Effects of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) administration in prenatal stage on the dopamine system in the postnatal mouse brain.

A dopaminergic neurotoxin, 1-methyl-4-phenyl-1,2,3,6-tetrahydro-pyridine (MPTP), administered to a pregnant female was found to affect postnatally the catecholamine metabolism of the pups. MPTP (5 mg/kg body weight/day) was administered to pregnant C57 Black BYA mice daily for 7 days between the 12th and 18th day of gestation. Dopamine levels and tyrosine hydroxylase (TH) activity were measured in the whole brain from the pups sacrificed after birth. In MPTP-treated pups at 7 days of age, TH total activity (TH activity/brain) did not change (92% of the control value), while TH specific activity (TH activity/mg protein) was increased to 163% of that in control mice. Thus, TH homospecific activity (TH activity/mg TH protein) doubled compared to the control mice. At 28 days of age, both the total activity and the specific activity of TH in the brains of postnatal mice were reduced to 50% and 78% of the control, respectively. Dopamine concentration in the striatum was also reduced significantly. Reduction in the TH activity and dopamine concentration were also observed at the age of 12 weeks. These data suggest that the prenatal exposure to MPTP induced a prolonged reduction of TH activity in the brains of mice with a transient increase of TH homospecific activity during the postnatal period.     

MOUSE BRAIN TYROSINE HYDROXYLASE AND GLUTAMIC ACID DECARBOXYLASE FOLLOWING TREATMENT WITH ADRENOCORTICOTROPHIC HORMONE, VASOPRESSIN OR CORTICOSTERONE

The activities of tyrosine hydroxylase (TH) and glutamic acid decarboxylase (GAD) from several mouse brain regions were assayed following repeated administration of adrenocorticotrophic hormone (ACTH), lysine vasopressin (LVP) or corticosterone. Although similar treatments with ACTH have been shown to result in changes of catecholamine turnover and GABA content, no changes in the activity of either TH or GAD were observed in any brain region. Likewise LVP had no effect on either enzyme. Since the assays for TH were performed with concentrations of tyrosine and tetrahydrobiopterin cofactor below their respective Michaelis constants, this suggests that the changes of catecholamine turnover are not mediated by changes of TH activity. Twice daily corticosterone adrninistration for four days increased TH activity in the hypothalamus but not in any other brain region.     

Maternal diazepam exposure on brain ornithine decarboxylase and growth of offspring

The prenatal treatment of diazepam on the developmental pattern of brain ornithine decarboxylase and the general growth of offspring were studied. Diazepam (120 mg/kg/day) was administered orally to pregnant Sprague-Dawley rats from day 14 to day 20 of gestation. The activity of brain ornithine decarboxylase and body weight of the offspring were measured from the late fetal stage to the early postnatal stage. It was found that diazepam inhibited both the prenatal and 4-hour postnatal ornithine decarboxylase activities, though the general maturation pattern of the enzyme in the brain was not much altered. It may indicate that diazepam inhibits early brain development. The enzyme activity fell off as it reached maturation. Prenatal treated neonates of 6-hour or older age group had the normal activities of brain ornithine decarboxylase. The general growth of the treated offspring was substantially retarded. Their body weights were very much lower than the control offspring. The results of the present study is an additional evidence that diazepam and other benzodiazepines should be used with great care in pregnant women.     

Hydrocortisone modification during intrauterine development of the activity of brain tyrosine hydroxylase in adult white rats

The activity of the key enzyme of catecholamine synthesis, tyrosine hydroxylase (TH), and the level of corticosteroids in blood were estimated in adult white rats in the normal state and after stress after their mothers were treated with hydrocortisone during pregnancy. The disturbance of the balance of corticosteroids during intrauterine development decreases the initial activity of TH in hypothalamus but increases it in the cortex of adult animals. Besides, after stress the increase in the level of corticosteroids in blood is less pronounced but the TH activation in hypothalamus is more distinct. Hence, the increase in the level of corticosteroids during intrauterine development induces long-term changes in the TH activity in brain which may be one of the causes of decrease in reactivity of adult animals after stress.     

Ontogenesis of Monoamine-Synthesizing Enzyme Activities and Biopterin Levels in Rat Brain or Salivary Glands, and the Effect of Thyroxine Administration

Neonatal changes in the activities of tyrosine hydroxylase (TH) and tryptophan hydroxylase (TrpH) and in the content of the co-factor, biopterin, were studied in rat midbrain for the first 20 days after birth. Changes in TH activity in the parotid and submandibular glands were also examined. Changes in TH activity per unit weight in the developing rat brain were briefly similar to those in the salivary glands; the activity increased from day 2 or 4 to day 9 after birth, and remained constant or slightly decreased at day 12, then rapidly increased on day 16. TrpH activity in the midbrain increased about twofold up to day 16. The biopterin concentration in the brain increased, reached a maximum level on day 12 after birth, and thereafter decreased. The effect of hyperthyroidism in rats given 0.2 mg/kg i.p. of thyroxine every 2 days postnatally was studied on the activity of TH in rat salivary glands at 12-day-old rats. In parotid or submandibular gland of hyperthyroid rats, TH activity increased at day 12 postnatally. In comparison with the effect on TH activity in the salivary glands, TH activity in the midbrain on day 20 postnatally was not induced by hyperthyroidism. Furthermore, increase of the TrpH activity and biopterin and catecholamine levels in the midbrain of hyperthyroid rats was not found on day 20 after birth in comparison with the corresponding controls. From these data, we suppose that postnatal hyperthyroidism may cause precocious induction of TH in rat salivary gland, but may not increase the activity of TH or TrpH, and the level of their co-factor, biopterin, in rat midbrain.     

Cretinism: influence on rate-limiting enzymes of amine synthesis in rat brain.

The effect of neonatal hypothyroidism on tyrosine hydroxylase (TH) and tryptophan hydroxylase (TPH) activity, as well as on water content, was studied in different regions of the developing rat brain. Neonatal hypothyroidism, induced by daily treatment with propylthiouracil starting at birth, led to a cretinoid syndrome with a marked impairment of body and brain growth. Compared to control littermates, 30- and 45-day-old cretinous rats had elevated levels of water in the brain stem. The activities of TH and TPH were increased in a time-dependent manner in the brain stem, basal ganglia and hypothalamus of maturing cretinous animals. The increased activity of these rate-limiting enzymes of mono-amine synthesis may account for the elevated levels of brain norepi-nephrine and serotonin in rats subjected to neonatal hypothyroidism.     

Influence of prenatal stress on the rat hypothalamic-pituitary-adrenal axis activity: the role of the brain glycocorticoid receptors

The effects of prenatal stress on the hypothalamic-pituitary-adrenal (HPA) axis activity and brain glycocorticoid receptors were studied in neonatal male and female offspring, as well as the influence of neonatal glycocorticoid receptors blockade on hormonal stress reactivity of adult rats. The results showed that there were sexual differences in plasma corticosterone level and corticosteroid binding in the cortex and hypothalamus of 5-day old control rats. Prenatal stress increased basal level of corticosterone in female rats, decreased corticosterone binding in hypothalamus and hippocampus of male and female rats, and increased corticosteroid receptor level in the male cortex. Neonatal administration of glycocorticoid receptor antagonist did not change plasma corticosterone level in 5-day old rats, but prolonged hormonal stress response of the HPA axis in adult male rats and increased hormonal stress response in female ones. The character of the IIPA axis activity of male and female rats with neonatal blockade of glycocorticoid receptors correspond to hormonal stress response of prenatal stressed rats. These data suggest that change of brain glycocorticoid receptors function in neonatal period of development might be one of the mechanisms of prenatal stress influence on the HPA axis activity in the adulthood.     

Influence of environmental enrichment and handling on the acute stress response in individually housed mice

In this study we investigated the effect of environmental enrichment and handling on the acute physiological stress response caused by short periods of restraint in individually housed female mice. Heart rate (HR) and body temperature (BT) were measured by radiotelemetry and compared with plasma corticosterone (pCORT) levels. Also, postmortem thymus weight and tyrosine hydroxylase (TH) activity were assessed. The acute stress response was seen in both HR and BT. Enrichment and handling were found to increase rather than decrease this stress response, but pCORT values, measured 90 min after restraint, suggested a lower stress response in the enriched groups. No effect was found with thymus weight or TH as parameters.     

State of the Na+, K+-ATPase system of the female rat brain cerebral cortex in the postnatal period during ethanol consumption in pregnancy and lactation

The ontogenetic development of the rat brain cortex Na+, K(+)-ATPase and Mg(2+)-ATPase activities under female ethanol (20% v/v) consumption in the third trimester of gestation or in postpartum period was studied. The weight characteristics (body, whole brain and cortex weight) of viable rats on the first day after birth were not affected critically by prenatal alcohol exposure. It is revealed that the delay of postnatal rat growth 10 days after birth under translactational ethanol consumption is accompanied by reliable decrease of plasma membrane Na+, K(+)-ATPase activity in comparison with control animals. The comparable decrease in activities was observed for the ouabain-sensitive and ouabain-resistant Na+, K(+)-ATPase components (isoform species). From the 20th day the differences in enzyme activity were not revealed. Mg(2+)-ATPase increases in postnatal period independent of Na+, K(+)-ATPase activity and it remains insensitive to postnatal maternal alcohol intake. It is suggested, the first ten day period of lactation is critical for ethanol effect on the developmental control of the brain Na+, K(+)-ATPase functional expression and the course of adaptive processes in the rat organism.     

The effects of exogenous cortisone acetate on development (especially skeletal development) and on circulating levels of corticosteroids in chick embryos.

Chick embryos were treated with cortisone acetate on day 8 of incubation and the subsequent growth of the whole embryo and the development of the tibia studied to day 18 of incubation. Cortisone, at 10 ng to 2 mg/embryo decreased general body growth; above 0.5 mg/embryo it also retarded morphogenesis by as much as 3 Hamilton-Hamburger stages; and above 1 mg/embryo gross abnormalities were produced. The growth and differentiation of the tibia were affected to a greater extent than was the whole body. The reductions in tibial and total body weight were not linearly related to dose of cortisone injected. The exogenous cortisone acetate resulted in drastic alterations in the circulating levels of cortisone, cortisol, corticosterone, and progesterone, but plasma progesterone level was most readily correlated with the growth retardation. This study emphasizes that avian embryos can readily compensate for exogenous corticosteroids and that caution must be exercised when attributing causality to the substance administered.     

Effects of steroid hormones on total brain Na(+)-k+ ATPase activity in Oreochromis mossambicus

The effects of administration of cortisol, corticosterone, testosterone, progesterone and a synthetic estrogen. diethylstilbestrol (DES) on total brain Na(+)-K+- ATPase were investigated in tilapia, O. mossambicus. Exogenous administration of 0.125 and 0.25 microg/g body weight of glucocorticoids and 0.125, 0.25 and 0.5 microg/g body weight of DES for 5 days significantly stimulated Na+(-) K+ ATPase activity by 14-41% in the brain, while 0.5 microg/g body weight of glucocorticoids did not evoke any response on the activity of the enzyme. Progesterone (0.125 and 0.25 microg/g body weight) administration significantly decreased the enzyme activity by 21-36% and high dose (0.5 microg/g body weight) was ineffective. Testosterone exhibited a biphasic effect on Na(+)-K+ ATPase activity--a low dose stimulated by 14% while middle and high doses inhibited it by 19-24%. The results seem to be the first report on the effect of steroids on brain ATPase activity in a teleost. When 0.25microg/g body weight of actinomycin D or puromycin was administered prior to the treatment of similar doses of hormones, the inhibitors significantly inhibited the effect of the hormones by 24-52%. This clearly shows that the effect of the hormones was sensitive to the action of inhibitors suggesting a possible genomic mode of action under long-term treatment. The results suggest that cortisol, corticosterone and DES may possibly stimulate the co-transport of glucose and excitation of membrane potential while progesterone and testosterone inhibit them in the brain of O. mossambicus by regulating the activity of Na(+)-K+ ATPase.     

Effect of testosterone on adrenal corticosteroidogenesis in lithium treated male rats

Lithium chloride at a dose of 200 micrograms/100 g body weight/day given for 21 days caused a significant increase in adrenal weight, adrenal 5-ene-3 beta-hydroxysteroid dehydrogenase (5-ene-3 beta-HSD) activity along with elevation in serum level of corticosterone on the 22nd day in the rat. Administration of testosterone for the last 14 days to lithium treated rats caused a significant decrease in adrenal weight, adrenal 5-ene-3 beta-HSD activity and serum level of corticosterone in comparison to lithium treated animals.     

Temporal Synergism of Corticosterone and Prolactin in the Syrian Hamster, Mesocricetus auratus

To augment the limited work reported in the literature regarding testing of the hormonal temporal synergism hypothesis in Syrian hamsters (Joseph MM, Meier AH. Proc Soc Exp Biol Med. 1974;146:1150-5), a large experiment with female hamsters was conducted. Forty-eight received corticosterone at 18:00 h on January 21, 23, 25, 27, and 29 and ovine prolactin at one of six times of day beginning January 22 for 8 days; 36 received saline (at 18:00) and prolactin at one of the six times of day for 8 days; 35 received only prolactin at one of the six times of day for 8 days; and 16 received no injections. Twelve hamsters receiving corticosterone and prolactin and eight uninjected hamsters were on running wheels. The corticosterone and prolactin group not on wheels had a body weight gain and no circadian rhythm of weight gain, but did have circadian rhythms of response in organ weight, per 100 g of body weight, and in weights of fat pads and uteri. The corticosterone and prolactin group with access to running wheels gained in body weight and had larger ovaries and smaller fat pads. Hamsters receiving saline and prolactin had a body weight gain, but had no circadian rhythms of response in organ weights. The hamsters receiving only prolactin gained in body weight but had no rhythms of response, except for unexpected circadian rhythms in body weight gain and weights of fat pads. The uninjected hamsters had a modest weight gain. Most or all hamsters with access to running wheels freeran, and the corticosterone injections did not appear to synchronize the locomotor activity rhythms. In conclusion, corticosterone does interact with the injection time effect of prolactin on weights of fat pads, paired ovaries, and uteri. The mechanism of that effect, in terms of circadian rhythm theory, is unclear.     

Temporal Synergism of Corticosterone and Prolactin in the Syrian Hamster,Mesocricetus auratus

To augment the limited work reported in the literature regarding testing of the hormonal temporal synergism hypothesis in Syrian hamsters (Joseph MM, Meier AH. Proc Soc Exp Biol Med. 1974;146:1150-5), a large experiment with female hamsters was conducted. Forty-eight received corticosterone at 18:00 h on January 21, 23, 25, 27, and 29 and ovine prolactin at one of six times of day beginning January 22 for 8 days; 36 received saline (at 18:00) and prolactin at one of the six times of day for 8 days; 35 received only prolactin at one of the six times of day for 8 days; and 16 received no injections. Twelve hamsters receiving corticosterone and prolactin and eight uninjected hamsters were on running wheels. The corticosterone and prolactin group not on wheels had a body weight gain and no circadian rhythm of weight gain, but did have circadian rhythms of response in organ weight, per 100 g of body weight, and in weights of fat pads and uteri. The corticosterone and prolactin group with access to running wheels gained in body weight and had larger ovaries and smaller fat pads. Hamsters receiving saline and prolactin had a body weight gain, but had no circadian rhythms of response in organ weights. The hamsters receiving only prolactin gained in body weight but had no rhythms of response, except for unexpected circadian rhythms in body weight gain and weights of fat pads. The uninjected hamsters had a modest weight gain. Most or all hamsters with access to running wheels freeran, and the corticosterone injections did not appear to synchronize the locomotor activity rhythms. In conclusion, corticosterone does interact with the injection time effect of prolactin on weights of fat pads, paired ovaries, and uteri. The mechanism of that effect, in terms of circadian rhythm theory, is unclear.     

Effect of glucocorticoid administration on the rate of muscle protein breakdown in vivo in rats, as measured by urinary excretion of Nτ-methylhistidine

The role of glucocorticoids in regulating the rate of muscle protein breakdown was evaluated by measuring excretion of N(tau)-methylhistidine during administration of various doses of corticosterone to adrenalectomized rats. Groups of rats received daily subcutaneous injections of 0, 0.2, 0.5, 1.0, 5.0 or 10.0mg of corticosterone/day per 100g body wt. for 7 days, followed by 3 days without hormone treatment, after which they were killed. A group with intact adrenal glands served as an additional control. All animals were pair-fed with the untreated adrenalectomized group. No significant differences were noted in growth rate or N(tau)-methylhistidine excretion between the intact or adrenalectomized control groups, or those given 0.2, 0.5 and 1.0mg of corticosterone, whereas growth ceased and N(tau)-methylhistidine excretion rose markedly in the groups receiving 5 and 10mg of corticosterone. After these two high doses of corticosterone, but not after lower doses, there was a loss of weight of the gastrocnemius muscle per 100g of final body wt., but not of the soleus and extensor digitorum longus muscles. The two highest doses of corticosterone also resulted in an increase in liver weight per 100g of final body wt. Lower doses of corticosterone did not cause these changes. Plasma corticosterone concentrations, measured on the final day of injection and again at the time of killing, were decreased to near zero by adrenalectomy and were little raised by doses of 0.2 and 0.5mg daily, but were increased to within the normal range by the 1mg dose. At 5 and 10mg doses, plasma corticosterone concentrations were sustained at 2-3 times those of intact rats, and thus in the range reported for rats exposed to severe stress. Rats given 5 and 10mg doses of corticosterone had glycosuria, and showed considerably elevated concentrations of insulin in the plasma. It is concluded that plasma concentrations of glucocorticoids within the normal range do not regulate the rate of muscle protein breakdown, whereas excessive plasma concentrations of corticosteroids, equivalent to those observed in severe stress, can accelerate muscle protein breakdown.     

Effect of corticosteroids on carbohydrate metabolism in Bufo melanostictus (Schneider)

A single injection of corticosterone (1 or 5 micrograms/50 g body weight) produced a significant elevation in plasma glucose, liver and muscle glycogen contents of B. melanostictus. Single but identical doses of aldosterone had no effect on plasma glucose concentration. Liver and muscle glycogen contents were however significantly augmented. Administration of 1 or 5 micrograms corticosterone and 1 microgram or 200 ng aldosterone/50 g body weight, for 15 days, caused no change in plasma glucose concentration. In all the groups receiving corticosterone or aldosterone for 15 days, liver and muscle glycogen contents significantly increased. The magnitude of increase in liver and muscle glycogen by aldosterone was marginally greater than that by corticosterone. The results suggest that both the corticosteroids may be gluconeogenic in B. melanostictus.     

Fetal brain serotonin synthesis and catabolism is under control by mother intake of tryptophan.

Previous morphological studies reported that serotonergic neurons appear in rats in the second half of prenatal life. Initially the biochemical differentiation of these neurons before birth was studied. Both serotonin (5-HT) and 5-hydroxyindole acetic acid (5-HIAA) was detected in the fetal brain on day 15 of gestation. During prenatal development an increase was detected in the brain levels of 5-HT (200% higher on day 19 than on day 15) and 5-HIAA (700% higher on day 19 than on day 15). Oral administration of tryptophan to pregnant rats induced a dose-related increase of tryptophan concentration in different fetal tissues, including brain. The increase in tryptophan tissue concentration was detected for low doses (50 mg/kg) and remained unsaturated after administration of high doses (1000 mg/kg). This observation suggests that the placental barrier is not effective to block the influx of high levels of tryptophan to the fetus. Tryptophan concentration in the brain is 300% higher than in the carcass and 600% higher than in the placenta. These data suggest a mechanism to assume a role in concentrating of tryptophan in the brain. Finally, it was found that an increase in brain tryptophan induced changes in both serotonin and 5-HIAA brain levels, but did not modify tyrosine, dopamine or norepinephrine levels. Thus, under physiological conditions, tryptophan hydroxylase activity in prenatal brain is probably not saturated by its substrate tryptophan.     

Feedback inhibition of adrenocorticotropin release by corticosterone infusions in the adrenalectomized rat.

Advantage was taken of a specific and sensitive bioassay for rat plasma adrenocorticotropin (ACTH) based on the dispersion of rat adrenal cells with trysin, to investigate the relationship between plasma corticosterone concentration and inhibition of ACTH release under steady-state conditions achieved by graded rates (0-5.12 mug/min per 100 g body weight) of intravenous infusion of the steroid for 45 min in 28-day adrenalectomized rats. In contrast to prior reports involving suppression of stress-induced ACTH release, the inhibitory effect of corticosterone was shown, under our experimental conditions, to be exerted also on the basal rate of ACTH secretion. Indeed, a slight though not significant decrease of plasma ACTH concentration was observed with the corticosterone infusion rate of 0.64 mg/min per 100 g body weight, and further progressive and highly significant drops in concentration were recorded for infusion rates of 2.56 and 5.12 mg/min per 100 g body weight. An increase of the metabolic clearance rate of corticosterone, observed as a function of the infusion rate, was ascribed to saturation by the steroid of the plasma transcortin binding sites.     

Influence of ACTH secreting tumor (MtTF4) on fetal rat adrenal gland steroidogenesis in vitro in prolonged pregnancy

Pregnant female rats with ACTH secreting tumor (MtTF4) have prolonged pregnancy and cannot deliver. The fetuses of tumor bearing females have in prolonged pregnancy on days 24 and 25 of pregnancy greater body weight and smaller adrenal weight as compared to intact fetuses of the 22nd day of pregnancy. The fetal adrenal glands converted to vitro 4-14C progesterone to radioactive 11-deoxycorticosterone (DOC), corticosterone (B), 18-hydroxy-11-deoxycorticosterone (18-OH-DOC), 18-hydroxy-corticosterone (18-OH-B) and aldosterone. Fetal adrenal glands in prolonged pregnancy synthetized in vitro less amount of radioactive DOC, B and 18-OH-DOC. A negative relationship exists between the maternal corticosterone which passes the placenta to fetuses and corticosteroidogenesis of fetal adrenal glands. These results indicate the possibility that fetal rat adrenal glands with their corticosteroids participate in pregnancy and influence normal delivery.     

Tyrosine hydroxylase activity and expression of its gene in mice with contrasting capacity to dominate in social stress]

Changes of tyrosine hydroxylase (TH) activity and level of mRNA of TH gene in PT and CBA/Lac mouse strains, which are contrast by ability to dominate in heterogenous populations, were investigated. It was established, that the activity of TH both in dominate PT and subordinate CBA/Lac mice in hypothalamus, hippocampus and brain stem elevated in one hour after forming of micropopulations. But the appearance of this increase was different: activation of TH in hypothalamus and brain stem of PT mice was stronger then one in CBA/Lac mice. Moreover, the beginning of the reaction in brain stem of PT mice was earlier then that of CBA/Lac mice. MRNA level of TH gene in hypothalamus and brain stem in one hour was elevated only in PT mice for 50% and 200%, respectively. No changing in expression TH gene was found in hippocampus. In conclusion, it was suggested that the activation of catecholamine biosynthesis under social stress in hypothalamus and brain stem of male mice was due to the TH activation and increase of its gene expression.