Interaction of [3H]dipyridamole with the nucleoside transporters of human erythrocytes and cultured animal cells

Summary Equilibrium binding of [³H]dipyridamole identified high-affinity (K _i 10nm) binding sites on human erythrocytes (5×10⁵ sites/cell) and on HeLa cells (5×10⁶ sites/cell). The equilibration of dipyridamole with these sites on human erythrocytes was compatible with a second-order process which proceeded at 22°C with a rate constant of about 6×10⁶ m ^–1 sec^–1. Binding of dipyridamole to these sites correlated kinetically with the inhibition of the equilibrium exchange of 500 m uridine in these cells and was inhibited in a concentration-dependent manner by nucleosides and other inhibitors of nucleoside transport, such as nitrobenzylthioinosine, dilazep and lidoflazine, but not by hypoxanthine, which is not a substrate for the nucleoside transporter of human erythrocytes. The results indicate that the substrate binding site of the transporter is part of the high-affinity dipyridamole binding site. Bound [³H]dipyridamole became displaced from these sites on human erythrocytes by incubation with an excess of unlabeled dipyridamole or high concentrations of nucleosides and inhibitors of nucleoside transport, but neither by hypoxanthine nor sugars. Dissociation of [³H]dipyridamole behaved as a simple first-order process, but the rate constant was about one order of magnitude lower (about 3×10^–3 sec^–1) than anticipated for typical ligand-protein binding on the basis of the measured association rate and equilibrium constants. The reason for this discrepancy has not been resolved. No high-affinity dipyridamole binding sites were detected on Novikoff rat hepatoma cells, P388, L1210 and S49 mouse leukemia cells or Chinese hamster ovary cells, and their absence correlated with a greater resistance of nucleoside transport in these cells to inhibition by dipyridamole. All cells expressed considerable low affinity (K _d>0.5 m) and nonspecific binding of dipyridamole.     

Apparent cooperativity of [3H]ouabain binding to myocytes obtained from guinea-pig heart

Kinetics of [3H]ouabain binding to intact cardiac cells were examined using myocytes obtained from guinea-pig heart. In intact cells, the use of excess unlabeled ouabain results in an under-estimation of nonspecific binding, presumably due to cytotoxic effects of the unlabeled glycoside; estimation of the specific binding, as that to rapidly releasing sites yields more accurate results. Specific [3H]ouabain binding to myocytes is promoted by an increase in Na+ influx, indicating that normal intracellular Na+ concentration is insufficient to fully stimulate glycoside binding. High concentrations of [3H]ouabain seem to increase the apparent affinity of binding sites for the glycoside via increases in intracellular Na+ concentration resulting from sodium-pump inhibition; hence the binding reaction may be regarded as having a novel type of cooperativity. This cooperativity has kinetics different from those of classical positive cooperativity based on binding-site interactions, and is apparent with toxic concentrations of the glycoside that cause marked increases in intracellular Na+ concentrations.     

[3H]Clonidine binding to rat hippocampal membranes

Alpha adrenergic receptor subtypes in rat hippocampal membranes were studied, using [³H]clonidine as the radioactive ligand. On the basis of competitive binding studies, using the selective antagonist-prazosin, WB-4101, and yohimbine, [³H] clonidine appeared to bind to a population of presynaptic sites that are pharmacologically similar to receptors previously classified as alpha₂. A computerized model that linearized and produced the best possible fit to the experimental data points indicated that [³H]clonidine binds to a single population of receptors possessing equal affinity for the ligand. Binding data also indicated that rat hippocampus contains significantly fewer [³H]clonidine binding sites than rat cortex.     

In vivo covalent binding of retronecine-labelled [3H]seneciphylline and [3H]senecionine to DNA of rat liver, lung and kidney

Retronecine-labelled [3H]seneciphylline ([3H]SPH) and [3H]senecionine ([3H]SON) of high specific radioactivity (22 and 49 mCi/mmol, respectively) were prepared biosynthetically with seedlings of Senecio vulgaris L. using [2,3-3H]putrescine as precursor. [2,3-3H]Putrescine was synthesized by Gabriel synthesis of 1,4-diamino-2-butene from 1,4-dibromo-2-butene and catalytic hydrogenation of the product with tritium gas. Rats of both sexes were treated with the labelled pyrrolizidine alkaloids (PAs) (75-215 microCi SPH or 40-485 microCi SON/kg body wt.) and killed after 6 h or 4-5 days. SON-treated females excreted 83.4 +/- 0.2% of applied radioactivity in faeces and urine within 4 days whereas equally treated males excreted 90.9 +/- 3.2% in the same time. Excretion of 3H-activity from SPH-treated females was completed within 5 days (104.7 +/- 6.4%). Corresponding with these results, tissue levels were highest in SON-treated females. DNA and proteins were isolated from liver, lungs and kidneys and covalent binding of the alkaloids to DNA was determined. A Covalent Binding Index (CBI, mumol alkaloid bound per mol nucleotides/mmol alkaloid administered per kg body wt.) of 210 +/- 12 was found for the liver from SON-treated females whereas binding to liver DNA of males was lower by a factor of 4. The DNA damage determined six hours after treatment persisted during the following 4 days. Administration of [3H]SPH to female and male rats resulted in a CBI of 69 +/- 7 and 73/92, respectively, for the liver DNA. Furthermore we found binding of both alkaloids to DNA of lungs and kidneys in male and female rats. The in vivo formation of [3H]SON derived DNA adducts could be proved by HPLC analysis of hydrolyzed DNA.     

Multiple binding sites for [3H]clonidine and [3H]WB-4101 in rat brain

Binding of the alpha-adrenergic agonist [3H]clonidine and the alpha-adrenergic antagonist [3H]WB-4101 exhibited multiple binding site characteristics in both rat frontal cortex and cerebellum. Kinetic analysis of the dissociation of both radioligands in rat frontal cortex suggests two high affinity sites for each ligand. Competition of various noradrenergic agonists and antagonists for [3H]WB-4101 binding yielded shallow competition curves, with Hill coefficients ranging from 0.45 to 0.7. This further suggests multiplicity in [3H]WB-4101 binding. In the rat cerebellum, competition of various noradrenergic drugs for [3H]clonidine binding yielded biphasic competition curves. Furthermore Scatchard analysis of [3H]clonidine binding in rat cerebellum showed two high affinity sites with KD = 0.5 nM and 1.9 nM, respectively. Competition of various noradrenergic drugs for [3H]WB-4101 binding in the rat cerebellum yielded biphasic competition curves. Lesioning of the dorsal bundle with 6-hydroxydopamine did not significantly affect the binding of either [3H]clonidine or [3H]WB-4101. These findings for both [3H]clonidine and [3H]WB-4101 binding in rat frontal cortex and cerebellum can be explained by the existence of postsynaptic binding sites for both 3H ligands.     

3H]U69,593 binding in guinea-pig brain: comparison with [3H]ethylketazocine binding at the kappa-opioid sites

[3H]U69,593 and [3H]ethylketazocine (mu + delta suppressed) binding was measured in homogenates of guinea-pig brain. Both ligands bind with high affinity to a single class of opioid sites. The relative equilibrium dissociation constant (KD) for [3H]U69,593 is 1.15 nM, while [3H]ethylketazocine has a KD value of 0.33 nM. Their respective maximum binding capacities are 4.49 and 4.48 pmol/g of wet tissue. Various mu-selective, delta-selective, kappa-selective, and nonselective opioids were tested in competition studies against the binding of [3H]U69,593 or [3H]ethylketazocine (in the presence of mu- and delta-blockers) to measure their relative affinity. [D-Ala2, MePhe4,Gly5-ol]enkephalin (mu-selective) has low affinity (600-3000 nM) and [D-Pen2,D-Pen5]enkephalin and [D-Ser2, Leu5, Thr6]enkephalin (delta-selective) have very low affinities (greater than 20,000 nM) at the sites labelled with [3H]U69,593 or [3H]ethylketazocine. On the other hand, unlabelled U69,593, U50,488H, and tifluadom (all three kappa-selective substances) display high affinity (1-5 nM) at those sites. Nonselective opioids, such as bremazocine, levorphanol, and ethylketazocine show similar affinities at the sites labelled with [3H]U69,593 and at the sites labelled with [3H]ethylketazocine. These data indicate that [3H]U69,593 is a selective high-affinity ligand for the same sites that are labelled with [3H]ethylketazocine (in the presence of mu- and delta-blockers) and that these are kappa-sites.     

Biochemical characterization of [3H]tryptamine binding sites from rat brain

Rat brain membranes were treated with different protein modifying reagents, all of which were able to reduce [3H]tryptamine binding. However, inactivation by N-ethylmaleimide and iodoacetamide only was counteracted by coincubation with tryptamine. Thus, the [3H]tryptamine binding molecule is a membrane protein with an essential sulfhydryl group at the binding site. After incubation of digitonin-solubilized membranes with seven different lectins, no precipitation of [3H]tryptamine binding sites was observed. On concanavalin A and wheat germ agglutinin affinity chromatography, no [3H]tryptamine binding activity was found to be specifically bound. Therefore, the [3H]tryptamine binding protein appears to be devoid of lectin binding carbohydrate residues.     

Effects of trypsin on binding of [3H]epinephrine and [3H]-dihydroergocryptine to rat liver plasma membranes. Evidence for interconversion of binding sites

Treatment of liver plasma membranes with trypsin at low concentrations (1 to 2 microgram/mg of protein) caused at 3- to 4-fold increase in alpha-specific [3H]epinephrine binding. The change was due to an increase in the number of high affinity binding sites, with no change in the dissociation constant. With increasing trypsin concentrations, the dissociation constant was decreased and there was a progressive loss of binding. Elastase, papain, and thermolysin caused similar effects, whereas the thrombin, leucine aminopeptidase, phospholipase A2, phospholipase C, phospholipase D, and detergents did not cause an increase in [EH]epinephrine binding. The increase in epinephrine high affinity binding sites was correlated with a loss of high affinity [3H]-dihydroergocryptine binding sites which also bind [3H]epinephrine with low affinity (El-Refai, M. F., Blackmore, P. F., and Exton, J. H. (1979) J. Biol. Chem. 254, 4375-4386). Incubation of membranes with the alpha blockers dihydroergocryptine (50 nM) and phenoxybenzamine (20 nM) prior to protease treatment diminished the increase in [3H]epinephrine binding induced by trypsin (1.5 microgram/mg). The concentration dependence and time course of trypsin actions on 70 nM [3H]epinephrine binding and 10 nM [3H]dihydroergocryptine binding are consistent with a trypsin-mediated conversion of low affinity epinephrine binding sites to high affinity epinephrine binding sites.     

[3H]Tyramine binding: A comparison with neuronal [3H]-dopamine uptake and [3H]mazindol binding processes

[³H]Spiperone ([³H]SPI) binding sites in rat or bovine striata have been solubilized using CHAPS or digitonin detergents. Solubilized sites retained the binding characteristics of those in native membrane preparations. The same solubilized material, however, did not bind [³H]tyramine ([³H]PTA), thus indicating that [³H]PTA binding sites and DA receptors are different chemico-physical entities. In membrane preparations or crude synaptosomes obtained from the c.striatum of neonatally-rendered hypothyroid rats, when central DA-pathways are impaired, both [³H]PTA binding and [³H]DA uptake processes were markedly decreased, with no effect on [³H]mazindol ([³H]MAZ) binding, compared to euthyroids. Reserpine, a well-known inhibitor of DA-uptake into a variety of secretory vesicles, and a potent in vivo andin vitro inhibitor of [³H]PTA binding, did not affect the [³H]MAZ binding process. This further supported the suggestion that while [³H]PTA binding sites are almost totally associated with the vesicular transporter for DA, [³H]MAZ does label a site involved in the DA-translocation across the neuronal membrane. The latter process seems to be rather insensitive to thyroid hypofunction, when however the intracellular storage of DA might be consistently impaired. In conclusion, PTA might be well exploited as a marker of the DA vesicular transporter through its molecular characterization, whenever possible.Special issue dedicated to Dr. Paola S. Timiras     

Purine nucleoside and nucleotide regulation of high affinity [3H]glutamate and [3H]aspartate uptake into rat brain synaptosomes

Purine nucleotides may interact with neurotransmitter transport sites either via specific receptor sites or as donors of high energy phosphate groups. This study shows that purine nucleotides and nucleosides have no effect on the high affinity transport of aspartate. However, the inhibition of high affinity glutamate transport by ATP and GTP may be mediated through a mechanism involving membrane protein phosphorylation.     

Properties of [3H] diazepam binding to rat peritoneal mast cells

Benzodiazepine binding to rat peritoneal mast cells was investigated using [³H] diazepam as the radioactive probe. The specific binding of [³H] diazepam reaches equilibrium within 10–15 min, is saturable and is linear with cell number. Scatchard analysis of equilibrium binding indicates the existence of only one class of binding sites with a K_D = 90 ± 10 nM and B_max of 261 ± 60 fmoles/10⁶ cells. The binding of [³H] diazepam is temperature dependent, the highest amount is bound at 0°C and shows a pH-optimum between pH 6.8 – 7.4. The binding of [³H] diazepam is reversible with $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{= 1.2 ± 0.2}\text{min.}$ Based on the relative potency of clonazepam and Ro5-4864 in displacing the specific [³H] diazepam binding, the binding sites in the mast cell are similar to those in the peripheral tissues like lung, liver, and kidney and are different from those in the brain. These data indicate that the mast cells have benzodiazepine binding sites which are of the peripheral type.     

Circadian-phase-dependency in [3H]-dihydroalprenolol binding to rat heart ventricular membranes

Binding studies with the beta-adrenoceptor antagonist ligand [3H]-dihydroalprenolol ([3H]-DHA, spec. act, 90-102 Ci/mmol) were performed with ventricular membranes L-D-synchronized (L:0.7-19 hr, D:-07 hr) male rats, sacrificed either at 08 hr or at 20 hr. Saturation experiments with crude or washed and preincubated membranes revealed two affinity states of specific [3H]-DHA binding which were abolished after addition of the guanine nucleotide Gpp(NH)p. In crude membranes the apparent Bmax-value at 20 hr was about 40% higher than at 08 hr, in washed and preincubated membranes the nocturnal increase in the apparent Bmax-value was not observed. Pretreatment of rats with isoprenaline (50 mg/kg, i.p.) decreased and catecholamine depletion (reserpine plus inhibition of tyrosine-hydroxylase) increased Bmax-values in crude membranes. The circadian-stage-dependent and the drug-induced effects on the apparent number of beta-adrenoceptors are assumed to be due to circadian or drug-induced variations in the turnover of cardiac noradrenaline.     

High affinity binding of [3H] cocaine to rat liver microsomes

[3H]Cocaine bound reversibly, with high affinity (KD 2.3 +/- 1.1 nM) and stereospecificity to rat liver microsomes. Little binding was detected in the lysosomal, mitochondrial and nuclear fractions. The binding kinetics were slow (T1/2 for association, 6 min and for dissociation 17 min), and the kinetically calculated KD was 2 nM. Induction of mixed function oxidases by phenobarbital did not produce significant change in [3H]cocaine binding. On the other hand, chronic administration of cocaine reduced [3H]cocaine binding drastically. Neither treatment affected the affinity of the liver binding protein for cocaine. Microsomes from mouse and human livers had less cocaine-binding protein and lower affinity for cocaine than those from rat liver. Binding of [3H]cocaine to rat liver microsomes was insensitive to monovalent cations and greater than 10 fold less sensitive to biogenic amines than the cocaine receptor in rat striatum. However, the liver protein had higher affinity for cocaine and metabolites except for norcocaine. Amine uptake inhibitors displaced [3H]cocaine binding to liver with a different rank order of potency than their displacement of [3H]cocaine binding to striatum. This high affinity [3H]cocaine binding protein in liver is not likely to be a monooxygenase, but may have a role in cocaine-induced hepatotoxicity.     

Characterization of [3H]flunitrazepam binding to melanin.

In both clinical and forensic toxicology, the analysis of hair for drugs is an important tool to determine drug use in the past or to verify abstinence from illegal drugs during extended periods. Melanin is proposed as one of the factors that influences drug incorporation to hair and we have characterized the binding of the drug flunitrazepam to melanin in vitro. The drug was 3H labeled and melanin granules from cuttlefish, Sepia officinalis, were used according to the suggested standard for melanin studies. We observed a rapid Langmuir-like binding followed by a slower diffusion-limited binding that may be interpreted as an initial surface binding followed by deeper bulk binding. From three concentrations of melanin, with a 60-min incubation time, a mean saturation value of 180 +/- 20 pmol/mg was calculated. The binding of a group of benzodiazepines and tranquilizers was compared to the binding of [3H]flunitrazepam by means of displacement experiments. These drugs showed binding characteristics similar to [3H]flunitrazepam except phenobarbital, which had a lower affinity to melanin. The method presented in this study allowed measurements with low melanin and drug concentrations and it has the strength of directly measuring the amount of drug bound to melanin, in contrast to previous indirect methods.     

Characterization of [3H]naltrindole binding to delta opioid receptors in rat brain.

[3H]Naltrindole binding characteristics were determined using homogenized rat brain tissue. Saturation binding studies at 25 degrees C measured an equilibrium dissociation constant (Kd) value of 37.0 +/- 3.0 pM and a receptor density (Bmax) value of 63.4 +/- 2.0 fmol/mg protein. Association binding studies showed that equilibrium was reached within 90 min at a radioligand concentration of 30 pM. Naltrindole, as well as the ligands selective for delta (delta) opioid receptors, such as pCI-DPDPE and Deltorphin II inhibited [3H]naltrindole binding with nanomolar IC50 values. Ligands selective for mu (mu) and kappa (kappa) opioid receptors were only effective in inhibiting [3H]naltrindole binding at micromolar concentrations. From these data, we conclude that [3H]naltrindole is a high affinity, selective radioligand for delta opioid receptors.     

In vivo conversion of [3H]myoinositol to [3H]chiroinositol in rat tissues.

We report here the in vivo conversion of [3H]myoinositol to [3H]chiroinositol. After labeling intraperitoneally with [3H]myoinositol for 3 days to reach radioisotope equilibrium in urine, [3H]chiroinositol was isolated from tissues and purified after 6 N HCl hydrolysis by two sequential paper chromatographies and high performance liquid chromatography (HPLC). Percent conversion of [3H]myoinositol to [3H]chiroinositol was highest in urine (36%), liver (8.8%), muscle (8.8%), and blood (7.6%) with intestine, brain, kidney, spleen, and heart decreasing in percentage from 2.8 to 0.7%. Labeling of other inositol isomers including scyllo-, neo-, and epi-, and mucoinositol was minimal, approximately 0.06% of [3H]myoinositol. Glucose was unlabeled, but glucuronate, the product of myoinositol oxidation, was labeled up to 1.5% of the [3H] myoinositol. Acid hydrolysates of combined inositol-containing phospholipids contain significant labeled chiroinositol. [3H]Phosphatidylinositols and [3H]glycosylphosphatidylinositols were extracted from liver, muscle, and blood, isolated by thin layer chromatography, and inositols purified by HPLC after acid hydrolysis. Percent conversion of [3H]myoinositol to [3H] chiroinositol was highest in blood (60.4%) followed by muscle (7.7%) and liver (2.2%).     

Solubilization and characterization of [3H]Imipramine and [3H]Paroxetine binding sites from calf striatum

The serotonin (5-HT) transporter from calf striatum cerebral membranes was solubilized with digitonin and characterized by gel exclusion chromatography. [³H]Imipramine and [³H]paroxetine were utilized as markers for labeling it.³H-imipramine labels a high- and a low-affinity site on striaturn membranes, whereas it binds to a single high-affinity site on the solubilized fraction. [³H]Paroxetine binds with the same affinity to a single site on both membranes and solubilized preparations. After gel exclusion chromatography of the solubilizate both [³H]imipramine and [³H]paroxetine bind on an identical fraction of 205 kDa molecular weight, with a similar maximum number of binding sites (Bmax). Our results suggest that both³H-imipramine and [³H]paroxetine bind to a common site on the 5-HT transporter.