GABAA receptor antisense epilepsy: histological changes following infusion of antisense oligodeoxynucleotide to GABAA receptor gamma 2 subunit into rat hippocampus.

A deficiency of neuronal inhibition mediated by gamma-aminobutyric acid (GABA) via the GABAA receptor complex has been hypothesised to be a central factor in epileptogenesis. Intrahippocampal infusion of antisense oligodeoxynucleotide (ODN) to the GABAA receptor gamma 2 subunit in rats leads to electrographic limbic status epilepticus. In this model, epileptic phenomena are accompanied by loss of hippocampal neurones. The purpose of the present study was to investigate the time-course of morphological changes following hippocampal antisense 'knockdown' of the GABAA receptor gamma 2 subunit. gamma 2 subunit antisense ODN was infused continuously into the right hippocampus for periods between 1 and 5 days. After about 4 days of infusion, pronounced neurodegenerative changes were consistently observed within the ipsilateral hippocampus. In general, marked loss of CA3 pyramidal cells was found. The notion that the histological changes induced by the antisense ODN were specific to the applied ODN sequence was supported by the finding that a mismatch control ODN did not induce neurodegenerative changes, except for a small lesion in the immediate vicinity of the infusion site. Extensive ipsilateral hippocampal infiltration with monocytes and macrophages was a feature of antisense ODN infusion, but was considerably less pronounced after the infusion of control ODN. Immunocytochemistry using an antibody labeling glial fibrillary acidic protein (GFAP), revealed marked astroglial hypertrophy/proliferation after 4 days of antisense treatment, i.e., coincident with the development of neurodegeneration, in the ipsilateral hippocampus. At this time GFAP-immunoreactivity was also evident in the contralateral hippocampus, indicating contralateral spread of seizure activity.

Intrahippocampal infusion of antisense oligodeoxynucleotide to the GABA(A) receptor gamma2 subunit enhances neuropeptide Y gene expression.

The effects of hippocampal treatment with a phosphorothioate oligodeoxynucleotide (ODN) antisense to the gamma-aminobutyric acid (GABA)A receptor gamma2 subunit on neuropeptide Y (NPY) were studied. Adult male Wistar rats were treated with unilateral intrahippocampal infusion of gamma2 subunit antisense ODN for 5 days. Rats infused with mismatch ODN and naïve rats served as controls. Brain sections were analysed for levels of NPY mRNA by in situ hybridisation, NPY-immunoreactivity (NPY-ir) by means of immunocytochemistry, and specific NPY binding sites by in vitro receptor autoradiography. Following infusion of antisense ODN, a marked increase in cytoplasmic NPY-ir was observed in hilar neurones of the fascia dentata. Further, intense NPY-ir was visualised in the mossy fibres and in cell bodies of the entorhinal cortex and throughout the neocortex. High levels of NPY mRNA were detected in the same cortical areas of antisense treated rats. A very large increase was observed in the piriform and parietal areas. NPY gene expression also occurred in the granular cell layer, in which no NPY mRNA could be detected in normal animals. The level and distribution of cells displaying high levels of NPY mRNA differed among animals, perhaps as a result of the distinct anatomical location of ODN infusion. Finally, hippocampal levels of NPY specific binding increased, suggesting that NPY neurotransmission is markedly increased. These findings are reminiscent of reported changes in the expression of NPY mRNA and immunoreactivity in conditions of increased neuronal excitation and support the usefulness of the present animal model for the study of epileptic phenomena.

Molecular similarity analysis between insect juvenile hormone and N, N-diethyl-m-toluamide (DEET) analogs may aid design of novel insect repellents.

Molecular similarity analysis of stereoelectronic properties between natural insect juvenile hormone (JH), -a synthetic insect juvenile hormone mimic (JH-mimic, undecen-2-yl carbamate), and N, N-diethyl-m-toluamide (DEET) and its analogs reveals similarities that may aid the design of more efficacious insect repellents and give a better insight into the mechanism of repellent action. The study involves quantum chemical calculations using the AM1 semi-empirical computational method enabling a conformational search for the lowest and most abundant energy conformers of JH, JH-mimic, and 15 DEET compounds, followed by complete geometry optimization of the conformers. Similarity analyses of stereoelectronic properties such as structural parameters, atomic charges, dipole moments, molecular electrostatic potentials, and highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO) energies were performed on JH, JH-mimic and the DEET compounds. The similarity of stereoelectronic attributes of the amide/ester moiety, the negative electrostatic potential regions beyond the van der Waals surface, and the large distribution of hydrophobic regions in the compounds appear to be the three important factors leading to a similar interaction with the JH receptor. The similarity of electrostatic profiles beyond the van der Waals surface is likely to play a crucial role in molecular recognition interaction with the JH receptor from a distance. This also suggests electrostatic bioisosterism of the amide group of the DEET compounds and JH-mimic and, thus, a model for molecular recognition at the JH receptor. The insect repellent property of the DEET analogs may thus be attributed to a conflict of complementarity for the JH receptor binding sites.

Structural specificity of chloroquine-hematin binding related to inhibition of hematin polymerization and parasite growth.

Considerable data now support the hypothesis that chloroquine (CQ)-hematin binding in the parasite food vacuole leads to inhibition of hematin polymerization and parasite death by hematin poisoning. To better understand the structural specificity of CQ-hematin binding, 13 CQ analogues were chosen and their hematin binding affinity, inhibition of hematin polymerization, and inhibition of parasite growth were measured. As determined by isothermal titration calorimetry (ITC), the stoichiometry data and exothermic binding enthalpies indicated that, like CQ, these analogues bind to two or more hematin mu-oxo dimers in a cofacial pi-pi sandwich-type complex. Association constants (K(a)'s) ranged from 0.46 to 2.9 x 10(5) M(-1) compared to 4.0 x 10(5) M(-1) for CQ. Remarkably, we were not able to measure any significant interaction between hematin mu-oxo dimer and 11, the 6-chloro analogue of CQ. This result indicates that the 7-chloro substituent in CQ is a critical structural determinant in its binding affinity to hematin mu-oxo dimer. Molecular modeling experiments reinforce the view that the enthalpically favorable pi-pi interaction observed in the CQ-hematin mu-oxo dimer complex derives from a favorable alignment of the out-of-plane pi-electron density in CQ and hematin mu-oxo dimer at the points of intermolecular contact. For 4-aminoquinolines related to CQ, our data suggest that electron-withdrawing functional groups at the 7-position of the quinoline ring are required for activity against both hematin polymerization and parasite growth and that chlorine substitution at position 7 is optimal. Our results also confirm that the CQ diaminoalkyl side chain, especially the aliphatic tertiary nitrogen atom, is an important structural determinant in CQ drug resistance. For CQ analogues 1-13, the lack of correlation between K(a) and hematin polymerization IC(50) values suggests that other properties of the CQ-hematin mu-oxo dimer complex, rather than its association constant alone, play a role in the inhibition of hematin polymerization. However, there was a modest correlation between inhibition of hematin polymerization and inhibition of parasite growth when hematin polymerization IC(50) values were normalized for hematin mu-oxo dimer binding affinities, adding further evidence that antimalarial 4-aminoquinolines act by this mechanism.

Stereoelectronic features of the cinchona alkaloids determine their differential antimalarial activity.

For most potent antimalarial activity, the cinchona alkaloids appear to require certain electronic features, particularly a sufficiently acidic hydroxyl proton and an electric field direction pointing from the aliphatic nitrogen atom towards the quinoline ring. These observations are the result of an analysis of molecular electronic properties of eight cinchona alkaloids and an in vivo metabolite calculated using ab initio 3-21G quantum chemical methods in relation to their in vitro IC50 values against chloroquine-sensitive and chloroquine-resistant Plasmodium falciparum parasites. The purpose is to provide a profile of the electronic characteristics necessary for potent antimalarial activity for use in the design of new antimalarial agents and to gain insight into the mechanistic path for antimalarial activity. Distinguishing features of the weakly active epiquinine and epiquinidine include a higher dipole moment, a different direction of the electric field, a greater intrinsic nucleophilicity, lower acidity of the hydroxyl proton, a lesser electron affinity of the lowest unoccupied molecular orbitals, and a higher proton affinity than the active cinchona alkaloids. A moderately potent quinine metabolite possesses some, but not all, of the same electronic features as the most potent cinchona alkaloids. Both the positioning of the hydroxyl and aliphatic amine groups and their electronic features appear to play a crucial role for antimalarial potency of the cinchona alkaloids, most likely by controlling the ability of these groups to form effective intermolecular hydrogen bonds.

Stereoelectronic properties of antimalarial artemisinin analogues in relation to neurotoxicity.

Quantum chemical calculations on the molecular electronic structure of artemisinin (qinghaosu) and eight of its derivatives have resulted in stereoelectronic discriminators that differentiate between analogues with higher and lower neurotoxicities. Detailed ab initio quantum chemical calculations leading to complete optimization of geometry of each of the molecules were followed by calculation of their stereoelectronic properties using the 3-21G split valence basis sets and comparison of the stereoelectronic properties to in vitro neurotoxicity. The least neurotoxic compounds are more polar with an electric field pointing away from the endoperoxide bond and have a higher positive potential on the van der Waals surface of the all carbon-containing ring C, a more stable peroxide bond to cleavage, a less negative electrostatic potential by the endoperoxide, and a single negative potential region extending beyond the van der Waals surface of the molecule. In general, higher intrinsic lipophilicity is associated with greater neurotoxicity.

Isomorphous replacement combined with anomalous dispersion in the linear equations: application to a crystal containing four nonapeptide conformers.

The investigation of the structure of the four conformers of the nonapeptide described here has an additional purpose: to illustrate a method for combining isomorphous replacement information with anomalous dispersion information within the linear equations that have found use in the analysis of multiple-wavelength anomalous dispersion data. In the present application, isomorphous replacement data were obtained from the replacement of naturally occurring S atoms in the nonapeptide with Se atoms. Only one wavelength was used for the analysis: Cu Kalpha radiation. Details of the analysis are presented, as well as the structural results obtained. It was found that the four independent molecules in the structure have similar, but not identical, conformations. The backbones fold into predominantly alpha-helices with one or two 310-type hydrogen bonds and have extended side chains. Three to four water molecules are associated with each of the four head-to-tail regions between the peptides. Optimal packing between hydrophobic surfaces may account for the existence of four molecules in an asymmetric unit.

Predicting mosquito repellent potency of N,N-diethyl-m-toluamide (DEET) analogs from molecular electronic properties.

Specific molecular electronic properties of 30 N,N-diethyl-m-toluamide (DEET) analogs demonstrate functional dependence with their reported duration of protection against mosquito bites, thus providing predictors of insect repellent efficacy. No single electronic property is sufficient to predict repellent efficacy as measured by protection time, rather a set of specific electronic properties is required. Thus, the values of the van der Waals surface electrostatic potential by the amide nitrogen and oxygen atoms, the atomic charge at the amide nitrogen atom, and the dipole moment must all be in optimal ranges for potent repellency. The electronic properties were calculated using the AM semi-empirical quantum chemical method using commercial software. These easily calculable predictors of repellent efficacy should be useful in predicting the relative efficacy of newly designed compounds, thus guiding the selection of new repellents for testing.

Antisense oligonucleotide to GABA(A) receptor gamma2 subunit induces limbic status epilepticus.

Gamma-Aminobutyric acid (GABA) is the principal inhibitory neurotransmitter in the brain. A deficiency of GABAergic inhibition mediated via the GABAA receptor complex has for a long time been suspected to be a central factor in epileptogenesis. Status epilepticus is a condition of sustained and prolonged excitation of neuronal circuits, as detected by epileptiform discharges in the electroencephalogram (EEG). Reduction of GABAA receptor-mediated hippocampal inhibition has been implicated in the development of status epilepticus. The present study provides direct evidence of a link between the GABAA receptor and epilepsy. We show that selective inhibition of the expression of the GABAA receptor gamma2 subunit in the rat hippocampus by means of antisense oligonucleotides leads to spontaneous electrographic seizures that evolve into profound limbic status epilepticus, ultimately resulting in severe neurodegenerative changes. Concurrent treatment with diazepam prevents the development of status epilepticus and markedly reduces neuronal cell loss. These findings strongly support the hypothesis that the GABAA receptor is critically involved in the pathogenesis of seizures and status epilepticus.

Functional correlation of molecular electronic properties with potency of synthetic carbinolamine antimalarial agents.

Specific calculated molecular electronic properties of structurally diverse synthetic aromatic carbinolamines containing phenanthrene, quinoline, and N-substituted biphenyl rings are associated with antimalarial potency allowing use of these electronic features in the prediction of antimalarial efficacy, thus aiding the design of new antimalarial agents. These electronic features include the magnitude and location of 3-dimensional molecular electrostatic potentials, lowest unoccupied molecular orbitals, and highest occupied molecular orbitals. Stereoelectronic properties were calculated using quantum chemical AM1 methods on the optimized geometry of the lowest energy or most populated conformer in both gaseous and aqueous environments. In the phenanthrene carbinolamines, the aliphatic nitrogen atom and the hydroxyl proton are intrinsically more nucleophilic and less electrophilic, respectively, than in the non-phenanthrene compounds. Hydrogen bonding ability and the electrophilic nature of the aromatic ring appear to be two important features responsible for interaction with receptor molecules.

The use of in vivo antisense oligonucleotide technology for the investigation of brain GABA receptors.

Antisense oligodeoxynucleotides (ODN) can be used as selective inhibitors of in vivo gene expression in the central nervous system (CNS) of experimental animals. The gamma-aminobutyric acid type A (GABAA) receptor is a member of the ligand-gated ion channel superfamily of neurotransmitter receptors. GABAA receptor function is allosterically modulated by several clinically important compounds, e.g. 1,4-benzodiazepines, barbiturates and certain neurosteroids, which recognize binding sites within the receptor complex. GABAA receptor chloride channel complexes are probably pentamers of different polypeptide subunits. The number of known subunit families and isoforms (six alpha s, four beta s, three gamma s, one delta and two rho s) indicates an extensive heterogeneity of GABAA receptors. The gamma 2 subunit is a functionally integral part of the GABAA receptor, necessary for the high affinity binding of benzodiazepines. The infusion of phosphorothioate ODN antisense to the gamma 2 subunit mRNA, but not control sense or mismatch ODN, into the lateral cerebral ventricle or into the hippocampus of rats leads to significant decreases in benzodiazepine receptor radioligand binding. In the hippocampus this is accompanied by a decrease in the number of GABAA receptors and by a loss of neurones, the latter possibly being due to reduced GABAergic inhibitory neurotransmission. Autoradiographic analysis following continuous intrahippocampal infusion of antisense ODN shows the regional extent of the effect on [3H]flunitrazepam binding. The continuous infusion of antisense ODN, but not of mismatch control ODN, into the right lateral cerebral ventricle induced a significant decrease in benzodiazepine binding and [3H]muscimol binding to membranes of the right cortex. Antisense ODN infused into the striatum decreased benzodiazepine binding and binding to the GABA binding site of the GABAA receptor to an extent similar to that found in the hippocampus. It is concluded that the preferred route of administration of antisense ODN for in vivo studies of the GABAA receptor may be by infusion into defined rat brain regions. The reported data support the idea that antisense ODN can be used as a valuable tool for the investigation of the contribution of individual GABAA receptor subunits to the properties of the receptor complex and of mechanisms of receptor subunit assembly.

Diazepam protects against rat hippocampal neuronal cell death induced by antisense oligodeoxynucleotide to GABA(A) receptor gamma2 subunit.

Antisense oligodeoxynucleotides (ODNs) are used for the selective inhibition of gene expression. Antisense ODNs are promising tools for the investigation of physiological implications of proteins in the central nervous system of rodents in vivo. We have previously demonstrated that a phosphorothioate antisense ODN to the GABA(A) receptor gamma2 subunit, but not sense or mismatch control ODNs, induces a decrease in ex vivo benzodiazepine receptor radioligand binding in rat hippocampus when infused into the hippocampus in vivo [Karle et al., Neurosci. Lett., 202 (1995) 97-100]. This effect is parallelled by a decrease in the number of GABA(A) receptors and an extensive loss of hippocampal neurones. There is increasing awareness of risks of toxic 'non-antisense' effects induced by ODNs, and in particular phosphorothioate ODNs. The present experiments were designed to investigate the specificity of effects induced by the gamma2 subunit antisense ODN. The temporal development of changes in [3H]flunitrazepam and [3H]quinuclidinyl benzilate binding as well as in tissue protein levels supports the notion that the antisense ODN primarily acts by blocking the expression of the targeted receptor subunit protein. Furthermore, it is shown that a threshold for the elicitation of neurodegenerative changes exists. Finally, it is demonstrated that diazepam treatment of rats protects against the development of neuronal cell death induced by the antisense ODN. Collectively, the results support the hypothesis that the neurodegeneration induced by the antisense ODN is a consequence of diminished GABAergic inhibitory tonus following a selective down-regulation of gamma2 subunit-containing GABA(A) receptor complexes.

X-ray crystal structure of the antimalarial agent (-)-halofantrine hydrochloride supports stereospecificity for cardiotoxicity.

The crystal and molecular structures and absolute configuration of (-)-halofantrine hydrochloride were determined by X-ray diffraction. The absolute configuration of the single chiral center of (-)-halofantrine was established to be in the S configuration. Thus, (+)-halofantrine, the more cardiotoxic isomer, has the R configuration. The carbon atom adjacent to the aromatic ring has the same configuration in both (+)- halofantrine and quinidine, suggesting a stereospecific component to the cardiotoxicity produced by both agents. The intramolecular N ... O distance is 4.177 +/- 0.006 A (1 A = 0.1 nm), which is close to the N ... O distance found in the crystal structure of (+/-)-halofantrine hydrochloride, even though the N-H group points in opposite directions in racemic halofantrine and (-)-halofantrine. Both the hydroxyl group and the amine group form hydrogen bonds with the chloride anions. The crystallographic parameters for (-)-halofantrine hydrochloride were as follows: chemical formula, C26H31Cl2F6NO+. Cl-; Mr, 492.4; symmetry of unit cell, orthorhombic; space group, P2(1)2(1)2(1); parameters of unit cell, a was 6.290 +/- 0.001 A, b was 13.533 +/- 0.003 A, and c was 30.936 +/- 0.006 A; volume of the unit cell, 2,633.2 +/- 0.7 A(3); number of molecules per unit cell, 4; calculated density, 1.354 g cm(-3); source of radiation, Cu K(alpha) (lambda = 1.54178 A); mu (absorption coefficient), 3.50 mm(-1); F(000) (sum of atomic scattering factors at zero scattering angle), 1,120; room temperature was used; final R (residual index), 4.75% for 2,988 reflections, with absolute value of Fo > 3sigma(F), where Fo is the observed structure factor and F is the structure factor.

Differential changes in induced seizures after hippocampal treatment of rats with an antisense oligodeoxynucleotide to the GABA(A) receptor gamma2 subunit.

Gamma-aminobutyric acid (GABA) is the principal inhibitory neurotransmitter in the brain. Impairment of GABAergic neurotransmission may be involved in the pathogenesis of epileptic phenomena. We have previously characterized biochemical and histological changes following unilateral intrahippocampal infusion of a phosphorothioate antisense oligodeoxynucleotide to the GABA(A) receptor gamma2 subunit in rats in vivo. The aim of the present study was to investigate the behavioral changes of rats following unilateral hippocampal antisense 'knockdown' of the GABA(A) receptor gamma2 subunit. Antisense, but not mismatch control oligodeoxynucleotide treated rats had a significant weight loss (10%) during 6 d of treatment. Antisense treated rats exhibited no changes in spontaneous behavior, including anxiety-like behavior as measured in the social interaction test, compared to mismatch oligodeoxynucleotide treated rats. However, antisense treated rats developed pronounced changes in induced seizure activity. Seizures induced by subcutaneously injected pentylenetetrazol were markedly accentuated in antisense treated rats compared to treatment naive rats, whereas mismatch treated rats showed a lower seizure score than that of naive rats. Antisense treated rats had a significantly elevated threshold for seizures induced by electrical stimulation in the maximal electroshock seizure threshold test. The results suggest that intrahippocampal infusion of antisense oligodeoxynucleotide to the GABA(A) receptor gamma2 subunit leads to specific alterations in the sensitivity to induced seizures. The results are viewed as consequences of selective down-regulation of GABA(A) receptors and diminished inhibitory neurotransmission in the hippocampus.

Molecular electronic properties of a series of 4-quinolinecarbinolamines define antimalarial activity profile.

A detailed computational study on a series of 4-quinolinecarbinolamine antimalarials was performed using the semiempirical Austin model 1 (AM1) quantum chemical method to correlate the electronic features with antimalarial activity and to illuminate more completely the fundamental molecular level forces that affect the function and utility of the compounds. Ab initio (3-21G level) calculations were performed on mefloquine, the lead compound in this series, to check the reliability of the AM1 method. Electron density in specific regions of the molecules appears to play the pivotal role toward activity. A large laterally extended negative potential in the frontal portion of the nitrogen atom of the quinoline ring and the absence of negative potential over the molecular plane are crucial for the potent antimalarials. These electrostatic features are likely to be the modulator of hydrophobicity or lipophilicity of the compounds and, hence, determine their activities. The magnitude of the positive potential located by the hydroxyl hydrogen atom also correlates with potent antimalarial activity. Two negative potential regions occur near the hydroxyl oxygen and piperidyl nitrogen atoms. The two negative potential regions and the positive potential located by the hydroxyl hydrogen atom are consistent with intermolecular hydrogen bonding with the cellular effectors. The present modeling study should aid in efficient designing of this class of antimalarial agents.

Structure-activity relationships of the antimalarial agent artemisinin. 3. Total synthesis of (+)-13-carbaartemisinin and related tetra- and tricyclic structures.

Provided by total synthesis, endoperoxides 18, 20, and 22 underwent intramolecular oxymercuration-demercuration leading respectively to formation of an isomeric tetracycle, (1aS, 3S, 5aS, 6R, 8aS, 9R, 12S)-10-deoxo-13-carbaartemisinin (19), (+)-10-deoxo-13-carbaartemisinin (21), and (+)-13-carbaartemisinin (4). Structure assignment to 19 and 21 was based on single-crystal X-ray crystallographic analysis. Tricyclic endoperoxide 20 was converted to methyl and benzyl ethers 23 and 24 and reduced to saturated analog 25 which was also converted to ethers 26 and 27. In vitro antimalarial screening of both tri- and tetracyclic analogs was conducted using the W-2 and D-6 clones of Plasmodium falciparum. Neither target 4 nor 21 displayed substantial antimalarial potency in vitro against P. falciparum, but the diastereomeric peroxide 19 possessed good antimalarial potency in vitro. Tricyclic analogs were uniformly impotent. Iron(II) bromide-promoted rearrangement of 21 gave, in 79% yield, the unique tetracyclic alcohol 35, while 19 provided ring-opened cyclohexanone 41 (39%) along with the tricyclic epoxide 42 (20%). Neither 41 nor 42 possessed in vitro antimalarial activity, suggesting that epoxide-like intermediates are not responsible for the mode of action of this subclass of antimalarials. Rearrangement of 10-deoxoartemisinin (43) with FeBr2 gave a major product (79%) not encountered in the rearrangement of artemisinin that resulted from unraveling of the tetracyclic system cyclohexanone 46. Minor amounts of 1,10-dideoxoartemisinin (49) (8%) were also produced in this reaction.

Antisense oligonucleotide to GABAA receptor gamma 2 subunit induces loss of neurones in rat hippocampus.

The binding site for 1,4-benzodiazepines in the brain is part of the hetero-oligomeric gamma-aminobutyric acid (GABA)A receptor complex which regulates a chloride ion channel. The presence of the gamma 2 subunit in the complex is necessary for the binding of benzodiazepines to their binding site. This study demonstrates a reduction of benzodiazepine receptor radioligand binding by 43% compared to control following infusion of phosphorothioate antisense oligodeoxynucleotide to gamma 2 subunit into rat hippocampus. Reduction of benzodiazepine binding sites was paralleled by a decrease in [35S]tert-butyl-bicyclo-phosphorothionate ([35S]TBPS) binding (51%) and [3H]muscimol binding (37%), indicating a reduction in the number of GABAA receptors. Changed macroscopic appearance, reduced protein content and severe loss of neurones in antisense-treated hippocampi suggests that the reduced formation of GABAA receptors leads to neuronal cell death.

Modest reduction of benzodiazepine binding in rat brain in vivo induced by antisense oligonucleotide to GABAA receptor gamma 2 subunit subtype.

The GABAA (gamma-aminobutyric acid-A) receptor gamma 2 subunit subtype is probably a functionally integral part of the benzodiazepine binding site of the GABAA receptor complex, important for benzodiazepine pharmacology. We have evaluated the possibility of specifically reducing benzodiazepine receptor binding properties in vivo using phosphorothioate antisense oligodeoxynucleotides to inhibit the expression of GABAA receptor gamma 2 subunit subtype. Intracerebroventricular infusions of an antisense oligonucleotide reduced benzodiazepine receptor radioligand binding by 9-15% in specific rat brain regions.