The application of rapid kinetic techniques to the transport of thymidine and 3-O-Methylglucose into Mammalian cells in suspension culture

Antioxidant and Inhibitory Effects of Saponin Extracts from Dianthus basuticus Burtt Davy on Key Enzymes Implicated in Type 2 Diabetes In vitro

Context:

Dianthus basuticus is a plant of South African origin with various acclaimed pharmaceutical potentials.

Aims:

This study explored the antioxidant and antidiabetic activities of saponin extract from D. basuticus in vitro.

Materials and Methods:

Antioxidant activity of saponin was evaluated by 2,2-diphenyl-1-picrylhydrazyl (DPPH) and nitric oxide (*NO)-free radical scavenging activity while antidiabetic potentials were measured by the α-amylase and α-glucosidase inhibitory activities of the saponin extract.

Results:

The results showed that the saponin extract, compared with quercetin, displayed better DPPH (IC₅₀ = 6.95 mg/ml) and NO (IC₅₀ = 3.31 mg/ml) radical scavenging capabilities. Similarly, the saponin extracts elicited stronger α-glucosidase (IC₅₀ = 3.80 mg/ml) and moderate α-amylase (IC₅₀ = 4.18 mg/ml) inhibitory activities as compared to acarbose. Saponin exhibited a competitive mode of inhibition on α-amylase with same maximum velocity (Vmax) of 0.0093 mM/min for saponin compared with control 0.0095 mM/min and different the Michaelis constant (Km) values of 2.6 × 10^-6 mM and 2.1 × 10^-5 mM, respectively, while for α-glucosidase, the inhibition was uncompetitive, Vmax of 0.027 mM/min compared with control 0.039 mM/min and Km values of 1.02 × 10^-6 mM and 1.38 × 10^-6 mM, respectively. The gas chromatography-mass spectrometric analysis revealed the presence of bioactive like β- and α-amyrin, 3-O-methyl-D-glucose, methyl commate, and olean-12-en-3-beta-ol.

Conclusion:

Overall, the data suggested that the saponin extract from D. basuticus has potentials as natural antioxidants and antidiabetics.

SUMMARY

Saponin extract from Dianthus basuticus displayed promising antidiabetic and antioxidant activity

Saponin competitively and uncompetitively inhibited a-amylase and a-glucosidase, respectively

The stronger inhibition of α-glucosidase and moderate inhibition of α-amylase by saponin extract from D. basuticus is promising good antidiabetes compared with existing drugs with associated side effects.

Abbreviations used: DPPH: 2,2-diphenyl-1-picrylhydrazyl, Km: The Michaelis constant, Vmax: Maximum velocity, ROS: Reactive oxygen species, NIDDM: Non-insulin-dependent diabetes mellitus, UFS: University of the Free State, GC-MS: Gas chromatography-mass spectrometric, MS: Mass spectrometry, NIST: National Institute of Standards and Technology, DNS: 3,5-dinitrosalicylic acid, NO: Nitric oxide, RNS: Reactive nitrogen species, PNPG: p-Nitrophenyl-α-D-glucopyranoside.

Relationship of octanol/water partition coefficient and molecular weight to cellular permeability and partitioning in s49 lymphoma cells

We have used modified standard methods and derived new formulae to quantitate cell permeability (P), cell/media partitioning (λ), and intracellular sequestration or binding rate constants (m) for cultured S49 murine lymphoma cells in suspension. Using 15 standard compounds and anticancer drugs, we found quantitative relationships among log P, log PO (octanol/pH 7.4 buffer partition coefficient), and molecular weight (MW) such that logP = -4.5 + 0.56log (PO(MW)(-1/2)). A good correlation among P, λ, and MW was also determined with λ = 0.67 + 5890 gm(1/2) cm(-1) sec (P (MW)(1/2)). These studies show that there is a strong partitioning (λ) dependence to molecular weight and permeability that can be predicted even for known carrier-transported and biotransformable compounds. Furthermore, results of this study show that the slope of the plot of permeability and lipophilicity is not necessarily unity as has been postulated from the results of other studies.

Preservation of mouse sperm by convective drying and storing in 3-O-methyl-D-glucose

With the fast advancement in the genetics and bio-medical fields, the vast number of valuable transgenic and rare genetic mouse models need to be preserved. Preservation of mouse sperm by convective drying and subsequent storing at above freezing temperatures could dramatically reduce the cost and facilitate shipping. Mouse sperm were convectively dried under nitrogen gas in the Na-EGTA solution containing 100 mmol/L 3-O-methyl-D-glucose and stored in LiCl sorption jars (Relative Humidity, RH, 12%) at 4°C and 22°C for up to one year. The functionality of these sperm samples after storage was tested by intracytoplasmic injection into mouse oocytes. The percentages of blastocysts produced from sperm stored at 4°C for 1, 2, 3, 6, and 12 months were 62.6%, 53.4%, 39.6%, 33.3%, and 30.4%, respectively, while those stored at 22°C for 1, 2, and 3 months were 28.8%, 26.6%, and 12.2%, respectively. Transfer of 38 two- to four-cell embryos from sperm stored at 4°C for 1 year produced two live pups while 59 two- to four-cell embryos from sperm stored at 22°C for 3 months also produced two live pups. Although all the pups looked healthy at 3 weeks of age, normality of offspring produced using convectively dried sperm needs further investigation. The percentages of blastocyst from sperm stored in the higher relative humidity conditions of NaBr and MgCl(2) jars and driest condition of P(2)O(5) jars at 4°C and 22°C were all lower. A simple method of mouse sperm preservation is demonstrated. Three-O-methyl-D-glucose, a metabolically inactive derivative of glucose, offers significant protection for dried mouse sperm at above freezing temperatures without the need for poration of cell membrane.

Mg2+ as activator of uridine phosphorylation in coordination with other cellular responses to growth factors

The divalent cation ionophore A23187 facilitates the manipulation of intracellular Mg2+ without increasing the general permeability of the cell. The uptake of uridine into cells is limited by its rate of intracellular phosphorylation that increases within minutes after the addition of growth factors. In the experiments described here, the rate of uridine uptake in ionophore-treated cells stimulated by either serum or insulin depended on the extracellular and intracellular concentrations of Mg2+ and was independent of the extracellular Ca2+ concentration. In very high concentrations of Mg2+ (50 mM), ionophore-treated cells take up uridine as fast, in the absence of growth factors as in their presence, demonstrating that Mg2+ can replace the growth factor requirement for the stimulation of uridine uptake. In contrast, thymidine uptake, which also is limited by its rate of intracellular phosphorylation, showed no early response to either growth factors or Mg2+ concentration, which is consistent with the 10-fold lower Mg2+ requirement of thymidine kinase compared with uridine kinase. The feedback inhibition of uridine kinase by UTP and CTP in cell-free extracts was alleviated by increased Mg2+ concentration. The results support the thesis that the increased uptake of uridine in cells treated with growth factors is determined by a membrane-induced increase in intracellular free Mg2+. Such increase would also accelerate the rate of translation-initiation and other coordinate responses that, unlike increased uridine uptake, are essential for cell proliferation. The rate of uridine uptake is suggested as a direct indicator of free cytosolic Mg2+ that drives the shift from quiescence to proliferation.

Kinetic Analysis of 2-[11C]Thymidine PET Imaging Studies of Malignant Brain Tumors: Compartmental Model Investigation and Mathematical Analysis

2-[11C]Thymidine (TdR), a PET tracer for cellular proliferation, may be advantageous for monitoring brain tumor progression and response to therapy. We previously described and validated a five-compartment model for thymidine incorporation into DNA in somatic tissues, but the effect of the blood–brain barrier on the transport of TdR and its metabolites necessitated further validation before it could be applied to brain tumors. Methods: We investigated the behavior of the model under conditions experienced in the normal brain and brain tumors, performed sensitivity and identifiability analysis to determine the ability of the model to estimate the model parameters, and conducted simulations to determine whether it can distinguish between thymidine transport and retention. Results: Sensitivity and identifiability analysis suggested that the non-CO2 metabolite parameters could be fixed without significantly affecting thymidine parameter estimation. Simulations showed that K1t and KTdR could be estimated accurately ( r = .97 and .98 for estimated vs. true parameters) with standard errors < 15%. The model was able to separate increased transport from increased retention associated with tumor proliferation. Conclusion: Our model adequately describes normal brain and brain tumor kinetics for thymidine and its metabolites, and it can provide an estimate of the rate of cellular proliferation in brain tumors.

Pharmacokinetics of the thymidine analog 2'-fluoro-5-[(14)C]-methyl-1-beta-D-arabinofuranosyluracil ([(14)C]FMAU) in rat prostate tumor cells

2'-Fluoro-5-[(14)C]-methyl-1-beta-D-arabinofuranosyluracil (FMAU) is an analog of thymidine (TdR) that is resistant to catabolism, is incorporated into DNA, and has been labeled with (11)C for use with positron emission tomography. We compared the uptake and metabolism of [(14)C]FMAU with that of [(3)H]TdR in fast- and slow-growing cell lines of a rat prostate tumor. Although FMAU was incorporated much less rapidly than TdR, FMAU behaved very similarly to TdR with respect to correlation between uptake velocity and cell growth rate, saturability of cellular incorporation, and intracellular metabolite pools. Thus, FMAU warrants further evaluation as an in vivo indicator of tumor cell division.

Cellular uptake of oligodeoxyribonucleoside methylphosphonates

The cellular uptake of oligodeoxyribonucleoside methylphosphonates has been evaluated using three radiolabeled oligomers. Oligomers I and II ([3H]-T8 and [3H]-T16, respectively) are nonionic methylphosphonate oligomers labeled with tritium on the phosphonate internucleotide linkage. EDA-III contains a single phosphodiester linkage, a [32P]-label and an ethylenediamine conjugate at the [32P]-5'-end. All three oligomers are stable in cells. At a 1 microM concentration, oligomer I is not taken up by human erythrocytes. The octanol/DPBS partition coefficients for oligomers I and II (1.5 x 10(-4) and 4.2 x 10(-4), respectively) further indicate that these molecules should not diffuse across cell membranes at appreciable rates. Oligomer I is taken up by HL-60 cells, although at a slower rate than the uptake of the fluid-phase marker sucrose. The cell-associated levels of oligomer II in K-562 cells following incubation of cells with the oligomer for 2 days is independent of concentration and nonsaturable, suggesting a mechanism of uptake independent of receptor. Finally, the initial uptake rate of EDA-III in mouse L cells is greater than the uptake of two oligodeoxyribonucleotides (T8, T16), reaching a plateau after 3 hours incubation with cells. These observations should aid in the elucidation of the mechanism by which this class of antisense agents enters the intracellular environment.

Evaluation of the mutagenic effects of SV40 in mouse, hamster, and mouse-human hybrid cells

We have examined the ability of SV40 to induce changes in drug or temperature resistance in mouse, hamster, and mouse-human hybrid cells. SV40 induced a substantial increase of cells resistant to 5-bromodeoxyuridine + trifluorothymidine in Balb/c 3T3 cells and induced an increase of hybrid cells resistant to 6-thioguanine. SV40 was found to be nonmutagenic or weakly mutagenic in other test systems. The 3T3 cells were T-antigen positive, exhibited a marked reduction in TK activity, were heterogeneous for [3H]BrdU incorporation by autoradiography, and exhibited instability of the drug-resistance phenotype, suggesting that SV40 may be inducing resistance by an epigenetic process. SV40-induced 6-thioguanine resistance in the hybrids appears to occur predominantly by chromosome loss.

[Effect of purine-rich nutrients on weight gain, catabolites in blood plasma and the uric acid transport of erythrocytes--a model study in dogs]

In a nutritional tolerance study 36 young dogs were fed over 52 weeks high or low purine diets at an average paired feeding intake of 0.6 and 80 mg purine-N/MJ per day. The high purine diet resulted in a significant decrease of growth rate by -23% (Beagles) and -38% (Dalmatians) and of feed efficiency (-29 and -42%). The fasting levels of allantoin, uric acid and uracil in blood plasma were significantly increased. During the experiment a metabolic adaptation to the high purine diet decreased the plasma concentrations of uric acid, uracil and in part of allantoin. The high purine diet effected a significant increase of Km (2.5-fold) and of Vmax (1.6-fold) of uric transport through the erythrocyte membrane. The results documented disadvantageous effects of high purine nutrition during juvenile development.

Initial single-strand DNA damage and cellular pharmacokinetics of bleomycin A2

The cellular association and fate of high specific activity [3H]bleomycin A2 (BLM A2) were examined in three previously untreated cultured cell lines. Human head and neck A-253 carcinoma cells were 10-fold more sensitive to a 1-hr exposure to BLM A2 than either murine leukemic L1210 or human ovarian SK-OV cells. Both murine and human cells displayed rapid drug association with steady-state drug levels being reached within 15-30 min. At steady state, the T1/2 of drug dissociation was slow (between 65 and 155 min), unaltered by 100-fold excess of unlabeled BLM A2, and unrelated to cellular sensitivity to BLM. Approximately 15% of the total cellular drug was found in the nuclei at steady state. In intact cells, BLM hydrolase activity appeared latent; significant BLM hydrolase activity was detected using broken cell homogenates with all cell types, but no extensive drug metabolism was evident in intact cells. Murine L1210 cells differed from both human cell lines in that they had only 50% of the steady-state drug levels, had lower nuclear drug content, and had markedly less initial single-strand DNA damage. Human SK-OV cells had 2.4-fold greater initial single-strand DNA damage despite similar nuclear content and a much lower rate of DNA repair. Thus, cellular or nuclear factors, in addition to BLM A2 content, affect initial single-strand DNA damage. Collectively, our data support the proposition that lesions other than single-strand DNA breaks contribute to the cytotoxicity of BLM.

Membrane transport and the antineoplastic action of nucleoside analogues

This article summarizes recent studies characterizing nucleoside transport in mammalian cells and discusses evidence for a role of membrane transport in the pharmacologic action of nucleoside analogues. Some of these studies have also addressed the controversy concerning the multiplicity in transport routes. It seems clear that erythrocytes and, perhaps, some other mammalian cells possess a single, broadly specific system for transporting nucleosides. However, substantial evidence from valid studies discriminating between transport and intracellular metabolism suggests that at least some mammalian cells, including some tumor cells, possess more than a single system. Evidence now exists for a determining role of membrane transport of nucleoside analogues in their cytotoxicity and, in the case of one pyrimidine nucleoside (AraC), in therapeutic responsiveness in leukemic patients. There are also numerous examples of transport-related resistance to nucleoside analogues. Included in this article are the results of studies from the authors' laboratory pertaining to the therapeutic activity of the purine nucleoside, FAraA, in murine tumor models. These studies provide evidence for a determining role of both membrane transport and intracellular phosphorylation in the selective antitumor action of this agent against murine leukemia. Substantially increased transport inward of FAraA occurs at pharmacologically achievable concentrations of this agent in tumor cells as compared to drug-limiting, normal proliferative epithelium of the small intestine. The basis for this differential appears to be the kinetic duality of FAraA and adenosine transport inward found in tumor cells, but not in proliferative intestinal epithelial cells. Tumor cells have highly saturable (low influx Km) and poorly saturable (high influx Km) systems for adenosine transport, both of which are shared by FAraA. In contrast, proliferative epithelial cells have only a poorly saturable system for these substrates. If a similar kinetic duality of nucleoside transport is found in other tumor cells certain implications arise concerning the significance of the duality to neoplastic transformation.

Carrier-mediated transport of folate compounds in L1210 cells. Initial rate kinetics and extent of duality of entry routes for folic acid and diastereomers of 5-methyltetrahydrohomofolate in the presence of physiological anions

Comparison of the kinetic parameters for influx of highly purified [3H]folic acid versus [3H]methotrexate in L1210 cells under anionic buffer conditions showed a marked discordancy. In addition, the kinetics for influx of [3H]folic acid were unchanged in variant L1210 cells defective in [3H]methotrexate transport. In these variant cells, the Vmax for methotrexate was reduced 17-fold and the Km was increased 3-fold. The results show that [3H]folic acid influx is mediated by a system which has a low affinity, but a 20-fold higher capacity, for folate compounds than the classical high-affinity system mediating [3H]methotrexate influx. Since the latter system also exhibits very low affinity for [3H]folic acid, it would not be expected to contribute significantly to the total influx of [3H]folic acid. The high-capacity system for [3H]folic acid influx is different from that believed to mediate pterin influx in L1210 cells since it was not inhibited by adenine, a potent inhibitor of pterin influx. However, exposure of cells to [3H]folic acid in a nonanionic buffer resulted in marked stimulation of initial influx, and a fraction of influx under these conditions was inhibited by methotrexate. These results suggest that anions modulate the extent of multiplicity of [3H]folic acid influx by their known effects on the high-affinity, reduced folate/methotrexate system. The diastereomers, at carbon 6, of [14C]5-methyltetrahydrohomofolate shared both transport systems. The influx Km for the natural diastereomer was one-half that of the unnatural form for both transport systems. Both diastereomers showed a much greater differential in affinity between the two transport systems than did [3H]folic acid. Our results suggest that an analog which could be effectively transported by the low-affinity/high-capacity route may be useful in the treatment of tumors resistant to methotrexate due to a defective high-affinity/low capacity influx system. We also found that incubation of L1210 cells with [3H]folic acid or the natural diastereomer [14C]5-methyltetrahydrohomofolate for 10 min resulted in the formation of a nonexchangeable fraction of radioactivity amounting to 20-40% of the total accumulation. This non-exchangeable fraction may be explained by the accumulation of metabolites other than polyglutamates. Preloading of cells with methotrexate prior to incubation with [3H]folic acid prevented the accumulation of radioactivity as a nonexchangeable fraction.

Further studies on amino acid transport in murine P388 leukemia cells in vitro. Presence of system y+

The transport of glycine and L-lysine into murine P388 leukemia cells has been examined. Glycine transport appears to be shared by both systems A and ASC in P388 cells. Glycine transport is Na+-dependent and is effectively blocked by alpha-(methylamino)isobutyric acid, threonine and alanine but only a marginal reduction in transport is seen with 100-fold excess cold 2-aminobicyclo[2,2,1]heptane-2-carboxylic acid. System gly is not expressed in P388 cells. Lysine is largely transported by a Na+-independent, pH-insensitive system with a Km of 0.079 mM. Lysine transport is relatively unaffected by the addition of 100-fold excess cold alpha-(methylamino)isobutyric acid, 2-aminobicyclo[2,2,1]heptane-2-carboxylic acid and the anionic amino acids, L-glutamate and L-aspartate. A partial inhibition of lysine transport was observed with L-threonine and L-leucine while L-arginine and L-histidine radically decreased lysine transport. Lysine appears to be transported by a system similar to the system y+ seen in cultured human fibroblasts, Ehrlich ascites cells, and hepatoma cell lines.

Perfluorodecanoic acid inactivation of a channel for 2-aminopurine in the L5178Y cell membrane and recovery of the channel

Treatment of L5178Y mouse lymphoma cells with perfluoro-n-decanoic acid (PFDA) in growth medium for 24 hr at 30 degrees C produces a dose-dependent inactivation of a channel in the cell membrane. Activity of the channel was estimated from the initial rate of efflux of a fluorescent purine, 2-aminopurine (AP). The L5178Y cells were preloaded with 100 microM AP and excess AP was removed. The preloaded cells were put in a flow system, and AP efflux was estimated continuously at 21 degrees C from the fluorescence emission of AP at 370 nm. The AP channel was markedly inactivated by a treatment with 150 micrograms/ml PFDA for 24 hr at 30 degrees C. There was no significant recovery of AP flux after 3 days at 30 degrees C in fresh growth medium; however, recovery was significant after 6 days. Recovery of activity of the AP channel occurs in 1 day at 37 degrees C. The initial rate of AP efflux for control cells increases with AP concentration; the reaction is not saturated at 1000 microM AP. The efflux of AP was inhibited by the presence of uric acid in the external buffer. An apparent inhibition constant value of 355 microM was determined for urate inhibition of AP efflux. These observations suggest the presence of a urate-sensitive channel for AP in the membrane of L5178Y cells. The channel was inactivated by PFDA under conditions that had no significant effect on cell viability.

Studies on the mechanisms of the radiosensitizing and cytotoxic properties of RSU-1069 and its analogues

RSU 1069 is a substantially more efficient sensitizer than misonidazole when hypoxic Chinese hamster V79 cells are irradiated in vitro at room temperature; such that for 0.5 mmol dm-3 sensitizer an ER of 3.0 is obtained for RSU 1069 whereas an ER of only 1.6 is obtained for misonidazole. However, when irradiation is done at 4 degrees C, the radiosensitization caused by RSU 1069 is reduced to a level close to that obtained with misonidazole, the action remaining unaltered at the lower temperature. This temperature dependent component of sensitization for RSU 1069 suggests the involvement of a slow biochemical process that has an appreciable activation energy. The RSU 1069 analogue RB 7040 is a more efficient radiosensitizer than RSU 1069 particularly at lower concentrations. This compound has a pKa value of 8.45, in contrast to that of RSU 1069 which is 6.04. Weak bases with pKa values in excess of average intra-cellular pH can be taken up preferentially into cells from medium at pH 7.4. It is shown that RB 7040 has a 4 X higher intracellular concentration than RSU 1069 for a similar extracellular concentration. This will explain, at least in part, the greater sensitizing efficiency of this compound when compared to RSU 1069 in vitro.

Characterization of L-threonine and L-glutamine transport in murine P388 leukemia cells in vitro. Presence of an N-like amino acid transport system

The transport of L-threonine and L-glutamine into murine P388 leukemia cells has been characterized. Threonine appears to be a specific substrate for a Na+-dependent amino acid transport system similar to system ASC of the HTC hepatoma cell. Threonine transport is uninhibited by 2-aminobicyclo[2,2,1]heptane-2-carboxylic acid and alpha-(methylamino)isobutyric acid, shows a pattern of transport similar to that seen in HTC hepatoma cells over the pH range of 5.5-7.5, and is inhibited by L-serine and L-cysteine. Approximately two-thirds of glutamine transport into P388 cells also appears to enter P388 cells via this ASC-analogous system. However, based upon (a) inhibition studies with threonine (where the K1 of threonine inhibition of glutamine transport was 7-fold the Km of threonine transport), (b) inhibition analysis of glutamine transport with various amino acids and amino acid analogues, and (c) different patterns of transport between threonine and glutamine over the pH range of 5.5-7.5, approximately one-third of glutamine transport can be attributed to a second Na+-dependent amino acid transport system. This system appears to be similar to the system N of rat hepatocytes. Glutamine and threonine do not appear to enter P388 cells via systems A or L to any significant degree. P388 cells do not appear to exhibit 'adaptive regulation' of amino acid transport. Differences in 'adaptive regulation' could therefore not be utilized for comparing threonine and glutamine transport.

Markedly altered membrane transport and intracellular binding of vincristine in multidrug-resistant Chinese hamster cells selected for resistance to vinca alkaloids

Studies of a multidrug-resistant variant (DC-3F/VCRd-5L) of Chinese hamster lung cells selected for resistance to vinca alkaloids revealed marked alterations in transport and intracellular binding of [3H]vincristine compared to parental DC-3F cells. Influx of [3H]vincristine in DC-3F cells appears to be an equilibrating, but mediated, process. Although saturation kinetics for [3H]vincristine influx were not demonstrated, an extremely high temperature-dependence (Q10 27-37 degrees C = 5-6) and trans-inhibition of influx following preloading of cells with nonradioactive vincristine argue in favor of a carrier-mediated process. Efflux of [3H]vincristine from parental cells conformed to first-order kinetics (t1/2 37 degrees = 3.6 +/- 0.4) and exhibited a lower temperature-dependence (Q10 27-37 degrees C = 3-3.5) than influx. In variant vs. parental cells, influx of [3H]vincristine was reduced 24-fold and efflux was increased two-fold, accounting for the large (approximately 48-fold) reduction in steady-state level of exchangeable drug accumulating in variant cells. Otherwise, transport of [3H]vincristine in these cells showed characteristics similar to parental DC-3F cells. Also, the rate and amount of intracellular binding of [3H]vincristine in variant cells was almost 40-fold lower than in parental cells. These alterations in influx and efflux of [3H]vincristine and its intracellular binding appear to account, at least to a major extent, for the high level of resistance (2,750-fold) of this variant to vinca alkaloids. In contrast, cross-resistance of this variant to daunomycin (178-fold) could be explained only minimally by a transport alteration. Only a two-fold increase in efflux of [3H]daunomycin was demonstrated in variant vs. parental cells along with some decrease in intracellular binding. Influx of [3H]daunomycin was unaltered. In view of these results, we conclude that these two agents most likely do not share the same route for entry in these cells but might share the same efflux route.

Uric acid uptake in erythrocytes of beagle and dalmatian dogs

Uric acid uptake by erythrocytes of Beagle and Dalmatian dogs has been measured, using (2-14C) uric acid. Uptake was characterized by a fast and a slow component. Urate uptake was inhibited by certain purine and pyrimidine derivatives and by anion transport inhibitors. It was dependent on intraerythrocyte glycolysis. Temperature only influenced uptake by the slow component (Q10 = 2.6). Urate uptake by the slow component is apparently due to the transport into the erythrocytes by facilitated diffusion (Km = 6.6 mmol/l, Vmax = 390 mumol/l/min), whereas the fast component exhibits an adsorption of urate on erythrocyte surface. No difference of urate uptake by erythrocytes of Beagle and Dalmatian dogs has been observed.

Effects of amino acids on the transport and cytotoxicity of melphalan by human bone marrow cells and human tumor cells

In human tumor cells freshly obtained from patients with breast cancer, ovarian cancer, or adenocarcinoma of unknown etiology and in normal human bone marrow cells, the cell-to-medium ratio (intracellular/extracellular concentration) in vitro of 5.42 microM melphalan rose rapidly to levels of 6-17 after 35 min at 37 degrees C in Dulbecco's phosphate-buffered saline containing bovine serum albumin and glucose. Only patient C (breast cancer) had received chemotherapy. In all cells studied, L amino acids (1 mM) such as leucine, glutamine, tyrosine, and methionine reduced the cell-to-medium ratio of melphalan at 3 and 35 min. There was a good correlation between the reduction of melphalan transport at 35 min in the heterogeneous nucleated bone marrow cell population by amino acids and their effect on melphalan cytotoxicity in the CFU-C system. Aminoisobutyric acid (A1B), a specific substrate of the A system of amino acid transport, at a concentration between 1 and 50 mM had no significant effect on melphalan uptake at 3 min in any of the human cells studied except those of patient C. At 35 min A1B (10 or 50 mM) significantly reduced the intracellular melphalan concentration in normal bone marrow cells and tumor cells from patients B and C. At 2 mM, 2-aminobicyclo-(2, 2,1)-heptane-2-carboxylic acid (BCH), a specific substrate of the L system of amino acid transport, reduced the cell-to-medium ratio to 70% of control at 3 and 35 min in human bone marrow cells. In tumor cells from patients A, B, D, and F, 2 mM BCH had no significant effect on melphalan uptake at 3 min; it slightly decreased uptake in tumor cells from patient C. At 35 min, 2 mM BCH significantly reduced melphalan transport in tumor cells from patients C and F only. The lack of a BCH-suppressible component to melphalan uptake into human tumor cells freshly obtained from previously untreated patients contrasts with the presence of this component in murine L1210 leukemia cells, murine P388 leukemia cells, and human tumor cell lines. This suggests that minor differences in melphalan transport may exist amongst species and also between human tumor cells which are freshly obtained and cell lines maintained in culture.

Characterization of the metabolic forms of 6-thioguanine responsible for cytotoxicity and induction of differentiation of HL-60 acute promyelocytic leukemia cells

HL-60 human acute promyelocytic leukemia cells that lack hypoxanthine-guanine phosphoribosyltransferase (HGPRT) activity have been developed by mutagenization and selection. These cells exhibited markedly decreased sensitivity to the cytotoxic action of 6-thioguanine (TG) and, in contrast to parental HL-60 cells, had the capacity to undergo terminal granulocytic differentiation after treatment with this purine antimetabolite. Analysis of extracellular and intracellular metabolites of TG revealed negligible metabolism of TG in these HGPRT- HL-60 cells. These findings are consistent with the concept that inhibition of cellular replication requires generation of analog nucleotide and suggest that TG itself is capable of initiation of differentiation. 6-Thioguanosine (TGuo) had limited activity, while beta-2'-deoxythioguanosine (dTGuo) was inactive, as an inducer of maturation of HGPRT- HL-60 cells. These cells converted relatively large amounts of the nucleosides to the free base TG; the simultaneous exposure of cells to 8-aminoguanosine (AGuo), an inhibitor of purine nucleoside phosphorylase activity, decreased the degradation of TGuo and dTGuo to TG and promoted the intracellular accumulation of TG nucleotides, presumably through the action of nucleoside kinase activities. In a double mutant deficient in both HGPRT and deoxycytidine kinase (DCK) activities, dTGuo was devoid of cytotoxicity and was an effective inducer of maturation. The potency of dTGuo as an inducer in this system was not significantly affected by the presence of AGuo. These results suggested that dTGuo itself was also an active initiator of maturation. Thus, induction of differentiation appeared to be due to the free base, TG, as well as its deoxynucleoside form, dTGuo, whereas the formation of TG nucleotides appeared to antagonize maturation and produce cytotoxicity.

The oil-microcentrifuge assay: a rapid and sensitive method for analyzing specific [3H]estradiol binding in cultured cells

We have developed an oil- microcentrifuge assay system for analyzing the binding of [3H]estradiol in metabolically active MCF-7 and MDA human breast cancer cells. Complete separation of 2 X 10(6) cells from radioactive media can be achieved within 5 s of centrifugation at 12,000 rpm. The [3H]estradiol binding sites in MCF-7 cells are filled within 20 min of radioligand exposure. Using this assay, our MCF-7 cells contain approximately 15,000 high affinity and saturable binding sites. Binding is inhibited by estradiol and tamoxifen but not progesterone. There is no specific binding of [3H]estradiol in MDA cells. This assay is a rapid, sensitive and reproducible method for investigating hormone-receptor binding and ligand specificity in cultured cells; results compare favorably with those obtained by more complex and lengthy techniques.

Effects of metabolic deprivation on methotrexate transport in L1210 leukemia cells: further evidence for separate influx and efflux systems with different energetic requirements

Measurements of methotrexate transport in L1210 cells in the presence and absence of D-glucose reveal that both influx and efflux are depressed in the absence of D-glucose, whereas the steady-state accumulation of drug is enhanced. The reason for the increase in steady state is that the relative decline in efflux is greater than the decline in influx. Analysis of the concentration dependence of steady-state methotrexate accumulation in D-glucose-deprived cells indicates a linear relationship consistent with a one-carrier active transport model. Similar data in nondeprived cells is highly nonlinear and strongly supports the postulate that under physiological conditions influx and efflux of methotrexate are mediated by separate carrier systems. These results indicate that the efflux system, preferentially transporting methotrexate under normal conditions, cannot operate in the absence of D-glucose, whereas the influx system is only partially inhibited under conditions of glucose deprivation.

Kinetics of thymidine entry into tonsillar lymphocytes and its alteration in the presence of a lymphokine

Thymidine uptake into the acid soluble cell fraction of human tonsillar lymphocytes was studied in vitro. Uptake was linear for 15-20 minutes at low concentrations (less than 1.2 microM) of thymidine. The plot of uptake versus time could be extrapolated to the origin. Value for KM (0.5-0.6 microM) and values for Vmax were determined. In the presence of a lymphokine which inhibited thymidine incorporation into DNA the uptake of thymidine into the acid soluble cell fraction was also inhibited. The decreased uptake could be characterized by an increase in the apparent KM, without the alteration of Vmax. Lymphokines which inhibit thymidine incorporation may influence and regulate in vivo the entry of the exogenous thymidine into the cells.

Glycerol transport and phosphorylation by rat hepatocytes

The entry of glycerol into isolated rat hepatocytes appears to be catalyzed by a specific carrier. At a physiological concentration of 0.1 mM, glycerol utilization is rate limited by the permeation step. Intracellular glycerol is trapped by an excess of glycerol kinase, which has a higher apparent affinity for the substrate than that of the membrane carrier. The entry of glycerol into the hepatocytes is highly sensitive to inhibition by monoacetin and cytochalasin B, but not by DL-1,2-propanediol, erythritol, D-glucose, D-galactose, D-mannose, or D-fructose.

Multiple controls on the intracellular trapping of uridine

Uridine uptake by mouse or hamster cells grown in conditions which support good growth is very sensitive to inhibition by cyanide and azide, at concentrations which only slightly reduce overall cellular ATP levels. Iodoacetate, when present alone, reduces uridine uptake only insofar as it reduces cellular ATP levels. At concentrations which by themselves do not affect uridine uptake, iodoacetate greatly reduces the sensitivity of uridine uptake to cyanide or azide. The effect of cyanide is on intracellular trapping of uridine and not on its transport into the cell. The specific effect of cyanide is confined to uridine and not found for the uptake of adenine, thymidine or 2-deoxyglucose. The effect is of rapid onset (within 2 min) and is rapidly reversible (also within 2 min). Phosphorylation of uridine in homogenised cells or in Triton X-100-permeabilised cells is unaffected by cyanide. The data are interpreted in terms of a model in which intracellular trapping of uridine is subject to multiple controls, including one regulated by some factor requiring intact functioning of the mitochondrion. These multiple control systems interact synergistically to affect trapping of uridine by the intact cell.

The effect of alkylating agents and other drugs on the accumulation of melphalan by murine L1210 leukaemia cells in vitro

The effect of cytotoxic and other drugs on the accumulation of melphalan by L1210 murine leukaemia cells was studied. We have confirmed that uptake is an active process competitively inhibited by L-leucine. In 36 experiments in amino acid-free medium the mean concentration of melphalan taken up was 225 pmoles/10(6) cells. High pressure liquid chromatographic analysis showed that the majority of the drug is present as free native melphalan. 1,3-Bis(2-chloroethyl)-1-nitrosourea (BCNU) was the only drug that stimulated accumulation, but without significant effect on influx or efflux rates. Busulphan, chlorambucil, cyclophosphamide, interferon, methotrexate and prednisolone had no effect on accumulation after 30 min melphalan transport. Adriamycin, CCNU, methyl CCNU, mustine and vincristine all impaired melphalan accumulation as did the non-cytotoxic drugs aminophylline, chlorpromazine and ouabain. Adriamycin, aminophylline, chloropromazine, indomethacin and ouabain all reduced melphalan influx.

Caffeine-metabolizing capability of primary rat hepatocytes, Chinese hamster V79 cells and normal human fibroblasts in culture

Caffeine is metabolized by primary rat hepatocytes in culture to metabolites similar to those found in rats in vivo, including 6-amino-5-[N-formylmethylamino]-1,3-dimethyluracil, one of the major caffeine metabolites produced in the rat. At a substrate-limiting level of caffeine, the rat hepatocytes metabolized 25-30% of the total added caffeine in 24 h. About 99% of the metabolites was found in the extracellular medium and rinse fractions, suggesting that on a volume basis, caffeine metabolites are in equilibrium inside and outside the cells. No detectable caffeine metabolites were produced in preparations of either Chinese hamster V79 cells, or normal human fibroblasts at caffeine concentrations from 5 microM to 5 mM. These results suggest that the varied biological effects induced by caffeine in Chinese hamster cells cannot be attributed to caffeine metabolites and further that the differential responses of Chinese hamster cells and normal human fibroblasts to caffeine are not due to qualitative or quantitative differences in caffeine metabolism in the two cell lines.

Synthesis, retention, and biological activity of methotrexate polyglutamates in cultured human breast cancer cells

To determine the pharmacologic importance of methotrexate (MTX) polyglutamates, we examined the formation, retention, and effect of these metabolites in cultured human breast cancer cells. Two cell lines (MCF-7 and ZR-75-B) converted the drug to gamma-polyglutamate derivatives in a dose- and time-dependent reaction. After 24-h incubations with 2 muM MTX, polyglutamates of two to five amino acids in length accounted for 55.4% (51.9 nmol/g) of intracellular drug in the MCF-7 cells and 87.6% (62.4 nmol/g) of drug in ZR-75-B cells. In contrast, MDA-231 cells showed lesser accumulation of MTX, and only 32% (4.06 nmol/g) of the intracellular drug was in the form of polyglutamates, a difference that could only partially be explained by decreased ability of these cells to take up free drug from the medium. When MCF-7 and ZR-75-B cells containing polyglutamates were transferred to drug-free medium for 24 h, 22 and 51% of the total intracellular drug were, respectively, retained in each cell line. The loss of intracellular drug was primarily accounted for by disappearance of parent compound and polyglutamates containing 1-3 additional glutamyl residues. The rates of disappearance from cells decreased with increasing glutamyl chain length. All of the 4-NH(2)-10-CH(3)-PteGlu(5) and 47 and 38% of the 4-NH(2)-10-CH(3)-PteGlu(4) remained in the MCF-7 and ZR-75-B cells, respectively, and could be identified in the cytosol after 24 h in drug-free medium. The retention of MTX polyglutamates in these two cell lines in excess of dihydrofolate reductase binding capacity led to prolonged inhibition of thymidylate synthesis and loss of cell viability after removal of extracellular MTX. After 24-h incubation with 2 muM MTX and an additional 24 h in drug-free medium, [(3)H]deoxyuridine incorporation was still inhibited to 30% of control in the MCF-7 cells and 34.7% of control in ZR-75-B cells; this persistent inhibition was associated with a 30% reduction in cell numbers in each cell line during the 24-h period in drug-free medium. In contrast, [(3)H]deoxyuridine incorporation and cell growth quickly recovered to normal in the MDA-231 cells following removal of 2 muM MTX from the medium after a 24-h incubation. Prolonged inhibition of both thymidylate synthesis and cell growth was observed in this cell line in drug-free medium only after a 24-h incubation with 10 muM MTX, a condition that leads to the synthesis of 11.3 nmol/g of MTX polyglutamates. These studies demonstrate that polyglutamate formation allows a prolonged retention of drug in a noneffluxable form and prolonged inhibition of both thymidylate synthesis and cell growth following removal of extracellular drug.

Evaluation of Mg2+ as an intracellular regulator of uridine uptake

The rate of uptake of the nucleoside uridine increases within minutes after adding a growth stimulus to quiescent 3T3 cells. We have previously shown this uptake rate to be highly sensitive to changes in the intracellular concentration of Mg2+. In the present paper, the alteration of uptake by Mg2+ is shown to occur at the phosphorylation step - the same point at which serum acts to modulate uridine uptake. The serum stimulation of uridine uptake can be mimicked by Mg2+ alone or blocked by partially depleting cells of their Mg2+. Work with cell-free extracts shows that the uridine kinase enzyme responds to Mg2+ in a manner similar to that exhibited by whole cells whose concentrations of Mg2+ have been raised. In addition, the enzyme's inhibition by ATP is relieved by raising the Mg2+ concentration. Thymidine uptake, a reaction which does not respond quickly to mitogenic stimulation, is unaffected by alterations in Mg2+ concentration. These results are discussed in terms of a possible role for Mg2+ as an intracellular regulator of uridine uptake and other reactions of the coordinate response of cells to external effectors.

The hexose transport system in the human K-562 chronic myelogenous leukemia-derived cell

Kinetics of glucose transport in K-562 cells was studied using 3-O-methylglucose, a nonmetabolizable analog of glucose. A Km of 3.7 mM and Vmax of 32.0 nmoles/minute/10(6) cells was found for the process. D-Glucose, phloretin, and phlorizin competitively inhibit the transport of 3-O-methylglucose with Ki values of 4.1 mM, 4.1 muM and 225 muM, respectively, whereas L-glucose did not inhibit transport at all. The results indicate that K-562 cells, which are known to have erythropoietic characteristics, possess a glucose carrier system similar to the one in adult human erythrocytes. However, the Vmax data suggest that more copies of the carrier are present in the malignant cell, presumably to support the high rate of anaerobic glycolysis.

Effect of temperature on kinetics and symmetries of the hexose transporter of Novikoff rat hepatoma cells

We have used rapid kinetic techniques to measure the accumulation of radioactively labeled 3-O-methyl-D-glucose to transmembrane equilibrium in Novikoff cell suspensions as a function of temperature. Arrhenius plots of the maximum velocities of isotopic exchange and zero-trans entry were continuous between 6 and 39 degrees C (Ea = 15-19 kcal/mol). Equilibrium exchange and zero-trans entry of 3-O-methyl-glucose at six concentrations (1-30 mM) at 16, 27, and 35 degrees C conformed to appropriate integrated rate equations derived for a single transporter. The hexose transporter exhibited directional symmetry, but the loaded carrier moved about 2 times faster than the empty carrier at all three temperatures investigated. Thus, the differential mobilities of loaded and empty carrier are not affected by temperature in this range. The Michaelis--Menten constant for equilibrium exchange increased about 2-fold with increase in temperature between 16 and 35 degrees C.

Inhibition of cell division by interferons: Changes in the transport and intracellular metabolism of thymidine in human lymphoblastoid (Daudi) cells

The Daudi line of human lymphoblastoid cells shows a high sensitivity towards growth inhibition by human interferons. In cells pretreated with 70 reference units/ml of an interferon preparation for 48 h, the incorporation of exogenous [3H]thymidine into DNA is inhibited by as much as 85%. We are investigating the extent to which this effect reflects a true inhibition of the rate of DNA synthesis or whether it may be caused by changes in the metabolic utilization of exogenous thymidine by the cells. Interferon treatment results in a 30% inhibition of the rate of membrane transport and a 60% decrease in the rate of phosphorylation of [3H]thymidine in vivo. The latter effect is due to a decrease in V of thymidine kinase without any change in the value of Km for this enzyme. In addition to these changes, incorporation of [3H]uridine into DNA, which occurs as a result of the intracellular conversion of this precursor into thymidine nucleotides, is also inhibited by 75%, whereas RNA labelling by [3H]uridine is decreased by only 15% in interferon-treated cells. Thus several different metabolic events associated with thymidine nucleotide metabolism and DNA synthesis in Daudi cells are disrupted by interferon treatment.

Permeability of Novikoff hepatoma cells to water and monohydric alcohols

The permeability coefficients of Novikoff hepatoma ascites cell membranes for tritiated water (3HHO) and for a homologous series of monohydric alcohols (methanol through hexanol) were deduced from linear diffusion coefficients by means of a series-parallel pathway model (Redwood et al. (1974) J. Gen. Physiol. 64, 706-729). Membrane permeability coefficients for 3HHO at 20, 30 and 37 degrees C were (all x 10(-5)) 97, 125, and 163 cm . s-1, respectively, and were significantly smaller than the corresponding values for the alcohols tested. In the alcohols series, ethanol had the lowest permeability coefficient 198 x 10(-5) cm . s-1 at 20 degrees C. The apparent activation energy for water permeation was 6.7 +/- 1.9 S.E. kcal . mol-1. The apparent membrane diffusion coefficients for the alcohols were a complex function of molecular properties with less diffusional membrane resistance to the alcohols in the middle of the homologous series than would have been expected on the basis of oil-water partitioning or molar volume considerations. The conventional parallel aqueous lipophilic pathway model is not consistent with the present data which can be interpreted by consideration of parallel lipophilic pathways through the Novikoff hepatoma cell membrane.

Hexose transport in Novikoff rat hepatoma cells. A simple carrier with directional symmetry, but variable relative mobilities of loaded and empty carrier

The kinetics of transport of the non-metabolizable hexose, 3-O-methyl-D-glucose, have been measured in Novikoff rat hepatoma cells by both zero-trans entry and equilibrium exchange procedures. Transport conformed to a simple carrier model which operates symmetrically with respect to direction, but with greater mobility of the loaded than of the empty carrier. Although a complete kinetic description of the transporter can, in theory, be obtained by application of integrated equations describing the time course of substrate equilibrium across the membrane beginning from the zero-trans situation, statistical analysis of hypothetical data indicated that directional asymmetry or differential mobilities of loaded and empty carrier cannot be discerned reliably from such data alone. The difference in mobility of loaded and empty carrier, apparent in a comparison of zero-trans entry and exchange data, ranged from 1.5--7-fold in different batches of cells. It is concluded that the magnitude of the difference is not an inherent property of the transporter, but is determined physiologically, and may be involved in regulation of hexose transport.

Facilitated transport of inosine and uridine in cultured mammalian cells is independent of nucleoside phosphorylases

The zero-trans uptake of uniformly and base-labeled inosine and uridine was measured a 25 degrees C in suspensions of Novikoff rat hepatoma cells, Chinese hamster ovary cells, mouse L cells, mouse S49 lymphoma cells and a purine-nucleoside phosphorylase-deficient subline thereof (NSU-1), and in monolayer culture of mouse 3T3 and L cells. The initial velocities of uptake of both nucleosides were about the same in all cell lines investigated, regardless of the position of the label or of the substrate concentration between 3 and 300 microM or whether or not the cells possessed uridine or purine-nucleoside phosphorylase activity. The kinetic parameters for the facilitated transport of uridine and inosine were also similar in phosphorylase positive and negative cell lines (K = 120--260 microM and V = 6--40 pmol/microliters cell water per s) and the transport activities of the cells exceeded their total phosphorylase activities by at least 10-fold for uridine and 1--2-fold for inosine. Chromatographic fractionation of the intracellular contents and of the culture fluid showed that the free nucleosides appeared intracellularly prior to and more rapidly than their phosphorolysis products. During the initial 20--60 s of uptake of U-14C-labeled nucleosides the rates of intracellular appearance of ribose-1-P and base were about the same. After several minutes of incubation, on the other hand, the main intracellular component was ribose-1-P whereas the base attained a low intracellular steady-state concentration and accumulated in the medium due to exit transport. Other nucleosides, dipyridamole and nitrobenzylthioinosine, specifically inhibited the transport of uridine and inosine, and depressed the intracellular accumulation of ribose-1-P and the formation of base commensurate with that inhibition. The data indicate that the metabolism of inosine and uridine by the various cell lines can be entirely accounted for by the facilitated transport of unmodified nucleoside into the cell followed by intracellular phosphorolysis.

Permeation of Chinese hamster ovary cells by glycerol: mechanism and kinetics

When monolayer cultures of Chinese hamster ovary cells were exposed to 3H-glycerol ranging in concentration from 0.1 microM to 200 mM, glycerol in flux was found to increase in direct proportion to the extracellular concentration of glycerol. Other experiments indicated that the same relationship existed at concentrations in excess of 1.0 M. Similarly, glycerol efflux was found to vary in direct proportion to the intracellular concentration of glycerol. In neither case could influx or efflux be saturated. Glycerol influx was not affected by depletion of ATP, alkylation by parachloromercuribenzene sulfonic acid, or exposure to persantine. Altering the pH or temperature also had little effect. Attempts at demonstrating countertransport of glycerol were negative. These data indicate that glycerol probably passes through the membrane by a non-mediated process. For cells in monolayer, the kinetics of influx and efflux are biphasic. Similar biphasic kinetics are observed with cells in suspension culture. A close fit to the data may be obtained by adding together two first-order curves. The pair of curves for influx are clearly different from the pair for efflux. The fit provided by the two pairs of first-order functions suggested that glycerol might diffuse into and out of two intracellular compartments. However, the experimental data do not agree with the predicted behavior of a two-compartment system. As a result, the exact nature of the diffusion limiting steps which are described by the first-order equations remains undefined.

Lack of correlation between effects of tumor promoter TPA on plasminogen activator production, phosphatidyl choline synthesis, and hexose transport in mammalian cell culture systems

We have investigated the effects of the tumor promoter 12-0-tetradecanoyl-phorbol-13-acetate (TPA) on plasminogen activator production, hexose transport and metabolism, and the incorporation of choline into the acid soluble pool and into phosphatidylcholine in suspension cultures of mouse L, mouse P388 leukemia, human HeLa, and Chinese hamster ovary cells, and in monolayer cultures of baby hamster kidney (BHK), mouse 3T3, mouse 3T6, and mouse P388D1 macrophage-like cells. BHK, 3T3, P388D1, and P388 cells produced plasminogen activator constitutively, but no significant production was observed in the other cell lines. Plasminogen activator production was induced or stimulated by TPA only in P388 cells (10- to 20-fold by 100 ng TPA/ml). On the other hand, phosphatidylcholine synthesis was stimulated by TPA only in HeLa cells, and hexose transport, as measured with 3-0-methyl-D-glucose, only in 3T3 and P388D1 cells, as well as in human lymphocytes. The stimulation of hexose transport occurred more rapidly than the induction of plasminogen activator production and seemed to be part of the mitogenic response of cells to TPA treatment. A stimulation of deoxyglucose uptake was similarly limited to 3T3 and P388D1 cells. A significant decarboxylation of carbon 1 of deoxyglucose occurred in P388 and P388D1 cells, but not in Novikoff cells, and any decarboxylation that occurred was not stimulated by TPA. The results indicate that the various investigated responses of cells to TPA are unrelated and occur independent of each other. The time courses of the biochemical responses also differ significantly.

Adenosine transport by a variant of C1300 murine neuroblastoma cells deficient in adenosine kinase

The uptake of adenosine by an adenosine kinase deficient variant of C1300 murine neuroblastoma cells has been studied in the absence and in the presence of erythro-9-(2-hydroxy-3-nonyl)adenine, a potent adenine deaminase inhibitor. Although 100 micro M inhibitor completely blocks the metabolism of adenosine under the conditions studied, the uptake of adenosine is concentrative, i.e., the intracellular adenosine concentration exceeds the extracellular concentration. This concentrative effect decreases as the concentration of adenosine increases and is hypothesized to be due to the binding of adenosine to an intracellular component. Despite this concentrative effect, we believe that the kinetics of uptake, as determined in experiments with short (10-20 s) uptake periods, reflect the kinetics of adenosine transport by a facilitated diffusion process. This nucleoside transport system appears to be nonspecific in that the transport of adenosine is competitively antagonized by thymidine. It does not appear to be necessary to inhibit adenosine deaminase in order to study transport in these cells as the Km for transport is not affected by the presence of erythro-9-(2-hydroxy-3-nonyl)adenine. However, erythro-9-(2-hydroxy-3-nonyl)adenine does depress the V for transport. This effect of the inhibitor is probably not due to the inhibition of adenosine deaminase as the transport of thymidine is similarly affected.