Inhibition of neuronal Ca(2+) influx by gabapentin and subsequent reduction of neurotransmitter release from rat neocortical slices

A comparison of Ca2+ channel blocking mode between gabapentin and verapamil: implication for protection against hypoxic injury in rat cerebrocortical slices

1 The mode of Ca(2+) channel blocking by gabapentin [1-(aminomethyl)cyclohexane acetic acid] was compared to those of other Ca(2+) channel blockers, and the potential role of Ca(2+) channel antagonists in providing protection against hypoxic injury was subsequently investigated in rat cerebrocortical slices. 2 mRNA for the alpha(2)delta subunits of Ca(2+) channels was found in rat cerebral cortex. 3 Nitric oxide (NO) synthesis estimated from cGMP formation was enhanced by KCl stimulation, which was mediated primarily by the activation of N- and P/Q-type Ca(2+) channels. Gabapentin blocked both types of Ca(2+) channels, and preferentially reversed the response to 30 mM K(+) stimulation compared with 50 mM K(+) stimulation. In contrast, verapamil preferentially inhibited the response to depolarization by the higher concentration (50 mM) of K(+). 4 Gabapentin inhibited KCl-induced elevation of intracellular Ca(2+) in primary neuronal culture. 5 Hypoxic injury was induced in cerebrocortical slices by oxygen deprivation in the absence (severe injury) or presence of 3 mM glucose (mild injury). Gabapentin preferentially inhibited mild injury, while verapamil suppressed only severe injury. omega-Conotoxin GVIA (omega-CTX) and omega-agatoxin IVA (omega-Aga) were effective in both models. 6 NO synthesis was enhanced in a manner dependent on the severity of hypoxic insults. Gabapentin reversed the NO synthesis induced by mild insults, while verapamil inhibited that elicited by severe insults. omega-CTX and omega-Aga were effective in both the cases. 7 Therefore, the data suggest that gabapentin and verapamil cause activity-dependent Ca(2+) channel blocking by different mechanisms, which are associated with their cerebroprotective actions and are dependent on the severity of hypoxic insults.

Pregabalin: a new anxiolytic

Pregabalin (S-[+]-3-isobutylgaba) was designed as a lipophilic GABA (gamma-aminobutyric acid) analogue substituted at the 3'-position in order to facilitate diffusion across the blood-brain barrier. It was originally developed as an anticonvulsant agent, however it has been shown to be effective in the treatment of several disorders including hyperalgesia and behavioural disorders. Although its exact mode of action remains unclear, pregabalin interacts with the same binding site and has a similar pharmacological profile as its predecessor, gabapentin (1-[aminomethyl] cyclohexane acetic acid). Its main site of action appears to be on the alpha(2)delta subunit of voltage-dependent calcium channels, widely distributed throughout the peripheral and central nervous system. Pregabalin appears to produce an inhibitory modulation of neuronal excitability. In healthy volunteers, it is rapidly absorbed with peak blood concentrations within 1 h and it has a bioavailability of approximately 90%. In preclinical trials of anticonvulsant activity, pregabalin is three to ten times more potent than gabapentin. It is well-tolerated and associated with dose-dependent adverse effects (ataxia, dizziness, headache and somnolence) that are mild-to-moderate and usually transient. There are no known pharmacokinetic drug-drug interactions reported to date. Preliminary animal and human studies showed beneficial effects in both ethological and conflict models of anxiety, as well as having some sleep-modulating properties. In Phase II and III trials, pregabalin shows promising anxiolytic action when compared to placebo in generalised anxiety disorder, social phobia and panic disorder.

Gabapentin-- actions on adult superficial dorsal horn neurons

Despite identification of GABA(B) receptors with gb1a-gb2 composition and the alpha2delta calcium channel subunit as putative molecular targets for gabapentin (GBP), its cellular mechanism of action has remained elusive. Therefore, we have used an in vitro spinal cord slice preparation to study the effects of GBP on lamina II neurons. The frequency and amplitude of spontaneous EPSCs and IPSCs were unaffected by GBP, suggesting presynaptic neurotransmitter release is not regulated. Direct modulation of postsynaptic membrane excitability is also unlikely since the level of holding current required to maintain neurons at -70, 0 and +45 mV was unaffected by GBP. Effects on excitatory and inhibitory synaptic transmission were variable across the population. Primary afferent-evoked fast glutamatergic EPSCs were unaffected by GBP, while evoked NMDA receptor-mediated EPSCs and IPSCs were variably affected. In contrast, GBP enhanced responses to bath applied NMDA in 71% of neurons. Thus, in adult rat dorsal horn, synaptic and extrasynaptic NMDA receptors may be differentially regulated by GBP perhaps due to differences in subunit composition.

Anticonvulsants in central pain

Treatment of central neuropathic pain (CP) following lesions of the CNS is a great challenge to the clinician. Preclinical and clinical studies indicate that neuronal hyperexcitability in damaged areas of the central nervous system plays a major role in the development of CP. Anticonvulsants are thought to act by increasing gamma-aminobutyric acid-mediated inhibition, decreasing abnormal neuronal hyperexcitability by modulating sodium and calcium channels or by inhibiting excitatory amino acid actions. The resulting inhibition of excess neuronal activity is thought to be the basis for the use of anticonvulsants in epilepsy as well as neuropathic pain. Both first-generation anticonvulsant drugs (e.g., phenytoin, benzodiazepines, valproate and carbamazepine) and second-generation anticonvulsant drugs (e.g., lamotrigine, gabapentin and topiramate) are used in CP conditions. However, few randomised controlled trials on the treatment of this condition have been published. Present suggestions for anticonvulsant treatment of CP are lamotrigine as the first choice, followed by gabapentin or carbamazepine/oxcarbazepine. These compounds are considered as effective as the antidepressant amitriptyline.

Preferential action of gabapentin and pregabalin at P/Q-type voltage-sensitive calcium channels: inhibition of K+-evoked [3H]-norepinephrine release from rat neocortical slices

Gabapentin (GBP; Neurontin) and pregabalin (PGB; CI-1008), efficacious drugs in several neurological and psychiatric disorders, inhibit neurotransmitter release from mammalian brain slices at therapeutically relevant concentrations. A detailed investigation, exploring the basis for this in vitro phenomenon, focused on norepinephrine (NE) and rat neocortical tissue in complementary assays of neurotransmitter release and radioligand binding. The results are consistent with the hypothesis that GBP, PGB, and related substances decrease neocortical NE release by acting at the alpha2delta subunit of presynaptic P/Q-type voltage-sensitive Ca2+ channels (VSCC) subserving Ca2+ influx in noradrenergic terminals. The inhibitory action appears competitive with [Ca2+]o and preferential to those neurons undergoing prolonged depolarization. Other results indicate that the reduction of exocytotic NE release is independent of L- and N-type VSCC, classical drug/peptide binding sites on VSCC, Na+ channels, alpha2-adrenoceptors, NE transporter, and system L amino acid transporter. These findings suggest a selective modulation of P/Q-type VSCC that are implicated in neurotransmission and several GBP-responsive pathologies.

Gabapentin inhibits presynaptic Ca(2+) influx and synaptic transmission in rat hippocampus and neocortex

Gabapentin is a widely used drug with anticonvulsant, antinociceptive and anxiolytic properties. Although it has been previously shown that Gabapentin binds with high affinity to the alpha(2)delta subunit of voltage-operated Ca(2+) channels (VOCC), little is known about the functional consequences of this interaction. Here, we investigated the effect of Gabapentin on VOCCs and synaptic transmission in rat hippocampus and neocortex using whole-cell patch clamp and confocal imaging techniques. Gabapentin (100-300 microM) did not affect the peak amplitude or voltage-dependency of VOCC currents recorded from either dissociated or in situ neocortical and hippocampal pyramidal cells. In contrast, Gabapentin inhibited K(+)-evoked increases in [Ca(2+)] in a subset of synaptosomes isolated from rat hippocampus and neocortex in a dose-dependent manner, with an apparent half-maximal inhibitory effect at approximately 100 nM. In hippocampal slices, Gabapentin (300 microM) inhibited the amplitude of evoked excitatory- and inhibitory postsynaptic currents recorded from CA1 pyramidal cells by 30-40%. Taken together, the results suggest that Gabapentin selectively inhibits Ca(2+) influx by inhibiting VOCCs in a subset of excitatory and inhibitory presynaptic terminals, thereby attenuating synaptic transmission.

Ca2+ channels and epilepsy

The epilepsies encompass diverse seizure disorders afflicting as many as 50 million people worldwide. Many forms of epilepsy are intractable to current therapies and there is a pressing need to develop agents and strategies to not only suppress seizures, but also cure epilepsy. Recent insights from molecular genetics and pharmacology now point to an important role for voltage-dependent calcium channels in epilepsy. In this article, I first provide an introduction to the classification of the epilepsies and an overview of neuronal Ca(2+) channels. Next, I attempt to review the evidence for a role of Ca(2+) channels in epilepsy and the insights gained from genetics and pharmacology. Lastly, I describe new avenues for how such information might be exploited in the development of therapeutic reagents.

Gabapentin: pharmacology and its use in pain management

Although its exact mode of action is not known, gabapentin appears to have a unique effect on voltage-dependent calcium ion channels at the postsynaptic dorsal horns and may, therefore, interrupt the series of events that possibly leads to the experience of a neuropathic pain sensation. Gabapentin is especially effective at relieving allodynia and hyperalgesia in animal models. It has been shown to be efficacious in numerous small clinical studies and case reports in a wide variety of pain syndromes. Gabapentin has been clearly demonstrated to be effective for the treatment of neuropathic pain in diabetic neuropathy and postherpetic neuralgia. This evidence, combined with its favourable side-effect profile in various patient groups (including the elderly) and lack of drug interactions, makes it an attractive agent. Therefore, gabapentin should be considered an important drug in the management of neuropathic pain syndromes.

The interaction between gabapentin and amitriptyline in the rat formalin test after systemic administration

We examined the effects of systemically administered gabapentin on flinching and biting/licking behaviors produced by 2.5% formalin in the rat, compared these with those of amitriptyline, and determined the effects of combinations of gabapentin with amitriptyline. Gabapentin produced a dose-related inhibition of Phase 2, but not Phase 1, flinching and biting/licking behaviors. In contrast, amitriptyline produced an increase in Phase 2 flinching behaviors while simultaneously decreasing biting/licking behaviors. Fifty percent effective dose (ED50) values against biting/licking behaviors were 22.9 +/- 1.3 mg/kg and 8.5 +/- 1.3 mg/kg for gabapentin and amitriptyline, respectively. Combinations of increasing fractional increments of ED50 doses of gabapentin and amitriptyline produced an additive effect against biting/licking behaviors, as revealed by isobolographic analysis. These increments had no effect on flinching behaviors except at the ED25 + ED25 doses, at which flinching was increased, again revealing additivity between the two drugs. Flinching behaviors in rats do not reflect the analgesic properties of systemically administered amitriptyline observed in humans and may not be useful for predicting an effect of combinations of drugs with amitriptyline. Biting/licking behaviors do reflect analgesic properties for both drugs and may be more useful in this regard.

IMPLICATIONS

By use of the rat formalin test, a model of persistent pain, we examined the effect of a combination of amitriptyline and gabapentin, which are used to treat chronic pain in humans. The drug combination produced additive analgesia against one outcome, but another outcome was more ambiguous.

Gabapentin-mediated inhibition of voltage-activated Ca2+ channel currents in cultured sensory neurones is dependent on culture conditions and channel subunit expression

We have used the whole cell patch clamp method and fura-2 fluorescence imaging to study the actions of gabapentin (1-(aminoethyl) cyclohexane acetic acid) on voltage-activated Ca(2+) entry into neonatal cultured dorsal root ganglion (DRG) neurones and differentiated F-11 (embryonic rat DRG x neuroblastoma hybrid) cells. Gabapentin (2.5 microM) in contrast to GABA (10 microM) did not influence resting membrane potential or input resistance. In current clamp mode gabapentin failed to influence the properties of evoked single action potentials but did reduce the duration of action potentials prolonged by Ba(2+). Gabapentin attenuated high voltage-activated Ca(2+) channel currents in a dose- and voltage- dependent manner in DRG neurones and reduced Ca(2+) influx evoked by K(+) depolarisation in differentiated F-11 cells loaded with fura-2. The sensitivity of DRG neurones to gabapentin was not changed by the GABA(B) receptor antagonist saclofen but pertussis toxin pre-treatment reduced the inhibitory effects of gabapentin. Experiments following pre-treatment of DRG neurones with a PKA-activator and a PKA-inhibitor implicated change in phosphorylation state as a mechanism, which influenced gabapentin action. Sp- and Rp-analogues of cAMP significantly increased or decreased gabapentin-mediated inhibition of voltage-activated Ca(2+) channel currents. Culture conditions used to maintain DRG neurones and passage number of differentiated F-11 cells also influenced the sensitivity of Ca(2+) channels to gabapentin. We analysed the Ca(2+) channel subunits expressed in populations of DRG neurones and F-11 cells that responded to gabapentin had low sensitivity to gabapentin or were insensitive to gabapentin, by Quantitative TaqMan PCR. The data obtained from this analysis suggested that the relative abundance of the Ca(2+) channel beta(2) and alpha(2)delta subunit expressed was a key determinant of gabapentin sensitivity of both cultured DRG neurones and differentiated F-11 cells. In conclusion, gabapentin inhibited part of the high voltage-activated Ca(2+) current in neonatal rat cultured DRG neurones via a mechanism that was independent of GABA receptor activation, but was sensitive to pertussis toxin. Gabapentin responses identified in this study implicated Ca(2+) channel beta(2) subunit type as critically important to drug sensitivity and interactions with alpha(1) and alpha(2)delta subunits may be implicated in antihyperalgesic therapeutic action for this compound.

Inhibition of neuronal Ca(2+) influx by gabapentin and pregabalin in the human neocortex

Gabapentin and pregabalin (S-(+)-3-isobutylgaba) produced concentration-dependent inhibitions of the K(+)-induced [Ca(2+)](i) increase in fura-2-loaded human neocortical synaptosomes (IC(50)=17 microM for both compounds; respective maximal inhibitions of 37 and 35%). The weaker enantiomer of pregabalin, R-(-)-3-isobutylgaba, was inactive. These findings were consistent with the potency of these drugs to inhibit [(3)H]-gabapentin binding to human neocortical membranes. The inhibitory effect of gabapentin on the K(+)-induced [Ca(2+)](i) increase was prevented by the P/Q-type voltage-gated Ca(2+) channel blocker omega-agatoxin IVA. The alpha 2 delta-1, alpha 2 delta-2, and alpha 2 delta-3 subunits of voltage-gated Ca(2+) channels, presumed sites of gabapentin and pregabalin action, were detected with immunoblots of human neocortical synaptosomes. The K(+)-evoked release of [(3)H]-noradrenaline from human neocortical slices was inhibited by gabapentin (maximal inhibition of 31%); this effect was prevented by the AMPA receptor antagonist NBQX (2,3-dioxo-6-nitro-1,2,3,4-tetrahydro[f]quinoxaline-7-sulphonamide). Gabapentin and pregabalin may bind to the Ca(2+) channel alpha 2 delta subunit to selectively attenuate depolarization-induced Ca(2+) influx of presynaptic P/Q-type Ca(2+) channels; this results in decreased glutamate/aspartate release from excitatory amino acid nerve terminals leading to a reduced activation of AMPA heteroreceptors on noradrenergic nerve terminals.

Gabapentin inhibits high-threshold calcium channel currents in cultured rat dorsal root ganglion neurones

1. This study examined the action of gabapentin (gabapentin,1-(aminomethyl) cyclohexane acetic acid (Neurontin) on voltage-gated calcium (Ca(2+)) channel influx recorded in cultured rat dorsal root ganglion (DRG) neurones. 2. Voltage-gated Ca(2+) influx was monitored using both fura-2 based fluorescence Ca(2+) imaging and the whole-cell patch clamp technique. 3. Imaging of intracellular Ca(2+) transients revealed that gabapentin inhibited KCl (30 mM)-evoked voltage-dependent Ca(2+) influx. Both the duration for 50% of the maximum response (W50) and total Ca(2+) influx were significantly reduced by approximately 25-30% in the presence of gabapentin (25 microM). 4. Gabapentin potently inhibited the peak whole-cell Ca(2+) channel current (I(Ba)) in a dose-dependent manner with an estimated IC(50) value of 167 nM. Block was incomplete and saturated at a maximal concentration of 25 microM. 5. Inhibition was significantly decreased in the presence of the neutral amino acid L-isoleucine (25 microM) but unaffected by application of the GABA(B) antagonist, saclofen (200 microM), suggesting a direct action on the alpha(2)delta subunit of the Ca(2+) channel. 6. Gabapentin inhibition was voltage-dependent, producing an approximately 7 mV hyperpolarizing shift in current voltage properties and reducing a non-inactivating component of whole-cell current activated at relatively depolarized potentials. 7. The use of specific Ca(2+) channel antagonists revealed a mixed pharmacology of the gabapentin-sensitive current (N-, L- and P/Q-type), which is dominated by N-type current. 8. The present study is the first to demonstrate that gabapentin directly mediates inhibition of voltage-gated Ca(2+) influx in DRG neurones, providing a potential means for gabapentin to effectively mediate spinal anti-nociception.

Antiepileptic drugs: affective use in autism spectrum disorders

Antiepileptic drugs are widely administered to individuals with autistic spectrum disorders. There are several reasons for the use of antiepileptic drugs in autistic spectrum disorders, including the high incidence of epilepsy in these individuals, the anecdotal reports suggesting an improvement of communication and behavior in autistic subjects with epileptic discharges, and the increased awareness that some disruptive behaviors may be manifestations of an associated affective disorder. In this study, data on the current use of antiepileptic drugs in the treatment of autism, and on the association of affective disorders with epilepsy and autism, are reviewed. The evidence supporting the hypothesis that there may be a subgroup of autistic children with epilepsy and affective disorders that preferentially respond to antiepileptic drugs is still very preliminary, and further investigations with double-blind controlled studies are needed. Although the role of antiepileptic drugs at the present time is not established, there is evidence that autism, epilepsy, and affective disorders commonly co-occur, and that they may share a common neurochemical substrate, which is the common target of the psychotropic mechanism of action of different antiepileptic drugs.

Calcium channel alpha(2)delta subunits-structure and Gabapentin binding

High-voltage activated calcium channels are modulated by a series of auxiliary proteins, including those of the alpha(2)delta family. Until recently, only a single alpha(2)delta subunit was known, but two further members, alpha(2)delta-2 and -3, have since been identified. In this study, the structure of these two novel subunits has been characterized and binding of the antiepileptic drug gabapentin investigated. Using antibodies directed against the amino terminal portion of the proteins, the gross structure of the subunits could be analyzed by Western blotting. Similar to alpha(2)delta-1, both alpha(2)delta-2 and -3 subunits consist of two proteins-a larger alpha(2) and a smaller delta that can be separated by reduction. The subunits are also highly N-glycosylated with approximately 30 kDa of their mass consisting of oligosaccharides. alpha(2)delta-1 was detected in all mouse tissues studied, whereas alpha(2)delta-2 was found at high levels in brain and heart. The alpha(2)delta-3 subunit was observed only in brain. alpha(2)delta-1 and alpha(2)delta-2, but not alpha(2)delta-3, were found to bind gabapentin. The K(d) value of gabapentin binding to alpha(2)delta-2 was 153 nM compared with the higher affinity binding to alpha(2)delta-1 (K(d) = 59 nM).

Voltage-dependent calcium channels--beyond dihydropyridine antagonists

The blockade of L-type calcium channels by dihydropyridines, phenylalkylamines and benzothiazepines has been well described and forms the basis of a multibillion dollar market for the treatment of cardiovascular disease and migraine. More recently, neuron-specific calcium channels have become the subject of intense interest regarding their potential as therapeutic targets for the treatment of chronic and neuropathic pain. A number of recently described agents that selectively target neuronal calcium channels have been described and appear promising for a variety of pain conditions.