Ganaxolone suppression of behavioral and electrographic seizures in the mouse amygdala kindling model.

Ganaxolone (3alpha-hydroxy-3beta-methyl-5alpha-pregnan-20-one), a synthetic analog of the endogenous neurosteroid allopregnanolone and a positive allosteric modulator of GABAA receptors, may represent a new treatment approach for epilepsy. Here we demonstrate that pretreatment with ganaxolone (1.25-20 mg/kg, s.c.) causes a dose-dependent suppression of behavioral and electrographic seizures in fully amygdala-kindled female mice, with nearly complete seizure protection at the highest dose tested. The ED50 for suppression of behavioral seizures was 6.6 mg/kg. The seizure suppression produced by ganaxolone was comparable to that of clonazepam (ED50, 0.1 mg/kg, s.c.). To the extent that amygdala kindling represents a model of mesial temporal lobe epilepsy, this study supports the utility of ganaxolone in the treatment of patients with temporal lobe seizures.

Neurosteroids as endogenous regulators of seizure susceptibility and use in the treatment of epilepsy.

Neurosteroids such as allopregnanolone are positive allosteric modulators of GABAA receptors with powerful antiseizure activity in diverse animal models. Neurosteroids may be endogenous regulators of seizure susceptibility, for example, in catamenial epilepsy. Clinical trials with the synthetic neurosteroid analog ganaxolone in the treatment of refractory partial seizures and infantile spasms have been encouraging. Neurosteroids and analogs such as ganaxolone show promise in the treatment of diverse forms of epilepsy. For an expanded treatment of this topic see Jasper's basic mechanisms of the epilepsies, 4th ed. (Noebels JL, Avoli M, Rogawski MA, Olsen RW, Delgado-Escueta AV, eds) published by Oxford University Press (available on the National Library of Medicine Bookshelf [NCBI] at www.ncbi.nlm.nih.gov/books).

Neurosteroid replacement therapy for catamenial epilepsy.

Perimenstrual catamenial epilepsy, the cyclical occurrence of seizure exacerbations near the time of menstruation, affects a high proportion of women of reproductive age with drug-refractory epilepsy. Enhanced seizure susceptibility in perimenstrual catamenial epilepsy is believed to be due to the withdrawal of the progesterone-derived GABA(A) receptor modulating neurosteroid allopregnanolone as a result of the fall in progesterone at the time of menstruation. Studies in a rat pseudopregnancy model of catamenial epilepsy indicate that after neurosteroid withdrawal there is enhanced susceptibility to chemoconvulsant seizures. There is also a transitory increase in the frequency of spontaneous seizures in epileptic rats that had experienced pilocarpine-induced status epilepticus. In the catamenial epilepsy model, there is a marked reduction in the antiseizure potency of anticonvulsant drugs, including benzodiazepines and valproate, but an increase in the anticonvulsant potency and protective index of neurosteroids such as allopregnanolone and the neurosteroid analog ganaxolone. The enhanced seizure susceptibility and benzodiazepine-resistance subsequent to neurosteroid withdrawal may be related to reduced expression and altered kinetics of synaptic GABA(A) receptors and increased expression of GABA(A) receptor subunits (such as alpha4) that confer benzodiazepine insensitivity. The enhanced potency of neurosteroids may be due to a relative increase after neurosteroid withdrawal in the expression of neurosteroid-sensitive delta-subunit-containing perisynaptic or extrasynaptic GABA(A) receptors. Positive allosteric modulatory neurosteroids and synthetic analogs such as ganaxolone may be administered to prevent catamenial seizure exacerbations, in what we call neurosteroid replacement therapy.

Mass spectrometric assay and physiological-pharmacological activity of androgenic neurosteroids.

Steroid hormones play a key role in the pathophysiology of several brain disorders. Testosterone modulates neuronal excitability, but the underlying mechanisms are obscure. There is emerging evidence that testosterone-derived "androgenic neurosteroids", 3alpha-androstanediol and 17beta-estradiol, mediate the testosterone effects on neural excitability and seizure susceptibility. Testosterone undergoes metabolism to neurosteroids via two distinct pathways. Aromatization of the A-ring converts testosterone into 17beta-estradiol. Reduction of testosterone by 5alpha-reductase generates 5alpha-dihydrotestosterone, which is then converted to 3alpha-androstanediol, a powerful GABA(A) receptor-modulating neurosteroid with anticonvulsant properties. Although the 3alpha-androstanediol is an emerging neurosteroid in the brain, there is no specific and sensitive assay for determination of 3alpha-androstanediol in biological samples. This article describes the development and validation of mass spectrometric assay of 3alpha-androstanediol, and the molecular mechanisms underlying the testosterone modulation of seizure susceptibility. A liquid chromatography-tandem mass spectrometry assay to measure 3alpha-androstanediol is validated with excellent linearity, specificity, sensitivity, and reproducibility. Testosterone modulation of seizure susceptibility is demonstrated to occur through its conversion to neurosteroids with "anticonvulsant" and "proconvulsant" actions and hence the net effect of testosterone on neural excitability and seizure activity depends on the levels of distinct testosterone metabolites. The proconvulsant effect of testosterone is associated with increases in plasma 17beta-estradiol concentrations. The 5alpha-reduced metabolites of testosterone, 5alpha-dihydrotestosterone and 3alpha-androstanediol, had powerful anticonvulsant activity. Overall, the testosterone-derived neurosteroids 3alpha-androstanediol and 17beta-estradiol could contribute to the net cellular actions of testosterone in the brain. Because 3alpha-androstanediol is a potent positive allosteric modulator of GABA(A) receptors, it could serve as an endogenous neuromodulator of neuronal excitability in men. The 3alpha-androstanediol assay is an important tool in this area because of the growing interest in the potential to use adjuvant aromatase inhibitor therapy to improve treatment of epilepsy.

Perimenstrual catamenial epilepsy.

Epilepsy affects 50 million people worldwide, including women afflicted with catamenial epilepsy. Catamenial epilepsy is a form of epilepsy in which seizures are clustered around specific points in the menstrual cycle, most frequently during the perimenstrual or periovulatory phase. Although there are a number of standard and newer antiepileptic drugs for epilepsy, no specific drugs exist to treat catamenial seizures, which affect at least one in three women with epilepsy. Moreover, the molecular pathophysiology of catamenial seizures remains unclear. This article describes the pathophysiology, hormonal basis, diagnosis and treatment of perimenstrual catamenial epilepsy. Natural progesterone and synthetic neurosteroid replacement appears to be a suitable therapeutic approach for catamenial epilepsy.

Hippocampal neurodegeneration, spontaneous seizures, and mossy fiber sprouting in the F344 rat model of temporal lobe epilepsy.

The links among the extent of hippocampal neurodegeneration, the frequency of spontaneous recurrent motor seizures (SRMS), and the degree of aberrant mossy fiber sprouting (MFS) in temporal lobe epilepsy (TLE) are a subject of contention because of variable findings in different animal models and human studies. To understand these issues further, we quantified these parameters at 3-5 months after graded injections of low doses of kainic acid (KA) in adult F344 rats. KA was administered every 1 hr for 4 hr, for a cumulative dose of 10.5 mg/kg bw, to induce continuous stages III-V motor seizures for >3 hr. At 4 days post-KA, the majority of rats (77%) exhibited moderate bilateral neurodegeneration in different regions of the hippocampus; however, 23% of rats exhibited massive neurodegeneration in all hippocampal regions. All KA-treated rats displayed robust SRMS at 3 months post-KA, and the severity of SRMS increased over time. Analyses of surviving neurons at 5 months post-KA revealed two subgroups of rats, one with moderate hippocampal injury (HI; 55% of rats) and another with widespread HI (45%). Rats with widespread HI exhibited greater loss of CA3 pyramidal neurons and robust aberrant MFS than rats with moderate HI. However, the frequency of SRMS (approximately 3/hr) was comparable between rats with moderate and widespread HI. Thus, in comparison with TLE model using Sprague-Dawley rats (Hellier et al. [1998] Epilepsy Res. 31:73-84), a much lower cumulative dose of KA leads to robust chronic epilepsy in F344 rats. Furthermore, the occurrence of SRMS in this model is always associated with considerable bilateral hippocampal neurodegeneration and aberrant MFS. However, more extensive hippocampal CA3 cell loss and aberrant MFS do not appear to increase the frequency of SRMS. Because most of the features are consistent with mesial TLE in humans, the F344 model appears ideal for testing the efficacy of potential treatment strategies for mesial TLE.

A high-performance liquid chromatography-tandem mass spectrometry assay of the androgenic neurosteroid 3alpha-androstanediol (5alpha-androstane-3alpha,17beta-diol) in plasma.

The testosterone metabolite 3alpha-androstanediol (5alpha-androstane-3alpha,17-diol) is a potential GABA(A) receptor-modulating neurosteroid with anticonvulsant properties and hence could act as a key neuromodulator in the central nervous system. However, there is no specific and sensitive assay for quantitative determination of the androgenic neurosteroid 3alpha-androstanediol in biological samples. We have established a liquid chromatography-tandem mass spectrometry (LC-MS-MS) assay to measure 3alpha-androstanediol in rat plasma. Standard 3alpha-androstanediol added to rat plasma has been successfully analysed with excellent linearity, specificity, sensitivity, and reproducibility. The sensitivity of the method was < 10 ng/ml with a detection limit of 2 ng/ml (6.8 nmol/l) and a linear range of 10-2000 ng/ml. The method was used for the analysis of testosterone-induced increase in plasma 3alpha-androstanediol levels in rats. Testosterone produced a dose-dependent elevation in plasma 3alpha-androstanediol, which was almost completely prevented by pretreatment with the 5alpha-reductase inhibitor finasteride, indicating that 3alpha-androstanediol is synthesized from testosterone via a 5alpha-reductase pathway. This LC-MS-MS method allows accurate, high-throughput analysis of 3alpha-androstanediol in small amounts (200 microl) of plasma and possibly other biological samples.

Anesthetic effects of progesterone are undiminished in progesterone receptor knockout mice.

Progesterone has sedative and anesthetic effects but the underlying molecular mechanisms remain unclear. The two possible mechanisms by which progesterone affects the function of the brain include binding to intracellular progesterone receptors (PR) and metabolism to GABA(A) receptor-modulating neurosteroids. In this study, PR knockout (PRKO) mice were used as model to study the role of PRs in the anesthetic activity of progesterone. The progesterone-induced anesthetic activity was undiminished in female PRKO mice (ED50, 172 mg/kg) as compared to their wild-type littermates (ED50, 167 mg/kg). The progesterone-induced anesthetic activity was highly correlated with increased plasma allopregnanolone levels. Pretreatment of PRKO mice with the 5alpha-reductase inhibitor finasteride significantly reduced the progesterone-induced anesthetic activity. Allopregnanolone also evoked dose-dependent anesthetic activity in PRKO mice, which was similar to those of wild-type mice. Thus, the anesthetic activity of progesterone is not mediated by its interaction with PRs. The neurosteroid allopregnanolone partially mediates the anesthetic activity of progesterone by potentiation of GABA(A) receptor function.

Anxiolytic activity of progesterone in progesterone receptor knockout mice.

Progesterone is an anxiolytic steroid that could play a role in the regulation of anxiety in women. However, the mechanism by which progesterone decreases anxiety is incompletely understood. Progesterone affects the function of the brain by two distinct mechanisms. Progesterone regulates reproductive behavior by activating intracellular progesterone receptors (PRs). In addition, progesterone is believed to influence neuronal activity through its conversion to allopregnanolone, a neurosteroid that acts as a positive allosteric modulator of GABAA receptors. The extent to which the anxiolytic action of progesterone requires PRs is uncertain. In this study, we utilized PR knockout (PRKO) mice bearing a targeted null mutation of the PR gene that abrogates the function of both PR-A and PR-B subtypes to determine the requirement for PRs in the anxiolytic actions of progesterone. The absence of PR receptor protein expression in PRKO brain was confirmed by immunocytochemistry. In PRKO mice and their isogenic wild-type (WT) littermates, progesterone administration was associated with a dose-dependent rise in plasma allopregnanolone concentrations and corresponding anxiolytic effects in the elevated plus maze test. PRKO mice exhibited a greater anxiolytic response than WT animals although the allopregnanolone levels were similar in the two genotypes. Allopregnanolone also exhibited anxiolytic effects, but the magnitude of the response was similar in both genotypes. Pretreatment of PRKO mice with finasteride, a 5alpha-reductase inhibitor that blocks the conversion of progesterone to allopregnanolone, completely prevented the anxiolytic activity of progesterone, but had no effect on the response to allopregnanolone, demonstrating that allopregnanolone (or other 5alpha-reduced metabolites of progesterone) accounts for the response to the parent steroid hormone. These results provide direct evidence that the anxiolytic action of progesterone does not require PRs. However, PR activation by progesterone may influence the anxiolytic response since PRKO mice were more sensitive to progesterone.

Role of neurosteroids in catamenial epilepsy.

Catamenial epilepsy is a menstrual cycle-related seizure disorder that affects up to 70% of women with epilepsy. Catamenial epilepsy is characterized by an increase in seizures during particular phases of the menstrual cycle. Three distinct patterns of catamenial epilepsy - perimenstrual, periovulatory, and inadequate luteal phase - have been described. Currently, there is no specific treatment for catamenial epilepsy. The molecular mechanisms involved in the pathophysiology of catamenial epilepsy are not well understood. Recent studies suggest that cyclical changes of ovarian hormones estrogens (proconvulsant) and progesterone (anticonvulsant) appear to play a key role in the genesis of catamenial seizures. Progesterone reduces seizure susceptibility partly through conversion to neurosteroids such as allopregnanolone, which enhances GABA(A) receptor function and thereby inhibits neuronal excitability. In animal models, withdrawal from chronic progesterone and, consequently, of allopregnanolone levels in brain, has been shown to increase seizure susceptibility. Natural progesterone therapy has proven effective in women with epilepsy. Moreover, neurosteroids have been shown to be very effective inhibitors of catamenial seizures in animal models. Thus, synthetic neuroactive steroids, such as ganaxolone, which are orally active and devoid of hormonal side effects, represent a novel treatment strategy for catamenial epilepsy. However, their clinical efficacy in catamenial epilepsy has yet to be explored. A greater understanding of the molecular mechanisms is clearly needed for designing effective treatment and prevention strategies of catamenial epilepsy in women at risk.

Anticonvulsant activity of the testosterone-derived neurosteroid 3alpha-androstanediol.

3alpha-Androstanediol is synthesized from testosterone in peripheral tissues and in the brain, but the clinical importance of this neurosteroid remains unclear. This study evaluated the effects of 3alpha-androstanediol on seizure susceptibility in mouse models of epilepsy. 3alpha-Androstanediol protected mice against seizures induced by GABAA receptor antagonists pentylenetetrazol, picrotoxin, and beta-carboline ester in a dose-dependent fashion. However, 3alpha-androstanediol was inactive against seizures induced by glutamate receptor agonists kainic acid, NMDA and 4-aminopyridine. Pretreatment with the androgen receptor antagonist flutamide had no effect on seizure protection by 3alpha-androstanediol. These results suggest that 3alpha-androstanediol has powerful anticonvulsant activity that occurs largely through non-genomic mechanisms. Testosterone-derived 3alpha-androstanediol might be an endogenous protective neurosteroid in the brain.

Is there a physiological role for the neurosteroid THDOC in stress-sensitive conditions?

Endogenous neurosteroids affect brain excitability during physiological states such as pregnancy and the menstrual cycle, and during conditions of acute and chronic stress. The neurosteroid allotetrahydrodeoxycorticosterone (THDOC) is an allosteric modulator of the GABA(A) receptor. Although the role of THDOC within the brain is undefined, recent studies indicate that stress induces THDOC to levels that can activate GABA(A) receptors. These results might have significant implications for human stress-sensitive conditions such as epilepsy, post-traumatic stress disorder and depression.

Neurosteroids and infantile spasms: the deoxycorticosterone hypothesis.

Deoxycorticosterone (DOC) is a mineralocorticoid precursor that has anticonvulsant properties in animals and possibly also in humans. Studies indicate that the anticonvulsant activity of DOC requires its enzymatic conversion to 5 alpha,3 alpha-tetrahydrodeoxycorticosterone (THDOC), a neurosteroid that lacks classical hormonal properties but acts as a powerful positive allosteric modulator of GABAA receptors. DOC can be considered a stress hormone because its synthesis is under the control of ACTH. Therefore, stress-induced fluctuations in seizure susceptibility could in part result from alterations in DOC availability. Also, the therapeutic activity of ACTH in infantile spasms could partially relate to its stimulatory effects on the synthesis of DOC, which then undergoes biotransformation to neurosteroids. The recent demonstration that the synthetic neurosteroid analog ganaxolone reduces spasm frequency in children with intractable infantile spasms suggests that neurosteroid-related anticonvulsants may offer a potential new nonhormonal approach for the treatment of infantile spasms and other developmental epilepsies. In addition, it further confirms the utility of pharmacological enhancement of GABA-mediated inhibition in the control of infantile spasms.

Stress-induced deoxycorticosterone-derived neurosteroids modulate GABA(A) receptor function and seizure susceptibility.

Stress affects seizure susceptibility in animals and humans, but the underlying mechanisms are obscure. Here, we provide evidence that GABA(A) receptor-modulating neurosteroids derived from deoxycorticosterone (DOC) play a role in stress-related changes in seizure control. DOC, an adrenal steroid whose synthesis is enhanced during stress, undergoes sequential metabolic reduction by 5alpha-reductase and 3alpha-hydroxysteroid oxidoreductase to form 5alpha-dihydrodeoxycorticosterone (DHDOC) and allotetrahydrodeoxycorticosterone (THDOC), a GABA(A) receptor-modulating neurosteroid with anticonvulsant properties. Acute swim stress in rats significantly elevated plasma THDOC concentrations and raised the pentylenetetrazol (PTZ) seizure threshold. Small systemic doses of DOC produced comparable increases in THDOC and PTZ seizure threshold. Pretreatment with finasteride, a 5alpha-reductase inhibitor that blocks the conversion of DOC to DHDOC, reversed the antiseizure effects of stress. DOC also elevated plasma THDOC levels and protected mice against PTZ, methyl-6,7-dimethoxy-4-ethyl-beta-carboline-3-carboxylate, picrotoxin, and amygdala-kindled seizures in mice (ED50 values, 84-97 mg/kg). Finasteride reversed the antiseizure activity of DOC (ED50, 7.2 mg/kg); partial antagonism was also obtained with indomethacin (100 mg/kg), an inhibitor of 3alpha-hydroxysteroid oxidoreductase. Finasteride had no effect on seizure protection by DHDOC and THDOC, whereas indomethacin partially reversed DHDOC but not THDOC. DHDOC, like THDOC, potentiated GABA-activated Cl- currents in cultured hippocampal neurons (< or =1 microm) and directly activated GABA(A) receptor currents (> or =1 microm), compatible with a role for DHDOC in the antiseizure activity of DOC. DOC is a mediator of the physiological effects of acute stress that could contribute to stress-induced changes in seizure susceptibility through its conversion to neurosteroids with modulatory actions on GABA(A) receptors including THDOC and possibly also DHDOC.

Newer GABAergic agents for pharmacotherapy of infantile spasms.

Infantile spasms is an age-specific epileptic syndrome in infants and young children. Although the exact mechanism is unknown, adrenocorticotrophic hormone (ACTH) has been the mainstay for the therapeutic management of infantile spasms and other developmental epilepsies. Clinical benefits of ACTH in infantile spasms could partially relate to its stimulatory effects on the release of adrenocorticosteroids and neurosteroids. Glucocorticoids, pyridoxine and ketogenic diet therapy have all been used for the treatment of refractory infantile spasms. Recent studies indicate that several newer anticonvulsant agents, which are positive allosteric modulators of GABA(A) receptors, are as effective as ACTH in acutely controlling infantile spasms. The efficacy of agents that enhance GABA-mediated inhibition (such as vigabatrin and benzodiazepines) for rapid and complete abolition of infantile spasms has been demonstrated in several clinical studies. Ganaxolone, a novel neuroactive steroid has, however, demonstrated outstanding efficacy and better tolerability in children with intractable infantile spasms. Zonisamide, topiramate, deoxycorticosterone and neurosteroids are emerging as effective treatment approaches. These new antiepileptic drugs represent a potential nonhormonal approach for infantile spasms, but additional studies are needed to verify their efficacy and tolerability. Future studies will hopefully identify rational antiseizure drugs that not only control infantile spasms but also abrogate its risk on the development of the brain.

The clinical potentials of endogenous neurosteroids.

Stress increases plasma and brain concentrations of the neurosteroids allopregnanolone and allotetrahydrodeoxycorticosterone (THDOC), which can have potent effects on GABAA receptors in the brain. Blockade of the formation of neurosteroids prevents specific biochemical and behavioral effects of stress, suggesting that those effects are dependent upon the actions of GABA(A)-receptor active neurosteroids. Recent investigations provide a better understanding of the role of endogenous neurosteroids in normal neuronal development and in the pathophysiology of brain disorders. Physiological neurosteroid fluctuations have potential implications for stress-sensitive neurological conditions such as epilepsy, infantile spasms, as well as psychiatric disorders such as schizophrenia, posttraumatic stress disorder and depression. Future studies may provide important new evidence that may not only explain acute actions of stress, but also reveal the clinical importance of neurosteroid mechanisms during chronic stress.