Adrenalectomy-induced increase of brain protein synthesis is antagonized by corticosterone replacements in free-moving rats

Early and prolonged widespread increase in brain protein synthesis following a single electroconvulsive shock in free-moving rats

The autoradiographic method with l-[35S] methionine ([35S]Met) was used to determine the effect of a single electroconvulsive shock (ECS) on local rates of protein synthesis in the adult rat brain in free-moving conditions. We have estimated the relative contribution of methionine derived from protein breakdown to the intracellular precursor amino acid pool (tRNA pool) for protein synthesis. In steady-state conditions, we showed a large contribution (around 60%) of Met recycling into the precursor pool (lambda=0.37+/-0.11), after a single ECS. In all the 36 brain regions examined, apparent rates of protein synthesis were greatly increased (21-50%) 3 h after a single ECS indicating a generalized effect in rat brain. This ECS-induced activation of the overall rate of brain protein synthesis persisted for at least 24 h after cessation of ECS. This is consistent with the hypothesis that electroconvulsive therapy is associated with long-term molecular changes in neuronal activity.

Dexamethasone effects on cerebral protein synthesis prior to and following hypoxia-ischemia in immature rat

We hypothesized that the neuroprotection against cerebral hypoxic-ischemic damage observed with dexamethasone treatment in immature rats is related to a change in cerebral protein synthesis. Six-day-old Wistar rats were injected with either vehicle (10 ml/kg) or dexamethasone (0.1 mg/kg) 24 h prior to cerebral hypoxia-ischemia. Local cerebral protein synthesis (incorporation of 14C-leucine into proteins) was measured in 7-day-old rats during normoxia, during hypoxia-ischemia, and after hypoxia-ischemia which was produced with right carotid artery ligation and 2-h exposure to 8% O2. In normoxic controls, cerebral protein synthesis was similar in dexamethasone and vehicle-treated animals. During hypoxia-ischemia, local cerebral protein synthesis decreased markedly (p < 0.0001) in ischemic regions ipsilateral to the occlusion, irrespective of treatment. After hypoxia-ischemia, protein synthesis declined even further in vehicle-treated animals. Reductions in protein synthesis were substantially more severe in vehicle- than dexamethasone-treated animals, particularly after hypoxia-ischemia (p < 0.0001). Thus, neuroprotection with dexamethasone is not related to a reduction in basal levels of cerebral protein synthesis, but is associated with an improved protein synthesis during and following hypoxia-ischemia.

Paradoxical metabolic response of the human brain to a single electroconvulsive shock

Regional brain protein synthesis was evaluated with positron emission tomography (PET) and L-(S-[11C]methyl)methionine ([11C]MET) in depressive patients, before and 3 h after an electroconvulsive shock (ECS), when energy supply is restored, and in healthy volunteers. Depressive patients presented apparent lower protein synthesis than normals, in agreement with known reduction of cerebral activity. In contrast, ECS resulted in a significant increase (56%, P < 0.05) in global cortical protein synthesis. This paradoxical hyperactivation of cellular protein metabolism in response to seizures and the fact that synaptic activity is further reduced after electroconvulsive therapy (ECT), may provide new insights for understanding the mechanism of action of ECT.

Effect of metyrapone administration in pregnant rats on monoamine concentration in fetal brain

Studies performed in our laboratory indicate that the adrenal deprivation during gestation can greatly influence the fetal catecholamines development in several cerebral areas. The present study was undertaken to determine whether the administration of metyrapone to pregnant rats affects the content of monoamines in fetal brain at term. To test wether the content of monoamines in fetal brain is regulated, at least in part, by endogenous glucocorticoids, pregnant rats were injected for 5 days prior to delivery with metyrapone, an adrenal 11-beta-steroid hidroxylase inhibitor which crosses the placenta and blocks endogenous glucocorticoid synthesis, or saline. On day 21 of gestation, delivery of all animals was accomplished by cesarean section. The encephalons were extracted and immediately dissected in metencephalon, mesencephalon, diencephalon and telencephalon. Monoamine determination was carried out using HPLC-ED. The results obtained indicate that the metyrapone treatment increases both DA and 5-HT and their metabolites in the brain studied areas.

Regulation of gene expression by corticoid hormones in the brain and spinal cord

Glucocorticoids (GC) and mineralocorticoids (MC) have profound regulatory effects upon the central nervous system (CNS). Hormonal regulation affects several molecules essential to CNS function. First, evidences are presented that mRNA expression of the alpha3 and beta1-subunits of the Na,K-ATPase are increased by GC and physiological doses of MC in a region-dependent manner. Instead, high MC doses reduce the beta1 isoform and enzyme activity in amygdaloid and hypothalamic nuclei, an effect which may be related to MC control of salt appetite. The alpha3-subunit mRNA of the Na,K-ATPase is also stimulated by GC in motoneurons of the injured spinal cord, suggesting a role for the enzyme in GC neuroprotection. Second, we provide evidences for hormonal effects on the expression of mRNA for the neuropeptide arginine vasopressin (AVP). Our data show that GC inhibition of AVP mRNA levels in the paraventricular nucleus is sex-hormone dependent. This sexual dimorphism may explain sex differences in the hypothalamic-pituitary-adrenal axis function between female and male rats. Third, steroid effects on the astrocyte marker glial fibrillary acidic protein (GFAP) points to a complex regulatory mechanism. In an animal model of neurodegeneration (the Wobbler mouse) showing pronounced astrogliosis of the spinal cord, in vivo GC treatment down-regulated GFAP immunoreactivity, whereas the membrane-active steroid antioxidant U-74389F up-regulated this protein. It is likely that variations in GFAP protein expression affect spinal cord neurodegeneration in Wobbler mice. Fourth, an interaction between neurotrophins and GC is shown in the injured rat spinal cord. In this model, intensive GC treatment increases immunoreactive low affinity nerve growth factor (NGF) receptor in motoneuron processes. Because GC also increases immunoreactive NGF, this mechanism would support trophism and regeneration in damaged tissues. In conclusion, evidences show that some molecules regulated by adrenal steroids in neurons and glial cells are not only involved in physiological control, but additionally, may play important roles in neuropathology.

Quantitative measurement of cerebral protein synthesis in vivo: theory and methodological considerations

The true rate of cerebral protein synthesis can be calculated from the ratio of labeled proteins to integrated arterial plasma amino acid specific activity (SA) only when the fraction of amino acid precursor pool dilution is known. In the following, current experimental designs on the measurement of cerebral protein synthesis are discussed and compared to our own approach in which the determination of regional precursor pool dilution by recycled unlabeled leucine is combined with the quantitation of regional cerebral protein synthesis rates. For this purpose, a constant arterial plasma leucine SA level is maintained for 45 min by programmed intravenous infusion which is sufficient for complete equilibrium between tissue leucine pool SAs and plasma free leucine SA. In addition to the regional assessment of the precursor dilution factor, protein radioactivity can be determined in the same tissue sample or in parallel brain sections of the same animal by quantitative autoradiography. It is then possible to calculate the actual rate of protein synthesis using the correct fraction of precursor pool dilution. This renders our approach particularly suitable for the quantitative measurement of regional CPS under pathological conditions.

Prevention of ACTH- and adrenalectomy-induced muricidal behavior: by benzodiazepinic ligands

We investigated the effect of treatment with central (neuronal and glial) benzodiazepine binding site-active molecules on ACTH- or adrenalectomy (ADX)-induced muricidal behavior in male Wistar rats. Pretreatment (IP) with either flumazenil or clonazepam prevented the subsequent induction of ADX-induced behavior, but only flumazenil protected against ACTH-induced behavior; posttreatment in both cases induced no significant modifications. Using 4'-chloro-diazepam or PK 11195, both pre- and posttreatment afforded protection, the effect lasting longer (> 1 week) than that induced by flumazenil or clonazepam (2 days). Pretreatment with the GABAA agonist, muscimol, also resulted in complete protection, whereas posttreatment had only a slight effect.

Widespread increase in brain protein synthesis following acute immobilization stress in adult rat brain

The autoradiographic method with [L-35S]methionine was used to determine the effects of a 2 h acute immobilization stress followed by a 4 h recovery on local rates of protein synthesis in the adult rat brain. Methionine incorporation into proteins was significantly increased (from 17 to 86%) in 37 out of the 39 analyzed brain structures. These results show that the stress-induced activation of the overall rate of brain protein synthesis may persist for at least 4 h after cessation of the stimulus even though the stress-related physiological variables have returned to basal levels. They suggest that increased protein synthesis may play a key role in the molecular events which lead to the neuronal plastic changes following an acute stress.

Restoration of brain protein synthesis in mature and aged rats by a DA agonist, piribedil

Brain ageing affects numerous cerebral metabolic pathways such as cerebral glucose consumption or protein synthesis rate. The pharmacological effect of a mixed D1-D2 dopaminergic agonist, piribedil, on this last metabolism is reported. Cerebral Protein Synthesis Rate (CPSR) was measured by the [35S]L-methionine autoradiographic procedure in 38 main brain regions of 11 and 26-month-old Wistar rats after a 2-month treatment per os at 9 and 30 mg/kg/day with piribedil. Mean decrease of CPSR was -21% during the 15-month ageing we followed, with important local variations. Mean CPSR increased with the two treatments, +25% in mature and +35% in aged rats. Treatments restored CPSR of aged rats to the exact mature subjects levels in quite all the brain regions. No dose-effect or asymetrical modification was statistically revealed for the two treatments. Metabolic increases involved particularly central brain gray structures, especially some DA-targeted brain nuclei concerned with behaviour and learning. This effect argued for a general metabotrophic effect of D1-D2 dopamine stimulation of the brain. The original pattern of local ageing of brain protein synthesis in rat was also incidentally reported. This was the first direct report of a wide and effective metabolic activation of CPSR in the brain during ageing by a curative dopaminergic agonist treatment.

Cerebral protein synthesis alterations in response to acute and chronic immobilization stress in the rat

The quantitative autoradiographic method with L-(35S)methionine was used to determine the effects of 1-acute (4h) and 2-chronic (14 days) immobilization stress followed by one week of recovery. Acute stress induced a significant decrease in methionine incorporation into proteins in 17 of the 35 brain structures examined (mean effect: -22%), and a significant increase in the prepositus hypoglossal nucleus (+23%). Chronic stress induced a significant decrease in methionine incorporation into proteins in 8 of the 35 structures analyzed. Only 4 structures were similarly affected in both these conditions. Our results indicate that stress-induced specific molecular changes in brain are also associated with changes in more general molecular components of cellular metabolism.

Triiodothyronine does not affect the average incorporation of L-[35S]methionine in rat brain structures

The autoradiographic method with L-[35S]methionine was used to examine the effect of acute administration of L-triiodothyronine on local rates of brain protein synthesis in free-moving adult rats. Triiodothyronine was given intraperitoneally at doses of 12.5 or 25 micrograms kg-1. It did not modify the rate of plasma methionine incorporation in the 40 brain regions examined, despite a 4- to 8-fold increase of plasma free triiodothyronine levels. Biochemical analysis confirmed that triiodothyronine (25 micrograms kg-1) had no apparent effect on the overall rate of protein synthesis in the brain as a whole. These results suggest that changes in the circulating levels of thyroid hormones do not exert a general and direct metabolic effect in brain of intact adult rats.