Prenatal Stress and Adaptive Behavior of Offspring: The Role of Placental Serotonin.

The effect of mild prenatal stress in mice, leading to an increase in the placental serotonin level, on the formation of adaptive behavior in male offspring at the age of 35 days was studied. It was shown that, in BalbC mice, daily immobilization for 1 h during the period from 11 to 14 days of pregnancy led to an increase in placental and fetal serotonin levels on the 15th day of prenatal development. According to "resident-intruder" behavioral test, the prenatally stressed mice showed more reactive behavior in adulthood and low tendency to defend their territory. Thus, placental serotonin, formed under the stress condition, may act as a mediator between the environment and the fetuses and determine the adaptive behavior of offspring.

Expression of components of the serotonergic system in the developing rat thymus.

The developing thymus of rat fetuses contains all components of the serotonergic system: receptors, enzymes of synthesis, and membrane transporters. The expression of receptors suggests the possibility of a direct influence of serotonin on thymic development. The presence of tryptophan hydroxylase (the key rate-limiting enzyme of serotonin synthesis) and aromatic l-amino acid decarboxylase indicates the ability of fetal thymic cells to synthesize serotonin. It was shown that the cells of a developing thymus can actively uptake extracellular monoamines. The results of this study suggest different functions of the intrathymic and circulating serotonin pools in the regulation of thymic development.

The inhibition of dopamine synthesis in fetuses changes the pattern of T-lymphocyte maturation in the thymus of adult rats.

The mRNA for dopamine receptors of type D1, D3, D5, but not type D2, was detected in the thymus of rats starting from day 16 of embryonic development (E16). Dopamine at concentrations of 10-8-10‒6 M inhibited fetus thymocyte response to mitogen, confirming the functionality of the receptors and the possibility of a direct effect of dopamine on the developing thymus. Pharmacological inhibition of catecholamine synthesis in the crucial period of thymus development leads to long-term changes in the T-system immunity due to increased production of natural regulatory T-lymphocytes. The presence and functional activity of dopamine receptors in the fetal thymus indicates its ability to influence the development of the immune system of rats during ontogeny.

[Reciprocal Humoral Regulation of Endocrine Noradrenaline Sources in Perinatal Development of Rats].

The goal of the present study was to verify our hypothesis of humoral interaction between the norepinephrine secreting organs in the perinatal period of ontogenesis that is aimed at the sustaining of physiologically active concentration of norepinephrine in blood. The objects of the study were the transitory organs, such as brain, organ of Zuckerkandl, and adrenals, the permanent endocrine organ of rats that releases norepinephrine into the bloodstream. To reach this goal, we assessed the adrenal secretory activity (norepinephrine level) and activity of the Zuckerkandl's organ under the conditions of destructed noradrenergic neurons of brain caused by (1) their selective death induced by introduction of a hybrid molecular complex, which consisted of antibodies against dopamine-ß-hydroxylase (DBH) conjugated with saporin cytotoxin (anti-DBH-saporin) into the lateral brain ventricles of neonatal rats; and (2) microsurgical in utero destruction of embryo's brain (in utero encephalectomy). It was observed that 72 h after either pharmacological or microsurgical norepinephrine synthesis deprivation in the newborn rat's brain, the level of norepinephrine was increased in adrenals and, conversely, decreased in the Zuckerkandl's organ. Therefore, the experiments with models of chronical inhibition of norepinephrine synthesis in prenatal and early postnatal rat's brain revealed changes in the secretory activity of peripheral norepinephrine sources. This, apparently, favors the sustaining of physiologically active norepinephrine level in the bloodstream.

Immune proteasomes in the developing rat thymus.

The age dynamics of the content of the immune proteasome subunits LMP2 and LMP7 in rat thymus during prenatal and early postnatal ontogeny was studied. The LMP2 and LMP7 immune subunits were detected by Western blotting already by the 18th day of embryonic development, their amount increased to the 21st day to the level characteristic of the postnatal state. Double immunofluorescent labeling showed that in the thymus tissue the largest amount of LMP2 and LMP7 is localized in epithelial cells, whereas the level of their expression in thymocytes is lower. The results suggest that the establishment in thymus of selection processes, which depend on activity of immune proteasomes, can take place already in prenatal ontogeny. Analysis of age dynamics of the natural apoptosis level in thymocytes also favors this supposition. The presence of immune proteasomes in thymocytes during perinatal ontogeny suggests that, besides the antigen presentation, immunoproteasomes may possess other important functions.

Dopamine synthesis by non-dopaminergic neurons expressing individual complementary enzymes of the dopamine synthetic pathway in the arcuate nucleus of fetal rats.

This study was aimed to test our hypothesis about dopamine (DA) synthesis by non-DAergic neurons expressing individual complementary enzymes of the DA synthetic pathway in cooperation, i.e. L-dihydroxyphenylalanine (L-DOPA) synthesized in tyrosine hydroxylase (TH)-expressing neurons is transported to aromatic L-amino acid decarboxylase (AADC)-expressing neurons for conversion to DA. The mediobasal hypothalamus of rats at the 21st embryonic day was used as an experimental model because it contains mainly monoenzymatic TH neurons and AADC neurons (>99%) whereas the fraction of bienzymatic (DAergic) neurons does not exceed 1%. The fetal substantia nigra containing DAergic neurons served as a control. DA and L-DOPA were measured by high performance liquid chromatography in: (1) cell extracts of the cell suspension prepared ex tempora; (2) cell extracts and incubation medium after the static incubation of the cell suspension with, or without exogenous L-tyrosine; (3) effluents of the incubation medium during perifusion of the cell suspension in the presence, or the absence of L-tyrosine. Total amounts of DA and L-DOPA in the incubation medium and cell extracts after the static incubation were considered as the indexes of the rates of their syntheses. L-Tyrosine administration caused the increased L-DOPA synthesis in the mediobasal hypothalamus and substantia nigra. Moreover, L-tyrosine provoked an increase of DA synthesis in the substantia nigra and its decrease in the mediobasal hypothalamus. This contradiction is most probably explained by the L-tyrosine-induced competitive inhibition of the L-DOPA transport to the monoenzymatic AADC-neurons after its release from the monoenzymatic TH neurons. Thus, this study provides convincing evidence of cooperative DA synthesis by non-DAergic neurons expressing TH or AADC in fetal rats at the end of the intrauterine development.

Tyrosine hydroxylase expression in differentiating neurons of the rat arcuate nucleus: stimulatory influence of serotonin afferents.

The influence of serotonin afferents on tyrosine hydroxylase expression in differentiating neurons of the rat arcuate nucleus was studied in vivo and in vitro. In the in vivo study, pchlorophenylalanine inhibited serotonin synthesis in fetal brain from the 11th to the 20th embryonic day. We then used semiquantitative immunocytochemistry to evaluate tyrosine hydroxylase levels in neurons of the arcuate nucleus in fetuses at the 21st embryonic day or in offspring at the 35th postnatal day. Serotonin depletion significantly decreased the tyrosine hydroxylase content in neurons of males and females at the 21st embryonic day and in males at the 35th postnatal day. For the in vitro study, embryonic neurons of the arcuate nucleus were cocultured with embryonic neurons of the raphe nucleus, the main source of serotonin innervation of the brain, including the arcuate nucleus. Co-culture of the neurons resulted in a gender-specific increase of the tyrosine hydroxylase level in the neurons of the arcuate nucleus. In turn, the neurons of the raphe nucleus showed increased levels of serotonin in both males and females, with no sexual dimorphism. Thus, our results suggest a stimulatory, long-lasting effect of serotonin afferents on tyrosine hydroxylase expression in the differentiating neurons of the rat arcuate nucleus during prenatal ontogenesis.

Prolactin secretion and its dopamine inhibitory control in rat fetuses.

This study has determined in rats the ontogenetic schedule of the onset of pituitary prolactin (PRL) synthesis and release as well as of the establishment of the dopamine (DA) inhibitory control of PRL secretion. RIA recognized PRL traces in the pituitary at the 18th embryonic day (E18), although a clearly detectable amount of this hormone was first measured at E20, suggesting the onset of PRL synthesis. The PRL level in the pituitary increased significantly by E22, in females to a higher extent than in males. Decapitation of fetuses did not cause any change in the PRL plasma level in males showing no PRL release from the pituitary until term. Conversely, there was a slight but significant fall of plasma PRL in decapitated females, suggesting PRL release from the pituitary. An inhibition of DA receptors on lactotropes of fetuses resulted in an increased level of plasma PRL at E20, but not at E18, while the pituitary content of PRL remained unchanged. The same treatment at E22 caused a significant increase of the PRL concentration in plasma and a concomitant fall in the pituitary that could be prevented by preliminary encephalectomy. These data show that the tuberoinfundibular DA system begins to inhibit PRL release from lactotropes between E20 and E22, completely arresting PRL release from the pituitary in males but not in females.