Biotin deficiency facilitates kindling hyperexcitability in rats

Biotin-deficient conditions are frequently associated with epileptic disorders. Biotin deficiency may be caused by long-term treatment with anticonvulsants or excessive ingestion of avidin. Absence of biotinidase activity can also lead to biotin deficiency, and is characterized by developmental delay as well as neurological and dermatological abnormalities. Because seizures are one of the most frequent signs of the latter, biotin-deficient conditions could conceivably facilitate convulsive disorders. To test this hypothesis, we investigated the occurrence of a latent kindling hyperexcitability in biotin-deprived rats. In these animals, duration of after-discharge on the first stimulation was longer at threshold amplitude, kindling development through its early stages was accelerated and duration of the forelimb clonus of fully kindled seizures was increased. Biotin deprivation in mixed cerebellar granule cell-astrocyte cultures also produced a tetrodotoxin-sensitive delayed loss of the glutamatergic neuronal population. The data thus support a facilitatory role for biotin-deficient conditions in convulsive disorders.

N-(2-hydroxyethyl)hexadecanamide is orally active in reducing edema formation and inflammatory hyperalgesia by down-modulating mast cell activation

Mast cells play a key role in inflammatory reactions triggered by tissue injury or immune perturbations. Little is known about endogenous molecules and mechanisms capable of modulating inappropriate mast cell activity. N-(2-Hydroxyethyl)hexadecanamide (palmitoylethanolamide), found in peripheral tissues, has been proposed to act as a local autacoid capable of negatively regulating mast cell activation and inflammation-hence the acronym Autacoid Local Inflammation Antagonism (ALIA). Recently, N-(2-hydroxyethyl)hexadecanamide (LG 2110/1) has been reported to down-modulate mast cell activation in vitro by behaving as an agonist at the peripheral cannabinoid CB2 receptor. Here, we have characterized and functionally correlated the anti-inflammatory actions of LG 2110/1 with its ability to control mast cell activation, when given orally in a battery of rodent models of inflammation. LG 2110/1 diminished, in a dose-dependent and correllated manner, the number of degranulated mast cells and plasma extravasation induced by substance P injection in the mouse ear pinna. In addition, LG 2110/1 reduced dose dependently plasma extravasation induced by passive cutaneous anaphylaxis reaction. In adult rats LG 2110/1 decreased, in a dose-dependent manner, carrageenan-induced hindpaw edema and hyperalgesia, but not phospholipase A2-induced hindpaw edema. Further, anti-edema effects were observed when utilizing dextran and formalin, known to also cause mast cell activation. Locally administered LG 2110/1 was likewise effective in minimizing dextran-induced hind paw edema. In contrast, equivalent amounts of palmitic acid plus ethanolamine were ineffective against plasma extravasation provoked by substance P. LG 2110/1 did not decrease plasma extravasation induced by the substance P fragment, substance P-(6-11), known to be inactive on mast cells. These results indicate that orally administered N-(2-hydroxyethyl)hexadecanamide is effective in: (a) directly down-modulating mast cell activation in vivo; (b) suppressing pathological consequences initiated by mast cell activation independently of the activating stimuli; (c) exerting an anti-inflammatory action distinguishable from that of classical steroidal and non-steroidal anti-inflammatory agents. These findings raise the possibility that N-(2-hydroxyethyl)hexadecanamide and related saturated N-acylamides ('ALIAmides') represent novel therapeutic agents useful in the management of inflammatory disease conditions.

Monosialoganglioside GM1 reduces NMDA neurotoxicity in neonatal rat brain

Monosialoganglioside GM1 prevents excitatory amino acid (EAA)-related neuronal death in cultured central nervous system (CNS) neurons and reduces the severity of acute brain damage in different experimental models of cerebral ischemia. Using a model of brain damage induced by intracerebroventricular administration of N-methyl-D-aspartate (NMDA) in neonate rats, we evaluated whether GM1 is capable of exerting antiexcitotoxic effects following its systemic administration in vivo. Newborn rats subjected to brain damage by NMDA and contemporaneously treated subcutaneously with GM1 showed significantly reduced (i) loss in hemispheric weight, (ii) loss in tissue choline acetyltransferase activity, and (iii) morphological damage in various brain areas. These results indicate that systemic GM1 treatment is efficacious in reducing EAA-related neuronal damage in vivo and suggest that such a phenomenon may underlie its capability to ameliorate neurological outcome following cerebral ischemia.

Effects of monosialoganglioside GM1 in experimental models of ischemic brain damage

Systemic administration of monosialoganglioside GM1 is efficacious in reducing excitatory amino acid (EAA)-related neurotoxicity in vivo following intracerebroventricular injection of N-methyl-D-aspartate (NMDA) in 7-day-old rats. Five days later, NMDA-treated animals showed extensive brain damage which was accompanied by significant decreases in brain weight, choline acetyltransferase activity and 3H-ouabain binding. All these neurotoxic effects were significantly reduced with ganglioside treatment. Since excessive activation of EAAS is implicated in hypoxic-ischemic brain damage, these results favor the hypothesis that a similar effect is involved in the ability of ganglioside to ameliorate outcome following cerebral ischemia.

Hypoxic-ischemic damage and the neuroprotective effects of GM1 ganglioside

In vitro studies have shown that monosialoganglioside GM1 reduces excitatory amino acid-related neurotoxicity by limiting the downstream consequences of abusive excitatory amino acid receptor stimulation. Systemic administration of GM1 appears to be efficacious in reducing acute neuronal damage and in facilitating medium- and long-term functional recovery after brain injury. We propose that GM1 protective effects in the acute injury phase results from attenuation of excitotoxicity, whereas the functional recovery seen at longer term could reflect GM1 potentiation of neuronotrophic factors. The potential therapeutic efficacy of GM1 administration in humans is suggested by clinical studies demonstrating improved neurologic outcome in stroke patients.

Intracerebral quinolinic acid injection in the rat: effects on dopaminergic neurons

Intrastriatal infusion of the endogenous excitotoxin quinolinic acid (QUIN) leads to the degeneration of neuronal cell bodies around the injection site. Dopaminergic afferents not only survive the toxic insult but react by increasing their activity in the acute and subacute phases following the injection of QUIN. Measurements of the tissue concentrations of acidic dopamine metabolites, and determinations of L-DOPA accumulation after DOPA-decarboxylase inhibition, indicate an increased dopamine turnover within 90 min after the administration of 50 micrograms QUIN. At the later timepoints examined (6 h, 4 and 11 days after QUIN), dopaminergic parameters are increased in the injected striatum only while no changes can be detected in the homolateral substantia nigra. Local norepinephrine levels are elevated 4 and 11 days after an intrastriatal QUIN injection but remain unchanged at distant sites or earlier postinjection periods. The acute increase in nigrostriatal activity may be mediated by an excessively stimulated, yet functional striatonigral feedback loop whereas subsequent changes represent local reactions of dopaminergic nerve terminals secondary to neuronal degeneration in the striatum. In accordance with this interpretation, no monoaminergic changes can be observed in the hypothalamus 4 days following the local injection of 50 micrograms QUIN, a dose which does not cause neuronal necrosis in this brain area. These data are concordant with, and are discussed in the context of, a possible involvement of QUIN in the pathogenesis of Huntington's disease.

Experimental models of aging and quinolinic acid

The normal aging process results in many functional deficits in which the central nervous system (CNS) plays a primary role. However, the study of brain aging involves numerous difficulties, including not only the complex anatomical and functional organization of the brain itself, but also because the length of the experiments themselves and experimental costs are often crucial limitations. This highlights an ever increasing need for the development of alternative model systems capable of mimicking at least to some degree the main alterations observed during the normal aging process. A comparative study of electrophysiological and behavioural features in aged rats and in young rats following chronic administration of a naturally occurring brain metabolite, quinolinic acid (QUIN), recently demonstrated to increase in the cerebral cortex of rats as a function of age, is reported. In rats there occurs an age-dependent increase in the number of animals displaying spontaneous asymptomatic spike-wave discharges, associated with impaired performance in the passive avoidance test. Chronic oral administration of QUIN to young rats also results in cortical spiking activity, without any detectable neuronal cell damage at cortical or hippocampal levels, associated with behavioural deficits similar to those observed in old rats. The utilization of young, QUIN-treated animals may thus perhaps offer an alternative model system for the comprehension of the mechanisms involved in some age-related functional impairments.

Synergistic effect of phosphatidylserine with gamma-aminobutyric acid in antagonizing the isoniazid-induced convulsions in mice

The influence of phosphatidylserine (PS) on the isoniazid-induced convulsions has been studied in mice. Sonicated dispersions of this phospholipid given intravenously do not show anticonvulsant activity but they do so when gamma-aminobutyric acid (GABA) is simultaneously injected. GABA alone is inactive. The synergism between PS and GABA is influenced by the structure of the phospholipid liposomes. In contrast to multilamellar vesicles, oligolamellar vesicles are active. Under these conditions the effect shows head group specificity, in that the neutral phosphatidylcholine (PC) or the acidic phosphatidylinositol (PI) are inactive, either in the presence or in the absence of GABA. Lysophosphatidylserine (lysoPS), the deacylated PS derivative, shows increased efficacy as an isoniazid antagonist in the presence of GABA, and has anticonvulsant activity also in the absence of GABA. Other lysophospholipids are inactive. It is suggested that PS, after its metabolic conversion to lysoPS, enhances the anticonvulsant effect of GABA.

Endogenous inhibitors of Na+-independent [3H]GABA binding to crude synaptic membranes

The characteristics of the Na+-independent high-affinity binding of [3H]GABA to various types of crude synaptic membranes (CSM) prepared from rat brain cortex were studied. In freshly prepared CSM the content of GABA was so high that the high-affinity [3H]GABA binding could not be determined. In contrast when the frozen-thawed CSM were incubated at 37 degrees for 30 min with or without Triton X-100 or phospholipase C and then washed repeatedly, there was a virtual disappearance of GABA from the supernatant extracts and the binding constants of [3H]GABA to CSM could be determined. Two apparent populations of [3H]GABA binding sites, one with a low- and the other with a high-affinity constant, were detected. The ratio of the number of high- to low-affinity binding sites varies with the method used to prepare the membranes. The lowest value of this ratio was observed with membranes incubated at 37 degrees for 30 min. However, when frozen-thawed CSM were treated with 0.05% Triton X-100 repeatedly, the ratio of the number of high- to low-affinity binding sites increased progressively. This increase in ratio is due to a selective increase in the number of the high-affinity sites without significant changes in the number of the low-affinity sites. The extent of the increase in the number of sites that bind [3H]GABA with high affinity after repeated Triton X-100 treatments was paralleled by a decrease of an endogenous protein which inhibits GABA binding. The reapplication of this endogenous material to membranes repeatedly treated with Triton X-100 reduces the number of high-affinity binding sites for [3H]GABA to values similar to those measured in membranes that were not treated with Triton X-100. The inhibitory preparation extracted from CSM incubated with Triton X-100 was shown to be free of GABA or phospholipids. The gel filtration chromatography reveals the presence of two molecular forms of the inhibitor; of these, the high-molecular-weight material fails to bind GABA, whereas the low-molecular-weight material appears to bind GABA. The high-molecular-weight endogenous inhibitor has been termed GABA modulin.

The effect of transient ischemia on fatty acid and lipid metabolism in the gerbil brain

Brain ischemia was produced in gerbils by contemporary occlusion of both carotid arteries. Definite changes of the energy state in brain demonstrated that carotid occlusion was effective. At short time intervals from occlusion the free fatty acid content, their distribution, and their concentration and specific activity in arachidonate were determined in brain. A noticeable increase of the arachidonate pool and that of other free fatty acids was detected at very early times from occlusion. Specific activity by arachidonate increased after 30-60 seconds from ligation. By examining arachidonate distribution and specific activity in neutral and polar lipids of brain, it is concluded that phosphatidylcholine and phosphatidylinositol represent the more important source for the release of arachidonate during ischemia. Enzymic-mediated phenomena produced free arachidonate from lipids by a mechanism yielding diglycerides further transformed into fatty acids and by lipid degradation through phospholipase A activity.

PGF2 alpha, thromboxane B2 and HETE levels in gerbil brain cortex after ligation of common carotid arteries and decapitation

The effects of ligation of both common carotid arteries in the gerbil on the levels of PGF2 alpha, TXB2, HETE and of energy metabolites in brain cortex, have been investigated. Also, in the same experimental conditions the changes of cyclic AMP in brain cortex, cerebellum, striatum and hippocampus have been monitored. ATP, glycogen, glucose and phosphocreatine decrease whereas, lactate and cyclic AMP are enhanced in the ischemic brain, as previously reported. In contrast, levels of arachidonic acid metabolites are not modified. During ischemia following decapitation, instead, PGF2 alpha, and TXB2, show considerable increase.