Discrete roles of hepatocytes and nonparenchymal cells in uridine catabolism as a component of its homeostasis

M. P. Liu1, L. Beigelman2, E. Levy3, R. E. Handschumacher1, and G. Pizzorno1

1 Section of Medical Oncology, Departments of Internal Medicine and Pharmacology, Yale University School of Medicine, New Haven, Connecticut 06520; 2 United States Biochemical, Cleveland, Ohio 44128; and 3 Abbott Diagnostics, Abbott Park, Illinois 60064

    ABSTRACT
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Previous studies indicated that uridine is essentially cleared in a single pass through a rat liver and replaced in a highly regulated manner by uridine formed presumably by de novo synthesis. We report a cellular basis for the catabolic component of this apparent paradox by dissociation of the liver with collagenase into two cell fractions, hepatocytes and a nonparenchymal cell population. Suspensions of the nonparenchymal cells rapidly cleave uridine to uracil, whereas in hepatocytes this activity was <5% of that in nonparenchymal cells. Conversely, hepatocytes cause extensive degradation of uracil to beta -alanine. These differences correlate with the uridine phosphorylase and dihydrouracil dehydrogenase activity in cell-free extracts of each cell type. We have documented the existence of a Na+-dependent, nitrobenzylthioinosine-insensitive transport system for uridine in the parenchymal cells (Michaelis constant 46 ± 5 µM) that achieves a three- to fourfold concentration gradient in hepatocytes. A similar system is present in the nonparenchymal cell population. In addition, a highly specific and active Na+-dependent transport system for beta -alanine, the primary catabolic metabolite of uracil, has been demonstrated in hepatocytes.

pyrimidines; metabolism; compartmentalization

    INTRODUCTION
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

A ROLE OF THE LIVER in the physiological regulation of circulating purines and pyrimidines has been suggested by numerous studies (6, 12, 16, 17). This laboratory (6) and others (14) have demonstrated that the liver is capable of rapid and essentially complete removal of incoming uridine derived from intestinal absorption and the peritoneal organs. Despite this extensive degradation, the concentration of uridine in blood exiting the liver is at least as great as that in the portal vein and hepatic artery. This uridine has been shown to be derived from de novo synthesis as well as turnover of the liver RNA and uracil nucleotide pools (6).

The ability to control the availability of endogenous nucleosides from circulation may be the limiting factor in the action of some inhibitors of pyrimidine synthesis de novo because tumors and normal tissues differ in their ability to transport and salvage nucleosides (5). Rescue of some normal tissues from 5-fluorouracil toxicity by very large doses of uridine has been reported (13). This requirement for large doses to overcome the rapid degradation of uridine provides further impetus to develop an understanding of the sites and cellular basis for uridine homeostasis.

Histochemical studies (23) have suggested that the localization of enzymes of uridine degradation and synthesis could be a key element of the fate of uridine. Uridine phosphorylase, the first enzyme of uridine degradation, was noted in the nuclei of nonparenchymal cells, whereas in hepatocytes such activity was not detected. Later, however, the highest rates of uridine phosphorolysis were attributed to Kupffer cells, but significant activity was also associated in those studies with hepatocytes and endothelial cells (7). The current study examines the cellular basis for the hepatic clearance of uridine by dissociation of the liver with collagenase into two cell fractions, hepatocytes and the nonparenchymal cell population, made up primarily of resident macrophages (Kupffer cells) and endothelial cells. The distinctly compartmentalized biochemical activity of each of these cell types provides insight on the cellular compartmentalization of uridine homeostasis.

    MATERIALS AND METHODS
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Chemicals. [5-3H]uridine (20 Ci/mmol) and [5,6-3H]uracil (25 Ci/mmol) were obtained from Moravek Biochemicals (Brea, CA). [Carboxy-14C]inulin (10 mCi/mmol) was purchased from Amersham (Arlington Heights, IL). [3H]H2O (18 µCi/mmol) and beta -[3-3H]alanine (87.20 Ci/mmol) were obtained from NEN (Boston, MA).

Hepatocytes and nonparenchymal cell preparation. A modification of the method of Seglen (1, 27) was used to prepare liver cell populations. Male Sprague-Dawley rats (150-200 g) from Charles River Laboratories were anesthetized with 50 mg/kg pentobarbital by intraperitoneal injection. Heparin (500 U/100 g body wt) was injected into the abdominal vena cava, and the livers were perfused through the portal vein with calcium-free perfusion buffer (pH 7.4 at 37°C) saturated with a gas mixture of 95% O2-5%CO2 (27) at 38 ml/min for 10 min. Extending the preperfusion beyond this time period reduced the metabolic and transport activity of both cell populations. The calcium-free perfusate was changed to buffer containing 0.025-0.05% collagenase (Boehringer Mannheim Biochemicals, Indianapolis, IN) and 0.5 mM CaCl2. Perfusion was continued for 10 min at 38 ml/min. The liver was removed from the animal and combed into 50 ml of L-15 medium (pH 7.4; GIBCO BRL, Grand Island, NY) saturated with O2. The cell suspension was filtered through 45-µm mesh nylon fabrics (Tetko), and the filtrate was sedimented at 50 g. The hepatocyte pellet was washed three times with cold L-15 medium and resuspended at 5 × 106 cells/ml.

The supernatant from the original centrifugation was sedimented at 400 g for 15 min to pellet nonparenchymal cells that were subsequently resuspended in the same medium. The final purification of hepatocytes and nonparenchymal cells was achieved by Percoll centrifugation (28). The cell viability, determined by trypan blue exclusion, was in excess of 85% for the hepatocytes and 90-95% for the nonparenchymal cells before use and at least 80% at the end of uptake experiments. The purity of the hepatocyte suspensions ranged from 92 to 95%. The nonparenchymal cell preparations were >95% pure, validated by esterase staining and microscopic evaluation of the cell suspension, and typically contained 55-60% of Kupffer cells and 35-40% of endothelial cells.

Transport studies. To prepare cells for transport studies, the suspension was pelleted at 500 g for 5 min in a Sorvall GLC-4 centrifuge. The pellet was resuspended twice in Na+-free (150 mM choline chloride) Hanks' balanced salt medium plus 5.5 mM D-glucose and 4 mM HEPES buffer (pH 7.4) and centrifuged at 500 g for 5 min. The pellet was resuspended with an appropriate medium [± Na+ with choline replacement and ± nitrobenzylthioinosine (NBMPR) to give a final cell density of 5 × 106 cells/ml].

The transport of [3H]uridine was initiated by mixing 30 µl of cell suspension with 60 µl of radioactive substrate in a 1.5-ml Eppendorf Microfuge tube. At appropriate time intervals, 60 µl of the mixture were placed in an "oil-stop tube" consisting of a 400-µl Eppendorf Microfuge tube containing 125 µl of oil (16% Fisher 0121 light paraffin oil, 84% Dow Corning 550 silicon fluid; final specific gravity 1.04 g/ml) layered over 30 µl of 15% TCA (100 µl for HPLC studies) and centrifuged in a Beckman model B Microfuge for 30 s at 10,000 g. Microfuge tubes were then cut through the oil layer, and radioactivity in each half was determined as previously described (4). Time-zero values, attributable to the extracellular radioactivity trapped in the cell pellet, were determined by centrifugation of 20 µl of cell suspension through a layer of radioactive substrate (40 µl) placed over the oil in the oil-stop tube. The intracellular volume was calculated in all experiments with [3H]H2O to determine total water space and [14C]inulin for estimation of extracellular space (4).

Uridine and uracil metabolism. Liver cells were incubated with 5 µM [3H]uridine or uracil at 22-24°C for various time periods. The reaction was terminated by the oil-stop method described previously. Supernatants were immediately removed from the oil-stop tube and mixed with 100 µl of 15% TCA. Both supernatant and cell pellet fractions were then extracted with an equal volume of trioctylamine and Freon (1,1,2-trichlorotrifluoroethane, Aldrich; 45:55, vol/vol). The [3H]uridine concentration was determined by HPLC using a C18 reverse phase column with a mobile phase of 10 mM phosphoric acid and 30 µM heptane-sulfonic acid (pH 3.3) at 1 ml/min at 13°C. The following retention times were observed: void volume, 3 min; uridine nucleotides, 4.5-5.5 min; uracil, 7-8 min; and uridine, 13 min. Intracellular [3H]uracil was determined by TLC separation on silica plates (Kieselgel 60 Merck) developed in chloroform-methanol-formic acid (65:18:1, vol/vol/vol) (18).

For assay of uridine phosphorylase, dihydrouracil dehydrogenase, and uridine kinase activity, hepatocytes and nonparenchymal cells were collected by centrifugation (1,000 g, 5 min) and washed twice by resuspending in the appropriate homogenization buffer containing potassium phosphate (20 mM, pH 8), 1 mM EDTA, and 1 mM beta -mercaptoethanol for the dehydrogenase assay (18) and Tris buffer (50 mM, pH 7.4) containing (in mM) 4 NaF, 2 dithiothreitol, and 2 MgCl2 for uridine phosphorylase and uridine kinase assays. The cell pellets were homogenized with a Tissuemizer in two volumes of the appropriate buffer, sedimented at 100,000 g for 1 h at 4°C, and the supernatant was used for enzyme assays.

Dihydrouracil dehydrogenase activity was determined by measuring the sum of the products (dihydrouracil, carbamyl-beta -alanine, and beta -alanine) formed from [5-3H]uracil. The incubation medium contained 25 µM [5-3H]uracil, 100 µM NADPH, and 25 µl cytosol in a final volume of 50 µl. After incubation at 37°C for 5, 10, and 30 min, the reaction was terminated by immersing the 500-µl Eppendorf tubes in a boiling water bath for 1 min. Proteins were removed by centrifugation, and 5 µl of the supernatant were spotted on silica gel TLC plates (Kieselgel 60, Merck) prespotted with 5 µl of a standard mixture containing 10 mM uracil, carbamyl-beta -alanine, and beta -alanine and 25 mM dihydrouracil. The TLC plates were developed in chloroform-methanol-formic acid (65:18:1). Uracil was identified by ultraviolet (UV) quenching and beta -alanine by spraying with 0.2% ninhydrin in 95% ethanol. Carbamyl-beta -alanine was visualized with 5% dimethylaminobenzaldehyde in 50% ethanol-1 N HCl, and appropriate areas were counted with 5 ml Ecolite in a Beckman model LS-700 liquid scintillation spectrometer.

Uridine phosphorylase and uridine kinase activity were determined by incubating 40 ul of cytosol with 200 µM [14C]uridine in 50 mM Tris buffer (pH 7.4) containing (in mM) 4 NaF, 2 dithiothreitol, 2 MgCl2, and 1 potassium phosphate (uridine phosphorylase) or ATP (1 mM) (uridine kinase) in a final volume of 100 µl at 37°C for 5-60 min. The mix (10 µl) was spotted on TLC plates (Kieselgel 60, Merck) while being quickly dried in a stream of hot air to stop the reaction. The TLC plates were prespotted with 3 µl of a nonradioactive standard mixture containing ~10 mM uridine, uracil, and UMP. The plates were developed in chloroform-methanol-acetic acid (17:3:1) and visualized by UV, and appropriate areas were assayed as described above. Protein concentrations were determined by the method of Bradford using BSA as a standard.

[3H]NBMPR-binding assay. Equilibrium [3H]NBMPR-binding assays were initiated by adding 20-µl aliquots of cell suspension (5 × 105 cells) to [3H]NBMPR (0.1-2 nM) in a final volume of 220 µl at 22°C in the presence or absence of 10 µM cold NBMPR. After 30 min incubation the reaction was stopped by the oil-stop method as previously described. Specific binding is defined as the difference between the [3H]NBMPR bound in the presence and absence of a competing nonradioactive ligand.

    RESULTS
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

To define the components and mechanisms of uridine homeostasis, cells of the rat liver have been separated into parenchymal (hepatocytes) and nonparenchymal (largely Kupffer and endothelial cells) populations. This has revealed a sharp dichotomy in the metabolic potential of these cell types. For these experiments a uridine concentration of 5 µM was chosen to approximate physiological levels. Very active catabolism of uridine occurs in the nonparenchymal cell population (Fig. 1), but uridine catabolism was essentially undetectable in hepatocytes. By contrast, the uracil generated by uridine phosphorolysis is remarkably stable in the nonparenchymal cell population but is very rapidly catabolized by hepatocytes (Fig. 2). 3-Deazauracil (20 µM), a competitive inhibitor of dihydrouracil dehydrogenase (20), reduced by 90% the catabolism of uracil in hepatocytes. This compartmentalization of the catabolic pathway seen in whole cells is reflected in the relative activity of the two enzymes, uridine phosphorylase and dihydrouracil dehydrogenase, in extracts of the two cell lineages (Fig. 3). We also determined the uridine phosphorylase activity of two macrophage cell lines, P388D1 and J774A.1. As reported in Table 1, extracts from each cell type had phosphorylase activity at least 10 times higher than that in hepatocyte extracts.


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Fig. 1.   Fate of [3H]uridine in suspension of rat liver hepatocytes and nonparenchymal cells. Cell suspensions (hepatocytes, 5 × 106 cells/ml; nonparenchymal cells, 3 × 106 cells/ml) were incubated with 5 µM [3H]uridine (1 µCi/ml), and the cells were processed as described in MATERIALS AND METHODS. Results represent means ± SE of 3 different experiments. UXP, uridine nucleotides.


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Fig. 2.   [3H]uracil catabolism in rat hepatocytes and nonparenchymal cells. Suspensions of hepatocytes (5 × 106 cells/ml) and nonparenchymal cells (3 × 106 cells/ml) were incubated with 5 µM [3H]uracil (1 µCi/ml) and processed as described in MATERIALS AND METHODS. Results represent means ± SE of 3 different experiments.


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Fig. 3.   Activity of uridine phosphorylase and dihydrouracil dehydrogenase in extracts of rat liver hepatocytes and nonparenchymal cells. Top: uridine phosphorylase reaction mixture containing 200 µM [14C]uridine and 40 µl cell extracts was incubated at 37°C. Bottom: dihydrouracil dehydrogenase reaction mixture containing 25 µM [3H]uracil, 100 µM NADPH, and 25 µl cell extracts was incubated at 37°C. Uracil and its metabolites were measured by TLC methods as described in the text. Results represent means ± SE of 3 different experiments.

                              
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Table 1.   Uridine phosphorylase activity in rat liver hepatocytes, nonparenchymal cells, and macrophages (P388D1 and J774A.1 cells)

Another major factor in uridine homeostasis may be membrane transport. Hepatocytes were found to exhibit a concentrative transport mechanism for uridine that is highly dependent on cotransport with Na+. This system has properties similar to Na+-dependent nucleoside transporters in kidney and intestinal cells. Intracellular concentrations of free [3H]uridine rapidly exceed media concentrations (Fig. 4), and the process is not sensitive to NBMPR. Although phosphorylation of uridine to nucleotide form could concentrate uridine radioactivity, under these experimental conditions HPLC and TLC analysis revealed that <10% of uridine was converted to uracil nucleotides.


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Fig. 4.   Time course of [3H]uridine uptake by rat hepatocytes. Hepatocytes suspended in regular Hanks' (+Na+) or 150 mM choline Hanks' (-Na+) were preincubated with or without 10 µM nitrobenzylthioinosine (NBMPR) for 5 min before addition of [3H]uridine to final concentration of 50 µM. Values are means ± SE of 3 different experiments.

The Na+-dependent uridine transport in hepatocytes exhibits typical Michaelis-Menten kinetics. In studies ranging from 5 to 200 µM uridine, we observed an apparent Michaelis constant (Km) of 46.8 ± 4 µM and a maximal velocity (Vmax) of 6.1 ± 0.5 pmol · µl-1 · s-1. The purine nucleosides adenosine, guanosine, and inosine were good inhibitors of this concentrative mechanism, whereas the pyrimidine nucleosides thymidine and cytidine were much less effective (Table 2).

                              
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Table 2.   Inhibitory effects of purine and pyrimidine nucleoside on sodium-dependent uridine transport in rat hepatocytes

Uridine uptake was evaluated in nonparenchymal cells, and in this cell population we observed a Na+-dependent concentrative transport mechanism for uridine very similar in its efficiency and capacity to that described for the hepatocytes with Km of 34.8 ± 4.0 µM and Vmax of 4.83 ± 0.65 pmol · µl-1 · s-1.

Na+-dependent transport is known to coexist with facilitated diffusion and passive equilibration in different proportions, depending on cell type. We have determined the number of NBMPR binding sites (1.5 ± 0.14 × 105/cell) and their affinity (0.6 ± 0.2 nM) in the hepatocyte populations. These values are in the range seen for many other cell types. However, measurement of uridine entry into hepatocytes in Na+-free (choline replacement) media in the presence and absence of 10 µM NBMPR indicates that at nonphysiological concentrations of uridine above 50 µM, the predominant mechanism is nonsaturable and presumed to be passive diffusion or at least NBMPR insensitive (Fig. 4). This may be an intrinsic property of hepatocytes or be consequent to the collagenase treatment that may alter the plasma membrane in a subtle manner to permit diffusion of uridine at high concentrations without permitting entry of trypan blue (cells exhibit >80% trypan blue exclusion). The very slight difference between intra- and extracellular concentrations of uridine at these unphysiological concentrations of uridine up to 2,000 µM may reflect small errors in the estimation of the intracellular volume by [14C]inulin and [3H]H2O. These factors may explain why hepatocytes in suspension are unable to generate more than threefold greater concentrations of uridine in the presence of Na+, whereas in the intact animal liver concentrations of uridine are about 10-fold greater than seen in the plasma (4).

The metabolism of [3H]uracil in hepatocytes is associated with an extensive accumulation of radioactivity within the cell. Intracellular uracil rapidly equilibrates with the medium concentration of uracil, but as time progresses most of the radioactivity is present as beta -alanine. This end product of the uracil catabolic pathway is avidly retained within cells by a Na+-dependent concentrative mechanism (Fig. 5) with an apparent Km of 38.8 ± 5.9 µM that has not previously been reported in liver cells (data not shown). GABA as well as hypotaurine, the sulfonic acid analog of beta -alanine, are potent inhibitors of this process with an apparent inhibitory constant of 20.0 ± 1.8 and 20.1 ± 1.3 µM, respectively. alpha -Fluoro-beta -alanine, the primary catabolic product of 5-fluorouracil, also exhibits inhibitory properties in this transport system, albeit less efficiently. All three compounds displayed competitive inhibition kinetics (data not shown). The intermediate degradation products of uracil, N-dihydrouracil and N-carbamyl-beta -alanine were not detected in agreement with a previous report (30) and in contrast to 5-fluorouracil catabolism where these intermediates can accumulate (29).


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Fig. 5.   Time course of beta -alanine uptake by rat hepatocytes. Hepatocytes suspended in either regular Hanks' (+Na+) or 150 mM choline Hanks' (Na+ free) were incubated with 5 µM beta -[3H]alanine for 25 min. Results represent means ± SE of 3 different experiments.

In nonparenchymal cells nonconcentrative entry of uracil occurred, but analysis of intracellular radioactivity indicated that >85% was present as uracil after 20 min of incubation. Extracellular radioactivity from each time point also indicated the absence of uracil degradation. Thus uracil is the end product of uridine degradation in the nonparenchymal cell population, and only hepatocytes are responsible for uracil degradation in rat liver. The enzymatic basis for this difference in uracil catabolism in two cell populations can be seen in the dihydropyrimidine dehydrogenase activity in cell-free extracts of both cell types (Fig. 3, bottom).

    DISCUSSION
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

The discrete compartmentalization of uridine metabolism between two cellular compartments of the liver affords a partial insight into the apparent paradox of essentially complete catabolism and replacement of plasma uridine in a single pass. Previous studies indicated relatively high phosphorylase activity in liver extracts (26). Although it had been shown that macrophages and Kupffer cells possess considerable uridine phosphorylase (7), the virtual absence of this enzyme activity in hepatocytes was unexpected, particularly since they comprise at least 80% of the liver mass.

The reciprocal relationship between uracil catabolism and uridine cleavage adds to the dichotomy of this physiological process. A possible model would be that entering uridine from both the hepatic artery and the portal circulation initially or at least predominantly encounters the endothelial and Kupffer cells that cleave it to uracil. Subsequently, uracil diffuses to hepatocytes where it is rapidly degraded. What remains to be established is the mechanism by which uridine concentrations in the hepatic vein are essentially equal to that found in the portal vein and the hepatic artery; this uridine is presumed to come from de novo synthesis in hepatocytes and possibly from the turnover of mRNA and other RNA species by 5-nucleotidase activity. Previously, it had been shown that the specific activity of exiting uridine is less than would be expected if it came solely from the acid-soluble pyrimidine nucleotide pool (6). In hepatocytes, however, most of the uridine formed by dephosphorylation of UMP is undoubtedly conserved for reutilization by the Na+-dependent active transport system documented in this report. What is also not clear at this time is the nature of the chemostat that maintains the concentration of uridine in blood at about 1-3 µM despite wide variations in the concentration of uridine entering the liver (6).

The remarkable stability of uridine in suspensions of hepatocytes indicates that a previous report (7) suggesting that uridine phosphorylase activity is associated with hepatocyte membranes has limited physiological significance. It is also apparent that the ~10-fold concentration of free uridine in the whole liver (4) is predominantly in the hepatocyte population because it comprises 80% or more of the total mass.

Although the coexistence of a unidirectional Na+-dependent pathway and equilibrative facilitated diffusion establishes a concentration of uridine inside hepatocytes, the equilibrium can be shifted by appropriate agents. The minimal effect of NBMPR indicates that at concentrations up to 50 µM uridine, facilitated diffusion plays a minor role. Other experiments not presented indicate that at higher concentrations of uridine the Na+-dependent process approaches saturation, and facilitated and passive diffusion mechanisms become predominant. The pattern of inhibition by purine nucleosides at lower concentrations of uridine is consistent with previous reports with renal tubular vesicles (10, 11) and enterocytes (8, 22) and confirms the presence of a purine-specific Na+-dependent transporter on the bile canalicular membrane (3). Other data support the existence of a Na+-dependent concentrative system found on the surface of the hepatocyte that forms the biliary canaliculi. In fact, uridine concentrations in bile are less than in blood, presumably because of the active concentration process that retains uridine (unpublished results). The transporter must also, however, be found in the basolateral membrane because hepatic concentrations of uridine rapidly respond to changes in plasma uridine to sustain a gradient of ~10 to 1 in the intact liver (4). This last observation is in agreement with a report from Ruiz-Montasell et al. (24) indicating the presence of a Na+-dependent uridine transporter in the basolateral membrane vesicles from rat liver. However, contradictory results were reported in an earlier study that demonstrated the existence of a Na+-dependent uptake only on the bile canalicular membrane (15).

Concentration of beta -alanine, the product of uracil catabolism by hepatocytes, occurs by a specific transporter different from that for neutral alpha -amino acids (9). It is also apparently different from beta -alanine transport in the brain (25). The current studies that demonstrate inhibition of transport by the neurotransmitter GABA raise the question of what may be the relevant natural substrate for this concentrative mechanism in the liver. beta -Alanine is a component of CoA, a low concentration cofactor, but is found in relatively high concentrations in various tissues as carnosine and anserine, dipeptides in amide linkage with histidine or methyl histidine. Because the liver has relatively low concentrations of these dipeptides and an active dipeptidase, carnosinase, it is unlikely to be a primary site of synthesis of these peptides for distribution to other tissues. Although several roles have been postulated for these dipeptides, definitive statements cannot be made about their normal metabolic roles or the effects of altered concentrations associated with certain disease states (2).

In a variety of animal species, including humans, the pool of incoming and exiting nucleosides is distinct and regulated to sustain uridine concentrations of 1-3 µm. The geometry of elements permitting this homeostasis of uridine in the liver is not yet known. The biological relevance of this system is apparent in 5-fluorouracil therapy as attempts are being made to expand or contract circulating and tissue pools of uridine and uracil nucleotides by administering exogenous uridine or such agents as PALA (20), brequinar (21), and benzylacyclouridine (5).

    ACKNOWLEDGEMENTS

The hepatic cells were kindly supplied by the Liver Research Core Center, supported in part by the National Institute of Diabetes and Digestive and Kidney Diseases Grant DK-34989 and by the National Cancer Institute Grant R25-CA-47883-03.

    FOOTNOTES

The study was supported by grants from the American Cancer Society (CH67) and National Cancer Institute (CA-08341, CA-45303, and CA-67035).

Address for reprint requests: G. Pizzorno, Section of Medical Oncology, Dept. of Internal Medicine, Yale Univ. School of Medicine, New Haven, CT 06520.

Received 10 October 1997; accepted in final form 27 February 1998.

    REFERENCES
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

1.   Berry, M. N., and D. S. Friend. High-yield preparation of isolated rat liver parenchymal cells: a biochemical and fine structural study. J. Cell Biol. 43: 506-520, 1969[Abstract/Free Full Text].

2.   Boldyrev, A. A., and S. E. Severin. The histidine-containing dipeptides, carnosine and anserine: distribution, properties and biological significance. Adv. Enzyme Regul. 31: 175-194, 1990.

3.   Che, M.-X., D. F. Ortiz, and I. M. Arias. Primary structure and functional expression of a cDNA encoding the bile canalicular, purine-specific Na+-nucleoside cotransporter. J. Biol. Chem. 270: 13596-13599, 1995[Abstract/Free Full Text].

4.   Darnowski, J. W., and R. E. Handschumacher. Tissue uridine pools: evidence in vivo of a concentrative mechanism for uridine uptake. Cancer Res. 46: 3490-3494, 1986[Abstract].

5.   Darnowski, J. W., and R. E. Handschumacher. Enhancement of fluorouracil therapy by the manipulation of tissue uridine pools. Pharmacol. Ther. 41: 381-392, 1989[Medline].

6.   Gasser, T., J. D. Moyer, and R. E. Handschumacher. Novel single-pass exchange of circulating uridine in rat liver. Science 213: 777-778, 1981[Medline].

7.   Holstege, A., H. G. Leser, J. Pausch, and W. Gerok. Uridine catabolism in Kupffer cells, endothelial cells and hepatocytes. Eur. J. Biochem. 149: 169-173, 1985[Abstract].

8.   Jakobs, E. S., and A. R. P. Paterson. Sodium-dependent concentrative nucleoside transport in cultured intestinal epithelial cells. Biochem. Biophys. Res. Commun. 14: 1028-1035, 1986.

9.   Le Cam, A., and P. Freychet. Neutral amino acid transport. Characterization of A and L systems in isolated rat hepatocytes. J. Biol. Chem. 252: 148-156, 1977[Abstract].

10.   Lee, C. W., C. J. Cheeseman, and S. M. Jarvis. Na+-dependent uridine transport in rat renal brush border membrane vesicles. Biochim. Biophys. Acta 942: 139-149, 1988[Medline].

11.   Le Hir, M., and U. C. Dubach. Uphill transport of pyrimidine nucleosides in renal brush border vesicles. Pflügers Arch. 404: 238-243, 1985[Medline].

12.   Levine, R. L., N. T. Moogenhaad, and N. Kretchmese. A review: biological and clinical aspects of pyrimidine metabolism. Pediatr. Res. 8: 729-734, 1975.

13.   Martin, D. S., R. L. Stolfi, R. C. Sawyer, S. Spiegelman, and C. W. Young. High-dose 5-fluorouracil with delayed uridine "rescue" in mice. Cancer Res. 42: 3964-3969, 1982[Abstract].

14.   Monks, A., and R. L. Cysyk. Uridine regulation by isolated rat liver: perfusion with artificial oxygen carrier. Am. J. Physiol. 242 (Regulatory Integrative Comp. Physiol. 11): R465-R470, 1982[Medline].

15.   Moseley, R. H., S. Jarose, and P. Permoad. Adenosine transport in rat liver plasma membrane vesicles. Am. J. Physiol. 261 (Gastrointest. Liver Physiol. 24): G716-G722, 1991[Abstract/Free Full Text].

16.   Moyer, T. D., and R. E. Handschumacher. Selective inhibition of pyrimidine synthesis and depletion of nucleoside pools by N-(phosphonacetyl)-4-aspartate. Cancer Res. 39: 3089-3094, 1979[Medline].

17.   Moyer, T. D., T. T. Oliver, and R. E. Handschumacher. Salvage of circulating pyrimidine nucleosides in the rat. Cancer Res. 41: 3010-3017, 1981[Abstract].

18.   Naguib, F. N. M., M. H. el Kouni, and S. Cha. Enzymes of uracil catabolism in normal and neoplastic human tissues. Cancer Res. 45: 5405-5412, 1985[Abstract].

19.   Naguib, F. N. M., M. H. el Kouni, and S. Cha. Structure-activity relationship of ligands of dihydrouracil dehydrogenase from mouse liver. Biochem. Pharmacol. 38: 1471-1480, 1989[Medline].

20.   O'Dwyer, P. J., A. R. Paul, J. Walczak, L. M. Weiner, S. Litwin, and R. L. Comic. Phase II study of biochemical modulation fluorouracil by low dose PALA in patients with colorectal cancer. J. Clin. Oncol. 8: 1497-1503, 1990[Abstract].

21.   Pizzorno, G., R. A. Wiegand, S. K. Lentz, and R. E. Handschumacher. Brequinar potentiates 5-fluorouracil antitumor activity in a murine model colon 38 tumor by tissue specific modulation of uridine nucleotide pools. Cancer Res. 52: 1660-1665, 1992[Abstract].

22.   Plagemann, P. G. W., and J. M. Aran. Characterization of Na+-dependent, active nucleoside transport in rat and mouse peritoneal macrophages, a mouse macrophage cell line and normal rat kidney cells. Biochim. Biophys. Acta 1022: 93-102, 1990[Medline].

23.   Rubio, R., and R. M. Berne. Localization of purine and pyrimidine nucleoside phosphorylases in heart, kidney and liver. Am. J. Physiol. 239 (Heart Circ. Physiol. 8): H721-H730, 1980[Medline].

24.   Ruiz-Montasell, B., F. J. Casado, A. Felipe, and M. Pastor- Anglada. Uridine transport in basolateral plasma membrane vesicles from rat liver. J. Membr. Biol. 128: 227-233, 1992[Medline].

25.   Schon, F., and J. S. Kelly. The selective uptake of [3H]-beta -alanine by glia: association with the glial uptake system for GABA. Brain Res. 86: 243-257, 1975[Medline].

26.   Schwartz, P. M., R. D. Moir, C. M. Hyde, P. J. Turek, and R. E. Handschumacher. Role of uridine phosphorylase in the anabolism of 5-fluorouracil. Biochem. Pharmacol. 34: 3585-3589, 1985[Medline].

27.   Seglen, P. O. Preparation of isolated rat liver cells. Methods Cell Biol. 13: 29-83, 1976[Medline].

28.   Smedsrod, B., and H. Pertoft. Preparation of pure hepatocytes and reticuloendothelial cells in high yield from a single rat liver by means of Percoll centrifugation and selective adherence. J. Leukoc. Biol. 38: 213-230, 1985[Abstract].

29.   Sommadossi, J. P., D. A. Gewirtz, R. B. Diasio, C. Aubert, J. P. Cano, and I. D. Goldman. Rapid catabolism of 5-fluorouracil in freshly isolated rat hepatocytes as analyzed by high performance liquid chromatography. J. Biol. Chem. 237: 8171-8176, 1982.

30.   Traut, T. W., and S. Loechel. Pyrimidine catabolism: individual characterization of the three sequential enzymes with new assay. Biochemistry 23: 2533-2539, 1984[Medline].


Am J Physiol Gastroint Liver Physiol 274(6):G1018-G1023
0002-9513/98 $5.00 Copyright © 1998 the American Physiological Society