Alteration of opioid receptors in seizure-susceptible El mouse brain

The distribution density of opioid receptors in the brain of El mice (seizure-susceptible strain) was examined to determine the relation between seizures and the opioid system. Saturation curves and Scatchard plots of [³H]2-d-alamine-5-d-leucine enkephalin binding revealed that the opioid delta receptor density in adult El mice during interictal periods was significantly increased in the cerebral cortex, hippocampus, and septal area. It was further shown that the concentration of such receptors in 25-day-old El mice that had no seizures was also significantly increased in the hippocampus and septal area, with no changes in apparent affinities, as compared with in the corresponding regions in ddY mice (seizure-nonsusceptible strain; the mother strain of El). Such up-regulation of opioid receptors in the El mouse brain could result from deficits in endogenous opioid peptides, which could be associated with the pathogenesis of seizure diathesis in the El mouse.     

Endogenous methionine enkephalin may play an anticonvulsant role in the seizure-susceptible El mouse

After the intracisternal injection of three protease inhibitors which prevent the degradation of methionine enkephalin (amastatin, Des-Pro²-bradykinin, and phosphoramidon) and a mixture of these protease inhibitors, we investigated the effect on convulsive seizures in the seizure-susceptible El mouse. We also measured the cerebral methionine enkephalin content by high-performance liquid chromatography coupled with radioimmunoassay. Protease inhibitors significantly decreased both the incidence of seizures and the seizure score in El mice in a dose-dependent manner. This anticonvulsant effect was reversed by naloxone (2 mg/kg, sc). The cerebral methionine enkephalin content increased significantly after the administration of protease inhibitors in comparison with saline injection. These findings suggest that it was not protease inhibitors but instead increase of endogenous methionine enkephalin that reduced the incidence of seizures and the seizure score in El mice. Together with our previous data, the present findings support our hypothesis that a deficit in anticonvulsant endogenous methionine enkephalin is involved in the pathogenesis of seizures in the El mouse.     

HPLC/RIA analysis of bioactive methionine enkephalin content in the seizure-susceptible El mouse brain

We previously reported a deficit of methionine enkephalin-like immunoreactivity (ME-LI), in the cerebral cortex, septal area, hippocampus, and striatum and the abnormal metabolism of opioid peptides in the hippocampus and striatum of seizure-susceptible El mice, which are involved in the pathogenesis of seizures. However, these findings suggest that the ME-LI does not necessarily reflect the bioactive methionine enkephalin (ME). Herein, we measured the biologically active peptide, ME excluding cross-reactive substances by using HPLC coupled with radioimmunoassay to clarify the abnormal function of enkephalinergic neurons in the El mouse brain. The ME content in 25-day-old El mice that had no seizures was significantly decreased in the hippocampus and septal area, as compared with corresponding regions in ddY mice (seizure-nonsusceptible; the mother strain of El). At the age of 50 days when El mice displayed abortive seizures, this content in both stimulated El[s] and nonstimulated El[ns] was significantly reduced in the septal area and cerebral cortex. At the age of 150 days when El mice exhibit tonic-clonic seizures, this content in both El[s] and El[ns] was significantly reduced in the septal area, cerebral cortex and striatum. These findings were generally compatible with our previous findings. This study further supports our hypothesis that a deficit of anticonvulsant endogenous ME, in the cerebral cortex, septal area, and hippocampus of seizuresusceptible El mice play an important role in the pathogenesis of seizures.     

Developmental and regional alteration of methionine enkephalin-like immunoreactivity in seizure-susceptible E1 mouse brain

Methionine enkephalin-like immunoreactivity (ME-LI) in the brain of El mice (seizure-susceptible strain) was measured by radioimmunoassay (RIA) to elucidate the relation between seizures and the opioid system. The lyophilized supernatants of tissue extracts were subjected to ME RIA. The concentration of ME-LI in 25-day-old El mice that had no seizures was significantly decreased in the hippocampus. At the age of 50 days when El mice displayed abortive seizures, the levels of ME-LI in both El(+) and nonstimulated El(o) mice were also significantly reduced in the hippocampus and septal area. It was further shown that the ME-LI concentrations in both 150-day-old adult El(+) during interictal periods and El(o) mice were markedly decreased in the cerebral cortex, septal area, and striatum, as compared with the corresponding regions in ddY mice (seizurenonsusceptible strain; the mother strain of El). The decrease of ME-LI in the El mouse brain was generally compatible with our previous findings concerning the up-regulation of opioid delta receptors in this species. These results suggest that the reduction of ME-LI in the El mouse brain is not due to convulsions, but could be associated with the pathogenesis of seizure diathesis and seizure manifestations in the El mouse.     

Metabolic profile of opioid peptides differs in the hippocampus and striatum of seizure-susceptible E1 mice

We previously suggested that a deficit of anticonvulsant endogenous methionine enkephalin, in the cerebral cortex, septal area, hippocampus, and striatum of seizure-susceptible E1 mice plays a role in the pathogenesis of seizures. To determine whether a hypofunction of enkephalinergic neuron may be due to metabolic abnormalities of opioid peptides in the E1 mouse brain, we measured methionine enkephalin-like immunoreactivity (ME-LI) of 50 fractions eluted by high performance liquid chromatography obtained from those four regions of the brain of E1 and seizure-nonsusceptible ddY mice (the mother strain of E1 mice). We observed the same ME-LI patterns of 50 fractions in the cerebral cortex and septal area in E1 and ddY mice, whereas exhibited differing ME-LI patterns in the hippocampus and striatum in the two stains. Different ME-LI patterns may imply the difference in the metabolic profile of opioid peptides. Thus, an abnormal metabolism of opioid peptides in the hippocampus and striatum of the E1 mouse may be involved in the pathogenesis of seizures.     

Differences in ME-LI and VIP-LI in discrete brain regions of seizure-naive and seizure-experienced El mice

In an attempt to elucidate the relationship between endogenous methionine-enkephalin (ME) and vasoactive intestinal polypeptide (VIP) with generalized seizures, we determined regional brain levels of ME-like and VIP-like immunoreactivity (ME-LI and VIP-LI) in El mice during and after seizures induced by repeated tossing stimulation. The levels of ME-LI in the striatum and hippocampus of seizure-naive El mice (El–) were lower than those of the control ddY mice, the mother strain of El mice. Conversely, the level of VIP-LI in the medulla oblongata and pons of El– was higher than that of ddY mice. The level of ME-LI in the striatum of seizure-experienced El mice (El+) killed 96 hours after three consecutive seizures was high, while levels of VIP-LI in the striatum and hypothalamus were low, in comparison to those of El– mice. A detailed time-course study revealed that seizures in El mice caused (1) significant decreases in levels of ME-LI in the striatum and hippocampus during seizures, (2) a significant decrease of VIP-LI content in the striatum 3 hours after seizures, and (3) a significant increase in hypothalamic VIP-LI 9 hours after seizures. These observations suggest that ME and VIP may play some role in El mouse seizures.     

Effects of muscimol and baclofen on levels of monoamines and their metabolites in the El mouse brain

We compared the changes in monoamines and their metabolites in the El mouse brain induced by GABA-A and GABA-B receptor agonists. Muscimol was used as a GABA-A receptor agonist, and baclofen as a GABA-B receptor agonist. Muscimol (3 mg/kg) significantly increased the DOPAC level in all parts of the mouse brain and the HVA level in the cortex, striatum, and midbrain. No significant change was observed in the dopamine (DA) level. These findings suggest that muscimol may accelerate both the synthesis and catabolism of DA. Baclofen (20 mg/kg) increased the DA level in the hippocampus and midbrain, and the DOPAC level in the hippocampus. Muscimol increased 5-HIAA levels and decreased 5-HT levels. This result suggests that 5-HT metabolism is accelerated by muscimol. No change in 5-HT or 5-HIAA levels was induced by baclofen. The GABA-A receptor system seems to have a potent effect not only on DA neurons, but on 5-HT neurons. However, the GABA-B receptor system appears to have almost no effect on 5-HT neurons, though it appears to have some effect on DA neurons.     

Regional excitatory and inhibitory amino acid levels in epileptic El mouse brain

Inbred mutant El mice are highly susceptible to convulsive seizures upon tossing stimulation. The levels of excitatory (e.g. glutamate and aspartate) and inhibitory amino acids [e.g. -aminobutyrate (GABA)] were examined in discrete regions of stimulated El mice [El(+)] non-stimulated El mice [El(-)] and ddY mice, which do not have convulsive disposition. In comparison with ddY, a general increased levels of aspartate, glutamate, glutamine, and taurine were detected in brain regions of El(-). The levels of GABA and glycine were almost the same in ddY and El(-). Compared to El(+), the levels of aspartate, glutamate, glutamine, and GABA in El(-) were either the same or higher. In the case of taurine and glycine, the levels in El(-) were either the same or lower than El(+). Alanine is special in that El(-) have a higher level than El(+) in hippocampus but lower in cerebellum. Furthermore, while marked changes were registered in several brain regions, none of the amino acids investigated showed any significant differences in the hypothalamus of three different groups of mice.     

Decreased benzodiazepine receptor binding in epileptic El mice: A quantitative autoradiographic study

Benzodiazepine receptors and subtypes were examined in El mice and normal ddY mice with a quantitative autoradiographic technique. Specific [³H]flunitrazepam binding in stimulated El mice, which had experienced repeated convulsions, was significantly lower in the cortex and hippocampus than in ddY mice and unstimulated El mice. In the amygdala, specific [³H]flunitrazepam binding in stimulated El mice was lower than in ddY mice. There was a tendency for the [³H]flunitrazepam binding in these regions in unstimulated El mice to be intermediate between that in stimulated El mice and that in ddY mice, but there was no significant difference between unstimulated El mice and ddY mice. [³H]Flunitrazepam binding displaced by CL218,872 was significantly lower in the cortex of stimulated El mice than in that of the other two groups, and in the hippocampus of stimulated than of unstimulated El mice. These data suggest that the decrease in [³H]flunitrazepam binding in stimulated El mice may be due mainly to that of type 1 receptor and may be the result of repeated convulsions.     

Absence of seizure activity following focal cerebral injection of enkephalins in a primate

Baboons (Papio papio) with photosensitive epilepsy have been chronically prepared with guide cannulae and deep electrodes to study the effects of focal injections of opioids.In the hippocampus, amygdala and thalamus (centre median) 50–100 μg morphine, 20–100 μg Met-enkephalin or 2–10 μg FK 33,824 do not induce local or general electrographic or motor signs of epilepsy.The acute epileptogenic effect of morphine and enkephalins observed in rats is not a general phenomenon whereas the anticonvulsant action of opioids acting on μ-receptors is seen in rodents and primates.     

Increased seizure susceptibility induced by guanidinoethane sulfonate in El mice and its relation to glutamatergic neurons

Convulsions and brain levels of amino acids and 5-hydroxytryptamine (5-HT) in El mice were examined after oral administration of a 1% guanidinoethane sulfonate (GES) solution. The incidence of convulsions increased 3 days after starting GES administration, and this effect continued throughout the 6 months of drug administration. Glutamate levels were increased in the cerebrum, and glutamine levels were increased in the cerebellum three days after starting GES administration. Brain 5-HT levels were not changed at that time. These results suggest that increased seizure susceptibility induced by GES in mice is related to glutamatergic neurons.     

Age- and seizure-related changes in noradrenaline and dopamine in several brain regions of epileptic El mice

Noradrenaline (NA) and dopamine (DA) levels in six brain regions of stimulated and nonstimulated El (El[s] and El[ns]) mice and their maternal ddY mice were determined at various ages and various times after a convulsion. The NA levels in the striatum and hippocampus of 12-week-old El[s] and El[ns] mice were lower than in ddY mice, and remained lower in 23-week-old El[s] mice, but not in El[ns] mice. DA levels were lower in the striatum of El[s] mice than in El[ns] and ddY mice at 16 and 23 weeks of age. NA levels decreased during seizure in the striatum and hippocampus of El[s] mice, and returned to preconvulsive levels 1 hr after convulsion in the striatum and 30 min in the hippocampus. DA levels in the striatum of El[s] mice decreased during convulsion and increased from 1 to 10 min after convulsion. These changes suggest that the NAergic systems in the striatum and hippocampus and the DAergic system in the striatum have important roles in relation to seizure susceptibility in El mice.     

Opioid receptors and opioid peptides in the cardiomyogenesis of mouse embryonic stem cells

The stimulation of myocardium repair is restricted due to the limited understanding of heart regeneration. Interestingly, endogenous opioid peptides such as dynorphins and enkephalins are suggested to support this process. However, the mechanism—whether through the stimulation of the regenerative capacity of cardiac stem cells or through effects on other cell types in the heart—is still not completely understood. Thus, a model of the spontaneous cardiomyogenic differentiation of mouse embryonic stem (mES) cells via the formation of embryoid bodies was used to describe changes in the expression and localization of opioid receptors within cells during the differentiation process and the potential of the selected opioid peptides, dynorphin A and B, and methionin-enkephalins and leucin-enkephalins, to modulate cardiomyogenic differentiation in vitro. The expressions of both κ- and δ-opioid receptors significantly increased during mES cell differentiation. Moreover, their primary colocalization with the nucleus was followed by their growing presence on the cytoplasmic membrane with increasing mES cell differentiation status. Interestingly, dynorphin B enhanced the downregulation gene expression of Oct4 characteristic of the pluripotent phenotype. Further, dynorphin B also increased cardiomyocyte-specific Nkx2.5 gene expression. However, neither dynorphin A nor methionin-enkephalins and leucin-enkephalins exhibited any significant effects on the course of mES cell differentiation. In conclusion, despite the increased expression of opioid receptors and some enhancement of mES cell differentiation by dynorphin B, the overall data do not support the notion that opioid peptides have a significant potential to promote the spontaneous cardiomyogenesis of mES cells in vitro.     

吗啡对鸡胚胎发育的影响

目的：研究吗啡对胎动、心率、孵化率、孵化时间、雏鸡体重等的影响。方法：以气室给药的方式给鸡胚注射吗啡,记录胎动、心率、孵化率、孵化时间、雏鸡体重。结果：吗啡可以缩短雏鸡的孵化时间,降低雏鸡的孵化率,并导致雏鸡出现运动障碍;20mg／kg吗啡剂量和12—16胚龄的给药时间,鸡胚孵化率最高,残疾率最低;吗啡导致胚胎心率加快,胎动减少（P〈0．05）。结论：吗啡对胚胎发育有损伤作用,损伤程度与吗啡剂量和给药时间有关。     

Shifted Cytosolic NADP+-Dependent Isocitrate Dehydrogenase on 2-D Gel in the Brain of Genetically Epileptic El Mice

We observed a spot on two-dimensional (2-D) gel in the epileptic mutant strain El mice with a similar molecular weight but with a different isoelectric point of approximately 0.2, compared with its mother strain ddY mice. The collected protein from the El mice was identified as cytosolic NADP⁺-dependent isocitrate dehydrogenase by internal amino acid sequencing. The enzyme is known to be maximally active during the development of the brain and to play an important role in NADPH production for fatty acids and cholesterol synthesis. In addition, alterations in cholesterol synthesis early in the development of the mammalian brain have been reported to lead to chronic epilepsy. The results in the present study therefore suggest that cytosolic NADP⁺-dependent isocitrate dehydrogenase might be involved in the epileptogenesis of the El mouse.     

Effects of 5-azacytidine on the development of parthenogenetic mouse embryos

This study describes the effects of 5-azacytidine (5-azaC) on the development of diploid parthenogenetic embryos (PE) of CBA, C57BL/6 and (CBA × C57BL/6)F₁ mice in vitro at the 1-cell or the blastocyst stage or in vivo after implantation. Our findings indicate that genomic imprinting is modulated by genetic background. Non-fertilized C57BL/6 eggs form diploid parthenogenetic blastocysts at a much higher frequency than CBA eggs. Eggs from F₁ hybrid females form parthenogenetic blastocysts at an approximately intermediate level between these inbred strains of mice. C57BL/6 PE do not develop to the somite stages. In contrast, CBA PE and F₁ PE develop to various somite stages. Following administration of 5–azaC at 1.0 μmol/L in vitro at the 1- -cell stage, the number of implantations of C57BL/6 PE transferred to pseudopregnant females increased. In contrast, the number of implantations and somite F₁ PE did not significantly change following exposure to 5–azaC. However, administration of 5-azaC at the 1-cell stage stimulates development of somite F₁ PE. Administration of 5-azaC at 0.2 and 1.0 μmol/L in vitro at the blastocyst stage did not change the number of implantations of C57BL/6 PE. However, the number of implantations and somite CBA PE decreased. After injection of 5azaC at 0.24mg/kg in vivo at day 8 of gestation, some F₁ PE developed to 26–35 somites compared with a maximum of 25 somites in controls. The different effects of 5-azaC on the development of PE depend upon the mouse strain used and the stage of development.     

A locus on mouse Ch10 influences susceptibility to limbic seizure severity: fine mapping and in silico candidate gene analysis

Identification of genes contributing to mouse seizure susceptibility can reveal novel genes or pathways that provide insight into human epilepsy. Using mouse chromosome substitution strains and interval‐specific congenic strains (ISCS), we previously identified an interval conferring pilocarpine‐induced limbic seizure susceptibility on distal mouse chromosome 10 (Ch10). We narrowed the region by generating subcongenics with smaller A/J Ch10 segments on a C57BL/6J (B6) background and tested them with pilocarpine. We also tested pilocarpine‐susceptible congenics for 6‐Hz ECT (electroconvulsive threshold), another model of limbic seizure susceptibility, to determine whether the susceptibility locus might have a broad effect on neuronal hyperexcitability across more than one mode of limbic seizure induction. The ISCS Line 1, which contained the distal 2.7 Mb segment from A/J (starting at rs29382217), was more susceptible to both pilocarpine and ECT. Line 2, which was a subcongenic of Line 1 (starting at rs13480828), was not susceptible, thus defining a 1.0 Mb critical region that was unique to Line 1. Bioinformatic approaches identified 45 human orthologs within the unique Line 1 susceptibility region, the majority syntenic to human Ch12. Applying an epilepsy network analysis of known and suspected excitability genes and examination of interstrain genomic and brain expression differences revealed novel candidates within the region. These include Stat2, which plays a role in hippocampal GABA receptor expression after status epilepticus, and novel candidates Pan2, Cdk2, Gls2 and Cs, which are involved in neural cell differentiation, cellular remodeling and embryonic development. Our strategy may facilitate discovery of novel human epilepsy genes .     

New insights on the potential anti-epileptic effect of metformin: Mechanistic pathway

Epilepsy is a chronic neurological disease characterized by recurrent seizures. Epilepsy is observed as a well-controlled disease by anti-epileptic agents (AEAs) in about 69%. However, 30%–40% of epileptic patients fail to respond to conventional AEAs leading to an increase in the risk of brain structural injury and mortality. Therefore, adding some FDA-approved drugs that have an anti-seizure activity to the anti-epileptic regimen is logical. The anti-diabetic agent metformin has anti-seizure activity. Nevertheless, the underlying mechanism of the anti-seizure activity of metformin was not entirely clarified. Henceforward, the objective of this review was to exemplify the mechanistic role of metformin in epilepsy. Metformin has anti-seizure activity by triggering adenosine monophosphate-activated protein kinase (AMPK) signalling and inhibiting the mechanistic target of rapamycin (mTOR) pathways which are dysregulated in epilepsy. In addition, metformin improves the expression of brain-derived neurotrophic factor (BDNF) which has a neuroprotective effect. Hence, metformin via induction of BDNF can reduce seizure progression and severity. Consequently, increasing neuronal progranulin by metformin may explain the anti-seizure mechanism of metformin. Also, metformin reduces α-synuclein and increases protein phosphatase 2A (PPA2) with modulation of neuroinflammation. In conclusion, metformin might be an adjuvant with AEAs in the management of refractory epilepsy. Preclinical and clinical studies are warranted in this regard.