Regional heterogeneity of benzodiazepine receptors at 37 degrees C: an in vitro study in various regions of the rat brain

The most compelling pharmacological evidence in support of benzo-diazepine (BZD) receptor heterogeneity is derived from the study of the complex interactions of CL 218872 and propyl beta-carboline-3-carboxylate (PCC) with brain BZD receptors. In the present study, we provide evidence to support the hypothesis that intraregional BZD receptor heterogeneity in rat brain is a result of the different conformational states of a single receptor. This hypothesis is based upon the observation that CL 218872 and PCC lose the ability to effectively discriminate BZD receptor subtypes in rat cerebral cortex, hippocampus and pons-medulla at physiological temperature (37 degrees C). Interestingly, both PCC and CL 218872 show higher affinity for BZD receptors in the cerebellum when compared to other brain regions at 37 degrees C. This observation suggests that interregional BZD receptor heterogeneity occurs under physiologically relevant temperatures. We propose that distinct cerebellar and non-cerebellar type BZD receptors exist in vivo while marked differences in the affinity of the type I and type II BZD receptor subtypes postulated by Klepner et al. 1979 may only occur in vitro at 0 degree--4 degree C.     

The effect of temperature on CL 218872 and propyl beta-carboline-3-carboxylate inhibition of [3H]-flunitrazepam binding in rat brain

The competitive inhibition of [³H]-flunitrazepam binding by CL 218872 and propyl beta-carboline-3-carboxylate (PCC), non-benzodiazepine compounds that show differential affinities for benzodiazepine (BZD) receptor subtypes, was studied in the rat cerebral cortex and hippocampus at different temperatures of incubation. The potency of both inhibitors was significantly greater at 0° than at 37°C. The magnitude of temperature induced enhancement of potency may correlate with the pharmacological efficacy of compounds that interact with BZD receptors. Hill slopes for CL 218872 shifted from 0.52 to 0.97 in the cerebral cortex when incubations were performed at 0° and 37°C, respectively. Hill values for PCC changed from 0.68 to 0.93 under similar temperature conditions. These observations suggest the presence of a homogenous population of benzodiazepine receptors at physiological temperatures or the inability of CL 218872 and PCC to distinguish between receptor subtypes at 37°C.     

Modulation of the Electrically Evoked Release of 5-[3H]Hydroxytryptamine from Rat Cerebral Cortex: Effects of Alpidem, CL 218872, and Diazepam

The effect of omega (benzodiazepine)-receptor agonists, antagonists, and inverse agonists on the electrically evoked release of 5-[3H]hydroxytryptamine ([3H]5-HT) was studied in superfused slices of the rat frontal cerebral cortex. The electrically evoked release of [3H]5-HT was enhanced by nanomolar concentrations of diazepam and the selective omega 1-receptor agonists alpidem and CL 218872. The omega 1/omega 2- and omega 1-receptor antagonists flumazenil and CGS 8216, respectively, did not modify the electrically evoked release of [3H]5-HT. The omega 3-receptor agonist Ro 5-4864 and the omega 1-receptor inverse agonist ethyl-beta-carboline-3-carboxylate on their own did not affect the electrically evoked release of [3H]5-HT. On the other hand, the inverse agonist 6,7-dimethoxy-4-ethyl-beta-carboline-3-carboxylic acid methyl ester (DMCM), at micromolar concentrations, inhibited both the spontaneous and the evoked release of [3H]5-HT. The facilitation of the electrically evoked release of [3H]5-HT by diazepam, alpidem, or CL 218872 was potentiated by gamma-aminobutyric acid (GABA). Exposure to flumazenil and CGS 8216 antagonized the facilitation by diazepam, alpidem, or CL 218872 of [3H]5-HT release. The inhibition of the release of [3H]5-HT by DMCM was not modified by exposure to either flumazenil, CGS 8216, or GABA. The inhibitory effect of DMCM was not observed when monoamine oxidase activity was inhibited by pargyline.(ABSTRACT TRUNCATED AT 250 WORDS)     

Two forms of the GABAA receptor distinguished by anion-exchange chromatography

The GABAA receptor complex was solubilized from rat brain membranes in Triton X-100, enriched by 1012-S affinity chromatography, and subjected to DEAE anion-exchange chromatography. Two forms were distinguished by their differential elution during this HPLC with a KCl gradient. They displayed similar [3H]muscimol- and [3H]flunitrazepam-binding characteristics, as well as [3H]flunitrazepam-binding inhibition by CL 218872. Rechromatography of these distinct ionic forms indicated that they were not in dynamic equilibrium during chromatography. Resolution of these two pharmacologically similar populations of GABAA receptor by anion-exchange HPLC suggests that they differ in charge densities, a condition which may reflect differing glycosylation or phosphorylation states of the complex.     

Autoradiographic Localization of [3H]Zolpidem Binding Sites in the Rat CNS: Comparison with the Distribution of [3H]Flunitrazepam Binding Sites

The regional distribution of [3H]zolpidem, a novel imidazopyridine hypnotic possessing preferential affinity for the BZD1 (benzodiazepine subtype 1) receptor, has been studied autoradiographically in the rat CNS and compared with that of [3H]flunitrazepam. The binding of [3H]zolpidem to rat brain sections was saturable, specific, reversible, and of high affinity (KD = 6.4 nM). It occurred at a single population of sites whose pharmacological characteristics were similar to those of the benzodiazepine receptors labeled with [3H]flunitrazepam. However, ethyl-beta-carboline-3-carboxylate and CL 218,872 were more potent displacers of [3H]zolpidem than of [3H]flunitrazepam. The autoradiographic brain distribution of [3H]zolpidem binding sites was qualitatively similar to that previously reported for benzodiazepine receptors. The highest levels of [3H]-zolpidem binding sites occurred in the olfactory bulb (glomerular layer), inferior colliculus, ventral pallidum, nucleus of the diagonal band of Broca, cerebral cortex (layer IV), medial septum, islands of Calleja, subthalamic nucleus, and substantia nigra pars reticulata, whereas the lowest densities were found in parts of the thalamus, pons, and medulla. Comparative quantitative autoradiographic analysis of the binding of [3H]zolpidem and [3H]flunitrazepam [a mixed BZD1/BZD2 (benzodiazepine subtype 2) receptor agonist] in the CNS revealed that the relative density of both 3H-labeled ligands differed in several brain areas. Similar levels of binding for both ligands were found in brain regions enriched in BZD1 receptors, e.g., substantia nigra pars reticulata, inferior colliculus, cerebellum, and cerebral cortex lamina IV. The levels of [3H]zolpidem binding were five times lower than those of [3H]flunitrazepam binding in those brain regions enriched in BZD2 receptors, e.g., nucleus accumbens, dentate gyrus, and striatum. Moreover, [3H]zolpidem binding was undetectable in the spinal cord (which contains predominantly BZD2 receptors). Finally, like CL 218,872 and ethyl-beta-carboline-3-carboxylate, zolpidem was a more potent displacer of [3H]flunitrazepam binding in brain regions enriched in BZD1 receptors than in brain areas enriched in BZD2 receptors. The present data add further support to the view that zolpidem, although structurally unrelated to the benzodiazepines, binds to the benzodiazepine receptor and possesses selectivity for the BZD1 receptor subtype.     

Enhancement of γ-Aminobutyric Acid Binding by Quazepam, a Benzodiazepine Derivative with Preferential Affinity for Type I Benzodiazepine Receptors

We evaluated the effect of the two N-trifluoroethyl benzodiazepines, quazepam and its 2-oxo metabolite SCH 15725, which possess preferential affinity for type I benzodiazepine recognition sites, on the binding of [3H] gamma-aminobutyric acid ([3H]GABA) to rat brain membrane preparations. The study also included compounds such as diazepam and N-desalkyl-2-oxoquazepam (SCH 17514), which have equal affinity for the type I and type II receptor subtypes. Binding of [3H]GABA was studied in frozen-thawed and repeatedly washed cortical membranes incubated in 20 mM KH2PO4 plus 50 mM KCl, pH 7.4, at 4 degrees C in the absence and presence of quazepam or its metabolites. Addition of 10(-6) M quazepam increased by 30% specific [3H]GABA binding; as revealed by Scatchard plot analysis, the effect was due to an increase in the total number of GABA receptors. The effect of quazepam was concentration dependent, and it was shared by its active metabolite SCH 15725. The potency of quazepam and SCH 15725 in enhancing [3H]GABA binding was similar to that of diazepam, whereas CL 218872 and SCH 17514 were less active. Moreover, the [3H]GABA binding-enhancing effect of quazepam was mediated by an occupancy of benzodiazepine receptors, because it was specifically antagonized by 5 X 10(-6) M Ro15-1788.     

Tricyclic pyridones as functionally selective human GABAA alpha 2/3 receptor-ion channel ligands

A series of tricyclic pyridones has been evaluated as benzodiazepine site ligands with functional selectivity for the alpha(3) over the alpha(1) containing subtype of the human GABA(A) receptor ion channel. This investigation led to the identification of a high affinity, functionally selective, orally bioavailable benzodiazepine site ligand that demonstrated activity in rodent anxiolysis models and reduced sedation relative to diazepam.     

The pharmacology of neurosteroidogenesis

In adrenal cortex and other steroidogenic tissues including glial cells, the conversion of cholesterol into pregnenolone is catalyzed by the cytochrome P450_scc located in the inner mitochondrial membrane. A complex mechanism operative in regulating cholesterol access to P450_scc limits the rate of pregnenolone biosynthesis. Participating in this mechanism are DBI (diazepam binding inhibitor), an endogenous peptide that is highly expressed in steroidogenic cells and some of the DBI processing products including DBI 17–50 (TTN). DBI and TTN activate steroidogenesis by binding to a specific receptor located in the outer mitochondrial membrane, termed mitochondrial DBI receptor complex (MDRC). MDRC is a hetero-oligomeric protein: only the subunit that includes the DBI and benzodiazepine (BZD) recognition sites has been cloned. Several 2-aryl-3-indoleacetamide derivatives (FGIN-1-X) with highly selective affinity (nM) for MDRC were synthesized which can stimulate steroidogenesis in mitochondrial preparations. These compounds stimulate adrenal cortex steroidogenesis in hypophysectomized rats but not in intact animals. Moreover, this steroidogenesis is inhibited by the isoquinoline carboxamide derivative PK 11195, a specific high affinity ligand for MDRC with a low intrinsic steroidogenic activity. Some of the FGIN-1-X derivatives stimulate brain pregnenolone accumulation in adrenalectomized-castrated rats. The FGIN-1-X derivatives that increase brain pregnenolone content, elicit antineophobic activity and antagonize punished behavior in the Vogel conflict test in rats. These actions of FGIN-1-X are resistant to inhibition by flumazenil, a specific inhibitor of BZD action in GABA_A receptors but are antagonized by PK 11195, a specific blocker of the steroidogenesis activation via MDRC stimulation. It is postulated that the pharmacological action of FGIN-1-X depends on a positive modulation of the GABA action on GABA_A receptors mediated by the stimulation of brain neurosteroid production.     

Occurrence of "natural" benzodiazepines

There is accumulating evidence that benzodiazepines (BZD)--agents widely used as anxiolytics and hypnotics-could be regarded as "natural" drugs since they have been found in trace amounts also in plants, various tissues of different animal species and even humans. The biosynthesis of such BZD is still unknown and the hypothesis is favoured that they may be of plant origin. Besides diazepam (D) and its major metabolite desmethyldiazepam (DD) several other BZD (e.g. delorazepam, deschloro-diazepam, delormetazepam, isodiazepam, lormetazepam, oxazepam) could be detected. In some cases identification of these compounds was accomplished by specific mass spectrometry (GC-MS) and for quantification various methods have been applied resulting in different concentrations which range for D from about 0.005 to 1 ng/g and for DD from 0.01 to 0.5 ng/g. It is very unlikely that these trace amounts exert any direct pharmacological effects and at the moment only speculations upon their physiological/biological role are possible. Recently BZD-receptor binding activity equivalent to surprisingly high levels of more than 900 ng/ml was found in cerebrospinal fluid of patients with advanced hepatic encephalopathy. As long as the structure of this binding activity has not been elucidated no firm conclusions can be drawn from these findings. If pertinent analytical problems (e.g. drug-free biological material; exact quantification by internal standard techniques) are solved and if the source(s) of BZD are established it might be possible to answer also the critical question whether "endogenous" or "natural" BZD play any (in-) direct role in the regulation of CNS activity.     

Aging: Effect on ex-vivo benzodiazepine binding after a diazepam injection

Ex vivo [³H]flunitrazepam receptor occupation was determined in the brain of young, mature and old male Fischer 344 rats after a single intravenous injection of a low dose of diazepam. The two benzodiazepine receptor subtypes or conformations (BZ₁ and BZ₂) were differentiated by the displacement of [³H]flunitrazepam specific binding with the triazolopyridazine, CL 218,872. The acute diazepam injection decreased ex vivo [³H]flunitrazepam binding in only the senescent rats. The [³H]flunitrazepam binding at both the BZ₁ and BZ₂ receptor or receptor conformation was significantly reduced in the old rats.     

Photoaffinity Labelling of the Benzodiazepine Receptor Compromises the Recognition Site but Not Its Effector Mechanism

When subjected to ultraviolet light flunitrazepam could be irreversibly attached to brain membrane preparations such that the affinity of the benzodiazepine receptor for certain ligands, such as diazepam, becomes markedly reduced. However, the apparent affinity for diazepam is increased by the addition of gamma-aminobutyric acid and sodium chloride, to the same extent in this membrane preparation as in membranes not so pretreated. This observation suggests that photoaffinity labelling of the benzodiazepine receptor with flunitrazepam modifies the recognition characteristics of the receptor but not its effector mechanism.     

Structural elements of the gamma-aminobutyric acid type A receptor conferring subtype selectivity for benzodiazepine site ligands

gamma-aminobutyric acid type A (GABAA) receptors comprise a subfamily of ligand-gated ion channels whose activity can be modulated by ligands acting at the benzodiazepine binding site on the receptor. The benzodiazepine binding site was characterized using a site-directed mutagenesis strategy in which amino acids of the alpha5 subunit were substituted by their corresponding alpha1 residues. Given the high affinity and selectivity of alpha1-containing compared with alpha5-containing GABAA receptors for zolpidem, mutated alpha5 subunits were co-expressed with beta2 and gamma2 subunits, and the affinity of recombinant receptors for zolpidem was measured. One alpha5 mutant (bearing P162T, E200G, and T204S) exhibited properties similar to that of the alpha1 subunit, notably high affinity zolpidem binding and potentiation by zolpidem of GABA-induced chloride current. Two of these mutations, alpha5P162T and alpha5E200G, might alter binding pocket conformation, whereas alpha5T204S probably permits formation of a hydrogen bond with a proton acceptor in zolpidem. These three amino acid substitutions also influenced receptor affinity for CL218872. Our data thus suggest that corresponding amino acids of the alpha1 subunit, particularly alpha1-Ser204, are the crucial residues influencing ligand selectivity at the binding pocket of alpha1-containing receptors, and a model of this binding pocket is presented.     

Isoliquiritigenin, a chalcone compound, is a positive allosteric modulator of GABAA receptors and shows hypnotic effects

Isoliquiritigenin (ILTG) is a chalcone compound and has valuable pharmacological properties such as antioxidant, anti-inflammatory, anticancer, and antiallergic activities. Recently, the anxiolytic effect of ILTG has been reported; however, its action mechanism and hypnotic activity have not yet been demonstrated. Therefore, we investigated the hypnotic effect and action mechanism of ILTG. ILTG significantly potentiated the pentobarbital-induced sleep in mice at doses of 25 and 50 mg/kg. The hypnotic activity of ILTG was fully inhibited by flumazenil (FLU), a specific gamma-aminobutyric acid type A (GABA_A)–benzodiazepine (BZD) receptor antagonist. The binding affinity of ILTG was 0.453 μM and was found to be higher than that of the reference compound, diazepam (DZP, 0.012 μM). ILTG (10⁻⁵ M) potentiated GABA-evoked currents to 151% of the control level on isolated dorsal raphe neurons. ILTG has 65 times higher affinity for GABA_A–BZD receptors than DZP, and the dissociation constant for ILTG was 4.0 × 10⁻¹⁰ M. The effect of ILTG on GABA currents was blocked by 10⁻⁷ M FLU and ZK-93426. These results suggest that ILTG produces hypnotic effects by positive allosteric modulation of GABA_A–BZD receptors.     

Inhibitors of peripheral-type benzodiazepine receptors present in human urine and plasma ultrafiltrates

Several endogenous substances that inhibit central-type benzodiazepine (BZD) receptor binding have recently been identified. We have found that ultrafiltrates of human uremic plasma, normal plasma, and urine contain competitive inhibitors of peripheral-type benzodiazepine receptors. Using urine as source, we have partially purified a peripheral-type BZD receptor inhibitor(s) by adsorption to and selective elution from small octadecyl-silane (Sep-pak) columns and thin layer chromatography. The inhibitor has a 125-fold greater affinity for peripheral-type than central-type BZD receptors and has been purified 8000-fold from urine.     

Heterogeneity in the Allosteric Interaction Between the γ-Aminobutyric Acid (GABA) Binding Site and Three Different Benzodiazepine Binding Sites of the GABAA/Benzodiazepine Receptor Complex in the Rat Nervous System

In the present communication we have investigated the allosteric coupling between the gamma-aminobutyric acidA (GABAA) receptor and the pharmacologically different benzodiazepine (BZD) receptor subtypes in membranes from various rat nervous system regions. Two types of BZD receptors (type I and type II) have been classically defined using CL 218.872. However, using zolpidem, three different BZD receptors have been identified by binding displacement experiments in membranes. These BZD receptor subtypes displayed high, low, and very low affinity for zolpidem. The distribution of the high- and low-affinity binding sites for zolpidem was similar to that of type I and type II subtypes in cerebellum, prefrontal cortex, and adult cerebral cortex. On the other hand, the very-low-affinity binding site was localized in relative high proportion in spinal cord, hippocampus, and newborn cerebral cortex and, to a minor extent, in superior colliculus. The allosteric coupling between the GABAA receptor and the BZD receptor subtypes was different. The high- and low-affinity binding sites for zolpidem seemed to have a similar high degree of coupling, except in spinal cord. On the other hand, the very-low-affinity binding site for zolpidem displayed a low degree of coupling with the GABAA receptor. These results seem to indicate that the different efficacy of GABA in enhancing the [3H]flunitrazepam binding could be due to the different BZD receptor subtypes present in the GABAA/BZD receptor complex and, moreover, led us to speculate that the low GABA efficacy found in membranes from spinal cord, hippocampus, and newborn cerebral cortex might be due to the presence in relatively high proportion of the very-low-affinity binding site for zolpidem.     

CL 218,872 Binding to Benzodiazepine Receptors in Rat Spinal Cord: Modulation by γ-Aminobutyric Acid and Evidence for Receptor Heterogeneity

The binding of the triazolopyridazine CL 218,872 to central benzodiazepine receptors identified with [3H]Ro 15-1788 was studied in extensively washed homogenates of rat spinal cord and cerebral cortex. CL 218,872 displacement curves were shallow in both spinal cord (nH = 0.67) and cortex (nH = 0.54), suggesting the presence of type 1 and type 2 benzodiazepine receptors in both tissues. CL 218,872 had lower affinity in spinal cord (IC50 = 825 nM) than cortex (IC50 = 152 nM), possibly reflecting the presence of fewer type 1 sites in the cord. Activating gamma-aminobutyric acid (GABA) receptors with 10 microM muscimol resulted in a two- to threefold increase in CL 218,872 affinity in both tissues without changes in the displacement curve slope. This indicates that GABA enhances CL 218,872 affinity for both type 1 and type 2 sites in both spinal cord and cerebral cortex.     

A novel pyrazoloquinoline that interacts with brain benzodiazepine receptors: characterization of some in vitro and in vivo properties of CGS 9896

The novel pyrazoloquinoline, CGS, 9896, was a potent inhibitor of specific [3H]-flunitrazepam binding in several brain regions with subnanomolar KI values. The inhibition of [3H] propyl beta-carboline-3-carboxylate ([3H]-PCC-) binding by CGS 9896 was enhanced by gamma-aminobutyric acid (GABA) but not by chloride ion. GABA enhancement of CGS 9896 inhibition of [3H]-PCC binding predicts this compound has benzodiazepine (BZD) agonist-type activity. Behavioral studies support this prediction. CGS 9896 was found to protect mice against bicuculline and metrazol induced seizure at doses that did not induce ataxia or sedation. CGS 9896 may represent a class of compounds with potential therapeutic value. The high affinity of this non-BZD compound suggests that CGS 9896 may also be of value as a high affinity ligand for the continued study of BZD receptors.     

Benzodiazepine receptor sites in the chick optic lobe: Development and pharmacological characterization

To investigate the, interaction between -aminobutyric acid (GABA) and benzodiazepine (BZD) receptor sites during development, the time-course of appearance of flunitrazepam (FNZ) binding sites and their pharmacological characterization were studied in developing chick optic lobe. At the earliest stage examined, embryonic day (Ed) 12, the receptor density was 30.9 % (0.05±0.01 pmol/mg protein) of that found in the chick optic lobes of adult chicks. The adult value was achieved on Ed 16 (0.16±0.01 pmol/mg protein). After this stage there was a sharp and transient increase in specific [³H]FNZ binding of about two-fold reaching a maximal value between hatching and the postnatal day (pnd) 2 (0.33±0.01 pmol/mg protein). Scatchard analysis at different stages of development revealed the presence of a single population of specific FNZ binding sites. The increase in [³H]FNZ binding during development was due to a large number of binding sites while their affinity remained unchanged. Competition experiments in the chick optic lobe revealed that the order of potency for displacement of specific [³H]FNZ binding paralleled the pharmacological potency of the BZDs tested. The IC₅₀ s for clonazepam, flunitrazepam, Ro 15-1788 and chlordiazepoxide were 3.02, 4.30, 0.32, and 4778.64 nM respectively. Ro 5-4864, a potent inhibitor of BZD binding to peripheral tissues, had no effect on specific [³H]FNZ binding indicating that only central BZD binding sites are present in the chick optic lobe. The peak of maximal expression of BZD receptor sites precedes in 5–6 days the peak of GABA receptor sites indicating a precocious development of BZD receptor sites. The different appearance of both peaks may represent important events during development probably related to synaptogenesis.     

Inhibition of rat brain adenylate cyclase activity by benzodiazepine through the effects on Gi and catalytic proteins

The effect of benzodiazepines on adenylate cyclase system was examined in rat brain. Micromolar concentrations of diazepam inhibited the enzyme activity in synaptic membranes in dose- and time-dependent manners. The inhibitory effect of diazepam was more evident on the enzyme activity in the presence of guanylyl-5'-imidodiphosphate (GppNHp) or NaF-AlCl3 than on that in the basal state. In the pertussis toxin-treated membranes, the effect of diazepam in the presence of GppNHp or NaF-AlCl3 was markedly suppressed. In addition, other benzodiazepines, such as medazepam, flurazepam, flunitrazepam, and clonazepam, had similar effects to those of diazepam, whereas Ro15-1788, an antagonist of a high affinity receptor in the central nervous system, had no effect on adenylate cyclase activity and did not antagonize the effect of diazepam. These findings indicate that benzodiazepines inhibit rat brain adenylate cyclase activity through the effects on both a low affinity benzodiazepine receptor coupled with the inhibitory GTP-binding regulatory protein (Gi) and catalytic protein.     

The mobile receptor hypothesis and "cooperativity" of hormone binding. Application to insulin.

The mobile receptor hypothesis has been proposed to describe the process by which hormone receptor binding initiates a biological response; it states that receptors, which can diffuse independently in the plane of the membrane, reversibly associate with effectors to regulate their activity. The affinity for effector is greater when the receptor is occupied by hormone. A mathematical expression of the mobile receptor hypothesis is used to show that: (1) The predicted kinetics of hormone receptor binding may be indistinguishable from "negative cooperativity." (2) Receptor occupancy and biological response may be coupled in a non-linear fashion. By choosing specific parameters, most of the existing data on insulin binding and biological responses can be explained in terms of the mobile receptor hypothesis. Thus, the following are easily explained: (1) A single homogeneous receptor may appear kinetically to be composed of two classes (of high and low affinity) of receptors. (2) Occupancy of the apparent class of high affinity receptors is related linearly to the biological response. (3) The same receptor in different tissues may appear to have different affinity. (4) The binding of different biologically active insulin analogues may exhibit different degrees of "cooperativity." These considerations may also be pertinent to interpretations of other hormone-receptor systems and of various ligand-macromolecule interactions.