Affinity of 3-acyl substituted 4-quinolones at the benzodiazepine site of GABA(A) receptors

The finding that alkyl 1,4-dihydro-4-oxoquinoline-3-carboxylate and N-alkyl-1,4-dihydro-4-oxoquinoline-3-carboxamide derivatives may be high-affinity ligands at the benzodiazepine binding site of the GABA(A) receptor, prompted a study of 3-acyl-1,4-dihydro-4-oxoquinoline (3-acyl-4-quinolones). In general, the affinity of the 3-acyl derivatives was found to be comparable with the 3-carboxylate and the 3-carboxamide derivatives, and certain substituents (e.g., benzyl) in position 6 were again shown to be important. As it is believed that the benzodiazepine binding site is situated between an alpha- and a gamma-subunit in the GABA(A) receptor, selected compounds were tested on the alpha(1)beta(2)gamma(2s), alpha(2)beta(2)gamma(2s) and alpha(3)beta(2)gamma(2s) GABA(A) receptor subtypes. The 3-acyl-4-quinolones display various degrees of selectivity for alpha(1)- versus alpha(2)- and alpha(3)-containing receptors, and high-affinity ligands essentially selective for alpha(1) over alpha(3) were developed.     

Hormonal regulation of peripheral-type benzodiazepine receptors

Central benzodiazepine (BZ) receptors are located only in the central nervous system and mediate the clinical effects obtained by various BZs. In addition, there is another receptor that binds BZs with different drug specificities, which is located mainly on the outer mitochondrial membrane of various peripheral tissues. Peripheral BZ receptors (PBR) are composed of three subunits: an isoquinoline binding site, a voltage-dependent anion channel, and an adenine nucleotide carrier, with molecular weights of 18, 32, and 30 kDa, respectively. Complementary DNA of the isoquinoline binding subunit has been cloned in rat, calf, and human. The major role of PBR is in the regulation of steroid biosynthesis. Various PBR ligands stimulate the conversion of cholesterol into pregnenolone and the production of steroid hormones. The naturally occurring diazepam-binding inhibitor stimulates in vivo steroidogenesis via binding to PBR. In the female, PBR density is increased in rat and human ovary proportional with greater cell maturation and differentiation. In the male, testosterone modulates PBR density in the genital tract. These results show the strong relationship between PBR and the endocrine system.     

Molecular mechanisms of peripheral benzodiazepine receptors

Peripheral-type benzodiazepine receptors were identified initially as binding sites in peripheral tissues with markedly different drug specificity than the central type receptors. The density of peripheral receptors varies greatly among tissue with selective localization within organs. Steroid producing areas of glands, such as the adrenal, testes and ovary, are highly enriched in these receptors. Intracellular localizations provide further insight into function with peripheral receptors largely if not exclusively associated with outer membranes of mitochondria. Purification of the peripheral receptor protein from rat kidney mitochondria reveals two apparent subunits with molecular weights of about 30 and 18 kD respectively. This complex is functionally intact as determined by its ability to reversibly bink PK-11195 Ro5-4864, and PK-14105 with high affinity and specificity.Acknowledgements: Supported by USPHS grant DA-00266, Research Scientist Award DA-00074 to S.H.S. and a gift of the Bristol Myers Company.Special issue dedicated to Dr. Erminio Costa.     

Brain benzodiazepine receptors increase after chronic ethyl-β-carboline-3-carboxylate

Rats were treated with repeated intraventricular injections of ethyl-3-carboline-3-carboxylate (β-CCE) (10 ug/rat, twice daily for 8 days), 36 h after the last injection, the total number of H-diazepam binding sites was increased in the cerebral cortex, cerebellum and hippocampus by 63, 51 and 38%, respectively. On the other hand, there were no significant differences in the dissociation constants (K_D) between β-CCE and solvent treated rats. In contrast, chronic β-CCE administration failed to change the number of the apparent affinity of H-β-CCE binding sites in all the brain areas examined. The results suggest that β-CCE is an antagonist at the ³H- diazepam binding sites.     

Soluble benzodiazepine receptors: Gabaergic regulation

Benzodiazepine receptor binding has been measured in soluble brain extracts with ³H-flunitrazepam as a ligand. Binding to soluble receptors is enhanced by GABAergic agonists with potencies and maximal augmentation essentially the same as on membrane bound benzodiazepine receptors. The GABA induced increase of binding to soluble receptors is reversed by the GABA antagonist bicuculline.     

Peripheral benzodiazepine receptors and mitochondrial function

For over 20 years, numerous investigations have focused on elucidating the function of the peripheral benzodiazepine receptor (PBR). This relatively small protein (18kDa) arouses great interest because of its association with numerous biological functions, including the regulation of cellular proliferation, immunomodulation, porphyrin transport and heme biosynthesis, anion transport, regulation of steroidogenesis and apoptosis. Although the receptor was first identified as a binding site for the benzodiazepine, diazepam, in peripheral organ systems, the PBR was subsequently found to be distinct from the central benzodiazepine receptor (CBR) in terms of its pharmacological profile, structure, subcellular localization, tissue distribution and physiological functions. The PBR is widely expressed throughout the body, with high densities found in steroid-producing tissues. In contrast, its expression in the CNS is restricted to ependymal cells and glia. The benzodiazepine Ro5-4864 and the isoquinoline carboxamide PK11195 exhibit nanomolar affinity for the PBR, and are the archtypic pharmacological tools for characterizing the receptor and its function. Primary among these functions are its regulation of steroidogenesis and apoptosis, which reflect its mitochondrial localization and involvement in oxidative processes. This review will evaluate the basic pharmacology and molecular biology of the PBR, and highlight its role in regulating mitochondrial function, the mitochondrial transmembrane potential and its sensitivity to reactive oxygen species (ROS), and neurosteroid synthesis, processes relevant to the pathogenesis of a number of neurological and neuropsychiatric disorders.     

Affinities of gidazepam and its analogs for mitochondrial benzodiazepine receptors

Mitochondrial benzodiazepine receptors (MBRs) participate in many physiological processes, such as calcium flow regulation, proliferative and respiratory cell functions, mitochondrial steroidogenesis and adaptational reactions to stress. We have found that the selective anxiolytic gidazepam has a higher affinity for CNS MBRs as compared to central benzodiazepine receptors. The ability of gidazepam to bind to MBRs probably underlies a wide spectrum of its pharmacological effects. We have studied affinities of gidazepam analogs for CNS MBRs in search for the ligands possessing higher affinity and selectivity. The experiments were carried out with male Wistar rats weighing between 200-220 g. Affinities of the investigated compounds were assessed on their ability to displace radioligand Ro5-4864 from its specific binding sites on MBRs of rat brain. Within the series of tested compounds three substances comparable on affinity with Ro5-4864 were found. Experimental results have shown that the presence of chlorine atom in o-position of 5-phenyl substituent leads to a 10 to 15-fold increase in affinity for CNS MBRs. We have also found that the essential contribution in affinity of the investigated series is brought by lipophilicity of substituent in IN-position. Our data may be useful in design and synthesis of novel potent selectively acting ligands of CNS MBRs.     

Affinity of beta-carbolines on rat brain benzodiazepine and opiate binding sites

The affinity of beta-carbolines, which may be formed in the body, to benzodiazepine and opiate receptors was studied by measuring their ability to inhibit the binding of [3H]-flunitrazepam and [3H]-dihydromorphine on rat brain synaptosomal membranes. All "aromatized" beta-carbolines studied (norharmane, harmane and 6-methoxyharmane) inhibited the specific binding of [3H]-flunitrazepam in micromolar concentrations, dihydro-beta-carbolines (6-methoxyharmalan, harmalol) were less potent, while all tetrahydro-beta-carbolines showed very low affinity. 6-Hydroxytetrahydroharmane, which is formed by condensation 5HT with acetaldehyde, inhibited [3H]-dihydromorphine binding in micromolar concentration, while norharmane and tetrahydro-beta-carbolines without OH-group showed little affinity. beta-Carbolines are the most potent known natural benzodiazepine receptor ligands. Because they are formed after alcohol drinking, their effects on benzodiazepine and opiate receptors may be connected with alcohol dependence although some beta-carbolines may inhibit 5HT uptake in still lower concentrations.     

Modulating effect of cerulein on benzodiazepine receptors

Subcutaneous administration of caerulein (100-500 micrograms/kg) significantly reduced the development of picrotoxin (8 mg/kg) seizures in male mice. The same doses of caerulein inhibited 3H-flunitrazepam binding in in vivo experiments. Proglumide, an antagonist of cholecystokinin receptors, in low dose (5 mg/kg) potentiated the effects of caerulein (100 micrograms/kg), whereas the administration of proglumide in high dose (25 mg/kg) reduced the action of caerulein on 3H-flunitrazepam binding and picrotoxin seizures. Caerulein (5-1000 nM) decreased 3H-flunitrazepam binding in in vitro experiments only after supplementation of the binding medium with 120 mM NaCl and 5mM KCl. The results suggest the possible interaction of caerulein with chloride ionophor. It seems probable that the direct interaction of caerulein with chloride ionophor in involved in the inhibitory effect of caerulein on picrotoxin seizures and 3H-flunitrazepam binding.     

Characterization of benzodiazepine receptors with fluorescent ligands

Fluorescein conjugates of the high-affinity benzodiazepine receptor ligands Ro 15-1788 and Ro 7-1986 were synthesized. The binding of these fluorescent ligands (BD 621 and BD 607) to benzodiazepine receptors was characterized by direct fluorescence measurement. Both the equilibrium dissociation constants (KD) of BD 621 and BD 607 and the maximum number of binding sites (Bmax) estimated by fluorescence monitoring were consistent with values obtained by using radioligand binding techniques. The binding of BD 621 and BD 607 assessed by fluorescence measurement was reversible, abolished by photoaffinity labeling with Ro 15-4513, and unaffected by a variety of substances that do not bind to benzodiazepine receptors. The potencies of chemically diverse benzodiazepine receptor compounds to inhibit fluorescent ligand binding were highly correlated (r = 0.94, P less than 0.001), with potencies obtained from radioligand binding techniques. These findings demonstrate the feasibility of using direct fluorescence measurement techniques to quantitate ligand-receptor interactions.     

Antagonism of benzodiazepine receptors by beta carbolines

A number of beta carbolines were found to interact at brain benzodiazepine sites $\text{in vitro}$. The compounds we evaluated had affinities in the low nanomolar range and had Hill slopes less than unity. In addition to being potential antagonists at benzodiazepine receptors, they may specifically label the BZ₁ site. After intravenous administration, these compounds antagonized benzodiazepine actions in the cat spinal cord and in a mouse free behavioral model. Aspects of this antagonism and their proposed role as endogenous benzodiazepine ligands in brain are discussed.     

3-Alkyl- and 3-amido-isothiazoloquinolin-4-ones as ligands for the benzodiazepine site of GABA(A) receptors

Based on a pharmacophore model of the benzodiazepine binding site of the GABA(A) receptors, developed with synthetic flavones and potent 3-carbonylquinolin-4-ones, 3-alkyl- and 3-amido-6-methylisothiazoloquinolin-4-ones were designed, prepared and assayed. The suggestion that the interaction between the hydrogen bond donor site H1 with the 3-carbonyl oxygen in 3-carbonylquinolin-4-ones can be replaced by an interaction between H1 and N-2 in the isothiazoloquinolin-4-ones, was confirmed. As with the 3-carbonylquinolin-4-ones, the length of the chain in position 3 is critical for an efficient interaction with the lipophilic pockets of the pharmacophore model. The most potent 3-alkyl derivative, 3-pentyl-6-methylisothiazoloquinolin-4-one, has an affinity (K(i) value) for the benzodiazepine binding site of the GABA(A) receptors of 13 nM. However, by replacing the 3-pentyl with a 3-butyramido group an even more potent compound was obtained, with a K(i) value of 2.8 nM, indicating that the amide function facilitates additional interactions with the binding site.     

Affinity chromatography of estrogen receptors on diethylstilbestrol-agarose

Diethylstilbestrol was coupled to epoxy-activated agarose yielding an affinity resin which is highly efficient for the isolation of estrogen receptors. This resin, diethylstilbestrol-agarose (DES-agarose), bound two proteins (Mr = 50,000 and 65,000) from rabbit uterine cytosol that show a specific interaction with estradiol. A two step procedure--adsorption on DES-agarose followed by a selective elution with p-sec-amylphenol and NaSCN, yielded highly purified estrogen receptors which can be used in the studies of estradiol-receptor interactions with other cell constituents.     

Demonstration of [3H] diazepam binding to benzodiazepine receptors in vivo.

Benzodiazepine receptors were labeled with [³H] diazepam following intravenous injection in rats. Binding of [³H] diazepam $\text{in}$$\text{vivo}$ to rat forebrain membranes was displaceable by co-injection of clonazepam or the pharmacologically active enantiomers of two benzodiazepines, B9 and B10, but was not displaced by equal doses of the pharmacologically in-active enantiomers. Binding of [³H] diazepam $\text{in}$$\text{vivo}$ was bserved in kidney, liver, and abdominal muscle, but was not stereospecifically diplaced in any peripheral tissue studied. The regional distribution of benzodiazepine receptors in brain was uneven, with specific [³H] diazepam binding being highest in the cerebral cortex and lowest in the ponsmedulla. Preliminary studies of the subcellular distribution of [³H] diazepam binding demonstrated highest specific binding to synaptosomal membranes. These data demonstrate the feasibility of labeling benzodiazepine receptors in rat brain $\text{in}$$\text{vivo}$.     

Evidence for the pharmacological relevance of benzodiazepine receptors to anticonvulsant activity

Each of a series of benzodiazepines was found to be effective in preventing convulsions evoked by intermittent photic stimulation of epileptic chickens. There was a high correlation between the anticonvulsant potencies (mean effective dosages) and the affinity of the agents for the putative benzodiazepine receptor as measured by displacement of [3H]diazepam from binding sites on chicken synaptosomal membranes. This correlation in a genetic model of epilepsy provides further evidence that benzodiazepines exert their anticonvulsant effects by interacting with the benzodiazepine receptor.     

Searching for endogenous ligand(s) of central benzodiazepine receptors

The discovery, in 1977, of the specific binding sites for benzodiazepines in the brain of mammals, notably in man, lends support to the possible existence of endogenous compounds acting as natural ligands of these sites. At present, more than a dozen of molecules with the capacity to displace bound [³H]benzodiazepines from their specific sites have been extracted from the brain of several species (rat, pig, bovine), the cerebrospinal fluid and urine of man. These molecules are proteins, peptides, purines, β-carbolines and exhibit (some) pharmacological properties similar or opposite to those of benzodiazepines. The most recent data concerning benzodiazepine receptors suggest that the endogenous ligand would be, if it exists, a benzodiazepine-like compound (agonist) with an indolic structure.     

Characterization of benzodiazepine receptors with a fluorescence-quenching ligand

A conjugate of the high affinity benzodiazepine receptor ligand Ro 15-1788 and the fluorescent 7-nitrobenz-2-oxa-1,3-diazol-4-yl (NBD) moiety was synthesized. This novel compound (BD 623) exhibited excitation and emission maxima at 486 and 542 nm, respectively, and possessed fluorescent properties that are dependent upon the polarity of its environment. BD 623 bound reversibly to benzodiazepine receptors in the central nervous system with an apparent affinity (K(i) 5.7 nM) comparable to the parent imidazobenzodiazepine (K(d) 2.8 nM). Addition of BD 623 to a suspension of brain membranes resulted in a time-dependent quenching of its fluorescence. Fluorescence quenching of this compound was readily reversed by specific benzodiazepine receptor ligands but not by a variety of other substances. Moreover, inactivation of benzodiazepine receptors by photoaffinity labeling with Ro 15-4513 resulted in a reduction in the fluorescence quenching of BD 623 consistent with the reduction in density of benzodiazepine receptors measured using a radioreceptor assay. Monitoring of fluorescence/dequenching of BD 623 in real time permitted a quantitative characterization of the ligand-receptor interaction, with both the K(d) of BD 623 (13.9 nM) and K(i) of Ro 15-1788 (5.7 nM) comparable with the estimates obtained using radioreceptor techniques. These results indicate that application of fluorescence quenching techniques with BD 623 could prove a useful adjunct for the study of benzodiazepine receptors. BD 623 may serve as a prototype for the development of other fluorescent ligands to study ligand-receptor interactions.     

A nonequilibrium binary elements-based kinetic model for benzodiazepine regulation of GABAA receptors

Ion channels, like many other proteins, are composed of multiple structural domains. A stimulus that impinges on one domain, such as binding of a ligand to its recognition site, can influence the activity of another domain, such as a transmembrane channel gate, through interdomain interactions. Kinetic schemes that describe the function of interacting domains typically incorporate a minimal number of states and transitions, and do not explicitly model interactions between domains. Here, we develop a kinetic model of the GABA_A receptor, a ligand-gated ion channel modulated by numerous compounds including benzodiazepines, a class of drugs used clinically as sedatives and anxiolytics. Our model explicitly treats both the kinetics of distinct functional domains within the receptor and the interactions between these domains. The model describes not only how benzodiazepines that potentiate GABA_A receptor activity, such as diazepam, affect peak current dose–response relationships in the presence of desensitization, but also their effect on the detailed kinetics of current activation, desensitization, and deactivation in response to various stimulation protocols. Finally, our model explains positive modulation by benzodiazepines of receptor currents elicited by either full or partial agonists, and can resolve conflicting observations arguing for benzodiazepine modulation of agonist binding versus channel gating.