Petra Bittigau

Antiepileptic drugs and apoptotic neurodegeneration in the developing brain.

Epilepsy is the most common neurological disorder of young humans. Each year 150,000 children in the United States experience their first seizure. Antiepileptic drugs (AEDs), used to treat seizures in children, infants, and pregnant women, cause cognitive impairment, microcephaly, and birth defects. The cause of unwanted effects of therapy with AEDs is unknown. Here we reveal that phenytoin, phenobarbital, diazepam, clonazepam, vigabatrin, and valproate cause apoptotic neurodegeneration in the developing rat brain at plasma concentrations relevant for seizure control in humans. Neuronal death is associated with reduced expression of neurotrophins and decreased concentrations of survival-promoting proteins in the brain. β-Estradiol, which stimulates pathways that are activated by neurotrophins, ameliorates AED-induced apoptotic neurodegeneration. Our findings present one possible mechanism to explain cognitive impairment and reduced brain mass associated with prenatal or postnatal exposure of humans to antiepileptic therapy.

Neurotransmitters and apoptosis in the developing brain

In the immature mammalian brain during a period of rapid growth (brain growth spurt/synaptogenesis period), neuronal apoptosis can be triggered by the transient blockade of glutamate N-methyl-d-aspartate (NMDA) receptors, or the excessive activation of gamma-aminobutyric acid (GABA(A)) receptors. Apoptogenic agents include anesthetics (ketamine, nitrous oxide, isoflurane, propofol, halothane), anticonvulsants (benzodiazepines, barbiturates), and drugs of abuse (phencyclidine, ketamine, ethanol). In humans, the brain growth spurt period starts in the sixth month of pregnancy and extends to the third year after birth. Ethanol, which has both NMDA antagonist and GABA(A) agonist properties, is particularly effective in triggering widespread apoptotic neurodegeneration during this vulnerable period. Thus, maternal ingestion of ethanol during the third trimester of pregnancy can readily explain the dysmorphogenic changes in the fetal brain and consequent neurobehavioral disturbances that characterize the human fetal alcohol syndrome. In addition, there is basis for concern that agents used in pediatric and obstetrical medicine for purposes of sedation, anesthesia, and seizure management may cause apoptotic neuronal death in the developing human brain.

Drug-induced apoptotic neurodegeneration in the developing brain.

Physiological cell death (PCD), a process by which redundant or unsuccessful neurons are deleted by apoptosis (cell suicide) from the developing central nervous system, has been recognized as a natural phenomenon for many years. Whether environmental factors can interact with PCD mechanisms to increase the number of neurons undergoing PCD, thereby converting this natural phenomenon into a pathological process, is an interesting question for which new answers are just now becoming available. In a series of recent studies we have shown that 2 major classes of drugs (those that block NMDA glutamate receptors and those that promote GABAA receptor activation), when administered to immature rodents during the period of synaptogenesis, trigger widespread apoptotic neurodegeneration throughout the developing brain. In addition, we have found that ethanol, which has both NMDA antagonist and GABAmimetic properties, triggers a robust pattern of apoptotic neurodegeneration, thereby deleting large numbers of neurons from many different regions of the developing brain. These findings provide a more likely explanation than has heretofore been available for the reduced brain mass and lifelong neurobehavioral disturbances associated with the human fetal alcohol syndrome (FAS). The period of synaptogenesis, also known as the brain growth spurt period, occurs in different species at different times relative to birth. In rats and mice it is a postnatal event, but in humans it extends from the sixth month of gestation to several years after birth. Thus, there is a period in pre‐ and postnatal human development, lasting for several years, during which immature CNS neurons are prone to commit suicide if exposed to intoxicating concentrations of drugs with NMDA antagonist or GABAmimetic properties. These findings are important, not only because of their relevance to the FAS, but because there are many agents in the human environment, other than ethanol, that have NMDA antagonist or GABAmimetic properties. Such agents include drugs that may be abused by pregnant mothers (ethanol, phencyclidine [angel dust], ketamine [Special K], nitrous oxide [laughing gas], barbiturates, benzodiazepines), and many medicinals used in obstetric and pediatric neurology (anticonvulsants), and anesthesiology (all general anesthetics are either NMDA antagonists or GABAmimetics).

Apoptotic neurodegeneration following trauma is markedly enhanced in the immature brain

Age dependency of apoptotic neurodegeneration was studied in the developing rat brain after percussion head trauma. In 7‐day‐old rats, mechanical trauma, applied by means of a weight drop device, was shown to trigger widespread cell death in the hemisphere ipsilateral to the trauma site, which first appeared at 6 hours, peaked at 24 hours, and subsided by 5 days after trauma. Ultrastructurally, degenerating neurons displayed features consistent with apoptosis. A decrease of bcl‐2 in conjunction with an increase of c‐jun mRNA levels, which were evident at 1 hour after trauma and were accompanied by elevation of CPP 32‐like proteolytic activity and oligonucleosomes in vulnerable brain regions, confirmed the apoptotic nature of this process. Severity of trauma‐triggered apoptosis in the brains of 3‐ to 30‐day‐old rats was age dependent, was highest in 3‐ and 7‐day‐old animals, and demonstrated a subsequent rapid decline. Adjusting the mechanical force in accordance with age‐specific brain weights revealed a similar vulnerability profile. Thus, apoptotic neurodegeneration contributes in an age‐dependent fashion to neuropathological outcome after head trauma, with the immature brain being exceedingly vulnerable. These results help explain unfavorable outcomes of very young pediatric head trauma patients and imply that, in this group, an antiapoptotic regimen may constitute a successful neuroprotective approach. Ann Neurol 1999;45:724–735

Antiepileptic drugs and apoptosis in the developing brain.

Abstract: Epilepsy is the most common neurologic disorder in young humans. Antiepileptic drugs (AEDs), used to treat seizures in children, infants, and pregnant women, cause cognitive impairment, microcephaly, and birth defects by unknown mechanisms. We tested whether common AEDs cause neurodegeneration in the developing rat brain. Rats aged 3‐30 days received phenytoin, phenobarbital, diazepam, clonazepam, vigabatrin, or valproic acid. Histologic examination of the brains revealed that these drugs cause widespread and dose‐dependent apoptotic neurodegeneration in the developing rat brain during the brain growth spurt period. Apoptotic neurodegeneration was triggered at plasma drug levels relevant for seizure control in humans. Antiepileptic drugs lead to reduced expression of neurotrophins and decreased concentrations of the active forms of ERK1/2, RAF, and AKT. β‐Estradiol, which stimulates pathways that are activated by neurotrophins, ameliorated AEDs‐induced apoptotic neurodegeneration. Our findings present one possible mechanism to explain cognitive impairment and reduced brain mass associated with pre‐ or postnatal exposure of humans to antiepileptic therapy.

Anandamide, but not 2-arachidonoylglycerol, accumulates during in vivo neurodegeneration

Endogenous cannabinoid receptor ligands (endocannabinoids) may rescue neurons from glutamate excitotoxicity. As these substances also accumulate in cultured immature neurons following neuronal damage, elevated endocannabinoid concentrations may be interpreted as a putative neuroprotective response. However, it is not known how glutamatergic insults affect in vivo endocannabinoid homeostasis, i.e. N‐arachidonoylethanolamine (anandamide) and 2‐arachidonoylglycerol (2‐AG), as well as other constituents of their lipid families, N‐acylethanolamines (NAEs) and 2‐monoacylglycerols (2‐MAGs), respectively. Here we employed three in vivo neonatal rat models characterized by widespread neurodegeneration as a consequence of altered glutamatergic neurotransmission and assessed changes in endocannabinoid homeostasis. A 46‐fold increase of cortical NAE concentrations (anandamide, 13‐fold) was noted 24 h after intracerebral NMDA injection, while less severe insults triggered by mild concussive head trauma or NMDA receptor blockade produced a less pronounced NAE accumulation. By contrast, levels of 2‐AG and other 2‐MAGs were virtually unaffected by the insults employed, rendering it likely that key enzymes in biosynthetic pathways of the two different endocannabinoid structures are not equally associated to intracellular events that cause neuronal damage in vivo. Analysis of cannabinoid CB1 receptor mRNA expression and binding capacity revealed that cortical subfields exhibited an up‐regulation of these parameters following mild concussive head trauma and exposure to NMDA receptor blockade. This may suggest that mild to moderate brain injury may trigger elevated endocannabinoid activity via concomitant increase of anandamide levels, but not 2‐AG, and CB1 receptor density.

Ethanol-induced apoptotic neurodegeneration in the developing brain.

It has been known for three decades that ethanol, the most widely abused drug in the world, has deleterious effects on the developing human brain, but progress has been slow in developing animal models for studying this problem, and the underlying mechanisms have remained elusive. Recently, we have shown that during the synaptogenesis period, also known as the brain growth spurt period, ethanol has the potential to trigger massive neuronal suicide in the in vivo mammalian brain. The brain growth spurt period in humans spans the last trimester of pregnancy and first several years after birth. The NMDA antagonist and GABAmimetic properties of ethanol may be responsible for its apoptogenic action, in that other drugs with either NMDA antagonist or GABAmimetic actions also trigger apoptotic neurodegeneration in the developing brain. Our findings provide a likely explanation for the reduced brain mass and neurobehavioral disturbances associated with the human fetal alcohol syndrome. Furthermore, since NMDA antagonist and GABAmimetic drugs are sometimes abused by pregnant women and also are used as anticonvulsants, sedatives or anesthetics in pediatric medicine, our findings raise several complex drug safety issues. In addition, the observation that ethanol and several other drugs trigger massive neuronal apoptosis in the developing brain provides an unprecedented opportunity to study both neuropathological aspects and molecular mechanisms of apoptotic neurodegeneration in the in vivo mammalian brain.

Mechanisms leading to disseminated apoptosis following NMDA receptor blockade in the developing rat brain.

The developing rodent brain is vulnerable to pharmacological blockade of N-methyl-d-aspartate (NMDA) receptors which can lead to severe and disseminated apoptotic neurodegeneration. Here, we show that systemic administration of the NMDA receptor antagonist MK801 to 7-day-old rats leads to impaired activity of extracellular signal-regulated kinase 1/2 (ERK1/2) and reduces levels of phosphorylated cAMP-responsive element binding protein (CREB) in brain regions which display severe apoptotic neurodegeneration. Impaired ERK1/2 and CREB activity were temporally paralleled by sustained depletion of neurotrophin expression, particularly brain-derived neurotrophic factor (BDNF). BDNF supplementation fully prevented MK801-induced neurotoxicity in immature neuronal cultures and transgenic constitutive activation of Ras was associated with marked protection against MK801-induced apoptotic neuronal death. These data indicate that uncoupling of NMDA receptors from the ERK1/2-CREB signaling pathway in vivo results in massive apoptotic deletion of neurons in the developing rodent brain.

Erythropoietin protects the developing brain against N-methyl-D-aspartate receptor antagonist neurotoxicity.

Pharmacological blockade of NMDA receptor function induces apoptotic neurodegeneration in the developing rat brain. However, the use of NMDA receptor antagonists as anesthetics and sedatives represents a difficult-to-avoid clinical practice in pediatrics. This warrants the search for adjunctive neuroprotective measures that will prevent or ameliorate neurotoxicity of NMDA receptor antagonists. The NMDA receptor antagonist MK801 triggered apoptosis in the neonatal rat forebrain, most notably in cortex and thalamus. MK801 exposure reduced mRNA levels of erythropoietin (EPO) and the EPO receptor, suggesting that loss of endogenous EPO activity may contribute to MK801-induced apoptosis. Coadministration of recombinant EPO (rEPO) conferred 50% neuroprotection, partially restored MK801-induced reduction of brain-derived neurotrophic factor (BDNF) and glial cell line-derived neurotrophic factor (GDNF) mRNA, and prevented decreased phosphorylation levels of extracellular signal-regulated protein kinase-1/2 (ERK1/2) and Akt. These observations indicate that rEPO partly rescues newborn rats from MK801-mediated brain damage by enhancing neurotrophin-associated signaling pathways.

Therapeutic doses of topiramate are not toxic to the developing rat brain.

Antiepileptic drugs (AEDs) used to treat seizures in pregnant women, infants, and young children may cause cognitive impairment. One of the implicated mechanisms is enhancement of apoptotic neuronal death, which occurs physiologically in the developing brain. We investigated whether topiramate, one of the newer antiepileptic drugs, has neurotoxic properties in the developing rat brain. Topiramate slightly but significantly enhanced apoptotic neuronal death in the 7-day-old rat brain at doses of 50 mg/kg and above. These doses are several folds higher than reported ED(50) doses in infant rodent seizure models that respond to topiramate. Electron microscopy confirmed that dying neurons following topiramate treatment displayed the same morphological features as neurons undergoing physiological cell death during development. When compared to the neurotoxicity profile of phenytoin, valproate, and phenobarbital, the separation between the effective anticonvulsant dose and the neurotoxic dose was greater for topiramate and the neurotoxic effect was lower.