The Role of the Brain in the Regulation of Peripheral Noradrenaline-producing Organs in Rats During Morphogenesis.

This work represents one part of our research project, in which we attempted to prove that a humoral regulation between noradrenaline-producing organs exist in the perinatal period. In this study, we used a rat model that allowed blocking the synthesis of noradrenalin in the brain and evaluated gene expression and protein levels of noradrenaline key synthesis enzymes such as tyrosine hydroxylase (TH) and dopamine beta-hydroxylase (DBH) in peripheral noradrenaline-producing organs. As a result, we showed an increased gene expression of TH and DBH in adrenal glands. These data indicate that, if neonatal rat brain lacks the ability to produce noradrenaline, then the synthesis of noradrenaline in adrenal glands increased as a compensatory process, so that the concentration levels in blood are maintained at normal levels. This indicates that there is a humoral regulation between brain and adrenal glands, which is not fully understood yet.

General Sources of Dopamine As a Potential Morphogenic Factor in the Developing Striatum of Rats.

In the striatum of rats at different stages of development, we determined the content of tyrosine hydroxylase and aromatic L-amino acids decarboxylase using double immunohistochemical labeling and estimated the expression level of their transcripts by real-time PCR. We found that, in different periods of development, there are three sources of dopamine in the striatum of rats: bienzymatic nerve fibers (throughout ontogeny), bienzymatic neurons (appear on day 18 of embryonic development), and monoenzymatic neurons (in adult animals). Dopamine, which is synthesized in the striatal neurons in the prenatal period, may function as a morphogenetic factor.

Secretory activity of the brain and peripheral organs: Spontaneous and stimulated release of noradrenaline in the ontogenesis of rats.

Spontaneous and K(+)-stimulated release of noradrenaline from the hypothalamus, adrenal gland, and organ of Zuckerkandl under their flowing incubation was investigated in the perinatal period of ontogenesis of rats. The results suggest that, during the investigated period of ontogenesis, adrenal glands are the main source of noradrenaline in the blood, whereas the contributions of the organ of Zuckerkandl and the brain are not as significant and change during this period.

[Noradrenaline role in regulation of dopamine-producing neurons in rat arcuate nucleus].

Among most important functions of the neuroendocrine system is the regulation of reproduction, including the inhibitory control of prolactin secretion by dopamine (DA) synthesized in the arcuate nucleus (AN). Besides DA, noradrenaline (NA) contributes to this regulation though, in contrast DA, its concrete functional role remains to be uncertain. In the previous studies, it has been suggested that NA inhibits compensatory synthesis of DA in DA-producing neurons of AN under the failure of the dopaminergic system though no evidence were obtained. Therefore, the goal of this study was to specify the role of NA in the regulation of DA-producing neurons in AN. Two pharmacological models were used to this aim: a) switching off dopaminergic and noradrenergic neurons and their afferents in An or b) switching of only dopaminergic neurons and afferents that allowed us to recognize NA role in the complex catecholaminergic regulation of prolactin secretion. According to our data, the maintaining of the noradrenergic innervation of AN under the neurotoxin-induced failure of dopaminergic neurons resulted in the decrease of the expression of tyrosine hydroxylase (TH), the first enzyme ofDA synthesis, thereby enhancing DA deficit. This is considered as direct evidence of noradrenergic inhibitory control of TH expression in the neurons of AN.