Uridine transport in Novikoff rat hepatoma cells and other cell lines and its relationship to uridine phosphorylation and phosphorolysis.

Time courses of [³H]uridine uptake as a function of uridine concentration were determined at 25° in untreated and ATP-depleted wild-type and uridine kinase-deficient Novikoff cells and in mouse L and P388 cells, Chinese hamster ovary cells and human HeLa cells. Short term uptake was measured by a rapid sampling technique which allows sampling of cell suspensions in intervals as short as one and one-half seconds. The initial segments of the time courses were the same in untreated, wild-type cells in which uridine is rapidly phosphorylated and in cells in which uridine phosphorylation was prevented due to lack of ATP or uridine kinase. The initial rates of uptake, therefore, reflected the rate of uridine transport. Uridine uptake, however, was approximately linear for only five to ten seconds at uridine concentrations from 20–160 μM and somewhat longer at higher concentrations. In phosphorylating cells the rate of uridine uptake (at 80 μM) then decreased to about 20–30% of the initial rate and this rate was largely determined by the rate of phosphorylation rather than transport. At uridine concentrations below 1 μM, however, the rate of intracellular phosphorylation in Novikoff cells approached the transport rate. The apparent substrate saturation of phosphorylation suggests the presence of a low K_m uridine phosphorylation system in these cells. The “zero-trans” (zt) K_m for the facilitated transport of uridine as estimated from initial uptake rates fell between 50 and 240 μM for all cell lines examined. The zero-trans V_max values were also similar for all the lines (4–15 pmoles/μ1 cell H₂O.sec). The time courses of uridine uptake by CHO cells and the kinetic constants for transport were about the same whether the cells were propagated (and analyzed for uridine uptake) in suspension or monolayer culture. When Novikoff cells were preloaded with 10 μM uridine the apparent K_m and V_max values (infinite-trans) were two to three times higher than the corresponding zero-trans values. Uridine transport was inhibited in a simple competitive manner by several other ribo- and deoxyribonucleosides. All nucleosides seem to be transported by the same system, but with different efficiencies. Uridine transport was also inhibited by hypoxanthine, adenine, thymine, Persantin, papaverin, and o-nitrobenzylthioinosine, and by pretreatment of the cells with p-chloromercuri-benzoate, but not by high concentrations of cytosine, D-ribose or acronycin. The inhibition of uridine transport by Persantin involved changes in both V and K. Because of the rapidity of transport, some loss of intracellular uridine occurred when cells were rinsed in buffer solution to remove extracellular substrate, even at 0°. This loss was prevented by the presence of a transport inhibitor, Persantin, in the rinse fluid or by separating suspended cells from the medium by centrifugation through oil. Metabolic conversion of intracellular uridine were also found to continue during the rinse period. The extent of artifacts due to efflux and metabolism during rinsing increased with duration of the rinse.     

Nucleoside transport in cultured mammalian cells multiple forms with different sensitivity to inhibition by nitrobenzylthioinosine or hypoxanthine

The zero-trans influx of 500 μM uridine by CHO, P388, L1210 and L929 cells was inhibited by nitrobenzylthioinosine (NBTI) in a biphasic manner; 60–70% of total uridine influx by CHO cells and about 90% of that in P388, L1210 and L929 cells was inhibited by nmolar concentrations of NBTI (ID₅₀ = 3?10 nM) and is designated NBTI-sensitive transport. The residual transport activity, designated NBTI-resistant transport, was inhibited by NBTI only at concentrations above 1 μM (ID₅₀ = 10?50 μM). S49 cells exhibited only NBTI-sensitive uridine transport, whereas Novikoff cells exhibited only NBTI-resistant uridine transport. In all instances NBTI-sensitive transport correlated with the presence of between 7·10⁴ and 7·10⁵ high-affinity NBTI binding sites/cell (K_d = 0.3?1 nM). Novikoff cells lacked such sites. The two types of nucleoside transport, NBTI-resistant and NBTI-sensitive, were indistinguishable in substrate affinity, temperature dependence, substrate specificity, inhibition by structurally unrelated substances, such as dipyridamole or papaverine, and inhibition by sulfhydryl reagents or hypoxanthine. We suggest, therefore, that a single nucleoside transporter can exist in an NBTI-sensitive and an NBTI-resistant form depending on its disposition in the plasma membrane. The sensitive form expresses a high-affinity NBTI binding site(s) which is probably made up of the substrate binding site plus a hydrophobic region which interacts with the lipophilic nitrobenzyl group of NBTI. The latter site seems to be unavailable in NBTI-resistant transporters. The proportion of NBTI-resistant and sensitive uridine transport was constant during proportion of NBTI-resistant and sensitive uridine transport was constant during progression of P388 cells through the cell cycle and independent of the growth stage of the cells in culture. There were additional differences in uridine transport between cell lines which, however, did not correlate with NBTI sensitivity and might be related to the species origin of the cells. Uridine transport in Novikoff cells was more sensitive to inhibition by dipyridamole and papaverine than that in all other cell lines tested, whereas uridine transport in CHO cells was the most sensitive to inactivation by sulfhydryl reagents.     

Uridine transport in basolateral plasma membrane vesicles from rat liver

Summary The characteristics of uridine transport were studied in basolateral plasma membrane vesicles isolated from rat liver. Uridine was not metabolized under transport measurement conditions and was taken up into an osmotically active space with no significant binding of uridine to the membrane vesicles. Uridine uptake was sodium dependent, showing no significant stimulation by other monovalent cations. Kinetic analysis of the sodium-dependent component showed a single system with Michaelis-Menten kinetics. Parameter values were K _M 8.9 m and V _max 0.57 pmol/mg prot/sec. Uridine transport proved to be electrogenic, since, firstly, the Hill plot of the kinetic data suggested a 1 uridine: 1 Na⁺ stoichiometry, secondly, valinomycin enhanced basal uridine uptake rates and, thirdly, the permeant nature of the Na⁺ counterions determined uridine transport rates (SCN^– > NO ₃ ^– > Cl^– > SO ₄ ^2– ). Other purines and pyrimidines cis-inhibited and trans-stimulated uridine uptake.This work has been partially supported by grant PM90-0162 from D.G.I.C.Y.T. (Ministerio de Educación y Ciencia, Spain). B.R.-M. is a research fellow supported by the Nestlé Nutrition Research Grant Programme.     

Uridine uptake and its intracellular phosphorylation during the cell cycle

The rate of 5-³H uridine uptake into Chinese hamster V79 cells and the rate of its incorporation into RNA increase tenfold during the cell cycle. Both reactions exhibit the same apparent K_m(1.7 × 10^?5 M ). Chromatography of acid-soluble material from cells incubated with 5-³H uridine (0.25 μM) at different times of the cell cycle revealed that intracellular uridine was rapidly phosphorylated at all times, even though cells in late S and G₂ take up roughly ten times as much uridine as cells in G₁. Uridine kinase activity in synchronized cells increases about two and one-half-fold during the same time period, and in exponentially growing cells is not saturated until the external uridine concentration is raised above 200 μM. It is concluded that the change in uridine kinase activity during the cell cycle is not responsible for the tenfold increase in the rate of uridine transport, and that these two processes are independently regulated.     

Independent blood-brain barrier transport systems for nucleic acid precursors

The blood-brain barrier permeability to certain ¹⁴C-labelled purine and pyrimidine compounds was studied by simultaneous injection in conjunction with two reference isotopes into the rat common carotid artery and decapitation 15 s later. The amount of ¹⁴C-labelled base or nucleoside remaining in brain was expressed in relation to ³H₂O (a highly diffusible internal standard) and ^113mIn-labelled EDTA (an essentially non-diffusible internal standard).Of the 17 compounds tested, measurable, saturable uptakes were established for adenine, adenosine, guanosine, inosine and uridine.Two independent transport systems in the rat blood-brain barrier were defined. One transported adenine (K_m = 0.027 mM) and could be inhibited with hypoxanthine. Adenosine (K_m = 0.018 mM), guanosine, inosine and uridine all cross-inhibit, defining a second independent nucleoside carrier system. Adenosine inhibited [¹⁴C]uridine uptake more effectively than did uridine, suggesting a weaker affinity of uridine for this nucleoside carrier.     

Uridine transport by mouse blastocysts

Transport of uridine by mouse early blastocysts is a saturable process. Kinetic studies of uptake by the blastocysts reveal an apparent K_m of 1.6 μM and V_max of 0.0063 pmole/min/embryo at 37°C. Uridine uptake is reduced when thymidine, adenosine, deoxyuridine, cytidine, or deoxyadenosine is added to the medium. These findings suggest that transport of these compounds may occur at the same or overlapping sites in the cell membrane. Inhibition of transport by dinitrophenol and KCN suggests a coupling of transport to phosphorylation and energy metabolism, probably through the phosphorylation of uridine to form UTP, the principal intracellular metabolite of uridine. However, since phosphorylation of uridine is not measurable separately from the transport process in the intact embryo, it has not been determined whether uridine uptake by the embryos occurs by facilitated diffusion or by active transport.     

Some kinetic studies on ribonucleosides degradation by extracts of penicillium citrinum

Cell-free extracts of 3–4 days old mats of nitrate-grown Penicillium citrinum catalyze the hydrolytic cleavage of the N-glycosidic bonds of inosine, guanosine and adenosine optimally at pH 4, 0.1 M citrate buffer. The same extracts catalyze the hydrolytic deamination of cytidine at a maximum rate in 0.08 M Tris-acetate buffer pH 6.5, 40°C and 50°C were the most suitable degrees for purine nucleoside hydrolysis and cytidine deamination, respectively. The incubation of the extracts at 60°C, in the absence of cytidine caused a loss in the deaminating activity, while freezing and thawing had no effect on both activities. The deaminating activity seems to be cytidine specific as neither cytosine, adenine, adenosine nor guanosine could be deaminated. Uridine competively inhibited this activity, while ammonia had no effect. The apparent K_m value of this enzyme for cytidine was 1.57×10^?3M and its K_i value for uridine was 7.8×10^?3M. The apparent K_m values of the N-glycosidic bond cleaving enzyme for inosine, guanosine and adenosine were 13.3, 14.2 and 20×10^?3 M, respectively.     

The uptake and metabolism of uridine by the slime mould Physarum polycephalum.

1. Uridine is taken up by microplasmodia of Physarum polycephalum via a saturatable transport system with an apparent Km of 29 muM. An intracellular concentration significantly higher than that in the growth medium is attained, suggesting that the uptake is an active process. Both deoxyribonucleosides and ribonucleosides are competitive inhibitors of the uptake of uridine. 2. In contrast, the rate of entry of uridine into surface plasmodia is a linear function of the concentration of the nucleoside in the growth medium, and the uptake is not inhibited by other nucleosides. 3. As well as serving as a source of pyrimidine nucleotides for the synthesis of nucleic acids, uridine is also catabolised by P. polycephalum. Uracil accumulates in the growth medium and there is also significant conversion of C-2 of the pyrimidine ring to CO2. The proportion of uridine subject to catabolism in surface plasmodia is less than that observed for microplasmodia.     

Sodium-dependent nucleoside transport in choroid plexus from rabbit. Evidence for a single transporter for purine and pyrimidine nucleosides.

The overall goal of this study was to determine the mechanisms by which nucleosides are transported in choroid plexus. Choroid plexus tissue slices obtained from rabbit brain were depleted of ATP with 2,4-dinitrophenol. Uridine and thymidine accumulated in the slices against a concentration gradient in the presence of an inwardly directed Na+ gradient. The Na(+)-driven uptake of uridine and thymidine was saturable with Km values of 18.1 +/- 2.0 and 13.0 +/- 2.3 microM and Vmax values of 5.5 +/- 0.3 and 1.0 +/- 0.2 nmol/g/s, respectively. Na(+)-driven uridine uptake was inhibited by naturally occurring ribo- and deoxyribonucleosides (adenosine, cytidine, and thymidine) but not by synthetic nucleoside analogs (dideoxyadenosine, dideoxycytidine, cytidine arabinoside, and 3'-azidothymidine). Both purine (guanosine, inosine, formycin B) and pyrimidine nucleosides (uridine and cytidine) were potent inhibitors of Na(+)-thymidine transport with IC50 values ranging between 5 and 23 microM. Formycin B competitively inhibited Na(+)-thymidine uptake and thymidine trans-stimulated formycin B uptake. These data suggest that both purine and pyrimidine nucleosides are substrates of the same system. The stoichiometric coupling ratios between Na+ and the nucleosides, guanosine, uridine, and thymidine, were 1.87 +/- 0.10, 1.99 +/- 0.35, and 2.07 +/- 0.09, respectively. The system differs from Na(+)-nucleoside co-transport systems in other tissues which are generally selective for either purine or pyrimidine nucleosides and which have stoichiometric ratios of 1. This study represents the first direct demonstration of a unique Na(+)-nucleoside co-transport system in choroid plexus.     

Adenosine Release and Uptake in Cerebellar Granule Neurons Both Occur via an Equilibrative Nucleoside Carrier that Is Modulated by G Proteins

Abstract: There is debate about the mechanisms mediating adenosine release from neurons. In this study, the release of adenosine evoked by depolarizing cultured cerebellar granule neurons with 50 mM K⁺ was inhibited by 49 ± 7% in Ca²⁺-free medium. The remaining release was blocked by dipyridamole (IC₅₀ = 6.4 × 10^?8M) and nitrobenzylthioinosine (IC₅₀ = 3.6 × 10^?8M), inhibitors of adenosine uptake. Ca²⁺-dependent release was reduced by 78 ± 9% following a 21-h pretreatment of the cells with pertussis toxin, which ADP-ribosylates G_i/G_o G proteins, thereby preventing their dissociation. The nucleoside transporter-mediated component of K⁺-induced adenosine release also was inhibited by 62 ± 8% by pertussis toxin and was potentiated by 78 ± 11% following cholera toxin treatment, which permanently activates G_s. Uptake of [³H]adenosine into cultured cerebellar granule neurons over a 10-min period was not dependent on extracellular Na⁺ but was reduced by dipyridamole (IC₅₀ = 3.2 × 10^?8M) and nitrobenzylthioinosine (IC₅₀ = 2.6 × 10^?8M). Thus, adenosine uptake likely occurs via the same transporter mediating Ca²⁺-independent adenosine release. Adenosine uptake was potentiated by cholera toxin pretreatment (152 ± 15% of control), but pertussis toxin had no statistically significant effect. It is possible that G_s, G_i/G_o, or free Gβγ dimer modulate the equilibrative, inhibitor-sensitive nucleoside carrier to enhance adenosine transport.     

Nucleotide pools of Novikoff rat hepatoma cells growing in suspension culture. IV. Nucleoside transport in cells depleted of nucleotides by treatment with KCN

Incubation of Novikoff rat hepatoma cells in glucose-free basal medium containing 2 mM KCN results in a rapid and almost complete loss of uracil and adenine nucleotides. By following the fate of radioactivity from ³H-nucleoside pulse-labeled cells during incubation with KCN it was shown that the nucleotides are degraded to nucleosides and bases which are released into the culture fluid. Depletion of the cells of nucleotides by incubation with KCN allows a direct analysis of the kinetics of uridine transport into the cell, since KCN-treated cells fail to phosphorylate uridine. Uridine uptake follows normal Michaelis-Menten kinetics with an apparent K_n of about 50 μm at 18°C. Uptake is by facilitated diffusion since it does not require energy and uridine is not transported against a concentration gradient. The effects of KCN are largely prevented by the presence of 10 mM glucose in the medium. They are also rapidly reversed by resuspending the cells in fresh medium without KCN. Upon removal of KCN, the cells rapidly regenerate their nucleotide pools and resume growth at the normal rate.     

Nucleoside transport in rat erythrocytes: two components with differences in sensitivity to inhibition by nitrobenzylthioinosine andp-chloromercuriphenyl sulfonate

Summary The sensitivity of nucleoside transport by rat erythrocytes to inhibition by nitrobenzylthioinosine (NBMPR) and the slowly permeating organomercurial,p-chloromercuriphenyl sulfonate (pCMBS), was investigated. The dose response curve for the inhibition of uridine transport (100 M) by NBMPR was biphasic –35% of the transport activity was inhibited with an IC₅₀ value of 0.25 nM, but 65% of the activity remained insensitive to concentrations as high as 1 M. These two components of uridine transport are defined as NBMPR-sensitive and NBMPR-insensitive, respectively. Uridine influx by both components was saturable and conformed to simple Michaelis-Menten kinetics, and was inhibited by other nucleosides. The uridine affinity of the NBMPR-sensitive transport component was threefold higher than for the NBMPR-insensitive transport mechanism (apparentK _m for uridine 50±18 and 163±28 M, respectively). The two transport systems also differed in their sensitivity topCMBS. NBMPR-insensitive uridine transport was inhibited bypCMBS with an IC₅₀ of 25M, while 1 mMpCMBS had little effect on NBMPR-sensitive transport by intact cells.pCMBS inhibition was reduced in the presence of uridine and adenosine and reversed by the addition by -mercaptoethanol, suggesting that thepCMBS-sensitive thiol group is located on the exterior surface of the erythrocyte membrane within the nucleoside binding site of the transport system. Inhibition of uridine transport by NBMPR was associated with high-affinity [³H]NBMPR binding to the cell membrane (apparentK _d46±25 pM). Binding of inhibitor to these sites was competitively blocked by uridine and inhibited by adenosine, thymidine, dipyridamole, dilazep and nitrobenzylthioguanosine. Assuming that each NBMPR-sensitive transport site binds a single molecule of NBMPR, the calculated translocation capacity of each site is 25±6 molecules/site per sec at 22°C.pCMBS had no effect on [³H]NBMPR binding to intact cells but markedly inhibited binding to disrupted membranes indicating that the NBMPR-sensitive nucleoside transporter probably has a thiol group located on the inner surface of the membrane. Exposure of rat erythrocyte membranes to UV light in the presence of [³H]NBMPR resulted in covalent radiolabeling of a membrane protein(s) (apparent M_r on SDS gel electropherograms of 62,000). Labeling of this protein was abolished in the presence of nitrobenzylthioguanosine. We conclude that nucleoside transport by rat erythrocytes occurs by two facilitated-diffusion systems which differ in their sensitivity to inhibition by both NBMPR andpCMBS.     

Characterization of equilibrative and concentrative Na+-dependent (cif) nucleoside transport in acute promyelocytic leukemia NB4 cells

Nucleoside transport processes can be classified by the transport mechanism, e = equilibrative and c = concentrative, by the sensitivity to inhibition by nitrobenzylthioinosine (NBMPR), s = sensitive and i = insensitive, and also by permeant selectivity. To characterize nucleoside transport in acute promyelocytic NB4 cells, nucleoside transport was resolved into different components by selective elimination of transport processes with NBMPR and with Na⁺-deficient media. Initial transport rates were estimated from time course experiments. For adenosine, uridine, and formycin B, equilibrative transport accounted for approximately 60% of their uptake, with ei and es transport contributing almost equally, and Na⁺-dependent transport accounting for the remaining 40% of the total uptake. Thymidine uptake was mediated exclusively by equilibrative systems with ei and es systems each contributing 50% to total uptake. Adenosine accumulated above equilibrative concentrations, suggesting that a concentrative transport process was active and/or that metabolism led to adenosine's accumulation. Formycin B, a nonmetabolizable analog, also accumulated in the cells, supporting the concentrative potential of the Na⁺-dependent transporter. Kinetic analyses also provided evidence for three distinct high affinity transport mechanisms. NBMPR binding assays indicated the presence of two high affinity (K_m 0.10 and 0.35 nM) binding sites. In conclusion, NB4 cells express ei and es transport, as well as a large ci transport component, which appears to correspond to cif (f = formycin B or purine selective) nucleoside transport, not previously described in human cells. © 1996 Wiley-Liss, Inc.     

Plant adenosine kinase: purification and some properties of the enzyme from Lupinus luteus seeds.

Adenosine kinase (ATP:adenosine 5′-phosphotransferase, EC 2.7.1.20) from Lupinus luteus seeds has been obtained with good yield in almost homogeneous state by ammonium sulfate fractionation, chromatography on aminohexyl-Sepharose, and gel filtration. Active enzyme is a single polypeptide chain with a molecular weight of about 38,000 as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and gel nitration. Estimated molecular activity is 156. The enzyme exhibits a strict requirement for divalent metal ions. Among several ions tested the following appeared to be active as cofactors: Co²⁺ ? Mn²⁺ > Mg²⁺ = Ca²⁺ ? Ni²⁺ > Ba²⁺. The optimal metal ion concentrations were as follows: Mn²⁺, 0.5 mm, Mg²⁺ and Ca²⁺, 1 mm, Co²⁺, 1.5 mm. The adenosine kinase shows optimum activity at pH 7.0–7.5. K_m values for adenosine and ATP are 1.5 × 10^?6 and 3 × 10^?4m, respectively. Lupin adenosine kinase is completely inhibited by antisulfhydryl reagents. ATP is the main phosphate donor and among other nucleoside triphosphates ITP, dATP, GTP, and XTP can substitute it but less effectively. Among the ribo- and deoxyribonucleosides occurring in nucleic acids adenosine is phosphorylated effectively and 2′-deoxyadenosine at a lower rate. Of other adenosine analogs tested all adenine d-nucleosides and purine derivative ribosides, besides those with a hydroxyl group at C-6, were found to be substrates for lupin adenosine kinase. Pyrimidine ribo- and deoxyribonucleosides were not phosphorylated.     

Kinetics of uridine uptake and incorporation into RNA in tobacco pollen culture

The capacity of pollen tubes to utilize exogenous uridine during 8 h of cultivation in shaken suspension in a sugar-mineral medium was examined by continuous and pulse labelling with³H-uridine. The increase of uptake with increasing concentration of the nucleoside indicated a saturable transport system with an approximate K_m of 9.4 × 10⁻⁶ M and 12.5 × 10⁻⁶M as determined in 1-h and 6-h cultures, respectively. Maximal uptake took place at the beginning of germination reaching a rate of about 2 nmol h⁻¹ per 1 mg of dry pollen at 0.1 mM external uridine. The uptake activity decreased with the time of pollen tube growth to less than one third during the 8-h cultivation period. Moreover, the level of radioactivity taken up initially decreased later on during continuous cultivation in the presence of³H-uridine. The uptake took place against a concentration difference and the onset and rate of uridine release depended on its exogenous concentration. The activity of the nucleoside incorporation into RNA increased during the first 4 h of cultivation, decreasing later on. The proportion of RNA radioactivity in continuously labelled pollen tubes grew steadily during 6 h and reached 2.5% with respect to soluble pool at 0.4 μM uridine. The time course of RNA labelling was independent of uridine concentration within the range of 0.4 μM to 40 μM but this concentration rise resulted in an about fiftyfold increase of the total amount of external uridine incorporated.     

Nucleoside transporter proteins of Saccharomyces cerevisiae. Demonstration of a transporter (FUI1) with high uridine selectivity in plasma membranes and a transporter (FUN26) with broad nucleoside selectivity in intracellular membranes

FUI1 and function unknown now 26 (FUN26) are proteins of uncertain function with sequence similarities to members of the uracil/allantoin permease and equilibrative nucleoside transporter families of transporter proteins, respectively. [(3)H]Uridine influx was eliminated by disruption of the gene encoding FUI1 (fui1) and restored by expression of FUI1 cDNA, whereas influx in transport-competent and fui1-negative yeast were unaffected, respectively, by disruption of the FUN26 gene or overexpression of FUN26 cDNA. FUI1 transported uridine with high affinity (K(m), 22 +/- 3 micrometer) and was unaffected or inhibited only partially by high concentrations (1 mm) of a variety of ribo- and deoxyribonucleosides or nucleobases. When FUN26 cDNA was expressed in oocytes of Xenopus laevis, inward fluxes of [(3)H]uridine, [(3)H]adenosine, and [(3)H]cytidine were stimulated, and uridine influx was independent of pH and not inhibited by dilazep, dipyridamole, or nitrobenzylmercaptopurine ribonucleoside. Fractionation of yeast membranes containing immunotagged recombinant FUN26 (shown to be functional in oocytes) demonstrated that the protein was primarily in intracellular membranes. These results indicated that FUI1 has high selectivity for uracil-containing ribonucleosides and imports uridine across cell-surface membranes, whereas FUN26 has broad nucleoside selectivity and most likely functions to transport nucleosides across intracellular membranes.     

Nucleoside transport in Walker 256 rat carcinosarcoma and S49 mouse lymphoma cells. Differences in sensitivity to nitrobenzylthioinosine and thiol reagents.

The characteristics of nucleoside transport were examined in Walker 256 rat carcinosarcoma and S49 mouse lymphoma cells. In Walker 256 cells the initial rates of uridine, thymidine and adenosine uptake were insensitive to the nucleoside transport inhibitor nitrobenzylthioinosine (NBMPR) (1 microM), but were partially inhibited by dipyridamole (10 microM), another inhibitor of nucleoside transport. In contrast, the transport of these nucleosides in S49 cells was completely blocked by both inhibitors. Nucleoside transport in Walker 256 and S49 cells also differed in its sensitivity to the thiol reagent p-chloromercuribenzenesulphonate (pCMBS). Uridine transport in Walker 256 cells was inhibited by pCMBS with an IC50 (concentration producing 50% inhibition) of less than 25 microM, and inhibition was readily reversed by beta-mercaptoethanol. In S49 cells uridine transport was only inhibited at much higher concentrations of pCMBS (IC50 approximately equal to 300 microM). In other respects nucleoside transport in Walker 256 and S49 cells were quite similar. The Km and Vmax. values for uridine transport were nearly identical, and the transporters of both cell lines appeared to accept a broad range of nucleosides as substrates. Uridine transport in Walker 256 cells was non-concentrative and did not require an energy source. These studies demonstrate that nucleoside uptake in Walker 256 cells is mediated by a facilitated-diffusion mechanism which differs markedly from that of S49 cells in its sensitivity to the transport inhibitor NBMPR and the thiol reagent pCMBS.     

CARRIER MEDIATED BLOOD-BRAIN BARRIER TRANSPORT OF CHOLINE AND CERTAIN CHOLINE ANALOGS

Blood-brain barrier (BBB) transport of choline and certain choline analogs was studied in adult and suckling rats, and additionally compared in the paleocortex and neocortex of adult rats. Saturable uptake was characterized by a single kinetic system in all cases examined, and in adult rat forebrains we determined a K_m= 442 ± 60 μM and V_max= 10.0 ± 0.6 nmol min^-1 g^-1. In 14–15-day-old suckling forebrains a similar K_m (= 404 ± 88 μM) but higher V_max (= 12.5 ± 1.5 nmol min^-1 g^-1) was determined. When choline uptake was compared in two regions of the forebrain, similar Michaelis-Menten constants were determined but a higher uptake velocity was found in the neocortex (i.e. neocortex K_m= 310 ± 103 μM and V_max= 12.6 ± 2.8 nmol min^-1g^-1; paleocortex K_m= 217 ± 76 μM and V_max= 7.2 ± 1.5 nmol min^-1 g^-1). Administration of radiolabelled choline at low (5 μM) and high (100 μM) concentrations, followed by microwave fixation 60 s later and chloroform-methanol-water separations of the homogenized brain did not suggest a relationship between concentration and the appearance of label in lipid or aqueous fractions as observed in another in-vitro study elaborating two-component kinetics of choline uptake. It was observed that 60s after carotid injection 12–14% of the radiolabel in the ipsilateral cortex was found in the chloroform-soluble fraction. Hemicholinium-3 (K_i= 111 μM), dimethylaminoethanol (K_i= 42 μM), tetraethyl ammonium chloride, tetramethyl ammonium chloride, 2-hydroxyethyl triethylammonium iodide, carnitine, normal rat serum, and to a lesser extent lithium and spermidine all inhibited choline uptake in the BBB. Unsubstituted ammonium chloride and imipramine did not inhibit choline uptake. No difference was observed in blood-brain barrier choline uptake of unanesthetised, carotid artery-catheterized animals, and comparable sodium pentobarbital-anesthetized controls.     

Competitive substrate inhibition of amyloglucosidase from Rhizopus sp. by vanillin and curcumin

Kinetic studies of two glucosylation reactions catalyzed by an amyloglucosidase from Rhizopus sp. leading to the synthesis of vanillin-α/β-D-glucoside from D-glucose and vanillin and curcumin-bis-α-D-glucoside from D-glucose and curcumin were investigated in detail. Initial reaction rates were determined from kinetic runs involving different concentrations of D-glucose and vanillin (5?mM to 0.1?M) or D-glucose and curcumin (5?mM to 0.1?M). Graphical double reciprocal plots showed that the kinetics of the two enzyme catalyzed reactions exhibited Ping-Pong Bi-Bi mechanism where competitive substrate inhibition by vanillin/curcumin led to dead-end amyloglucosidase–vanillin/curcumin complexes at higher concentrations of vanillin/curcumin. An attempt to obtain the best fit of this kinetic model through computer simulation yielded in good approximation, the values of four important kinetic parameters, vanillin-α/β-D-glucoside: k_cat=35.0±3.2 10^?5M?h^?1·mg, K_i=10.5±1.1?mM, K_mD-glucose=60.0±6.2?mM, K_mvanillin=50.0±4.8?mM; curcumin-bis-α-D-glucoside: k_cat=6.07±0.58 10^?5M?h^?1·mg, K_i=3.0±0.28?mM, K_mD-glucose=10.0±0.9?mM, K_mcurcumin=4.6±0.5?mM.     

Acquisition of alanyl-alanine in an Agnathan: Characteristics of dipeptide transport across the hindgut of the Pacific hagfish Eptatretus stoutii

This study used ³H-_L-alanyl-_L-alanine to demonstrate dipeptide uptake using in vitro gut sacs prepared from the hindgut of the Pacific hagfish Eptatretus stoutii. Concentration-dependent kinetic analysis resulted in a sigmoidal distribution with a maximal (± SE) uptake rate (J_max-like) of 70 ± 3 nmol cm⁻² h⁻¹ and an affinity constant (K_m-like) of 1072 ± 81 μM. Addition of high alanine concentrations to transport assays did not change dipeptide transport rates, indicating that hydrolysis of the dipeptide in mucosal solutions and subsequent uptake via apical amino acid transporters was not occurring, which was further supported by a K_m distinct from that of amino acid transport. Transport occurred independent of mucosal pH, but uptake was reduced by 42% in low mucosal sodium. This may implicate cooperation between peptide transporters and sodium-proton exchangers, previously demonstrated in several mammalian and teleost species. Finally, apical _L-alanyl-_L-alanine uptake rates (i.e., mucosal disappearance) were significantly increased following a meal, demonstrating regulation of uptake. Overall, this examination of dipeptide acquisition in the earliest extant Agnathan suggests evolutionarily conserved mechanisms of transport between hagfish and later-diverging vertebrates such as teleosts and mammals.