Chloride channels as tools for developing selective insecticides

Ligand-gated chloride channels underlie inhibition in excitable membranes and are proven target sites for insecticides. The gamma-aminobutyric acid (GABA(1)) receptor/chloride ionophore complex is the primary site of action for a number of currently used insecticides, such as lindane, endosulfan, and fipronil. These compounds act as antagonists by stabilizing nonconducting conformations of the chloride channel. Blockage of the GABA-gated chloride channel reduces neuronal inhibition, which leads to hyperexcitation of the central nervous system, convulsions, and death. We recently investigated the mode of action of the silphinenes, plant-derived natural compounds that structurally resemble picrotoxinin. These materials antagonize the action of GABA on insect neurons and block GABA-mediated chloride uptake into mouse brain synaptoneurosomes in a noncompetitive manner. In mammals, avermectins have a blocking action on the GABA-gated chloride channel consistent with a coarse tremor, whereas at longer times and higher concentrations, activation of the channel suppresses neuronal activity. Invertebrates display ataxia, paralysis, and death as the predominant signs of poisoning, with a glutamate-gated chloride channel playing a major role. Additional target sites for the avermectins or other chloride channel-directed compounds might include receptors gated by histamine, serotonin, or acetylcholine.The voltage-sensitive chloride channels form another large gene family of chloride channels. Voltage-dependent chloride channels are involved in a number of physiological processes including: maintenance of electrical excitability, chloride ion secretion and resorption, intravesicular acidification, and cell volume regulation. A subset of these channels is affected by convulsants and insecticides in mammals, although the role they play in acute lethality in insects is unclear. Given the wide range of functions that they mediate, these channels are also potential targets for insecticide development.     

Cyclodiene resistance at the insect GABA receptor/chloride channel complex confers broad cross resistance to convulsants and experimental phenylpyrazole insecticides

This study investigated the pharmacological profile of cyclodiene resistance in Drosophila melanogaster and the mode of action of a phenylpyrazole insecticide, JKU 0422. Toxicological studies were performed with a sucrose bait assay containing the synergist piperonyl butoxide. The Maryland strain of D. melanogaster was resistant to dieldrin, lindane, picrotoxinin, TBPS, p-CN-TBOB, and JKU 0422. In contrast, this strain was susceptible to cypermethrin and the avermectins MK-243, abamectin, and abamectin 8,9-oxide. Neurophysiological studies showed that both TBPS and JKU 0422 reversed the inhibitory action of GABA in central nerve preparations from susceptible D. melanogaster. However, the response to these compounds was attenuated in nerve preparations from the resistant Maryland strain, which indicated that the resistance was expressed at the level of the nerve. Topical toxicity bioassays with JKU 0422 on susceptible (CSMA) and cyclodiene-resistant (LPP) strains of German cockroach revealed a resistance ratio of 553-fold for this compound. These studies demonstrate that cyclodiene resistance in D. melanogaster confers broad cross resistance toward compounds thought to block the GABA-gated chloride channel in a manner similar to the cyclodienes. Moreover, the cross resistance extends to JKU 0422, and resistance to this compound is also present in a strain of cyclodiene-resistant German cockroach. These toxicological results, along with the neurophysiological studies, confirm that JKU 0422 has a mode of action that is similar to the cyclodienes and TBPS. These findings suggest that the introduction and use of new chloride channel antagonists as insecticides should be managed carefully in order to prevent the rapid development of resistance in the field. © 1994 Wiley-Liss, Inc.     

RdlDv,a novel GABA-gated chloride channel gene from the American dog tick Dermacentor variabilis

The American dog tick Dermacentor variabilis is a major transmitter of bacterial and viral pathogens in human and animal populations, and compounds active against this species would benefit both human and animal health. Invertebrate GABA-gated chloride channels are validated targets of commonly used insecticides and acaricides. We cloned a novel member of the invertebrate GABA-gated chloride channel gene family from Dermacentor variabilis, RdlDv. The closest homologue of the predicted gene product of RdlDv is the RDL protein encoded by the GABA-gated chloride channel gene Drosophila Rdl (Resistance to Dieldrin), with which it shares 64% amino acid identity. When expressed in Xenopus oocytes, RdlDv produces GABA-activated currents blocked by the known insecticides and RDL antagonists fipronil and picrotoxinin. These results suggest that RdlDv encodes a GABA-gated chloride channel subunit, making it a potential target for compounds active against the tick D. variabilis.     

Activation of gamma-aminobutyric acid insensitive chloride channels in mouse brain synaptic vesicles by avermectin B1a.

The interaction of avermectin B1a (AVMB1a) with mouse brain chloride channels was characterized using a radiochloride efflux assay. The loss of intravesicular chloride from synaptoneurosomes preloaded with 36Cl involved an initial rapid phase followed by a slower phase that approached equilibrium within 10 min. AVMB1a stimulated a 30% loss of intravesicular chloride within the first 2 s of exposure; however, AVMB1a had no effect on the rate of the slower phase of chloride loss. Experiments with lysed synaptoneurosomes showed that both chloride loading and basal and AVMB1a-stimulated chloride release required the presence of intact vesicles. The efflux of 36Cl from mouse brain synaptosomes and the stimulation of efflux by AVMB1a were qualitatively similar to the results obtained with synaptoneurosomes but involved much lower overall levels of chloride loading and release. AVMB1a produced half-maximal stimulation of chloride efflux from synaptoneurosomes at a concentration of 2.1 +/- 0.3 microM and a 35.4 +/- 1.4% maximal loss of intravesicular chloride at saturating concentrations. gamma-Aminobutyric acid (GABA), bicuculline, or the chloride channel blockers picrotoxinin, t-butylbicyclophosphorothionate (TBPS) 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid (DIDS), and anthracene 9-carboxylic acid (9-CA) had little or no effect on the loss of chloride from synaptoneurosomes either in the presence or the absence of AVMB1a. However, the chlorinated cycloalkane insecticides dieldrin and lindane were equally effective as inhibitors of GABA-dependent chloride uptake and AVMB1a-stimulated chloride efflux. These data demonstrate that AVMB1a-stimulated chloride efflux from mouse brain synaptic vesicles results from the activation of GABA-insensitive chloride channels and that this action is distinct from their previously documented effects on GABA-gated chloride channels in mouse brain preparations. Our findings imply that both GABA-gated and GABA-insensitive chloride channels may be toxicologically significant targets for the action of avermectins.     

杀虫药剂的神经毒理学研究进展

大多数杀虫药剂都具有较强的神经毒性,它们对神经系统的作用靶标不同。有机磷类杀虫剂不仅抑制乙酰胆碱酯酶活性和乙酰胆碱受体功能,影响乙酰胆碱的释放,而且还具有非胆碱能毒性,有些有机磷杀虫剂还能引发迟发性神经毒性。新烟碱类杀虫剂作为烟碱型乙酰胆碱受体（nAChR）的激动剂,作用于该类受体的α亚基;它对昆虫的毒性比对哺乳动物的毒性大得多,乃是因为它对昆虫和哺乳动物nAChR的作用位点不同。拟除虫菊酯类杀虫剂主要作用于神经细胞钠通道,引起持续开放,导致传导阻滞;该类杀虫剂也可抑制钙通道。另外,这类杀虫剂还干扰谷氨酸递质和多巴胺神经元递质的释放。拟除虫菊酯类杀虫剂对昆虫的选择毒性很可能是因为昆虫神经元的钠通道结构与哺乳动物的不同。阿维菌素类杀虫剂主要作用于γ-氨基丁酸（GABA）受体,它能促进GABA的释放,增强GABA与GABA受体的结合,使氯离子内流增加,导致突触后膜超级化。由于这类杀虫剂难以穿透脊椎动物的血脑屏障而与中枢神经系统的GABA受体结合,故该类杀虫剂对脊椎动物的毒性远低于对昆虫的毒性。多杀菌素类杀虫剂可与中枢神经系统的nAChR作用,引起Ach长时间释放,此外,这类杀虫剂还可作用于昆虫的GABA受体,改变GABA门控氯通道的功能。     

35S]t-butylbicyclophosphorothionate binding sites in susceptible and cyclodiene-resistant houseflies.

4-aminobutyric acid (GABA)-gated chloride ion channels are important molecular targets for a number of polychlorocycloalkane compounds including cyclodiene insecticides. Previous radioligand binding studies have indicated that cyclodiene insecticides are potent inhibitors of [35S]t-butylbicyclophosphorothionate ([35S]TBPS) binding to housefly thorax and abdomen membranes. In the present study, a laboratory-reared, cyclodiene-resistant (CYW) housefly strain (Musca domestica) showed resistance to a number of cyclodiene insecticides. Specific, saturable [35S]TBPS binding was detected in thorax and abdomen membranes prepared from housefly strains susceptible (CSMA) and resistant (CYW) to cyclodienes. Scatchard analysis of [35S]TBPS binding data from CSMA and CYW membranes revealed no significant differences between the two strains in either the affinity (Kd) or the density (Bmax) of specific, saturable binding sites. There were no differences in the comparative effectiveness of a range of polychlorocycloalkanes, including cyclodiene insecticides, as inhibitors of specific [35S]TBPS binding to CSMA and CYW thorax and abdomen membranes. Therefore, if an alteration in target site is a mechanism for resistance to cyclodienes in the CYW strain, it is not readily measurable using [35S]TBPS.     

Recent progress in understanding the interaction between avermectins and ligand-gated ion channels: putting the pests to sleep

Avermectins and milbemycins are an important family of anthelmintics, insecticides and acaricides. Their mode of action is as positive allosteric modulators of ligand-gated chloride channels, and at higher concentrations, they gate some channels directly. Though it has long been known that the avermectins do not compete for the ligand binding site, the actual site at which they interact with their receptors has been unclear. Recent data demonstrate the importance to drug binding of amino acid residues predicted to line a water-filled pocket in the channel domain. This pocket acts as the binding site for anaesthetics and other modulators of mammalian GABA_A and glycine receptors, suggesting similarities in the mode of action between these drugs and the avermectins/milbemycins.     

Activation of γ-aminobutyric acid insensitive chloride channels in mouse brain synaptic vesicles by avermectin B1a

The interaction of avermectin B_1a (AVMB_1a) with mouse brain chloride channels was characterized using a radiochloride efflux assay. The loss of intravesicular chloride from synaptoneurosomes preloaded with ³⁶Cl involved an initial rapid phase followed by a slower phase that approached equilibrium within 10 min. AVMB_1a stimulated a 30% loss of intravesicular chloride within the first 2 s of exposure; however, AVMB_1a had no effect on the rate of the slower phase of chloride loss. Experiments with lysed synaptoneurosomes showed that both chloride loading and basal and AVMB_1a-stimulated chloride release required the presence of intact vesicles. The efflux of ³⁶Cl from mouse brain synaptosomes and the stimulation of efflux by AVMB_1a were qualitatively similar to the results obtained with synaptoneurosomes but involved much lower overall levels of chloride loading and release. AVMB_1a produced halfmaximal stimulation of chloride efflux from synaptoneurosomes at a concentration of 2.1 ± 0.3 μM and a 35.4 ± 1.4% maximal loss of intravesicular chloride at saturating concentrations. γ-Aminobutyric acid (GABA), bicuculline, or the chloride channel blockers picrotoxinin, t-butylbicyclophosphorothionate (TBPS) 4,4′-diisothiocyanatostilbene-2,2′-disulfonic acid (DIDS), and anthracene 9-carboxylic acid (9-CA) had little or no effect on the loss of chloride from synaptoneurosomes either in the presence or the absence of AVMB_1a. However, the chlorinated cycloalkane insecticides dieldrin and lindane were equally effective as inhibitors of GABA-dependent chloride uptake and AVMB_1a-stimulated chloride efflux. These data demonstrate that AVMB_1a-stimulated chloride efflux from mouse brain synaptic vesicles results from the activation of GABA-insensitive chloride channels and that this action is distinct from their previously documented effects on GABA-gated chloride channels in mouse brain preparations. Our findings imply that both GABA-gated and GABA-insensitive chloride channels may be toxicologically significant targets for the action of avermectins.     

Receptors for gamma-aminobutyric acid and voltage-dependent chloride channels as targets for drugs and toxicants

The function of chloride (Cl-) channel proteins is to regulate the transport of Cl- across membranes. There are two major kinds of Cl- channels: 1) those activated by binding of a transmitter such as gamma-aminobutyric acid (GABA), glycine, or glutamate, and thus are receptors; and 2) those activated by membrane depolarization or by calcium. There are two kinds of GABA receptors: GABAA is the major inhibitory receptor of vertebrate brain and the one that operates a Cl- channel, and the GABAB receptor, which is proposed to regulate cAMP production that is stimulated by other receptors. Except for binding of GABA, these two GABA receptors differ completely in their drug specificities. However, there are many similarities among the GABAA receptor, the glycine receptor, and the voltage-dependent Cl- channel. The two receptors and Cl- channels bind avermectin, whereas bicuculline binds only to mammalian GABAA and glycine receptors, not to the insect brain GABAA receptor. Barbiturates bind to GABAA and voltage-dependent Cl- channels, possibly directly activating them. Benzodiazepines potentiate both the glycine and GABAA receptors. Several insecticides act on the GABAA receptor and voltage-dependent Cl- channel. It is suggested that the GABAA receptor is the primary target for the action of toxaphene and cyclodiene insecticides but a secondary target for lindane and type II pyrethroids. On the other hand, the Cl- channel may be a primary target for avermectin and lindane but a secondary one for cyclodienes. The similarity in certain drug specificities and the operation of Cl- channels suggest a degree of homology between the subunits of GABAA and glycine receptors and the voltage-dependent Cl- channels.     

Blockage of chloride channels and anion transporters with pesticidal natural products and their synthetic analogs

Ligand-gated chloride channels mediate a variety of functions in excitable membranes of nerve and muscle in insects, and have a long history as targets for neurotoxic insecticides. Recent findings from our laboratory confirm that the natural product silphinenes and their semi-synthetic analogs share a mode of action with the established ligand-gated chloride channel antagonist, picrotoxinin. The silphinenes are non-selective, being roughly equipotent on insect and mammalian receptors, but also possess lethal and neurotoxic effects on a dieldrin-resistant strain of Drosophila melanogaster. These findings suggest that silphinenes act on insect GABA receptors in a way that is different from picrotoxinin, and it is possible that resistant insect populations in the field could be controlled with insecticidal compounds derived from the silphinenes. Voltage-gated chloride channels and anion transporters provide additional classes of validated targets for insecticidal/nematicidal action. Anion transporter blockers are toxic to insects via an action on the gut, and RNAi studies implicate voltage-gated chloride channels in nematode muscle as another possible target. There was no cross resistance to DIDS in a dieldrin-resistant strain of Drosophila melanogaster, and no evidence for neurotoxicity. The potent paralytic actions of anion transporter blockers against nematodes, and stomach poisoning activity against lepidopteran larvae suggests they are worthy of further investigation as commercial insecticidal/nematicidal agents.     

Differential sensitivity of two insect GABA-gated chloride channels to dieldrin,fipronil and picrotoxinin

In the central nervous system of both vertebrates and invertebrates inhibitory neurotransmission is mainly achieved through activation of γ-aminobutyric acid (GABA) receptors. Extensive studies have established the structural and pharmacological properties of vertebrate GABA receptors. Although the vast majority of insect GABA-sensitive responses share some properties with vertebrate GABAA receptors, peculiar pharmacological properties of these receptors led us to think that several GABA-gated chloride channels are present in insects. We describe here the pharmacological properties of two GABA receptor subtypes coupled to a chloride channel on dorsal unpaired median (DUM) neurones of the adult male cockroach. Long applications of GABA induce a large biphasic hyperpolarization, consisting of an initial transient hyperpolarization followed by a slow phase of hyperpolarization that is not quickly desensitized. With GABA, the transient hyperpolarization is sensitive to picrotoxinin, fipronil and dieldrin whereas the slow response is insensitive to these insecticides.When GABA is replaced by muscimol and cis-4-aminocrotonic acid (CACA) a biphasic hyperpolarization consisting of an initial transient hyperpolarization followed by a sustained phase is evoked which is blocked by picrotoxinin and fipronil. Exposure to dieldrin decreases only the early phase of the muscimol and CACA-induced biphasic response, suggesting that two GABA-gated chloride channel receptor subtypes are present in DUM neurones. This study describes, for the first time, a dieldrin resistant component different to the dieldrin- and picrotoxinin-resistant receptor found in several insect species.     

Toxicity, synergism, and neurological effects of novel volatile insecticides in insecticide-susceptible and -resistant Drosophila strains

Naturally derived volatile insecticides from the heterobicyclic and formate ester classes were investigated using a combination of volatility and synergist bioassays. In these studies, Drosophila melanogaster (Meigen) was used as a model for other medically important dipterans. In addition to a susceptible strain (Canton-S), three mutant strains were tested that included a strain resistant by P450-based metabolism (Hikone-R) and two resistant neurological mutant strains; one voltage-gated sodium channel mutant (para(ts-1)) and one GABA-gated chloride channel mutant (Rdl). In general, the 11 tested insecticides displayed a diversity of toxicity, metabolism, and resistance characteristics that correlate with their structural diversity. Several important trends were revealed by these studies, including hydrolase- and cytochrome P450 (P450)-based activation, P450-based resistance, distinct patterns of neurological activity, and negative cross-resistance with established insecticides. These findings provide important insight into the metabolism and modes of action for the volatile insecticides. These findings also suggest potential approaches for insecticide deployment in integrated vector management and resistance management programs.     

Ion channels: molecular targets of neuroactive insecticides

Many of the insecticides in current use act on molecular targets in the insect nervous system. Recently, our understanding of these targets has improved as a result of the complete sequencing of an insect genome, i.e., Drosophila melanogaster. Here we examine the recent work, drawing on genetics, genomics and physiology, which has provided evidence that specific receptors and ion channels are targeted by distinct chemical classes of insect control agents. The examples discussed include, sodium channels (pyrethroids, p,p′-dichlorodiphenyl-trichloroethane (DDT), dihydropyrazoles and oxadiazines); nicotinic acetylcholine receptors (cartap, spinosad, imidacloprid and related nitromethylenes/nitroguanidines); γ-aminobutyric acid (GABA) receptors (cyclodienes, γ-BHC and fipronil) and L-glutamate receptors (avermectins). Finally, we have examined the molecular basis of resistance to these molecules, which in some cases involves mutations in the molecular target, and we also consider the future impact of molecular genetic technologies in our understanding of the actions of neuroactive insecticides.     

The rat beta 1-subunit of the GABAA receptor forms a picrotoxin-sensitive anion channel open in the absence of GABA

The structural basis of GABA-gated chloride channels in mammalian brain is presently explored by the functional expression of cDNAs coding for the alpha, beta or gamma-subunits of the receptor and their isoforms. In this context, we expressed the cloned cDNA coding for the rat beta 1-subunit of the GABAA receptor in the Xenopus oocyte. Surprisingly, efficient expression of a functional ion channel was found. The channel was anion-selective, and able to open in the absence of GABA. Since this channel could be shunt by the GABA-channel blocker picrotoxin, we conclude that the beta 1-subunit of the GABAA receptor is sufficient to form binding sites for picrotoxin.     

Allosteric modulation by benzodiazepines of GABA-gated chloride channels of an identified insect motor neurone

The actions of benzodiazepines were studied on the responses to GABA of the fast coxal depressor (D_f) motor neurone of the cockroach, Periplaneta americana. Ro5-4864, diazepam and clonazepam were investigated. Responses to GABA receptors were enhanced by both Ro5-4864 and diazepam, whereas clonazepam, a potent-positive allosteric modulator of human GABA(A) receptors, was ineffective on the native insect GABA receptors of the D_f motor neurone. Thus, clear pharmacological differences exist between insect and mammalian native GABA-gated chloride channels with respect to the actions of benzodiazepines. The results enhance our understanding of invertebrate GABA-gated chloride channels which have recently proved important in (a) comparative studies aimed at identifying human allosteric drug-binding sites and (b) understanding the actions of compounds used to control ectoparasites and insect crop pests.     

新型二酰胺类杀虫剂对鱼尼丁受体作用的分子机理

最近发现了一类新型二酰胺类杀虫剂——氟虫酰胺和氯虫酰胺,其作用靶标是鱼尼丁受体 (ryanodine receptors, RyRs)。本文对RyR的结构与功能、电压门控钙离子通道和鱼尼丁受体钙离子释放通道对细胞质钙离子内环境稳定的调节以及二酰胺类杀虫剂对RyRs作用的分子机理进行综述。二酰胺类杀虫剂使昆虫RyR通道处于持续的开放状态,引发钙离子从肌质网腔内大量释放,破坏了细胞质钙离子内环境的稳定,从而产生不同的药物学特性。这些变化都是由一个不同于鱼尼丁在RyR上的结合部位介导的。该类杀虫剂的作用对昆虫RyR s是高度专一的,结果产生选择毒性。由于二酰胺类杀虫剂的结构独特,作用方式新颖,对鳞翅目害虫效果好、杀虫谱广,对各种益虫和天敌安全,并对现用的杀虫剂无交互抗性,故它们非常适合于抗性治理和IPM。     

Polychlorocycloalkane insecticide-induced convulsions in mice in relation to disruption of the GABA-regulated chloride ionophore

The toxicity to mice of intraperitoneally-administered polychlorocycloalkane (PCCA) insecticides is generally correlated with their potency as in vitro inhibitors of the brain specific [35S]t-butylbicyclophosphorothionate [( 35S]TBPS) binding site with correction for metabolic activation and detoxification. These findings from our earlier studies are extended here to in vivo investigations relating convulsant action to inhibition of the TBPS binding site in poisoned mice. Radioligand binding assays involved brain P2 membranes washed three times with 1 mM EDTA to remove endogenous gamma-aminobutyric acid (GABA) or other modulator(s) which otherwise serves as a noncompetitive inhibitor of [35S]TBPS binding at the GABA-regulated chloride ionophore. Examination of lindane, technical toxaphene, toxaphene toxicant A, and 10 polychlorocyclodiene insecticides revealed 62 +/- 4% binding site inhibition 30 min after their LD50 doses with 32 +/- 3% inhibition at one-half and 6 +/- 3% inhibition at one-quarter of their LD50 doses. This correlation between binding site inhibition and convulsant action is also evident in dose- and time-dependency studies with endosulfan sulfate. The brain P2 membranes of treated mice contain the parent compound with each of the PCCAs plus activation products of some of the cyclodienes, i.e. endosulfan sulfate from alpha- and beta-endosulfan and 12-ketoendrin from isodrin and endrin. The finding that the brains of treated mice contain sufficient PCCA or its activation products to achieve a magnitude of [35S]TBPS binding site inhibition correlated with the severity of the poisoning signs supports the hypothesis that the acute toxicity of PCCA insecticides to mammals is due to disruption of the GABA-regulated chloride ionophore.     

Ion-channels on parasite muscle: pharmacology and physiology

Ion-channels are essential components of excitable cells. This fact has been exploited in the development of anthelmintic agents; the majority of which act on nematode ion channels. The purpose of this review is to describe the site of action of some frequently used anthelmintic compounds: nAChRs and levamisole/pyrantel; Glu-Cls and avermectins/mylbemycins; GABA receptors and piperazine. Also described is some of the physiological and pharmacological data on other nematode muscle ion-channels which may prove attractive targets for future anthelmintic development: Ca²⁺ activated Cl⁻ channels; peptide gated chloride Cl⁻ channels; Ca²⁺ channels and potassium channels. Emphasis is placed on the pharmacological and physiological data from parasite tissue. Information on the genes involved in ion-channel formation and modulation are reviewed in detail elsewhere in this issue.     

Unusual effects of benzodiazepines and cyclodiene insecticides on an expressed invertebrate GABAA receptor.

We have previously reported [(1991) EMBO J. 10, 3239-3245] the sequence of an invertebrate gamma-aminobutyric acid (GABA) type A (GABAA) receptor polypeptide which forms homo-oligomeric GABA-gated, bicuculline-sensitive, chloride-ion channels upon heterologous expression. We now demonstrate that the benzodiazepines Ro5-4864 (4'-chlorodiazepam) and diazepam, that are active at mammalian peripheral benzodiazepine sites, and not those benzodiazepines specific for central sites, directly active the homo-oligomeric receptor and evoke larger maximal responses than those elicited by GABA. In addition, members of the cyclodiene class of insecticides block the channel of the receptor in a manner indistinguishable from that of picrotoxin.     

GABA-gated chloride ion influx in brains of tremor rats

We measured the GABA-gated chloride ion influx and GABA concentrations in the cerebral cortex and the hippocampus of young (5 weeks old) and older (15 weeks old) tremor rats. GABA-gated chloride ion influx in these tremor rats was significantly greater than in the controls of both the 5 week- and 15 week-old groups. GABA concentrations in the cerebral cortex and hippocampus of the tremor rats increased compared with controls of 5 weeks and decreased compared with controls of 15 weeks. These findings suggest that the GABAergic presynaptic neurons in the cortex and hippocampus of the tremor rat are disturbed with aging. This change may be related to the appearance of absence-like seizures in the rats. The increased GABA-gated chloride ion influx in tremor rats may be a compensatory mechanism against the genetically-determined seizure susceptibility of these rats. Furthermore, the increased GABA levels and GABA-gated chloride ion influx found in 5 week-old tremor rats may be related to the tremor movements.