Deletion of the lifespan determinant p66(Shc) improves performance in a spatial memory task, decreases levels of oxidative stress markers in the hippocampus and increases levels of the neurotrophin BDNF in adult mice.

Deletion of the p66(Shc) gene in mice results in reduced levels of oxidative stress and longer lifespan. Reactive oxygen species (ROS) can lead to tissue damage, particularly in the brain. In this study we extended previous findings on the behavioral phenotype of the p66(Shc-/-) mice. Cognitive performance of adult and old p66(Shc-/-) and p66(Shc+/+) mice was tested in a Morris water maze (MWM) task while general reactivity and pain sensitivity were assayed at adulthood, respectively, in an open field and by means of a tail flick test. Levels of brain-derived neurotrophic factor (BDNF), a neurotrophin involved in several aspects of synaptic plasticity, emotionality and pain sensitivity, were assessed in selected brain areas. P66(Shc-/-) adult subjects, compared to WT, overall showed a better performance in the MWM, lower emotionality and a higher pain threshold, in addition to increased basal levels of BDNF in the hippocampus, as well as decreased levels of oxidative stress markers in the same brain area. Although all aged subjects failed to learn the cognitive task, aged p66(Shc-/-) mice were characterized by a better physical performance. These results suggest an interaction between the p66(Shc) gene and specific signaling pathways involved in behavioral adaptation to stress and aging.

Evolution of the spindlin gene in birds: independent cessation of the recombination of sex chromosomes at the spindlin locus in neognathous birds and tinamous, a palaeognathous avian family.

Tinamous (Aves, Palaeognathae, Tinamiformes) are primitive birds, generally considered to be the sister group to the ratites. Tinamous possess a W sex-chromosome, intermediate in heterochromatization between the largely euchromatic W chromosome of the ratites and the highly condensed W chromosome of the neognathous birds. Of the four genes which are known to have diverged copies on the neognathous avian W and Z chromosome (ATP5A1, CHD1, PKC and SPIN) only the spindlin gene has W- and Z-chromosomal forms in the tinamiformes. This paper describes experiments which show that the sequences of these forms are more similar to each other and to the homologous undifferentiated spindlin gene sequences in the ratite genome than to the W or Z forms of the spindlin gene in other, neognathous species. This suggests that cessation of recombination at the spindlin locus of the ancestral W and Z chromosomes of the paleognathous tinamiformes and the neognathous avian species were independent events.

Increased sensitivity to glucocorticoids in peripheral blood mononuclear cells of chronic fatigue syndrome patients, without evidence for altered density or affinity of glucocorticoid receptors.

BACKGROUND: In this study we tested the hypothesis that the increased sensitivity to glucocorticoids in chronic fatigue syndrome (CFS)-patients can be attributed to an altered functioning of their glucocorticoid receptors (GR). METHODS: For this purpose, affinity and distribution of the GR were studied in purified, peripheral blood mononuclear cells (PBMC) of 10 CFS patients and 14 controls along with the responsiveness of these cells to glucocorticoids in vitro. RESULTS: Affinity (Kd) and number of GR was not different in PBMC of CFS patients when compared with the controls (Kd, 12.9 +/- 8.9 nmol vs 18.8 +/- 16.2 nmol and GR number, 4,839 +/- 2,824/ cell vs 4,906 +/- 1,646/cell). Moreover, RT-PCR revealed no differences in GR messenger RNA expression. Nevertheless, PBMC from CFS patients showed an increased sensitivity to glucocorticoids in vitro. In CFS patients 0.01 micromol dexamethasone suppressed PBMC proliferation by 37%, whereas the controls were only suppressed by 17% (P < 0.01). Addition of phorbol 12-myristate 13-acetate to the cultures rendered the cells resistant to dexamethasone with regard to proliferation and IL-10 and IFN-gamma production, but not to IL-2 and TNF-alpha production in both patients and controls. No difference between patients and controls was observed in this respect CONCLUSIONS: In conclusion, PBMC of CFS patients display an increased sensitivity to glucocorticoids, which cannot be explained by number or affinity of the GR but should rather be attributed to molecular processes beyond the actual binding of the ligand to the GR.

The active phase-related increase in corticosterone and aggression are linked.

Recently we demonstrated that corticosterone exerts an acute facilitatory effect on aggression in male rats. Corticosterone production reaches a maximum at the onset of the dark period, while male rats are more aggressive in the dark. Here we present evidence demonstrating that the corticosterone increase at the beginning of the dark period is causally linked to the increase in aggressiveness. We measured plasma corticosterone and quantified aggressive behaviour of male territorial rats at various time points of the day-night transition. Low aggression levels were observed in the full light period when plasma concentrations of corticosterone were low. An increase in plasma corticosterone occurred just prior to the dark phase, when aggressive responding was the highest. Aggressive behaviour remained high in the early dark period when corticosterone was still high. We found that blocking the high affinity mineralocorticoid receptor (MR) with spironolactone (5 or 10 mg/kg) during the early dark period dramatically and specifically reduced territorial aggression.

Steroid effects on brain functions: an example of the action of glucocorticoids on central dopaminergic and neurotensinergic systems.

It is now clearly established that steroid hormones released from peripheral endocrine glands may, through specific receptors in the brain, directly regulate brain function. These effects may be rapid or involve long-term modifications at the genomic level. Concerning the glucocorticoids, their receptors are found in most neuronal cells, an observation which can be related to their widespread effects on neuronal metabolism. Furthermore, glucocorticoids are often related to stress. We have previously demonstrated that neonatal handling of the rat prevented excessive endocrine response to stress. In adults, this action appeared to protect the animal from potential damaging effects of glucocorticoids and from related impairment of cognitive functions. The effects of glucocorticoids are thought to involve an interaction of several central neurotransmitter systems. One such neurotransmitter is neurotensin, a neuropeptide which was reported to be closely related to central dopaminergic system regulation. This paper presents a rapid overview of the central effects of glucocorticoids and possible evidence for the interrelationship between these steroids, dopamine and neurotensin systems in the regulation of the hypothalamo-pituitary-adrenal axis. It provides a new way to approach stress responses and to develop new substances that may become potential drugs in the treatment of some psychiatric disorders.

Time- and region-dependent effect of adrenalectomy on neuropeptide gene expression in rat hippocampus and striatum.

Seven days after removal of the adrenals in rats, the messenger RNA levels of preproenkephalin (ENK), preprodynorphin (DYN), cholecystokinin (CCK), and neuropeptide Y (NPY) were measured in hippocampus, striatum, and hypothalamus. Adrenalectomy (ADX) in the morning, when endogenous corticosterone levels were low, resulted 7 days later in a decrease of ENK mRNA and DYN mRNA levels in the hippocampus (41.3 +/- 4.3 and 41.9 +/- 5.7%, respectively) and in the striatum (32.1 +/- 6.6 and 31.2 +/- 12.9%, respectively), but no change was observed in the ENK mRNA content of the hypothalamus. When ADX was performed in the evening the opioid mRNA levels were not changed in these brain areas 7 days after ADX. Pretreatment with a single dose of corticosterone before surgery in the morning produced high corticosterone levels similar to those in the evening and prevented the decrease of ENK mRNA in the hippocampus. The decrease in hippocampal DYN mRNA and in striatal ENK mRNA and DYN mRNA persisted. CCK mRNA and NPY mRNA were not changed in any of the experimental groups in any of the three examined brain areas. This study demonstrates that ADX decreases opioid gene expression in the rat hippocampus and striatum. The effect of ADX on hippocampal ENK mRNA levels that persists for at least 7 days postsurgery is independent of the circulating corticosterone level at the time of surgery.

Metabolic rate in different rat brain areas during seizures induced by a specific delta opiate receptor agonist.

The glucose utilization during specific delta opiate agonist-induced epileptiform phenomena, determined by the [14C]2-deoxyglucose technique (2-DG), was examined in various rat brain areas at different time intervals. The peak in EEG spiking response and the most intensive 2-DG uptake occurred 5 min after intraventricular (i.v.t.) administration of the delta opiate receptor agonist. The most pronounced 2-DG uptake at this time interval can be observed in the subiculum, including the CA1 hippocampal area, frontal cortex and central amygdala. A general decrease of glucose consumption, compared to control values, is observed after 10 min, in all regions, with exception of the subiculum. Since functional activity and 2-DG uptake are correlated, we suggest that the subiculum and/or CA1 area, are probably the brain regions most involved in the enkephalin-induced epileptic phenomena.

Interactions in vivo and in vitro of corticoids and progesterone with cell nuclei and soluble macromolecules from rat brain regions and pituitary.

Adrenalectomized-ovariectomized (ADX-OVX) rats were given tail vein infusions of [3H]corticosterone, dexamethasone, cortisol, deoxycorticosterone or progesterone in doses around 10 nmoles/kg body weight. After a 30-60 min uptake period, cell nuclei were isolated from 9 brain regions and pituitary. Patterns of cell nuclear retention of [3H]corticosterone and [3H]dexamethasone differed: the former steroid was highest in hippocampus and septum and low in pituitary; the latter steroid was highest in pituitary and more uniformly distributed in the brain. The other 3H steroids showed very little cell nuclear labeling in vivo. In contrast, in vitro cytosol binding in hippocampus for [3H]progesterone, cortisol, deoxycorticosterone, and dexamethasone was 40-60% of that observed for [3H]corticosterone. The specificity of cell nuclear binding in slices of hippocampus in vitro was similar to that observed for cytosol binding. Reasons for the selectivity of in vivo cell nuclear labeling remain to be discovered but the selectivity does not appear to be an intrinsic feature of the receptors themselves. The pattern of in vivo labeling by [3H]corticosterone and [3H]dexamethasone differs from the in vivo distribution of [3H]estradiol in ADX-OVX rats using the same dissection procedure and this demonstrates the regional differentiation within brain of steroid hormone uptake and 'receptor' processes.

Differences in corticosterone and dexamethasone binding to rat brain and pituitary.

In an attempt to relate binding of 3H-corticosterone and 3H-dexamethasone to their respective potencies in blocking pituitary-adrenal activity, cytosol binding in vitro and cell nuclear binding both in vivo and in tissue slices in vitro were studied in hippocampus, hypothalamus, and anterior pituitary of adrenalectomized rats. It was found that the extremely potent glucocorticoid dexamethasone has a different pattern of binding than corticosterone in the brain and in the anterior pituitary. 1) In cytosol, differences in the estimated binding capacities in a particular tissue for 3H-corticosterone and 3H-dexamethasone and different rates of inactivation in the ability to bind the two steroids are observed. 2) For 3H-corticosterone, cytosol binding in hippocampus is higher than that in hypothalamus, and cell nuclear binding follows the same pattern. For 3H-dexamethasone, cytosol binding is again higher in the hippocampus than in hypothalamus but cell nuclear binding in the two structures is not significantly different. With respect to the anterior pituitary, binding to cell nuclei is higher for 3H-dexamethasone, while the binding to cytosol macromolecules is higher for 3H-corticosterone. 3) In vivo and in vitro cell nuclear binding for both steroids showed the same pattern among the three tissues, but in vivo data showed more distinctly the preference of 3H-dexamethasone for the anterior pituitary and the preference of 3H-corticosterone for the hippocampus. 4) When labeled in tissue slices, cell nuclear radioactivity appears to be bound to macromolecules. 5) Steroid metabolism does not occur in slices during 60 min in vitro at 25 C and cannot account for the observed tissue differences in binding. The existence of more than one population of corticosteroid-binding sites in brain and in anterior pituitary is suggested. The results are consistent with the view that the dexamethasone blockade of stress-induced ACTH release is mediated by the anterior pituitary, while the high specificity of cotricosterone binding in the hippocampus implies a specific but as yet undetermined effect of the hormone in this brain area, an effect which may not be directly related to regulation of ACTH secretion.