The existence of a group translocation transport mechanism in animal cells: Uptake of the ribose moiety of inosine

After exposure to inosine, transport-competent plasma membrane vesicles isolated from SV -40-transformed Balb/c 3T3 cells accumulate intravesicular ribose 1-PO₄ at a concentration 200-fold greater than the extravesicular concentration. An analysis of the purine nucleoside phosphorylase activity distribution in various subcellular fractions, relative to other enzyme activities, indicated the presence of plasma membrane-associated purine nucleoside phosphorylase activity. The plasma membrane vesicles appear relatively impermeable to hypoxanthine. However, hypoxanthine, which is a competitive inhibitor of the transport reaction, is the only compound tested capable of mediating efflux of already accumulated ribose 1-PO₄. In addition, hypoxanthine does not result in the efflux of transported uridine which is accumulated in these membrane vesicles as uridine. Exogenous ribose 1-PO₄ neither results in counterflow nor does it inhibit the original uptake reaction. The following transport reaction is proposed: uptake occurs by group translocation, mediated by membrane-localized purine nuceloside phosphorylase. The data are consistent with sites for inosine and hypoxanthine being on the outer membrane surface whereas the ribose 1-PO₄ site is only on the inner surface.     

Hypoxanthine transport in mammalian cells: Cell type-specific differences in sensitivity to inhibition by dipyridamole and uridine

Summary We have measured by rapid kinetic techniques the zero-trans influx of hypoxanthine in various cell lines and its sensitivity to inhibition by uridine, dipyridamole, nitrobenzylthioinosine and nitrobenzylthiopurine. The results and those reported earlier divided the cells into two distinct groups. In mouse P388, L1210 and L929 cells uridine and hypoxanthine had little effect on the transport of each other, supporting the view that nucleosides and hypoxanthine are transported by different carriers. In these cells, hypoxanthine transport was also uniquely resistant to inhibition by dipyridamole (IC₅₀ (50% inhibition dose) >30M). In Novikoff and HTC rat hepatoma, Chinese hamster ovary and Ehrlich ascites tumor cells, on the other hand, hypoxanthine and uridine inhibited the transport of each other about 50% at a concentration corresponding to the Michaelis-Menten constant of their transport, and hypoxanthine transport was strongly inhibited by dipyridamole (IC₅₀=100 to 400nM). Although these results are compatible with the view that nucleosides and hypoxanthine are transported by a common carrier in these cells, this conclusion is not supported by the finding that uridine transport is strongly inhibited in some of these cell lines, as in first group of cells, by nitrobenzylthioinsine, whereas hypoxanthine transport is highly resistant in all cell lines tested. In contrast, the transport of both substrates is highly resistant to inhibition by nitrobenzylthiopurine. The Michaelis-Menten constants for uridine transport are about the same in all cell lines. The Michaelis-Menten constants for hypoxanthine transport are similar to those for uridine transport in some cell lines, but are much higher in others. This difference is unrelated to the sensitivity of uridine and hypoxanthine transport to inhibition by each other or dipyridamole.     

Effect of purine-free low-malt liquor (happo-shu) on the plasma concentrations and urinary excretion of purine bases and uridine--comparison between purine-free and regular happo-shu.

To determine whether purine-free and regular low-malt liquor beverages (happo-shu) increase the plasma concentration and urinary excretion of purine bases (hypoxanthine, xanthine, uric acid) and uridine, 6 healthy males were given regular (10 ml/kg of body weight) and purine-free happo-shu (10 ml/kg of body weight). Plasma concentration-time curves were plotted, and the areas under the curves for uric acid and total purine bases (the sum of hypoxanthine, xanthine, and uric acid) were greater in the regular than in the purine-free happo-shu ingestion experiment (both p < 0.05). In addition, the total urinary excretion of xanthine, total purine bases, and uridine was greater in the regular than in the purine-free happo-shu ingestion experiment (p < 0.05 in all cases), although the total urinary excretion of hypoxanthine and uric acid was no different between the regular and the purine-free happo-shu ingestion experiments. These results suggest that uridine contained in regular happo-shu might contribute to an increase in the urinary excretion of uridine along with ethanol, and that the purines contained in regular happo-shu may contribute to the increase in plasma concentration of uric acid due to purine degradation.     

Nucleoside and Oxypurine Homeostasis in Adult Rabbit Cerebrospinal Fluid and Plasma

Abstract: In adult New Zealand white rabbits, the effects of food deprivation and of massive elevations of plasma uridine or thymidine concentrations on CSF and plasma nucleoside and oxypurine concentrations were studied. Nucleoside and oxypurine levels were determined by high performance liquid chromatography using unequivocal methods of compound identification. After 48 and 96 h of food deprivation, the concentrations of uridine, cytidine, inosine, thymidine, deoxycytidine, deoxyuridine, hypoxanthine, xanthine, and uric acid in CSF and plasma were not different than in controls, except at 96 h, when the plasma uridine concentration was 35% lower (p < 0.05). After elevation of the plasma and CSF thymidine concentrations to ∼200 and 100 μM, respectively, with intravenous thymidine for 5 h, there was a large increase in CSF and plasma thymine to ∼100 μM and a smaller increase in plasma and CSF deoxyuridine concentrations. After elevation of the plasma and CSF uridine concentrations to 0.6 and 0.2 mM, respectively, there was a large increase in CSF and plasma uracil and a smaller increase in plasma and CSF deoxyuridine concentrations. Elevated plasma concentration of thymidine and uridine significantly decreased the CSF to plasma ratios of deoxyuridine and thymidine; however, only elevated plasma uridine concentrations decreased the CSF to plasma ratio of uridine. These results document the powerful homeostatic mechanisms that regulate the concentrations of the principal nucleosides and oxypurine bases in CSF.     

Effects of allopurinol on beer-induced increases in plasma concentrations of purine bases and uridine

We investigated the effects of allopurinol on beer-induced changes in the plasma concentration and urinary excretion of purine bases. Five healthy subjects underwent three studies: ingestion of beer after taking 300 mg allopurinol (combination study); ingestion of beer alone; ingestion of allopurinol alone. Increased plasma concentrations and urinary excretion of hypoxanthine were greater in the combination study than the beer alone study. However, increases in total plasma purine base concentrations were greater in the beer alone study, even though increases in plasma uridine concentrations did not differ. Beer-induced increases in plasma concentrations of purine bases appear partially offset by increased urinary excretion of hypoxanthine after allopurinol, which also controls increases in plasma uric acid levels caused by alcoholic beverage ingestion.     

Effects of Allopurinol on Beer-Induced Increases in Plasma Concentrations of Purine Bases and Uridine

We investigated the effects of allopurinol on beer-induced changes in the plasma concentration and urinary excretion of purine bases. Five healthy subjects underwent three studies: ingestion of beer after taking 300 mg allopurinol (combination study); ingestion of beer alone; ingestion of allopurinol alone. Increased plasma concentrations and urinary excretion of hypoxanthine were greater in the combination study than the beer alone study. However, increases in total plasma purine base concentrations were greater in the beer alone study, even though increases in plasma uridine concentrations did not differ. Beer-induced increases in plasma concentrations of purine bases appear partially offset by increased urinary excretion of hypoxanthine after allopurinol, which also controls increases in plasma uric acid levels caused by alcoholic beverage ingestion.     

Alterations in cerebrospinal fluid uridine,hypoxanthine, and xanthine in head-injured patients

1. Examination of the cerebrospinal fluid (CSF) of head-injured patients reveals that the concentration of intraventricular xanthine is elevated and that of uridine is decreased relative to those of adult lumbar CSF. 2. No correlations were observed between CSF lactate and CSF hypoxanthine, xanthine, or uridine, suggesting that changes in purine metabolites and the pyrimidine nucleoside do not index similar cellular events as does lactic acid production. 3. Ventricular CSF from hydrocephalic infants had uridine and hypoxanthine concentrations not significantly different from those of normal adult lumbar CSF, but xanthine was significantly elevated. 4. Since uridine has anticonvulsant properties and is a crucial substrate for cerebral metabolism, it may be useful to evaluate this pyrimidine for use in the management of patients with head injury.     

Evaluation of Uridine Metabolism in Human and Animal Spermatozoa

The objective of this study was to elucidate the role of uridine for spermatozoa, since this pyrimidine nucleoside was found in millimolar concentration in human seminal plasma. Here, the degradative activity of uridine-phosphorylase [EC 2.4.2.3] and the salvage activity of uridine kinase [EC 2.7.1.48] were detected in human spermatozoa. HPLC analysis depicted the uptake of exogeneous ¹⁴C-labelled adenine, but not of uridine and of hypoxanthine, into nucleotide pools of boar spermatozoa. On addition of uridine, the computer-assisted semen analysis (CASA) of human cells revealed a reduction of the percentage of motile spermatozoa in contrast to an elevation of some velocity parameters. It is concluded that exogeneous uridine could function as suppressor for early capacitation and as a substrate for phosphorolysis, if ribose is needed, rather than to satisfy a demand for intracellular pyrimidine nucleotides.     

Effects of allopurinol on beer-induced increases in plasma concentrations and urinary excretion of purine bases (uric acid, hypoxanthine, and xanthine).

To determine the effects of allopurinol on beer-induced increases in plasma and urinary excretion of purine bases (hypoxanthine, xanthine, and uric acid), we performed three experiments on five healthy study participants. In the first experiment (combination study), the participants ingested beer (10 ml/kg body weight) eleven hours after taking allopurinol (300 mg). In the second experiment (beer-only study), the same participants ingested beer (10 ml/kg body weight) alone, while in the third experiment (allopurinol-only study), they took allopurinol (300 mg) alone. There was a two-week interval between each of the studies. Beer-induced increases in plasma concentration and urinary excretion of hypoxanthine in the combination study were markedly higher than those in the beer-only study. On the other hand, the sum of increases in plasma concentrations of purine bases in the beer-only study was greater than in the combination study, whereas the increase in plasma uridine concentration in the combination study did not differ from the beer-only study. In addition, allopurinol administration inhibited the beer-induced increase in plasma concentration of uric acid. These results suggest that abrupt adenine nucleotide degradation may increase plasma concentration and urinary excretion of hypoxanthine under conditions of low xanthine dehydrogenase activity, which is mostly ascribable to allopurinol. Further, the difference in the sum of increases in plasma concentrations of purine bases between the combination study and beer-only study was largely ascribable to a greater increase in urinary excretion of hypoxanthine in the combination study. In addition, allopurinol intake seems to be effective in controlling the rapid increase in plasma uric acid caused by ingestion of alcoholic beverages.     

Evaluation of uridine metabolism in human and animal spermatozoa

The objective of this study was to elucidate the role of uridine for spermatozoa, since this pyrimidine nucleoside was found in millimolar concentration in human seminal plasma. Here, the degradative activity of uridine-phosphorylase [EC 2.4.2.3] and the salvage activity of uridine kinase [EC 2.7.1.48] were detected in human spermatozoa. HPLC analysis depicted the uptake of exogeneous 14C-labelled adenine, but not of uridine and of hypoxanthine, into nucleotide pools of boar spermatozoa. On addition of uridine, the computer-assisted semen analysis (CASA) of human cells revealed a reduction of the percentage of motile spermatozoa in contrast to an elevation of some velocity parameters. It is concluded that exogeneous uridine could function as suppressor for early capacitation and as a substrate for phosphorolysis, if ribose is needed, rather than to satisfy a demand for intracellular pyrimidine nucleotides.     

Blood uridine concentration may be an indicator of the degradation of pyrimidine nucleotides during physical exercise with increasing intensity

During prolonged maximal exercise, oxygen deficits occur in working muscles. Progressive hypoxia results in the impairment of the oxidative resynthesis of ATP and increased degradation of purine nucleotides. Moreover, ATP consumption decreases the conversion of UDP to UTP, to use ATP as a phosphate donor, resulting in an increased concentration of UDP, which enhances pyrimidine degradation. Because the metabolism of pyrimidine nucleotides is related to the metabolism of purines, in particular with the cellular concentration of ATP, we decided to investigate the impact of a standardized exercise with increasing intensity on the concentration of uridine, inosine, hypoxanthine, and uric acid. Twenty-two healthy male subjects volunteered to participate in this study. Blood concentrations of metabolites were determined at rest, immediately after exercise, and after 30 min of recovery using high-performance liquid chromatography. We also studied the relationship between the levels of uridine and indicators of myogenic purine degradation. The results showed that exercise with increasing intensity leads to increased concentrations of inosine, hypoxanthine, uric acid, and uridine. We found positive correlations between blood uridine levels and indicators of myogenic purine degradation (hypoxanthine), suggesting that the blood uridine level is related to purine metabolism in skeletal muscles.     

Mechanism of energy coupling for transport of deoxycytidine, uridine, uracil, adenine and hypoxanthine in Escherichia coli.

The transport processes for uridine, deoxycytidine, uracil, adenine and hypoxanthine require an energy source and are active under anaerobic or aerobic conditions. Inhibitory effects of cyanide, arsenate, carbonylcyanide m-chlorophenylhydrazone, 2,4-dinitrophenol and N,N'-dicyclohexylcarbodiimide on the transport of uridine and deoxycytidine differ from the corresponding effects on the transport of uracil, adenine and hypoxanthine. The nature of these inhibitory effects supports the conclusion that uridine and deoxycytidine transport is energized either by electron transport or by ATP hydrolysis via (Ca2+ + Mg2+)-ATPase. The transport or uracil, adenine and hypoxanthine is dependent upon ATP or some high energy phosphate derivative of ATP, but is independent of (Ca2+ + Mg+)-ATPase and electron transport. Uptake of the ribose moiety of uridine by a mutant of Escherichia coli B, which lacks the transport system for uracil and intact uridine, is neither stimulated by energy sources nor inhibited by various inhibitors of energy metabolism under either aerobic or anaerobic conditions.     

Effect of dietary protein on the capacity of urea synthesis in rats

The in vivo capacity of urea nitrogen synthesis (CUNS) during alanine stimulation was measured within the blood amino acid concentration interval 7.3-11.6 mmol/l, where urea synthesis is at maximum and independent of substrate concentration. Three groups of rats were fed for 14 days, either a low protein diet (8%), a normal diet (17%), or a high protein diet (53%). Diet protein modified both CUNS and plasma glucagon concentration. CUNS was 5.86 +/- 2.93, 7.43 +/- 2.16, and 19.31 +/- 4.32 mumol/(min.100 g BW) (mean +/- SD, N = 6), respectively. The corresponding plasma glucagon concentrations after alanine stimulation were 222 +/- 400, 633 +/- 229, and 1700 +/- 627 ng/l, respectively. The in vivo kinetics of urea production is regulated by dietary protein, possibly via glucagon. This implies that the liver plays an active part in adaptation of whole body nitrogen homeostasis to dietary changes.     

Ribose 1-phosphate and inosine activate uracil salvage in rat brain

The purpose of this study was to determine the mechanism by which inosine activates pyrimidine salvage in CNS. The levels of cerebral inosine, hypoxanthine, uridine, uracil, ribose 1-phosphate and inorganic phosphate were determined, to evaluate the Gibbs free energy changes (deltaG) of the reactions catalyzed by purine nucleoside phosphorylase and uridine phosphorylase, respectively. A deltaG value of 0.59 kcal/mol for the combined reaction inosine+uracil <==> uridine+hypoxanthine was obtained, suggesting that at least in anoxic brain the system may readily respond to metabolite fluctuations. If purine nucleoside phosphorolysis and uridine phosphorolysis are coupled to uridine phosphorylation, catalyzed by uridine kinase, whose activity is relatively high in brain, the three enzyme activities will constitute a pyrimidine salvage pathway in which ribose 1-phosphate plays a pivotal role. CTP, presumably the last product of the pathway, and, to a lesser extent, UTP, exert inhibition on rat brain uridine nucleotides salvage synthesis, most likely at the level of the kinase reaction. On the contrary ATP and GTP are specific phosphate donors.     

Chemotactic selection of Tetrahymena pyriformis GL induced with histamine, di-iodotyrosine or insulin

Ethoxyquin (6-ethoxy-2,2,4-trimethyl-1,2-dihydroquinoline (EQ) is a synthetic antioxidant used for preventing rancidity in animal foodstuffs. Three groups of ten fish were given a diet containing respectively 75 (control group with the commercial food), 200 and 400 ppm EQ for 16 days. The control group had a plasma osmolality and chloride concentration within the normal range of marine teleosts, but sodium concentrations of only about 110 mM, indicating the presence in the plasma of substantial amounts of another cation. Fish given food with 400 ppm EQ displayed a 70 mM increase in the plasma concentration of sodium. This indicates that EQ has disturbed the iono-regulatory mechanisms, probably by reducing the ATP production or inhibiting directly the Na/K-ATPase in the gills. The large increase in plasma sodium concentration was not accompanied by any significant increase in plasma osmolality, indicating that at least a part of the sodium added to the plasma is made osmotically inactive. In spite of the elevated plasma sodium concentration, the sodium content of erythrocytes of the 400-ppm EQ fish was reduced to half, while the content of calcium was unaffected. The transmembrane energy gradient of sodium in the EQ exposed turbot obviously increased, allowing them to use a sodium coupled antiport system to keep the cellular calcium content low when the Ca-ATPases is blocked. A mechanism of this kind is also likely to be important to turbot that experience hypoxia under natural conditions. The 400-ppm group also displayed a substantial increase in liver weight, but the physiological significance of this effect is not clear. The leucocyte counts indicated the absence of obvious immunological effects.     

Diagnosis of Gilbert's Syndrome: Role of Reduced Caloric Intake Test

Reduction in caloric intake to 400 a day for 72 hours resulted in a significant increase in the plasma bilirubin concentration in patients with Gilbert''s syndrome and in normal subjects. This was due to an increase in unconjugated pigment. There was no significant increase in the bilirubin concentration in patients with liver disease or haemolytic anaemia.The increase in unconjugated bilirubin was signficantly greater in Gilbert''s syndrome than in normals but only when the initial bilirubin concentration was raised. It was usually seen within 24 hours of reducing the caloric intake. An increase of 100% or more suggests that unconjugated hyperbilirubinaemia is due to Gilbert''s syndrome. In the normal subjects the unconjugated bilirubin level did not exceed 1·0 mg/100 ml.The increase in unconjugated bilirubin concentration on reducing the caloric intake may be due to decreased hepatic bilirubin uridine diphosphate glucuronyl transferase activity, which was shown to be present in seven rats starved for 72 hours. The effect of a 400 calorie diet for 24 hours on the unconjugated bilirubin level may distinguish Gilbert''s syndrome from other causes of unconjugated hyperbilirubinaemia.     

Relationship between plasma zinc, angiotensin-converting enzyme, alkaline phosphatase and onset of symptoms of zinc deficiency in the rat

Recent evidence suggests that changes in plasma zinc concentration may play a central role in the development of early lesions of zinc deficiency. The aim of the following work was to better understand events occurring in plasma during the onset of zinc deficiency, and to investigate biochemical mechanisms by which plasma zinc may exert its effects. Fifty male weanling rats of 90 g weight were allocated to five treatment groups of ten rats each. Treatments were: 1, zinc deficient, mixed diet (1-2 mg Zn per kg): 2, zinc deficient, self-select diet; 3, zinc repleted; 4, control, pair fed; 5, control, ad libitum fed. With the exception of treatment 1, which consisted of a 25% casein diet, all rats were offered protein as a separate component of the diet. Control rats received zinc in the drinking water (100 mg l-1). The sequence of events following initiation of zinc deficiency were: reduced plasma zinc concentration (2 days), reduced plasma angiotensin-converting enzyme and alkaline phosphatase activities (3-4 days), reduced feed intake and growth (5-6 days) and reduced percentage protein intake (12 days). Plasma zinc concentration in the deficient rats was inversely correlated with the growth rate of the rat over the previous 24 h. Zinc repletion resulted in marked overshoot in plasma zinc concentration (300%) and converting-enzyme activity (150%) within 24 h, but a return to normal within 72 h. Alkaline phosphatase activity responded likewise, albeit more slowly. Protein self selection had no effect on the manifestations of zinc deficiency, although reduced protein intake was associated with lower plasma zinc concentration. The results provide evidence of a role for plasma zinc in the development of early clinical signs of zinc deficiency, possibly acting biochemically through reduced activity of zinc-dependent peptidases such as angiotensin-converting enzyme.     

Hypoxanthine and xanthine levels determined by high-performance liquid chromatography in plasma, erythrocyte, and urine samples from healthy subjects: the problem of hypoxanthine level evolution as a function of time

The levels of hypoxanthine and xanthine are determined in plasma, erythrocyte, and urine samples by a reverse-phase high-performance liquid chromatographic (HPLC) method. The hypoxanthine concentration increases in erythrocyte and plasma samples when whole blood is stored at room temperature between sampling and centrifugation. Furthermore, the hypoxanthine concentration increases in erythrocyte samples when they are kept apart at room temperature before analysis, whereas the plasma hypoxanthine level remains constant. This result proves an endogenous formation of hypoxanthine in erythrocytes with time, at room temperature. These studies show the necessity of rigorous conditions for the collection, transport, and treatment of blood samples. In order to achieve accurate results, the blood must be centrifuged immediately after collection. The erythrocyte and plasma samples must be stored frozen until deproteinization and HPLC analysis. Under these conditions, the concentrations of hypoxanthine and xanthine in plasma are 2.5 +/- 1 and 1.4 +/- 0.7 microM, respectively. In erythrocyte samples, hypoxanthine concentration reaches 8.0 +/- 6.2 microM.     

Hypoxanthine transport through the blood-brain barrier

The unidirectional influx of hypoxanthine across cerebral capillaries, the anatomical locus of the blood=brain barrier, was measured with an in situ rat brain perfusion technique employing [³H]hypoxanthine. Hypoxanthine was transported across the blood-brain barrier by a saturable system with a one-half saturation concentration of approximately 0.4 mM. The permeability-surface area product was 3×10^–4 sec^–1 with a hypoxanthine concentration of 0.02 M in the perfusate. Adenine (4 mM) and uracil and theophylline (both 10 mM), but not inosine (10 mM) or leucine (1 mM), inhibited hypoxanthine transfer through the blood-brain barrier. Thus, hypoxanthine is transported through the blood-brain barrier by a high-capacity, saturable transport system with a half-saturation concentration about 100 times the plasma hypoxanthine concentration. Although involved in the transport hypoxanthine from blood into brain, this system is not powerful enough to transfer important quantities of hypoxanthine from blood into brain.