Dietary lithium during development: Changes in amino acid levels,ionic content,and [3H]spiperone binding in the brain of rats

We found that chronic lithium diet affects the sensitivity of neuroleptic receptors and the content of amino acids in the brain, and that the changes in adult animals differ from those in young rats. Pregnant rats were kept on lithium diet (pellets with 0.21% Li2CO3 and 0.21% NaCl) during the gestation period and the offspring were kept on lithium for six weeks after delivery. Control rats were kept on normal diet under identical conditions. In corpus striatum and cerebral cortex of lithium-treated young rats a reduction in apparent dissociation constant and no change in (3H)spiperone total binding sites were found, suggesting a sensitization of the neuroleptic receptor; this result was unlike that obtained with adult lithium-treated rats, where the total number of binding sites was decreased. The lithium content of brain was very high (2.32 meq/kg of wet weight), whereas in the serum only 0.75 meq/l was recorded. K+ and Na+ levels increased by 20% and 9% respectively in the brain and remained at normal levels in the serum. Analysis of free amino acids in the cerebral cortex, midbrain, and cerebellum showed increases in GABA and glycine levels in all three regions, a significant increase in taurine in midbrain, and an increase in lysine in cerebral cortex and cerebellum. The results indicate that the effect of chronic dietary lithium given during pregnancy on the neuroleptic receptor in young rats is different from that in adult animals. It produces an increase in the number of the neuroleptic receptor sites instead of the decline in the number of binding sites found in adult rats. It remains to be established whether this effect is related more to the age of the animal tested or to the stage of development of the CNS at which the lithium was administered.     

Acetylcholine Content in Rat Brain Is Elevated by Status Epilepticus Induced by Lithium and Pilocarpine

The effects of status epilepticus on the concentration, synthesis, release, and subcellular localization of acetylcholine, the concentration of choline, and the activity of acetylcholinesterase in rat brain regions were studied. Generalized convulsive status epilepticus was induced by the administration of pilocarpine to lithium-treated rats. The concentration of acetylcholine in the cortex, hippocampus, and striatum decreased prior to the onset of spike activity or status epilepticus. Once status epilepticus began, the concentration of acetylcholine increased over time in the cortex and hippocampus, reaching peak levels that were 461% and 304% of control levels, respectively, after 2 h of seizures. Such high in vivo levels of acetylcholine had not been reported previously following any treatment. During status epilepticus, the concentration of acetylcholine in the striatum returned to control levels after the initial depression, but did not accumulate to high levels as it did in the other two regions. The in vivo cortical efflux of acetylcholine was also increased during the seizures. Choline levels were increased by status epilepticus in all three brain regions. Inhibition of seizures by pretreatment with atropine blocked the increases of acetylcholine and choline. Synaptosomes prepared from the cortex and from the hippocampus of rats with status epilepticus had elevated concentrations of acetylcholine: in the hippocampus the acetylcholine was principally in the cytoplasmic fraction, whereas in the cortex the acetylcholine was elevated in both the cytoplasmic and the vesicular fractions. The extra acetylcholine was in a releasable compartment, since increased K+ in the media or ouabain increased the release of acetylcholine from cortical slices to a greater extent in tissue from seized rats than from controls.(ABSTRACT TRUNCATED AT 250 WORDS)     

Behavioral and receptor binding studies of phencyclidine (PCP) and lithium interaction in the rat

Three groups of female Sprague-Dawley rats (n = 4) were conditioned to drink water during a daily 2 hr session. The water was then changed to a solution of 1.0 mg/ml lithium chloride producing average doses between 62.9 and 72.1 mg/kg/day for Groups I and II. These rats were challenged with 4 mg/kg PCP i.p. before and during lithium treatment. Group I was tested for spontaneous locomotor activity in the open field apparatus. Lithium alone did not affect activity. After 1, 2, and 3 weeks of chronic lithium, PCP-induced activity increased 2.1, 1.7, and 2.8 fold, respectively, relative to PCP-induced activity during limited access to water only. Whole brain homogenates from Group II, after one week of chronic lithium, were used for receptor binding experiments using [3H] PCP; Group III served as water controls. The Kd (nM +/- S.E.M.) was not different in untreated (146.39 +/- 18.95) and lithium-treated (181.22 +/- 14.35) rats. The Bmax (pmole/mg protein +/- S.E.M.), however, was increased 48% (p less than 0.01) from 1.50 +/- 0.08 to 2.22 +/- 0.10 after lithium. These preliminary results suggest that chronic administration of lithium modifies the behavioral effects of PCP possibly via alterations at the receptor level.     

Seizures increase acetylcholine and choline concentrations in rat brain regions

Seizures induced by three convulsant treatment produced differential effects on the concentration of acetylcholine in rat brain. Status epilepticus induced by (i) coadministration of lithium and pilocarpine caused massive increases in the concentration of acetylcholine in the cerebral cortex and hippocampus, (ii) a high dose of pilocarpine did not cause an increase of acetylcholine, and (iii) kainate increased acetylcholine, but the magnitude was lower than with the lithium/pilocarpine model. The finding that the acetylcholine concentration increases in two models of status epilepticus in the cortex and hippocampus is in direct contrast with manyin vitro reports in which excessive stimulation causes depletion of acetylcholine. The concentration of choline increased during seizures with all three models. This is likely to be due to calcium- and agonist-induced activation of phospholipase C and/or D activity causing cleavage of choline-containing lipids. The excessive acetylcholine present during status epilepticus induced by lithium and pilocarpine was responsive to pharmacological manipulation. Atropine tended to decrease acetylcholine, similar to its effects in controls. The N-methyl-D-aspartate (NMDA) receptor antagonist, MK-801, reduced the excessive concentration of acetylcholine, especially in the cortex. Inhibition of choline uptake by hemicholinium-3 (HC-3) administered icv reduced the acetylcholine concentration in controls and when given to rats during status epilepticus. These results demonstrate that the rat brain concentrations of acetylcholine and choline can increase during status epilepticus. The accumulated acetylcholine was not in a static, inactive compartment, but was actively turning-over and was responsive to drug treatments. Excessive concentrations of acetylcholine and/or choline may play a role in seizure maintenance and in the neuronal damage and lethality associated with status epilepticus.     

Effectiveness of Zinc in Modulating Lithium Induced Biochemical and Behavioral Changes in Rat Brain

1. The purpose of the present study was to determine the effect of zinc on the status of various neurotransmitters as well as behavioral patterns of lithium-treated rats. The study was designed with a view to find out whether zinc affords protection to brain against lithium toxicity. 2. Animals were segregated into four different groups. Animals in group I were fed with standard laboratory feed and water ad libitum and served as normal controls. Animals in group II and IV were given lithium in the form of lithium carbonate in their diet at a dose level of 1.1 g/Kg diet. Animals in group III and IV were given zinc treatment in the form of zinc sulfate at a dose level of 227 mg/L mixed in drinking water of animals. 3. The effects of all the treatments were studied for a duration of 1, 2, and 4 months with regard to the parameters, which included estimation of serotonin and dopamine concentrations as well as the activity of acetylcholinesterase in cerebral cortex of rat brain. Further, passive avoidance, active avoidance, and behavior despair tests were conducted to assess the short-term memory, cognitive behavior, and psychomotor dysfunction of the animals, respectively. 4. Initially, a decrease in the acetylcholinesterase activity was reported in cerebral cortex followed by an increase in the enzyme activity after 2 and 4 months of lithium treatment. Serotonin concentration significantly decreased after 2 and 4 months of lithium treatment, whereas dopamine concentration increased significantly after 4 months of lithium treatment. Zinc administration to the lithium-treated group significantly improved the acetylcholinesterase activity as well as the concentration of dopamine and serotonin. Further, lithium-treated rats showed an increase in depression time as compared to normal controls both after 1 and 4 months of treatment. Short-term memory significantly improved in lithium-treated rats in all treatment groups. However, no change in the cognitive behavior of the animals was reported after lithium treatment. Zinc co-administration with lithium significantly improved the short-term memory and cognitive functions of the animals. From the above results it can be concluded that zinc proved beneficial in altering the status of neurotransmitters as well as the behavior patters of the animals treated with both short and long-term lithium therapy.     

Effect of chronic lithium administration on endothelium-dependent relaxation of rat mesenteric bed: role of nitric oxide

The mechanism of action of lithium, an effective treatment for bipolar disease, is still unknown. In this study, the mesenteric vascular beds of control rats and rats that were chronically treated with lithium were prepared by the McGregor method, and the mesenteric vascular bed vasorelaxation responses were examined. NADPH-diaphorase histochemistry was used to determine the activity of NOS (nitric oxide synthase) in mesenteric vascular beds. We demonstrated that ACh-induced vasorelaxation increased in the mesenteric vascular bed of rats treated with lithium. Acute No-nitro-L-arginine methyl ester (L-NAME) administration in the medium blocked ACh-induced vasorelaxation in the control group more effectively than in lithium-treated rats, while the vasorelaxant response to sodium nitroprusside, a NO donor, was not different between lithium-treated and control groups. Acute aminoguanidine administration blocked ACh-induced vasorelaxation of lithium-treated rats, but had no effect in the control rats. Furthermore, NOS activity, determined by NADPH-diaphorase staining, was significantly greater in the mesenteric vascular beds from chronic lithium-treated rats than in those from control rats. These data suggest that the enhanced ACh-induced endothelium-derived vasorelaxation in rat mesenteric bed from chronic lithium-treated rats might be associated with increased NOS activity, likely via iNOS. Simultaneous acute L-NAME and indomethacin administration suggests the possible upregulation of EDHF (endothelium-derived hyperpolarizing factor) in lithium-treated rats.     

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.Special Issue dedicated to Claude Baxter.     

Therapeutic lithium alters polar head-group region of lipid bilayer and prevents lipid peroxidation in forebrain cortex of sleep-deprived rats

Lithium is regarded as a unique therapeutic agent for the management of bipolar disorder (BD). In efforts to explain the favourable effects of lithium in BD, a wide range of mechanisms was suggested. Among those, the effect of clinically relevant concentrations of lithium on the plasma membrane was extensively studied. However, the biophysical properties of brain membranes isolated from experimental animals exposed to acute, short-term and chronic lithium have not been performed to-date. In this study, we compared the biophysical parameters and level of lipid peroxidation in membranes isolated from forebrain cortex (FBC) of therapeutic lithium-treated and/or sleep-deprived rats. Lithium interaction with FBC membranes was characterized by appropriate fluorescent probes. DPH (1,6-diphenyl-1,3,5-hexatriene) and TMA-DPH (1-(4-trimethylammoniumphenyl)-6-phenyl-1,3,5-hexatriene p-toluenesulphonate) were used for characterization of the hydrophobic lipid core and Laurdan (6-dodecanoyl-2-dimethylaminonaphthalene) for the membrane-water interface. Lipid peroxidation was determined by immunoblot analysis of 4-HNE-(4-hydroxynonenal)-protein adducts. The organization of polar head-group region of FBC membranes, measured by Laurdan generalized polarization, was substantially altered by sleep deprivation and augmented by lithium treatment. Hydrophobic membrane interior characterized by steady-state anisotropy of DPH and TMA-DPH fluorescence was unchanged. Chronic lithium had a protective effect against peroxidative damage of membrane lipids in FBC. In summary, lithium administration at a therapeutic level and/or sleep deprivation as an animal model of mania resulted in changes in rat FBC membrane properties.     

Change of synaptic membrane lipid composition and fluidity by chronic administration of lithium

The effect of chronic administration of lithium salts on the lipid composition and physical properties of the synaptosomal plasma membrane was examined in rat brain. The effect of lithium treatment has been studied on the fluorescence polarization of synaptosomal plasma membrane and artificial lipid vesicles and on the lipid composition of the membranes. Fluorescence polarization of lipophilic probes was used to study membrane lipid structure. Steady-state polarization of 1,6-diphenyl-1,3,5-hexatriene (DPH), a probe of the hydrophobic core, was significantly lower in plasma membranes from lithium-treated animals. Altered DPH polarization was due to a decrease in the order parameter of the probe. The lithium-treatment also changed the fluorescence of 1-anilino-8-naphthalene sulfonate (ANS), a probe that binds to the polar head group of the phospholipids and to proteins on the membrane surface. Synaptic plasma membranes from treated rats presented no significant changes on the cholesterol-to-phospholipid ratio, although the phospholipid class distribution was altered and the membrane phospholipid unsaturation increased. In summary, the neural plasma membranes became disorder after chronic lithium administration at therapeutic levels. This structural change may be due to changes in plasma membrane phospholipid distribution and to the degree of unsaturation of phospholipid fatty acids.     

Chronic Stress and Lithium Treatments Alter Hippocampal Glutamate Uptake and Release in the Rat and Potentiate Necrotic Cellular Death After Oxygen and Glucose Deprivation

This study was undertaken to evaluate the effects of chronic variate stress and lithium treatment on glutamatergic activity and neuronal vulnerability of rat hippocampus. Male Wistar rats were simultaneously treated with lithium and submitted to a chronic variate stress protocol during 40?days, and afterwards the hippocampal glutamatergic uptake and release, measured in slices and synaptosomes, were evaluated. We observed an increased synaptosomal [(3)H]glutamate uptake and an increase in [(3)H]glutamate stimulated release in hippocampus of lithium-treated rats. Chronic stress increased basal [(3)H]glutamate release by synaptosomes, and decreased [(3)H]glutamate uptake in hippocampal slices. When evaluating cellular vulnerability, both stress and lithium increased cellular death after oxygen and glucose deprivation (OGD). We suggest that the manipulation of glutamatergic activity induced by stress may be in part responsible for the neuroendangerment observed after stress exposure, and that, in spite of the described neuroprotective effects of lithium, it increased the neuronal vulnerability after OGD.     

Lithium: Short-term and chronic effects on plasma testosterone and luteinizing hormone concentrations in mice

The effects of short-term and chronic lithium administration on the concentrations of plasma testosterone (T) and luteinizing hormone (LH) were evaluated in C57BL/6 mice, maintained on a fixed photo-period of LD 14:10 (white lights on at 06:00 h, CST). Lithium chloride was injected intraperitoneally twice daily (at 09:00 and 16:00 h) in groups of adult male mice at a dosage of 2.5 meq/kg for 7 days, and 1.25 meq/kg for 21 days. Circulating levels of T and LH were measured by standard radioimmunoassay (RIA) methods. Plasma T levels showed a significant increase in mice treated with lithium for 7 days as compared to those in saline-injected control animals. However, there was no significant difference in the concentrations of plasma T between chronic (21 days) lithium-treated mice and the matched control. Plasma LH levels remained unchanged following both short-term and chronic lithium treatment.     

Effect of lithium and sodium ions on opiate-and dopamine-receptor binding

The effects of lithium and sodium were studied in the corpus striatum and cerebral cortex of rats. Lithium was inhibitory at low concentrations but at 20 mM it increased the binding of [G-³H]naloxone (specific activity 15.6 Ci/mmol). Sodium stimulated the high-affinity binding of this compound. Membranes obtained from the rats treated with lithium showed lower specific binding of both [³H]naloxone and [³H]DHM. Binding of [³H]d-alanine Leu-enkephalin was not changed in the brains of lithium-treated rats, but that of [³H]-spiroperidol was lowered. Cerebral cortex and striatum of lithium-treated rats had a decreased apparent dissociation constant and a lower receptor concentration of naloxone binding sites.     

Seasonal Variation in Urinary Excretion of Calcium, Magnesium and Phosphate in Manic-Melancholic Patients

The 24-hr urinary excretion of calcium, magnesium and phosphate was measured in 76 normal control persons, 95 manic-melancholic patients not on lithium treatment and 74 lithium-treated manic-melancholic patients. The mean value of the urinary excretion for each of the four seasons during a 5-year period was calculated. The normal control persons had a higher excretion of calcium during the summer months than during the rest of the year; this seasonal variation was not present in the two groups of manic-melancholic patients.

Previously reported changes in electrolyte metabolism during lithium treatment were confirmed, but some of the results varied with the season.     

Renal function after long-term treatment with lithium.

Daily urine volumes, plasma creatinine concentrations, and creatinine clearance were measured in 106 patients with unipolar and bipolar affective disorders attending a "lithium" clinic. Urine volumes exceeded 3.51 in only six patients, plasma creatinine concentrations exceeded 150 mumol/1 (1.7 mg/100 ml) in only five, and creatinine clearance was below 50 ml/min in 16. Renal function was assessed by measuring creatinine clearance and renal tubular function, including response to 20 hours of water deprivation, in a representative sample of 30 patients from the lithium clinic and 30 psychiatric patients matched for age and sex who were taking other psychotropic drugs. Creatinine clearance and tubular function, including urine osmolality after water deprivation, were not significantly different between the two groups. Urinary excretion of arginine vasopressin (AVP), however, was much greater in the lithium-treated patients, who therefore had a diminished tubular responsiveness to AVP. The findings do not support suggestions that long-term lithium treatment results in seriously impaired renal function, renal damage, and polyuria. Compared with other series, however, the patients were being maintained with low serum lithium concentrations, which apparently area as effective prophylactically as higher concentrations.     

Neuroprotective effects of zinc on antioxidant defense system in lithium treated rat brain

With a view to find out whether zinc affords protection against lithium toxicity the activities of antioxidant enzymes and lipid peroxidation profile were determined in the cerebrum and cerebellum of lithium treated female Sprague Dawley rats. Lipid peroxidation was significantly increased in both the cerebrum and the cerebellum of animals administered with lithium for a total duration of 4 months as compared to the normal control group. On the contrary, the activities of catalase and glutathione-s-transferase (GST) were significantly reduced after 4 months of lithium treatment. The activity of superoxide dismutase (SOD) was significantly increased in the cerebrum after 4 months lithium administration, whereas in the cerebellum the enzyme activity was unaffected. No significant change in the levels of reduced glutathione (GSH) was found in either cerebrum or cerebellum after 2 months of lithium treatment. However, 4 months lithium treatment did produce significant changes in GSH levels in the cerebrum and in the cerebellum. Zinc supplementation for 4 months in lithium-treated rats significantly increased the activities of catalase and GST in the cerebellum, showing that the treatment with zinc reversed the lithium induced depression in these enzyme activities. Though, zinc treatment tended to normalize the SOD activity in the cerebrum yet it was still significantly higher in comparison to normal levels. From the present study, it can be concluded that the antiperoxidative property of zinc is effective in reversing the oxidative stress induced by lithium toxicity in the rat brain.     

Fewer metabolites of dietary choline reach the blood of rats after treatment with lithium

Choline is an important precursor for the biosynthesis of acetylcholine, phosphatidylcholine and sphingomyelin. It is also a major source of labile methyl groups. Lithium is an important component of the treatment of bipolar affective illness, and it inhibits choline transport across membranes. We studied the effect of lithium treatment upon the appearance in blood, liver and intestine of metabolites formed from dietary choline. Rats were treated for 9 days with 2 mEq/kg lithium carbonate or water. Animals were fasted overnight, and on the 10th day were fed with a solution containing radiolabeled choline chloride. The lithium-treated groups also received 2.0 mEq/kg lithium as part of this solution. After an oral dose of 1 ml of a 1 mM choline solution, the lithium-treated animals had significantly lower levels of choline-derived radiolabel in blood than did controls at 30, 60, 120, and 180 minutes (47% (+/- 5%; SEM), 51% (+/- 7%), 59% (+/- 4%) and 74% (+/- 9%), respectively). We observed similar decreases of the accumulation in blood, at 180 minutes after the dose, of choline-derived radiolabel when choline was administered at lower or higher concentrations. After an oral treatment containing 0.1, 1 or 10 mM choline, lithium treated animals accumulated 69% (+/- 6%; SEM), 66% (+/- 11%) and 72% (+/- 7%) as much radiolabel in serum as did controls. Most of the radiolabel found in blood at 180 minutes was in metabolites of choline which are formed within liver (betaine and phosphatidylcholine). The diminished accumulation of radiolabel in serum after lithium treatment was not due to increased accumulation of label by erythrocytes, liver or gut wall. We suggest that lithium influences the release by liver of betaine and phosphatidylcholine.     

Effect of chronic hypernatremic dehydration and rapid rehydration on brain carbohydrate, energy, and amino acid metabolism in weanling mice

Abstract: This is a study of the effects of chronic hypernatremic dehydration and rehydration on carbohydrate, energy, and amino acid metabolism in the brains of weanling mice. Chronic hypernatremic dehydration induced by 4 days of water deprivation and salt loading was associated with severe weight loss (no other observed clinical effects), increased brain Na⁺ levels, and a decreased brain water content. Changes in the concentrations of brain glucose, glycolytic and citric acid cycle metabolic intermediates, and phosphocreatine were compatible with reduced cerebral metabolic rate. In adaptation to chronic hypernatremia, there was a significant increase in the content of the measured brain amino acids. Rapid rehydration over a 4-h period with 2.5% dextrose in water returned plasma Na⁺ levels and brain Na⁺ and water contents to normal. After rehydration, metabolites were altered in a manner consistent with increased fluxes through the glycolytic pathway and citric acid cycle; the brain glycogen content almost tripled. Brain taurine and glutamine levels were not lowered by rehydration, and the total content of the measured amino acids in brain was still significantly higher than in controls. We speculate that these metabolic perturbations may relate to the development of cerebral edema and seizures or coma following rapid rehydration of humans with chronic hypernatremic dehydration.     

Transport of tryptophan and tyrosine in rat brain slices in the presence of lithium

Slices from rat cerebral cortex, brain stem, and cerebellum were incubated in media in which 1, 10, or 100 mmol/liter NaCl had been replaced by equimolar amounts of LiCl. The initial influx fo tryptophan and tyrosine into the slices diminished in the lithium-containing media. The lithium-induced inhibition was not competitive. The equilibrium accumulation of the amino acids was also less in the presence of LiCl. The incorporation of tryptophan and tyrosine into the proteins of the slices was inhibited by lithium. There were no clear differences between the brain areas studied. It has been suggested earlier that a lithium treatment enhances thesin vivo cerebral uptake of these aromatic amino acids. The present results show that such a possible increase in uptake is not a direct effect of lithium ions on cell membranes.     

Uptake of Exogenous Glutamate and Aspartate by Circumventricular Organs but Not Other Regions of Brain

Abstract: Glutamate (Glu) and aspartate (Asp) concentrations in blood and selected regions of brain were measured at sequential intervals over a 3-h period following subcutaneous administration of Glu, Asp, or Glu plus Asp (2 mg/g body wt) to 4-day-old mouse or rat pups. Marked serum elevations of the administered amino acids (peak values exceeding 200 times control levels) were detected within 1 h. In circumventricular organ (CVO) regions of brain, which are thought to have no blood-brain barriers, a sharp and steady increase in tissue concentrations of the administered amino acids (peak values 4–10 times higher than control levels) occurred during a 15–120 min interval, whereas no appreciable increases were detected in other brain regions. When 2 mg/g Glu plus 2 mg/g Asp were administered, CVO tissue concentrations of each amino acid rose to approximately the same level obtained when the individual amino acids were given. It is concluded that blood-brain barriers preventing net entry of Glu or Asp into brain proper are relatively well established by the 4th postnatal day in rodents, but that CVO brain regions lack such barriers; selective access of blood-borne Glu or Asp to CVO neurons explains why these neurons are selectively destroyed by systemic administration of these neurotoxic amino acids.     

Chronic Lithium Treatment Decreases Brain Phospholipase A2 Activity

Chronic lithium administration decreases the turnover of arachidonic acid (AA) in several brain phospholipids. This suggests that lithium may attenuate phospholipase A₂ (PLA₂) activity in brain. We now report effects of chronic lithium treatment on PLA₂ activity in postnuclear supernatant from rat brain: Enzyme activity was determined by two assay methods, radiometric and fluorometric, and measured the release of the fatty acid on the second acyl position (sn2) from choline and ethanolamine phospholipids. PLA₂ activity in brain postnuclear supernatant from rats chronically treated with lithium in the diet was significantly decreased (20–50%) when compared with controls. In vehicle or lithium-treated rats, PLA₂ activity was not significantly augmented or attenuated by the addition of calcium chelators, divalent cations or LiCl supplementation (1.0 mM) to postnuclear supernatant. These results suggest that a major therapeutic effect of lithium is to attenuate brain PLA₂ activity involved in signal transduction.