Corticosteroid hormones in pathogenetic heterogenety of post-stress depression

The role of corticosteroid hormones in post-stress depression progress and their usage for correction of this psychopathology was studied in active and passive Wistar rats. It was found that only passive individuals had sensitivity to corticosteroids and, among them, only adrenal gland hormones lead to corrections of post-stress depression.     

Corticosteroid hormones: mechanisms involved in the recognition of aldosterone by mineralocorticoid receptors

Aldosterone and cortisol, the major mineralocorticoid and glucocorticoid hormones in humans, are structurally very closed. Both hormones bind to the mineralocorticoid receptor (MR) with the same affinity. Nevertheless MR is preferentially activated by aldosterone, suggesting that the binding of these two hormones to MR involved some distinct contacts. We constructed a tridimensional model of the ligand-binding domain of the human MR, by taking as a template the structural data of the retinoid receptor associated with its ligand. The MR model allowed the identification of several residues involved in the interaction with aldosterone and cortisol. The residues Gln 776 and Arg 817 make hydrogen bonds with the 3-keto function and the residue Asn 770 with the C21-hydroxyl group. Analyses of the wild type and mutant MRs activities in response to corticosteroids bearing hydroxyl groups at various steroid skeleton position led to the following conclusions: 1) the interaction between the residue Asn 770 and the C21-hydroxyl group of corticosteroids is determinant for stabilizing the active MR conformation and 2) the stability of this conformation is enhanced by the 11-18 hemiketal group of aldosterone whereas it is decreased by the 11 beta- and 17 alpha-hydroxyl groups of cortisol. These results are discussed in the light of a model for the MR activation process.     

Corticosteroid receptors in the brain as signal systems of stress and adaptation

The modern literature date and own authors investigation allow to consider brain corticosteroid receptors as the importance system of stress and adaptation. The main attention is paid for functional meaning and distribution of corticosteroid receptors in brain regions. The role of brain corticosteroid receptors in transduction of hormonal signal and its modification different regulatory factors are discussed.     

Steroid hormones and their receptors in the brain

Steroid hormones regulate several important functions of the brain by altering the expression of particular genes through their receptors. First in this paper the localization of glucocorticoid receptor immunoreactivity and mRNA in the brain was examined. Second biphasic effects of glucocorticoid on the hippocampus was described and particular emphasis was given on the apoptosis. Third the significance of estrogen receptor in the sexually dimorphic areas was discussed. These results suggest that steroids modulate the gene expression along with the alteration of cell structures in a different manner in a tissue-specific pattern.     

Effect of some fragments of peptide hormones on the content of biogenic monoamines from mouse brain]

The effect of some tripeptides, which are fragments of peptide hormones, and their analogs on the content of biogenic monoamines (BM) from albino mice brain was studied. It was found that thyroliberin, melanostatin and the C-terminal tripeptide of gonadoliberin activate the dophaminergic (DA-ergic) system in the forebrain of mice treated with reserpine or haloperidol, whereas the C-terminal tripeptide of gastrin acts as a synergic blocker of the DA receptors. The N-terminal tripeptides (with and without the amido group) do not affect the content of BM. No effect of the tripeptides was observed in intact animals. It is assumed that the agonistic or antagonistic effect of the tripeptides on BM is due to certain structural peculiarities of the tripeptides, e.g. the presence of the C-terminal amido group and their endogenous nature.     

Membrane reception of thyroid hormones]

Comparative and competitive analyses of thyroxine (T4) and triiodothyronine (T3) binding to highly purified rat liver, brain and lung cell plasma membranes were carried out. The dependence of hormone binding on the time, temperature and concentration was studied. The effects of trypsin and partial delipidation on the binding parameters of thyroid hormones were investigated. Two thyroid hormone-binding sites were detected in cell plasma membranes of all tissues under study. The maximal binding of T4 to rat liver membranes and the maximal binding of T3 to rat brain membranes was observed in all experiments, the affinity for T3 being higher than that for T4. An important role of both protein and lipid components of plasma membranes in the membrane reception of thyroid hormones is proposed.     

Recent advances in gastrointestinal hormones]

Recent advances in the field of peptide chemistry and gene technology have resulted in an explosive accumulation of information on the chemical structures of gastrointestinal hormones. Based on the information, chemical syntheses of these peptides or their shorter fragments and analogs have been performed. Synthetic peptides related to the hormones have now become important tools in searching for functions of peptides and in producing region-specific antisera to the respective peptides. Using these antisera, hormone-producing cells were clearly identified and the post-translational biosynthetic processings in the cells were demonstrated. Recent immunohistochemical studies have also revealed that cells contain and can release a variety of peptides or amines that are capable of influencing target cells and acting as hormone, neurotransmitter or neuromodulator. In addition, recent studies on galanin and glucagon-like peptide-1 (GLP-1) are described.     

Sex hormones and neurotransmitters as mediators for sexual differentiation of the brain

Sexual differentiation of the brain is regarded as a model for environment-dependent brain development mediated by systemic hormones and neurotransmitters. Abnormal concentrations of systemic hormones and/or neurotransmitters, if occurring during a critical period of brain development, can lead to permanent developmental disabilities of fundamental processes of life. Such developmental disabilities appear to be avoidable, at least in part, by improving the external, i.e. psychosocial and natural environment, or by correcting abnormalities in the internal, i.e. metabolic and hormonal environment and, particularly, by correcting abnormal neurotransmitter concentrations (and/or turnover rates) during brain development.     

Thyroid hormones and neurotubule assembly in vitro during brain development

A new model has been used to evaluate the effects of thyroid hormones on brain development. This model is based on the assumption that the major effect of thyroid hormones is in regulating the rate of neurite growth of the rat brain at early stages of postnatal development. Microtubules were chosen as markers of neurite growth. We tested, therefore, whether the rate of microtubule assembly in vitro is under thyroid hormone control. The following results were obtained: The rate of tubulin assembly into microtubules in vitro seems to be thyroid hormone dependent: (a) in 15-day-old hypothyroid rats the rates of tubulin assembly in vitro are low, comparable to those levels found in normal rats on day 3; (b) normal rates of assembly in vitro are restored upon addition of very small amounts of microtubule fragments which act as nucleating centers in the process of microtubule formation; (c) addition of microtubule-associated proteins to a hypothyroid preparation restores maximal assembly rates; similar results were obtained on adding one of the microtubule-associated proteins (purified tau protein); (d) physiological amounts of thyroid hormones completely restore normal assembly rates provided that they are administered very early after birth; (e) the ability of tubulin to assemble maximally does not seem to be permanently impaired, since normal assembly rates are spontaneously restored when hypothyroidism is maintained until an adult stage; (f) normal microtubule assembly is observed when hypothyroidism is produced at an adult stage. The model which may be constructed from these results implies that thyroid hormones are required briefly after birth to accelerate the rate of microtubule assembly thus allowing intensive neurite growth during the critical period of brain development.     

Microtubules and brain development: The effects of thyroid hormones

The data accumulated during the past twenty years suggest that thyroid hormones have a direct effect on the differentiation of both the neurons and the glial cell during the critical period of brain development. A fast survey of the available data (which is presented in the introduction of this article) on the mechanism of action of thyroid hormones and on their different effects during brain development suggests that the most dramatic effect of hypothyroidism is a hypoplastic neuropile. Both in vivo, during the critical period of nerve cell differentiation and in vitro, when added to primary cultures of embryonic nerve cells thyroid hormones stimulate neurite outgrowth. Since neurite outgrowth requires massive microtubule assembly the assumption was made that thyroid hormones stimulate nerve cell differentiation by changing the concentration and/or activity of the different proteins (tubulin and “microtubule associated proteins”, MAPs) which co-polymerize to form microtubules.

Preliminary information was obtained by following the kinetics of microtubule assembly in crude brain supernatants. The data showed that: (1) the rate of in vitro microtubule assembly increases with age during brain development; (2) hypothyroidism, when produced in the rat at late pregnancy, slows this evolution; (3) early replacement therapy with thyroid hormones restores normal rates of assembly; (4) the addition of purified MAPs to normal young or 15-day-old hypothyroid brain preparations restores normal rates of polymerization. These and other data suggested that thyroid hormones regulate microtubule assembly by changing the concentration and/or activity of one or more of the MAPs.

Further analysis revealed that striking qualitative changes in MAPs composition occur during brain development. For instance, the TAU fraction, a group of 4–5 proteins with a molecular weight of 60–68 K which is present in adult brain, is absent at early stages of postnatal development: two other entities are present, TAU slow and TAU fast, with different molecular weights, lower activity and different peptide mapping. This latter observation suggests that different TAU genes are expressed during brain development; a conclusion which has been confirmed by cell-free translation of the mRNas coding for these proteins. Analysis of the TAU fraction prepared from hypothyroid rat brains also revealed that a group of TAU proteins. “TAU₃”, is almost missing, whereas thyroid hormone administration markedly increases its concentration. Two-dimensional gel electrophoresis showed that the TAU fraction is composed with more than 15 entities, with at least five of them being under thyroid hormone control.

The precise physiological significance of the heterogeneity of MAPs and of the changes in MAPs composition seen during development and in hypothyroid rat brain remains to be determined. The assumption is made that these changes might be of utmost importance to regulate the number and length of the microtubules, and therefore the number and length of the neurites which are formed during the differentiation process of the different neurons. Thyroid hormones would be in these respects one of the epigenic factors required to synchronize sequentially the expression of the genes coding for these proteins in the different nerve cells.