In vitro and in vivo inhibition by zopiclone of benzodiazepine binding to rodent brain receptors.

Up to now the only drugs known to be able to inhibit the binding of benzodiazepines to rodent brain receptors are members of this chemical family.Zopiclone (RP 27 267), a new drug with a pharmacological profile similar to that of chlordiazepoxide and nitrazepam but entirely different chemically from benzodiazepines, has been tested for its ability to inhibit benzodiazepine binding. $\text{In vitro}$ and $\text{in vivo}$ studies have shown that zopiclone is able to inhibit the binding of [³H] diazepam and [³H] flunitrazepam to brain receptors. The potency of zopiclone is quite comparable to that of diazepam and nitrazepam $\text{in vitro}$ and to that of chlordiazepoxide $\text{in vivo}$.These results confirm the pharmacological similarities existing between zopiclone and the benzodiazepines.     

Interactions of lindane,toxaphene and cyclodienes with brain-specific t-butylbicyclophosphorothionate receptor

Three major classes of chlorinated hydrocarbon insecticides, $\text{i}$. $\text{e}$., the lindane/hexachlorocyclohexane, toxaphene and aldrin/dieldrin types, are potent, competitive, and stereospecific inhibitors of $\text{t}$-butylbicyclophosphorothionate (TBPS) binding to brain-specific sites, thereby indicating an action at the γ-aminobutyric acid (GABA)-regulated chloride channel. The most inhibitory and toxic of four isomers of hexachlorocyclohexane is lindane and of >188 components of toxaphene is 2,2,5-$\text{endo}$, 6-$\text{exo}$, 8,9,9,10-octachlorobornane. 12-Ketoendrin (IC₅₀ = 36 nM) is twice as active as the most potent previously known inhibitor of TBPS binding and it is also the most inhibitory and toxic of 22 cyclodienes examined. Within each of these three series of polychlorocycloalkanes the mammalian toxicity is closely related to the potency for inhibition of TBPS binding. A modified receptor assay incorporating liver microsomes and reduced nicotinamide-adenine dinucleotide phosphate compensates in part for oxidative detoxification and bioactivation. Specific TBPS binding is reduced in a dose-dependent manner in dieldrin-poisoned rats. DDT, mirex and kepone are not inhibitors of TBPS binding, even at 10 μM.     

The influence of temperature and gamma-aminobutyric acid on benzodiazepine receptor subtypes in the hippocampus of the rat

The influence of GABA on the affinity of flunitrazepam (FLU) for benzodiazepine receptor subtypes (type I and II) was studied by measurement of the competitive inhibition of [³H]FLU and [³H]propyl beta-carboline-3-carboxylate ([³H]PCC) binding. When assays were carried out at 0°C using a low concentration (0.040 nM) of [³H]PCC so that the type I receptors were selectively labelled, no significant effect of GABA (10^?4 M) on the $\text{FLU}\text{[}{}^3\text{H]}\text{PCC}$ competition curve was detected. In contrast, when assays were carried out at 0°C using [³H]FLU or a high concentration of [³H]PCC to achieve [³H]ligand receptor occupancy of both type I and type II receptors, GABA (10^?4 M) caused a significant increase in the affinity of FLU as measured by $\text{FLU}\text{[}{}^3\text{H]}\text{FLU}$ and $\text{FLU}\text{[}{}^3\text{H]}\text{PCC}$ competition experiments. Collectively, these data suggest that the influence of GABA on benzodiazepine receptor binding is mediated, primarily, by the type II receptor. It was also noted that the $\text{PCC}\text{[}{}^3\text{H]}\text{FLU}$ competition curve had a Hill coefficient of approximately 1 at 37°C as compared to the results of experiments at 0°C during which a Hill coefficient of approximately 0.7 was calculated.     

Gamma amino butyric acid (GABA) levels in hypophyseal stalk plasma of rats

To determine the possible physiologic contribution of GABA to the tonic hypothalamic inhibition of adenohypophyseal prolactin secretion, we compared GABA levels in hypophyseal stalk plasma with those found in the peripheral circulation. Hypophyseal stalk blood was collected $\text{via}$ a parapharyngeal approach from 8 urethane anesthetized diestrus rats. Peripheral blood was collected simultaneously from the external jugular vein of the same rat at a rate similar to hypophyseal stalk blood flow. Blood samples resulting from a single 4 hr collection per animal were centrifuged, and the plasma stored frozen before ethanol extraction and assay using a radioreceptor method. GABA levels in hypophyseal stalk plasma ($\text{909±171}\text{pmol/ml}\text{;}\text{X}\text{±}\text{S.E.M.}$) were not significantly higher than levels in peripheral plasma (845±182; p>0.05), indicating little or no secretion of GABA by the median eminence.     

Putative endogenous ligands for the benzodiazepine receptor.

The recent discovery of pharmacologically relevant, high affinity, stereospecific binding sites for the benzodiazepines in the central nervous system (CNS) has rekindled investigations concerning the mechanism of action of these drugs. It has become increasingly clear that elucidation of benzodiazepine action will provide new and important insights into the neurochemical substances of seizure activity, centrally mediated muscle relaxation and anxiety, three major actions of this class of drugs.The existence of a functional receptor for the benzodiazepines, compounds not present $\text{in vivo}$, suggests that endogenous substances exist that serve as natural substrates for this receptor. Furthermore, the characterization of endogenous benzodiazepine receptor ligands affords an opportunity to determine the neurochemical mechanisms underlying the pharmacologic and behavioral effects manifested by the benzodiazepines.Using receptor binding methodology to assay tissue extracts for [³H] diazepam binding inhibitory activity, putative endogenous ligands for the benzodiazepine receptor have been isolated and identified as the purine nucleosides. Compounds such as inosine and hypoxanthine exhibit competitive inhibition of [³H] diazepam binding. The low affinity purinergic inhibition of diazepam binding is consistent with their $\text{in vivo}$ concentrations. Distinct structure-activity relationships exist for the purines with subtle structural alterations having marked effects on diazepam binding inhibitory potency. The methylxanthine stimulants, caffeine, theophylline, and theobromine, also competitively inhibit diazepam binding, suggesting that some of their actions may be mediated by the benzodiazepine receptor.The purines also have “benzodiazepine-like” pharmacologic properties, since they have been shown to antagonize pentylenetetrazol induced seizures in mice in a dose dependent manner. Neurophysiologic studies have also shown that iontophoresis of inosine on cultured mouse primary neurons produce neurotransmitter like effects. Furthermore, these effects are similar to those observed with flurazepam, a finding that provides additional evidence for the “benzodiazepine-like” properties of the purines.The preliminary studies outlined below indicate that the purines are good candidates as putative endogenous ligands for the benzodiazepine receptor and provide a foundation for future studies that concern the homeostatic mediation of seizure activity and anxiety.     

Benzodiazepine receptors': Correlation with pharmacological responses in living animals

The data relating the pharmacological activities of benzodiazepines to $\text{in vivo}$ occupancy of their receptor sites is reviewed, in the light of the complexity of evaluating pharmacodynamic parameters in living animals. Methodological problems in the measurement of $\text{in vivo}$ receptor occupancy and species differences in benzodiazepine metabolism are considered in detail.     

GABA mediated excitatory responses on Aplysia neurons

γ-Aminobutyric acid (GABA), a known inhibitory neurotransmitter in mammals, can elicit two different types of excitatory response in the nervous system of the marine mollusc, $\text{Aplysia}$. These responses are depolarizing when GABA is applied ionophoretically, and result from either an increase in membrane conductance to Na⁺ or a decrease in conductance to K⁺. In addition, GABA on other neurons causes an inhibitory response similar to that commonly found in other preparations. Although not all neurons have GABA receptors, identified single cells consistently have the same type of response. These observations suggest the possibility that GABA may function in at least some preparations as an excitatory neurotransmitter in addition to its documented inhibitory function.     

Studies on bicuculline binding sites on neuronal membrane using fluorescent antibody technique: Comparative binding of gaba and bicuculline

Highly purified fluorescent labelled anti-bicuculline antibodies were used to mark bicuculline binding sites in cerebral cortex of monkey brain. Specific binding of bicuculline could be demonstrated in the synaptosomal fraction, when bicuculline was added both $\text{in vitro}$ and $\text{in vivo}$. Addition of γ-aminobutyric acid (GABA) to the bicucullinised membrane led to a decrease in fluorescence indicating same receptor loci and establishing GABA-bicuculline antagonism at a molecular level.     

Antinociceptive and hypothermic effects of trimethyltin

Trimethyltin (TMT) induced a dose-dependent antinociceptive and hypothermic effect in mice. Antinociception was not attenuated by naloxone but was reversed by atropine. TMT, however, was ineffective in displacing (³H)-QNB binding $\text{in vitro}$ and did not affect (³H)-QNB binding or acetylcholinesterase activity after $\text{in vivo}$ administration. The ethyl ester of nipecotic acid, a specific inhibitor of synaptosomal GABA uptake, exerted a similar antinociceptive effect that could be blocked by atropine. The GABA receptor antagonist bicuculline attenuated antinociception induced by TMT and nipecotic acid ethyl ester but not by morphine or oxotremorine. γ-Vinyl GABA, an irreversible inhibitor of GABA metabolism, prolonged TMT but not morphine-induced antinociception. In contrast, neither the dose-response nor the time course of TMT-induced hypothermia were affected by any of the drugs tested. The findings suggest that the GABAergic system may be involved in TMT induced antinociception; however, the mechanism responsible for the hypothermic effect of TMT is not apparent.     

On the mechanism by which dopamine inhibits prolactin release in the anterior pituitary

An $\text{in}$$\text{vitro}$ perfusion system was used to assess the effects of chloride channel blockers, dopamine (DA) receptor agonists and antagonists, and GABA receptor agonists and antagonists on prolactin release from the mouse anterior pituitary. Dopamine and muscimol inhibited prolactin release ($\text{IC}{}_{50}{}^1\text{= 6 × 10}{}^{\mathrm{?8}}\text{M and}\text{10}{}^{\mathrm{?5}}\text{M}$ respectively). The GABA receptor antagonist bicuculline blocked the inhibition of prolactin release by muscimol but not dopamine. The dopamine receptor antagonist chlorpromazine blocked the dopamine- but not muscimol-induced inhibition of prolactin release. Haloperidol, however, reversed both the muscimol and dopamine induced inhibition of prolactin release. Furthermore, the chloride channel blocker picrotoxinin blocked the inhibition of prolactin release elicited by both dopamine and muscimol. These later results suggest that the anterior pituitary dopamine receptor which mediates the inhibition of prolactin release may be coupled to a picrotoxinin sensitive chloride ionophore and that haloperidol may affect the function of both DA and GABA receptors in the anterior pituitary.     

Interaction of cyclic nucleotides and ecdysterone in breaking the pupal diapause of the bertha armyworm, Mamestra configurata WLK.

Cyclic GMP and cyclic AMP have distinct and opposite effects upon the action of ecdysterone in diapausing pupae of the Bertha armyworm, $\text{Mamestra}$$\text{configurata}$. Cyclic GMP enhanced the effectiveness of suboptimal doses of ecdysterone in breaking diapause; the amount of cyclic GMP required to lower the ED50 of ecdysterone by half was 80 μg/g. Dibutyryl cyclic GMP had no apparent effect on the action of ecdysterone over a wide dose range (0.07 – 70 μg/g). On the other hand, cyclic AMP and dibutyryl cyclic AMP effectively blocked the diapause-breaking action of ecdysterone when administered simultaneously with the steroid hormone. The amount of cyclic AMP required to reduce the incidence of diapause termination from 100% to 50% was 60 μg/g; for dibutyryl cyclic AMP the amount required was only 14 μg/g. No cyclic nucleotide tested in the study could by itself break the pupal diapause of $\text{M.}$$\text{configurata}$. The concept that cyclic GMP and cyclic AMP provide at least different if not opposing regulatory influences in certain insect systems is discussed briefly in the light of these observations.     

Evidence for two types of binding of 3H-gaba and 3H-muscimol in rat cerebral cortex and cerebellum.

The binding of n$\text{M}$ concentrations of ³HGABA and ³Hmuscimol to synaptosomal membrane preparations from different areas of rat brain were studied by a radioreceptor assay. The characteristics of binding, with respect to kinetic parameters and inhibition of binding by nonradioactive GABA, before and after detergent treatment, suggest the presence of at least two types of binding at putative GABA receptor sites.     

Effects of the anti hormone-hormone mimic ETB on the induction of insect juvenile hormone esterase in Trichoplusia ni.

Juvenile hormone (JH) esterases can be artificially induced to appear in the hemolymph of last instar larvae of the lepidopterous insect $\text{Trichoplusia}$$\text{ni}$ (Noctuidae) by topical treatment with JH I, JH II, or dihomo branched juvenoids. ETB (ethyl-4-[2-(t-butylcarbonyloxy) butoxy] benzoate; ZR-2646) at high doses is a weak inducer of JH esterase (JHE). However, at doses of ETB that induce only low levels of JHE activity, ETB will block the JHE induction caused by the dihomo juvenoid epofenonane and at higher doses will reduce the induction caused by JH I or JH II. ETB is not a JHE inhibitor; rather, it appears to be acting as a JH agonist/antagonist in normal larvae and in isolated abdomens. These effects of ETB on JHE induction may illustrate a new mode of action of anti-JH's.     

Intracerebral injection of gamma vinyl GABA: Method for measuring rates of GABA synthesis in specific brain regions invivo

In order to obtain an index of the rate of GABA synthesis in different rat brain regions, we examined the rate of accumulation of GABA after irreversible inhibition of GABA-transaminase. Gamma-vinyl-GABA (GVG), a catalytic inhibitor of GABA-transaminase, was microinjected directly into each of four brain areas: superior colliculus (SC), substantia nigra (SN), frontal cortex (CTX) and caudate-putamen (CP). The subsequent rate of GABA accumulation was linear for at least 90 min in all regions, and was found to be 2–3 times higher in the SC and SN than in the CTX and CP. The nerve terminal contribution to the initial rate of GABA accumulation after GVG was determined by comparing values obtained in the intact SN with those obtained in the SN in which the GABAergic afferent terminals had been destroyed. The initial rate of GABA accumulation in the denervated SN was less than one-half of that measured in the intact SN, indicating that, under normal conditions, both nerve-terminal and non-nerve-terminal (perikarya, glia) compartments contribute to the rate of GABA accumulation after GABA-transaminase inhibition. Our results indicate that the intracerebral injection of GVG is a sensitive and reliable method for studying $\text{in}\text{vivo}$ GABA synthesis in brain. Although the rate of GABA accumulation after GVG is sensitive to changes in the nerve terminal compartment, other GABA compartments may also influence these measurements.     

Growth hormone secretion of the neonatal rat pituitaries is stimulated by gamma-aminobutyric acid in vitro

Growth hormone secretion from pituitaries of neonatal rats was stimulated by gamma-aminobutyric acid (GABA) and the GABA agonist muscimol $\text{in vitro}$. This response to GABA was absent after the 9th postnatal day. The stimulation of growth hormone secretion by GABA was antagonized by bicuculline-methiodide and by picrotoxin. Diazepam stimulated while baclophen had no effect on growth hormone secretion. This stimulatory GABA effect might be related to a certain developmental stage of the pituitary GABA receptors or to the lack of hypothalamic regulatory influence(s) in the newborn.     

In vitro and in vivo effects on brain GABA metabolism of (S)-4-amino-5-fluoropentanoic acid,a mechanism-based inactivator of γ-aminobutyric acid transaminase

The effects of intraperitoneal administration of (S)-4-amino-5-fluoropentanoic acid, a mechanism-based covalent inactivator of γ-aminobutyric acid transaminase (GABA-T), on whole brain GABA metabolism in mice were investigated. A dose-dependent and time-dependent irreversible inactivation of GABA-T was observed with a concomitant increase in whole brain GABA levels. The compound exhibited no $\text{in vitro}$ nor $\text{in vivo}$ time-dependent inhibition of glutamate decarboxylase (GAD), alanine transaminase, or aspartate transaminase (Asp-T). It was, however, a potent competitive reversible inhibitor of GAD and a weak competitive inhibitor of Asp-T. The chloro analogue, (S)-4-amino-5-chloropentanoic acid, was ineffective.     

Effects of γ-aminobutyric acid on 33Pi incorporation into rat brain phospholipids in vivo

The effects of γ-aminobutyric acid (GABA), bicuculline and strychnine on the incorporation $\text{in vivo}$ of ³³Pi into phospholipids of rat brain were studied at 10 and 30 minutes after intracisternal injection of the radionuclide. GABA inhibited labeling of phospholipids in the three brain regions studied at both times. Bicuculline by itself had no significant effect on ³³Pi incorporation, but totally blocked the inhibitory effect of GABA in all three brain regions. Strychnine by itself inhibited phospholipid labeling in the brain stem and forebrain, had no significant effect on GABA inhibition of ³³Pi incorporation in the cerebellum and forebrain, and partially blocked the GABA effect in the brain stem. GABA inhibited ³³Pi incorporation into phosphatidic acid, phosphatidylinositol, phosphatidyl choline and phosphatidyl ethanolamine but had no effect on phosphatidyl serine. The data suggest that the inhibitory effects of GABA on CNS phospholipid labeling are mediated specifically through GABA receptor sites.     

Ethanol and other CNS depressants decrease GABA synthesis in mouse cerebral cortex and cerebellum in vivo

GABA synthesis in mouse brain $\text{in vivo}$ was estimated by measuring the rate of GABA accumulation one hour after inhibition of GABA degradation using the selective and irreversible antagonism of GABA-transaminase by gabaculine. Using this method we found that acute and repeated ethanol administration lead to a potent depression of gabaculine induced enhancement of GABA levels in mouse brain cerebellum and cerebral cortex. Alcohol, in the absence of gabaculine had no effect on steady state GABA levels. These results demonstrate potent effects of ethanol on the dynamics of GABA metabolism which are compatible with a GABA like effect of ethanol.     

The genesis and transmission of epidermal potentials in an amphibian embryo

The genesis and transmission of action potentials in epidermal cells of the newt (Cynops pyrrhogaster) embryo were investigated with special reference to cellular differentiation during development. Typical action potentials can be recorded from any of the epidermal cells at Stage 31. These potentials consist of a fast spike (18 msec) followed by a slow component (164 msec). The potential is graded with current intensity, and only the slow component initiates action potentials in adjacent cells and induces a transmission to other cells. The fast spike was found in all epidermal cells throughout the embryonic stages examined (Stages 26–47). The slow potential, however, appears at Stage 28, persists until Stage $\text{36}\text{37}$ just before hatching and then disappears at Stage $\text{38}\text{42}$. Electrical recordings from traumatic embryos (embryos without neural crest cells) or from cultured epidermal cell masses isolated from the pregastrula or the ventral region of the neurula, were compared with the intact embryo. No differences were observed in either the form of the action potential or its transmission. Thus these action potentials appear to be derived from epidermal cells, and are not of nervous origin. Evidence suggests that the transient establishment of excitable membranes in epidermal cells during differentiation is closely related to neural cell differentiation.