Brain regional amino acid levels in seizure susceptible rats: Changes related to sound-induced seizures

Regional brain amino acid levels have been determined by HPLC, following microwave fixation, in seizure susceptible (University of Arizona, Audiogenic seizure-susceptible, AGS) and non-seizure susceptible Sprague-Dawley rats. Glutamine content is significantly lower in cerebellum, hippocampus, striatum, substantia nigra, colliculi and brain stem reticular formation in AGS rats. Aspartate levels are also reduced (by 33%) in striatum, substantia nigra and inferior colliculus, and glutamate is reduced in hippocampus and striatum. Other differences include a slight fall in taurine content (in striatum) and an increase in GABA content (in hippocampus). Measurements of amino acid levels in AGS rats during the course of a seizure induced by sound show increases in aspartate and glutamate content in some brain regions (including the inferior colliculus). Potassium-evoked [(3)H] d-aspartate release from hippocampal slices did not differ between the seizure-susceptible and seizure-resistant rat strains. It is proposed (i) that changes in the level and turnover of excitatory amino acid transmitters in AGS rats occur as a consequence of a primary biochemical defect that probably involves impaired neuronal membrane transport, and (ii) that altered function in excitatory synapses in the inferior colliculus, substantia nigra and reticular formation contributes importantly to the seizure susceptibility.

The amygdala to periaqueductal gray pathway: plastic changes induced by audiogenic kindling and reversal by gabapentin

Repeated, periodic induction of AGS (AGS kindling) in GEPR-9s increases seizure duration and induces an additional generalized clonus phase [post-tonic clonus (PTC)], which involves expansion of the localized brainstem AGS network to the amygdala. The pathway between central amygdala (CeA) and ventrolateral periaqueductal gray (vlPAG) is implicated in several disorders, including pain and anxiety. This pathway is also implicated in the network of audiogenic seizures (AGS) in genetically epilepsy-prone rats (GEPR-9s). We examined AGS kindling-induced changes in vlPAG extracellular action potentials evoked by electrical stimuli in CeA in awake, behaving GEPR-9s, using chronically-implanted stimulation electrodes in CeA and microwire recording electrodes in vlPAG. The effect of gabapentin, an anticonvulsant drug that is also effective in pain and anxiety disorders, on the CeA to vlPAG pathway in AGS-kindled GEPR-9s was also evaluated. Electrical stimulation in CeA evoked consistent, short latency and intensity-dependent vlPAG neuronal firing increases. However, in AGS-kindled GEPR-9s these responses showed a precipitous firing increase with increasing stimulus intensity, as compared to non-kindled GEPR-9s. Gabapentin (50mg/kg, i.p.) significantly reduced vlPAG neuronal responses to CeA stimulation to pre-AGS-kindled levels and reversibly blocked PTC in AGS-kindled GEPR-9s. These data suggest that the amygdala to vlPAG pathway may be critical in mediating the emergence of PTC during AGS kindling. The ability of gabapentin to suppress this pathway may be important for its anticonvulsant effects in AGS-kindled GEPR-9s, and this effect may contribute to gabapentin's effectiveness in anxiety and pain in which the amygdala to PAG pathway is also implicated.

Neurons in the periaqueductal gray are critically involved in the neuronal network for audiogenic seizures during ethanol withdrawal

The periaqueductal gray (PAG) is implicated in the network subserving audiogenic seizures (AGS). AGS are seen during ethanol withdrawal (ETX), and the present study examined effects of focal NMDA receptor blockade in PAG during ETX and PAG neuronal firing changes associated with ETX. Bilateral cannulae or microwire electrodes were chronically implanted into PAG. Ethanol was administered intragastrically at 8-h intervals for 4 days, resulting in AGS susceptibility during ETX. Microinjection of a competitive NMDA receptor antagonist, DL-2-amino-7-phosphonoheptanoic acid (AP7) (2 and 5 but not 1 nmol/side), into the PAG suppressed AGS, in part, reversibly. In microwire experiments spontaneous and acoustically evoked PAG neuronal responses in behaving rats were reduced significantly 1 h after initial administration of ethanol. During ETX, when the animals were susceptible to AGS, significant increases in spontaneous and acoustically evoked PAG neuronal firing occurred. PAG neurons exhibited burst firing 2-4 s prior to the tonic-clonic phase of AGS and tonic repetitive firing during this seizure phase, which ceased during post-ictal depression. Increased NMDA receptor function in PAG may be important to the aberrant PAG neuronal firing in AGS, since previous studies observed upregulation of NMDA receptors during ETX, and the present study observed that focal microinjection of a NMDA antagonist into PAG blocked AGS.

Modulation of audiogenically kindled seizures by gamma-aminobutyric acid-related mechanisms in the amygdala

Repetitive induction of audiogenic seizures (AGSs) ("AGS kindling") results in expansion of the AGS neuronal network from the brainstem to forebrain structures. AGSs in kindled genetically epilepsy-prone rats (GEPR-9s) exhibit a significant increase in the duration of posttonic clonus (PTC). The amygdala (AMG) does not appear to be a required network component before AGS kindling, but this structure is implicated in the seizure network after AGS kindling. gamma-Aminobutyric acid (GABA) is a major neurotransmitter in AMG, and histamine receptor activation is also reported to stimulate GABA release. The present study examined the effect on audiogenically kindled seizures of focal microinjections into the AMG of GEPR-9s. AGS kindling involved induction of 14 AGSs in GEPR-9s. Bilateral microinjection of a GABA(A) agonist, muscimol (0.3 nmol/side), into the AMG significantly reduced the duration of PTC, starting 0.5 h after drug infusion, with recovery by 24 h. Microinjection of histamine (60 nmol/side) suppressed PTC at 0.5 h, with total blockade at 24 h, but the seizure pattern did not revert to that observed before kindling until 120 h. This long duration suggests that mechanisms in addition to modulation of GABA function may be involved in the effect of histamine. The wild running and tonic components of AGS were never affected by microinjection of these agents into the AMG. These findings confirm previous work suggesting that the AMG is not a required nucleus in the AGS neuronal network before kindling. However, the AMG becomes critical in expansion of the seizure network during AGS kindling, and audiogenically kindled seizures are negatively modulated by increased GABA function.

Neurons in the deep layers of superior colliculus are a requisite component of the neuronal network for seizures during ethanol withdrawal

Ethanol withdrawal (ETX) in ethanol-dependent animals and humans often results in seizure susceptibility. The deep layers of superior colliculus (DLSC) are proposed to be involved in the neuronal networks of several types of seizures. In rodents, ETX results in susceptibility to audiogenic seizures (AGS), and the DLSC are implicated as a critical component of the seizure network in a genetic form of AGS. Ethanol inhibits NMDA receptors, and the binding at these receptors is increased during ETX in certain brain regions. Therefore, the effect of focal microinjection into DLSC of a competitive NMDA receptor antagonist, DL-2-amino-7-phosphonoheptanoic acid (AP7) on ETX seizures was examined. AP7 (2 and 5 nmol/side) microinjected bilaterally into DLSC suppressed AGS, supporting a critical role of the DLSC in the AGS network during ETX. DLSC neuronal firing changes in behaving rats were subsequently examined, using chronically implanted microwire electrodes. Acoustically-evoked DLSC firing was significantly suppressed during ethanol intoxication and during ETX. However, DLSC neurons began firing tonically 1-2 s before the onset of the wild running behavior of AGS. Acoustically-evoked DLSC firing was suppressed during post-ictal depression with recovery beginning as the righting reflex returned. These data support a requisite role of the DLSC in AGS during ETX. These neuronal firing changes suggest an important role of DLSC neurons in generation of the wild running phase of AGS during ETX, which may be a general pathophysiological mechanism and a critical event in the initiation of wild running, since a similar pattern was seen previously in a genetic form of AGS.

Audiogenic seizure susceptibility is induced by termination of continuous infusion of gamma-aminobutyric acid or an N-methyl-D-aspartic acid Antagonist into the inferior colliculus

The inferior colliculus (IC) is strongly implicated in seizure initiation in a genetic form of audiogenic seizures (AGS) and in AGS observed during ethanol withdrawal (ETX). Ethanol is known to block the actions of excitatory amino acids (EAA) and enhance the actions of gamma-aminobutyric acid (GABA) in several brain areas, including the IC. The present study investigated the effects on susceptibility to AGS following withdrawal from continuous blockade of N-methyl-D-aspartic acid (NMDA) receptors or continuous activation of GABA receptors in the IC. This involved infusion of GABA (1 M) or a competitive NMDA antagonist, DL-2-amino-7-phosphonoheptanoic acid (AP7, 1 mM), at 0.25 microl/h for 7 days using an Alzet osmotic minipump. Following abrupt termination of the infusion, AGS susceptibility began at 30 min. The incidence of AGS was 38.9 and 56.3% following GABA and AP7 withdrawal, respectively. The AGS behaviors observed during withdrawal, which included wild running and bouncing clonus, were very similar to those evoked by acoustic stimuli during ETX. AGS susceptibility lasted for several hours and in 13% of animals persisted for up to 6 months. The current results support diminished GABAergic and elevated glutamatergic function in the IC as the critical mechanisms and sites for AGS initiation. The present study, coupled with previous evidence that chronic ethanol exposure reduced GABA-mediated inhibition and enhanced EAA-mediated excitation, suggests that these amino acid receptor-mediated alterations in the IC are key elements in initiating AGS during ethanol withdrawal.

Modulation of audiogenic seizures by histamine and adenosine receptors in the inferior colliculus

Susceptibility to behaviorally similar audiogenic seizures (AGS) occurs genetically and is inducible during ethanol withdrawal (ETX). Comparisons between AGS mechanisms of genetically epilepsy-prone rats (GEPR-9s) and ethanol-withdrawn rats (ETX-Rs) are yielding information about general pathophysiological mechanisms of epileptogenesis. The inferior colliculus (IC) is the AGS initiation site. Excitatory amino acid (EAA) abnormalities in the IC are implicated in AGS, and histamine and adenosine receptor activation each reduce EAA release and inhibit several seizure types. Previous studies indicate that focal infusion of an adenosine receptor agonist into the IC blocked AGS in GEPR-9s, but the effects of adenosine receptor activation in the IC on AGS in ETX-Rs are unknown. The effects of histamine receptor activation on either form of AGS are also unexamined. The present study evaluated effects of histamine or a nonselective adenosine A(1) agonist, 2-chloroadenosine, on AGS by focal microinjection into the IC. Ethanol dependence and AGS susceptibility were induced in normal rats by intragastric ethanol. Histamine (40 or 60 nmol/side) significantly reduced AGS in GEPR-9s, but histamine in doses up to 120 nmol/side did not affect AGS in ETX-Rs. 2-Chloroadenosine (5 or 10 nmol/side) did not affect AGS in ETX-Rs, despite the effectiveness of lower doses of this agent in GEPR-9s reported previously. Thus, histamine and adenosine receptors in the IC modulate AGS of GEPR-9s, but do not modulate ETX-induced AGS. The reasons for this difference may involve the chronicity of AGS susceptibility in GEPR-9s, which may lead to more extensive neuromodulation as compensatory mechanisms to limit the seizures compared to the acute AGS of ETX-Rs.

Phenytoin administration reveals a differential role of pontine reticular formation and periaqueductal gray neurons in generation of the convulsive behaviors of audiogenic seizures

The ventrolateral periaqueductal gray (PAG) and pontine reticular formation (PRF) are implicated in the neuronal network for audiogenic seizures (AGS). The AGS of genetically epilepsy-prone rats (GEPR-9s) culminate in tonic hindlimb extension (TE), and elevated acoustically evoked neuronal firing and burst firing, immediately preceding TE, have been observed in PAG and PRF. This study examined changes in PAG and PRF neuronal firing and behavior in GEPR-9s, following phenytoin administration. Recordings involved 16 PAG and nine PRF neurons in GEPR-9s. Phenytoin in doses (mean, 6. 3 mg/kg) that suppressed TE selectively did not consistently alter PAG neuronal firing. However, these doses of phenytoin resulted in significant (51.6% of control) suppression of PRF neuronal firing. Doses of phenytoin (mean, 8.3 mg/kg), which completely blocked AGS, significantly reduced PAG neuronal firing (64.6% of control), and more greatly suppressed PRF firing (25.8% of control). These results are consistent with a critical role for PRF neurons in generation of TE not evident for PAG. The suppression of PAG and PRF neuronal firing induced by phenytoin with complete seizure blockade is consistent with vital roles for both structures in the seizure network. The differential effects of phenytoin on structures requisite to the seizure network indicate that this experimental approach may be able to identify the most sensitive therapeutic target for anticonvulsant drugs, which could be critical to pharmacological suppression of specific seizure behaviors manifest in various types of convulsions, potentially including human epilepsy.

Synaptic response patterns of neurons in the cortex of rat inferior colliculus

The present study examined synaptic potentials of neurons in inferior colliculus (IC) cortex slice and the roles of GABA and glutamate receptors in generating these potentials. Multipolar (82%) and elongated (18%) cells were observed with intracellular biocytin staining. Electrical stimulation of the IC commissure (CoIC) elicited only inhibitory postsynaptic potentials (IPSPs) (10% of cells), only excitatory postsynaptic potentials (EPSPs) (51%), or both (38%). IPSPs were elicited at lower thresholds and shorter latencies than EPSPs (mean: 1.6+/-1.2 ms) and IPSPs were observed in all neurons following membrane depolarization. Short-latency EPSPs were blocked by non-NMDA receptor antagonists, and longer-latency EPSPs were blocked by NMDA antagonists. CoIC stimulation evoked short-latency IPSPs (mean: 0.55+/-0.33 ms) in 48% of neurons, and the IPSPs persisted despite glutamate receptor blockade, which implies monosynaptic inhibitory input. A GABA(A) antagonist blocked IPSPs and paired pulse inhibition of EPSPs, suggesting GABA(A) receptor mediation. A GABA(B) antagonist reduced paired pulse inhibition of IPSPs, suggesting GABA(B) receptor modulation. Thus, GABA-mediated inhibition plays a critical role in shaping synaptic responses of IC cortex neurons. Normal GABAergic function in IC has been shown to be important in acoustic coding, and reduced efficacy of GABA function in IC neurons is critical in IC pathophysiology in presbycusis, tinnitus and audiogenic seizures.

Neuronal networks in the genetically epilepsy-prone rat

It is now possible to develop a dynamic neuronal network model for generalized convulsive seizures because of in vivo data recently obtained in a naturally occurring epilepsy model--the genetically epilepsy-prone rats (GEPR-9s). GEPR-9s exhibit audiogenic seizures (AGS) that consist of a sequence of discrete behavioral phases (i.e., wild running, clonus-tonus, and post-ictal depression). The neuronal firing changes in most nuclei implicated in the network during each phase of AGS in behaving GEPR-9s have been examined. The inferior colliculus is critical in AGS initiation, because extensive firing increases in inferior colliculus are observed preceding seizure initiation. The deep layers of superior colliculus (DLSC) are crucial to wild running, based on the emergence of tonic firing of DLSC neurons just preceding this phase. The pontine reticular nucleus (PRF) and periaqueductal gray (PAG) are critical to the clonic-tonic phase, because tonic firing patterns appear in these neurons just prior to this phase. During post-ictal depression all areas except the PRF are quiescent. These temporal relationships suggest that each nucleus plays a specific hierarchic role in each discrete convulsive behavior. Generalized tonic-clonic seizure behavior observed in human epilepsy, in GEPR-9s, and in other seizure models is likely to involve similar neuronal network components. The neurotransmitter mechanisms subserving the abnormal neuronal responses in the GEPR-9 neuronal network involve an increased availability of glutamate and a decrease in the effectiveness of gamma-aminobutyric acid (GABA) in many brain regions. Focal modification of the effects of GABA, glutamate, norepinephrine, or serotonin also modulates the nuclei of the network differentially. Together, these data reveal the anatomic, neurotransmitter, and neurophysiologic mechanisms of the neuronal network hierarchy in GEPR-9s, which is currently the most completely developed of any generalized convulsive model. Differential effects of anticonvulsants on the AGS phases and concomitant differential modifications of neuronal firing are observed on neurons in these network nuclei. With nearly complete identification of the network nuclei, the differential effects of these anticonvulsant drugs on different aspects of neuronal firing in different brain sites indicate that this experimental approach can likely identify the most sensitive therapeutic target for these agents. This concept is potentially vital to developing the most selective treatment of different convulsive behaviors occurring in human epilepsy. The neuronal network for AGS does not require brain structures rostral to the midbrain for seizure expression. However, the forebrain is recruited into an expanded seizure network through AGS repetition ("kindling"), resulting in prolonged AGS, post-tonic clonus, and epileptiform electrographic cortical abnormalities. AGS kindling produces network expansion into medial geniculate body (MGB) and amygdala and involves neuronal firing increases in MGB.

Differential roles in the neuronal network for audiogenic seizures are observed among the inferior colliculus subnuclei and the amygdala

The inferior colliculus (IC) is established as the initiation site within the neuronal network for audiogenic seizures (AGS), but the relative importance of the IC subnuclei in AGS is controversial. The lateral and basolateral subdivisions of the amygdala are implicated in the expansion of the AGS network that occurs during AGS kindling. However, the role of the amygdala in the AGS network in nonkindled AGS is unknown. NMDA receptors are implicated in modulation of AGS and in neurotransmission in both the IC and amygdala. Therefore, changes in AGS severity in genetically epilepsy-prone rats (GEPR-9s) were examined after bilateral focal microinjection into IC subnuclei or lateral/basolateral subdivisions of the amygdala of a competitive NMDA receptor antagonist, 3-((+)-2-carboxypiperazine-4-yl)propyl-1-phosphonic acid (CPP). Blockade of AGS in IC central nucleus (ICc) and external cortex (ICx) was observed at identical doses of CPP, but these doses were ineffective in IC dorsal cortex (ICd). Microinjection of CPP into the amygdala did not produce significant changes in AGS severity except at doses 20 times those effective in IC. The latter data contrast with the anticonvulsant effects of amygdala microinjections on seizure severity in kindled AGS reported previously. The present data in concord with neuronal recording studies of these nuclei suggest that the ICc is the most critical site in AGS initiation, the ICx in propagation, and that the ICd plays a lesser role in the AGS network. The amygdala does not appear to play a requisite role in the neuronal network for AGS in animals that have not been subjected to AGS kindling.

The periaqueductal grey is a critical site in the neuronal network for audiogenic seizures: modulation by GABA(A), NMDA and opioid receptors

The nuclei comprising the neuronal network for audiogenic seizures (AGS) are located primarily in the brainstem. Previous studies suggested a role for the periaqueductal grey (PAG) in the AGS network. The present study evaluated this possibility in genetically-epilepsy prone rats (GEPR-9s) by examining the effects of bilateral focal microinjection of a competitive NMDA receptor antagonist (DL-2-amino-7-phosphonoheptanoic acid (AP7), 1 and 5 nmol/side), a GABA(A) agonist (gaboxedol (THIP), 10 and 15 nmol) or an opioid peptide receptor antagonist (naloxone, 5 nmol) into PAG, based on the proposed role of these receptors in PAG neurotransmission. Blockade of NMDA receptors by AP7 (both doses) or activation of GABA(A) receptors with THIP (15 nmol/side) in the PAG suppressed AGS susceptibility. Naloxone displayed a seizure-suppressant effect that was delayed and incomplete. The seizure suppressant effect of AP7 or naloxone, unlike THIP, was observed at doses that did not produce motor quiescence. These data suggest that the PAG is a requisite nucleus in the neuronal network for AGS in GEPR-9s and that GABA(A), opioid peptide and NMDA receptors in the PAG modulate AGS propagation.

Neurons in the deep layers of superior colliculus play a critical role in the neuronal network for audiogenic seizures: mechanisms for production of wild running behavior

Recent investigations suggest that the deep layers of superior colliculus (DLSC) play a role in the neuronal network for audiogenic seizures (AGS). The present study examined DLSC neuronal firing and convulsive behavior simultaneously in freely-moving genetically epilepsy-prone rats (GEPR-9s) using chronically implanted microwire electrodes. An abrupt onset of acoustically-evoked firing at approximately 80-90 dB was observed in DLSC neurons of GEPR-9s, which was significantly above the normal threshold. DLSC neurons began to exhibit rapid tonic burst firing 1-2 s prior to the onset of the wild running behavior at the beginning of AGS. As the tonic phase of the seizure began, DLSC firing ceased, and only returned towards normal following post-ictal depression. These neuronal mechanisms may be relevant to other seizure models in which the DLSC is implicated. The temporal pattern of neuronal firing during AGS is specific to DLSC and differs markedly from those observed elsewhere in the AGS neuronal network. The temporal firing pattern suggests that the DLSC plays a primary role in the generation of the wild running phase of AGS. Previous studies indicate that the inferior colliculus is dominant during AGS initiation, and the pontine reticular formation is dominant during the tonic extension phase of AGS. Taken together these data suggest that the neurons in the neuronal network undergo a dominance shift as each specific convulsive behavior of AGS is elaborated.

Ethanol and neurotransmitter interactions--from molecular to integrative effects

There is extensive evidence that ethanol interacts with a variety of neurotransmitters. Considerable research indicates that the major actions of ethanol involve enhancement of the effects of gamma-aminobutyric acid (GABA) at GABAA receptors and blockade of the NMDA subtype of excitatory amino acid (EAA) receptor. Ethanol increases GABAA receptor-mediated inhibition, but this does not occur in all brain regions, all cell types in the same region, nor at all GABAA receptor sites on the same neuron, nor across species in the same brain region. The molecular basis for the selectivity of the action of ethanol on GaBAA receptors has been proposed to involve a combination of benzodiazepine subtype, beta 2 subunit, and a splice variant of the gamma 2 subunit, but substantial controversy on this issue currently remains. Chronic ethanol administration results in tolerance, dependence, and an ethanol withdrawal (ETX) syndrome, which are mediated, in part, by desensitization and/or down-regulation of GABAA receptors. This decrease in ethanol action may involve changes in subunit expression in selected brain areas, but these data are complex and somewhat contradictory at present. The sensitivity of NMDA receptors to ethanol block is proposed to involve the NMDAR2B subunit in certain brain regions, but this subunit does not appear to be the sole determinant of this interaction. Tolerance to ethanol results in enhanced EAA neurotransmission and NMDA receptor upregulation, which appears to involve selective increases in NMDAR2B subunit levels and other molecular changes in specific brain loci. During ETX a variety of symptoms are seen, including susceptibility to seizures. In rodents these seizures are readily triggered by sound (audiogenic seizures). The neuronal network required for these seizures is contained primarily in certain brain stem structures. Specific nuclei appear to play a hierarchical role in generating each stereotypical behavioral phases of the convulsion. Thus, the inferior colliculus acts to initiate these seizures, and a decrease in effectiveness of GABA-mediated inhibition in these neurons is a major initiation mechanism. The deep layers of superior colliculus are implicated in generation of the wild running behavior. The pontine reticular formation, substantia nigra and periaqueductal gray are implicated in generation of the tonic-clonic seizure behavior. The mechanisms involved in the recruitment of neurons within each network nucleus into the seizure circuit have been proposed to require activation of a critical mass of neurons. Achievement of critical mass may involve excess EAA-mediated synaptic neurotransmission due, in part, to upregulation as well as other phenomena, including volume (non-synaptic diffusion) neurotransmission. Effects of ETX on receptors observed in vitro may undergo amplification in vivo to allow the excess EAA action to be magnified sufficiently to produce synchronization of neuronal firing, allowing participation of the nucleus in seizure generation. GABA-mediated inhibition, which normally acts to limit excitation, is diminished in effectiveness during ETX, and further intensifies this excitation.

In vitro electrophysiology of neurons in subnuclei of rat inferior colliculus

We compared membrane and synaptic properties of neurons in the three major subdivisions of inferior colliculus (IC), central nucleus (ICc, N=18), external cortex (ICx, N=38), and dorsal cortex (ICd, N=31) of slices from rat IC, using intracellular neuronal recording. Three types of responses occurred in each IC subdivision in response to depolarizing currents: on-type (N=20), rapidly-adapting (N=11), and sustained firing (N=56), which was most common. The on-type neurons have lower input resistances and shorter time constants, with wider and lower amplitude action potentials (APs) than sustained neurons. A calcium-mediated 'hump' was often evoked by depolarizing current pulses in ICd neurons (11 of 28), was infrequent in ICx, but was absent in ICc. ICx and ICc neurons often exhibited spontaneous repetitive spike firing, lower repetitive AP firing thresholds, and faster repetitive spike firing than ICd neurons. Calcium-mediated fast after-hyperpolarizations and spike frequency adaptation were regularly seen in IC. Neurons in ICx and ICd, but not ICc, had synaptic responses to stimulation of the collicular commissure (CoIC). In ICx, large epileptiform depolarizing events were often elicited by strong electrical stimulation of CoIC, which was not normally seen in ICd. These results indicate that ICx neurons exhibit a greater degree of synaptic excitability than neurons in ICc or ICd, which may contribute to the proposed role of ICx in pathological IC hyperexcitability.

Periaqueductal gray neurons exhibit increased responsiveness associated with audiogenic seizures in the genetically epilepsy-prone rat

The ventrolateral periaqueductal gray is implicated as a component of the neuronal network for audiogenic seizure. This implication is based on immunocytochemical labeling of the proto-oncogene, c-fos, and microinjection studies in the severe substrain of genetically epilepsy-prone rats that exhibits tonic seizures. The present study examines changes in acoustically evoked neuronal responses within the periaqueductal gray in the awake and behaving genetically epilepsy-prone rat as compared to normal Sprague Dawley rats. Two populations of neuronal response were observed in the periaqueductal gray of both genetically epilepsy-prone and normal rats. Most of the neurons exhibited long latencies (>10 ms) and lower thresholds, and were more responsive to the acoustic stimulus. The remainder of the periaqueductal gray neurons exhibited short latencies (<10 ms) and higher thresholds, and exhibited minimal responsiveness to the acoustic stimulus. The mean threshold of periaqueductal gray acoustically evoked neuronal firing of short-latency neurons was significantly higher than normal in the genetically epilepsy-prone rat. The number of acoustically evoked action potentials was significantly elevated in the genetically epilepsy-prone rat, particularly at the highest acoustic intensity and at a repetition rate of 1/2 s. In the genetically epilepsy-prone rat, the number of action potentials exhibited adaptation (habituation) at 1/s as compared to 1/2 s across stimulus intensities. Habituation in normal rats was observed primarily at high intensities (95 dB sound pressure level or above). During wild running and tonic seizures in the genetically epilepsy-prone rat, periaqueductal gray neurons. which had diminished firing rates due to habituation, exhibited a tonic firing pattern. Just (1-5 s) prior to the onset of tonic convulsive behaviors, an increase in the rate of periaqueductal gray tonic firing was observed. These patterns of abnormal neuronal firing suggest that periaqueductal gray neurons may be involved in generation of the tonic seizure behavioral component of audiogenic seizure in the genetically epilepsy-prone rat, which will need confirmation in other audiogenic seizure models.

Comparison of neuronal response patterns in the external and central nuclei of inferior colliculus during ethanol administration and ethanol withdrawal

Convulsive seizures during ethanol withdrawal (ETX) in rodents can be precipitated by acoustic stimulation. The inferior colliculus (IC) is strongly implicated in the neuronal network for these audiogenic seizures (AGS) in animals undergoing ETX. Previous evidence indicates that the central nucleus of IC (ICc) is important in AGS initiation in ETX, but the ICc does not project directly to motor pathways. The external nucleus of IC (ICx) receives convergent output from a broad range of ICc neurons, which is not tonotopically organized, and projects to several nuclei with major motor connections. Lesion, neuroanatomical, and stimulation experiments suggest the involvement of the ICx in the AGS network in several forms of AGS, including ETX. The present study examined ICx neuronal firing patterns in awake behaving rats during ethanol administration and during ETX to examine the role of this structure directly. ICx neuronal responses during both ethanol intoxication and ETX were significantly suppressed as compared to pre-ethanol responses. ICx neuronal responsiveness was reduced (habituated) at faster (>0.25 Hz) rates of stimulus presentation. However, immediately prior to the onset of AGS, there was an increase in ICx neuronal responses that continued into the wild running phase of AGS. This increase in neuronal responses temporally corresponded to the sustained ICc neuronal responses during ETX just prior to AGS. The enhanced ICx neuronal responsiveness may be mediated, in part, by changes in GABA and glutamate receptor regulation previously observed during ETX. The net result of these changes involves a functional reversal of response habituation normally observed in ICx neurons. These data illuminate the nature of the changes in ICx neuronal function that serves to transmit the sensory input that originates in the ICc and propagates seizure to the brainstem AGS network nuclei responsible for the convulsive motor behaviors of ETX seizures.

Aberrant neuronal responsiveness in the genetically epilepsy-prone rat: acoustic responses and influences of the central nucleus upon the external nucleus of inferior colliculus

The inferior colliculus (IC) central nucleus (ICc), is critical for audiogenic seizure (AGS) initiation in the genetically epilepsy-prone rat (GEPR). The ICc lacks direct motor outputs but sends a major projection to the external nucleus of IC (ICx), which does project to the sensorimotor integration nuclei within the AGS neuronal network. The present study compared acoustic responses of ICx neurons in the GEPR and normal anesthetized rat and evaluated whether the GEPR exhibits functional abnormalities in the pathway from ICc to ICx. There is a significantly greater incidence of sustained repetitive response patterns to the acoustic stimulus in GEPR ICx neurons (75%) than in normal ICx neurons (24%). Following unilateral microinjection of N-methyl-D-aspartate (NMDA) into the contralateral ICc, acoustically-evoked ICx excitation and inhibition were each increased in normal animals, which is consistent with the mixed projections previously reported in this pathway and observed with electrical stimulation in the present study. The NMDA-induced ICx firing increase may be relevant to AGS, since, in previous studies, bilateral focal microinjection of NMDA into the ICc induced AGS susceptibility in normal rats [23]. However, the incidence and degree of the ICx neuronal response changes after NMDA microinjection was not abnormal in the GEPR. These data suggest that the hyperresponsiveness of ICx neurons may not involve abnormal transmission between the ICc and ICx, despite the elevated ICx neuronal responses to acoustic stimuli. However, the ICx hyperresponsivess of the GEPR, which is likely due to the known decrease in effectiveness of GABA-mediated inhibition in GEPR neurons, may be a major mechanism subserving the critical role that this structure plays in the AGS network.

Audiogenic kindling increases neuronal responses to acoustic stimuli in neurons of the medial geniculate body of the genetically epilepsy-prone rat

Frequent repetition of audiogenic seizure (AGS) ('AGS kindling') in the severe substrain of genetically epilepsy-prone rats (GEPR-9s) results in the appearance of cortical epileptiform electrographic activity, increases of seizure duration and additional convulsive behaviors. These findings suggest that the initial AGS network, which is located primarily in the brainstem, has undergone expansion to the forebrain. The medial geniculate body (MGB) is a thalamic structure that is the first major auditory nucleus efferent to the AGS-initiating site in the inferior colliculus. The MGB is not required for AGS induction, but it has been implicated in the expanded AGS network in GEPR-9s based on focal, pharmacological blockade experiments. The present study examined changes in acoustically evoked MGB neuronal responses in awake and behaving GEPR-9s and in anesthetized GEPR-9s after 14 repetitive AGS-inducing stimuli given daily. An elevated number of action potentials was observed in the MGB neuronal responses after AGS kindling in GEPR-9s. This increase of MGB neuronal responses was associated with a loss of habituation and lasted for at least 28 days after the 14th AGS. An increase in the incidence of sustained acoustic responses in MGB neurons was observed after repetitive AGS in GEPR-9s. Increases in the peak latency and threshold of MGB neuronal responses were also observed after AGS kindling. MGB neurons exhibited a rapid tonic firing during tonic seizures in behaving GEPR-9s, suggesting that the MGB may be implicated in the propagation of seizure activity. However, MGB neuronal firing was silent during post-tonic clonus, a behavior seen in GEPR-9s only after AGS repetition, suggesting that MGB does not play a direct role in the generation of this convulsive behavior. Thus, changes in neuronal firing in nuclei efferent to the MGB, in the expanded neuronal network for repetitive AGS, may be responsible for the generation of post-tonic clonus in GEPR-9s.

Increased responsiveness and failure of habituation in neurons of the external nucleus of inferior colliculus associated with audiogenic seizures of the genetically epilepsy-prone rat

Initiation of audiogenic seizures (AGS) emanates from the inferior colliculus (IC) to other IC subnuclei in the genetically epilepsy-prone rat (GEPR). The external nucleus of IC (ICx) is a suggested site of convergence of the auditory output onto the sensorimotor integration network components for AGS in the brainstem. Neuronal firing was recorded from the ICx of the awake, freely moving GEPR and normal Sprague-Dawley rats using microwire electrodes in the present study. Auditory stimuli consisted of 12-kHz tones (100 ms, 5-ms rise-fall at rates of 1/4s, 1/2s, and 1/s). AGS incidence in the GEPR is highest at 12 kHz. In the GEPR, ICx neuronal responses to acoustic stimuli were significantly greater than those seen in normal rats. This increased ICx firing was observed at relatively high acoustic intensities (> 80 dB SPL), which are near the threshold for AGS induction. Repetition-induced response attenuation (habituation) is commonly observed in ICx neurons, which appears to be overcome in the GEPR during AGS initiation. Tonic, acoustically evoked ICx neuronal firing was observed just prior to wild running. ICx firing was suppressed during the tonic and postictal phases of AGS. Recovery of ICx responses occurred when the animal regained postural control. Abnormal, intense output has previously been observed in the GEPR IC central nucleus (ICc) neurons. The neuronal firing pattern changes observed in the ICx in the present study may result from this intense ICc output. Diminished efficacy of GABA, which has been observed in several regions of the GEPR brain, including the IC, in a number of previous studies, may be involved in the exaggerated ICx responses to acoustic stimuli in the GEPR. Participation of the ICx in the AGS neuronal network may be subserved by this acoustic hyperresponsiveness.

Decreased GABA effectiveness in the inferior colliculus neurons during ethanol withdrawal in rats susceptible to audiogenic seizures

The inferior colliculus (IC) is the initiation site in the neuronal network for audiogenic seizure (AGS) in rats undergoing ethanol withdrawal (ETX). Considerable evidence supports a role of gamma-aminobutyric acid (GABA)-mediated inhibition in normal acoustic processing in the IC. Altered GABA-mediated inhibition in the IC is suggested to be important in the control of AGS initiation. The present study used microiontophoresis to examine the effectiveness of GABA on acoustically-evoked neuronal responses in the central nucleus of the IC (ICc). GABA effectiveness was compared in normal controls and a group of animals displaying high audiogenic seizure susceptibility (100% AGS) (HAGS), and a group exhibiting a low (mean, 33%) incidence of AGS (LAGS). Ethanol was administered for 4 days in three daily doses (9-15 g/kg/day) sufficient to maintain a moderate degree of intoxication. Tonic-clonic seizures were observed in HAGS animals, while LAGS rats exhibited less severe seizures, consisting primarily of wild running. Iontophoretic application of GABA consistently inhibited ICc neuronal firing in controls and in animals undergoing ETX. However, the mean dose (current) of GABA required to produce a 50% reduction of the ICc neuronal firing in the HAGS group was nearly twice that of the control animals. The mean dose of GABA for 50% inhibition in the LAGS group was about one-half that of the control group. Both of these differences were statistically significant. These data suggest that decreased GABA effectiveness in the IC neurons of HAGS susceptible animals is an important mechanism contributing to the propagation of severe AGS seen during ETX in these animals.

Repetitive audiogenic seizures cause an increased acoustic response in inferior colliculus neurons and additional convulsive behaviors in the genetically-epilepsy prone rat

Previous studies indicate that daily repetition of audiogenic seizures (AGS) leads to audiogenic 'kindling' with increased seizure duration and additional seizural behaviors. The present study examined the neuronal correlates of this phenomenon. Extracellular single neuron firing and concomitant convulsive behaviors associated with 14 repetitive AGS were evaluated in the genetically epilepsy-prone rat severe seizure strain (GEPR-9). An increase in the number of acoustically-evoked action potentials in neurons of the central nucleus of inferior colliculus (ICc) was observed by the second day of AGS repetition, and peaked at day four. The ICc responses remained at similar enhanced level through day 14. ICc neuronal responses were completely absent for approximately two min post-ictally after a single AGS in all animals, but 80% of the animals undergoing repetitive AGS consistently exhibited neuronal firing in this post-ictal period. Post-tonic clonus and an increased duration of post-ictal behavioral depression were also observed with repetitive AGS. The increased ICc neuronal firing was observed prior to the appearance of the post-tonic clonus component of repetitive AGS. This suggests that the ICc neuronal firing increase may subserve, at least, the initial increase in AGS severity. However, changes in neuronal firing in nuclei of the neuronal network for AGS efferent to the ICc may be responsible for the increased AGS severity that occurs after the fourth day of AGS repetition.

Pontine reticular formation neurons exhibit a premature and precipitous increase in acoustic responses prior to audiogenic seizures in genetically epilepsy-prone rats

The genetically epilepsy-prone rat (GEPR-9) exhibits elevated seizure sensitivity and audiogenic seizures (AGS). The pontine reticular formation (PRF) is implicated in the neuronal network for AGS in the GEPR-9. The present study examined PRF neuronal firing and convulsive behavior simultaneously in the GEPR-9. Chronically implanted microwire electrodes in PRF allowed single neuronal responses and behavior to be examined in freely-moving rats. PRF neurons in the GEPR-9 exhibit precipitous intensity-evoked increases at a significantly lower (approx. 15 dB SPL) intensity than normal Sprague-Dawley rats. PRF neurons in the GEPR-9 also exhibit increased auditory response latencies. At the onset of AGS (wild running) the firing rate of PRF neurons increased, and the rate of PRF firing increased dramatically as the tonic phase of the seizure began. During post-ictal depression the rate of PRF neuronal firing slowed, gradually returning to normal. This pattern of PRF periseizural neuronal firing changes differ dramatically in pattern and temporal characteristics from those previously observed in inferior colliculus (IC). The IC serves as the AGS initiation site. IC neurons show extensive firing increases prior to and during the initial wild running, silence during the tonic and post-ictal phases, and gradual recovery of responses thereafter. The changes in PRF neuronal firing pattern suggest that the PRF may play a major role in the generation of the tonic phase of AGS. The premature onset of the precipitous rise in PRF neuronal firing suggests that the influence of the IC on PRF neurons may be magnified in association with AGS susceptibility. The PRF neuronal firing increases observed in the present study coupled with previous observation of AGS blockade by PRF microinjections in the GEPR-9 further support an important role of the PRF in the propagation of AGS in the GEPR-9. The mechanisms of PRF firing elevation may also be relevant in other seizure models in which the brain-stem reticular formation is implicated.

Ethanol withdrawal induces increased firing in inferior colliculus neurons associated with audiogenic seizure susceptibility

Ethanol withdrawal (ETX) in ethanol-dependent rats results in susceptibility to seizures, including generalized tonic-clonic audiogenic seizures (AGS). The inferior colliculus (IC) is strongly implicated in AGS initiation during ETX, but IC neuronal mechanisms subserving AGS are unclear. The present study examined IC (central nucleus) single neuronal firing during repeated (4 day) intragastric ethanol administration and during ETX. This involved microwire electrodes implanted chronically into freely moving rats and acoustic stimulation in intensities up to 105 dB SPL. During initial ethanol administration the animals were stuporous, and IC spontaneous neuronal firing and acoustically evoked firing at high stimulus intensities were significantly reduced. This firing reduction is consistent with the action of ethanol to enhance gamma-aminobutyric acid (GABA)-mediated inhibition, which is prominent in IC neurons at high stimulus intensities. During ETX the animals were agitated, and spontaneous IC neuronal firing and acoustically evoked firing at all stimulus intensities were significantly increased during the period of AGS susceptibility. Previous studies indicate that IC neuronal responses are tightly regulated by GABA and glutamate. The IC firing increases during ETX in the present study may involve the down-regulation of GABAA receptors and supersensitivity of glutamate receptors reported to occur during ETX. Previous studies also indicate that focal blockade of GABAA receptors or activation of glutamate receptors produces AGS susceptibility in normal rats. Therefore, the IC neuronal firing increases observed in the present study may play a critical role in initiation of AGS during ethanol withdrawal.

Seizures during ethanol withdrawal are blocked by focal microinjection of excitant amino acid antagonists into the inferior colliculus and pontine reticular formation

Physical dependence on ethanol can result in seizure susceptibility during ethanol withdrawal. In rats, generalized tonic-clonic seizures are precipitated by auditory stimulation during the ethanol withdrawal syndrome. Excitant amino acids (EAAs) are implicated as neurotransmitters in the inferior colliculus and the brain stem reticular formation, which play important roles in the neuronal network for genetic models of audiogenic seizures (AGSs). Ethanol blocks the actions of EAAs in various brain regions, including the inferior colliculus. In this study, dependence was produced by intragastric administration of ethanol for 4 days. During ethanol withdrawal, AGSs were blocked by systemic administration of competitive or noncompetitive NMDA antagonists 3-((+/-)-2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid (CPP) or dizocilpine (MK-801). Focal microinjections of NMDA or non-NMDA antagonists into the inferior colliculus or the pontine reticular formation also inhibited AGSs. MK-801 was the most potent anticonvulsant systemically. When injected into the inferior colliculus, CPP had a more potent anticonvulsant effect than either MK-801 or the non-NMDA antagonist 6-cyano-7-nitroquinoxaline-2,3-dione. The inferior colliculus was more sensitive than the pontine reticular formation to the anticonvulsant effects of both competitive NMDA and non-NMDA antagonists. The results of the present support the idea that continued ethanol administration may lead to development of supersensitivity to the action of EAAs in inferior colliculus and pontine reticular formation neurons. This may be a critical mechanism subserving AGS susceptibility during ethanol withdrawal.

Increased responsiveness of pontine reticular formation neurons associated with audiogenic seizure susceptibility during ethanol withdrawal

Susceptibility to audiogenic seizures (AGS) is observed during ethanol withdrawal (ETX). The pontine reticular formation (PRF) is implicated in the propagation pathway for AGS during ETX. The present study examined the changes in single PRF neuronal firing patterns produced by ethanol and during ETX following repeated intragastrically administered ethanol. Microwire electrode bundles were implanted into PRF and single neuronal responses in freely moving rats were examined. During initial ethanol administration the animals were stuporous, and spontaneous and acoustically-evoked PRF neuronal firing were reduced significantly. During ETX the animals were susceptible to AGS and displayed agitated and irritable behavior. At this time a significant increase in spontaneous and acoustically-evoked PRF neuronal firing was observed. Repetition-induced response attenuation (habituation) of PRF neuronal responses was significantly diminished during ETX, leading to an exaggerated acoustic startle response, which may be a physiological basis for AGS. Previous reports indicate that ethanol enhances the effects of GABA and decreases the effects of glutamate. The PRF neuronal firing increases during EXT in the present study may involve the down-regulation of GABAA receptors and supesensitivity of glutamate receptors reported to occur during ETX, which could contribute to AGS susceptibility. The PRF neuronal firing increases observed in the present study in concord with previous observation of AGS blockade by PRF microinjections during ETX further support an important role of this brain region in the propagation of AGS during ethanol withdrawal.

Inferior colliculus neuronal membrane and synaptic properties in genetically epilepsy-prone rats

Previous studies using single-unit recording techniques have shown that the inferior colliculus is critical for audiogenic seizure initiation in genetically epilepsy-prone rats (GEPR). In order to investigate cellular abnormalities that may be important in causing audiogenic seizure susceptibility, intracellular recordings were made from neurons of inferior colliculus dorsal cortex (ICd) in a GEPR variety that exhibits severe audiogenic seizures (GEPR-9). GEPR neuronal membrane and synaptic properties were compared to those of normal Sprague-Dawley rats (SD), the strain from which GEPR were derived. We found six electrophysiological differences between GEPR and normal SD ICd neurons, all of which could promote seizures in GEPR. (1) Input resistance was higher in GEPR than in normal ICd neurons. (2) Threshold for repetitive action potential firing was closer to resting membrane potential in GEPR ICd neurons. (3) GEPR neurons showed faster repetitive spike firing than normal SD neurons. (4) Anode break spikes occurred at the offset of a hyperpolarizing pulse more often in GEPR than in normal SD neurons. (5) Stimulation of the commissure of the inferior colliculus caused synaptic paired pulse inhibition in normal ICd neurons, but paired pulse facilitation was always observed in GEPR neurons. (6) In GEPR, a large epileptiform depolarizing event could be elicited by strong electrical stimulation of the commissure of the inferior colliculus. In normal SD rats, similar epileptiform activity was seen only after application of bicuculline or NMDA. Our results suggest that both abnormal neuronal membrane properties and altered synaptic transmission are likely to contribute to seizure predisposition and audiogenic seizure initiation in GEPR.

Loss of synaptic inhibition during repetitive stimulation in genetically epilepsy-prone rats (GEPR)

Genetically epilepsy-prone rats (GEPR) are an animal model of generalized motor seizures. The underlying causes of the predisposition to seizures in GEPR have not been fully determined. The brainstem auditory system is critical for audiogenic seizures in GEPR, and neurophysiological abnormalities have been observed in these areas, but recent evidence suggests that non-auditory brain areas may also be abnormal. This may account for the lowered threshold in GEPR for various non-audiogenic seizures. Because the normal responses of the hippocampal Schaffer collateral/CA1 synapse are relatively well understood, we studied single and repetitive synaptic responses in hippocampal slices of GEPR in vitro. Our hypothesis was that altered excitatory or inhibitory synaptic transmission may contribute to GEPR non-audiogenic seizure predisposition. We recorded extracellular EPSPs, population spikes, and afferent volleys in hippocampal area CA1, and compared GEPR responses to those of Sprague-Dawley (SD) rats, the strain from which GEPR were derived. GEPR responses to single synaptic stimuli were not significantly different from SD. The second of a pair of closely spaced EPSPs or population spikes was larger in both GEPR and SD (paired pulse facilitation), but the magnitude of population spike facilitation was significantly increased in GEPR. Short trains of four stimuli caused inhibition of population spike firing in SD, an effect that was much reduced in GEPR. When SD slices were treated with bicuculline, a GABAA receptor antagonist, enhanced paired pulse facilitation and loss of inhibition during trains of stimuli were seen, similar to the patterns seen in GEPR.(ABSTRACT TRUNCATED AT 250 WORDS)

Blockade of GABA uptake with tiagabine inhibits audiogenic seizures and reduces neuronal firing in the inferior colliculus of the genetically epilepsy-prone rat

Tiagabine is a new anticonvulsant drug that blocks the uptake of GABA, prolonging the action of this inhibitory transmitter. In the present study the effects of systemically administered tiagabine [30 mg/kg, ip (ED50)] were examined on audiogenic seizure (AGS) severity and neuronal firing in the inferior colliculus (IC) in the freely moving genetically epilepsy-prone rat (GEPR-9). The IC is known to be critical to AGS initiation. The effects of focal microinjection of tiagabine into the IC were also examined. Bilateral focal microinjection of tiagabine into the IC significantly reduced seizure severity in the GEPR-9. Systemically administered tiagabine also produced a significant reduction in seizure severity in the GEPR-9. Tiagabine produced a reduction in IC (central nucleus) neuronal firing, which was significant only at high acoustic intensities (90-105 dB), concomitant with the considerable reduction in seizure severity. These data are consistent with enhancement by tiagabine of gamma-aminobutyric acid (GABA)-mediated inhibition in IC, which is most prominent at high acoustic intensities. The time course of the reduction in neuronal firing of IC neurons paralleled the reduction in seizure severity. Previous studies have shown that two forms of GABA-mediated inhibition (intensity-induced and offset inhibition) in IC neurons are most prominent at high stimulus intensities, which are required to induce AGS. The blockade of GABA uptake by tiagabine may act to inhibit audiogenic seizures, in part, by intensifying these naturally occurring forms of acoustically evoked inhibition in inferior colliculus neurons.

GABA in the inferior colliculus plays a critical role in control of audiogenic seizures

Previous studies have implicated a decreased efficacy of GABA as an important defect subserving the audiogenic seizures of the genetically epilepsy-prone rat (GEPR-9). The inferior colliculus (IC) is a critical site for audiogenic seizure (AGS) initiation, and the pontine reticular formation (PRF) is implicated in the propagation of AGS and in other generalized seizure models. The present study observed that microinjection of baclofen, a GABA-B receptor agonist, into IC protects against AGS, and blockade of the breakdown of endogenous GABA by gabaculine, a GABA transaminase inhibitor, increased GABA levels and blocked AGS susceptibility in the GEPR-9. Microinjection of baclofen or gabaculine into the PRF reduced AGS severity, but the doses required were considerably greater and the degree of anticonvulsant effect was less. Uptake of [3H]GABA into GEPR-9 synaptosomes from the IC is significantly increased as compared to normal, which could contribute to the diminished effectiveness of GABA in the GEPR-9. Previous studies indicate that GABA-A receptor agonists block AGS with IC microinjection, and recent data indicate that blockade of GABA uptake in this nucleus significantly reduced AGS severity. These data taken together strongly support the critical importance of the defect in GABA function in the IC in modulating susceptibility to audiogenic seizure initiation in the GEPR-9.

Stimulation or blockade of the dorsal nucleus of the lateral lemniscus alters binaural and tonic inhibition in contralateral inferior colliculus neurons

Recent studies have demonstrated that several specific types of acoustically-evoked GABA-mediated inhibition occur in neurons of the central nucleus of inferior colliculus (ICc). The dorsal nucleus of the lateral lemniscus (DNLL) provides a major GABAergic projection to ICc. The present study examined the effects of electrical or chemical stimulation or reversible blockade within the DNLL on the discharge characteristics of ICc neurons in anesthetized rats. Microinjection of a local anesthetic (lidocaine) or a GABA-A agonist (THIP) via a cannula placed into DNLL reversibly blocked acoustically-evoked binaural inhibition and increased spontaneous firing in most contralateral ICc neurons. Trains of electrical pulses or microinjection of the excitant amino acid, kainate, into DNLL resulted in reduced acoustically-evoked firing, which was similar to binaural inhibition, in most contralateral ICc neurons examined. The effects of DNLL electrical stimulation were reversibly blocked by microinjection of THIP into the stimulation site, suggesting that the effect of the electrical stimulation is mediated by direct effects on cell bodies of DNLL neurons. These data support the idea that contralateral GABAergic input from the DNLL is inhibitory to ICc neurons. Thus, binaural inhibition and tonic inhibition in ICc neurons may be mediated, in part, by the GABAergic projection from the contralateral DNLL.

Noncompetitive and competitive NMDA antagonists exert anticonvulsant effects by actions on different sites within the neuronal network for audiogenic seizures

Excitant amino acids are implicated in audiogenic seizure (AGS) susceptibility in the genetically epilepsy-prone rat (GEPR). In the present study systemic administration of NMDA receptor antagonists significantly decreased AGS severity in the GEPR. Systemic administration of the competitive NMDA antagonists 3-((+-)-2-carboxypiperazin-4-yl)-propyl-1-phosphonate (CPP) and 2-amino-7-phosphonoheptanoic acid and the non-competitive antagonist dizocilpine (MK-801) were effectively anticonvulsant in the GEPR. The inferior colliculus is the most critical nucleus for AGS initiation in the GEPR and an excitant amino acid is implicated as an important excitatory transmitter in inferior colliculus neurons. Systemically administered CPP significantly reduced inferior colliculus neuronal firing in the normal behaving rat and the GEPR concurrently with blockade of AGS and this effect occurred at nearly all sound intensities tested. Systemic administration of MK-801, while effective in blocking AGS, produced no consistent change in inferior colliculus neuronal firing, which is consistent with its very low potency in blocking AGS with bilateral microinjection into the inferior colliculus. These findings suggest that an important action of competitive, but not noncompetitive, NMDA antagonists is on brain stem auditory nuclei, especially the inferior colliculus, that are critical to AGS. MK-801 appears to exert its anticonvulsant effects in AGS network sites beyond the inferior colliculus. These findings and recent inferior colliculus slice studies suggest that NMDA receptors in inferior colliculus may have quantitatively different properties from those in other brain regions. These differences in NMDA receptor function in inferior colliculus may reflect NMDA receptor heterogeneity observed in binding studies.(ABSTRACT TRUNCATED AT 250 WORDS)

Glutamate in the inferior colliculus plays a critical role in audiogenic seizure initiation

Alterations of excitant amino acid (EAA) action are implicated in seizure susceptibility in the genetically epilepsy-prone rat (GEPR). The inferior colliculus (IC) is critical for audiogenic seizure (AGS) initiation in the GEPR. The present study observed that bilateral microinjection into the IC of L-canaline, a glutamate synthesis inhibitor, decreased AGS severity in the GEPR and also decreased potassium-evoked release of glutamate from IC slices. Bilateral microinjection of NMDA receptor antagonists, 2-amino-7-phosphonoheptanoate (AP7) or 3-((+/-)-2-carboxypiperazin-4-yl)-propyl-1-phosphonate (CPP) into IC blocked AGS, and an antagonist at non-NMDA EAA receptors, 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), also blocked AGS. NMDA receptor antagonists were 5-200 times more effective than CNQX. Microinjection of a non-competitive NMDA receptor antagonist, dizocilpine (MK-801), into IC had little effect except with very high doses. Microinjection of CPP or AP7 into the IC blocked AGS at considerably lower doses as compared to pontine reticular formation (PRF). However, MK-801 attenuated AGS when microinjected into PRF at doses that were ineffective in IC. Systemically administered CPP blocked AGS and significantly reduced IC neuronal firing in the behaving GEPR, suggesting an important action of systemically administered NMDA receptor antagonists on brainstem auditory nuclei critical to AGS. The present results support a critical role for glutamate acting, in part, through NMDA receptors in IC in initiation of AGS.

Repetition of audiogenic seizures in genetically epilepsy-prone rats induces cortical epileptiform activity and additional seizure behaviors

Repetition of seizures appears to increase severity in a number of seizure models, but the nature of these severity increases has not been elucidated in naturally occurring genetic epilepsy models. The genetically epilepsy-prone rat (GEPR) is highly susceptible to many seizure provoking stimuli, and high intensity acoustic stimuli induce audiogenic seizures (AGS). The role of forebrain structures in AGS in the GEPR has not been clear, and the presence of cortical epileptiform EEG activity in the GEPR is controversial. The present study examined the effects of 21 daily AGS repetitions on behavior and EEG activity recorded from the cortex of two GEPR substrains that exhibit moderate (GEPR-3) or severe AGS (GEPR-9). The results indicated that AGS repetition induced seizure severity increases in both GEPR substrains and resulted in prominent cortical epileptiform EEG activity. The AGS behavioral patterns remained distinctly different in the two substrains throughout seizure repetition. In each substrain a different additional behavioral phase was expressed; the GEPR-9 exhibited post-tonic clonus, and the GEPR-3 exhibited facial and forelimb clonus. These findings indicate that seizure repetition results in expansion of the neuronal network subserving AGS to involve forebrain structures. The medial geniculate body and amygdala appear to be part of this expanded network, and long-term potentiation, which was reported in the pathway between the latter brain structures, may be involved. These data suggest that recruitment of forebrain structures into the AGS neuronal network appears to be essential for production of the additional ictal behaviors evoked by AGS repetition.

Loss of intensity-induced inhibition in inferior colliculus neurons leads to audiogenic seizure susceptibility in behaving genetically epilepsy-prone rats

The genetically epilepsy-prone rat (GEPR) exhibits elevated seizure sensitivity and audiogenic seizures (AGS). The inferior colliculus (IC) is the most critical brain region for AGS initiation. The present study evaluated IC neuronal firing and convulsive behavior simultaneously in freely moving GEPRs. High intensity acoustic stimulation produces neuronal firing reductions (intensity-induced inhibition) in about 50% of IC neurons in normal rats. However, in GEPR IC neurons, intensity-induced inhibition is significantly less effective than normal. Offset inhibition is also reduced in GEPR IC neurons, which leads to a greater than normal incidence of offset (afterdischarge) responses at high stimulus intensities. At AGS onset most IC neurons exhibit burst firing and reductions of acoustically evoked neuronal responses. Responsiveness to acoustic stimuli returns following AGS. This change in IC neuronal firing pattern suggests that the network that governs IC neuronal firing has temporarily changed from the auditory system to the network that mediates seizure propagation. GABA is strongly implicated in intensity-induced, binaural, and offset inhibition in IC neurons. The diminished efficacy of these forms of GABA-mediated acoustically evoked inhibition in the GEPR IC extends previous results, showing reduced effectiveness of exogenously applied GABA and benzodiazepine in GEPR IC neurons. This reduced effectiveness of GABA-mediated inhibition along with excess excitant amino acids in GEPR IC, previously reported, appear to be vital neurotransmitter mechanisms, subserving the exaggerated output of IC neurons at high acoustic intensities. This exaggerated IC firing may be instrumental in seizure initiation in this epilepsy model.

Effect of norepinephrine depletion on audiogenic-like seizures elicited by microinfusion of an excitant amino acid into the inferior colliculus of normal rats

Infusions of an excitant amino acid, N-methyl-D-aspartate (NMDA) into the inferior colliculus (IC) render normal rats susceptible to audiogenic seizures (AGS) and/or spontaneous audiogenic-like seizures without tonic components. The excess excitant amino acid in the IC and the anticonvulsant effects of NMDA antagonists in genetically epilepsy-prone rats (GEPRs), along with innate norepinephrine (NE) deficits and anticonvulsant effects of NE agonists in these animals suggest a mutual role of excitant amino acids and NE in regulating AGS in GEPRs. Saline or 6-hydroxydopamine (6-OHDA, 4 micrograms/side in 2 microliters) was infused bilaterally into the locus coeruleus (LC) of normal male rats and guide cannulas were implanted into the IC. Two weeks later, NMDA was infused bilaterally into the IC (0.5 microliters; 10 nmol/side) and 10 min later the rats were subjected to an electric bell (110 db, 60 s) unless preceded by spontaneous tonic seizures. Tonic seizures were not observed in male rats following NMDA infusions in rats with LC infusions of saline. However, a marked increase in the incidence of tonic seizures was observed in the 6-OHDA-treated rats which were markedly depleted of brain NE as determined by HPLC. These findings indicate that a NE deficit greatly enhances the incidence of tonic convulsions and support the hypothesis that an excitant amino acid excess in the GEPR IC may act to initiate AGS, whereas the NE deficit may allow expression of the tonic components of AGS seen in some GEPRs.

Involvement of GABA in acoustically-evoked inhibition in inferior colliculus neurons

Most criteria for establishing GABA as an inhibitory neurotransmitter in the central nucleus of inferior colliculus (ICc) have been satisfied, but the role of GABA in acoustic coding in ICc is not established. The present study examined this issue by evaluating the effects of iontophoretic application of agents that alter activity at GABA receptors on potential forms of acoustically-evoked inhibition in ICc neurons. Application of the GABAA antagonist, bicuculline, selectively blocked the firing reduction at high intensities observed during non-monotonic rate-intensity functions in ICc neurons. Binaural inhibition was selectively blocked by bicuculline and increased by nipecotic acid. Application of GABA, nipecotic acid (GABA uptake inhibitor) and a benzodiazepine (flurazepam), which enhances the action of GABA, increased the duration and intensity of ipsilateral inhibition and response pause, while bicuculline blocked these acoustically-evoked inhibitory events. Offset inhibition was increased by nipecotic acid application and reduced by bicuculline with the appearance of an offset peak. The present data support an important role for GABA as a neurotransmitter, mediating, in part, non-monotonicity, binaural inhibition, response pause and offset inhibition in ICc neurons. Alterations of these GABA-mediated inhibitory phenomena may occur in auditory dysfunctions observed with aging and audiogenic seizures.

Audiogenic seizure severity and hearing deficits in the genetically epilepsy-prone rat

Hearing deficits have been observed in rodents that are susceptible to audiogenic seizures (AGS), including the genetically epilepsy-prone rat (GEPR). AGS susceptibility can be induced in normal animals by treatments that damage the cochlea. In this study, we measured the relative degree of hearing loss in animals from the GEPR substrains that exhibit different degrees of AGS severity and examined the relationship between the deficit and the AGS severity. Auditory brain stem response (ABR) thresholds to clicks in the GEPR substrain that exhibits exclusively maximal AGS severity (GEPR-9) were significantly elevated, and latencies for ABR peaks I, III, and IV were significantly increased as compared to normal Sprague-Dawley rats. ABR thresholds for the substrain of GEPRs were even higher than those in the GEPR-9, and ABR waveforms were distorted. ABR peak IV was significantly longer than normal in the GEPR-3 substrain, as were mean interpeak intervals and central conduction times. These data indicate that significant hearing deficits occur in the GEPR-3 substrain. In non-AGS-susceptible progeny of the GEPR-9 [GEPR-0(9)], ABR thresholds were not significantly different from normal. These data along with studies of ABR thresholds in thyroid-deficient rats suggest that an inverted U-shaped relationship exists between hearing deficit and AGS severity. That is, moderate threshold elevations are associated with increasing AGS severity, but when the hearing deficit exceeds a certain level, a decrement in AGS severity occurs.

Non-N-methyl-D-aspartate receptors may mediate ipsilateral excitation at lateral superior olivary synapses

Principal cells of the lateral superior olivary nucleus (LSO) are thought to receive a direct excitatory input from spherical bushy cells located in the ipsilateral ventral cochlear nucleus (VCN) and an indirect input from the contralateral VCN globular bushy cells via a secure synapse in the medial nucleus of the trapezoid body (MNTB). MNTB bushy cells project to the somata and proximal dendrites of LSO principal cells. LSO neurons display phasic 'chopper' temporal response patterns to ipsilateral tone-burst stimuli at characteristic frequency (CF), while binaural stimuli suppress this ipsilaterally evoked activity. This suppression is sensitive to interaural differences in intensity, phase and time, suggesting a role for these neurons in the localization of sound in space. In the present study, the nature of the neurotransmitter mediating fast ipsilateral excitation of LSO neurons was examined using iontophoretic application of excitant amino acid (EAA) agonists and antagonists. N-methyl-D-aspartate (NMDA) and quisqualate (QUIS) were used as agonists, while the selective NMDA receptor antagonist D. L-2-amino-5-phosphonovaleric acid (APV), and the non-selective receptor EAA antagonist cis-2,3-piperidine-dicarboxylic acid (PDA) were used to study ipsilaterally evoked neuronal responses. In 3 additional experiments the selective non-NMDA receptor antagonist 6,7-dinitroquinoxaline-2,3-dione (DNQX) replaced PDA. Ipsilateral, tone-evoked and spontaneous activities were generally enhanced by EAA agonists while partial blockade of tone-evoked, ipsilateral excitation was observed with EAA antagonists. Both PDA and DNQX more effectively blocked ipsilateral tone-evoked excitations and spontaneous activity than did the NMDA-receptor antagonist, APV.(ABSTRACT TRUNCATED AT 250 WORDS)

On the role of GABA as an inhibitory neurotransmitter in inferior colliculus neurons: iontophoretic studies

Significant neurochemical, immunocytochemical, and ligand binding studies support a role for GABA as an inhibitory neurotransmitter in the inferior colliculus (IC). The present study attempted to satisfy some of the remaining criteria for establishing transmitter identity by utilizing iontophoretic application onto IC neurons of agents affecting the action of gamma-aminobutyric acid (GABA). The agents examined include GABA, a GABAB agonist (baclofen), a GABAA antagonist (bicuculline), a GABA uptake inhibitor (nipecotic acid), and a benzodiazepine (flurazepam), thought to exert its actions on the GABA receptor complex. Application of GABA results in inhibition of the spontaneous firing and acoustically evoked responses of inferior colliculus neurons. The inhibitory effect of GABA is enhanced by the simultaneous application of nipecotic acid or flurazepam. These agents as well as baclofen produce firing reductions when applied alone in higher doses. The effect of GABA can be blocked by application of bicuculline, and acoustically evoked (binaural) inhibition can also be selectively blocked by low doses of this GABAA antagonist. These data along with previous studies utilizing different techniques fulfill many of the criteria for establishment of GABA as an important inhibitory transmitter in the inferior colliculus.

Injections of noradrenergic and GABAergic agonists into the inferior colliculus: effects on audiogenic seizures in genetically epilepsy-prone rats

Genetically epilepsy-prone rats (GEPRs) which display tonic seizures (GEPR-9s) in response to acoustic stimulation were used in these studies. Other laboratories have shown that GEPR-9s have a reduced concentration of brain norepinephrine (NE). Previous reports have also indicated that audiogenic seizures (AGS) in these animals are inhibited by treatments that enhance noradrenergic (NA) neurotransmission. AGS in GEPRs are believed to be initiated in the inferior colliculus (IC) where GABA has been shown to exert inhibitory influences in GEPRs that display submaximal AGS. The present study examined whether the IC is a crucial site for NA suppression of tonic seizures by examining the effect of microinfusing NA agonists into the IC. The intracollicular effect of a GABA agonist, muscimol, on sound-induced tonic convulsions in GEPR-9s was also examined. Bilateral microinfusion of NE, phenylephrine, clonidine or isoproterenol failed to alter the AGS. In contrast, muscimol (30 or 60 ng/side) infused into the IC abolished the tonic and clonic components of the AGS in GEPR-9s. These findings suggest that enhancement of GABAergic neurotransmission in the IC markedly attenuates AGS in the GEPR, while augmentation of NA neurotransmission has little effect in this brain region.

Effects of excitant amino acids on acoustic responses of inferior colliculus neurons

Iontophoretic application of the excitant amino acids (EAAs), glutamate, aspartate and N-methyl-D-aspartate (NMDA) resulted in increased acoustically evoked and spontaneous firing of most neurons in the central nucleus of inferior colliculus (ICC). The excitatory effects of these EAAs were blocked by simultaneous application of EAA antagonists which selectively block the NMDA receptor subtype, 2-amino-5-phosphonovalerate or D-alpha-aminoadipate and to a lesser extent with non-selective EAA antagonists, such as glutamic acid diethylester. Application of NMDA receptor-selective EAA antagonists alone greatly reduced the firing of most ICC neurons examined, but non-selective EAA antagonists either increased or produced little change in firing of most ICC neurons examined. In this and previous studies cholinergic agonists were found to increase the firing of ICC neurons, but the cholinergic agonists were less effective in exciting ICC neurons than EAA agonists. Cholinergic antagonists in a previous study were considerably less effective in inhibiting the discharge of ICC neurons than were the EAA antagonists in the present study. These results, in conjunction with previous neurochemical and anatomical localization studies, support a possible role of an EAA as a candidate for afferent excitatory transmitter in neurons of the inferior colliculus.

Induction of audiogenic seizures in normal and genetically epilepsy-prone rats following focal microinjection of an excitant amino acid into reticular formation and auditory nuclei

An excitant amino acid (EAA), N-methyl-D-aspartate (NMDA), induces susceptibility to seizures when bilaterally microinjected into subcortical auditory nuclei of normal rats. Thirty-five percent of animals exhibit only audiogenic seizures (AGS) after infusions of NMDA into inferior colliculus (IC). Infusions into cochlear nucleus and medial geniculate body never produce susceptibility to AGS without non-audiogenic seizures (N-AGS). The overall seizure incidence (AGS and N-AGS) with IC infusions is 100%, but the incidence is less than 50% with infusions into cochlear nucleus or medial geniculate body. Although AGS susceptibility is induced by NMDA infusions in normal animals, the seizures are submaximal in severity and lack tonic components. Bilateral infusions of NMDA into IC or reticular formation of the substrain of genetically epilepsy-prone rats (GEPRs) that exhibits submaximal AGS (GEPR-3s) do not increase seizure severity. These data along with studies showing increased EAA levels and excitotoxic-like damage in the IC of the GEPR and blockade of AGS with an EAA receptor antagonist or synthesis inhibitor suggest that an EAA in the IC is involved in initiation of AGS in the GEPR. However, EAA action in the GEPR IC is not sufficient to induce the complete spectrum of seizure behaviors, and additional mechanisms may be required for induction of maximal severity audiogenic seizures.

Excitant amino acids and audiogenic seizures in the genetically epilepsy-prone rat. I. Afferent seizure initiation pathway

The afferent pathway involved in initiation of audiogenic seizures in the genetically epilepsy-prone rat was investigated by bilateral microinfusion of the excitant amino acid antagonist 2-amino-7-phosphonoheptanoate into the major brain stem and subcortical nuclei of the auditory system. This antagonist has been shown to possess anticonvulsant properties in other seizure models, and an excitant amino acid has been implicated as a putative neurotransmitter in several of these nuclei. Seizure severity was significantly reduced following infusion of this agent into the cochlear nucleus, superior olivary complex, inferior colliculus, and medial geniculate body. Many of these animals exhibited a complete blockade of seizures. The smallest effective dose in the cochlear nucleus and the medial geniculate body was 5 nmol per side. The smallest effective dose in the olive was 1 nmol, and in the inferior colliculus 0.1 nmol per side was protective. The onset of anticonvulsant effectiveness was earliest in the inferior colliculus. These findings showed that the inferior colliculus was the most sensitive auditory center to the anticonvulsant action of 2-amino-7-phosphonoheptanoate and that imbalance between inhibitory and excitatory transmission within this brain structure may be crucial in the initiation of audiogenic seizures in the genetically epilepsy-prone rat.

Excitant amino acids and audiogenic seizures in the genetically epilepsy-prone rat. II. Efferent seizure propagating pathway

Previous studies indicate that the inferior colliculus is the brain stem auditory nucleus most sensitive to the chemical blockade of audiogenic seizures in the genetically epilepsy-prone rat. Other auditory structures do not appear to be as important. This study attempted to define the efferent pathways involved in propagation of the seizure from the colliculus to the spinal cord where the motor components of the convulsion are generated. This study also determined whether certain nuclei which have been implicated in the propagation of seizures in other epilepsy models are involved in audiogenic seizures. The excitant amino acid antagonist, 2-amino-7-phosphonoheptanoate, was infused bilaterally into several of those sites. The drug was effective in significantly reducing seizure severity with infusion of 5 nmol bilaterally into the midbrain and the pontine reticular formation or the substantia nigra. However, similar drug doses were not effective when infused into the entopeduncular nucleus even though prominent behavioral effects were observed with this infusion. Infusion of 2-amino-7-phosphonoheptanoate into the prepiriform cortex resulted in a small but significant reduction in seizure severity. These results suggest that inhibition of excitatory transmission within the substantia nigra and the reticular formation effectively blocks the output pathway for the audiogenic seizures, whereas the role of the prepiriform cortex in this process is relatively minor.

The genetically epilepsy-prone rat

1. The genetically epilepsy-prone rat (GEPR) is a valuable model for investigating mechanisms involved in epilepsy because of the controllable nature of the convulsions and their genetic origin. 2. The GEPR exhibits audiogenic seizures (AGS) and also displays higher than normal sensitivity to convulsant drugs, kindling, electroshock and hyperthermic seizures. 3. An abnormal electroencephalographic pattern and increased thresholds for auditory evoked potentials from the cochlea and brainstem are observed in the GEPR. 4. Afterdischarge-like responses and decreased sound-induced inhibition are observed in neurophysiological recordings from neurons of the inferior colliculus (IC) in the GEPR. 5. Significant deficits of norepinephrine and serotonin are observed in many regions of the GEPR brain. 6. Increases in the number of GABAergic neurons and a reduced effectiveness of iontophoretically-applied GABA are observed in the IC of this animal. 7. GABA agonists or an excitant amino acid (EAA) antagonist block AGS susceptibility when microinjected into brainstem auditory nuclei of the GEPR up to the level of IC. 8. A GABA antagonist or an EAA agonist induces susceptibility to AGS in normal rats following microinjection into IC. An increase in EAA release in IC during AGS in the GEPR is also observed. 9. This increased release of EAA and the reduced effectiveness of GABA in IC may be important seizure initiation mechanisms in the GEPR. 10. The AGS pathway in the GEPR appears to involve the auditory nuclei up to the IC as well as the brainstem reticular formation and substantia nigra but not the entopenduncular nucleus or hippocampus.

Strychnine alters the fusiform cell output from the dorsal cochlear nucleus

Anatomical and physiological evidence suggests that fusiform cells, the major output neurons of the dorsal cochlear nucleus (DCN), receive significant inhibitory input. Fusiform cells often display strongly non-monotonic rate-intensity functions and pauser-buildup or buildup tone-evoked temporal responses, patterns which may be mediated by inhibitory neurotransmitters. Other neurons located within the fusiform cell layer or in the more superficial molecular layer display varied rate-intensity functions and temporal responses. Neurons displaying response properties characteristic of fusiform cells are sensitive to iontophoretic application of the inhibitory amino acid neurotransmitter, glycine. Application of the glycine receptor antagonist, strychnine, alters the non-monotonic portion of the rate-intensity function at doses which do not alter spontaneous activity or near-threshold tone-evoked responses. These neurons are also sensitive to GABA and the GABAB agonist, (-)-baclofen, but are insensitive to the GABAA antagonist, bicuculline. DCN neurons which display monotonic rate-intensity functions and temporal response properties different than those associated with fusiform cells are sensitive to bicuculline, (-)-baclofen, and GABA. These data suggest that a glycinergic input onto fusiform cells may control the non-monotonic nature of the response of these neurons near characteristic frequency and therefore may contribute significantly to the nature of the output of the DCN.