Vitamin C deficiency activates the purine nucleotide cycle in zebrafish

Vitamin C (ascorbic acid, AA) is a cofactor for many important enzymatic reactions and a powerful antioxidant. AA provides protection against oxidative stress by acting as a scavenger of reactive oxygen species, either directly or indirectly by recycling of the lipid-soluble antioxidant, α-tocopherol (vitamin E). Only a few species, including humans, guinea pigs, and zebrafish, cannot synthesize AA. Using an untargeted metabolomics approach, we examined the effects of α-tocopherol and AA deficiency on the metabolic profiles of adult zebrafish. We found that AA deficiency, compared with subsequent AA repletion, led to oxidative stress (using malondialdehyde production as an index) and to major increases in the metabolites of the purine nucleotide cycle (PNC): IMP, adenylosuccinate, and AMP. The PNC acts as a temporary purine nucleotide reservoir to keep AMP levels low during times of high ATP utilization or impaired oxidative phosphorylation. The PNC promotes ATP regeneration by converting excess AMP into IMP, thereby driving forward the myokinase reaction (2ADP → AMP + ATP). On the basis of this finding, we investigated the activity of AMP deaminase, the enzyme that irreversibly deaminates AMP to form IMP. We found a 47% increase in AMP deaminase activity in the AA-deficient zebrafish, complementary to the 44-fold increase in IMP concentration. These results suggest that vitamin C is crucial for the maintenance of cellular energy metabolism.     

Thermodynamics of the purine nucleotide cycle

Since the standard Gibbs energies of formation are known for all the species in the purine nucleotide cycle at 298.15 K, the functions of pH and ionic strength that yield the standard transformed Gibbs energies of formation of the ten reactants can be calculated. This makes it possible to calculate the standard transformed Gibbs energies of reaction, apparent equilibrium constants, and changes in the binding of hydrogen ions for the three reactions at desired pHs and ionic strengths. These calculations are also made for the net reaction and a reaction that is related to it. The equilibrium concentrations for the cycle are calculated when all the reactants are initially present or only some are present initially. Since the concentrations of GTP, GDP, and P(i) may be in steady states, the equilibrium concentrations are also calculated for the system at specified steady-state concentrations.     

Increased inflammatory response in aged mice is associated with age-related zinc deficiency and zinc transporter dysregulation

Aging is a complex process associated with physiological changes in numerous organ systems. In particular, aging of the immune system is characterized by progressive dysregulation of immune responses, resulting in increased susceptibility to infectious diseases, impaired vaccination efficacy and systemic low-grade chronic inflammation. Increasing evidence suggest that intracellular zinc homeostasis, regulated by zinc transporter expression, is critically involved in the signaling and activation of immune cells. We hypothesize that epigenetic alterations and nutritional deficits associated with aging may lead to zinc transporter dysregulation, resulting in decreases in cellular zinc levels and enhanced inflammation with age. The goal of this study was to examine the contribution of age-related zinc deficiency and zinc transporter dysregulation on the inflammatory response in immune cells. The effects of zinc deficiency and age on the induction of inflammatory responses were determined using an in vitro cell culture system and an aged mouse model. We showed that zinc deficiency, particularly the reduction in intracellular zinc in immune cells, was associated with increased inflammation with age. Furthermore, reduced Zip 6 expression enhanced proinflammatory response, and age-specific Zip 6 dysregulation correlated with an increase in Zip 6 promoter methylation. Furthermore, restoring zinc status via dietary supplementation reduced aged-associated inflammation. Our data suggested that age-related epigenetic dysregulation in zinc transporter expression may influence cellular zinc levels and contribute to increased susceptibility to inflammation with age.     

The purine nucleotide cycle inHelix hepatopancreas

Summary The enzymes adenylosuccinate synthetase (EC 6.3.4.4 IMP: L-aspartate ligase [GDP-forming]), adenylosuccinate lyase (EC 4.3.2.2) and AMP deaminase (EC 3.5.4.6 AMP aminohydrolase) were demonstrated inHelix aspersa hepatopancreas tissue. The presence of these enzymes along with high levels of aspartate transaminase is presumptive evidence for the operation in this tissue of the purine nucleotide cycle. In the absence of evidence that glutamate dehydrogenase acts to release ammonia during amino acid catabolism, it is suggested that the purine nucleotide cycle serves this function. Glutamine synthetase (EC 6.3.1.2 L-glutamate: ammonia ligase [ADP-forming]) was shown to be present primarily in the cytosolic fraction ofHelix hepatopancreas. Since the operation of the purine nucleotide cycle results in the release of ammonia in the cytosol, the localization of glutamine synthetase in this compartment indicates that it is the primary ammonia-detoxifying enzyme and is consistent with the suggestion that the purine nucleotide cycle serves as the major pathway for amino acid catabolism.Supported by grants from the USPHS National Institute of Allergic and Infections Diseases (AI 05006) and the National Science Foundation (PCM-75-13161)     

Influence of dietary zinc deficiency and parenteral zinc on rat liver fructose 1,6-bisphosphatase activity

Fructose 1,6-bisphosphatase activity in liver of rats fed a zinc deficient diet was decreased to 60% of that in zinc adequate controls. Activity in the zinc deprived rats was not restored to control values by in vitro addition of EDTA. When a physiological dose of zinc was tube fed to the depleted rats, activity increased approximately 150% within 0.5 hr of the dose, and by 1 hr plateaued to a level seen in zinc adequate controls. A significant transient decrease in activity occurred following an intraperitoneal zinc load. This is reversible by in vitro addition of EDTA. These results suggest that rat liver fructose 1,6-bisphosphatase activity is highly sensitive to zinc in vivo as has been demonstrated in vitro.     

The purine nucleotide cycle and ammoniagenesis in rat kidney tubules

The contribution of the purine nucleotide cycle to renal ammoniagenesis was examined in cortical tubule suspensions prepared from acidotic rats and incubated with [alpha-15N]glutamine, [15N]glutamate, or [15N]aspartate. Labeling of ammonia and adenine nucleotides was determined after enzymatic transformations designed to circumvent the technical problem that 15NH3 and H2O have the same nominal mass. Labeling of the adenine nucleotide was undetectable (less than 10%) even after 1 h of incubation. From the measured concentrations of adenine nucleotides and ammonia and the labeling of the ammonia, the flux through the purine nucleotide cycle was calculated to account for less than 1% of the deamination of alpha-amino groups from all three substrates. The glutamate dehydrogenase reaction is therefore the likely pathway for deamination. The rate of 15NH3 production from [alpha-15N]glutamine was two or three times greater than from added [15N]glutamate, indicating a preference for intracellularly generated glutamate. 15NH3 production from added [15N]aspartate was similar to and perhaps slightly greater than that from added [15N]glutamate.     

Oscillations of the glycolytic pathway and the purine nucleotide cycle.

In a treatment modeled after the oscillatory behavior of the glycolytic pathway and the purine nucleotide cycle observed in skeletal muscle extracts, it is shown that the basis of the oscillations is the AMP-dependent activation of phosphofructokinase by fructose diphosphate. Control of phosphofructokinase by the adenine nucleotides alone leads to the establishment of a steady state. Whether steady state or oscillatory behavior occurs depends in part on the activity of glyceraldehyde-3-phosphate dehydrogenase, which controls the rate of removal of fructose diphosphate. Under appropriate conditions oscillatory behavior can maintain a higher [ATP]/[ADP] ratio than steady state behavior. Viewed in the context of conditions that may be encountered in skeletal muscle in vivo, oscillatory behavior of glycolysis is shown to have additional advantages for maintaining a high [ATP]/[ADP] ratio.     

Susceptibility to kainate-induced seizures under dietary zinc deficiency

Zinc homeostasis in the brain is altered by dietary zinc deficiency, and its alteration may be associated with the etiology and manifestation of epileptic seizures. In the present study, susceptibility to kainate-induced seizures was enhanced in mice fed a zinc-deficient diet for 4 weeks. When Timm's stain was performed to estimate zinc concentrations in synaptic vesicles, Timm's stain in the brain was attenuated in the zinc-deficient mice. In rats fed the zinc-deficient diet for 4 weeks, susceptibility to kainate-induced seizures was also enhanced. When the release of zinc and neurotransmitters in the hippocampal extracellular fluid of the zinc-deficient rats was studied using in vivo microdialysis, the zinc concentration in the perfusate was less than 50% of that of the control rats and the increased levels of zinc by treatment with kainate were lower than the basal level in control rats, suggesting that vesicular zinc is responsive to dietary zinc deficiency. The levels of glutamate in the perfusate of the zinc-deficient rats were more increased than in the control rats, whereas the levels of GABA in the perfusate were not at all increased in the zinc-deficient rats, unlike in the control rats. The present results demonstrate an enhanced release of glutamate associated with a decrease in GABA concentrations as a possible mechanism for the increased seizure susceptibility under zinc deficiency.     

Simulation of the purine nucleotide cycle as an anaplerotic process in skeletal muscle

A computer model of purine nucleotide and citric acid cycles joined through fumarate is given. Steady-state equations corresponding to metabolic enzymes are written based on the information from the literature about their kinetic behavior. Numerical integration of this set of equations is performed and in order to maintain an overall stabilization between the two cycles, enzymatic activities, in the form of V, have been calculated. Sensitivity coefficients for enzymes indicate that the control is exerted, depending upon the intermediate concentrations, and furthermore, it is demonstrated that AMP concentration in muscle should be very low. From stabilization, simulation of exercise conditions has been performed by diminishing [ATP] and increasing accordingly [ADP] and [AMP]. In such conditions the operation of purine nucleotide cycle leads to a considerable increase in the level of citric acid cycle intermediates. Disruption of purine nucleotide cycle by altering some of the three enzymatic steps leads to a lesser increase of these intermediates. The set of results presented seems to confirm the hypothesis that purine nucleotide cycle acts as an anaplerotic process in muscle, as the experimental results of Aragon and Lowenstein (Aragon, J.J., and Lowenstein, J.M. (1980) Eur. J. Biochem. 110, 371-377) suggest.     

Characteristics of purine nucleotide metabolism and GMP-reductase activity in chicken tissues

The [3H]guanosine and [3H]guanine label is shown to be distributed unevenly in the purine components of chicken tissues. 60 min after isotope administration about 80% of radioactivity is localized in xanthine and uric acid in the liver and duodenum, that agrees with high activity of purine nucleoside phosphorylase (EC 2.4.2.1) and guanine deaminase (EC 3.5.4.3). At the same time over 50% of label is found in the spleen in adenine nucleotides of the pool, RNA as well as in hypoxanthine and only 20% in oxypurines. Such a distribution of the label is in direct correlation with the activity of GMP-reductase (EC 1.6.6.8) catalyzing the reduction deamination of GMP in IMP.     

Coordinate enzymatic activity of beta-oxidation and purine nucleotide cycle in a diversity of muscle and other organs of rat.

1. Most mammalian muscles consist of a mixture of different muscle fiber types. 2. We analyzed various muscles with different percentages of slow and fast fibers in addition to other organs of rat for enzyme activities of beta-oxidation and the purine nucleotide cycle (PNC). 3. According to the content of slow-twitch fibers all enzymes of beta-oxidation were high in activity whereas enzymes of the purine nucleotide cycle were low. 4. Amongst all enzymes of beta-oxidation, crotonase showed the highest activity. 5. In heart muscle, enzyme activities of beta-oxidation were even higher than in m. soleus which consists almost exclusively of slow-twitch type I fibers. 6. Measurements of all three enzymes involved in the purine nucleotide cycle revealed high activities in muscles predominantly composed of fast-twitch fibers. 7. It was always adenylate deaminase which revealed the highest activity. 8. Heart muscle showed low activities for enzymes of PNC.     

Incorporation of purine nucleosides in cultured fibroblasts from a patient with purine nucleoside phosphorylase deficiency and associated T-cell immunodeficiency.

Cultured skin fibroblasts from a patient with T-cell immune deficiency and an absence of purine nucleoside phosphorylase activity in red cells were assayed for their capacity to metabolize inosine and guanosine. The cultured fibroblasts were lacking activity of nucleoside phosphorylase and, compared to normal fibroblasts, could incorporate only 2% and 4% of 14C-inosine and 3H-guanosine, respectively, into acid precipitable material. Autoradiography visually confirmed the failure of the NP deficient cell line to incorporate the nucleosides into nuclear material. The physiological mechanism by which the deficiency of purine nucleoside phosphorylase causes T-cell dysfunction remains unclear.     

The purine nucleotide cycle and ammonia formation from glutamine by rat kidney slices.

To test the significance of the purine nucleotide cycle in renal ammoniagenesis, studies were conducted with rat kidney cortical slices using glutamate or glutamine labelled in the alpha-amino group with 15N. Glucose production by normal kidney slices with 2 mM-glutamine was equal to that with 3 mM-glutamate. With L-[15N]glutamate as sole substrate, one-third of the total ammonia produced by kidney slices was labelled, indicating significant deamination of glutamate or other amino acids from the cellular pool. Ammonia produced from the amino group of L-[alpha-15N]glutamine was 4-fold higher than from glutamate at similar glucose production rates. Glucose and ammonia formation from glutamine by kidney slices obtained from rats with chronic metabolic acidosis was found to be 70% higher than by normal kidney slices. The contribution of the amino group of glutamine to total ammonia production was similar in both types of kidneys. No 15N was found in the amino group of adenine nucleotides after incubation of kidney slices from normal or chronically acidotic rats with labelled glutamine. Addition of Pi, a strong inhibitor of AMP deaminase, had no effect on ammonia formation from glutamine. Likewise, fructose, which may induce a decrease in endogenous Pi, had no effect on ammonia formation. The data obtained suggest that the contribution of the purine nucleotide cycle to ammonia formation from glutamine in rat renal tissue is insignificant.