Purine base transport in Neurospora crassa.

Observations presented in this paper point to the presence of dual transport mechanisms for the base adenine in Neurospora crassa. Competition for transport, as well as growth inhibition studies using an ad-1 auxotroph, show that the purine bases adenine, guanine, and hypoxanthine share at least one transport mechanism which is insensitive to adenosine, cytosine, and a variety of other purine base analogues. On the other hand, uptake of adenine by an ad-8 mutant strain unable to transport [8-14C]hypoxanthine at any concentration was not inhibited by guanine or hypoxanthine. This observation demonstrates the existence of an adenine-specific transport system which was also found to be insensitive to inhibition by other purine base analogues, adenosine or cytosine. Recombination analysis of ad-8 by wild-type crosses showed that the inability to transport [8-14C]hypoxanthine was a consequence of the ad-8 lesion or a closely linked mutation. Saturation plots of each system gave intermediary plateaus and nonlinear reciprocal plots which, based on comparison with pure enzyme kinetic analysis, suggest that either each system consists of two or more uptake systems, at least one of which exhibits cooperativity, or that each system is a single uptake mechanism which possesses more than two binding sites where the relative affinity for the purine base first decreases and then increases as the sites are filled.     

Detection and characterization of a nucleoside transport system in human fibroblast lysosomes

Lysosomes contain enzymatic activities capable of degrading nucleic acids to their constituent nucleosides, but the manner by which these degradation products are released from the lysosome is unknown. To investigate this process, human fibroblast lysosomes, purified on Percoll density gradients, were incubated with [3H]adenosine at pH 7.0, and the amount of adenosine taken up by the lysosomes was measured. Adenosine uptake by fibroblast lysosomes attained a steady state by 12 min at 37 degrees C and was unaffected by the presence of 2 mM MgATP or changes in pH from 5.0 to 8.0. An Arrhenius plot was linear with an activation energy of 12.9 kcal/mol and a Q10 of 2.0. Lysosomal adenosine uptake is saturable, displaying a Km of 9 mM at pH 7.0 and 37 degrees C. Various nucleosides and the nucleobase, 6-dimethylaminopurine, strongly inhibit lysosomal adenosine uptake, whereas neither D-ribose or nucleotide monophosphates have any significant effect upon lysosomal adenosine uptake. On a molar basis, purines are recognized more strongly than pyrimidines. Changing the nature of the nucleoside sugar from ribose to arabinose or deoxyribose has little effect on reactivity with this transport system. The known plasma membrane nucleoside transport inhibitors, dipyridamole and nitrobenzylthioinosine, inhibit lysosomal nucleoside transport at relatively low concentrations (25 microM) relative to the Km of 9 mM for lysosomal adenosine uptake. The half-times of [3H]inosine and [3H]uridine efflux from fibroblast lysosomes ranged from 6 to 8 min at 37 degrees C. Trans effects were not observed to be associated with either inosine or uridine exodus. In contrast to adenosine uptake, adenine primarily enters fibroblast lysosomes by a route not saturable by high concentrations of various nucleosides. In conclusion, the saturability of lysosomal adenosine uptake and its specific, competitive inhibition by other nucleosides indicate the existence of a carrier-mediated transport system for nucleosides within fibroblast lysosomal membranes.     

A transport system for phosphoenolpyruvate, 2-phosphoglycerate, and 3-phosphoglycerate in Salmonella typhimurium.

Salmonella typhimurium strain LT-2 was found to utilize phosphoenolpyruvate, 2-phosphoglycerate, and 3-phosphoglycerate as sole sources of carbon and energy for growth, but Escherichia coli strains did not. The following evidence suggests that this growth difference was due to the presence in Salmonella cells of an inducible phosphoglycerate permease distinct from previously studied transport systems: (a) The ability of cells to take up 3-phospho[14-C]glycerate was induced by growth in the presence of phosphoenolpyruvate, 2-phosphoglycerate, or 3-phosphoglycerate, but not glycerate, alpha-glycerophosphate, or other carbon sources tested. (b) Uptake of 3-phospho[14-C]glycerate was strongly inhibited by the three nonradioactive inducers of 3-phosphoglycerate uptake, but not by glycerate or alpha-glycerophosphate. (c) Mutants which lost the ability to utilize and take up 3-phosphoglycerate simultaneously lost the ability to utilize 2-phosphoglycerate and phosphoenolpyruvate, but not other compounds tested. (d) Mutant strains which constitutively synthesized the phosphoglycerate transport system could use both phosphoglycerates and phosphoenolpyruvate as sole sources of phosphate at low substrate concentrations. (e) A strain lacking alkaline and acid phosphatases could still grow with 3-phosphoglycerate as sole carbon source. Maximal rates of 3-phospho[14-C]glycerate uptake occurred at pH 6 in the presence of an exogenous energy source. The apparent Km for 3-phosphoglycerate uptake under these conditions was about 10-minus 4 M. The maximal uptake rate (but not the Km) was dependent on potassium ions. Although synthesis of the phosphoglycerate transport system appeared to be under adenosine 3:5-monophosphate control, glucose repressed induction only slightly. The genes controlling synthesis of the phosphoglycerate transport system (pgt genes) appeared to map at about 74 min on the Salmonella chromosome.     

Specificity of nucleoside transport in Neurospora crassa.

The specificity of nucleoside uptake in germinating conidia of Neurospora crassa was investigated by examining the kinetics of [2-14C]uridine and [8-14C]-adenosine uptake in the wild-type, ad-8, and ud-1 pyr-1 strains. The results obtained strongly indicate that nucleoside transport in N. crassa is mediated solely by a general transport system which accepts both purine and pyrimidine nucleosides. Studies directed at characterizing the specificity of the transport system indicate that general structural features of the nucleoside which enhance its efficiency in binding to the transport system include: (i) a purine or pyrimidine as the heterocyclic ring, (ii) an unfunctionalized ribose or 2'-deoxyribose as the sugar unit, (iii) a beta-configuration about the anomeric carbon, (iv) the absence of substituents at C8 in the purine series and at C5 and C6 in the pyrimidine series, (v) the presence of a C5-C6 double bond in the pyrimidine series, and (vi) the absence of a charge on the heterocyclic ring.     

A nucleoside transporter is functionally linked to ectonucleotidases in rat liver canalicular membrane.

Prevention of nucleoside loss in bile is physiologically desirable because hepatocytes are the main source of nucleosides for animal cells which lack de novo nucleoside biosynthesis. We have demonstrated a Na+ gradient-energized, concentrative nucleoside transport system in canalicular membrane vesicles (CMV) from rat liver by studying [3H]adenosine uptake using a rapid filtration technique. The Na(+)-dependent nucleoside transporter accepts purine, analogues of purine nucleosides and uridine; exhibits high affinity for adenosine (apparent Km, 14 microM); is not inhibited by nitrobenzylthioinosine or dipyridamole, and is present in CMV but not in rat liver sinusoidal membrane vesicles. Adenosine transport in right side-out CMV was substantially greater than with inside-out CMV. CMV also contain abundant ecto-ATPase and ecto-AMPase (5'-nucleotidase). These ectoenzymes were shown to degrade nucleotides into nucleosides which were conserved by the Na(+)-dependent nucleoside transport system.     

Transport and metabolism of galactose in rat kidney cortex

1. Analysis of transport of d-galactose was complicated by metabolism of the compound but appeared to have two components: a substrate-saturable component and a diffusion component. At low substrate concentration (<1mm) active transport was observed. Accumulation of galactose was largely independent of Na(+) concentration. The apparent K(m) for this component was 0.2mm. At substrate concentrations above 1mm the active transport system appeared saturated and further increases in substrate concentration resulted in a linear increase in the rate of galactose accumulation, but no concentration gradient was formed. 2. d-[1-(14)C]Galactose (2mm) was metabolized to (14)CO(2) by rat kidney-cortex slices incubated at 37 degrees C, at the rate of 68nmol/h per 100mg of tissue. 3. Intracellular components from such incubations were separated into a neutral fraction, the only major labelled component being galactose, and a phosphorylated fraction. 4. Phosphorylated metabolites found in galactose-incubated slices increased with increasing substrate concentration and achieved a limiting value of 0.42mm after 60min of incubation. 5. Galactose uptake was inhibited by anaerobiosis, dinitrophenol and phlorrhizin. 6. Methyl alpha-d-glucoside and d-glucose partially inhibited galactose uptake only at ratios of 100:1. 7. The presence of pyruvate did not decrease galactose metabolism although it did decrease production of (14)CO(2) from [1-(14)C]galactose. Gluconeogenesis occurred in the presence of pyruvate and (14)C from galactose was found in glucose. 8. Rat kidney-cortex slices metabolized 2mm-[1-(14)C]galactonate to (14)CO(2) at a rate of 20nmol/h per 100mg of tissue.     

Regulation of hypoxanthine transport in Neurospora crassa.

Hypoxanthine uptake and hypoxanthine phosphoribosyltransferase activity (EC 2.4.2.8) were determined in germinated conidia from the adenine auxotrophic strains ad-1 and ad-8 and the double mutant strain ad-1 ad-8. The mutant strain ad-1 appears to lack aminoimidazolecarboximide ribonucleotide formyltransferase (EC 2.1.2.3) or inosine 5'monophosphate cyclohydrolase (EC 3.5.1.10) activities, or both, whereas the ad-8 strain lacks adenylosuccinate synthase activity (EC 6.3.4.4). Normal (or wild-type) hypoxanthine transport capacity was found to the ad-1 conidia, whereas the ad-8 strains failed to take up any hypoxanthine. The double mutant strains showed intermediate transport capacities. Similar results were obtained for hypoxanthine phosphoribosyl-transferase activity assayed in germinated conidia. The ad-1 strain showed greatest activity, the ad-8 strain showed the least activity, and the double mutant strain showed intermediate activity levels. Ion-exchange chromatography of the growth media revealed that in the presence of NH+/4, the ad-8 strain excreted hypoxanthine or inosine, the ad-1 strain did not excrete any purines, and the ad-1 ad-8 double mutant strain excreted uric acid. In the absence of NH+/4, none of the strains excreted any detectable purine compounds.     

L-[3H]Adenosine, a New Metabolically Stable Enantiomeric Probe for Adenosine Transport Systems in Rat Brain Synaptoneurosomes

The stereoenantimers D-[3H]adenosine and L-[3H]adenosine were used to study adenosine accumulation in rat cerebral cortical synaptoneurosomes. L-Adenosine very weakly inhibited rat brain adenosine deaminase (ADA) activity with a Ki value of 385 microM. It did not inhibit rat brain adenosine kinase (AK) activity, nor was it utilized as a substrate for either ADA or AK. The rate constants (fmol/mg of protein/s) for L-[3H]adenosine accumulation measured in assays where transport was stopped either with inhibitor-stop centrifugation or with rapid filtration methods were 82 +/- 14 and 75 +/- 10, respectively. Using the filtration method, the rates of L-[3H]adenosine accumulation were not significantly different from the value of 105 +/- 15 fmol/mg of protein/s measured for D-[3H]adenosine transport. Unlabeled D-adenosine and nitrobenzylthiolnosine, both at a concentration of 100 microM, reduced the levels and rates of L-[3H]adenosine accumulation by greater than 44%. These findings suggest that L-adenosine, a metabolically stable enantiomeric analog, and the naturally occurring D-adenosine are both taken up by rat brain synaptoneurosomes by similar processes, and as such L-adenosine may represent an important new probe with which adenosine uptake may be studied.     

Effect of artemisinin (qinghaosu) and chloroquine on drug-sensitive and drug-resistant strains of Plasmodium falciparum malaria: use of [2,8-3H]adenosine as an alternative to [G-3H]hypoxanthine in the assessment of in vitro antimalarial activity

Using [G-3H]hypoxanthine uptake as a radioactive indicator for the growth of malarial parasites, we measured the antimalarial activity of artemisinin (Qinghaosu, QHS) against FCMSU1/Sudan strain (chloroquine-sensitive strain) and FCB K+ strain (chloroquine-resistant strain) of Plasmodium falciparum in continuous culture in vitro. The 50% inhibitory concentrations (IC50) for QHS against FCMSU1/Sudan strain and FCB K+ strain were 2.8 X 10(-8) and 3.0 X 10(-8) M, respectively. On the contrary, the response of the two strains to chloroquine was quite different. The IC50 for chloroquine against FCMSU1/Sudan strain was 5.6 ng/ml, whereas that for the FCB K+ strain was 65.6 ng/ml. Therefore, QHS did not appear to exhibit any cross-resistance with chloroquine. If [2,8-3H]adenosine was used as a radioactive precursor instead of [G-3H]hypoxanthine for the determination of antimalarial activity, virtually identical results were obtained. Therefore, [2,8-3H]adenosine can be used as an alternative to [G-3H]hypoxanthine for the assessment of antimalarial action.     

Saturable, energy-dependent uptake of phenanthrene in aqueous phase by Mycobacterium sp. strain RJGII-135

The mechanism of uptake of phenanthrene by Mycobacterium sp. strain RJGII-135, a polycyclic hydrocarbon-degrading bacterium, was examined with cultures grown on phenanthrene (induced for phenanthrene metabolism) and acetate (uninduced). Washed cells were suspended in aqueous solutions of [9-(14)C]phenanthrene, and then the cells were collected by filtration. Low-level steady-state (14)C concentrations in uninduced cells were achieved within the first 15 s of incubation. This immediate uptake did not show saturation kinetics and was not susceptible to inhibitors of active transport, cyanide and carbonyl cyanide m-chlorophenylhydrazone. These results indicated that phenanthrene enters rapidly into the cells by passive diffusion. However, induced cells showed cumulative uptake over several minutes. The initial uptake rates followed saturation kinetics, with an apparent affinity constant (K(t)) of 26 +/- 3 nM (mean +/- standard deviation). Uptake of phenanthrene by induced cells was strongly inhibited by the inhibitors. Analysis of cell-associated (14)C-labeled compounds revealed that the concurrent metabolism during uptake was rapid and was not saturated at the substrate concentrations tested, suggesting that the saturable uptake observed reflects membrane transport rather than intracellular metabolism. These results were consistent with the presence of a saturable, energy-dependent mechanism for transport of phenanthrene in induced cells. Moreover, the kinetic data for the cumulative uptake suggested that phenanthrene is specifically bound by induced cells, based on its saturation with an apparent dissociation constant (K(d)) of 41 +/- 21 nM (mean +/- standard deviation). Given the low values of K(t) and K(d), Mycobacterium sp. strain RJGII-135 may use a high-affinity transport system(s) to take up phenanthrene from the aqueous phase.     

Uridine and cytidine transport in Escherichia coli B and transport-deficient mutants.

Three mutants of Escherichia coli B which are defective in components of the transport system for uridine and uracil were isolated and utilized to study the mechanism of uridine transport. Mutant U- was isolated from a culture resistant to 77 micronM 5-fluorouracil. Mutant U-UR-, isolated from a culture of mutant U-, is resistant to 770 micronM 5-fluorouracil and 750 micronM adenosine. Mutant NUC- is resistant to 80 micronM showdomycin and has been reported previously. The characteristics of uridine transport by E. coli B and the mutants provide data supporting the following conclusions. The transport of adenosine, deoxyadenosine, guanosine, deoxyguanosine, adenine, or guanine by mutant U- and mutant U-UR- is identical with that in the parental strain. Uridine is transported by E. coli B as intact uridine. In addition, extracellular uridine is also rapidly cleaved to uracil and the ribose moiety. The latter is transported into the cells, whereas uracil appears in the medium and is transported by a separate uracil transport system. The entry of the ribose moiety of uridine is fast relative to the uracil and uridine transport processes. The Km values and the inhibitory effects of heterologous nucleosides for the transport of uridine and the ribose moiety of uridine are similar. Studies of cytidine uptake in the parental and mutant strains provide evidence that cytidine is transported by two independent systems, one of which is the same as that involved in the transport of intact uridine. Uridine inhibits but is not transported by the other system for cytidine transport. Evidence for the above conclusions was based on comparisons of the characteristics of [2-14C]uridine, [U-14C]uridine, and [2-14C]cytidine transport using E. coli B and the three transport mutants under conditions which measure initial rates. The nature of the inhibitory effects of heterologous nucleosides on the uridine transport processes and identification of extracellular components from radioactive uridine provides supportive data for the conclusions.     

Kinetics of nucleotide transport in rat heart mitochondria studied by a rapid filtration technique

A rapid filtration technique has been used to measure at room temperature the kinetics of ADP and ATP transport in rat heart mitochondria in the millisecond time range. Transport was stopped by cessation of the nucleotide supply, without the use of a transport inhibitor, thus avoiding any quenching delay. The mitochondria were preincubated for 30 s either in isotonic KCl containing succinate, MgCl2, and Pi (medium P) or in isotonic KCl supplemented only with EDTA and Tris (medium K); they were referred to as energized and resting mitochondria, respectively. The kinetics of [14C]ADP transport in energized mitochondria were apparently monophasic. The plateau value for [14C]ADP uptake reached 4-5 nmol of nucleotide.(mg of protein)-1. Vmax values for [14C]ADP transport of 400-450 nmol exchanged.min-1.(mg of protein)-1 with Km values of the order of 13-15 microM were calculated, consistent with rates of phosphorylation in the presence of succinate of 320-400 nmol of ATP formed.min-1.(mg of protein)-1. The rate of transport of [14C]ATP in energized mitochondria was 5-10 times lower than that of [14C]ADP. Upon uncoupling, the rate of [14C]ATP uptake was enhanced, and that of [14C]ADP uptake was decreased. However, the two rates did not equalize, indicating that transport was not exclusively electrogenic. Transport of [14C]ADP and [14C]ATP by resting mitochondria followed biphasic kinetics.(ABSTRACT TRUNCATED AT 250 WORDS)     

Brain to blood efflux transport of adenosine: blood-brain barrier studies in the rat

The blood-brain barrier (BBB) efflux transport of [(14)C] adenosine was studied using the brain efflux index (BEI) technique. BEI increased linearly over the first 2 min after injection, with deviation from linearity thereafter; 90.12 +/- 1.5% of the injected [(14)C] radioactivity remained within the brain after 20 min. The remaining tracer appears to be mainly intracellular, trapped by phosphorylation, as an almost linear increase of BEI over 20 min was observed after intracerebral injection of [(14)C] adenosine together with 5-iodo tubercidin. The BBB efflux clearance of [(14)C] radioactivity was estimated to be 27.62 +/- 5.2 micro L/min/g, almost threefold higher than the BBB influx clearance estimated by the brain uptake index technique. High-performance liquid chromatography (HPLC) analysis of blood plasma collected from the jugular vein after the intracerebral injection revealed metabolic breakdown of [(14)C] adenosine into nucleobases. The BBB efflux transport was saturable with apparent K(m) = 13.22 +/- 1.75 micro m and V(max) = 621.07 +/- 71.22 pmole/min/g, which indicated that BBB efflux in vivo is 6.2-12p mole/min/g, negligible when compared to the reported rate of adenosine uptake into neurones/glia. However, these kinetic parameters also suggest that under conditions of elevated ISF adenosine in hypoxia/ischaemia, BBB efflux transport could increase up to 25% of the uptake into neurones/glia and become an important mechanism to oppose the rise in ISF concentration. HPLC-fluorometry detected 93.6 +/- 5.25 nm of adenosine in rat plasma, which is 17- to 220-fold lower than the reported K(m) of adenosine BBB influx in rat. Together with the observed rapid degradation inside endothelial cells, this indicated negligible BBB influx of intact adenosine under resting conditions. Cross-inhibition studies showed that unlabelled inosine, adenine and hypoxanthine caused a decrease in BBB efflux of [(14)C] radioactivity in a concentration-dependent manner, with K(i) of 16.7 +/- 4.88, 65.1 +/- 14.1 and 71.1 +/- 16.9 micro m, respectively. This could be due to either competition of unlabelled molecules with [(14)C] adenosine or competition with its metabolites hypoxanthine and adenine for the same transport sites.     

Adenosine kinase-deficient mutant of Neurospora crassa.

Tubercidin-resistant mutant strains of Neurospora crassa were isolated, and at least one appeared to be deficient in adenosine kinase. No significant differences in [8-14C]adenosine labeling of purine nucleotides or nucleosides were found between the wild type and the adenosine kinase-deficient strains.     

Studies on purine transport and on purine content in vacuoles isolated from Saccharomyces cerevisiae.

The transport of purine derivatives into vacuoles isolated from Saccharomyces cerevisiae was studied. Vacuoles which conserved their ability to take up purine compounds were prepared by a modification of the method of polybase-induced lysis of spheroplasts. Guanosine greater than inosine = hypoxanthine greater than adenosine were taken up with decreasing initial velocities, respectively; adenine was not transported. Guanosine and adenosine transporting systems were saturable, with apparent Km values 0.63 mM and 0.15 mM respectively, while uptake rates of inosine and of hypoxanthine were linear functions of their concentrations. Adenosine transport in vacuoles appeared strongly dependent on the growth phase of the cell culture. The system transporting adenosine was further characterized by its pH dependency optimum of 7.1 and its sensitivity to inhibition by S-adenosyl-L-methionine. In the absence of adenosine in the external medium, [14C]adenosine did not flow out from preloaded vacuoles. However, in the presence of external adenosine, a very rapid efflux of radioactivity was observed, indicating an exchange mechanism for the observed adenosine transport in the vacuoles. In isolated vacuoles the only purine derivative accumulated was found to be S-adenosyl-L-homocysteine.     

A member of the second carbohydrate uptake subfamily of ATP-binding cassette transporters is responsible for ribonucleoside uptake in Streptococcus mutans

Streptococcus mutans has a significant number of transporters of the ATP-binding cassette (ABC) superfamily. Members of this superfamily are involved in the translocation of a diverse range of molecules across membranes. However, the functions of many of these members remain unknown. We have investigated the role of the single S. mutans representative of the second subfamily of carbohydrate uptake transporters (CUT2) of the ABC superfamily. The genetic context of genes encoding this transporter indicates that it may have a role in ribonucleoside scavenging. Inactivation of rnsA (ATPase) or rnsB (solute binding protein) resulted in strains resistant to 5-fluorocytidine and 5-fluorouridine (toxic ribonucleoside analogues). As other ribonucleosides including cytidine, uridine, adenosine, 2-deoxyuridine, and 2-deoxycytidine protected S. mutans from 5-fluorocytidine and 5-fluorouridine toxicity, it is likely that this transporter is involved in the uptake of these molecules. Indeed, the rnsA and rnsB mutants were unable to transport [2-(14)C]cytidine or [2-(14)C]uridine and had significantly reduced [8-(14)C]adenosine uptake rates. Characterization of this transporter in wild-type S. mutans indicates that it is a high-affinity (K(m) = 1 to 2 muM) transporter of cytidine, uridine, and adenosine. The inhibition of [(14)C]cytidine uptake by a range of structurally related molecules indicates that the CUT2 transporter is involved in the uptake of most ribonucleosides, including 2-deoxyribonucleosides, but not ribose or nucleobases. The characterization of this permease has directly shown for the first time that an ABC transporter is involved in the uptake of ribonucleosides and extends the range of substrates known to be transported by members of the ABC transporter superfamily.     

ADENOSINE KINASE OF MAMMALIAN BRAIN: PARTIAL PURIFICATION AND ITS ROLE FOR THE UPTAKE OF ADENOSINE

Abstract— Adenosine metabolism in the homogenate of brain mainly undergoes deamination to inosine and hypoxanthine, while uniformly labelled [¹⁴C]adenosine injected into the carotid artery or [8-¹⁴C]adenosine incubated with brain slices was mostly phosphorylated to [¹⁴C]adenine nucleotides in brain cells. Adenosine kinase has now been partially purified from homogenates of guinea pig brain. The kinase preparation was free of adenosine deaminase, almost free of adenosine triphosphatase and had a K_m of the order of 2 × 10^-5M for adenosine.
Kinetic studies with brain slices showed that adenosine reached the cells by diffusion and that the diffusion was facilitated by subsequent phosphorylation to adenine nucleotides. From the following experimental results, it is concluded that the phosphorylation is catalysed by adenosine kinase quantitatively. (1) During the uptake and phosphorylation of adenosine by brain slices, the nucleoside did not split to adenine and ribose moieties. (2) The rate of formation of adenine nucleotides in the slices was a hyperbolic function of the concentration of adenosine in the medium, showing an apparent K_m foradenosine of the order of 2 × 10^-5 M. (3) Some analogues of adenosine inhibited both the facilitated diffusion of adenosine and the kinase activity, but ouabain (0.005 mM) did not inhibit either.     

Properties of the lactose transport system in Klebsiella sp. strain CT-1.

Highly purified [D-glucose-1-14C]lactose has been used to study the transport of lactose by Klebsiella sp. strain CT-1. Strain CT-1 transports lactose by a lactose-inducible system that exhibited an apparent Km of 6 mM lactose and an apparent Vmax of 140 nmol/min per mg of cell protein. Lactose uptake was inhibited competitively by o-nitrophenyl-beta-D-galactoside with a Ki value of 8 mM, but was not inhibited by thio-beta-methyl-galactoside. D-Glucose, D-mannose, 2-deoxyglucose, and alpha-methyl-D-glucoside also inhibited lactose uptake. Phosphoenolpyruvate-dependent hydrolysis of o-nitrophenyl-beta-D-galactoside and lactose-dependent release of pyruvate from phosphoenolpyruvate by benzene-treated CT-1 cells showed that CT-1 transports lactose by a phosphoenolpyruvate:sugar phosphotransferase system. Correlations between the growth rate of CT-1 on lactose and properties of the transport system indicated that transport is the rate limiting step in utilization of lactose.     

Intracellular formation of analogs of cyclic AMP. Studies with brain slices labeled with radioactive derivatives of adenine and adenosine.

A variety of radioactive analogs of adenine and adenosine were incubated with guinea pig cerebral cortical slices. Neither 1,N6-etheno[14C] adenosine nor 1,N6-etheno[14C] adenine were significantly incorporated into intracellular nucleotides. 2-chloro[8-3H] adenine was incorporated, but at a very low rate and conclusive evidence for the formation of intracellular radioactive 2-chloro-cyclic AMP was not obtained. N6-Benzyl[14C] adenosine was converted only to intracellular monophosphates and significant formation of radioactive N6-benzylcyclic AMP was not detected during a subsequent incubation. 2'-Deoxy-[8-14C] adenosine was converted to both intracellular radioactive 2'-deoxy-adenine nucleotides and radioactive adenine nucleotides. Stimulation of these labeled slices with a variety of agents resulted in formation of both radioactive 2'-deoxycyclic AMP and cyclic AMP. Investigation of the effect of various other compounds on uptake of adenine or adenosine suggested that certain other adenosine analogs might serve as precursors of abnormal cyclic nucleotides in intact cells.     

Sodium-dependent and inhibitor-insensitive uptake of adenosine by mouse peritoneal exudate cells

[8-3H]Adenosine uptake in mouse peritoneal exudate cells, harvested following i.p. challenge with Complete Freund's Adjuvant from BALB/c mice, was found to be insensitive to common nucleoside transport inhibitors such as dilazep or 6-[(4-nitrobenzyl)mercapto]purine ribonucleoside and to require sodium ion, being inactive when sodium was replaced by lithium or potassium. These findings also applied to the adherent (macrophages) and nonadherent (polymorphonuclear cells) cell fractions prepared from the peritoneal cell mixture. Uptake was inhibited by several nucleosides including deoxyadenosine, inosine, uridine, thymidine and, to a lesser extent, by the adenosine analog tubercidin, while adenine, fructose, glucose and ribose were without effect. Uptake [8-3H]adenosine was fully matched by rapid intracellular phosphorylation to AMP, ADP and ATP. Inosine was a substrate for the transporter, but tubercidin was not. The system clearly is distinct from carrier-mediated, nonconcentrative transport and has similarities to concentrative, sodium-dependent nucleoside transporters described in other cell types.