HCO₃ ^? fixation into pyruvic acid to produce L-malic acid with coenzyme (NADH) generation. Glucose-6-phosphate dehydrogenase (EC1.1.1.49) of Leuconostoc mesenteroides was suitable for coenzyme regeneration. Optimum conditions for the carboxylation of pyruvic acid were examined, including pyruvic acid, NAD⁺, and both malic enzyme and glucose-6-phosphate dehydrogenase concentrations. Under optimal conditions, the ratio of HCO₃ ^? and pyruvic acid to malic acid was about 38% after 24 h of incubation at 30 °C, and the concentration of the accumulated L-malic acid in the reaction mixture was 38 mM. The malic enzyme reverse reaction was also carried out by the conjugated redox enzyme reaction with water-soluble polymer-bound NAD⁺.     

Exogenous NAD Effects on Plant Mitochondria: A Reinvestigation of the Transhydrogenase Hypothesis

Addition of NAD⁺ to purified potato (Solanum tuberosum L.) mitochondria respiring α-ketoglutarate and malate in the presence of the electron transport inhibitor rotenone, stimulated O₂ uptake. This stimulation was prevented by incubating mitochondria with N-4-azido-2-nitrophenyl-aminobutyryl-NAD⁺ (NAP₄-NAD⁺), an inhibitor of NAD⁺ uptake, but not by 1 mm EGTA, an inhibitor of external NADH oxidation. NAD⁺-stimulated malate-cytochrome c reductase activity, and reduction of added NAD⁺ by intact mitochondria, could be duplicated by rupturing the mitochondria and adding a small quantity to the cuvette. The extent of external NAD⁺ reduction was correlated with the amount of extra mitochondrial malate dehydrogenase present. Malate oxidation by potato mitochondria depleted of endogenous NAD⁺ by storing on ice for 72 hours, was completely dependent on added NAD⁺, and the effect of NAD⁺ on these mitochondria was prevented by incubating them with NAP₄-NAD⁺. External NAD⁺ reduction by these mitochondria was not affected by NAP₄-NAD⁺. We conclude that all effects of exogenous NAD⁺ on plant mitochondrial respiration can be attributed to net uptake of the NAD⁺ into the matrix space.     

The action of extracellular NAD+ on gluconeogenesis in the perfused rat liver

In the rat liver NAD⁺ infusion produces increases in portal perfusion pressure and glycogenolysis and transient inhibition of oxygen consumption. The aim of the present work was to investigate the possible action of this agent on gluconeogenesis using lactate as a gluconeogenic precursor. Hemoglobin-free rat liver perfusion in antegrade and retrograde modes was used with enzymatic determination of glucose production and polarographic assay of oxygen uptake. NAD⁺ infusion into the portal vein (antegrade perfusion) produced a concentration-dependent (25–100 μM) transient inhibition of oxygen uptake and gluconeogenesis. For both parameters inhibition was followed by stimulation. NAD⁺ infusion into the hepatic vein (retrograde perfusion) produced only transient stimulations. During Ca²⁺-free perfusion the action of NAD⁺ was restricted to small transient stimulations. Inhibitors of eicosanoid synthesis with different specificities (indo-methacin, nordihydroguaiaretic acid, bromophenacyl bromide) either inhibited or changed the action of NAD⁺. The action of NAD⁺ on gluconeogenesis is probably mediated by eicosanoids synthesized in non-parenchymal cells. As in the fed state, in the fasted condition extracellular NAD⁺ is also able to exert two opposite effects, inhibition and stimulation. Since inhibition did not manifest significantly in retrograde perfusion it is likely that the generating signal is located in pre-sinusoidal regions.     

NAD(P)+-dependent isocitrate dehydrogenases in mitochondria purified from Picea abies seedlings

Isocitrate dehydrogenase (IDH) activities were measured in mitochondria isolated from aerial parts of 21-day-old spruce (Picea abies L. Karst.) seedlings. Mitochondria were purified by two methods, involving continuous and discontinuous Percoll gradients. Whatever the method of purification, the mitochondrial outer membrane was about 69% intact, and the mitochondria contained very low cytosolic, chloroplastic and peroxisomal contaminations. Nevertheless, as judged by the recovery of fumarase activity, purification on a continuous 28% Percoll gradient gave the best yield in mitochondria, which exhibited a high degree of inner membrane intactness (91%). The purified mitochondria oxidized succinate and malate with good respiratory control and ADP/O ratios. The highest oxidation rate was obtained with succinate as substrate, and malate oxidation was improved (+ 60%) by addition of exogenous NAD⁺. Experiments using standard respiratory chain inhibitors indicated that, in spruce mitochondria, the alternative pathway was present. Both NAD⁺-isocitrate dehydrogenase (EC 1.1.1.41) and NADP⁺-isocitrate dehydrogenase (EC 1.1.1.42) were present in the mitochondrial matrix fraction, and NAD⁺-IDH activity was about 2-fold higher than NADP⁺-IDH activity. The NAD⁺-IDH showed sigmoidal kinetics in response to isocitrate and standard Michaelis-Menten kinetics for NAD⁺ and Mg²⁺. The NADP⁺-IDH, in contrast, displayed lower K_m values. For NAD⁺-IDH the pH optimum was at 7.4, whereas NADP⁺-IDH exhibited a broad pH optimum between 8.3 and 9. In addition, NAD⁺-IDH was more thermolabile. Adenine nucleotides and 2-oxoglutarate were found to inhibit NAD(P)⁺-IDH activities only at high concentrations.     

Vanadate stimulates oxidation of NADH to generate hydrogen peroxide

Vanadate in the polymeric form of decavanadate, but not other forms, stimulated oxidation of NADH to NAD⁺ NADPH was also oxidized with comparable rates. This oxidation of NADH was accompanied by uptake of oxygen and generated hydrogen peroxide with the following stoichiometry: NADH + H⁺ + O₂ → NAD⁺ + H₂O₂. The reaction followed second-order kinetics. The rate was dependent on the concentration of both NADH and vanadate and increased with decreasing pH. The reaction had an obligatory requirement for phosphate ions. Esr studies in the presence of the spin trap dimethyl pyrroline N oxide indicated the involvement of Superoxide anion as an intermediate. The reaction was sensitive to Superoxide dismutase and other scavengers of superoxide anions.     

Hexose metabolism in pancreatic islets: Effect of D-glucose on the mitochondrial redox state

The mitochondrial NADH/NAD⁺ ratio for free nucleotides in rat pancreatic islets was judged from the cell content in L-glutamate and L-alanine, 2-ketoglutarate and pyruvate, and NH ₄ ⁺ . At a physiological concentration of D-glucose, such a ratio averaged 9.6±1.1%. A rise in hexose concentrations, above a threshold value in excess of 5.6 mM, caused a rapid, sustained and rapidly reversible decrease in the mitochondrial NADH/NAD⁺ ratio. It is speculated that in the process of glucose-stimulated insulin release, the latter change participates in the coupling between metabolic and secretory events by favouring both the activity of key mitochondrial dehydrogenases and the translocation of Ca²⁺ from the mitochondria into the cytosol.     

Electrochemical characterization of immobilized NAD+

Nicotinamide adenine dinucleotide (NAD⁺) has been covalently attached to alginic acid using carbodiimide coupling, thereby producing a macromolecular adduct of NAD, which can be rendered either soluble or insoluble by adjustment of pH. It was found that this NAD⁺ · alginic acid complex was enzymatically active, and also that the oxidized form could be electrochemically reduced without loss in enzymatic activity. This NAD⁺ adduct has now also been polarographically characterized as to its two-step reduction waves, which are slightly shifted toward more cathodic potential as compared to free NAD⁺. When controlled electrolysis was conducted to reduce the bound NAD⁺ at the cathode, the NADH so formed by electrochemical action was found to be again oxidizable either enzymatically or electrochemically without loss in co-enzymic function. The NADH adduct produced by electrochemical reduction of the NAD⁺ adduct has also been characterized by voltammetry.     

NAD+-induced inhibition of phosphate transport in canine renal brush-border membranes Mediation through a process other than or in addition to NAD+ hydrolysis

We previously demonstrated inhibition of Na⁺-dependent ³²P_i transport in canine renal brush-border membranes in association with NAD⁺-induced ADP ribosylation of membrane protein(s) and postulated that NAD⁺ inhibits P_i transport across the brush-border membrane via ADP ribosylation. Recently it was shown that incubation of rat brush-border membrane with NAD⁺ resulted in release of P_i which was prevented by EDTA. It was proposed that NAD⁺-mediated inhibition of ³²P_i transport might occur through this mechanism. To determine whether NAD⁺ inhibited ³²P_i transport by a mechanism other than or in addition to release of P_i, we compared Na⁺-dependent ³²P_i counterflow in brush-border membrane equilibrated with P_i or with P_i generated from NAD⁺. Release of P_i from NAD⁺ incubated with brush-border membrane was confirmed. The increased uptake of ³²P_i which was demonstrated in brush-border membrane equilibrated with P_i was not measured when intravesicular P_i was generated from a concentration of NAD⁺ which effected ADP-ribosylation of brush border membranes (100 μM NAD⁺). In contrast, increased uptake of ³²P_i was demonstrated when intravesicular P_i was generated from 1 μM NAD⁺ which did not effect ADP ribosylation. Mg²⁺-dependent ADP ribosylation of brush-border membrane incubated with NAD⁺ was demonstrated which persisted during the time interval of ³²P_i uptake measurements. Our findings are compatible with the hypothesis that NAD⁺-induced ADP ribosylation of brush-border membrane protein(s) results in inhibition of P_i transport across the membrane in vivo. EDTA may act to prevent this inhibition in brush-border membrane by chelation of Mg²⁺ and decreased ADP ribosylation.