Permanent neuronal deficits in rats exposed to alcohol during the brain growth spurt

The purpose of this study was to determine whether developmental alcohol exposure could induce permanent neuronal deficits, whether the peak blood alcohol concentration (BAC) influences the severity of the effects, and whether the effects are gender related. Rat pups were reared artificially over postnatal days (PD) 4 through 11 (a period of rapid brain growth, comparable to part of the human third trimester). Alcohol treatments were administered on PD 4 through 9. Patterns of alcohol exposure that produce different peak BACs have been shown to affect differentially the amount of brain weight deficits and neuron loss shortly after the exposure period, so this study investigated whether the pattern of alcohol exposure was also effective in producing permanent deficits. Two groups received a daily alcohol dose of 4.5 g/kg, condensed into either four or two feedings. A third group received a higher daily alcohol dose of 6.6 g/kg administered in 12 uniformly spaced daily feedings. Pups were fostered back to dams on PD 11 and perfused on PD 90. Brain weights were measured, and Purkinje cells and granule cells were counted in each of the 10 lobules of the cerebellar vermis. In the hippocampal formation, cell counts were made of the pyramidal cells of fields CA1 and CA2/3, the multiple cell types of CA4 and the granule cells of the dentate gyrus. The groups receiving the lower daily dose (4.5 g/kg) condensed into either four or two feedings were exposed to higher peak BACs and suffered significant permanent brain weight deficits and neuronal losses, relative to controls. The group receiving the higher daily dose (6.6 g/kg) in continuous fractions had no significant brain weight reductions or neuronal loss. Vulnerability to alcohol-induced neuronal loss varied among regions and cell populations and as a function of peak BAC. In the hippocampus, only the CA1 pyramidal cells were significantly reduced in number and only in group receiving the most condensed alcohol treatment. In the cerebellum, the severity of Purkinje cell and granule cell losses varied among lobules, and Purkinje cell vulnerability appeared to depend on the maturational state of the neuron at the time of the alcohol exposure, with the more mature Purkinje cells being the more vulnerable.     

Differential neuronal loss following early postnatal alcohol exposure

Neonatal rats were exposed to 6.6 g/kg of alcohol each day between postnatal days 4 and 10 while artificial-rearing procedures were used, in a manner which produced high peak and low trough blood alcohol concentrations each day. Gastrostomy controls were reared artificially with maltose/dextrin isocalorically substituted for alcohol in the milk formula, and suckle controls were reared normally by dams. The pups were sacrificed on day 10 and tissue sections (2 microns thick) were obtained in the sagittal plane through the cerebellum and in the horizontal plane through the hippocampal formation. Overall area measures were obtained for the hippocampus proper, area dentata, and cerebellum, along with areas of the cell layers of these regions. In the hippocampal formation, cell counts were made of the pyramidal cells of the hippocampus proper, the multiple cell types of the hilus, and the granule cells of the area dentata. In the cerebellum, cell counts of Purkinje cells, granule cells of the granular layer, granule cells of the external granular layer, and mitotic cells of the external granular layer were obtained from lobules I, V, VII, VIII, and IX. Alcohol selectively reduced areas and neuronal numbers in the cerebellum but had no significant effects on neuronal numbers in the hippocampal formation. Purkinje cells exhibited the greatest percent reductions, and cerebellar granule cells were significantly reduced in the granular layer but not in the external granular layer. All lobules showed these effects, but lobule I was significantly more affected than the other four lobules that were analyzed. The results demonstrate the differential vulnerability of selected neuronal populations to the developmental toxicity of alcohol exposure during the brain growth spurt.     

Brain changes in rats induced by prenatal injection of methylazoxymethanol

Various doses (0, 1, 5, 10, 15, 20, or 25 mg/kg) of methylazoxymethanol acetate (MAM), a potent alkylating agent, were injected singly into pregnant rats intraperitoneally on day 15 of gestation. Relationships between brain weights and neurochemical changes in the cerebral hemispheres (CHs; cerebral cortex and subjacent white matter, hippocampus, amygdala) and remainder of the brain (BGDM; basal ganglia, diencephalon, and mesencephalon) were examined at 60 days of age in offspring; varying degrees of microencephaly were observed. Dose-dependent reductions in the weights of CH and BGDM were observed. Reductions in total DNA content positively correlated with decreases in brain weights also observed. Dose-dependent elevations of noradrenaline (NA) and dopamine (DA) were observed in CH at MAM levels 10 mg/kg and above; dose-dependent elevations of 5-hydroxytryptamine (5-HT) were observed at 15 mg/kg and above; and in BGDM at 20 mg/kg and above dose-dependent elevations for NA and 5-HT were observed; dose-dependent elevations at 15 mg/kg and above were observed for DA. Monoamine concentrations were negatively correlated with brain weights or total DNA contents. NA and DA concentrations increased to the extent of approximately 1.3 times of control at a time when an 18% loss of CH weight was noted in animals treated with 10 mg/kg MAM. It is suggested that the above variables might be appropriately sensitive neurochemical markers for detecting minor developmental anomalies in the brain.     

Effects of oral meso-2,3-dimercaptosuccinic acid (DMSA) administration on late gestation and postnatal development in the mouse

The present study was conducted to evaluate the effects of meso-2,3-dimercaptosuccinic acid (DMSA) on late gestation and postnatal viability and growth in the mouse. DMSA was given po to four groups of pregnant Swiss mice at 0, 200, 400, and 800 mg/kg/day from day 14 of pregnancy until postnatal day 21. At birth, the following data were recorded: length of gestation, number of live, dead, and abnormal pups, sex, and individual pup weights. Each pup was weighed again on day 4, 14, and 21 of lactation. Pinna detachment, incisor eruption and eye opening were also monitored. No treatment-related signs of toxicity were noted in any of the dams during the study. No adverse effects on offspring survival or development were evident in the 200 or 400 mg DMSA/kg/day groups. However, on days 14 and 21 of lactation a significant decrease in pup body weight was observed in the 800 mg/kg/day group. Also, a significant increase in the relative weight of the brain was seen in this group. The "no observable effect level" (NOEL) for health hazards to the developing pup was greater than 400 mg/kg/day. This dose is higher than the amounts of DMSA usually given in the treatment of human heavy metal intoxications.     

Juvenile toxicity assessment of open-acid lovastatin in rats

BACKGROUND: Lovastatin, an inhibitor of 3‐hydroxy‐3‐methylglutaryl‐coenzyme A reductase, reduces de novo cholesterol biosynthesis primarily in the liver. Since cholesterol is a major component of brain myelin and peak periods of brain myelination occurs after birth, this study was designed to encompass this period in rats and evaluate the potential neurotoxic effects. METHODS: The pharmacologically active, open‐acid form of lovastatin was administered to groups of 50 Sprague–Dawley rats per sex subcutaneously once daily at dose levels of 0 (vehicle), 2.5, 5, or 10 mg/kg/day beginning on postnatal day 4 and continuing until termination on postnatal day 41 to 51. Physical signs and body weights were monitored during the study. Animals were assessed in a battery of behavioral tests, and at termination a set of animals were examined for gross and histological changes. RESULTS: There were no test article‐related deaths, physical signs, or effects on preweaning and postweaning body weights during the study. In the behavior tests there were no test article‐related effects in the passive avoidance, auditory startle habituation, open‐field motor activity, or FOB. No test article‐related postmortem findings were observed, including brain weights and histomorphology of brain, spinal cord, eye, optic nerve, or peripheral nerve. CONCLUSION: Based on these results, the no‐effect level for general and neurobehavioral toxicity in neonatal rats was ≥10 mg/kg/day for open‐acid lovastatin. Birth Defects Res (Part B) 92:314–322, 2011. © 2011 Wiley‐Liss, Inc.     

Maternal Alcohol Consumption Increases Sphingosine Levels in the Brains of Progeny Mice

The effect of ‘binge’ alcohol upon sphingolipid metabolism in the fetal alcohol syndrome (FAS) was examined in pregnant mice (C57BL/6J) by administering a single dose of alcohol during the third trimester (gestational day 15–16). The control mice were administered a sucrose solution of equal caloric value. Brains from progeny at postnatal days 5, 15, 21 and 30 were dissected into three regions, and sphingolipid concentrations of the brain regions were determined including assay of monoglycosylceramide, ceramide, sphingosine and sphingomyelin. We found that a single dose of ethanol induces an elevation of sphingosine (2–3.5-fold) in the brain of progeny. The level of brain ceramide at a dose of 1.5 g/kg was significantly higher than control. Alcohol consumption during pregnancy induces neuronal loss in progeny brains. Our result suggests that the elevation of sphingosine in progeny brain induced by maternal alcohol consumption may be responsible for observed neuronal loss in FAS. Special issue in honor of Naren Banik.     

Amphetamine treatment during early postnatal development transiently restricts somatic growth

AimsRestricted somatic growth during fetal or early postnatal periods has been suggested to serve as a predictive indicator for neuroanatomical changes and behavioral impairments during adulthood. Here, the effects of d-amphetamine sulfate (AMPH) exposure during the brain growth spurt period on this potential indicator were evaluated.Main methodsRats received 0, 5, 15 or 25 mg/kg/day of AMPH via two daily intragastric intubations from PD4-9. Body weight data were collected every other day from PD1 to 21, and then weekly until PD59. On PD9, a subset of animals was terminated 90 min after the last amphetamine treatment and the weights of the cortex, cerebellum, and brainstem were collected. Weights of these brain regions from young adult rats were also assessed on PD68.Key findingsAMPH exposure during early postnatal development limited somatic growth in a dose-related manner, with significantly lower body weights in animals assigned to the AMPH 25 and AMPH 15 groups. However, this was transient in nature, with no significant difference in weight observed after pups were weaned on PD21. Further, no differences in brain weight were observed at either age as a result of AMPH exposure.SignificanceThese findings support the idea that developmental AMPH exposure transiently restricts somatic growth. Moreover, the lack of effect on brain weight shows that AMPH differentially affects somatic and brain growth. The current findings suggest that in addition to the immediate effects on body weight, amphetamine may alter the rate of growth, and increase the risk for weight-related adult diseases.     

Dose- and duration-dependent alterations by tellurium on lipid levels: differential effects in cerebrum,cerebellum, and brain stem of mice

The effect of various doses of sodium tellurite (1/50 LD50=0.4 mg/kg, 1/25 LD50=0.8 mg/kg, and 1/10 LD50=2.0 mg/kg body weight orally) on the lipid levels (cholesterol, triglycerides, phospholipids, esterified fatty acids, gangliosides, and total lipids) in the cerebrum, cerebellum, and brainstem of male albino mice was studied after 7 and 15 d of treatment. Sodium tellurite (2.0 mg/kg body weight) for 7 d has an apparent effect on the depletion of cholesterol, triglycerides, phospholipids, esterified fatty acids, and total lipids. The cholesterol content was decreased significantly in the cerebrum, cerebellum, and brainstem after 7 d of treatment with a 2.0-mg/kg dose compared to the control. On the other hand, treatment for 15 d with doses of 0.4, 0.8, and 2.0 mg/kg body weight resulted in a significant and dose-dependent increment in cholesterol level in the cerebrum, cerebellum, and brainstem. The triglycerides content was decreased significantly in the cerebrum, cerebellum, and brainstem with the 2.0-mg/kg dose after 7 d of treatment. The doses of 0.4, 0.8, and 2.0 mg/kg orally for 15 d resulted in a significant and dose-dependent depletion of triglycerides in the cerebrum, cerebellum, and brainstem. All the doses of tellurium (0.4, 0.8, and 2.0 mg/kg) both for 7 and 15 d have depleted the level of phospholipids in varying degrees of significance in the cerebrum, cerebellum, and brainstem. However, the level of esterified fatty acids was decreased significantly with the 2.0-mg/kg dose of tellurium for 7 d but increased with the 0.4-mg/kg dose for 15 d in the cerebrum and cerebellum. The level of gangliosides was depleted in the cerebrum but elevated in the cerebellum and brainstem after receiving a 2.0-mg/kg dose of sodium tellurite for 7 d. The content of gangliosides was increased with doses of 0.4 and 0.8 mg/kg but decreased with 2.0 mg/kg for 15 d in the cerebrum, cerebellum, and brainstem. The total lipids content was depleted significantly and dose dependently after 7 and 15 d of treatment in the cerebrum, cerebellum, and brainstem. These results suggest that sodium tellurite affects the lipids content differentially in various parts of the mice brain.     

Dose–Response Effects of Diphenylhydantoin on Pregnant Dams and Embryo‐Fetal Development in Rats

Despite the widespread use of diphenylhydantoin (DPH), there is a lack of reliable information on the teratogenic effects, correlation with maternal and developmental toxicity, and dose–response relationship of DPH. This study investigated the dose–response effects of DPH on pregnant dams and embryo‐fetal development as well as the relationship between maternal and developmental toxicity. DPHwas orally administered to pregnant rats from gestational days 6 through 15 at 0, 50, 150, and 300 mg/kg/day. At 300 mg/kg, maternal toxicity including increased clinical signs, suppressed body weight, decreased food intake, and increased weights of adrenal glands, liver, kidneys, and brain were observed in dams. Developmental toxicity, including a decrease in fetal and placental weights, increased incidence of morphological alterations, and a delay in fetal ossification delay also occurred. At 150 mg/kg, maternal toxicity manifested as an increased incidence of clinical signs, reduced body weight gain and food intake, and increased weights of adrenal glands and brain. Only minimal developmental toxicity, including decreased placental weight and an increased incidence of visceral and skeletal variations, was observed. No treatment‐related maternal or developmental effects were observed at 50 mg/kg. These results show that DPH is minimally embryotoxic at a minimal maternotoxic dose (150 mg/kg/day) but is embryotoxic and teratogenic at an overt maternotoxic dose (300 mg/kg/day). Under these experimental conditions, the no‐observed‐adverse‐effect level of DPH for pregnant dams and embryo‐fetal development is considered to be 50 mg/kg/day. These data indicate that DPH is not a selective developmental toxicant in the rat.     

Neurotoxicological Examination of the Piglet Brain after Prenatal and Postnatal Exposure to Trichlorfon

Piglets were given 10 repeated doses of the orga-nophosphorus compound trichlorfon during the postnatal period in order to examine the effect on the brain development (Experiment 1). Following prenatal exposure to trichlorfon, the ability of a presumptive hypoplastic cerebellum and cerebrum at birth, to regenerate postnatally was investigated (Experiment 2). Administration of repeated doses of trichlorfon postnatally was accompanied by only small changes in brain weights, morphology and transmitter enzyme activity (choline acetyltransferase, glutamate decarboxylase, aromatic amino acid decarboxylase) in 35 days old piglets. Animals exposed prenatally, and sacrificed at the age of 35 days, showed a significant increase in brain weights and enzyme activities. The animals did, however, not reach control values in cerebral weight, cerebellar weight or total enzyme activities. Morphological changes still showed regional loss of Purkinje cells in the cerebellum. The study clearly indicated that the pig brain was less vulnerable to trichlorfon in the postnatal period of development than when exposed to the compound prenatally.     

Lysosomal Acid Hydrolases in Developing Huml Brain Regions

beta-D-Glucosidase, beta-D-glucosaminidase, acid phosphatase, and beta-D-galactosidase were monitored in the human foetal brain at different gestational periods. Glucosidase specific activity in all brain regions exhibits two peaks, at 8 g and 32 g foetal weights. Acid phosphatase exhibits very high specific activity in all brain regions at 5 g, but the cerebellar activity forms a peak at 220 g foetal weight, the midbrain at 135 g, and the spinal activity at 760 g. beta-D-Glucosaminidase has a peak at 220 g and 660 g in the midbrain, and beta-D-galactosidase specific activity is highest in the cortex and cerebellum in late gestation (neuronal differentiation phase). The midbrain medulla and the spinal cord show peak activity at 8 g and 220 g foetal weight. The results suggest an inter- and intraregional heterogeneity of acquisition for these enzymes in human brain ontogeny.     

A reproductive and developmental screening study of the fungal toxin ochratoxin A in Fischer rats

The presence of the mycotoxin ochratoxin A (OTA) in cereal grains is due to the growth of toxigenic Penicillium mold on stored crops. Human exposure to OTA is higher in infants, toddlers, and children than in adolescents and adults, based on exposure assessments of ng OTA consumed/kg body weight/day. Ochratoxin A is nephrotoxic and teratogenic in animals, but its effects on juveniles exposed during the reproduction and development period have not been studied. To address this, Fischer rats were exposed to 0, 0.16, 0.4, 1.0, or 2.5 mg OTA/kg diet throughout breeding, gestation, and lactation and its adverse effects were assessed in adult rats and their offspring on postnatal day (PND) 21. There were no effects on implantation but post-implantation fetotoxicity was observed in the 2.5 mg/kg dose group, corresponding to a calculated dose of 167.0 μg/kg bw/day in dams. Adverse effects on body and kidney weights and on clinical parameters indicative of renal toxicity were significant in adult rats exposed to 1.0 mg OTA/kg diet (55.2 and 73.3 μg/kg bw/day in adult males and females, respectively) and in PND21 rats at the 0.4 mg/kg dose (33.9 μg/kg bw/day in dams), suggesting that weanling rats were more sensitive to OTA than adults. Overall, nephrotoxicity was the primary effect of OTA in weanling rats exposed throughout gestation and lactation at sub-fetotoxic concentrations in diet.     

Serum bilirubin levels in breast- and formula-fed infants in the first 5 days of life.

A prospective study was conducted in a level II maternity unit to investigate the incidence of hyperbilirubinemia in healthy, term, breast-fed and formula-fed infants. Serum bilirubin levels were determined for 176 breast-red and 164 formula-fed infants in cord blood and on days 1, 2, 3 and 5 after birth. The mean total bilirubin levels were significantly higher on each postnatal day in the breast-fed infants, as was the proportion of infants with peak levels above 12 mg/dl (205 mumol/l; 28% v. 6%). The breast-fed infants also had significantly higher proportional weight losses on each postnatal day than the formula-fed infants. However, there was no correlation between the cumulative weight loss on day 3 and bilirubin levels on the same day with either feeding regimen. None of the infants required an exchange transfusion or prolonged care in hospital for hyperbilirubinemia.     

Results of the negative control chemical allyl alcohol in the 15-day intact adult male rat screening assay for endocrine activity

Development, standardization, and validation of methods to assess the potential of chemicals to disrupt hormonal homeostasis have been the focus of considerable research efforts over the past 10 years. As part of our validation effort, we evaluated the specificity of the 15-day intact adult male rat assay, using a negative control chemical, allyl alcohol, a known hepatotoxicant that was not expected to induce endocrine effects. Male rats were dosed for 15 days via oral gavage with 0, 10, 30, 40, or 50 mg/kg/day allyl alcohol. The endpoints evaluated included final body and organ weights, serum hormone concentrations, and a limited histopathology assessment. No mortality or adverse clinical signs were observed. Mean final body weight for rats in the 50-mg/kg/day dose group was decreased to 90% of control. Mean relative liver weights were increased at 40 and 50 mg/kg/day (115% and 117% of control, respectively). Serum testosterone and DHT concentrations were statistically significantly decreased at 50 mg/kg/day (72% of control). Serum prolactin concentrations were statistically significantly decreased at 40 mg/kg/day (58% of control), but not at 50 mg/kg/day. There were no effects on the other endpoints evaluated. Consistent with previous guidance for interpreting the 15-day intact adult male rat assay, histological and weight changes of target organs were given a higher weight-of-evidence than changes in serum hormone concentrations alone. Therefore, with only minimal changes in serum hormone concentrations and no effects on organ weights or microscopic alterations, the results of allyl alcohol in the 15-day intact adult male rat assay were considered negative and consistent with the predicted results.     

Effect of alcohol and kolanut interaction on brain sodium pump activity in Wistar Albino rats.

Effect of alcohol-kolanut interaction on Sodium Pump activity in wistar albino rats was studied. Thirty wistar albino rats were divided into six groups of five (5) rats per group and used for the study. The control group (1) received via oral route a placebo (4ml of distilled water). Groups 2 to 6 were treated for a period of 21 days, with (10% v/v) of alcohol (group 2), 50mg/kg body weight of kolanut (group 3), 50 mg/kg body weight of caffeine (group 4), 4ml of 10% v/v of alcohol and 50 mg/kg body weight kolanut (group 5), 4ml of 10% v/v of alcohol and 50 mg/kg body weight of caffeine in 4.0ml of the vehicle via gastric intubation respectively. A day after the final exposure, the brain of each rat was harvested and processed to examine several biochemical parameters, i.e., total ATpase, ouabain-insensitive ATpase, ouabain sensitive ATpase (Na(+)-K(+)ATPase), non-enzymatic breakdown of ATP and inorganic phosphate (Pi) released. The results showed that the essential enzyme of the brain responsible for neuronal function, Na(+)-K(+)ATPase, was inhibited by alcohol-kolanut co-administration relative to control, resulting in a decrease in Na(+)-K(+)ATPase activity, ATP production, ion transport and action potential, leading to loss of neuronal activities.     

Fetal dexamethasone exposure alters macromolecular characteristics of rat brain development: a critical period for regionally selective alterations?

Fetal glucocorticoid exposure retards postnatal growth and evokes abnormalities of nervous system structure and function. To examine the underlying mechanisms, we administered 0.2 or 0.8 mg/kg of dexamethasone to pregnant rats on gestational days 17, 18, and 19 and assessed brain region cell development with indices of DNA content (total cell numbers), DNA concentration (cell packing density), and protein/DNA ratio (relative cell size). Dexamethasone evoked deficits of pup body and brain region weights, but the brain regions displayed growth-sparing associated initially with preservation of cell numbers (normal or elevated DNA content and concentration), at the expense of relative cell size (decreased protein/DNA). Subsequently, brain cell acquisition lagged behind that of controls, with deficits in DNA and elevations of protein/DNA. In midbrain + brainstem and in cerebellum, cell markers returned to normal by weaning. However, the forebrain showed persistent elevations of DNA and reduced protein/DNA, indicative of replacement of neurons with glia. Because the treatment period coincided with the timing of neuronal cell replication in the forebrain, but not in the other regions, these results suggest that the critical period for lasting deficits of dexamethasone coincides with the peak of neuronal mitosis.     

Distinct, Developmentally Regulated Brain mRNAs Direct the Synthesis of Neurotransmitter Transporters

The Xenopus laevis oocyte expression system was utilized to define developmental and structural properties of neurotransmitter transporter mRNAs and the pharmacological characteristics of encoded carriers independent of the complexities of brain tissue preparations. Poly(A)+ RNA from dissected brain regions of neonatal and adult rats was microinjected into Xenopus oocytes and the expression of Na(+)-dependent neurotransmitter transporters determined 48 h later. Transport studies conducted with oocytes injected with RNAs derived from juvenile rat tissues indicate a region- and transporter-specific, postnatal increase in mRNA abundance as a major factor in the developmental changes observed for brain high-affinity amino acid uptake systems. Both L-glutamic acid (Glu) and gamma-aminobutyric acid (GABA) uptake systems were detectable by day 3 in postnatal forebrain mRNA and became progressively enriched during the next 2 weeks of forebrain development. In contrast, brainstem Glu and GABA transporter enrichment was 60-70% of adult values by day 3 and exceeded adult levels by day 10. Parallel determinations of L-glutamic acid decarboxylase mRNA abundance during development argue for distinct regulatory influences on mRNAs directing transmitter synthesis and reuptake. Glycine uptake could not be detected at any point of forebrain development and exhibited a gradual postnatal rise to adult levels over the first 3 postnatal weeks of brainstem development. Uptake studies conducted with well-characterized inhibitors of Glu, GABA, dopamine, and choline transport (D-aspartate, nipecotic acid, nomifensine, and hemicholinium-3, respectively) revealed that oocyte transporters encoded by adult rat brain mRNAs retained antagonist sensitivities exhibited by in vitro brain preparations. In addition, a differential regional sensitivity to the Glu transport antagonist dihydrokainate (1 mM) was observed, lending support to previous reports of region-specific Glu transporter subtypes. To determine the structural diversity present among brain transporter mRNAs, poly(A)+ RNA was size-fractionated on linear (10-31%) sucrose density gradients prior to oocyte injection. These experiments revealed two mRNA size classes (2.4-3.0 kb, 4.0-4.5 kb) independently capable of directing the synthesis of Glu, GABA, and glycine transporters. In regions other than the cerebellum, Glu and GABA transporter activities migrated as single, yet distinct, peaks of 4.0-4.5 kb. In contrast, both Glu and GABA transporters exhibited major peaks of activity at 2.5-3.0 kb with size-fractionated cerebellar mRNA. Brainstem glycine uptake exhibited a broad sedimentation profile, with peaks apparent at 2.4 and 4.0 kb. Taken together, these findings indicate previously unappreciated complexity in mRNA structure and regulation which underlies the expression of amino acid neurotransmitter uptake systems in the rodent CNS.     

Caspase-3 and calpain activities after acute and repeated ethanol administration during the rat brain growth spurt

Ethanol administration during the rat brain growth spurt triggers apoptotic neurodegeneration that appears to be mediated by caspase-3 activation. In order to gain more insight on the role of this caspase in ethanol-induced developmental neurotoxicity, we studied its expression and activity under different conditions of ethanol exposure during development. Furthermore, because of the cross-talk between caspase-3 and calpain we extended our study also at this protease. Ethanol was administered by gavage to rat pups as a single-day exposure on postnatal day (PN) 7 or from PN4 to PN10. Cleaved caspase-3 expression peaked in the cerebral cortex 12 h after ethanol treatment and returned to control values at 24 h. An identical pattern was found for caspase-3-like activity, that was increased only with the highest dose of ethanol tested (5 g/kg) and mostly in PN4. Repeated ethanol exposure, at a dose that was previously found to induce microencephaly, did not increase caspase-3 expression and activity although it decreased procaspase-3 expression and released mitochondrial cytochrome c. Repeated ethanol administration also increased calpain activity. These data show that acute and repeated ethanol administration differentially affect caspase-3 and calpain activity, suggesting that calpain activation may play a role in developmental neurotoxicity of ethanol.     

Melanocortins and opioids modulate early postnatal growth in rats

This study was undertaken to investigate the effects of melanocortins and opioids on rat early postnatal body and organ growth. Among melanocortins tested desacetyl-alpha-melanocyte-stimulating hormone (alpha-MSH) at dosages of 0.3 and 3 micrograms/g/day was effective in stimulating neonatal growth with a weight gain of 7 and 5.6%, respectively, after 2 weeks of treatment. Likewise, a weight rise of 4.2 and 3% was obtained with 3 micrograms/g/day of both alpha-MSH and Nle4-D-Phe7 alpha-MSH. As far as opioids were concerned, while N-acetyl-beta-endorphin (beta-End) was ineffective, the activity of beta-End was dependent on dosage. Indeed, newborns treated with 0.03 microgram/g/day showed a slight, but significant, increase in weight, whereas a marked decrease in growth followed treatment with 0.3 and, mainly, 3 micrograms/g/day, with a final weight loss of 3.4 and 5.5%, respectively. All melanocortins exerted a positive action on muscular and brain trophism and, in addition, desacetyl-alpha-MSH also induced a rise of fat deposits. On the contrary, while the 0.03 microgram/g/day beta-End dose caused an increase in muscular and brain weight, the higher dosages of the opioid were detrimental, not only for muscle and brain, but also for both liver and spleen weight. A slight, although significant (P < 0.05), enhancement of serum dehydroepiandrosterone sulfate (DHEAS) level was found after the injection of 0.3 microgram/g desacetyl-alpha-MSH, whereas both the 0.3 and 3 micrograms/g doses of desacetyl-alpha-MSH and the 3 micrograms/g dose of alpha-MSH determined the rise of plasma androstenedione (P < 0.05). All tested melanocortins and opioids failed to modify the concentrations of corticosterone. Our results suggest that melanocortins and opioids can modulate early postnatal growth in rats either by direct or indirect mechanisms.