Tyrosine hydroxylase expression in differentiating neurons of the rat arcuate nucleus: inhibitory effect of serotoninergic afferents]

In vivo studies, serotonine synthesis in the rat fetal brain was inhibited by p-chlorphenylalanine from the 11th to the 20th embryonic day. Serotonine depletion significantly decreased thyrosine hydroxylase content in the neurones of males and females on the 21st embryonic day and in males--on the 35th postnatal day. In vitro, a co-culture of arquate nucleus' and raphe nucleus' embryonic neurones resulted in a sex-specific increase of the thyrosine hydroxylase level in the former neurones. The raphe nucleus' neurones manifested an increased level of serotonine. The findings suggest an activating long-lasting effect of serotonine afferents on the thyrosine hydroxylase expression in differentiating neurones of the arquate nucleus in rats during prenatal ontogenesis.     

Intracellular distribution of creatine kinase isoenzymes in the brains and hearts of rats at different stages of postnatal development]

The total activity and range of the creatine kinase (CK) isozymes have been studied in the homogenate and subcellular fractions (nuclei, mitochondria, cytoplasm) of the rat brain and heart during postnatal ontogenesis. The total activity of CK in the brain and heart of newborn rats was found to be 4 and 2 times less, resp., than in those of adults. The age patterns were established in the activity of cytoplasmic (CK-1, CK-2 and CK-3) and mitochondrial (CK-4) isozymes. During the whole postnatal development the rat brain contains only one cytoplasmic isozyme, CK-1. In the heart of newborn rats, as compared with adults, the content of CK-1 and CK-2 is much higher and that of CK-3 lower. On the 12-15th day of life the range of the CK isozymes approaches that characteristic of adult animals. The activity of CK-4 was found in the brain on the 5-7th day of life and in the heart on 12-15th day. In the range of the CK isozymes in the adult brain the content of mitochondrial CK amounts to 19.3% and in the heart to 16.5%. The data obtained complement the literary ones suggesting the low level of energy-forming processes in the brain and heart cells at the early stages of the rat postnatal development.     

Content of NCAM, the neural cell adhesion molecule, in the brain of rats subjected to prenatal stress

The content of NCAM, the neural cell adhesion molecule, was studied in the cerebral cortex, hippocampus, striatum, cerebellum, and pons of 15- and 30-day-old rats, the offspring of intact females and females subjected to stress during pregnancy. At the 30th day of the postmatal development, opposite NCAM concentration changes were observed in the cortex and other brain parts of the offspring of stressed rats. These differences can be related to a deficiency of mature synapses in the forebrain of prenatally stressed rats and adaptation rearrangements in the neuronal systems of the brainstem and cerebellum.     

Neonatal manipulation of oxytocin alters oxytocin levels in the pituitary of adult rats.

The neuropeptide oxytocin (OT) and its OT antagonists (OTA) in infant rats affect their behavior as adults. In this study we attempted to determine whether treating rats on the day of birth (postnatal day 1) with OT or OTA would affect brain OT levels of these rats as adults. Rat pups were injected with OT (3 microg), OTA (0.3 microg) or saline vehicle ip on postnatal day 1. As 60-day-old adults, treated rats were killed, and the OT content in their medial preoptic areas (MPOAs), medial hypothalami (MH) and pituitaries were assayed. In females, treatment with OTA on postnatal day 1 significantly decreased pituitary OT levels as adults. In males, by contrast, treatment with OTA on postnatal day 1 resulted in increased pituitary OT levels when they become adults compared to male rats treated with OT on postnatal day 1. There were no significant effects of neonatal treatment on OT levels in either the MH or MPOA. Day 1 postnatal treatment with OT or OTA had a long-term sexually dimorphic effect on OT levels in the pituitary.     

IMMUNOHISTOCHEMICAL STUDIES OF S-100 PROTEIN DURING POSTNATAL ONTOGENESIS OF THE BRAIN OF TWO STRAINS OF RATS

Abstract— We have studied the dynamics of the appearance of cells reacting positively with anti-S-100 protein antiserum, during postnatal neurocytogenesis in the brain of rats of two strains differing in their susceptibility to sound stimuli. The postnatal time of appearance of cells reacting positively with anti-S-100 protein antiserum was somewhat later in rats susceptible to sound-induced seizures than in sound-resistant rats. These differences concerned mainly the cerebral cortex of 12-day-old rats. By day 21 of postnatal life these differences had disappeared. In subcortical structures of the brain, S-100 protein was first found on the 4th to the 5th day of life and the rate of appearance of cells containing this protein was similar in the two strains.     

Postnatal changes of cathepsin D activity in rat liver and brain

Total and specific activity of cathepsin D (EC. 3.4.23.5) were measured in rat liver and brain from 1 to 98 days of age. The activity of cathepsin D in the liver of adult and newborn rats was the same while in the rat brain it was higher in adult than in newborn rats. In the liver maximum specific activity of cathepsin D occurred on the 10th postnatal day and minimum on the fourth day of age. In the brain maximum specific activity of the enzyme occurred on the 14th postnatal day. Total activity of cathepsin D increased after birth in rat liver and brain. These results are discussed in relation to the functional role of cathepsin D in the rat liver and the brain.     

Rat brain iron concentration is lower following perinatal copper deficiency

Experiments performed with Holtzman rats demonstrated that brain iron (Fe) was lower by postnatal day 13 (P13) in pups born and nursed by dams that began copper-deficient (-Cu) treatment at embryonic day 7. Transcardial perfusion of P24-P26 males and females to remove blood Fe contamination revealed that brain Fe was still 20% lower in -Cu than +Cu rats. Estimated blood content of brain for -Cu rats was greater than for +Cu rats; for all groups, values ranged between 0.43 and 1.03%. Using group-specific data and regression analyses, r = 0.99, relating blood Fe to hemoglobin, brain Fe in non-perfused rats in a replicate study was lower by 33% at P13 and 39% at P24 in -Cu rats. Brain extracts from these rats and from P50 rats from a post-weaning model were compared by immunoblotting for transferrin receptor (TfR1). P24 brain -Cu/+Cu TfR1 was 3.08, suggesting that brains of -Cu rats were indeed Fe deficient. This ratio in P13 rats was 1.44, p < 0.05. No change in P50 -Cu rat brain TfR1 or Fe content was detected despite a 50% reduction in plasma Fe. The results suggest that brain Fe accumulation depends on adequate Cu nutriture during perinatal development.     

Maternal Separation during Breastfeeding Induces Gender-Dependent Changes in Anxiety and the GABA-A Receptor Alpha-Subunit in Adult Wistar Rats

Different models of rodent maternal separation (MS) have been used to investigate long-term neurobiological and behavioral changes, associated with early stress. However, few studies have involved the analysis of sex-related differences in central anxiety modulation. This study investigated whether MS during breastfeeding affected adult males and females in terms of anxiety and brain GABA-A receptor-alpha-subunit immunoreactivity. The brain areas analyzed were the amygdale (AM), hippocampus (HP), medial prefrontal cortex (mPFC), medial preoptic area (POA) and paraventricular nucleus (PVN). Rats were housed under a reversed light/dark cycle (lights off at 7∶00 h) with access to water and food ad libitum. Animals underwent MS twice daily during the dark cycle from postnatal day 1 to postnatal day 21. Behavior was tested when rats were 65–70 days old using the elevated plus maze and after brains were treated for immunohistochemistry. We found that separated females spent more time in the open arms and showed more head dipping behavior compared with controls. The separated males spent more time in the center of the maze and engaged in more stretching behavior than the controls. Immunohistochemistry showed that separated females had less immunostained cells in the HP, mPFC, PVN and POA, while separated males had fewer immunolabeled cells in the PFC, PVN and AM. These results could indicate that MS has gender-specific effects on anxiety behaviors and that these effects are likely related to developmental alterations involving GABA-A neurotransmission.     

Postnatal Development of Synaptic Glycine Receptors in Normal and Hyperglycinemic Rats

The postnatal development of glycine synaptic receptors has been studied. Strychnine binding to the synaptic membrane fraction is very low at birth, increases thereafter, and reaches adult values at the 15th day in the brain, and at the 30th day in the spinal cord. Throughout postnatal development, there are more glycine receptors in the spinal cord than in the brain. The development of receptors in the spinal cord displays a pattern similar to that reported previously for the glycine reuptake system in spinal cord slices and in the activity of spinal cord glycine synthase. In rats with experimental hyperglycinemia strychnine binding to spinal cord glycine receptors increases much more rapidly, reaching a level 1.5 times the control value by day 10. When the hyperglycinemia was induced after the 10th postnatal day, however, no effect on the glycine receptors was observed. This increased number of receptors could be explained by an effect of glycine on the synaptic stabilisation process. No changes in the KD for strychnine were observed either during postnatal development or in hyperglycinemic rats. The KD remained approximately 10 nM in the spinal cord and 50 nM in the brain. Results are discussed with respect to the ontogeny of glycinergic synapses and the pathogenesis of nonketotic hyperglycinemia.     

The postnatal development of the genital system in male rats following the prenatal administration of corticosterone

Corticosterone administration to pregnant Wistar rats on days 16 and 18 of pregnancy leads to changes in genital system of male offspring during postnatal ontogenesis: reduction of ano-genital distance in two days old rats, increase of preputial glands' weight in 35 and 70 day old embryos, changes in nature of puberal increase in testosterone blood level from day 35 to day 70 of life. The obtained data suggest that the increase in the corticosteroid level in blood of pregnant females owing to any stress factor can affect the postnatal development of genital system of male offspring.     

The brain is one of the sources of L-dihydroxyphenylalanine in systemic circulation in fetuses and neonatal rats

The performed study was aimed at checking our hypothesis that the developing brain is a source of L-dihydroxyphenylalanine (L-DOPA), a precursor of dopamine in the total circulation system. At the initial stage, the L-DOPA concentration in peripheral blood was analyzed at the 18th and 21st embryonal days (E18 and E21), at the 3rd postnatal day (P3), and at the prepubertal period (P30). The highest L-DOPA concentration was revealed at the perinatal period, while decreased 4–12 times for the first month of life. The subsequent analysis of dynamics of the total blood L-DOPA content showed that maintenance of the constant L-DOPA concentration at the perinatal period on the background of a gradual increase of the blood serum volume is due to a rise of its secretion. At the postnatal period (P3–P30), the blood L-DOPA content increased twice in males, whereas it decreased to the same extent in females. Analysis of the L-DOPA concentration in two most important brain centers, hypothalamus and mesencephalon-rhombencephalon, showed its twofold decrease in hypothalamus during E18–E21 of development; then it slightly increased from E21 to P3 and fell 4–5 times by P30. In mesencephalon-rhombencephalon, the L-DOPA concentration was slightly reduced from E18 to E21 (only in females), while on P3 it returned to the E18 level and decreased 7–9 times by P30. The direct proof for the L-DOPA release from the developing brain into the systemic circulation follows from comparison of the blood L-DOPA concentration in shamoperated and encephalectomized rat fetuses after mechanical destruction of neurons of the two abovementioned most important dopaminergic centers. Thus, encephalectomy led to a twofold reduction of the blood L-DOPA concentration (statistically significant differences were observed only in females). Thus, the work presents evidence that the developing brain is one of L-DOPA sources in the total circulation system in rats during prenatal and early postnatal periods of ontogenesis.     

Developmental expression of glial markers in ependymocytes of the rat subcommissural organ: role of the environment

Summary The rat subcommissural organ (SCO), principally composed of modified ependymocytes (a type of glial cell), is a suitable model for the in vivo study of glial differentiation. An immunohistochemical study of the ontogenesis of rat SCO-ependymocytes from embryonic day 13 to postnatal day 10 shows that these cells express transitory glial fibrillary acidic protein (GFAP) from embryonic day 19 until postnatal day 3. However, S100 protein (S100) is never expressed in the SCO-cells, contrasting with the ventricle-lining cells of the third ventricle, which contain S100 as early as embryonic day 17. Environmental factors could be responsible for the repression of GFAP and S100 in adult rats, because GFAP and S100 are observed in ependymocytes of SCO 3 months after being grafted from newborn rat into the fourth ventricle of an adult rat. Neuronal factors might be involved in the control of the expression of S100, since after the destruction of serotonin innervation by neurotoxin at birth, S100 can be observed in some SCO-ependymocytes of adult rats. On the other hand, GFAP expression is apparently not affected by serotomin denervation, suggesting the existence of several factors involved in the differentiation of SCO-cells.     

Expression of CCDC85C,a causative protein for hydrocephalus,and intermediate filament proteins during lateral ventricle development in rats

Coiled-coil domain containing 85c (Ccdc85c) is a causative gene for genetic hydrocephalus and subcortical heterotopia with frequent brain hemorrhage. In the present study, we examined the expression pattern of CCDC85C protein and intermediate filament proteins, such as nestin, vimentin, GFAP, and cytokeratin AE1/AE3, during lateral ventricle development in rats. CCDC85C was expressed in the neuroepithelial cells of the dorsal lateral ventricle wall, diminishing with development and almost disappearing at postnatal day 20. By immunoelectron microscopy, CCDC85C was localized in the cell-cell junction and apical membrane. The expression of nestin and vimentin was decreased in the wall of the lateral ventricle in manner similar to CCDC85C, but GFAP expression started immediately after birth and became stronger with age. Moreover, cytokeratin expression was found at postnatal day 13 and increased at postnatal day 20 in conjunction with the disappearance of CCDC85C expression. Taken together, CCDC85C is expressed in the cell-cell junctions lining the wall of the lateral ventricle and plays a role in neural development with other intermediate filaments in the embryonic and postnatal periods. Our chronological study will help to relate CCDC85C protein with intermediate filaments to elucidate the detailed role of CCDC85C protein during neurogenesis.     

Disruption of behavior and brain metabolism in artificially reared rats

Early adverse life stress has been associated to behavioral disorders that can manifest as inappropriate or aggressive responses to social challenges. In this study, we analyzed the effects of artificial rearing on the open field and burial behavioral tests and on GFAP, c‐Fos immunoreactivity, and glucose metabolism measured in anxiety‐related brain areas. Artificial rearing of male rats was performed by supplying artificial milk through a cheek cannula and tactile stimulation, mimicking the mother's licking to rat pups from the fourth postnatal day until weaning. Tactile stimulation was applied twice a day, at morning and at night, by means of a camel brush on the rat anogenital area. As compared to mother reared rats, greater aggressiveness, and boldness, stereotyped behavior (burial conduct) was observed in artificially reared rats which occurred in parallel to a reduction of GFAP immunoreactivity in somatosensory cortex, c‐Fos immunoreactivity at the amygdala and primary somatosensory cortex, and lower metabolism in amygdala (as measured by 2‐deoxi‐2‐[¹⁸fluoro]‐d ‐glucose uptake, assessed by microPET imaging). These results could suggest that tactile and/or chemical stimuli from the mother and littermates carry relevant information for the proper development of the central nervous system, particularly in brain areas involved with emotions and social relationships of the rat. © 2017 Wiley Periodicals, Inc. Develop Neurobiol 77: 1413–1429, 2017     

Upregulation of astrocytic basic fibroblast growth factor in the cingulate cortex of lactating rats: time course and role of suckling stimulation

Previous work from our laboratory has shown that there is a much higher level of bFGF and GFAP immunoreactivity in area 2 of the cingulate cortex (Cg2) of rats on day 16 of lactation than in cycling or late pregnant females. To examine the time course of this change, in the first of the current studies, we compared bFGF and GFAP immunoreactivity in the brains of lactating females on postpartum day 4 (PP4), day 10 (PP10), day 16 (PP16), and day 24 (PP24) with that of cycling and ovariectomized (OVX) females. In the second study, we investigated whether the maintenance of these changes in bFGF and GFAP depended on suckling stimulation by removing litters on day 1 or day 16 postpartum and examining the brains of the dams on day 4 (Pr4) or day 24 (Pr24) postpartum, respectively. bFGF and GFAP immunoreactivity within Cg2 and the medial preoptic area (MPOA) were measured. In both experiments astrocytic bFGF and GFAP surface density in the Cg2 varied significantly across groups. All postpartum rats, regardless of stage of lactation or presence of the litter, had significantly higher levels of bFGF and GFAP immunoreactivity than cycling animals. Thus, the maintenance of this upregulation in bFGF and GFAP immunoreactivity does not depend on suckling stimulation. Consistent with our previous report, astrocytic bFGF was also elevated in the MPOA of PP16 animals. These data suggest a robust, long-lasting, postpartum change in bFGF and GFAP immunoreactivity in Cg2 and a role for this area of the cortex in the physiological and behavioral adaptations that accompany reproductive experience.     

The ontogeny of cytosol and nuclear progestin receptors in male rat brain and its male-female differences

The fetal and postnatal development of the progestin receptor systems in the intact male rat brain was investigated by means of the in vitro cytosol binding and the nuclear exchange assay using [³H]R5020 ([17α-methyl-³H]17α,21-dimethyl-19-nor-4,9-pregnadiene-3,20-dione). The cortical cytosol receptors, first detectable at day 0, rapidly increased at day 7, reaching a maximum at day 10, then gradually declined thereafter. The receptors in the HPOA appeared clearly at day 1, increased during the first 10 days, then remained constant at days 14–21. The postnatal developmental patterns of cytosol brain progestin receptors in males were essentially similar to those in females, but there were some differences between both sexes. The male HPOA at days 10–14 contained more receptors than the female one. Nuclear progestin binding was low in the neonatal male brain at days 1–3. Despite the low level of serum progesterone, the cortical nuclear binding suddenly increased at days 7–10, then remained high at days 14–21. A similar, though less pronounced, pattern was seen in the HPOA. The male pattern of nuclear binding, thus, essentially resembled the female one. However, lower binding in the cortex and, possibly, HPOA was found in males than in females at days 10–21. After progesterone injection postnatal male rats accumulated a lower concentration of progestin receptors in the cortex and, possibly, HPOA than similarly-treated females.It is concluded from these results that progestin receptors in male rat brain appear immediately after birth and develop differentially in the cortex and HPOA. The sudden onset of increased nuclear translocation of endogenous progestin receptor complexes may occur in the brain at around days 7–10. There is a marked sex difference in the nuclear progestin receptor system in the postnatal brain, particularly the cortex. Moreover, the postnatal male brain has lower capacities of nuclear receptor translocation than does the female one. The progestin receptor system in the cortex and, possibly, HPOA of rats in the early postnatal life might be involved with some processes in the mechanism of sexual differentiation of the brain.     

An iron-deficient diet during development induces oxidative stress in relation to age and gender in Wistar rats

Iron is a trace element and a structural part of antioxidant enzymes, and its requirements vary according to age and gender. We hypothesized that iron deficiency (ID) leads to an increase in free radicals which mainly affect the brain, and the severity of damage would therefore be dependent on age and gender. Two groups of Wistar rats were evaluated evolutionarily: 100 rats (50 males; 50 females) with ID diet and 100 rats (50 males; 50 females) with standard diet. Both groups were offspring from mothers who were previously under the same dietary intervention. The ages studied roughly correspond to stages of human development: birth (0 postnatal day “PND” in rats), childhood (21 PND), early adolescence (42 PND), late adolescence (56 PND), and adulthood (70 PND). The following biomarkers in the brain, blood, and liver were analyzed: lipid peroxidation products (LPO), protein carbonyl content and activity of the antioxidant enzymes, superoxide dismutase, catalase, and glutathione peroxidase. It was demonstrated that ID subjects are born with high levels of LPO in the brain and low antioxidant activity, the damage being more severe in males. After birth, antioxidant defense focuses on the central level (brain) in ID females and on the peripheral level (blood and liver) in ID males. In two critical stages of development, birth and late adolescence, antioxidant protection is insufficient to counteract oxidative damage in ID subjects. Moreover, we observed that the variability of results in the literature on oxidative stress and ID comes from gender and age of the subjects under study. With this, we can establish patterns and exact moments to carry out studies or treatments.     

Postnatal changes in the amount of acetylcholine in the atrial tissue of the albino rat heart.

Changes in the acetylcholine (ACh) content and concentration in the atrial tissue of albino rats between the third day of postnatal life and adulthood were studied. The ACh content (ng in whole atria) rose during the whole of the period in question, from 5.6 ng at 3--4 days to 307.5 ng in adult rats. The ACh concentration (micrograms/g fresh tissue) rose up to the 53rd day after birth, when it attained adult values. The fastest increase in both the ACh content and concentration was observed between the 10th and the 17th postnatal day, when it amounted to over 46% of the total concentration increase between the third day of life and adulthood.     

Postnatal thyroxine modifies effects of early androgen on lordosis

The sensitivity of female rats to the organizational effects of postnatal androgen was examined after néonatal manipulations known to affect the rate of brain development: thyroxine (T₄) administration and handling at birth. Testosterone propionate (TP) was injected subcutaneously in oil on postnatal day 6 to littermates that (i) had been undisturbed at birth; (ii) had received saline injections (S) and associated handling (H) on the day of birth (postnatal day 1) and the following day; and (iii) had received T₄ in saline (1 μg/g body wt) and H on postnatal days 1 and 2. Estrous cycles at 45 and 90 days of age, ovulation at Day 100 and sexual receptivity (lordosis score) at Days 115 and 125 were used to evaluate changes in TP effects. The majority of animals treated with 100 μg TP on postnatal day 6 exhibited persistent estrus (PE) at 45 and 90 days of age as expected. Neither T₄ nor S pretreatment on postnatal days 1 and 2 changed the incidence of PE. A reduction in ovarian weights and incidence of ovulation at 100 days of age supported cycle data in that only one out of 25 androgenized rats showed ovulation, compared with 16 of 22 controls. At approximately 115 days of age 2 μg of estradiol benzoate were administered for 3 days and 0.5 mg progesterone given on the 4th day 4 hr prior to placing females with sexually vigorous males. T₄-TP females exhibited higher (< .01) median lordosis scores than their S-TP littermates. The latter results were replicated in a second test conducted 10 days later (p = .002). In addition, the second test indicated that the S-TP group had lower (p = .005) lordosis scores than littermates given only TP neonatally. The results of these studies demonstrate that pretreatment with T₄ and handling, which are known, respectively, to hasten and retard the chronology of brain maturation, can exert differential effects on behavioral manifestations of postnatal TP without modifying androgen-induced sterility.     

Abnormal development of blood pressure and growth in rats exposed to perinatal injection stress

Subcutaneous injections of alkaline saline were made perinatally in Sprague-Dawley rats according to two schedules. In a pre-/postnatal group, dams were treated from 19th gestational day to 9th day postpartum and pups from day 0–9. In a postnatal group, pups alone were injected from day 0–6. At 19–23, 50–56 and 82–86 days of age, injected rats and uninjected controls were anesthetized and arterial blood pressure measured. Rats from the pre-/postnatal group had higher blood pressures (58%) and body weights at 19–23 days and lower blood pressure (35%) and body weight at 82–86 days of age. Blood pressure and body weight were comparable to control at all ages in the postnatal injection group. It is concluded that as a result of the maternal stress produced by the injections there was a generalized disturbance of growth processes resulting in hypotension and decreased body weight in adulthood.