Effects of epileptic seizures on brain ribosomes: mechanism and relationship to cerebral energy metabolism

Similar brain proteomic signatures in Alzheimer's disease and epilepsy

The prevalence of epilepsy is increased among Alzheimer's Disease (AD) patients and cognitive impairment is common among people with epilepsy. Epilepsy and AD are linked but the shared pathophysiological changes remain poorly defined. We aim to identify protein differences associated with epilepsy and AD using published proteomics datasets. We observed a highly significant overlap in protein differences in epilepsy and AD: 89% (689/777) of proteins altered in the hippocampus of epilepsy patients were significantly altered in advanced AD. Of the proteins altered in both epilepsy and AD, 340 were altered in the same direction, while 216 proteins were altered in the opposite direction. Synapse and mitochondrial proteins were markedly decreased in epilepsy and AD, suggesting common disease mechanisms. In contrast, ribosome proteins were increased in epilepsy but decreased in AD. Notably, many of the proteins altered in epilepsy interact with tau or are regulated by tau expression. This suggests that tau likely mediates common protein changes in epilepsy and AD. Immunohistochemistry for Aβ and multiple phosphorylated tau species (pTau396/404, pTau217, pTau231) showed a trend for increased intraneuronal pTau217 and pTau231 but no phosphorylated tau aggregates or amyloid plaques in epilepsy hippocampal sections. Our results provide insights into common mechanisms in epilepsy and AD and highlights the potential role of tau in mediating common pathological protein changes in epilepsy and AD.

Fifty years of research on status epilepticus: Seizures use hippocampal memory circuits to generate status epilepticus and disrupt brain development

This is a review of my laboratory's interest in status epilepticus (SE), which spanned five decades. It started with a study of the role of brain mRNAs in memory, and with the use of electroconvulsive seizures to disrupt recently acquired memories. This led to biochemical studies of brain metabolism during seizures, and to the serendipitous development of the first model of self-sustaining SE. The profound inhibition of brain protein synthesis by seizures had implications for brain development, and we showed that severe seizures and SE in the absence of hypoxemia and other metabolic complications can disrupt brain and behavioral development, a concept that was not widely accepted at that time. We also showed that many experimental models of SE can cause neuronal death in the immature brain, even at very young ages. Our studies of self-sustaining SE showed that the transition from single seizures to SE is accompanied by internalization and transient inactivation of synaptic GABAA receptors, while extrasynaptic GABAA receptors are untouched. At the same time, NMDA and AMPA receptors move to the synaptic membrane, creating a "perfect storm" combining failure of inhibition and runaway excitation. Major maladaptive changes in protein kinases and neuropeptides, particularly galanin and tachykinins, also contribute to the maintenance of SE. The therapeutic implications of these results are that our current practice to start the treatment of SE with benzodiazepine monotherapy leaves the changes in glutamate receptors untreated and that sequential use of drugs gives seizures more time to aggravate changes in receptor trafficking. In experimental SE, we showed that drug combinations based on the receptor trafficking hypothesis are far superior to monotherapy in stopping SE late in its course. Combinations that include an NMDA receptor blocker such as ketamine are much better than combinations that follow current evidence-based guidelines, and simultaneous delivery of the drugs is far more effective than sequential delivery of the same drugs at the same dose. This paper was presented as a Keynote Lecture at the 8th London-Innsbruck Colloquium on Status Epilepticus and Acute Seizures held in September 2022.

Phosphorylation of the alpha subunit of translation initiation factor-2 by PKR mediates protein synthesis inhibition in the mouse brain during status epilepticus

In response to different cellular stresses, a family of protein kinases phosphorylates eIF2alpha (alpha subunit of eukaryotic initiation factor-2), contributing to regulation of both general and genespecific translation proposed to alleviate cellular injury or alternatively induce apoptosis. Recently, we reported eIF2alpha(P) (phosphorylated eIF2alpha) in the brain during SE (status epilepticus) induced by pilocarpine in mice, an animal model of TLE (temporal lobe epilepsy) [Carnevalli, Pereira, Longo, Jaqueta, Avedissian, Mello and Castilho (2004) Neurosci. Lett. 357, 191-194]. We show in the present study that one eIF2alpha kinase family member, PKR (double-stranded-RNA-dependent protein kinase), is activated in the cortex and hippocampus at 30 min of SE, reflecting the levels of eIF2alpha(P) in these areas. In PKR-deficient animals subjected to SE, eIF2alpha phosphorylation was clearly evident coincident with activation of a secondary eIF2alpha kinase, PEK/PERK (pancreatic eIF2alpha kinase/RNA-dependent-protein-kinase-like endoplasmic reticulum kinase), denoting a compensatory mechanism between the two kinases. The extent of eIF2alpha phosphorylation correlated with the inhibition of protein synthesis in the brain, as determined from polysome profiles. We also found that C57BL/6 mice, which enter SE upon pilocarpine administration but are more resistant to seizure-induced neuronal degeneration, showed very low levels of eIF2alpha(P) and no inhibition of protein synthesis during SE. These results taken together suggest that PKR-mediated phosphorylation of eIF2alpha contributes to inhibition of protein synthesis in the brain during SE and that sustained high levels of eIF2alpha phosphorylation may facilitate ensuing cell death in the most affected areas of the brain in TLE.

Phosphorylation of translation initiation factor eIF2α in the brain during pilocarpine-induced status epilepticus in mice

In this work, we show extensive phosphorylation of the alpha subunit of translation initiation factor 2 (eIF2alpha) occurring in the brain of mice subjected to 30 min of status epilepticus induced by pilocarpine. eIF2alpha(P) immunoreactivity was detected in the hippocampal pyramidal layer CA1 and CA3, cortex layer V, thalamus and amygdala. After 2 h of recovery, there was a marked decrease in total brain eIF2alpha(P), with the cortex layer V showing the most pronounced loss of anti-eIF2alpha(P) labeling, whereas the CA1 subregion had a significant increase in eIF2alpha(P). These results indicate that inhibition of protein synthesis in experimental models of epilepsy might be due to low levels of eIF2-GTP caused by the phosphorylation of eIF2alpha, and suggest that translational control may contribute to cell fate in the affected areas.

Nuclear polyadenylate polymerase activity in the brain of seizure-prone EL mice

Nuclear polyadenylate polymerase from I activity in the brains of seizure-prone EL mice was significantly higher than in seizure-non-susceptible progenitor ddY mice. This finding may be essential in acquiring susceptibility to seizures, since there was no significant difference between EL(S) mice and those that did not receive stimulation, EL(NS) mice. Lower form II enzymatic activity was observed in both groups of EL mice but not in ddY mice. Moreover, significantly lower activities of form II 7 days after seizures were found in EL(S) mice compared with EL(NS) mice, suggesting that this is a consequence of repeated seizures. The activity of form I enzyme decreased immediately and at 30 and 60 min after seizures, then returned to control levels at 100 min. Form II enzymatic activity was significantly decreased only at 30 min after seizures, implying that seizures exerted a later effect on form II enzyme. These changes may cause a decrease in the rate of polyadenylation in the brain; thus, alteration of post-transcriptional events, including messenger RNA processing and transport, may occur during epileptic seizures.

GABA metabolism in the substantia nigra, cortex, and hippocampus during status epilepticus

The metabolism of GABA and other amino acids was studied in the substantia nigra, the hippocampus and the parietal cortex of rats following microinjections of GAMMA-vinyl-GABA during status epilepticus induced by lithium and pilocarpine. GABA metabolism showed striking regional variations. In controls, both GABA concentration and rate of GABA synthesis were highest in the substantia nigra and lowest in cortex, as expected. In substantia nigra, status epilepticus resulted in a 2 1/2 fold decline in the rate of GABA synthesis and in a 307% increase in the turnover time of the GABA pool. In hippocampus, the rate of GABA synthesis was not altered significantly, but the turnover time of the GABA pool was 284% of controls, and the size of that pool increased to 208% of controls. By contrast, in cortex, where seizure activity is limited in this model, the rate of GABA synthesis increased to 230% of controls while pool size and turnover time did not change. Aspartate concentration decreased in all three brain regions. These data suggest that the observed reduction of the rate of GABA synthesis in substantia nigra could play a key role in seizure spread in this model of status epilepticus.

Expression of the proto-oncogene c-fos following electrical kindling in the rat

Kindling is a permanent form of brain change that results from repeated elicitation of epileptiform neural activity. c-fos has been proposed as the gene responsible for turning on molecular events that might underlie the long-term neural changes that occur during kindling. This study investigated the enhancement of c-fos levels following kindled seizures and the role of c-fos in the plastic changes underlying kindling. Male hooded rats were electrically kindled in the amygdala and the resulting c-fos and c-Ha-ras gene expression was quantified using Northern blot hybridization analysis. The results indicated that c-fos was constitutively expressed in forebrain and cerebellum, and that basal levels of c-fos were equivalent in naive and in fully kindled rats that have been seizure-free for 3 weeks. Following an amygdala-piriform kindled seizure there was a massive and transient increase in c-fos levels throughout forebrain and cerebellum. Although enhanced c-fos levels were correlated with afterdischarge (AD) duration in the kindled site, enhanced c-fos levels were also observed in the amygdala-piriform contralateral to the kindled site, and the enhancement did not depend on the occurrence of AD in the contralateral amygdala-piriform. Furthermore, electrical stimulations not resulting in AD as well as other forms of control stimulation also increased c-fos levels. We conclude that c-fos was expressed simply as a consequence of neural activity and not exclusively due to the specific neural activity or underlying plastic change required for kindling. This does not preclude a role for c-fos in the long-term response to external stimuli, but it does suggest that c-fos is not the crucial 'master switch' in turning on a molecular program that might underlie kindling.

Protein changes associated with cobalt-induced epileptic activity in rat cerebral cortex

In cobalt-induced epileptogenic cortex in rats, a marked increase in two proteins of about 84 kDa and 70 kDa, a slight increase in 12-kDa and 10-kDa proteins and a decrease in a protein of about 57 kDa were noted, as determined by SDS-polyacrylamide gel electrophoresis. The initiation of these protein changes was ahead of the generation of epileptogenic activities. The anticonvulsant drugs phenytoin (PHT) and phenobarbital (PB) attenuated the cobalt-induced epileptogenic activities, but failed to suppress the protein changes. Among these proteins, a 70-kDa protein, when injected intracortically into the motor region of the normal rat cerebrum, evoked epileptic discharges on the electrocorticograph and behavioral seizure, which were abolished by prior treatment with PHT or PB. These findings suggest that the above protein changes are not an indirect offshoot of secondary stimulation of neurons by neurotransmitters or neuromodulators, and that P70 may contribute to the generation of epileptic seizure activities.

A novel protein induced in cortical epileptic focus of rat cerebrum: a possible linkage to epileptogenesis

To precisely evaluate a protein-related mechanism of epileptogenesis, we quantitatively analyzed the 70-kDa protein (namely, P70), a specific protein found in the cobalt-induced epileptic focus, and examined its effect on the electrocorticogram (ECoG) and cortical neurons in cerebral slices and its immunocytochemical localization in rats. Cobalt-induced cortical epileptogenic cortex exhibited a marked induction of P70. Its initiation time was ahead of the generation of epileptogenic activities. The anticonvulsant phenytoin (PHT) attenuated the cobalt-induced epileptogenic activities, but failed to suppress protein induction. Injection of this protein into the motor region of normal rat cerebral cortex elicited an epileptic ECoG and behavioral seizures. It also caused epileptiform activity with paroxysmal depolarization shifts in cortical neurons. These epileptogenic phenomena elicited by P70 were abolished by prior treatment with PHT or phenobarbital. Immunocytochemical analysis with an antiserum against P70 revealed that the reactivity was confined to pyramidal cells only in the region of the focus and was mainly localized on somatic, dendritic, and nuclear membranes and microtubles. These findings suggest that P70 may be linked to epileptogenesis.

Induction of epileptic seizure activity by a specific protein from cobalt-induced epileptogenic cortex of rats

To evaluate the protein-related mechanism for epileptogenesis, we examined protein behavior during cobalt-induced epileptic seizure activity and the effect of injection of cobalt-induced proteins into cerebral cortex on electrocorticographic discharge in rats. Cobalt-induced epileptic seizure activity caused an increase in two proteins that migrated at about 84 kDa (P84) and 70-71 kDa (P70) and a decrease in a protein of about 57 kDa (P57) as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Among these proteins, P70 evoked epileptic discharges on the electroencorticograph and behavioral seizure, when it was intracortically injected into the motor region of the normal rat cerebrum. The data suggest that P70 may be a factor for epileptogenesis.

Translational regulation in rat brain hemispheres

Present studies on the sensitivity of the transcription process in rat cerebral hemispheres showed that the relative abundance and translation of free and bound poly (A)+ mRNAs in a reticulocyte mRNA-dependent system were reduced following 1 h and 4 h of ethanol or pentobarbital administration with free being affected to a greater extent than the bound poly (A)+ mRNAs. In addition, the energy-dependent nucleocytoplasmic transport of in vivo [3H]labeled nuclear RNA to surrogate cytoplasm was modified in response to ethanol exposure. The translocation of the labeled nuclear RNA fraction occurred only to the microsomal/ribosomal fractions of the cytoplasm, was stimulated by cyclic cAMP and abolished when the cytoplasm was depleted of its protein factors following streptomycin treatment, thereby establishing the translocated RNA as messenger RNA. It is concluded that the neural cell, in response to ethanol exposure, modifies the efficiency of nuclear processing and transport of mRNA. This nuclear restriction probably occurs at multi-levels during the post-transcriptional modification of mRNAs.

Preparation of a cell-free extract from rat brain which can initiate protein synthesis in vitro

A cell-free protein synthesis system, derived from brains of 3 mo-old male Fischer-344 rats, has been characterized. The optimum conditions for amino acid incorporation in the system were 5 mM magnesium ion and 200 mM potassium ion. Incorporation depended on the addition of ATP, GTP, and an energy-generating system, and was sensitive to addition of the drugs aurintricarboxylic acid and sodium fluoride, inhibitors of initiation of protein synthesis. Both 40S and 80S initiation complexes were labeled in vitro, using [35S]methionine. Such labeling was sensitive to the protein synthesis inhibitors, aurintricarboxylic acid and sodium fluoride. The system, which can initiate protein synthesis, should be of use for examining mechanisms which underlie alterations in rat brain protein synthesis induced by various treatments.

Characterization of a translational inhibitor isolated from rabbit brain following intravenous administration of d-lysergic acid diethylamide

Intravenous administration of d-lysergic acid diethylamide (LSD) to rabbits results in a transient inhibition of brain protein synthesis in vivo and in vitro. A translational inhibitor that appears in the postribosomal supernatant fraction of cerebral hemispheres following LSD administration was partially purified by gel filtration on Sephadex G-150 and precipitation with 60% ammonium sulfate. This inhibitor, which was proteinaceous, reduced the translational capacity of an initiating cell-free protein synthesis system derived from brain. It also inhibited a messenger RNA-dependent reticulocyte lysate programmed with brain polysomes and a globin-synthesizing reticulocyte lysate system. Addition of the partially purified inhibitor to a brain cell-free protein synthesis system resulted in the decreased formation of ternary complexes as well as 40 and 80S initiation complexes, suggesting that the inhibitor affects an early step in the initiation of protein synthesis in brain.

Role of hyperthermia in effects of electroconvulsive shock on protein synthesis in the rabbit

The effects of electroconvulsive shock (ECS) on rectal temperature (TR) and on protein synthesis in brain and liver were compared in rabbit, rat, and mouse. Protein synthesis status was assessed using an in vitro amino acid incorporation method which provides information equivalent to polyribosome profiles. In the rabbit, TR rose from 39.5 +/- 0.4 degrees C to 40.4 +/- 0.2 degrees C within 10 min following a single ECS, and significant hyperthermia persisted for at least 60 min. This effect was markedly attenuated in animals housed at 4 degrees C. In vitro protein synthesis activities of rabbit brain and liver preparations were significantly reduced following ECS only in those animals whose TR exceeded 40 degrees C. In the rat, ECS gave rise to a significant hyperthermia, but in no case did TR exceed 40 degrees C, and protein synthesis activity of brain supernatants was not affected. In the mouse, ECS reduced TR and had no effect on in vitro protein synthesis activity. These results demonstrate that the unique sensitivity of protein synthesis in rabbit tissues to electroconvulsive shock is a direct consequence of the hyperthermia that arises following ECS in this species.

Effect of intravenous administration of D-lysergic acid diethylamide on initiation of protein synthesis in a cell-free system derived from brain

An initiating cell-free protein synthesis system derived from brain was utilized to demonstrate that the intravenous injection of D-lysergic acid diethylamide (LSD) to rabbits resulted in a lesion at the initiation stage of brain protein synthesis. Three inhibitors of initiation, edeine, poly(I), and aurintricarboxylic acid were used to demonstrate a reduction in initiation-dependent amino acid incorporation in the brain cell-free system. One hour after LSD injection, there was also a measurable decrease in the formation of 40S and 80S initiation complexes in vitro, using either [35S]methionine or [35S]Met-tRNAf. Analysis of the methionine pool size after LSD administration indicated there was no change in methionine levels. Analysis of the formation of initiation complexes in the brain cell-free protein synthesis system prepared 6 h after LSD administration indicated that there was a return to control levels at this time. The effects of LSD on steps in the initiation process are thus reversible.

Focal seizures disrupt protein synthesis in seizure pathways: an autoradiographic study using [1-14C]leucine

We have used a new autoradiographic technique developed by Smith et al.22,33 for visualizing rates of incorporation of [1-14C]leucine into protein in brain. Focal seizures caused by topical convulsants resulted in a marked decrease in autoradiographic density. This was primarily confined to the seizure focus, especially marked in pyramidal cell layers, and to subcortical seizure pathways. There were no distinct changes in cortico-cortical pathways beyond the seizure focus. Pure orthodromic pathways through basal ganglia showed an 18% inhibition of leucine incorporation in caudate nucleus and substantia nigra, pars compacta (P less than 0.05). By contrast, thalamic nuclei connected both ortho- and antidromically to the focus showed a 30-63% inhibition (P less than 0.01). The topographic pattern and intensity of the thalamic changes were related to the site, size and intensity of the seizure focus. As seizures became severe there was a more generalized depression of metabolism beyond seizure pathways, especially in the ipsilateral hemisphere. The results suggest that seizures block incorporation of leucine into protein either by an increase oxidation of the precursor, and/or an inhibition of protein synthesis per se. The effect is most severe in neurons undergoing epileptic burst discharge in the focus and in thalamic neuronal beds connected reciprocally with the focus.

Effect of epileptogenic agents on the incorporation of 3H-glycine into proteins in the cat's cerebral cortex

Filter paper strips soaked in 3H-glycine solution were applied to acoustic cortex of cats, anaesthetized with Nembutal and pretreated with epileptogenic agents (Metrazol, G-penicillin, and 3-amino-pyridine) and cycloheximide. The untreated contralateral hemisphere served as control. After 1 h incubation, both cortical samples were excised simultaneously and fixed in Bouin solution for autoradiography. Incorporation was blocked by cycloheximide. There was no glycine incorporation on the penicillin-treated side, while pyramidal cells were intensively labelled in layers II-V of the mirror focus. 3-Aminopyridine produced the same result. Metrazol as convulsant proved to be far weaker than the previous two. The intensity of incorporation was significantly more intensive in the mirror focus than in the primary one. Penicillin and 3-aminopyridine, while provoking cortical seizures, seem to inhibit glycine incorporation into a neuron-specific, function-dependent protein contained by the labelled cells in the autoradiogram.

Characterization of an initiating cell-free protein synthesis system derived from rabbit brain

Protein synthesis in the brain is known to be affected by a wide range of treatments. The detailed analysis of the mechanisms that are involved would be facilitated by the development of cell-free translation systems derived from brain tissue. To date, brain cell-free systems have not been fully characterized to demonstrate a capacity for initiation of translation. The following criteria were utilized to demonstrate that a cell-free protein synthesis system derived from rabbit brain was capable of initiation in vitro: (a) sensitivity of cell-free translation to the initiation inhibitor aurintricarboxylic acid (ATA); (b) binding of [35S]Met-tRNAf to 40S and 80S initiation complexes; (c) incorporation of labeled initiation methionine into high-molecular-weight proteins; and (d) the association of labeled exogenous mRNA with polysomes. The optimum conditions for amino acid incorporation in this system were 4 mM-Mg2+, 140 mM-K+, and pH 7.55. Incorporation was dependent on the addition of ATP, GTP, and an energy-generating system. Cell-free protein synthesis reflected the normal process, since a similar spectrum of proteins was synthesized in vitro and in vivo. This initiating cell-free translation system should have wide application in the analysis of the mechanisms whereby various treatments affect protein synthesis in the brain.

Comparison of the effect of intravenous administration of d-lysergic acid diethylamide on free and membrane-bound polysomes in the rabbit brain

The intravenous administration of LSD to young adult rabbits resulted in the disaggregation of both free and membrane-bound classes of brain polysomes. Based on the analysis of LSD dosage and the time course of the LSD-induced brain polysome shift, it was found that free polysomes were more sensitive to the drug than the membrane-bound polysome fraction. LSD-induced hyperthermia may be involved in the disaggregation of free and membrane-bound polysomes, since a correlation was found between the extent of LSD-induced hyperthermia and the degree of brain polysome shift. Prevention of LSD-induced hyperthermia by maintaining the animal at 4 degrees C blocked the disaggregation of both polysome classes. Induction of hyperthermia by elevation of ambient temperature also resulted in a shift in free and membrane-bound polysomes. In all cases the disaggregation of polysomes to monosomes was not caused by RNase activation. During polysome disaggregation, polyadenylated mRNA associated with both free and membrane-bound polysomes was not degraded but was relocalized from polysomes to monosomes.

Pathogenesis of brain lesions caused by experimental epilepsy. Light- and electron-microscopic changes in the rat cerebral cortex following bicuculline-induced status epilepticus

Status epilepticus was induced in rats by the GABA receptor blocking agent, bicuculline, during artificial ventilation and with closely monitored physiologic parameters. After 1 or 2 h of status epilepticus the brains were fixed by perfusion with glutaraldehyde and processed for light and electron microscopy. In the cerebral cortex two different types of changes were present, i.e., nerve cell injuries and status spongiosus. Type 1 injured neurons, mainly in the areas of most marked sponginess (layer 3), displayed progressive condensation of both karyo-and cytoplasm. In the most advanced stages the nucleus could no longer be distinguished from the cytoplasm in the light microscope, and vacuoles of apparent Golgi cisterna origin appeared in the darkly stained cytoplasm. This type of injured neurons comprised 41 and 56% of the cortical neurons after 1 or 2 h of status epilepticus, respectively. Seven to 9% of the neurons showed another type of injury (type 2). They were mainly located in the deeper cortical layers, and showed slit-formed cytoplasmic vacuoles chiefly due to swelling of the endoplasmic reticulum including the nuclear envelope. Marked sponginess of the cortex developed principally in layer 3 and it spread into deeper layers with longer duration of status epilepticus, but the outermost layers retained a compact structure. As judged by electron microscopy, the sponginess resulted mainly from swelling of astrocytes and their processes causing both perivascular and perineuronal vacuolation. The structural changes observed are considered to be caused by astrocytic and to a lesser extent intraneuronal edema related to the seizure activity. Although the exact pathogenetic mechanisms are not known, our findings indicate that hypoxia-ischemia is not a major determinant of the tissue damage observed.

Age-dependent changes in brain protein synthesis in the rat

Brain protein synthesis was studied in vivo, in brain slices, and in cell-free systems in rats aged 1, 16, and 24 months. We observed a highly significant reduction in amino acid incorporation with advancing age. This reduction was observed in vivo, in slices, in postmitochondrial supernatant, microsomes, and membrane-bound polysomes. Free heavy polysomes showed no age-dependent decline but formed a smaller proportion of total ribosomes in older animals. These studies suggest that in the rat brain protein synthesis declines before senescence, possibly due to an impairment in the initiation process.

A simple reproducible cell-free system for measuring brain protein synthesis

A simple, rapid, sensitive, and reproducible cell-free assay system for studying brain protein synthesis is described. This system uses small amounts of brain postmitochondrial supernatant, making it a convenient screening test when only small amounts of tissue are available. It showed over 95% dependence on Mg2+ and on an energy source. Optimal incorporation occurred under the following conditions: Mg2+ 3 mM; ATP, 0.6 mM; GTP, 0.6 mM; high K+, greater than or equal to 25 mM; Low Na+, less than or equal to 15 mM; pH 7.1-7.5. The rate of amino acid incorporation did not vary with leucine concentrations in vitro up to 1 mM, which obviated the need to measure endogenous leucine concentrations.

Fate of mRNA following disaggregation of brain polysomes after administration of (+)-lysergic acid diethylamide in vivo

Intravenous injection of (+)-lysergic acid diethylamide into young rabbits induced a transient brain-specific disaggregation of polysomes to monosomes. Investigation of the fate of mRNA revealed that brain poly(A+)mRNA was conserved. In particular, mRNA coding for brain-specific S100 protein was not degraded, nor was it released into free ribonucleoprotein particles. Following the (+)-lysergic acid diethylamide-induced disaggregation of polysomes, mRNA shifted from polysomes and accumulated on monosomes. Formation of a blocked monosome complex, which contained intact mRNA and 40-S plus 60-S ribosomal subunits but lacked nascent peptide chains, suggested that (+)-lysergic acid diethylamide inhibited brain protein synthesis at a specific stage of late initiation or early elongation.

Rapid changes in brain benzodiazepine receptors after experimental seizures

Seizures induced in the rat by electroshock or by injections of pentylenetetrazol increase the specific binding of diazepam to putative receptor sites in cerebral cortical membranes. The enhancement of diazepam binding results from a rapid increase in the number of available binding sites rather than a change in receptor affinity. The postictal increase in cortical benzodiazepine receptors suggests that the cerebral cortex might be more sensitive to the anticonvulsant effects of the benzodiazepines after seizures. This observation may be related to the mechanism of action of these drugs in the treatment of recurrent seizures such as status epilepticus.