Probe dependency in the determination of ligand binding kinetics at a prototypical G protein-coupled receptor.

Drug-target binding kinetics are suggested to be important parameters for the prediction of in vivo drug-efficacy. For G protein-coupled receptors (GPCRs), the binding kinetics of ligands are typically determined using association binding experiments in competition with radiolabelled probes, followed by analysis with the widely used competitive binding kinetics theory developed by Motulsky and Mahan. Despite this, the influence of the radioligand binding kinetics on the kinetic parameters derived for the ligands tested is often overlooked. To address this, binding rate constants for a series of histamine H1 receptor (H1R) antagonists were determined using radioligands with either slow (low koff) or fast (high koff) dissociation characteristics. A correlation was observed between the probe-specific datasets for the kinetic binding affinities, association rate constants and dissociation rate constants. However, the magnitude and accuracy of the binding rate constant-values was highly dependent on the used radioligand probe. Further analysis using recently developed fluorescent binding methods corroborates the finding that the Motulsky-Mahan methodology is limited by the employed assay conditions. The presented data suggest that kinetic parameters of GPCR ligands depend largely on the characteristics of the probe used and results should therefore be viewed within the experimental context and limitations of the applied methodology.

Pharmacokinetic analysis of the FAK scaffold inhibitor C4 in dogs.

Inhibition of focal adhesion kinase-vascular endothelial growth factor receptor 3 complex by C4 was previously shown to reduce tumor growth alone and synergistically with other chemotherapeutic agents in animal tumor models. Single and multiple dose IV and oral dosing studies were performed in dogs to determine C4 pharmacokinetics. C4 was administered to 4 dogs at 1.25 or 2.50 mg/kg IV, or 7.50 mg/kg oral gavage. Single- (IV and oral) and multiple- (IV) dose pharmacokinetic samples were collected on days 1 and 3 at pre-dose and 0.5, 1, 2, 4, 8, 24, 120, 144, and 168 h post-dose. C4 concentrations were determined using liquid chromatography with tandem mass spectral detection with a limit of quantitation of 2.50 pg/mL. Pharmacokinetics of C4 was characterized by a 3-compartment model with linear distributional and elimination clearances using Phoenix 64 WinNonlin 6.3. Mean C4 plasma concentration-time profiles revealed a triexponential decline following either IV or oral administration, independent of dose with no accumulation. For the 2.5 mg/kg dose, the median half-life was ~21 h. Median C max and area under the curve (AUC0-24) were similar for days 1 and 3. Oral bioavailability for formulations of PBS, TPGS, Maalox(®), and Pepcid(®) was greatest with TPGS (45 %), followed by Maalox(®) (42 %), Pepcid(®) (37 %), and PBS (30 %). The pharmacokinetic study revealed that C4 has linear pharmacokinetics and does not accumulate following multiple-dose administration. Characterization of C4 pharmacokinetics provides a better understanding of the novel targeted agent, which will help facilitate further development of C4.

[Carrier-mediated Transport of Cationic Drugs across the Blood-Tissue Barrier].

Studies of neurological dysfunction have revealed the neuroprotective effect of several cationic drugs, suggesting their usefulness in the treatment of neurological diseases. In the brain and retina, blood-tissue barriers such as blood-brain barrier (BBB) and blood-retinal barrier (BRB) are formed to restrict nonspecific solute transport between the circulating blood and neural tissues. Therefore study of cationic drug transport at these barriers is essential to achieve systemic delivery of neuroprotective agents into the neural tissues. In the retina, severe diseases such as diabetic retinopathy and macular degeneration can cause neurological dysfunction that dramatically affects patients' QOL. The BRB is formed by retinal capillary endothelial cells (inner BRB) and retinal pigment epithelial cells (outer BRB). Blood-to-retina transport of cationic drugs was investigated at the inner BRB, which is known to nourish two thirds of the retina. Blood-to-retinal transport of verapamil suggested that the barrier function of the BRB differs from that of the BBB. Moreover, carrier-mediated transport of verapamil and pyrilamine revealed the involvement of novel organic cation transporters at the inner BRB. The identified transport systems for cationic drugs are sensitive to several cationic neuroprotective and anti-angiogenic agents such as clonidine and propranolol, and the involvement of novel transporters was also suggested in their blood-to-retina transport across the inner BRB.

Influence of the N-terminus and the E2-loop onto the binding kinetics of the antagonist mepyramine and the partial agonist phenoprodifen to H(1)R.

Numerous competitive radioligand binding studies revealed significant differences between human and guinea pig histamine H(1)-receptors (hH(1)R and gpH(1)R), e.g. for the partial H(1)R agonist phenoprodifen. But until now, there are only few studies with regard to binding kinetics at H(1)R. Previous studies from our group revealed an influence of the exchange of N-terminus and E2-loop between hH(1)R and gpH(1)R onto affinity of phenoprodifen to H(1)R (Strasser A, Wittmann HJ, Seifert R, J Pharmacol Exp Ther 326:783-791, 2008). The aim of this study was, therefore, to examine the impact of the N-terminus and the E2-loop on binding kinetics of the H(1)R. The wild type hH(1)R and gpH(1)R and the chimeric h(gpE2)H(1)R (E2-loogp from guinea pig) and h(gpNgpE2)H(1)R (N-terminus and E2-loop from guinea pig) were co-expressed with regulator of G-protein signaling protein RGS4 in Sf9 insect cells and kinetic binding studies were performed using the antagonist [(3)H]mepyramine as radioligand. The rate constants for association and dissociation were, in dependence of the ligand, different between hH(1)R and gpH(1)R. Furthermore, the rate constants for association at h(gpNgpE2)H(1)R were significantly different compared to hH(1)R and gpH(1)R. Molecular dynamic simulation studies detected different interactions of amino acid side chains on the extracellular surface of the receptor. Based on these findings, the influence of extracellular surface onto binding kinetics and binding affinity can be explained. Thus, the extracellular surface of G protein-coupled receptors for biogenic amines, exhibits influence onto kinetics of ligand binding, onto ligand recognition and ligand guiding into the binding pocket.

Genetic deficiency of carnitine/organic cation transporter 2 (slc22a5) is associated with altered tissue distribution of its substrate pyrilamine in mice.

Carnitine/organic cation transporter 2 (OCTN2) recognizes various cationic compounds as substrates in vitro, but information on its pharmacokinetic role in vivo is quite limited. This paper demonstrates altered tissue distribution of the OCTN2 substrate pyrilamine in juvenile visceral steatosis (jvs) mice, which have a hereditary defect of the octn2 gene. At 30 min after intravenous injection of pyrilamine, the tissue-to-plasma concentration ratio (K(p)) in the heart and pancreas was higher, whereas the K(p) in kidney and testis was lower in jvs mice compared with wild-type mice. Pyrilamine transport studies in isolated heart slices confirmed higher accumulation, together with lower efflux, of pyrilamine in the heart of jvs mice. The higher accumulation in heart slices of jvs mice was abolished by lowering the temperature, by increasing the substrate concentration, and in the presence of other H(1) antagonists or another OCTN2 substrate, carnitine, suggesting that OCTN2 extrudes pyrilamine from heart tissue. On the other hand, the lower distribution to the kidney of jvs mice was probably due to down-regulation of a basolateral transporter coupled with OCTN2, because, in jvs mice, (i) the K(p) of pyrilamine in kidney assessed immediately after intravenous injection (approximately 1 min) was also lower, (ii) the urinary excretion of pyrilamine was lower, and (iii) the uptake of pyrilamine in kidney slices was lower. The renal uptake of pyrilamine was saturable (K(m) approximately 236 microM) and was strongly inhibited by cyproheptadine, astemizole, ebastine and terfenadine. The present study thus indicates that genetic deficiency of octn2 alters pyrilamine disposition tissue-dependently.

Pyrilamine in the horse: detection and pharmacokinetics of pyrilamine and its major urinary metabolite O-desmethylpyrilamine.

Pyrilamine is an antihistamine used in human and veterinary medicine. As antihistamines produce central nervous system effects in horses, pyrilamine has the potential to affect the performance of racehorses. In the present study, O-desmethylpyrilamine (O-DMP) was observed to be the predominant equine urinary metabolite of pyrilamine. After intravenous (i.v.) administration of pyrilamine (300 mg/horse), serum pyrilamine concentrations declined from about 280 ng/mL at 5 min postdose to about 2.5 ng/mL at 8 h postdose. After oral administration of pyrilamine (300 mg/horse), serum concentrations peaked at about 33 ng/mL at 30 min, falling to <2 ng/mL at 8 h postdose. Pyrilamine was not detected in serum samples at 24 h postdosing by either route. After i.v. injection of pyrilamine (300 mg/horse) O-DMP was recovered at a level of about 20 microg/mL at 2 h postdose thereafter declining to about 2 ng/mL at 168 h postdose. After oral administration, the O-DMP recovery peaked at about 12 microg/mL at 8 h postdose and declined to <2 ng/mL at 168 h postdose. These results show that pyrilamine is poorly bioavailable orally (18%), and can be detected by sensitive enzyme-linked immunosorbent assay tests in urine for up to 1 week after a single administration. Care should be taken as the data suggest that the withdrawal time for pyrilamine after repeated oral administrations is likely to be at least 1 week or longer.

Involvement of the pyrilamine transporter, a putative organic cation transporter, in blood-brain barrier transport of oxycodone.

The purpose of this study was to characterize blood-brain barrier (BBB) transport of oxycodone, a cationic opioid agonist, via the pyrilamine transporter, a putative organic cation transporter, using conditionally immortalized rat brain capillary endothelial cells (TR-BBB13). Oxycodone and [3H]pyrilamine were both transported into TR-BBB13 cells in a temperature- and concentration-dependent manner with Km values of 89 and 28 microM, respectively. The initial uptake of oxycodone was significantly enhanced by preloading with pyrilamine and vice versa. Furthermore, mutual uptake inhibition by oxycodone and pyrilamine suggests that a common mechanism is involved in their transport. Transport of both substrates was inhibited by type II cations (quinidine, verapamil, and amantadine), but not by classic organic cation transporter (OCT) substrates and/or inhibitors (tetraethylammonium, 1-methyl-4-phenylpyridinium, and corticosterone), substrates of OCTN1 (ergothioneine) and OCTN2 (L-carnitine), or organic anions. The transport was inhibited by metabolic inhibitors (rotenone and sodium azide) but was insensitive to extracellular sodium and membrane potential for both substrates. Furthermore, the transport of both substrates was increased at alkaline extracellular pH and decreased in the presence of a protonophore (carbonyl cyanide-p-trifluoromethoxyphenylhydrazone). Intracellular acidification induced with ammonium chloride enhanced the uptakes, suggesting that the transport is driven by an oppositely directed proton gradient. The brain uptake of oxycodone measured by in situ rat brain perfusion was increased in alkaline perfusate and was significantly inhibited by pyrilamine. These results suggest that blood-brain barrier transport of oxycodone is at least partly mediated by a common transporter with pyrilamine, and this transporter is an energy-dependent, proton-coupled antiporter.

Peripheral and central H1 histamine receptor occupancy by levocetirizine, a non-sedating antihistamine; a time course study in the guinea pig.

BACKGROUND AND PURPOSE: The H(1) receptor occupancy (H1RO) in brain is an indicator of central side effects of antihistamines. Here, we determined the kinetics of central and peripheral H1RO by levocetirizine in relation to its brain and plasma concentration, and investigated the role of the blood-brain barrier in any delay in brain H1RO. EXPERIMENTAL APPROACH: Concentration-time profiles in plasma and brain were obtained after 0.1 and 1 mg kg(-1) oral doses of levocetirizine in guinea pigs. H1RO in brain was measured ex vivo using [3H]-mepyramine and, in the periphery, by measuring the degree of inhibition of histamine-induced contractions of isolated guinea pig ileum. KEY RESULTS: The concentration-time profile of levocetirizine indicated lower levels (partition coefficient, K(p)=0.06-0.08), higher t(max) (2-4 h vs 1-1.5 h) and longer terminal half-life (4-5.6 h vs 2.1-2.8 h) in brain than plasma. The H1RO at 0.1 and 1 mg kg(-1) were 75% and 97%, respectively, at 1 hr in the periphery and, in the brain, were <20% and 28-67% respectively, at all time points studied. Brain H1RO vs plasma concentrations profile showed a delay, but not when compared to brain concentrations. CONCLUSIONS AND IMPLICATIONS: This study demonstrates an effective peripheral antihistamine effect of levocetirizine without central adverse effects at the dose close to human therapeutic dose. The slow increase in H1RO in the brain with time was caused by slow blood-brain barrier transport of levocetirizine. This demonstrates the importance of measuring time course of brain H1RO in relation to brain concentrations of drugs.

Mutation in an adaptor protein PDZK1 affects transport activity of organic cation transporter OCTNs and oligopeptide transporter PEPT2.

Genetic polymorphisms in xenobiotic transporters have recently been clarified to be associated with change in drug distribution and disposition. To expand on recent identification of direct interaction and functional regulation of several transporters by a PDZ (PSD95, Dlg and ZO1) domain containing protein PDZK1, the effect of mutation in PDZK1 on transport activity and subcellular localization of organic cation/carnitine transporters OCTN1 and OCTN2, and oligopeptide transporter PEPT2 was examined in the present study. HEK293 cells stably expressing a mutant transcript PDZK1-E195K (HEK293/PDZK1-E195K) were constructed, followed by transient transfection of cDNA for each transporter. Uptake of tetraethylammonium by OCTN1 was much higher in HEK293/PDZK1 cells, compared with that in the parent HEK293 cells, the uptake in HEK293/PDZK1-E195K cells showing middle range between the two values. Such difference in transport activity was accounted for the difference in transport capacity, with minimal change in affinity of OCTN1 to the substrate or other compounds. The similar difference among HEK293/PDZK1, HEK293/PDZK1-E195K and HEK293 cells was also observed in transport property of OCTN2 and PEPT2, whereas the difference was not so remarkable in each transporter with the last four amino acids deleted, that has much lower interaction potential with PDZK1. Immunohistochemical analysis indicated that OCTN1 was colocalized with PDZK1 on cell-surface, whereas colocalization with PDZK1-E195K was partially observed in cytoplasmic region. These results suggest a novel hypothesis that mutation in PDZK1 potentially changes transport property of various types of xenobiotic transporters by affecting their subcellular localization, possibly leading to change in disposition of various types of substrate drugs.

Multiple cedar pollen challenge diminishes involvement of histamine in allergic conjunctivitis of Guinea pigs.

It has been reported that antihistamines do not fully modify symptoms of allergic conjunctivitis in clinical settings, suggesting that histamine is not the only contributor to symptom generation in the disease. However, in the majority of experimental allergic conjunctivitis models, antihistamines are very effective in the reduction of symptoms. In the present study, we used our recently developed guinea pig model of allergic conjunctivitis and evaluated whether involvement of histamine in the induction of symptoms of allergic conjunctivitis is altered by multiple antigen challenges. Guinea pigs were sensitized by intraperitoneal injection of Japanese cedar pollen extracts adsorbed on aluminum hydroxide gel, and then challenged by dropping a pollen suspension without the adjuvant on each eye once a week until the 15th challenge. The magnitude of the conjunctivitis intensity score (CIS), itch-associated scratching response and albumin leakage were found to increase with repeated challenges. At the 1st-3rd challenges, histamine H(1) receptor antagonist, mepyramine (10 mg/kg, p.o.), strongly reduced all these symptoms. However, symptoms at the 5th-15th challenges were not inhibited by mepyramine. On the other hand, a nitric oxide synthase (NOS) inhibitor, N(omega)-nitro-L-arginine methyl ester (10 mg/kg, i.v.), potently inhibited the increase of CIS and albumin leakage at the 15th challenge. In conclusion, histamine involvement in the induction of conjunctivitis symptoms in our model was diminished by multiple antigen challenges. The allergic conjunctivitis at the chronic stage is partly mediated by nitric oxide (NO) derived from NOSs that may be activated by mediators other than histamine. The histamine-independent allergic conjunctivitis may be useful for analyzing mechanisms underlying chronic conjunctivitis.

Influence of histamine, cimetidine and pyrilamine on naloxone-induced jumping in morphine-dependent mice.

In the present study, the effects of histamine on naloxone-induced jumping in the presence or absence of adrenoceptor or acetylcholine receptor antagonists in morphine-dependent mice were examined. In these experiments, the drugs were used before s.c. injection of naloxone (2 mg/kg), to test their effects on the expression of jumping. The i.c.v. administration of histamine (5-20 microg/mouse) 15 min before naloxone injection decreased the number of jumps in mice. When the histamine H(2) receptor antagonist, cimetidine (5-20 mg/kg), and the histamine H(1) receptor antagonist, pyrilamine (5-20 mg/kg), were administered i.p. to morphine-dependent mice, only cimetidine enhanced the jumping behaviour. Administration of cimetidine (20 mg/kg, i.p.), 30 min, of the beta-adrenoceptor antagonist, propranolol (2.5-10 mg/kg, i.p.), 15 min but not of pyrilamine (20 mg/kg, i.p.), 30 min before naloxone injection, decreased the histamine effect. The i.p. administration of an acetylcholine receptor antagonist, atropine (5 and 10 mg/kg, i.p.), the alpha(1)-adrenoceptor antagonist, prazosin (0.5, 1 and 2 mg/kg, i.p.), and alpha(2)-adrenoceptor antagonist, yohimbine (0.5, 1 and 2 mg/kg, i.p.), 15 min before naloxone injection, had no effect on the histamine response. Single administration of propranolol, atropine or prazosin decreased, while yohimbine increased the naloxone-induced jumping. It is concluded that the histamine H(2) receptor mechanism may be involved in the influence of histamine on the expression of naloxone-induced jumping in morphine-dependent mice.

Molecular characterization of specific H1-receptor agonists histaprodifen and its Nalpha-substituted analogues on bovine aortic H1-receptors.

We determined the molecular properties of the selective and potent H(1)-receptor agonist histaprodifen and its N(alpha) substituted analogues: methyl-, dimethyl-, and imidazolylethyl-histaprodifen (suprahistaprodifen). All derivatives show high affinity for (3)H-mepyramine labeled bovine aortic H(1)-receptor binding sites with the following order of potency: suprahistaprodifen > dimethylhistaprodifen > methylhistaprodifen > histaprodifen > histamine. Suprahistaprodifen and dimethylhistaprodifen were the most potent displacers of (3)H-mepyramine binding (K(i)=4.3 and 4.9 nM, respectively). Histaprodifen, methylhistaprodifen and suprahistaprodifen binding was differentially influenced by GTP, whereas dimethylhistaprodifen was not affected. All drugs, except dimethylhistaprodifen, were activators of G-proteins. Their order of potency was suprahistaprodifen > histamine > histaprodifen > methylhistaprodifen. Their effect on G-protein activation was abolished by the addition of the H(1)-receptor antagonist triprolidine (10 microM), which given alone did not activate G-proteins. Our data suggest that histaprodifens are potent but heterogeneous H(1)-receptor ligands with diverse effects on the molecular level in our model system. While the histaprodifen, methylhistaprodifen and suprahistaprodifen data are in agreement with their agonistic nature, as shown in the functional studies performed on different species (rat and guinea pig H(1)-receptor), dimethylhistaprodifen behaved as an antagonist in our study.

Putative sigma(3) sites in mammalian brain have histamine H(1) receptor properties: evidence from ligand binding and distribution studies with the novel H(1) radioligand [(3)H]-(-)-trans-1-phenyl-3-aminotetralin.

A novel phenylaminotetralin (PAT) radioligand, [(3)H]-(1R, 3S)-(-)-trans-1-phenyl-3-dimethylamino-1,2,3,4-tetrahydronaphthalene ([(3)H]-[-]-trans-H(2)-PAT), is shown here to label a saturable (B(max)=39+/-6 fmol/mg protein) population of sites with high affinity (K(d)=0.13+/-0.03 nM) in guinea pig brain. Consistent with previous studies which showed that PATs stimulate catecholamine (dopamine) synthesis in rat striatum, autoradiographic brain receptor mapping studies here indicate that [(3)H]-(-)-trans-H(2)-PAT-labeled sites are highly localized in catecholaminergic nerve terminal fields in hippocampus, nucleus accumbens, and striatum in guinea pig brain. Competition binding studies with a broad range of CNS receptor-active ligands and CNS radioreceptor screening assays indicate that the pharmacological binding profile of brain [(3)H]-(-)-trans-H(2)-PAT sites closely resembles histamine H(1)-type receptors. Comparative studies using the histamine H(1) antagonist radioligand, [(3)H]mepyramine, indicate that the H(1) ligand binding profile and guinea pig brain distribution of H(1) receptors and [(3)H]-(-)-trans-H(2)-PAT sites are nearly identical; moreover, both sites have about 40-fold stereoselective affinity for (-)- over (+)-trans-H(2)-PAT. These results are discussed in light of previous studies which suggested that PATs stimulate dopamine synthesis through interaction with a novel sigma-type (sigma(3)) receptor in rodent brain; it now appears instead that PATs represent a new class of ligands for brain histamine H(1) receptors that can be stereoselectively labeled with [(3)H]-(-)-trans-H(2)-PAT.

Mechanisms of non-drowsiness after oral administration of TMK688, a novel antiallergic drug.

The mechanisms of non-drowsiness after oral administration of TMK688 (1- [[5'-(3"-methoxy-4"-ethoxycarbonyloxyphenyl)-2',4'-pentadienoyl ] aminoethyl]-4-diphenylmethoxypiperidine, CAS 110501-66-1) were investigated using mice. TMK688 inhibited the histamine-induced vascular permeability at oral doses of 3.2-10 mg/kg with an ID50 value of 5.4 mg/kg. More than 100 times higher doses were needed to prolong the hexobarbital-induced sleeping. Pyrilamine, a typical antihistamine agent, showed little difference among these doses and antiallergic drugs having antihistamine activity, i.e., terfenadine, azelastine and ketotifen, had effects between TMK688 and pyrilamine. The inhibitory activity of orally administered TMK688 against ex vivo [3H]-pyrilamine binding to mouse cerebral histamine receptors appeared at the same doses as its potentiating activity against hexobarbital-induced sleeping. When given orally, TMK688 was hydrolyzed to TMK777 (CAS 101619-11-8), then conjugated with glucuronic acid to TMK777-glucuronide. No TMK688 was detected in the blood. The main metabolite TMK777-glucuronide could hardly penetrate the blood-brain barrier because of its polarity. Although the plasma concentrations of TMK777 were far lower than those of TMK777-glucuronide, TMK777 was penetrable into the brain and the cerebral concentrations of TMK777 increased in parallel with the plasma concentrations of the drug. Since intracerebroventricularly-injected TMK777 prolonged the sleeping time, and since the threshold concentration of TMK777 in the cerebral cortex to potentiate the hexobarbital-induced sleeping was consistent despite different administration routes, the drowsiness elicited by markedly high doses of TMK688 is though to be caused by intracerebral TMK777. In other words, TMK688 does not seem to cause drowsiness at effective doses because of the poor prenetrability of its main metabolites into the brain.

Analysis of plasma metabolites during human PET-studies with three receptor ligands, [11C]YM-09151-2, [11C]doxepin and [11C]pyrilamine.

Carbon-11 labeled metabolites in human plasma were analyzed by high-performance liquid chromatography during positron emission tomography (PET) studies using the dopamine D2 ligand [11C]YM-09151-2 as well as the histamine H1 ligands [11C]doxepin and [11C]pyrilamine. For all the three tracers, blood clearance of the radioactivity was extremely rapid after an i.v. injection. The plasma protein-binding of [11C]YM-09151-2 and [11C]doxepin had protective effects upon the metabolic alteration of the ligands, whereas [11C]pyrilamine was free from the protein-binding and immediately degraded. The degradation of [11C]doxepin was more rapid in epileptic patients on medication than in normal subjects. These results indicate that analysis of metabolites in the plasma is necessary to determine the accurate arterial input function for quantitative PET measurement.

Carrier-mediated transport of H1-antagonist at the blood-brain barrier: a common transport system of H1-antagonists and lipophilic basic drugs.

The blood-brain barrier (BBB) transport system for H1-antagonists was studied using primary cultured bovine brain capillary endothelial cells (BCEC). The uptake of [3H]mepyramine was inhibited by various H1-antagonists. Ketotifen competitively inhibited [3H]mepyramine uptake with an inhibition constant (Ki) of 46.8 microM. Lipophilic basic drugs such as propranolol, lidocaine and imipramine significantly inhibited [3H]mepyramine uptake. In particular, propranolol inhibited [3H]mepyramine uptake competitively at an inhibition constant (Ki) of 51.1 microM. Moreover, in ATP-depleted BCEC, [3H]mepyramine uptake was stimulated by preloading with H1-antagonists and lipophilic basic drugs. These results indicated that H1-antagonists are transported across the BBB via a carrier-mediated transport system common to lipophilic basic drugs.

Antiallergic effect of ZCR-2060: antihistaminic action.

The antihistaminic effect of 2-[2-[4-(diphenylmethyl)-1-piperadinyl]ethoxy] benzoic acid maleate (ZCR-2060), a newly synthesized antiallergic agent, was investigated in both in vitro and in vivo studies. ZCR-2060 clearly antagonized histamine-induced contraction of isolated guinea pig ileum and trachea. In contrast, carbachol-, BaCl2- and 5-hydroxytryptamine-induced contractions of isolated guinea pig ileum were slightly inhibited by higher concentrations of ZCR-2060. 3H-Mepyramine specific binding to membranes from guinea pig lung and brain were markedly inhibited by ZCR-2060 in a concentration-dependent fashion. In the in vitro studies, the antihistaminic effect of ZCR-2060 was greater than those of cetirizine and terfenadine, but was less than that of ketotifen. In the in vivo studies, ZCR-2060 significantly inhibited the histamine-induced cutaneous reaction in rats, when administered orally 1 hr before the histamine injection. Moreover, ZCR-2060 has a long-lasting antihistaminic effect. In the in vivo studies, the antihistaminic effect of ZCR-2060 was found to be greater than that of cetirizine and terfenadine, and it was the same as that of ketotifen. Thiopental-induced sleep and spontaneous ambulatory activity in mice, however, were unaffected by ZCR-2060 at higher doses. These results indicate that ZCR-2060 has a potent, selective and long acting histamine H1-receptor antagonistic action without causing any unwanted CNS side effect.

Carrier-mediated transport of H1-antagonist at the blood-brain barrier: mepyramine uptake into bovine brain capillary endothelial cells in primary monolayer cultures.

The transport mechanism of the H1-antagonist mepyramine at the blood-brain barrier (BBB) was studied by using primary cultured monolayers of bovine brain capillary endothelial cells (BCEC). The initial uptake of [3H]mepyramine into the BCEC showed strong temperature and concentration dependency, indicating that it involves both saturable and nonsaturable processes. Transport at the luminal membrane may be the rate-limiting process in the transcellular transport, since the values of the uptake coefficient of [3H]mepyramine at the luminal membrane (609 microliters/mg protein/min) and the transcellular permeability coefficient (488 microliters/mg protein/min) are very similar. The initial uptake of [3H]mepyramine was not affected by metabolic inhibitors, but was stimulated by preloading with the drug. Mepyramine appears to be transported into the BCEC by a carrier-mediated transport system which does not require metabolic energy, probably via a facilitated diffusion mechanism.

Transport mechanism of an H1-antagonist at the blood-brain barrier: transport mechanism of mepyramine using the carotid injection technique.

The blood-brain barrier (BBB) permeability of mepyramine was measured by the carotid injection technique to elucidate the transport mechanism of an H1-antagonist in the central nervous system. Mepyramine was found to enter the brain by saturable and carrier-mediated transport. The in vivo kinetic parameters were estimated as follows: the maximum uptake rate (Jmax) was 7.12 +/- 1.37 mumol/min/g of brain, the Michaelis constant (Kt) was 4.40 +/- 2.00 mM, and the nonsaturable first order rate (Kd) was 0.28 +/- 0.02 ml/min/g of brain. The mepyramine transport was not inhibited either by nutrients or by choline, hemicholinium-3, though it was inhibited by the classical H1-antagonists such as diphenhydramine, diphenylpyraline, and also by propranolol. The above inhibitory effects suggest that a transport system different from the amine transport system exists for the BBB transport of mepyramine, and that this transporter is common not only for H1-antagonists but also for basic drugs.

Calcium-dependence of histamine- and carbachol-induced inositol phosphate formation in human U373 MG astrocytoma cells: comparison with HeLa cells and brain slices.

1. Histamine (1 mM) induced an accumulation of inositol monophosphate ([3H]-IP1) in the U373 MG human astrocytoma cell line which increased with time in the presence of 30 mM Li+. After a 30 min incubation period with 1 mM histamine [3H]-IP1 was the major product detected (84 +/- 1% of total [3H]-IPx) and was present at a level 11 (+/- 1) fold of basal accumulation. 2. Concentration-response curves for histamine-induced [3H]-IP1 accumulation in U373 MG cells (EC50 5.4 +/- 0.5 microM) were shifted to the right in a parallel fashion by mepyramine (slope of a Schild plot 0.99 +/- 0.08), yielding a Kd for mepyramine of 3.5 +/- 0.3 nM, consistent with the involvement of histamine H1-receptors. 3. The temelastine-sensitive binding of [3H]-mepyramine to a membrane fraction from U373 MG cells was hyperbolic and had a mean Kd of 2.5 +/- 1.0 nM. The maximum amount of temelastine-sensitive binding was 86 +/- 19 pmol g-1 membrane protein. 4. Carbachol also induced [3H]-IP1 accumulation in U373 MG cells, 2.8 (+/- 0.1) fold of basal with 1 mM carbachol, with an EC50 of 48 +/- 8 microM. Pirenzepine shifted carbachol concentration-response curves to the right (slope of Schild plot 0.89 +/- 0.07) giving a Kd for pirenzepine of 0.10 +/- 0.01 microM, suggesting that phosphoinositide hydrolysis in U373 MG cells is mediated by the M3-, rather than the M1-, muscarinic receptor subtype. 5. [3H]-IP1 accumulation induced by both 1 mM histamine and by 1 mM carbachol increased when the Ca2+ concentration of the medium was increased from 'zero' (no added Ca2+) to 0.3 mM. Histamine-stimulated [3H]-IP1 accumulation was further increased, although not so markedly, as the Ca2+ was raised to 4 mM. The same pattern was apparent with histamine-induced accumulations of [3H]-IP2 and [3H]-IP3. In contrast, [3H]-IPx accumulation in response to carbachol increased between 0.3 and 1.3 mM, but thereafter remained unchanged ([3H]-IP1) or declined ([3H]-IP2 and [3H]-IP3). 6. In HeLa cells, [3H]-IP1 accumulations induced by 1 mM histamine and 1 mM carbachol showed the same pattern of Ca2+ dependence and were independent of extracellular Ca2+ above 0.3 mM (histamine) or 1.3 mM (carbachol). The response to carbachol appeared to be mediated by an M3-muscarinic receptor (apparent Kd for pirenzepine 0.09 microM). 7. In cross-chopped slices of guinea-pig cerebral cortex and guinea-pig cerebellum, [3H]-IPI accumulation induced by 1 mM histamine in the presence of 10 mM Li+ increased as the extracellular Ca2+ was increased from 0.3 to 2.5 mM, but a further increase to 4 mM had no further effect. In contrast the response to histamine in rat cerebral cortex increased markedly between 1.3 and 4 mM Ca2+. Accumulations of [3H]-IP1 induced by carbachol in guinea-pig or rat cerebral cortical slices were not increased as extracellular Ca2+ was raised from 0.3 to 4 mM.8. Nimodipine (100 nM) and w-conotoxin (3 microM) had no significant effect on histamine-induced [3H]-IP1accumulation in rat cerebral cortical slices or in U373 MG cells. 9. We conclude that histamine-induced [3H]-IP1 accumulation in U373 MG cells does appear to have a component dependent on the extracellular Ca2+ concentration. The degree of Ca2+-dependence approaches that observed in guinea-pig cerebral cortex but is much less than in rat cerebral cortex.Whether U373 MG cells will be of use as a model system for the apparent Ca2+-entry component observed in guinea-pig or rat brain slices remains to be established.