Polymorphism of the fur pigmentation genes and the hormonal adaptation system in the water vole (Arvicola terrestris)

Postnatal ontogenesis of hormonal system of hypophysis - adrenal glands and hormonal reaction under stress conditions were examined in adult water mouse, which had polymorphic fur color genes. Black females (genotype aa), opposite to brown ones, (genotype AA, Aa) had changed postnatal ontogenesis of adrenal glands function and they had not hormonal reaction to the two days water deprivation.     

Morphometric structure of thyroid and adrenal glands in bulls under different modes of adaptive technology

This work was carried out to study dynamics of morphometric structure of thyroid and adrenal glands in bulls brought up in early postnatal ontogenesis at lowered (-4.4-(-)8.0 degree centigrade) and raised (8.7-20.5 degree centigrade) environment temperature with further grow and fattening using intensive technology with application of new biogenic matters. For the first time it has been experimentally proved the expediency of correction of morphometric structure of investigated endocrine glands in bulls under condition of joint application of Suvar with Polistim or with DAFS-25 during the various periods of postnatal ontogenesis. Special features of morphometric structures of the thyroid glands (diameter, the area of follicles, thickness of thyroid epithelium, follicles index) and the adrenal glands (weight, width of zones of cortical and brain substances, the areas of cells and nuclei, and nuclear cytoplasmic ratio) in animals maintained under condition of adaptive technology have been investigated. It has been established that the endocrine glands morphometric parameters in bulls brought up at both lowered and raised temperature are more relief under combined effect of Suvar and DAFS-25 than Suvar and Polistim.     

The effect of a deficiency of the hormones of the peripheral endocrine glands on behavioral, learning and memory processes]

A comparative study of the effects of thyroid, adrenal, and gonadal deficit on capability for learning, retention of memory traces, and behavior was carried out in male rats under conditions of hormonal disbalance produced by extirpation of the endocrine glands. Behavior of animals was tested during the active and passive avoidance learning and in the open field. It was found out that the extirpation of the peripheral endocrine glands impairs learning and reproduction of the acquired reaction and alters the behavior. The results suggest that corticosteroid hormones take part in learning and behavior. Gonadal and thyroid hormones appear to exert a modulating influence on the higher nervous activity.     

Developing Brain as an Endocrine Organ: A Paradoxical Reality

The maintaining of homeostasis in the organism in response to a variable environment is provided by the highly hierarchic neuroendocrine-immune system. The crucial component of this system is the hypothalamus providing the endocrine regulation of key peripheral organs, and the adenohypophysis. In this case, neuron-derived signaling molecules (SM) are delivered to the blood vessels in hypothalamic “neurohaemal organs” lacking the blood–brain barrier (BBB), the posterior lobe of the pituitary and the median eminence. The release of SM to the blood vessels in most other brain regions is prohibited by BBB. According to the conventional concept, the development of the neuroendocrine system in ontogenesis begins with the “maturation” of peripheral endocrine glands which first are self-governed and then operate under the adenohypophysial control. Meantime, the brain maturation is under the control of SM secreted by endocrine glands of the developing organism and coming from the placenta and maternal organism. The hypothalamus is involved in the neuroendocrine regulation only after its full maturation that is followed by the conversion of the opened-looped neuroendocrine system to the closed-looped system as in adulthood. Neurons of the developing brain begin to secrete SM shortly after their origin and long before the establishment of specific interneuronal relations providing initially autocrine and paracrine morphogenetic influence on differentiating target neurons. Taking into account that the brain lacks BBB over this ontogenetic period, we hypothesized that it operates as the multipotent endocrine gland secreting SM to the general circulation and thereby providing the endocrine regulation of peripheral organs and the brain. The term “multipotent” means that the spectrum of the brain-derived circulating SM and their occupancy at the periphery in the developing organism should greatly exceed those in adulthood. In order to test this hypothesis, gonadotropin-releasing hormone (GnRH), dopamine (DA), and serotonin (5-hydroxytryptamine, 5-HT) were chosen as the markers of the presumptive endocrine function of the brain in ontogenesis. According to our data, the concentrations of GnRH, DA, and 5-HT in the rat general circulation during the perinatal period, i.e. before the establishment of BBB, was as high as those in the portal circulation in adulthood. The concentrations of circulating GnRH and DA dropped to almost undetectable level after the development of BBB suggesting their brain origin. This suggestion has been proven by showing an essential decrease of GnRH, DA, and 5-HT concentrations in general circulation of perinatal rats after microsurgical elimination of synthesizing neurons or the inhibition of specific syntheses in the brain before the establishment of BBB. GnRH, DA, and 5-HT apparently as dozens of other brain-derived SM appear to be capable of providing the endocrine influence on their peripheral targets like the adenohypophysis, gonads, kidney, heart, blood vessels, and the brain (endocrine autoregulation). Although the ontogenetic period of the brain operation as the multipotent endocrine gland is relatively short, the brain-derived SM are thought to be capable of providing long-lasting morphogenetic effects on peripheral targets and the brain. Thus, the developing brain operates as the multipotent endocrine gland from the onset of neurogenesis to the establishment of BBB providing the endocrine regulation of the developing organism.     

Hormones and the levels of humoral regulation]

The problems on the place of hormones secreted by "classical" endocrine glands, on their relationship with other compounds that possess physiological activity, criteria that determine the definition "hormone" are considered in this article. The conception about the levels of the humoral regulatory systems that are organized and formed during phylogenesis and ontogenesis and provide a consecutive increase in their complexity and mobility of adaptation to changes of environment and internal conditions are substantiated on the basis of numerous data. The metabolites that are products of nonspecific activity of any cell of the multicellular organism form the first and simplest level of humoral regulatory organization. The next (second) level of humoral organization is also formed by chemically simple substances. However, these substances are specialized products of the secretory activity of cells and exert potent influence on the physiological processes. Neuroamines and regulatory peptides are applied to these agents, in the first place. They arise simultaneously and jointly at the first stage of ontogenesis. The distinctive characters of the third level of the humoral regulation are increased and complication of the regulatory activity conditioned by cooperative influences of humoral agents produced by single secretory elements situated outside the classical endocrine glands. The chemically and originally different substances causing predominantly local effects are attributed to these physiologically active substances. Their participation in general adaptive reactions as well as inclusion of classical hormones into hierarchy of humoral regulation signify the formation of the forth regulatory level that provides realization of general homeostatic reactions peculiar to the whole organism.(ABSTRACT TRUNCATED AT 250 WORDS)     

Neuropeptides,mental performance and aging

The presence of peptidergic neuronal networks in the brain and the modulating action of neuropeptides on brain functions as evidenced by their behavioral influence in particular support the concept that the brain like the peripheral endocrine glands is an endocrine target organ which is as sensitive to treatment with neuropeptides as the peripheral glands are to pituitary hormones. Animal and human data are reviewed showing that neuropeptides related to ACTH/MSH affect motivational and attentional processes and that those related to vasopressin are involved in memory processes. Since these functions decline during aging it is postulated that a decreased bioavailability of neuropeptides in brain of elderly people is associated with specific disturbances in mental performance. Thus, the decreased mental ability of the aged may be restored by treatment with neuropeptides particularly those with little, if any, peripheral, endocrine activity, like the ACTH neuropeptide Org 2766 and the vasopressin neuropeptide DGAVP.     

The development of neuroendocrine regulation in ontogeny

Published and author's data on hypothalamic control over the most important endocrine functions during mammalian ontogenesis were reviewed. The data presented indicates that adenohypophyseotropic protein neurohormones are synthesized and accumulated in hypothalamus long before birth. At the end of the prenatal period most of hypothalamic neurohormones reached the adenohypophysis and were involved in regulation of the tropic hormones secretion. Exceptionally, regulative properties of thyroliberin and somatostatin are only manifested in immature-born animals (rats) in early postnatal period.     

Characteristics of microbial association in secretions of various mammalian sebaceous glands

The following secretions of mammalian skin glands were subjected to a microbiological survey: the middle-abdominal glands of great and Mongolian gerbils, the preputial gland of musk deer, the perineal organ of African civet cat, the interdigital skin regions and interdigital glands of bison, European bison, European roe deer, and musk deer. All the secretions were found to contain microbial associations. The composition of bacterial species in the secretions and the quantity of microorganisms varied among different animal species, during the ontogenesis of an animal, and depended on the topography of a gland on an animal body as well as on its functional state in different seasons or upon hormonal changes. The secretions of certain glands contain factors which determine the composition of microbial species in a particular ecological niche and the stability of such a cenosis.     

Quantitative histochemical investigation of rat salivary gland at different age stages of involution of the endocrine system

A complex quantitative histochemical investigation of the submandibular salivary glands in female albino rats at different age periods (4-5 month, 12 to 14 month- and 20 to 25 month-old) revealed some structural and functional changes during the oestrus cycle. The animals were grouped according to the age changes of the endocrine system. The salivary glands were sensitive to hormonal balance changes at all age periods but their metabolic interrelations varied. The functional changes in the salivary glands of young rats were accompanied by synchronous changes in the indices of energy, synthesis and transport metabolism. The gradual increase of disintegration of the endocrine system resulted in the uncoupling between the indices of the parenchyma and the microcirculation, as well as between nucleo-cytoplasmic relationships and intracellular transport processes in the salivary glands. That was a condition under which the impairment of cellularly excretory processes occurred (secretory stasis). The intercalated ducts and the striated tubules were especially sensitive to hormonal balance fluctuations which is consistent with the hypothesis of the endocrine nature of their function.     

Effect of thyroxine on the lactate dehydrogenase isoenzyme composition of chicken tissues in ontogeny

Using disc electrophoresis in polyacrylamide gel, studies have been made on the content of isoenzymes of lactate dehydrogenase in the mitochondria and cytoplasm from the brain, heart and liver after thyroxine administration to embryonal, early postnatal and adult hens. After this administration, the isoenzymic composition becomes more complex, redistribution of separate isozymes being observed in ontogenesis. The level of aerobic form of LDH increases at early stages of ontogenesis, that of anaerobic ones--in adult birds. Basing on their different functional role due to the presence of H- and M-subunits, it may be suggested that thyroxine administration results in a compensatory increase of the oxidative or glycolytic processes at the corresponding stages of ontogenesis, these changes reflecting phylogenetic peculiarities of the formation of the hormonal control of lactate dehydrogenase in tissues of birds.     

Morphological and functional changes in several endocrine glands induced by hypothyroidism in the rat

The effect of hypothyroidism upon the morphology and the function of several endocrine glands was studied in radiothyroidectomized male rats. It was found that T3, T4, insulin, prolactin and corticosterone levels were significantly lower in hypothyroid rats. TSH levels were significantly higher in these animals while no changes were depicted in testosterone levels. The administration of T4 drew back to normal range the above-mentioned altered serum hormone levels. The studies performed with light microscopy revealed alterations only in the TSH secretory cells of the adenohypophysis. Conversely, when using the electron microscope to study the different endocrine glands, clear alterations were depicted in the TSH and prolactin secretory cells of the adenohypophysis, as well as in the pancreatic B cells and the cells of the zona fasciculata of the adrenal cortex. No abnormal changes were demonstrable at the level of the seminiferous tubules of the testis. All the above morphological changes were corrected by the administration of T4 to hypothyroid rats. These results suggest that the hypothyroid state is a complex hormonal dysfunction rather than a single hormonal defect. The secretory alterations are accompanied by fine cellular alterations in the corresponding glands.     

The role of gap junction membrane channels in secretion and hormonal action

Connexins, gap junctions, and coupling are obligatory features of both endocrine and exocrine glandular epithelia. Evidence from these two types of tissues, and particularly from pancreatic islets and acini, indicates that cell-to-cell communication via gap junction channels is required for proper biosynthesis, storage, and release of specific secretory products. However, endocrine and exocrine glands express a different set of connexins and show opposite connexin and coupling changes in relation with the activation and inhibition of their secretory function. Also, several hormones modulate connexin and coupling expression, and junctional coupling affects hormonal stimulation. These observations indicate that gap junction channels play an important role in the control of secretion and hormonal action.     

Characteristics of Basic Parameters of the Hormonal Function of the Adrenal Cortex and Its Modification in Rat Ontogenesis

The stress-reactivity of the pituitary-adrenocortical system (PAS) as assessed by the dynamics of the blood corticosterone level changes was studied in rats administered with cortisol at different periods of their pre- and postnatal ontogenesis. The participation of the activation and deactivation mechanisms in this process was estimated by means of a mathematical modeling, using the basic parameters of hormonal wave. It is established that in the one-month old rat pups born from mothers injected with cortisol from the day 14 to 18 of pregnancy, the basal and stress-evoked PAS activity was not essentially changed, whereas the adult animals demonstrated a faster decrease of the stress-induced corticosterone level. Injection of cortisol at the early neonatal ontogenesis (1–5 day of life) decreased the basal and stress-induced corticosterone levels at the morning hours in one-month old rats, whereas in adult rats it increased the PAS stress-reactivity. Injection of cortisol in the late neonatal ontogenesis, i.e., during the period of formation of the sensory systems (opening of the ears, eyes, maximal motor activity) resulted predominantly in changing the time of completion of the stress-induced hormonal response that became longer than in control animals of the same age. With the aid of mathematical modeling, we have found that at the early neonatal period of development the hormonal exposure mainly increases the rate of PAS activation, whereas injection of glucocorticoids at the late neonatal period changes PAS regulation by a feedback mechanism, thus decreasing the rate of system inactivation and increasing the time of completion of PAS stress-induced reaction. It is concluded that the phenotypic reorganization of PAS stress-reactivity by exogenous corticosteroids depends on the time of their action on development of the excitatory and inhibitory mechanisms during the critical periods of their formation.     

Several aspects of the problem of the development of hormonal regulation during prenatal development

Some general aspects of the problem of hormonal control mechanisms in prenatal life are discussed. An analysis is performed on the basis of both the literary and author's data pertaining to the development of hypothalamo-hypophysial-adrenal, hypothalamo-hypophysial-thyroid and hypothalamo-hypophysial-gonadal functions during the foetal life. Experimental evidences of the activity of these functions in foetuses are provided. Neuroendocrine mechanisms are considered as a system of coordinated and intercontrolling links where the relative autonomy, the self-regulation of lower levels is coupled with the centralized control of higher levels. A concept is put forward to the effect that interactions between individual links play an important part in the formation of these mechanisms. If it is so, organizing influences, or stimuli, may emanate both from higher levels of control towards the lower ones and vice versa. Hormonal influences in early ontogenesis are characterized by the fact that, besides direct effects at the same developmental stage, they ensure the maturation of higher levels of neuroendocrine mechanisms which perform hormonal control in adults.     

Microtopographic relation between the lymphatic capillaries and glands of the small intestine

Microtopographic interrelationships of the lymphatic capillaries and glands of the small intestine have been investigated taking into account new data on the diffuse endocrine system, which includes endocrine cells of the gastro-intestinal tract. An immediate contact of the lymphatic capillaries with the intestinal glands, resembling microtopographic interrelationships of the lymphatic capillaries in the endocrine glands, has been revealed in total translucent and histological preparations. A suggestion is made that the microtopographic interrelationships of the lymphatic capillaries and the intestinal glands can be regarded as a morphologic basis for absorption of hormones produced by the endocrine cells of the intestinal glands.     

Ontogeny of peptide-producing nerves and endocrine cells of the gastro-duodeno-pancreatic region

Summary The ontogeny of different types of endocrine cells and nerves producing different hormonal peptides was studied by immunocytochemistry. The data indicate that several endocrine cell types are more frequent in the foetal than in the adult gastro-duodeno-pancreatic region. Some cell types were found to show an over-lapping distribution. Such distributional over-laps were more frequent in foetuses and neonates than in adults. Both parallel and non-parallel patterns of development of endocrine cells and peptide-producing nerves were detected. Together with available information on the trophic effects of the gastrointestinal hormonal peptides these findings indicate that foetal and neonatal endocrine cells may participate in the regulation of growth and morphogenesis in the gastrointestinal tract.     

The distribution of insulin-containing cells in the developing tissues of the common frog (Rana temporaria)

Monoclonal antibodies to pig insulin were used to follow the changes in localization of insulin-containing cells during the ontogenesis of the brown frog, Rana temporaria L., from stage 20 (Dabagian, Sleptsova, 1975) until completion of metamorphosis and beginning of active nutrition. Insulin-containing were localized in brain, surface epithelium, intestine, olfactory epithelium, taste teats, kidney tubules, ciliated epithelium of the oral cavity, pancreas, Jacobson and interjaw glands was found out. Localization of insulin-containing cells and type of their specific fluorescence varied at different stages of development. Formation of the insulin-containing system of amphibians on the whole is typical for the development of diffuse endocrine system in vertebrates.     

Lateralized brain and neuroendocrine dysregulation as response to traumatic stress

Stressful life events cause a variety of conditions affecting cerebral and neuroendocrine functions. Repeated stressful events also may determine sensitization leading to an increase in responsiveness to stress stimuli. Recent findings suggest that cognitive and emotional dysregulation related to traumatic stress likely is linked to defective inhibitory functions that may also lead to temporo-limbic seizure-like activity, increased vulnerability to stressors, and dysregulated asymmetry in neural activity patterns that may influence interhemispheric dissociation. Together recent data show that dysregulation in the brain asymmetry and mental functioning may be caused by stress-related activation that can influence also the peripheral endocrine glands through the HPA axis and other pathways connecting the CNS and the target endocrine glands.     

Seasonal changes in the reproductive anatomy of male Antechinus stuartii (Marsupialia: Dasyuridae)

Male Antechinus stuartii (Marsupialia: Dasyuridae) undergo significant endocrinological changes during their life history. The endocrine changes are associated with complete male mortality. The accessory reproductive tract of males is important for seminal plasma production, and changes associated with the reproductive cycle were not described in detail by earlier studies. The present study sought to describe some of the seasonal changes in structure of the male accessory reproductive tract in relation to the known hormonal changes. The epididymis, prostate, and bulbourethral glands are relatively undifferentiated in February and May, a time when plasma concentrations of testosterone are known to be low. By July, considerable hypertrophy and differentiation of the accessory reproductive tract are observed. This is most obvious in the bulbourethral glands, which change from being indistinguishable from one another in February and May to being three large morphologically and histologically distinct glands in July. The hypertrophy and secretory activity continue into August, the breeding season. These findings correlate with the hormonal profiles found in other studies of A. stuartii. J Morphol 231:261–275, 1997. © 1997 Wiley-Liss, Inc.     

Functional morphology of the submandibular salivary glands of white rats during aging involution]

Functional morphology of different zones of submandibular glands of albino rats was studied quantitatively with due regard for the stages of neuroendocrine system involution. It is shown that function of salivary glands during ageing is not altered; cyclic fluctuations with estral cycle phases are maintained similarly to those in young animals. But the basal level of proteins and mucopolysaccharides is reduced, their mean levels being equal to the minimal level in young animals. On the other hand, activation of enzymes responsible for energy and transport processes takes place and their relationships change. The data obtained prove the relationship between salivary and endocrine glands and confirm the viewpoint that in early age involution disintegration occurs between different parameters of the functional activity of salivary glands rather than there take place changes in their function.