Effects of ethanol, given during pregnancy, on the offspring dopaminergic system

Synaptic Plasticity Abnormalities in Fetal Alcohol Spectrum Disorders

The brain's ability to strengthen or weaken synaptic connections is often termed synaptic plasticity. It has been shown to function in brain remodeling following different types of brain damage (e.g., drugs of abuse, alcohol use disorders, neurodegenerative diseases, and inflammatory conditions). Although synaptic plasticity mechanisms have been extensively studied, how neural plasticity can influence neurobehavioral abnormalities in alcohol use disorders (AUDs) is far from being completely understood. Alcohol use during pregnancy and its harmful effects on the developing offspring are major public health, social, and economic challenges. The significant attribute of prenatal alcohol exposure on offspring is damage to the central nervous system (CNS), causing a range of synaptic structural, functional, and behavioral impairments, collectively called fetal alcohol spectrum disorder (FASD). Although the synaptic mechanisms in FASD are limited, emerging evidence suggests that FASD pathogenesis involves altering a set of molecules involved in neurotransmission, myelination, and neuroinflammation. These studies identify several immediate and long-lasting changes using many molecular approaches that are essential for synaptic plasticity and cognitive function. Therefore, they can offer potential synaptic targets for the many neurobehavioral abnormalities observed in FASD. In this review, we discuss the substantial research progress in different aspects of synaptic and molecular changes that can shed light on the mechanism of synaptic dysfunction in FASD. Increasing our understanding of the synaptic changes in FASD will significantly advance our knowledge and could provide a basis for finding novel therapeutic targets and innovative treatment strategies.

Reference compounds for alternative test methods to indicate developmental neurotoxicity (DNT) potential of chemicals: example lists and criteria for their selection and use

There is a paucity of information concerning the developmental neurotoxicity (DNT) hazard posed by industrial and environmental chemicals. New testing approaches will most likely be based on batteries of alternative and complementary (non-animal) tests. As DNT is assumed to result from the modulation of fundamental neurodevelopmental processes (such as neuronal differentiation, precursor cell migration or neuronal network formation) by chemicals, the first generation of alternative DNT tests target these processes. The advantage of such types of assays is that they capture toxicants with multiple targets and modes-of-action. Moreover, the processes modelled by the assays can be linked to toxicity endophenotypes, i.e. alterations in neural connectivity that form the basis for neurofunctional deficits in man. The authors of this review convened in a workshop to define criteria for the selection of positive/negative controls, to prepare recommendations on their use, and to initiate the setup of a directory of reference chemicals. For initial technical optimization of tests, a set of >50 endpoint-specific control compounds was identified. For further test development, an additional “test” set of 33 chemicals considered to act directly as bona fide DNT toxicants is proposed, and each chemical is annotated to the extent it fulfills these criteria. A tabular compilation of the original literature used to select the test set chemicals provides information on statistical procedures, and toxic/non-toxic doses (both for pups and dams). Suggestions are provided on how to use the >100 compounds (including negative controls) compiled here to address specificity, adversity and use of alternative test systems.

Adenylyl cylases 1 and 8 mediate select striatal-dependent behaviors and sensitivity to ethanol stimulation in the adolescent period following acute neonatal ethanol exposure

Neonatal alcohol exposure in rodents causes dramatic neurodegenerative effects throughout the developing nervous system, particularly in the striatum, acutely after exposure. These acute neurodegenerative effects are augmented in mice lacking adenylyl cyclases 1 and 8 (AC1/8) as neonatal mice with a genetic deletion of both AC isoforms (DKO) have increased vulnerability to ethanol-induced striatal neurotoxicity compared to wild type (WT) controls. While neonatal ethanol exposure is known to negatively impact cognitive behaviors, such as executive functioning and working memory in adolescent and adult animals, the threshold of ethanol exposure required to impinge upon developmental behaviors in mice has not been extensively examined. Therefore, the purpose of this study was to determine the behavioral effects of neonatal ethanol exposure using various striatal-dependent developmental benchmarks and to assess the impact of AC1/8 deletion on this developmental progression. WT and DKO mice were treated with 2.5 g/kg ethanol or saline on postnatal day (P)6 and later subjected to the wire suspension, negative geotaxis, postural reflex, grid hang, tail suspension and accelerating rotarod tests at various time points. At P30, mice were evaluated for their hypnotic responses to 4.0 g/kg ethanol by using the loss of righting reflex assay and ethanol-induced stimulation of locomotor activity after 2.0 g/kg ethanol. Ethanol exposure significantly impaired DKO performance in the negative geotaxis test while genetic deletion of AC1/8 alone increased grid hang time and decreased immobility time in the tail suspension test with a concomitant increase in hindlimb clasping behavior. Locomotor stimulation was significantly increased in animals that received ethanol as neonates, peaking significantly in ethanol-treated DKO mice compared to ethanol-treated WT controls, while sedation duration following high-dose ethanol challenge was unaffected. These data indicate that the maturational parameters examined in the current study may not be sensitive enough to detect effects of a single ethanol exposure during the brain growth spurt period. Genetic deletion of AC1/8 reveals a role for these cylases in attenuating ethanol-induced behavioral effects in the neonatally-exposed adolescent.

Chronic ethanol exposure changes dopamine D2 receptor splicing during retinoic acid-induced differentiation of human SH-SY5Y cells

There is evidence for ethanol-induced impairment of the dopaminergic system in the brain during development. The dopamine D2 receptor (DRD2) and the dopamine transporter (DAT) are decisively involved in dopaminergic signaling. Two splice variants of DRD2 are known, with the short one (DRD2s) representing the autoreceptor and the long one (DRD2l) the postsynaptic receptor. We searched for a model to investigate the impact of chronic ethanol exposure and withdrawal on the expression of these proteins during neuronal differentiation. RA-induced differentiation of human neuroblastoma SH-SY5Y cells seems to represent such a model. Our real-time RT-PCR, Western blot, and immunocytochemistry analyses of undifferentiated and RA-differentiated cells have demonstrated the enhanced expression of both splice variants of DRD2, with the short one being stronger enhanced than the long one under RA-treatment, and the DRD2 distribution on cell bodies and neurites under both conditions. In contrast, DAT was down-regulated by RA. The DAT is functional both in undifferentiated and RA-differentiated cells as demonstrated by [(3)H]dopamine uptake. Chronic ethanol exposure during differentiation for up to 4 weeks resulted in a delayed up-regulation of DRD2s. Ethanol withdrawal caused an increased expression of DRD2l and a normalization of DRD2s. Thus the DRD2s/DRD2l ratio was still disturbed. The dopamine level was increased by RA-differentiation compared to controls and was diminished under RA/ethanol treatment and ethanol withdrawal compared to RA-only treated cells. In conclusion, chronic ethanol exposure impairs differentiation-dependent adaptation of dopaminergic proteins, specifically of DRD2s. RA-differentiating SH-SY5Y cells are suited to study the impact of chronic ethanol exposure and withdrawal on expression of dopaminergic proteins during neuronal differentiation.

Combined exposure to nicotine and ethanol throughout full gestation results in enhanced acquisition of nicotine self-administration in young adult rat offspring

RATIONALE

Epidemiological evidence shows positive correlation between either maternal cigarette smoking or alcohol consumption on subsequent drug-taking behavior in offspring. However, the consequences of full gestational exposure to both drugs have not been studied experimentally despite concurrent use frequently reported among women of childbearing age. Such comorbid gestational drug exposure may increase susceptibility to acquiring cigarette smoking (i.e., nicotine self-administration), a major gateway drug.

OBJECTIVES

We developed a noninvasive rat model for exposure to both nicotine (2-6 mg kg(-1) day(-1)) and EtOH (4 g/kg gavage) that continued throughout pregnancy and postnatal (P) days 2-12, the rodent equivalent of the human third trimester, a critical brain developmental period. Offspring with this full gestational exposure to both drugs (Nic+EtOH) were compared to controls: nicotine alone, EtOH alone, pair-fed (comparable nutrition and handling), and ad libitum chow-fed. At P60-90, offspring had unlimited chronic access to acquire i.v. nicotine self-administration.

RESULTS

There were no differences in gender ratio, stillbirths, birth weights, righting reflex, eye opening age, or weight gain. However, Nic+EtOH offspring of both genders acquired nicotine self-administration (15 or 30 microg kg(-1) injection(-1)) more rapidly, at a higher percentage, and at a higher level than offspring in the other cohorts.

CONCLUSION

Full gestational Nic+EtOH exposure produced no overt alterations in standard postnatal measures but resulted in an enhanced acquisition of nicotine self-administration in young adult offspring.

Prenatal ethanol preferentially enhances reactivity of the dopamine D1 but not D2 or D3 receptors in offspring

Reports of prenatal ethanol (ETOH) effects on the dopamine system are inconsistent. In an attempt to clarify this issue, dams were given 35% ethanol-derived calories as the sole nutrient source in a liquid diet from the 10th through the 20th day of gestation (ETOH). Controls were pair-fed (PF) an isocaloric liquid diet or given ad libitum access to laboratory chow (LC). Prenatal exposure to both liquid diets reduced body weight of offspring relative to LC controls, more so for ETOH than for PF exposure. Prenatal ETOH also decreased litter size and viability, relative to both LC and PF control groups. On postnatal days 21-23, male and female offspring were given an injection of saline vehicle or one of eight specific dopamine receptor agonists or antagonists. Immediately after injection subjects were placed in individual observation cages, and over the following 30 min, eight behaviors (square entries, grooming, rearing, circling, sniffing, yawning, head and oral movements) were observed and quantified. No prenatal treatment effects on drug-induced behaviors were observed for dopamine D2 (Apomorphine, DPAT or Quinpirole) or D3 (PD 152255, Nafadotride, Apo or Quin effects on yawning) receptor agonists or antagonists, or for the vehicle control. In contrast, prenatal treatment effects were seen with drugs affecting the dopamine D1 receptor. Both D1 agonists (SKF 38393) and antagonists (SCH 23390 and high doses of spiperone) altered behaviors, especially oral and sniffing behaviors, in a manner which suggested enhanced dopamine D1 drug sensitivity in both ETOH and PF offspring relative to LC controls. These results suggest that at this age, both sexes experience a prenatal undernutrition-linked increase in the behavioral response to dopamine D1 agonists and antagonists, which can be intensified by gestational exposure to alcohol.

Prenatal alcohol exposure causes attention deficits in male rats

Children with fetal alcohol spectrum disorder (FASD) are often diagnosed with attention-deficit/ hyperactivity disorder (ADHD). These children show increases in reaction time (RT) variability and false alarms on choice reaction time (CRT) tasks. In this study, adult rats prenatally exposed to ethanol were trained to perform a CRT task. An analysis of the distribution of RTs obtained from the CRT task found that rats with a history of prenatal ethanol exposure had more variable RT distributions, possibly because of lapses of attention. In addition, it was found that, similar to children with FASD, the ethanol-exposed rats had more false alarms. Thus, rats with prenatal ethanol exposure show attention deficits that are similar to those of children with FASD and ADHD.

Neurodevelopmental liabilities in alcohol dependence: central serotonin and dopamine dysfunction

Alcoholism is a complex disorder with symptoms ranging from abuse to dependence, often comorbid with depression, antisocial personality, or anxiety. Neurodevelopmental causes of the disorder are unknown but inferences are possible from current knowledge. Neurobiological studies implicate multiple brain changes, which may be characterized as premorbid or morbid. These studies have also examined specific aspects of the alcohol dependence syndrome, including alcohol reinforcement and craving. Here, we review the evidence for vulnerability factors in alcohol dependence, with an emphasis on central serotonin (5-HT) and dopamine (DA). Serotonin dysfunction likely contributes to the development of alcoholism since studies of alcohol-preferring rodents show decreased 5-HT function on many measures. We have shown that serotonin-enhancing drugs reduce consumption and craving in mild to moderate alcoholics, yet similar studies in severely dependent individuals remain inconclusive. Studies indicate that serotonin dysfunction may contribute to the development of dependence via impaired impulse control and/or mood regulation. The mesocorticolimbic dopamine pathway represents another important pathophysiological target in alcoholism. Differences in D(2) receptor density, dopamine sensitivity, and gene expression have been linked to consumption, reinforcement, craving, and relapse. However, while DA agonists reduce self-administration in animals, we found no effect in humans with long-acting bromocriptine, a D(2) agonist. Dopamine may contribute differentially to the development of dependence via its effects on alcohol wanting, reinforcement, and reward memory. Although animal experiments show consistent roles for serotonin and dopamine in alcohol dependence, human studies are not always concordant. Such discrepancies highlight the complexity of dependence-related behaviors in humans and of identifying vulnerabilities to alcoholism.

In utero alcohol and postnatal methylphenidate: locomotion and dopamine receptors

Prenatal alcohol exposure can cause central nervous system abnormalities and dysfunction referred to as Alcohol-Related Neurodevelopmental Disorder (ARND). Repeated intermittent methylphenidate (Ritalin) was used as a psychopharmacological challenge to reveal functional alterations in dopamine binding sites in rats exposed prenatally to alcohol. Pregnant Long-Evans dams were intubated with 0, 3, or 5 g/kg/day of alcohol from gestational day (GD) 8 to GD20. Adult offspring received repeated intraperitoneal injections of 0, 4, or 8 mg/kg of methylphenidate (MET), and were tested periodically for locomotor activity. Autoradiographic assessment of dopamine D1 and D2 receptors binding were visualized using [3H]SCH 23390 and [3H]raclopride, respectively. Prenatal alcohol did not produce significant dose-dependent effects on adult locomotor activity. Repeated MET injections produced dose-dependent sensitization of locomotor activity in all groups. The 3-g/kg prenatal alcohol group had a significantly decreased number of dopamine D2 binding sites within the dorsal and ventral striatum. This effect was reversed by MET. The neural changes detected in the lower alcohol group may indicate persistent changes within the dopaminergic system due to prenatal alcohol exposure.

Fetal alcohol syndrome: early olfactory learning as a model system to study neurobehavioral deficits

The goal of basic research examining the deficits underlying fetal alcohol syndrome is to develop an animal model which allows investigation and assessment of the neural and cognitive impairments resulting from prenatal alcohol exposure. The following review focuses on animal models and their relationship to human deficits following prenatal alcohol exposure. In addition, this review examines a unique, well-established model system which may permit an increased understanding of the role of alcohol on the developing brain and cognitive behavior. Specifically, large metabolic, neurochemical, neuropharmacological, morphological and neurophysiological changes in young rats have been reported as a consequence of early olfactory preference conditioning, a form of learning that normally occurs during both human and rat development. This olfactory odor preference training paradigm can be used to assess changes in learning as well as the neural substrates underlying this learning. Olfactory preference training has been used to examine: 1) learning, as demonstrated by a behavioral preference for an odor previously paired with stimulation which mimics maternal care; 2) metabolism, by measuring 2-deoxyglucose uptake and distribution in response to the trained odor; 3) neurotransmitter levels, by using in vivo microdialysis, to examine changes in neurotransmitter levels in the olfactory bulb in response to a trained odor. Using in vivo microdialysis enables measurement of both baseline responsiveness of alcohol-exposed pups as well as learned responses at several different developmental ages. The established neural features of this olfactory model include an increase in behavioral preference for a trained odor, increases in 2-DG uptake in specific foci within the olfactory bulb in response to the odor, and increases in dopamine in response to olfactory preference training stimuli, as well as conditioned increases in norepinephrine following olfactory preference training. Using these known behavioral, metabolic and neurochemical indices in control pups allows identification of some of the neurotransmitter systems involved in deficits and the neurobiological basis for impairments induced by prenatal alcohol exposure.

Prenatal binge-like alcohol exposure alters neurochemical profiles in fetal rat brain

The majority of studies examining the effects of prenatal exposure to alcohol on neurotransmitter levels have furnished results that are divergent (increase, decrease or no change). The present study assessed six neurochemical compounds [norepinephrine (NE), dopamine (DA), dihydroxyphenylacetic acid (DOPAC), serotonin (5-HT), 5-hydroxyindole acetic acid (5-HIAA), gamma-aminobutyric acid (GABA)] from the same brain tissue. Pregnant Sprague-Dawley rats were given 5.1 g/kg alcohol (by gavage) either daily from embryonic day 1 (E1) through E20 or E20 only. In addition, pairfed/intubated (PF/INT) and ad lib chow (Chow) groups were included as controls. The dams were sacrificed and the fetuses were removed on E20. Binge-like alcohol exposure throughout gestation (E1-E20) produced significantly higher brain to body weight ratios compared with all other groups. Alcohol exposure did not produce changes in NE levels, although the E1-E20 exposure to alcohol reduced the contents of DA and 5-HT compared with the PF/INT and Chow controls. In addition, the E20 alcohol treatment reduced both DA and 5-HT levels compared with the E1-E20 alcohol treatment. DOPAC and 5-HIAA contents were affected by the prenatal treatments insofar as the 5-HIAA levels were decreased in E/1-20 and E20 animals relative to both controls, while the DOPAC levels were decreased in E/1-20, E20 and PF/INT groups compared to the Chow group; however, both metabolites were unaffected by the difference in alcohol treatment duration. Moreover, GABA levels were increased in fetuses exposed to alcohol from E1-E20 compared with all other groups. Collectively, these findings suggest that binge-like alcohol exposure prior to and during neurotransmitter development affects the baseline content of several neurotransmitters.

Effects of prenatal ethanol exposure on dopamine systems in C57BL/6J mice

Young rats prenatally exposed to ethanol exhibit heightened responses to dopaminergie (DA) drugs, altered brain concentrations of dopamine, and its metabolite dihydroxyphenylacetic acid (DOPAC), and transient reductions in DA receptor binding. Adult mice exposed to ethanol prenatally also exhibit increased responses to DA drugs; however, brain concentrations of DA and DOPAC are unaltered. The effects of prenatal ethanol exposure on DA or DOPAC concentrations in young mice or on DA receptor binding in mice of any age are unknown. Therefore, to determine if the different effects of prenatal ethanol exposure on rats and mice are due to age at time of testing or species, we determined its effects on DA concentrations and turnover in young mice under conditions previously reported for adult offspring and on DA D1 and D2 receptor binding in both young and adult offspring. Consistent with our previous report for adult offspring, prenatal ethanol exposure did not alter DA concentrations or turnover. The treatment did, however, diminish periadolescent growth as previously reported and produced a transient increase in DA D1, but not DA D2 receptor binding. DA receptor binding was not altered in adult offspring. Although unrelated to prenatal ethanol exposure, the sexes differed on all of the DA measures. Combined with previous reports, the present study suggests that species rather than age is more likely to account for the different effects of prenatal ethanol exposure on DA systems, and that sex differences in DA systems should be further examined.

Prenatal ethanol effects and dopamine systems of adult C57 male mice

Behavioral, pharmacological, and neurochemical studies indicate that prenatal ethanol exposure can alter dopamine (DA) systems of developing rats. In addition, some of the behavioral changes described for prenatal-ethanol-exposed rats and mice (e.g., reduced responding for food and other rewards) as well as their response to various psychoactive drugs (e.g., amphetamines, methylphenidate, haloperidol) suggest that the DA system changes might extend into adulthood. Neurochemical studies on the effects of prenatal ethanol on DA systems of adults have not been reported for either species. The present study provides a neurochemical assessment of prenatal ethanol effects on DA systems of fully mature mice. Compared to chow and sucrose controls, adult offspring of mice fed a diet containing 25% ethanol derived calories had preadolescent growth deficits as observed in previous studies which also showed long-term behavioral deficits. Prenatal ethanol exposure in the present study, however, did not alter the concentration of DA or dihydroxyphenylacetic acid (DOPAC) nor the progressive decline in the concentration of these compounds in either striatum or nucleus accumbens of mature mice at intervals after synthesis inhibition by alpha-methyl-DL-p-tyrosine. Thus, the present study provides no neurochemical confirmation of altered DA systems resulting from prenatal ethanol exposure under conditions previously observed to alter adult behavior.

The effects of in utero ethanol administration on the electrophysiological activity of rat nigrostriatal dopaminergic neurons

Iontophoresis and single-unit extracellular recording techniques were utilized to study the effects of in utero ethanol administration on nigrostriatal dopaminergic (NSDA) neurons in adult rats. Pregnant Sprague-Dawley rats consumed an ethanol-containing liquid diet providing 0%, 17.5%, or 35% ethanol-derived calories (EDC) from gestation day 8 until parturition. A separate group was fed standard rat chow as an ad lib, diet control. The dose-response curves of intravenously administered apomorphine on the spontaneous activity of NSDA neurons were shifted to the right in animals exposed to a liquid diet containing 17.5% or 35% EDC compared to 0% EDC or ad lib. control groups. The responsiveness of NSDA neurons to microiontophoretic application of the D-2 DA receptor agonist, quinpirole, was not altered following in utero ethanol exposure. These results suggest that in utero ethanol exposure may produce a down-regulation in the function of DA receptors distinct from the somatodendritic impulse-regulating D-2 autoreceptors. The firing pattern of NSDA neurons was also found to be altered after in utero ethanol exposure. There was a dissociation between the firing rate and burst activity in neurons that displayed burst-firing patterns in animals with in utero ethanol exposure. These observations agree with biochemical and behavioral studies that in utero ethanol exposure produces a long-lasting effect on the development of electrophysiological and pharmacological characteristics of midbrain DA systems in adulthood.

Alterations in neuronal development in the substantia nigra pars compacta following in utero ethanol exposure: immunohistochemical and Golgi studies

The effects of gestational ethanol exposure on the development of dopaminergic neurons of substantia nigra pars compacta were investigated in the rat. Pregnant rats were either fed an ethanol-containing liquid diet (6.7% v/v) or pair-fed an isocaloric diet throughout gestation. The morphology of neurons in both ethanol-exposed and pair-fed control offspring was assessed on postnatal day 15 by using tyrosine hydroxylase immunohistochemistry and Golgi impregnation methods. Alterations in the development of neurons were indicated in ethanol-exposed offspring compared with control offspring by the following: (i) tyrosine hydroxylase-positive cell bodies were smaller and appeared more closely packed; (ii) the numbers of second-, third- and fourth-order dendrites and total dendritic segments per cell were reduced; (iii) the dendritic branching pattern relative to distance from the soma was altered; and (iv) some dysmorphic neurons with irregular cell body contours and spheroidal enlargements in the dendrites were encountered in both tyrosine hydroxylase-immunostained and Golgi-stained specimens. The results of the present study suggest that gestational ethanol exposure causes retardation in the development of substantia nigra pars compacta neurons, especially in their dendritic growth and branching, and also causes pathological changes in some neurons. The underdevelopment of dendrites could result in altered development of neuronal circuitry which, in turn, could result in abnormal motor function.

Fetal alcohol exposure and adult tumorigenesis

Adult rats exposed to prenatal alcohol were evaluated for their susceptibility to either hormone- or chemical-inducing tumors. In the first study, rats exposed to prenatal alcohol displayed an increased propensity to beta-estradiol (E2)-induced adenohypophyseal prolactinoma. The susceptibility was manifest as a potentiated increase in anterior pituitary weight as well as in serum prolactin levels after 1 and 3 weeks but not 5 weeks of hormone treatment. Two weeks after withdrawing the E2-implant, the prolactinoma underwent involution and serum prolactin reversed to baseline levels. The high concentrations of serum corticosterone were also reduced but did not return to baseline levels after E2 removal. In the second study, nitrosomethylbenzylamine (NMBA) was utilized to induce esophageal cancer in adult rats. There were no significant differences in tumor incidence or size between the prenatal alcohol-exposed and the pair-fed cohorts. However, the NMBA-treated prenatal alcohol-exposed rats displayed a marked decrease in thymus: body wt ratio as well as adrenal gland hyperplasia. The results suggest that no single mechanism can account for the variable susceptibility displayed by the prenatal alcohol-exposed rats to chemical carcinogens. Some of the observed changes, however, may be attributable to the long-lasting adverse effects of prenatal alcohol exposure on the well-being of the adult host.

Prenatal ethanol effects on reward efficacy for adult mice are gestation stage specific

We previously reported that adult mice exposed to ethanol throughout gestation (G5-17) responded slower than controls on reinforcement schedules which required large numbers of responses per unit of food, i.e., high fixed ratio (FR) schedules. The primary finding of the present study was that ethanol exposure during the last 5 days of gestation (G12-17) is sufficient to produce this effect whereas a similar exposure early in gestation (G5-10) is not. Both male and female mice exposed to ethanol late in gestation responded slower than either lab chow or pair-fed controls, and the effect was similar to that of mice exposed to ethanol throughout gestation (G5-17) in our earlier study. Thus, developmental events occurring late in gestation are important for the reduced reinforcing efficacy of food for prenatal-ethanol-exposed mice. In addition, the present experiment established the comparability of the sucrose and lab chow controls on this task. The results of the present study and our previous report are compatible with the hypothesis that the reduced responding on high FR schedules exhibited by prenatal-ethanol-exposed mice reflects a reduction in the efficacy of food reward. It is possible that the reduction in reward efficacy is due to altered development of neuronal systems functionally related to reward which develop late in gestation.

Maternal ethanol ingestion and somatostatin level and binding in developing rat brain

The effect of maternal ethanol ingestion on 125I-labeled [Tyr11]somatostatin (SS) binding and somatostatin-like immunoreactivity (SLI) in the rat frontoparietal cortex and hippocampus of developing offspring was explored. Female Sprague-Dawley rats were given ethanol in the drinking water before pregnancy, during gestation, and while nursing, whereas controls received a standard diet and fresh water ad libitum. In the ethanol group, food intake decreased as ethanol consumption augmented, with the ethanol calories comprising greater than 30% of the total energy intake during pregnancy. Total energy intake was similar for the ethanol group and normal controls. Maternal alcohol ingestion is associated with an enhanced SLI level in the frontoparietal cortex and hippocampus on the day of birth. This study provided evidence of a selective decrease in SS receptor binding in frontoparietal cortex but not in hippocampus in the 0- to 10-day-old offspring of the ethanol-fed rats. The SS receptor number increased from day 0 to 10 in both control and ethanol groups. However, the affinity appeared to decrease significantly in the ethanol group during this period. At day 30, no differences were found between offspring of control and ethanol-treated rats in any of the parameters. These results suggest that the development of SS receptors in the rat frontoparietal cortex can be transitorily delayed by maternal ethanol ingestion.

Effects of in utero ethanol exposure on the developing serotonergic system

Previous work in this laboratory demonstrated that the 19- and 35-day-old offspring of ethanol-fed rats have a significant deficiency of cortical serotonin (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA), as well as a decrease in the number of total 5-HT1 receptors in the motor and somatosensory cortex. The present studies extend our previous reports by demonstrating that there is also a deficit of 5-HT and 5-HIAA in the motor cortex but not in the somatosensory cortex. In addition, we have shown that a deficit of 5-HT1A receptors in the motor and somatosensory cortices contributes to the deficit of total 5-HT1 receptors. In contrast, we did not observe any changes in the binding to 5-HT1B receptors in these cortical regions from the 19-day-old offspring of ethanol-fed rats. The present studies also examined the effects of in utero ethanol exposure on the early development of the serotonergic system. The results of these studies demonstrated a deficit of 5-HT and/or 5-HIAA in the brain stem as early as the 15th day of gestation (G15) and in the cortex as early as G19. In addition, we demonstrated a delay in both the normal developmental decline of 5-HT1A receptors in the brain stem and in the acquisition of cortical 5-HT1A receptors. No changes were found in the binding of [125I]cyanopindolol to 5-HT1B receptors in either region of fetal or neonatal rats exposed to ethanol in utero.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of in utero ethanol exposure on the developing dopaminergic system in rats

Previous studies from this and other laboratories suggest that dopamine is decreased in selected brain regions of postnatal rats exposed to ethanol in utero. The present study expands previous work by examining the effects of in utero ethanol exposure on dopamine D1 and D2 binding sites and dopamine uptake in postnatal rats. In addition, dopamine content in the brain stem and frontal cortex of fetal and neonatal rats was examined. The experimental results indicate that in utero ethanol exposure markedly affects the postnatal development of the dopaminergic system in the striatum and frontal cortex. We observed a marked, transient deficiency of striatal dopamine (greater than 40% decrease at 19 days) and dopamine uptake sites (approximately 25% decrease in Vmax at 35 days). The Bmax for striatal dopamine D1 binding sites was decreased by greater than 20% at both 19 and 35 days. Cortical D1 sites were markedly decreased at 19 days (greater than 40%). In contrast, the number of striatal D2 receptors was unaffected by in utero ethanol exposure at both ages. Analysis of tissue from neonatal rats demonstrated a marked dopamine deficiency in ethanol-exposed rats on postnatal day 5. In light of the proposed morphogenic actions of dopamine early in development, it is possible that the early dopamine deficiency contributes to the abnormal postnatal development of the dopaminergic system.

The ontogeny of SCH 23390-induced catalepsy in male and female rats exposed to ethanol in utero

The maturation of sensitivity to the cataleptic actions of selective D1 dopamine receptor blockade was assessed in rats exposed prenatally to ethanol. Pregnant rats received an average of 12.68 g/kg body weight of ethanol per day through a liquid diet. Control dams were either pair-fed an isocaloric liquid diet without ethanol or given ad lib lab chow. Separate groups of male and female offspring of these dams were administered either 0.33 or 1.00 mg/kg of the selective dopamine D1 receptor antagonist SCH 23390 at postnatal days 13, 17 or 21, and catalepsy was measured 0, 15 and 30 min later. The results are consistent with a hypothesis that prenatal ethanol exposure alters behaviors mediated by nigrostriatal dopamine systems. Overall, prenatal ethanol-exposed animals showed less catalepsy than control rats. Further, there is a gender effect in that dopamine antagonist-induced catalepsy matures earlier in normal male than in normal female controls. Prenatal alcohol exposure appears to delay the emergence of mature behavioral responses to dopamine blockade in male but not female rats.

Prenatal ethanol exposure impairs lesion-induced plasticity in a dopaminergic synapse after maturity

This study examined the consequences of alcohol (ethanol) exposure during fetal life on lesion-induced dopaminergic synapse responsiveness (plasticity) in the olfactory tubercle of the adult rat. Normally, in the olfactory tubercle, olfactory bulbectomy elicits alterations in pre- and postsynaptic dopaminergic markers, including, respectively, (1) increased tyrosine hydroxylase activity and immunoreactivity, which is associated with dopaminergic axon sprouting, and (2) increased dopaminergic receptor density and potentiated dopamine activation of adenylate cyclase. We have utilized biochemical and quantitative immunocytochemical methodology to examine these synaptic markers in olfactory bulbectomized or sham-operated adult rats. These animals were offspring of dams which were administered one of the following diets during pregnancy: (1) liquid diet containing 35% ethanol-derived calories ad libitum; (2) liquid diet containing an isocaloric amount of maltose-dextrin instead of ethanol, pair-fed; or (3) unaltered liquid diet ad libitum. The results show that prenatal alcohol exposure leads to suppression of the lesion-elicited dopaminergic synapse responsiveness in the olfactory tubercle. There were no significant differences between offspring born to control and pair-fed animals, indicating that the observed abnormalities were not due to alterations in their nutritional status. In conclusion, the present data are a biochemical and quantitative immunocytochemical demonstration of impaired lesion-induced synaptic responsiveness. This renders a new dimension in support of previous evidence indicating that prenatal alcohol exposure leads to altered neuroanatomical, neuroendocrinological and behavioral responsiveness to various challenges. Such impaired synaptic responsiveness may underlie brain functional abnormalities characteristic of fetal alcohol syndrome.

Synaptic density of caudate-putamen and visual cortex following exposure to ethanol in utero

Pregnant Long-Evans rats were fed a liquid diet containing ethanol (30% of total calories) during days 3-19 of gestation. Controls were given ad libitum access to liquid diet lacking ethanol, or pair-fed isocaloric amounts based on consumption by the animals in the ethanol group. Brain development of female offspring was evaluated by analysis of electron micrographs of caudate-putamen and visual cortex. Numbers of presynaptic terminals and synaptic junctions (synaptic density) per unit area were compared for 14- and 28-day-old offspring of dams from the three treatment groups. Synaptic density of the caudate-putamen and visual cortex was not affected by ethanol at 14 or 28 days. Although exposure to ethanol during a period comparable to the first two trimesters of human development with minimal or no undernutrition did not affect numerical density of synapses in visual cortex or caudate-putamen, synaptogenesis of caudate-putamen was altered in offspring of pair-fed animals.

Alterations in regional catecholamine content and turnover in the male rat brain in response to in utero ethanol exposure

Fetal ethanol exposure is known to produce CNS abnormalities. The molecular basis for these manifestations observed in animals exposed to ethanol in utero may be explained by changes in regional catecholamine content and turnover. This study was designed to determine changes in catecholamine content and turnover in the cerebral cortex, cerebellum, medial basal hypothalamus, diencephalon, and septal area of male rats exposed to ethanol pre- and postnatally. Pregnant Sprague-Dawley rats were exposed to either an ad libitum liquid diet containing 35% ethanol-derived calories, an isocalorically matched liquid diet, or a diet consisting of laboratory chow and water. Regional alterations in catecholamine content and turnover in each of the brain areas were observed on postnatal Day 18. A regional variability was demonstrated in the effect of in utero ethanol exposure on catecholamine content and turnover. The most dramatic effect was found in the dopaminergic neurons of the medial basal hypothalamus where in utero ethanol exposed offspring had a significantly reduced DA content and turnover when compared to pups from both isocalorically matched and chow-fed dams. These data indicate that the dopaminergic neurons of this particular brain region are susceptible to alteration by ethanol exposure during development and that this alteration cannot be explained by changes in nutrition alone.

Prenatal ethanol exposure in C57 mice: effects on pregnancy and offspring development

Pregnant mice were fed lab chow or isocaloric liquid diets containing different concentrations of ethanol or sucrose from Day 5 through Day 17 of gestation. Ethanol added to the diet reduced ad lib consumption compared to that of the diet with sucrose. The reduced consumption was accompanied by an attenuated weight gain during pregnancy. The attenuated weight gain, however, was not specific to alcohol as evidenced by an equivalent attenuation for sucrose controls pair-fed to the ethanol group. Prenatal ethanol exposure increased neonatal mortality which appeared to be unrelated to the prenatal attenuated weight gain or to postnatal nurturance. Surviving offspring, reared by their biological mothers, had body weights similar to controls at birth and during lactation. However, in contrast to previous reports, mice prenatally exposed to ethanol manifested weight reductions near weaning that extended into adulthood (60 days). In spite of the increased mortality and reduced body weight, motor activity assessed by either longitudinal or cross-sectional methods was not influenced by the treatments. Possible mechanisms for the delayed weight reduction include retarded maturation and/or dysfunction of neural systems involving food regulation.

Changes in brain catecholamine mechanisms following perinatal exposure to marihuana

Adult female rats received daily oral doses of a crude marihuana extract (CME; equivalent to 20 mg/kg delta 9-THC) throughout gestation and lactation. The offspring were sacrificed at 10, 20, 40 or 60 days postpartum and tissue samples of cerebral cortex and striatum were dissected and assayed for alpha 1-adrenergic and D2-dopaminergic receptors, respectively, and tyrosine hydroxylase activity. The body weight at birth and 10 days of age was reduced as was brain weight at 10 and 60 days of age in offspring exposed to CME. Perinatal exposure to CME reduced the binding capacity (Bmax) of D2 receptors in the striatum of 10 and 20-day-old offspring. The Bmax for alpha 1 receptors in the cerebral cortex was not altered at any age. Tyrosine hydroxylase activity was significantly decreased in the striatum of 20 and 40-day-old offspring exposed to CME. The results indicate that chronic perinatal exposure to CME can selectively alter the development of specific catecholamine mechanisms in rat brain.

Morphine analgesia is potentiated in adult rats prenatally exposed to ethanol

Exposure to inescapable, intermittent footshock elicits an opioid-mediated stress-induced analgesia in rats. We have previously shown that this response is markedly potentiated in adult rats, prenatally exposed to ethanol. To further investigate our hypothesis that endogenous opioid pain-inhibitory systems are modified by prenatal ethanol exposure, we have measured the analgesic response to morphine, in vitro brain opiate receptor binding characteristics, and occupation of brain opiate receptors following systemic administration of morphine. Compared to controls, rats prenatally exposed to ethanol had significantly enhanced morphine analgesia. This enhancement, however, does not appear attributable to changes in number or affinity of mu or delta opiate receptors, or to altered occupation of receptors by morphine.

Lactational ethanol exposure: brain enzymes and [3H]spiroperidol binding

Long-Evans lactating rats were fed 27% calories as ethanol in a liquid diet to determine whether alcohol received through the milk would alter normal brain development in the offspring. On days 16, 21 and 30, brains of the female offspring were removed, corpus striatum dissected and assayed for choline acetyltransferase activity, glutamic acid decarboxylase activity and [3H]spiroperidol binding activity. At day 16, there were no differences among the three treatment groups for the enzyme activities assayed. At day 21, glutamic acid decarboxylase activity in the pairfed group was higher than in ET and CT groups. Choline acetyltransferase activity in PF group was higher when compared to ad libitum controls and [3H]spiroperidol binding was not affected. At 30 days of age, animals exposed to ethanol had higher choline acetyltransferase activity and [3H]spiroperidol binding activity when compared to pairfed and ad libitum controls; and higher glutamic acid decarboxylase activity when compared to ad libitum controls. Data from the present study suggest that ethanol exposure during the brain growth spurt has a toxic effect on the late development of dopaminergic, cholinergic and GABAergic systems in the corpus striatum. These results may be related to the clinical symptoms of hyperactivity and problems with motor control in children exposed to alcohol during the third trimester and during lactation.

Fetal ethanol exposure: a morphometric analysis of myelination in the optic nerve

Pregnant Long-Evans rats were fed a liquid diet containing ethanol during gestation. Controls consisted of both pair-fed dams and dams fed ad libitum with an equivalent, iso-caloric diet lacking ethanol. Subsequent effects of ethanol measured in the offspring include a significant lag in the rate at which non-myelinated axons are lost in association with the initial overproduction of neurons. Additionally, there was a slight lag in the rate of acquisition of myelinated axons; and altogether there was a large increase in the ratio of non-myelinated to myelinated axons. Frequency spectra of myelinated and non-myelinated axons by size were normal, and the relationship between axon size and myelin lamellae was also normal. Measured against the dynamic, normal background of rapid cell-loss and the progressive development of myelin, morphometric demonstration and evaluation of the comparatively small divergences associated with fetal alcohol exposure are difficult: nevertheless, these results are consistent with and help account for the marginal hypomyelination previously observed by quantitative neurochemistry.

Learning retardation and enhanced ethanol preference produced by postnatal pretreatments with ethanol in adult rats

Male neonates of Wistar strain rats were given 0.63-2.50 g/kg/day of ethanol, i.p., for 7 successive days from day 6 to 12 after birth. The acquisition processes of the discriminated lever-press avoidance response (intertrial interval: 25 sec, warning stimuli presentation: 5 sec, foot shock intensity: 110V, 0.5 mA, 50 Hz, AC) were investigated for 20 separate sessions from day 60 after birth. The preference test for ethanol was done beginning at 120 days of age. No significant differences in body weights were detected between saline- and ethanol-pretreated groups. However, learning retardation was observed in all groups pretreated with ethanol. In these groups, slow responses to warning stimuli followed by escape responses from shocks delivered were often observed in early training sessions. An enhanced preference for ethanol was observed in all groups pretreated with ethanol for 7 successive days at maturity. These results suggest the possibility that learning ability and preference for ethanol in adult rats are strongly influenced by pretreatments with ethanol during the early postnatal period.