Glutamate and N-methyl-d-aspartate binding sites in the guinea pig hippocampus: Ontogeny and effect of acute in vitro ethanol exposure

The objectives of this study were to characterize the ontogeny of the l-glutamate (glutamate) and N-methyl-d-aspartate (NMDA) binding sites in the developing guinea pig hippocampus, and to determine the effect of acute in vitro ethanol exposure on these binding sites. Specific [³H]glutamate binding and NMDA-sensitive [³H]glutamate binding were determined using a guinea pig hippocampal synaptic membrane preparation (HSMP). To characterize the ontogeny of the density (B_max) and affinity (K_d) of the glutamate and NMDA binding sites, saturation analysis was conducted on HSMP of guinea pigs at gestational day (GD) 50 (immature fetus; term, GD 68), GD 62 (mature, near-term fetus), postnatal day (PD) 13 (neonate), and PD > 60 (adult). To examine the effect of ethanol on the glutamate and NMDA binding sites, HSMP of guinea pigs at GD 50, GD 62, PD 13, and PD > 60 was incubated with ethanol (0–100 mM), followed by determination of specific ['H]glutamate binding and NMDA-sensitive [³H]glutamate binding. To determine the effect of 50 mM ethanol on the B_max, and K_d of the glutamate and NMDA binding sites, HSMP of guinea pigs at GD 62 and PD > 60 was incubated with 0 or 50 mM ethanol followed by saturation analysis. The B_max, values of the hippocampal glutamate and NMDA binding sites were greater at GD 62 and PD 13 compared with GD 50 and PD > 60, but there was no change in the K_d of the binding sites throughout development. Ethanol did not alter hippocampal specific [³H]glutamate binding or NMDA-sensitive [³H]glutamate binding at any of the ages studied, and did not alter the hippocampal B_max or K_d of the glutamate or NMDA binding sites at GD 62 and PD > 60.     

In vitro ethanol exposure decreases potassium-stimulated, but not veratridine-stimulated, glutamate release in the guinea pig hippocampus.

In this study we determined the effect of in vitro ethanol exposure on stimulated glutamate release in transverse hippocampal slices (400-microm thickness) of the young postnatal guinea pig (PD 12) by using two chemical stimuli with different mechanisms of action. Ethanol (50 mM) decreased K+ (45 mM)-, but not veratridine (10 microM)-, stimulated glutamate release. The study findings demonstrate that in vitro ethanol exposure produces differential inhibition of stimulated glutamate release in the hippocampus, dependent on the stimulating agent.     

Chronic ethanol exposure alters MK-801 binding sites in the cerebral cortex of the near-term fetal guinea pig.

The mechanism of ethanol central nervous system (CNS) teratogenesis, resulting from chronic maternal ingestion of high-dose ethanol during pregnancy, is not clearly understood. One of the target sites for ethanol-induced damage in the developing brain is the cerebral cortex. It has been proposed that chronic prenatal ethanol exposure alters NMDA receptors in the developing cerebral cortex. To test this hypothesis, timed pregnant guinea pigs were administered one of the following oral treatments throughout gestation: 4 g ethanol/kg maternal body weight/day; isocaloric sucrose/pair-feeding; water; or no treatment (ad lib). Near-term fetuses were studied at gestational day (GD) 63 (term, about GD 68). This ethanol regimen produced a maternal blood ethanol concentration of 66+/-4 mM (304+/-19 mg/dl) at 1 h after the daily dose on GD 58. The chronic ethanol regimen decreased near-term fetal body weight (12-26% decrease), brain weight (23% decrease), and cerebral cortical weight (21% decrease), compared with the isocaloric sucrose/pair-feeding, and combined water/ad lib experimental groups. Saturation analysis of near-term fetal cerebral cortical membranes using a [3H]MK-801 radioligand binding assay demonstrated a decreased affinity and increased number of MK-801 binding sites for the chronic ethanol regimen compared with the control treatments. These data support the suggestion that upregulation of NMDA receptors in the cerebral cortex after chronic prenatal ethanol exposure could lead to NMDA receptor-mediated excitotoxicity in this brain region.     

The in vitro binding of estradiol by the guinea pig cerebral cortex

The in vitro dynamics of the binding of estradiol by the cerebral cortex of the female guinea pig were studied. The uptake of ³H-estradiol by slices of cerebral cortex was temperature-dependent, being highest at 37°C. A significant increment in the binding of ³H-estradiol was observed in the cytosol up to 240 minutes. The increase on the binding of ³H-estradiol by the cytosol and the nucleus of the brain followed a linear relationship with the increment in protein concentration. The cytosol protein(s) of the cerebral cortex that bind(s) estradiol contain sulphydril groups and are thermolabiles. The number of binding sites and the Ka for estradiol in the cytosol of the cerebral cortex were 30 fm/mg proteins and 1.33 × 10⁹ M^?1, respectively. These results could suggest that in the guinea pig cerebral cortex there are receptors for estradiol, similar to those described in the uterus.     

Effects of acute ethanol exposure on glutamate release in the hippocampus of the fetal and adult guinea pig

The effects of in vitro and/or acute in vivo ethanol exposure on l-glutamate (GLU) release were determined in transverse hippocampal slices of the adult guinea pig and the immature and mature fetal guinea pig. In vitro ethanol (34–110 mM) exposure produced age-dependent and narrow concentration range-dependent depressant effects on K⁺-stimulated and basal GLU release, in which the fetal hippocampus was more sensitive than the adult. For acute in vivo ethanol exposure, the hippocampal slices were prepared 1 h after oral intubation of 4 g ethanol/kg body weight. In vivo ethanol exposure produced a persistent depressant effect on stimulated GLU release in the fetus and no effect in the adult. After acute in vivo ethanol treatment, in vitro ethanol (48 mM) exposure also decreased stimulated GLU release in the hippocampus of the immature and mature fetus and decreased basal GLU release only in the immature fetus. Furthermore, this acute in vivo/in vitro ethanol regimen did not affect stimulated or basal GLU release in the adult, which is indicative of tolerance development. Overall, the data indicate that ethanol depresses GLU release in the hippocampus of the guinea pig and that the fetal hippocampus is more susceptible to these depressant effects.     

Dose-dependent effects of prenatal ethanol exposure in the guinea pig

The guinea pig is an appropriate animal for studying ethanol central nervous system (CNS) teratogenesis due to its extensive prenatal CNS development. In order to establish an ethanol dosage regimen that produces CNS teratogenesis, the objective of this study was to characterize the dose-dependent effects of chronic ethanol administration on pregnancy outcome and locomotor activity of the offspring. Pregnant guinea pigs received one of the following oral treatments, via intubation into the oral cavity, throughout gestation: 3, 4, 5, or 6 g ethanol/kg maternal body weight/day; isocaloric sucrose and pair feeding; or water. The 5 and 6 g ethanol/kg/day regimens produced maternal death, spontaneous abortion, and perinatal death with at least 75% incidence; the 3 and 4 g ethanol/kg/day regimens produced little or no maternal, embryonic/fetal, or perinatal lethality. The 3 and 4 g ethanol/kg/day regimens did not affect other indices of pregnancy outcome compared with the respective isocaloric-sucrose pair-fed control animals and water-treated animals. The 3, 4, and 5 g ethanol/kg/day regimens increased spontaneous locomotor activity in the offspring, and there was a direct relationship between the magnitude of hyperactivity at days 10 and 60 of age and each of the ethanol dosage regimens and the maternal blood ethanol concentration on day 56 of gestation. The data demonstrate that, in the guinea pig, chronic oral administration of ethanol produces: (a) dose-dependent effects on pregnancy outcome, (b) hyperactivity in the offspring that is dose- (and maternal blood ethanol concentration-) and age-related, and (c) persistent hyperactivity into adulthood with minimal toxicity on pregnancy outcome for the 4 g ethanol/kg/day regimen.     

Chronic ethanol exposure increases the non-dominant glucocorticoid,corticosterone, in the near-term pregnant guinea pig

Maternal-fetal signaling is critical for optimal fetal development and postnatal outcomes. Chronic ethanol exposure alters programming of the fetal hypothalamic-pituitary-adrenal (HPA) axis, resulting in a myriad of neurochemical and behavioral alterations in postnatal life. Based on a recent study which showed that human intra-partum fetal stress increased fetal secretion of corticosterone, the non-dominant glucocorticoid, this investigation tested the hypothesis that an established model of HPA axis programming, chronic maternal ethanol administration to the pregnant guinea pig, would result in preferential elevation of corticosterone, which is also the non-dominant glucocorticoid. Starting on gestational day (GD) 2, guinea pigs received oral administration of ethanol (4 g/kg maternal body weight/day) or isocaloric-sucrose/pair-feeding. Each treatment was administered daily and continued until GD 45, 55, or 65 (approximately 3 days pre-term), when pregnant animals were euthanized and fetuses delivered by Caesarean section. Maternal and fetal plasma samples were collected. After sample preparation (protein precipitation and C-18 solid phase extraction), plasma cortisol and corticosterone concentrations were determined simultaneously by liquid chromatography coupled to tandem mass spectrometry. As predicted, chronic ethanol exposure increased both fetal and maternal plasma corticosterone concentration in late gestation. In contrast, plasma cortisol did not differ across maternal treatments in maternal or fetal samples. The plasma concentration of both maternal glucocorticoids increased with gestational age. Thus, corticosterone, the non-dominant glucocorticoid, but not cortisol, was elevated by chronic ethanol exposure, which may have effects on HPA function in later life.     

Omega-3 fatty acid attenuates oxidative stress in cerebral cortex,cerebellum, and hippocampus tissue and improves neurobehavioral activity in chronic lead-induced neurotoxicity

Objectives: In view of the increasing risk of lead on human health, the present study has been carried out to investigate the neuroprotective effect of omega-3 fatty acid on chronic lead-induced neurotoxicity and behavioral impairment in rats.

Methods: Different neurobehavioral parameters, biochemical assays, and histopathological analyses in brain regions of rats were conducted.

Results: Rats exposed to different doses of lead (lead acetate 2.5, 5.0, 7.5?mg/kg body weight p.o. for 90 days) caused a significant decrease in body weight, brain weight, and behavioral changes as compared to controls. Abnormal histopathological and increased levels of lead in blood and brain regions increased the levels of ROS, LPO, PCC and decreased the levels of GSH with concomitant reduction in SOD, CAT, and GPx activities in the brain region of rats treated with different doses of lead as compared to controls. Co-treatment of lead with omega-3 fatty acid (500?mg/kg body weight p.o. for 90 days) decreased the levels of ROS, LPO, PCC, and increased the level of GSH, also increased SOD, CAT, and GPx activity and showed improvements in behavioral as well as histopathological changes as compared to lead-treated groups.

Discussion: Our results proved that omega-3 fatty acid improved behavioral deficits, altered histopathological and oxidative stress in lead-intoxicated rats. Among three different doses, 2.5?mg/kg b.wt. of lead along with omega-3 fatty acid was the most preventive dose for the neurotoxicity. This work reveals the potential of omega-fatty acid as a protective drug for lead neurotoxicity.     

Effects of chronic prenatal ethanol exposure on mitochondrial glutathione and 8-iso-prostaglandin F2alpha concentrations in the hippocampus of the perinatal guinea pig

It is hypothesised that oxidative stress is a key mechanism of ethanol neurobehavioural teratogenicity, resulting in altered endogenous antioxidant status and increased membrane lipid peroxidation in the hippocampus of chronic prenatal ethanol exposure (CPEE) offspring. To test this hypothesis, timed pregnant guinea-pigs (term, approximately gestational day (GD) 68) received chronic daily oral administration of (i) 4 g ethanol kg(-1) maternal bodyweight, (ii) isocaloric sucrose with pair feeding, or (iii) water. At GD 65 (term fetus) and postnatal day (PD) 0 (neonate), individual offspring were killed, the brain was excised and the hippocampi were dissected. Glutathione (GSH) concentration was measured in the cytosolic and mitochondrial fractions of hippocampal homogenate. The occurrence of lipid peroxidation was determined by measuring the concentration of 8-iso-prostaglandin F2+/- (8-iso-PGF2+/-). There was CPEE-induced decreased brain weight and hippocampal weight at GD 65 and PD 0, decreased mitochondrial GSH concentration in the hippocampus at PD 0, with no change in mitochondrial GSH concentration at GD 65 or cytosolic GSH concentration at GD 65 or PD 0, and no change in mitochondrial or whole-homogenate 8-iso-PGF2+/- concentration in the hippocampus at GD 65 or PD 0. The data demonstrate that CPEE produces selective mitochondrial dysfunction in the hippocampus of the neonatal guinea-pig, involving GSH depletion.     

The metabolic action of gestagens on the cerebral cortex of the guinea pig.

The injection of chlormadinone acetate (CA) or norgestrel (N) potentiated the effects of estradiol (E₂) on RNA synthesis in the guinea pig cerebral cortex, but not in the uterus. Only CA inhibited the stimulation of protein synthesis by E₂ in the cerebral cortex. In contrast, the E₂-induced increment of protein synthesis in the uterus was not affected by the administration of either gestagen.When injected alone neither gestagen showed any metabolic action on the brain, indicating that their effects on RNA and protein synthesis in the cerebral cortex requires the presence of E₂.     

Effects of chronic prenatal ethanol exposure on hippocampal glutamate release in the postnatal guinea pig.

This study was designed to test the hypothesis that chronic prenatal ethanol exposure decreases basal and stimulated L-glutamate release in the hippocampus of young, postnatal guinea pigs. Timed, pregnant guinea pigs were randomly assigned to one of the following three chronic treatment groups: 4 g ethanol/kg maternal body weight/day, isocaloric-sucrose and pair-feeding to the ethanol group, and water. Each oral treatment was given daily throughout gestation. Spontaneous locomotor activity was increased on postnatal day (PD) 10, and brain and hippocampal weights were decreased on PD 12 in the offspring of the ethanol group compared with the isocaloric-sucrose/pair-fed and water groups. On PD 12, the 45 mM K(+)- and 10 microM veratridine-stimulated release of glutamate in transverse hippocampal slices was decreased in the ethanol group compared with the two control groups. This alteration in glutamate release produced by chronic prenatal ethanol exposure may decrease the efficiency of excitatory synaptic transmission in the hippocampus during postnatal life.     

铅对大鼠海马一氧化氮合酶活力及表达的影响

目的 通过研究铅对大鼠海马一氧化氮合酶（ＮＯＳ）活力及表达的影响。分析海马不同亚区ＮＯＳ活力变化与铅对海马长时程增强（ＬＴＰ）影响的关系。方法 Ｗｉｓｔａｒ大鼠采用饮水加２０、２００、２０００μｇ／ｍｌ醋酸铅（ＰｂＡｃ）方法染毒３个月后,用Ｙ－迷宫法测试大鼠神经行为的改变;用原子吸收法测定血液与海马中铅的含量;用ＮＡＤＰＨ－黄递酶（ＮＡＤＰＨ－ｄ）组化法和免疫组化法检测海马ＮＯＳ的活力及表达情况。     

Effect of chronic maternal ethanol administration on glutamate and N-methyl-d-aspartate binding sites in the hippocampus of the near-term fetal guinea pig

The objective of this study was to determine the effect of chronic maternal administration of ethanol on hippocampal l-glutamate (glutamate) and N-methyl-d-aspartate (NMDA) binding sites in the near-term fetal guinea pig. Starting on gestational day (GD) 2, pregnant guinea pigs received one of the following oral treatments up to and including GD 62 (term, about GD 68): 4 g ethanol · kg maternal body weight⁻¹ · day⁻¹; isocaloric sucrose and pair-feeding; or water. Maternal blood ethanol concentration was determined at 1 h after the daily ethanol dose on GD 59. Fetuses were studied at GD 63 (mature, near-term fetus). Fetal body weight and brain weight were determined. The density (B_max) and affinity (K_d) of the glutamate and NMDA binding sites in the fetal hippocampus were measured using a radioligand membrane binding assay; saturation analysis was conducted on hippocampal synaptic membrane preparation (HSMP). Maternal blood ethanol concentration on GD 59 was 269 ± 111 (SD) mg/dl (59 ± 24 mM). There was no maternal or embryonic fetal lethality in any of the three treatment groups, and ethanol treatment did not affect maternal body weight gain compared with sucrose or water treatment. Fetal brain weight, but not body weight, was decreased in the ethanol treatment group compared with the sucrose and water treatment groups. The B_max values of the glutamate and NMDA binding sites were decreased in the ethanol treatment group compared with the sucrose and water treatment groups; there was no difference in the K_d values of the glutamate and NMDA binding sites among the three treatment groups. The data demonstrate that, in the guinea pig, chronic maternal administration of a binge-type ethanol regimen throughout gestation restricts brain growth and decreases the density of glutamate and NMDA binding sites in the hippocampus, as manifested in the mature fetus.     

Effect of pre- and postnatal ethanol exposure on protein tyrosine kinase activity and its endogenous substrates in rat cerebral cortex.

The rat brain contains high levels of tyrosine-specific protein kinases (PTKs) that specifically phosphorylate the tyrosine-containing synthetic peptide poly(Glu4Tyr1). Using this peptide as a substrate, we have measured the protein tyrosine kinase activity in membrane and cytosolic fractions from the cerebral cortices of pre- and postnatal ethanol-exposed rats at time intervals of 8, 30, and 90 days. During the course of development of the cerebral cortex, PTK activity decreased both in the membrane and cytosolic fractions from 8 and 90 days of age. Maximum activity was associated at the age of 8 days and gradually declined in the later ages (30 and 90 days) of postnatal development. However, PTK activity in the ethanol exposed rat cerebral cortex was further decreased when compared to controls in all the ages of postnatal development in membrane as well as in cytosolic fractions. In the presence of vanadate, a specific inhibitor of protein tyrosine phosphatases (PTPs), the PTK activity increased, indicating that the balance between protein tyrosine kinase and protein tyrosine phosphatase might be lost during ethanol exposure. In addition, when using an antibody specific for phosphotyrosine, endogenous substrates for protein tyrosine kinases were identified on an immunoblot of membrane and cytosolic fractions from the ethanol-exposed rat cerebral cortex. The immunoblot showed several phosphotyrosine-containing proteins with molecular weights of 114, 70, 36, 34, 32, 20, and 14 kDa that were present in the cerebral cortex. However, higher levels of immunoreactivity of these proteins were found in the ethanol-exposed membrane fractions when compared to control fractions-particularly at the age of 30 and 90 days. Two phosphotyrosine proteins with molecular weights of 38 and 40 kDa showed decreased immunoreactivity at the age of 90 days in the cytosolic fraction of an ethanol-exposed rat's cerebral cortex. The differences in tyrosine-specific protein kinase activity and in phosphotyrosine-containing proteins observed during pre- and postnatal ethanol exposure may reflect specific functional defects in the cerebral cortex which could possibly underlie the mechanism contributing to fetal alcohol syndrome (FAS).     

Acute inhalation exposure of azodicarbonamide in the guinea pig

Humans have been exposed to azodicarbonamide (ADA) by inhalation where bulk quantities of ADA are handled in the workplace. Responses of some workers have led to concern for the potential irritant and sensitizing properties of inhaled ADA. This study examined the effects of inhaling ADA on lung structure and function of guinea pigs during and after an acute exposure. Groups of 20 guinea pigs were exposed to each of 3 concentrations of ADA (19, 58, and 97 mg/m3), plus air as a control, for 1 hr. Pulmonary function was measured before exposure (baseline), during exposure, immediately after exposure and 24 hr after exposure. Dynamic compliance (Cdyn), total pulmonary resistance (RL), tidal volume (VT), respiratory frequency and minute volume were measured. In addition, gross necropsies and histological examinations of respiratory tract tissues were done either immediately following the exposure or 24 hr after exposure. There were no effects of ADA exposure on gross necropsy, histology, Cdyn, or RL. Some significant, concentration-related decreases in VT, respiratory frequency and minute volume were seen. The magnitudes of these changes were small: the largest change was seen in minute volume, amounting to a 24% decrease in the high concentration group. Inhalation exposure of guinea pigs to ADA at concentrations of up to 97 mg/m3 resulted in minor changes in pulmonary function without any changes in lung histology.     

Chronic prenatal ethanol exposure alters expression of central and peripheral insulin signaling molecules in adult guinea pig offspring

Maternal ethanol consumption during pregnancy can produce a range of teratogenic outcomes in offspring. The mechanism of ethanol teratogenicity is multi-faceted, but may involve alterations in insulin and insulin-like growth factor (IGF) signaling pathways. These pathways are not only important for metabolism, but are also critically involved in neuronal survival and plasticity, and they can be altered by chronic prenatal ethanol exposure (CPEE). The objective of this study was to test the hypothesis that CPEE alters expression of insulin and IGF signaling molecules in the prefrontal cortex and liver of adult guinea pig offspring. Pregnant Dunkin-Hartley-strain guinea pigs received ethanol (4 g/kg maternal body weight/day) or isocaloric-sucrose/pair-feeding (nutritional control) throughout gestation. Fasting blood glucose concentration was measured in male and female offspring at postnatal day 150–200, followed by euthanasia, collection of prefrontal cortex and liver, and RNA extraction. IGF-1, IGF-1 receptor (IGF-1R), IGF-2, IGF-2 receptor (IGF-2R), insulin receptor substrate (IRS)-1, IRS-2, and insulin receptor (INSR) mRNA expression levels were measured in tissues using quantitative real-time PCR. The mean maternal blood ethanol concentration was 281 ± 15 mg/dL at 1 h after the second divided dose of ethanol on GD 57. CPEE resulted in increased liver weight in adult offspring, but produced no difference in fasting blood glucose concentration compared with nutritional control. In the liver, CPEE decreased mRNA expression of IGF-1, IGF-1R, and IGF-2, and increased IRS-2 mRNA expression in male offspring only compared with nutritional control. Female CPEE offspring had decreased INSR hepatic mRNA expression compared with male CPEE offspring. In the prefrontal cortex, IRS-2 mRNA expression was increased in CPEE offspring compared with nutritional control. The data demonstrate that CPEE alters both central and peripheral expression of insulin and IGF signaling molecules at the mRNA level, which may be related to metabolic dysregulation in adult offspring. Furthermore, altered insulin and IGF signaling may be a mechanism of ethanol neurobehavioral teratogenicity.     

Fetal guinea pig brain 15-hydroxyprostaglandin dehydrogenase: ontogeny and effect of ethanol

The objectives of this study were to determine the ontogeny of 15-hydroxyprostaglandin dehydrogenase (15-OH-PGDH) activity in the brain of the fetal guinea pig and to test the hypothesis that acute in vitro ethanol exposure produces concentration-dependent inhibition of fetal brain 15-OH-PGDH activity. Enzyme activity was determined in vitro by measuring the rate of oxidation of PGE2 to 15-keto-PGE2 using an optimized radiometric procedure. The study was conducted utilizing the whole brain of the fetal guinea pig at mean gestational ages of 34, 43 and 62 days (term, about 66 days) and the brain stem (pons and medulla) of the fetal guinea pig at mean gestational ages of 43 and 62 days. The direct effect of acute in vitro exposure to ethanol was assessed by incubating 15-OH-PGDH with ethanol in the concentration range of 10 to 80 mM. 15-OH-PGDH was measurable in the whole brain and brain stem, and the enzyme activity was similar for the gestational ages examined. There was no significant ethanol-induced inhibition of 15-OH-PGDH activity in the whole brain or brain stem. The data demonstrate that the whole brain and brain stem of the fetal guinea pig have the capacity to metabolize PGE2 to 15-keto-PGE2, an inactive metabolite, during the second half of gestation. The data apparently are not consistent with the hypothesis that acute in vitro exposure to ethanol directly inhibits 15-OH-PGDH activity in fetal brain.     

Effects of ethanol on the rat brain: ultrastructural alterations in the temporal cortex and in the hippocampus

Male rats were submitted either to an oral alcohol intoxication or to chronological aging. Nervous morphometry shows that chronic alcohol consumption induces an increase in the proportion of neurons with dense cytoplasm and an increase of the synaptic cleft affecting principally synapses with spherical vesicles. The cerebrovascular morphometry revealed that the vascularity enhances with chronic alcohol consumption in young animal. The same enhancement is observed in aged animals showing thus a parallelism between alcoholised and aged animals.