Development of sexual behavior in prenatally ethanol-exposed rats

Sex differences in neurodevelopmental abnormalities caused by early-life anaesthesia exposure: a narrative review

Exposure to anaesthetic drugs during the fetal or neonatal period induces widespread neuronal apoptosis in the brains of rodents and non-human primates. Hundreds of published preclinical studies and nearly 20 clinical studies have documented cognitive and behavioural deficits many months or years later, raising the spectre that early life anaesthesia exposure is a long-term, perhaps permanent, insult that might affect the quality of life of millions of humans. Although the phenomenon of anaesthesia-induced developmental neurotoxicity is well characterised, there are important and lingering questions pertaining to sex differences and neurodevelopmental sequelae that might occur differentially in females and males. We review the relevant literature on sex differences in the field of anaesthesia-induced developmental neurotoxicity, and present an emerging pattern of potential sex-dependent neurodevelopmental abnormalities in rodent models of human infant anaesthesia exposure.

Adverse reproductive outcomes associated with fetal alcohol exposure: a systematic review

Fetal alcohol exposure results in well-characterised neurobehavioural deficits in offspring, which form the basis for diagnosing fetal alcohol spectrum disorder. However, there is increasing interest in the full range of health complications that can arise in children and adults with this disorder. We used a systematic review approach to locate all clinical and preclinical studies across a broad range of health outcomes in offspring exposed to prenatal alcohol. Our search encompassed four databases (PubMed, CINAHL, EMBASE and Web of Science) and titles/abstracts from retrieved studies were screened against strict inclusion/exclusion criteria. This review specifically evaluated studies reporting on reproductive outcomes in both males and females. A total of 23 studies were included, 5 clinical and 18 preclinical. Although there was a wide range in the quality of reporting across both clinical and preclinical studies, and variable results, trends emerged amongst the reproductive measures that were investigated. In females, most studies focussed on age at first menarche/puberty onset, with evidence for a significant delay in alcohol-exposed offspring. In males, offspring exposed to prenatal alcohol had altered testosterone levels, reduced testes and accessory gland weights and reduced sperm concentration and semen volume. However, further studies are required due to the paucity of clinical studies, the narrow scope of female reproductive outcomes examined and inconsistencies in outcomes across preclinical studies. We recommend that adolescents and individuals of reproductive age diagnosed with f-etal alcohol spectrum disorder be assessed for reproductive dysfunction to allow appropriate management of their reproductive health and fertility.

Fetal alcohol spectrum disorders: Zebrafish in the analysis of the milder and more prevalent form of the disease

Fetal Alcohol Spectrum Disorders (FASD) represent a large unmet medical need. Exposure of the developing human embryo to alcohol can lead to life-long suffering. Despite the well documented deleterious effects of alcohol on the developing fetus, pregnant women continue to drink alcohol, and FASD remains the leading cause of preventable mental retardation and other behavioral abnormalities. Particularly prevalent are the milder forms of the disease cluster, representing children who do not show obvious physical signs and who may be undiagnosed or misdiagnosed. To develop treatment and diagnostic tools, researchers have turned to animal models. The zebrafish is becoming one of the leading biomedical research organisms that may facilitate discovery of the biological mechanisms underlying this disease and the identification of biomarkers that may be used for diagnosis. Here we review the latest advances of this field, mostly focussing on the discoveries made in our own laboratory and others with zebrafish employed to analyze the effects of moderate to low level of exposure to alcohol. We argue that the zebrafish represents unique advantages, and adding information obtained with this species to the mix of other animal models will significantly increase translational relevance of animal biomedical research for the analysis of human FASD.

Effect of prenatal ethanol exposure on sexual motivation in adult rats

Maternal alcohol use during pregnancy adversely affects prenatal and postnatal growth and increases the risk of behavioral deficits. The aim of the present study was to evaluate the effect of prenatal exposure to a moderate dose of alcohol on sexual motivation during adulthood. Rats were prenatally exposed to ethanol by feeding pregnant dams a liquid diet containing 25% ethanol-derived calories on days 6 through 19 of gestation. The controls consisted of pair-fed dams (receiving an isocaloric liquid diet containing 0% ethanol-derived calories) and dams with ad libitum access to a liquid control diet. The sexual motivation of offspring was evaluated during adulthood. The results revealed that the male and female pups of dams treated with alcohol exhibited reduced weight gain, which persisted until adulthood. Both male and female adult animals from dams that were exposed to alcohol showed a reduction in the preference score in the sexual motivation test. Taken together, these results provide evidence of the damaging effects of prenatal alcohol exposure on sexual motivation responses in adulthood.

Prenatal alcohol exposure and prenatal stress differentially alter glucocorticoid signaling in the placenta and fetal brain

Adverse intrauterine environments increase vulnerability to chronic diseases across the lifespan. The hypothalamic-pituitary-adrenal (HPA) axis, which integrates multiple neuronal signals and ultimately controls the response to stressors, may provide a final common pathway linking early adversity and adult diseases. Both prenatal alcohol exposure (PAE) and prenatal stress (PS) induce a hyperresponsive HPA phenotype in adulthood. As glucocorticoids are pivotal for the normal development of many fetal tissues including the brain, we used animal models of PAE and PS to investigate possible mechanisms underlying fetal programing of glucocorticoid signaling in the placenta and fetal brain at gestation day (GD) 21. We found that both PAE and PS dams had higher corticosterone (CORT) levels than control dams. However, 11β-hydroxysteroid dehydrogenase type 2 (11β-HSD2) enzyme levels were increased in PAE and unchanged in PS placentae, although there were no differences in 11β-hydroxysteroid dehydrogenase type 1 (11β-HSD1) levels. Moreover, only PAE fetuses showed decreased body weight and increased placental weight, and hence a lower fetal/placental weight ratio, a marker of placenta efficiency, compared to all other prenatal groups. Importantly, PAE and PS differentially altered corticosteroid receptor levels in placentae and brains. In the PS condition, maternal CORT was negatively correlated with both 11β-HSD1 and mineralocorticoid receptor (MR) protein levels in male and female placentae, whereas in the PAE condition, there were trends for a positive correlation between maternal CORT and 11β-HSD1, regardless of sex, and a negative correlation between maternal alcohol intake and MR in male placentae. In fetal brains, sexually dimorphic changes in MR and glucocorticoid receptor (GR) levels, and the MR/GR ratio seen in C fetuses were absent in PAE and PS fetuses. In addition, PS but not PAE female fetuses had higher MR and lower GR expression levels in certain limbic areas compared to C female fetuses. Thus the similar adult HPA hyperresponsive phenotype in PAE and PS animals likely occurs through differential effects on glucocorticoid signaling in the placenta and fetal brain.

Prenatal ethanol exposure alters core body temperature and corticosterone rhythms in adult male rats

Ethanol's effects on the developing brain include alterations in morphology and biochemistry of the hypothalamus. To examine the potential functional consequences of ethanol's interference with hypothalamic differentiation, we studied the long-term effects of prenatal ethanol exposure on basal circadian rhythms of core body temperature (CBT) and heart rate (HR). We also examined the late afternoon surge in corticosterone (CORT). Core body temperature and HR rhythms were studied in separate groups of animals at 4, 8, and 20 months of age. The normal late afternoon rise in plasma CORT was examined in freely moving male rats at 6 months of age via an indwelling right atrial cannula. Results showed that the CBT circadian rhythm exhibited an earlier rise after the nadir of the rhythm in fetal alcohol-exposed (FAE) males at all ages compared to controls. At 8 months of age, the amplitude of the CBT circadian rhythm in FAE males was significantly reduced to the level observed in controls at 20 months. No significant effects of prenatal ethanol exposure were observed on basal HR rhythm at any age. The diurnal rise in CORT secretion was blunted and prolonged in 6-month-old FAE males compared to controls. Both control groups exhibited a robust surge in CORT secretion around the onset of the dark phase of the light cycle, which peaked at 7:30 p.m. Whereas FAE males exhibited a linear rise beginning in mid afternoon, which peaked at 9:30 p.m. These results indicate that exposure to ethanol during the period of hypothalamic development can alter the long-term regulation of circadian rhythms in specific physiological systems.

Alcohol exposure during development: analysis of effects on female sexual behavior

BACKGROUND

Alcohol exposure during development has been shown to alter a variety of social behaviors in both humans and rodents. Sexual behavior in rodents has been well characterized and lends itself to a detailed investigation of the manner in which ethanol impacts this particular social behavior.

METHODS

Rats were exposed to ethanol during both the prenatal and early postnatal period (ET). Control groups included rats exposed to the administration procedures alone (intubated-control) and nontreated controls (NC). Sexual behavior of intact naïve female rats in estrus was assessed in adulthood (approximately postnatal day 90) and activity was measured by the number of crossings between chambers in the 3-chamber test apparatus. A separate study examined the olfactory preferences for 4 odors by intact naïve female rats in all 3 groups. The 4 odors were the odors resulting from 1 hour of occupation of the test chamber by an intact male, 1 hour of occupation of the test chamber by a gonadectomized male, 0.5 ml of urine from an intact male, and 0.5 ml of urine from a gonadectomized male.

RESULTS

ET female rats showed a reduced return latency after ejaculation compared to both control groups. There was a trend toward a reduction in percent exits after all forms of male behavior in the ET animals compared to the control groups. No significant differences across groups were seen in the lordosis quotient, activity, or the behavior of the nonexperimental male. ET female rats showed a reduced preference for the odor from the intact male compared to both control groups and a reduced preference for the odor from the gonadectomized male compared to NC females only.

CONCLUSIONS

These data suggest that ethanol exposure during the prenatal and postnatal period in females alters sexual motivation and changes the processing of olfactory cues and possibly coital cues from male rats.

Ethanol exposure during development reduces resident aggression and testosterone in rats

Ethanol exposure during development has been shown to alter social behaviors in people, but the range of deficits is not clear. Using an animal model of Fetal Alcohol Spectrum Disorders, inter-male aggression and testosterone levels were examined in adult rats. Rats were exposed to ethanol during the entire prenatal period and from postnatal day 2 through 10. Ethanol was administered via intragastric intubation. Two other groups consisted of a nontreated control and an intubated control group that was exposed to the administration procedures but not ethanol. Both offensive and defensive aggression were examined in experimental residents and intruders under three different housing conditions for the resident males: (1) with another male, (2) with a pregnant female, and (3) with a female and litter fathered by the experimental animal. When housed with a female and litter, ethanol-exposed rats displayed reduced offensive aggression compared to control groups under the same condition. Defensive aggression in the non-experimental intruders was reduced in this same condition. There were no differences in duration of non-aggressive social behaviors among the groups in any of the housing conditions. Testosterone levels were reduced in ethanol-exposed rats compared to controls. In summary, ethanol exposure over the combined prenatal and postnatal periods reduces aggressive behavior in a condition where aggressive behavior is normally seen. This reduction may be related to lower testosterone levels.

Fetal testosterone surge: specific modulations induced in male rats by maternal stress and/or alcohol consumption

Plasma testosterone (T) was measured in control male and female rats on gestational days 16, 17, 18, 19, and 20 and on days 17-20 in males from dams who were fed ethanol and/or were stressed during pregnancy. Circulating T in control males showed an earlier rise, yielding a longer period of prenatal T elevation, than was reported previously (Endocrinology 106 (1980)306). Compared to control males, exposure to alcohol-alone augmented T on days 18 and 19, stress-alone attenuated prenatal T, and the combination of stress and alcohol completely blocked the normal rise in T between days 17 and 18. When these prenatal alterations in T are viewed along with effects these same treatments have on the postparturient T surge (Horm. Behav. 41 (2002) 229), a possible explanatory mechanism emerges for the uniquely different behavioral patterns of sexual behavior differentiation induced in males by prenatal exposure to alcohol, stress, or both factors. Whereas the potential for feminine behavior is retained to the extent that either the prenatal or the neonatal T surge is attenuated, the male potential is more sensitive to reductions in the fetal surge and is maximally disrupted if both the prenatal and the postparturitional T surges are suppressed.

Postparturitional testosterone surge in male offspring of rats stressed and/or fed ethanol during late pregnancy

Male offspring of rats exposed to restraint stress and/or alcohol during late pregnancy show aberrant patterns of sexual behavior masculinization and defeminization that vary as a function of treatment. The impact of these treatments on the postparturitional testosterone (T) surge that contributes to sexual behavior differentiation was investigated. Plasma T was measured using radioimmunoassay in individual males sampled on day 21 of gestation within 10 min of cesarean delivery or 1, 2, or 4 h thereafter. Neonatal T in the group exposed only to stress did not differ from that in the control group. T was lower than control levels at birth in both alcohol groups. The magnitude of the T surge that occurred during the first hour of birth in the control group was diminished by 50% in both alcohol groups, whose T pattern was very similar. There was no common alteration in postparturitional T associated with the increased lordotic behavior potential that males in all three treatment groups typically share, nor were there idiosyncratic endocrine abnormalities linked to the very different male copulatory pattern each exhibits. Exposure to an abnormal T milieu during fetal as well as neonatal ontogeny may underlie the etiology of the different sexual behavior patterns exhibited by males exposed to stress and/or alcohol. Possible unique effects each treatment exerts on perinatal plasma T and it's aromatization to estradiol in hypothalamic targets are discussed.

Alcohol treatment during lactation produces an advance in the onset of puberty in female rats

It has been described that alcohol treatment after weaning produces a delay in the onset of puberty and a decrease in the body weight of female rats; however, during development, there are periods with different sensitivity to endogenous and exogenous substances. In this study, two daily doses of 2.5 g/kg of ethanol each administered to female pups during days 13-18 of postnatal age produced an advance in the age at vaginal opening but induced no effect on the body weight; however, the onset of sexual behavior was not advanced. Fertility and reproduction measures were not significantly impaired by this treatment. It is supported that, in this period, alcohol can produce different effects - even opposite to those described in other developmental stages - which seems to represent a critical period for alcohol action.

Effects of prenatal alcohol exposure on social behavior in humans and other species

Alcohol exposure during development causes central nervous system alterations in both humans and animals. Although the most common behavioral manifestation of these alterations is a reduction in cognitive abilities, it is becoming increasingly apparent that deficits in social behavior may be very prevalent sequelae of developmental alcohol exposure. In infancy and early childhood, deficits in attachment behavior and state regulation are seen in both alcohol-exposed people and animals, suggesting that these changes are largely the result of the alcohol exposure rather than maternal behavior. In the periadolescent period, people exposed to alcohol during development show a variety of difficulties in the social domain as measured by checklists filled out by either a parent or teacher. Rats exposed to alcohol during development show changes in play and parenting behaviors. In adulthood, prenatal alcohol exposure is related to high rates of trouble with the law, inappropriate sexual behavior, depression, suicide, and failure to care for children. These high rates all suggest that there may be fundamental problems in the social domain. In other animals, perinatal alcohol exposure alters aggression, active social interactions, social communication and recognition, maternal behavior, and sexual behavior in adults. In conclusion, research suggests that people exposed to alcohol during development may exhibit striking changes in social behavior; the animal research suggests that these changes may be largely the result of the alcohol insult and not the environment.

Androgen threshold to activate copulation differs in male rats prenatally exposed to alcohol, stress, or both factors

Few male rats prenatally exposed to a combination of alcohol and stress copulate spontaneously. This study determined adult sensitivity to testosterone (T) in males prenatally exposed to alcohol, to stress, or to both factors. Sexually naive males were tested with receptive females following castration and implantation of 20-, 30-, or 45-mm Silastic T-filled capsules. Serum T levels provided by these implants were measured. The behavior shown by males exposed only to prenatal alcohol did not differ from untreated control animals at any T dosage. Prenatal stress alone diminished the copulatory potential below control levels only when the intermediate T dosage was provided. Few males exposed to both alcohol and stress copulated under the lowest or the intermediate dose of adult T replacement, but most ejaculated normally when the largest capsule was implanted. The threshold to the sexual behavior-activating-properties of adult T exposure was moderately raised by prenatal stress but was severely affected when prenatal stress was combined with alcohol. We conclude that a diminished sensitivity to androgen in adulthood underlies some copulatory deficits resulting from treatments that alter fetal T levels. Such deficits may be concealed when behavior is evaluated in gonadally intact animals.

Effects of prenatal testosterone on sex and age differences in behavior elicited by stimulus pups in the rat

From Days 14 to 19, pregnant Wistar rats were treated with either 2 mg of testosterone propionate (TP) or vehicle. Thirty-, 60-, and 90-day-old offspring were tested individually during 15 min daily on 4 days with a stimulus litter, and pup-oriented and non-pup-oriented behaviors were recorded. Sex differences in pup-oriented behaviors observed in oil groups were eliminated by TP treatment, which affected mainly females. Additionally, TP treatment increased the frequency of self-grooming and decreased the time spent near the pups and the frequency of sniffing and pawing only at 90-days of age. Hiding behavior only occurred at 30 days of age, while pawing near the pups and lying-down behavior was observed mainly in adults. Results show that sex differences in behavior are present before subjects become sensitized to show evident maternal behavior, and suggest that prenatal androgens play an important role in the manifestation of these sex differences and that its effects depend on developmental factors.

Gonadotropin secretion in infantile rats exposed to ethanol in utero

Previous studies have shown that fetal alcohol exposure (FAE) alters reproductive function in both male and female rats. In females, FAE delays the onset of puberty, reduces a preovulatory-like LH surge, and results in an early onset of acyclicity. In males exposed to ethanol in utero, the perinatal surge of testosterone is reduced. During the infantile period of the female rat, there is a dramatic increase in plasma follicle-stimulating hormone (FSH), which is thought to play a role in initiating ovarian activity and perhaps the onset of puberty. In this study, we determined the effects of FAE on the patterns of gonadotropin secretion during the infantile period [postnatal days (PND) 8-21] in both male and female rats. Timed pregnant dams were fed a liquid diet containing 35% ethanol-derived calories during the final week of gestation. Control dams were fed either an isocaloric diet with sucrose substituted for ethanol (pair fed, PF) or laboratory chow (chow fed, CF). Male and female pups were sacrificed on PND 8, 10, 12, 15, 18, and 21, and trunk blood was collected. In males, LH levels decreased to a nadir on PND 18, and this decrease was blunted by FAE (p < 0.05). In contrast, FSH secretion was not altered by FAE. In females, plasma FSH levels were greater than males, and increased to peak on PND 12. This FSH peak was significantly delayed in FAE females (p < 0.02). There was no age-related change in LH levels in FAE females, and LH levels were not altered by FAE. The delayed peak of FSH secretion by FAE correlates with the delay in puberty previously seen in females. To investigate this further, we examined the possibility that the delay in the peak of serum FSH in FAE females is due to a reduced number of FSH-producing gonadotrophs. FSH-containing gonadotrophs were identified by immunocytochemistry. Cell counts of FSH-immunoreactive cells in pituitaries from PND 8, 15, and 21 control-fed and FAE female rats showed developmental increases in the number of FSH gonadotrophs per unit area (p < 0.001), but no treatment differences were observed. Overall, these data show that fetal alcohol exposure can alter gonadotropin secretion in infantile life in male and female rats. Importantly, the delay in FSH secretion in females may ultimately play a role in the delay in puberty observed in the FAE female rat.

Alterations in the estrogen sensitivity of hypothalamic proenkephalin mRNA expression with age and prenatal exposure to alcohol

Studies suggest that exposure to alcohol in utero causes reproductive and neuroendocrine deficits in adult female rats. The ventromedial nucleus of the hypothalamus (VMN) is an estrogen-sensitive brain region which is regarded as a primary locus for modulating female reproduction. Proenkephalin (PE) mRNA expression in the VMN is dramatically increased by estrogen and this elevation is thought to be involved in modulating female reproductive behavior and neuroendocrine function. To examine whether prenatal alcohol exposure has long-term effects on the ability of estrogen to influence hypothalamic PE mRNA levels, female rats at 2-3, 6-7 or 15-18 months of age, derived from alcohol- or control-fed dams, were studied. 7 days following ovariectomy, animals received either estrogen or sham treatment for 2 days prior to sacrifice. PE mRNA levels in the VMN and striatum were determined by in situ hybridization histochemistry. Film autoradiogram density, numbers of PE mRNA-expressing cells and exposed silver grains/cell were analyzed. Estrogen treatment increased hybridization density, the number of PE mRNA-expressing cells and PE mRNA (grains) level/cell in the VMN of normal adult female rats. In old rats, estrogen increased the number of PE mRNA-expressing cells without up-regulating PE mRNA grain density/cell. In fetal alcohol-exposed (FAE) female rats, the number of cells that expressed PE mRNA did not increase following estrogen treatment at any age. Elevation of grain density/cell following estrogen was observed in FAE animals but only at 7-8 months of age. Overall, these data indicate that the estrogen responsiveness of PE mRNA expression in the VMN declines with age and, furthermore, prenatal exposure to alcohol blunts estrogen's effects on PE mRNA expression in the adult VMN. These finding may help to explain the mechanisms underlying the loss of reproductive function observed in FAE females.

Prenatal ethanol exposure: effects on androgen and nonandrogen dependent behaviors and on gonadal development in male rats

Prenatal exposure to alcohol may impair gonadal and behavioral development in male rats, possibly via reduction of perinatal androgenization. We examined locomotor activity on postnatal day 18 (PND 18), which is not influenced by perinatal androgens and juvenile play and testicular development (testes weight), which are dependent on perinatal androgen exposure, in rats whose dams consumed ethanol during pregnancy. Male offspring of pair-fed and lab chow-fed dams served as controls. Despite reduced anogenital distance at birth, indicating compromised perinatal androgenization, fetal ethanol-exposed males did not exhibit demasculinization of play behavior. Hyperactivity in fetal ethanol-exposed males indicated that the treatment regimen was sufficient to produce behavioral deficits. Testes weight was reduced in both ethanol-exposed and pair-fed offspring, indicating that nutritional deficits associated with maternal ethanol intake may impair normal gonadal development in male rats. The findings suggest that fetal ethanol exposure may influence gonadal development but not necessarily affect a gonadal hormone-dependent behavior.

Sexual orientation of male mouse offspring prenatally exposed to ethanol

Pregnant mice were intubated with either low (2 g/kg) or high (4 g/kg) dose of ethanol twice daily throughout the last third of the gestational period (from dg14 to dg18: gestational day; plug positive = dg 0). Ninety days after birth, the sexual orientation test was conducted on male offspring. This test was designed to observe a two-choice preference for either male or female partners in a setting in which the test animal could move freely between the two incentive compartments within which a stud male and an estrous female had been placed. We found that young adult males that had been exposed to ethanol prenatally have a decreased preference for the opposite sex and an increased preference for the same sex as a partner, although their physical development was apparently unaffected.

Decreased postnatal testosterone surge in male rats exposed to ethanol during the last week of gestation

Prenatal alcohol exposure in the rat is known to interfere with the neurobehavioral sexual differentiation of the male brain. Because normal sexual differentiation of the male brain requires adequate levels of perinatal testosterone, we examined the effect of prenatal ethanol exposure on (1) the postnatal surge of testosterone and (2) the in vitro secretion of testosterone in response to luteinizing hormone (LH) stimulation of testes from fetal alcohol exposed (FAE) animals and controls. Sprague-Dawley dams were administered a fortified liquid diet containing 35% ethanol-derived calories, a pair-fed (PF) isocaloric liquid diet, or given ad libitum access to dry lab chow (CF). Dams were administered the liquid diets from days 7 or 14 through parturition. The postnatal surge of testosterone in FAE males was studied only in animals exposed to ethanol from day 14 through parturition. In the first experiment, FAE and PF males and females were delivered by cesarean section on day 22 of gestation (E22) and trunk blood collected at 0, 60, 120, and 240 min after parturition. Experiment 2 measured plasma testosterone in male pups that were killed at 0, 60, 120, 240, 360, and 480 min after delivery. Results showed that the postnatal testosterone surge of FAE males in both experiments was significantly attenuated compared with PF controls. No effect of prenatal ethanol was observed in female offspring. Female testosterone levels were several fold lower than male littermates, and no evidence of a postnatal testosterone surge was observed. Production of testosterone from testes was studied using an automated perifusion system.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of alcohol, acetaldehyde, and salsolinol on beta-endorphin secretion from the hypothalamic neurons in primary cultures

The effect of ethanol, acetaldehyde, and salsolinol on hypothalamic beta-endorphin secreting neurons is studied by using rat fetal hypothalamic neurons in primary culture. Exposure of these neuronal cells to different concentrations of ethanol (12.5-50 mM) and acetaldehyde (12.5-50 microM) caused a concentration-dependent increase in the secretion of beta-endorphin. Salsolinol (12.5-50 microM) did not cause any significant change in the secretion of beta-endorphin. Ethanol's effect was short-lasting (2 hr). Acetaldehyde's effect on beta-endorphin secretion was greater and longer lasting, as compared with ethanol. Ethanol and salsolinol do not have any effect on cell viability, whereas higher concentrations of acetaldehyde appear to reduce the number of viable cells after 6 hr of treatment. None of the above treatments has any effect on cellular DNA content. These results suggest that ethanol is a potent stimulator of hypothalamic beta-endorphin. These results also show for the first time that ethanol's metabolite acetaldehyde is more potent in stimulating beta-endorphin secretion and may be significant in the ethanol regulated beta-endorphin secretion.

Prenatal ethanol exposure alters ethanol-induced dopamine release in nucleus accumbens and striatum in male and female rats

Using in vivo microdialysis, ethanol-induced dopamine release in nucleus accumbens and striatum was examined in adult male and female Long-Evans rats exposed prenatally to ethanol and in controls. Following dialysis, ethanol intake was measured in an operant paradigm. Control rats showed increased dopamine release in nucleus accumbens and striatum in response to 0.5 g/kg ethanol, but not to 1.0 g/kg. Fetal ethanol-exposed rats showed no dopamine response at 0.5 g/kg. At 1.0 g/kg, fetal ethanol-exposed males showed increased dopamine release in both structures. Prenatally exposed females showed no change in accumbens, and decreased release in striatum. Fetal ethanol exposure did not significantly influence ethanol intake. The findings suggest that prenatal ethanol exposure influences subsequent neurochemical responses to ethanol; however, how these neurochemical measures are related to ethanol intake could not be determined in the present study. Data are discussed in terms of sex-specific shifts in the dose-response function for ethanol-induced dopamine release resulting from prenatal ethanol exposure.

Comparison of two weeks versus one week of prenatal ethanol exposure in the rat on gonadal organ weights, sperm count, and onset of puberty

Sprague-Dawley dams from Harlan Ind. (Indianapolis, IN) were administered a fortified ethanol liquid diet containing 35% ethanol derived calories for two weeks (E-2) beginning on day 7 or one week (E-1) beginning on day 13 of gestation and continuing through parturition. Control dams were pair-fed an isocaloric liquid diet containing no ethanol during these periods or remained on lab chow and water. E-2 dams consumed an average of 13.52 g ethanol/kg bwt during the first week of exposure (days 8-14) and 12.50 g ethanol/kg bwt the second week (days 14-20). E-1 dams consumed significantly less than E-2 dams during the second week (9.75 g/kg; p < 0.0001). Although the lower consumption in E-1 dams led to a significant decrease in maternal weight gained during the few days of pregnancy compared to E-2 dams, birthweights of E-1 offspring were significantly heavier than those of E-2 offspring (p < 0.05). No effect of ethanol was detected on anogenital distance at birth in either sex. Puberty was delayed in female offspring of both E-1 and E-2 dams (p < 0.01) as measured by age of vaginal opening. These data suggest that the primary teratogenic actions of ethanol in the rat on fetal growth, as well as delayed puberty in females, occur in the last week of gestation. In adult E-2 males, testis weight was significantly heavier than all other groups when indexed to body weight. No effect of prenatal ethanol exposure was observed on the indexed weights of prostate, epididymis, or seminal vesicles.(ABSTRACT TRUNCATED AT 250 WORDS)

Delayed onset of puberty and subtle alterations in GnRH neuronal morphology in female rats exposed prenatally to ethanol

Fetal alcohol exposed (FAE) animals exhibit physiological and behavioral deficits associated with reproduction including alterations in LH secretion and decreased sex behavior. Such deficits led us to examine the morphological characteristics and number of GnRH neurons in female rats prenatally exposed to ethanol. Sprague-Dawley dams (Harlan, Indianapolis, IN) were administered a fortified liquid diet (Sustacal) containing 35% ethanol derived calories from day 7 through parturition. Controls were pair-fed a similar isocaloric diet containing no ethanol during this period or allowed access to dry food pellets ad lib. Compared to both control groups, puberty was found to be significantly delayed in females that were exposed prenatally to ethanol. The median age of vaginal opening for chow-fed and pair-fed controls was 34-35 days compared to 38-39 days for FAE animals. A subgroup of these females was selected at 44 days of age on the basis of delayed onset of puberty and compared with pair-fed controls for the number and morphology of GnRH-immunoreactive staining (ir) neurons in the medial preoptic area (MPOA) and the diagonal band of Broca (DBB), regions which contain the majority of GnRH-IR cells in the rat brain. In both areas, light microscopic study revealed no differences in GnRH-IR cell number, nor were differences detected among the groups in the number of bipolar versus unipolar cells. However, a significant increase was observed in FAE brains compared to controls in the ratio of GnRH-IR neurons with irregular processes compared to smooth cell contours.(ABSTRACT TRUNCATED AT 250 WORDS)

The effect of prenatal ethanol exposure on scentmarking in the C57BL/6J and C3H/He mouse strains

In utero exposure to ethanol has been shown to alter sexually dimorphic behaviors in rats. However, it is not clear whether this phenomenon is robust in other species, such as the mouse, which is sensitive to ethanol-induced birth defects. Further, it is not known whether significant differences exist across murine strains. If similar to the classic teratogenic effects of ethanol, it would be expected that strain differences in sensitivity should be evident, with some strains demonstrating an alteration in sexually dimorphic behavior and other strains demonstrating little or no effect. As a first attempt to address these issues, we have examined two mouse strains widely used in prenatal alcohol research, the inbred C3H/He and C57BL/6J strains. Scentmarking was selected as the behavior of interest. It is robustly sexually dimorphic in the rat and mouse, with males marking more than females and preliminary reports have demonstrated that in utero ethanol exposure reduces this behavior in the male rat. In the mouse strains selected for study, pregnant females were provided with either a liquid diet consisting of 25% ethanol-derived calories or pair-fed an isocaloric liquid diet from gestation days 6-18. An additional control group was included which was fed laboratory chow ad lib throughout gestation. Male and female offspring of each strain were tested for scentmarking at 65-75 days of age. As expected, results showed that the effect of prenatal ethanol exposure on scentmarking varied with both strain and sex. In the C3H/He strain, scentmarking was reduced significantly in male ethanol-exposed offspring (i.e., the males were feminized).(ABSTRACT TRUNCATED AT 250 WORDS)

Fetal alcohol exposure and effects of LHRH and PMA on LH beta-mRNA expression in the female rat

Fetal alcohol exposure (FAE) is associated with a variety of physiological and behavioral dysfunctions. Effects of FAE on reproduction have been described that include delayed puberty, altered gonadotrophin secretion and steroidogenesis, and altered sexual behavior. Earlier work suggested that pituitary function was compromised in adult fetal alcohol-exposed female rats. This study examined the effects of LHRH and PMA in vitro on LH beta-mRNA expression in pituitary fragments from FAE animals; a separate experiment examined the effects of estradiol-17 beta on LH beta-mRNA under similar conditions. The results indicate that the pituitary glands of FAE females have a reduced ability to respond to these three stimuli. The reason for this reduced responsiveness to LHRH, PMA, and estradiol-17 beta is not clear, but the alterations suggest that LH synthesis is impeded following fetal ethanol exposure.

Sexual receptivity of adult female rats prenatally intoxicated with alcohol on gestational day 8

On gestational day 8 (GD 8), pregnant albino rats received two IP injections, spaced by 4 hours, of either ethanol (2.9 g/kg in 24% v/v saline solution) or saline. Adult females exposed to ethanol in utero showed greater sensitivity to estrogen, but not to estrogen plus progesterone, for induction of lordotic response. The 5-HT1 receptor agonist 5-methoxy-N,N-dimethyl-tryptamine (5-MeODMT) had a significantly smaller effect in inhibiting lordosis response in experimental rats. The greater sensitivity to estrogen and lower sensitivity to the receptor agonist could be a consequence of long-term changes in central neurotransmitter systems induced by acute intoxication with ethanol on GD 8.

Effects of prenatal ethanol exposure on glucocorticoid receptors in rat hippocampus

Animals exposed to ethanol in utero are typically hyperresponsive to stressors in adulthood as indicated by increased adrenocortical activation and/or deficits in response inhibition or recovery following stress. In the present study we reasoned that a deficit in feedback control of pituitary-adrenal activity might underlie this hyperresponsiveness in fetal ethanol-exposed (FEE) animals. Further, we hypothesized that a long-term decrease in hippocampal glucocorticoid receptor concentration, induced by prenatal ethanol exposure, might mediate such a deficit in pituitary-adrenal feedback regulation. Male and female Sprague-Dawley rats from prenatal ethanol (E), pair-fed (PF), and control (C) treatment groups were tested in adulthood for determination of cytosolic hippocampal glucocorticoid receptor binding. No significant differences in specific binding (Bmax) or binding affinity (Kd) of either type I or type II glucocorticoid receptors were found among animals from E, PF, and C conditions. There were, however, significant sex differences in receptor concentration and binding affinity; females showed significantly greater maximal binding and significantly lower binding affinity than males. These data do not support the hypothesis that prenatal ethanol exposure induces a long-term decrease in hippocampal glucocorticoid receptors in animals tested under basal nonstressed conditions. However, these data do not preclude the possibility that receptor binding capacity may be differentially affected in E, PF, and C animals during stress.

Sexual orientation in male rats prenatally exposed to ethanol

Previous studies have shown that prenatal ethanol exposure causes feminization of the male offspring, as evidenced by display of female sexual response (lordosis), when mounted by a stud male. In the present study we examined whether or not the feminization induced by prenatal ethanol exposure also affected a different aspect of sexually motivated behavior, namely, the approach towards a receptive female normally displayed by male rats. The testing apparatus consisted of an open-field arena with two small boxes in which were placed the stimulus animals, in one box a male rat, in the other a receptive female. The partition between the stimulus and the experimental animals consisted of a metal net allowing both animals to see and smell each other without actual physical contact. The tendency to approach the receptive female or the male was assessed by the proportion of the observation period the experimental male spent near the receptive female or the male rat, respectively. The experiment was performed on the adult male offspring of mothers consuming a liquid diet containing 5% ethanol, giving rise to a daily ethanol intake of about 14 g/kg. One group of control mothers was given a liquid diet without alcohol but isocaloric with the alcohol-containing diet. Another control group had free access to water and lab chow. The results showed that male offspring of both control groups devoted 29% of the observation period near the receptive female as compared to 13% near the male. The ethanol-exposed males on the other hand devoted as much time, 20%, to the male as to the receptive female.(ABSTRACT TRUNCATED AT 250 WORDS)

Prenatal ethanol exposure and opiatergic influence on puberty in the female rat

Fetal alcohol exposure (FAE) is associated with a variety of physiological and behavioral dysfunctions, including deficits to reproductive function. FAE has also been shown to increase brain beta-endorphin levels. This study sought to determine whether the common delay of the onset of puberty in fetal alcohol-exposed animals could be due to increased opiate inhibition of LH release. Prepubertal female rats were injected with an opiate antagonist, naltrexone, over days 26-29. This naltrexone treatment led to an acceleration of vaginal opening and first estrus in FAE animals; had no effect on chow-fed or pair-fed controls. The vaginal opening and first estrus advancement in FAE animals occurred at a lower body weight indicating independence from growth-promoting effects of the drug treatment. It is concluded that delays in puberty in FAE animals are not directly due to pituitary pathology, but are related, at least in part, to increased inhibition of the LHRH neuron and functional impairment of gonadotrophin secretion.

Indices of stress in rats: effects of sex, perinatal alcohol and artificial rearing

Three groups of rats were normally reared by dams, artificially reared but not exposed to alcohol or artificially reared and exposed to 6.6 g/kg/day of ethanol condensed into 8 h of each 24-h period. Alcohol exposure was given from postnatal day 4 through 9 and artificial rearing was conducted from postnatal day 4 to 12. In adulthood, approximately half of the rats were fitted with a chronic jugular catheter and were exposed to swim stress for 1 min in 21 degrees C water. Alcohol exposure augmented the corticosteroid stress response to the swim stress in female rats but not in male rats. The other half of the animals were tested for acquisition and extinction of a conditioned emotional response (CER). While alcohol exposure had no effects on the CER, extinction of CER was greatly accelerated by artificial rearing alone in female rats but not in male rats. Taken together, these findings suggest that some aspects of the stress response in female rats are more vulnerable to insults during the early postnatal period than those in male rats and that the insult-induced alterations can affect hormonal and behavioral measures differentially.

Prenatal ethanol and the prepubertal sexually dimorphic nucleus of the preoptic area

The volume of the sexually dimorphic nucleus of the preoptic area of the hypothalamus (SDN-POA) was determined in 14-31-day-old male and female rats whose mothers received a liquid diet containing 5% w/v ethanol from day 8 of gestation to parturition. Pair-fed dams received as a nutritional control an equal volume of an isocaloric liquid diet with maltose-dextrin in place of ethanol. Normal controls had laboratory rat chow and water available ad lib. The SDN-POA volume of ethanol-exposed males was significantly reduced compared to the pair-fed and normal males, and became indistinguishable from the SDN-POA volumes of the pair-fed and normal females. Ethanol-treated females also had a markedly reduced SDN-POA volume compared to the pair-fed and normal females. Our findings indicate that the SDN-POA of prepubertal rats of both sexes is sensitive to the effects of in utero ethanol exposure. While plasma testosterone, progesterone and estradiol titers, which we measured in fetuses on gestation day 22, were differentially affected by maternal ethanol consumption, the alterations by themselves cannot adequately explain the effects of prenatal ethanol exposure on the developing SDN-POA.

Effects of fetal alcohol exposure on brain 5 alpha-reductase/aromatase activity

The local formation of the testosterone metabolites 5 alpha-dihydrotestosterone and 17 beta-estradiol within the hypothalamic-preoptic area (HPOA) is essential for the normal sexual differentiation of the male central nervous system (CNS) during a perinatal critical period in the rat. Testosterone, the substrate for these reactions, is derived primarily from synthesis within the fetal testis. Fetal alcohol exposure (FAE) during this critical period profoundly affects fetal testicular steroidogenesis as well as the sexual differentiation of the CNS. The present study was conducted to determine whether FAE directly affects the local metabolism of androgens within the developing CNS or whether reduced androgen substrate, via a testicular lesion, is a more likely explanation for the known effects of FAE on the CNS. The enzymatic activities of 5 alpha-reductase and aromatase were simultaneously quantitated in the newborn rat HPOA following FAE. Neither the enzymatic activity of 5 alpha-reductase, aromatase nor their ratio were significantly influenced (P greater than 0.05) by FAE with respect to controls. FAE apparently does not alter the disposition of the androgens within the newborn rat HPOA. These results support the hypothesis that FAE alters the sexual differentiation of the CNS through inhibition of androgen biosynthesis at the level of the perinatal rat testis.

Inhibition of testicular steroidogenesis in the neonatal rat following acute ethanol exposure

We have previously reported detrimental effects of in utero ethanol exposure on testicular steroidogenic enzyme activity in newborn rats. It is now reported that in utero ethanol exposure during Day 12 of gestation through birth has no apparent morphological effect on the testes of Day 1 neonatal rats. It appears that the detrimental effects of ethanol on testicular steroidogenesis can be manifested at the biochemical level in the absence of morphological effects. However, it remained unknown as to whether acute exposure to ethanol would elicit similar biochemical effects as chronic ethanol exposure on testicular steroidogenesis. To test this possibility ethanol was injected at 0, 1, or 2 g/kg intraperitoneally (IP) into rats of various postnatal ages. Plasma ethanol and testosterone levels as well as testicular 17 alpha-hydroxylase and C17,20-lyase activities were measured. The results indicate that acute exposure to ethanol significantly (p less than 0.05) inhibits the catalytic activity of testicular 17 alpha-hydroxylase in the newborn rat testis. This inhibition was specific since the activity of testicular C17,20-lyase was not affected. In conjunction with the reduction in testicular enzyme activity, plasma testosterone levels were reduced to 30% of the control levels in newborn animals receiving ethanol. In older animals, i.e., postnatal Day 20 and 40 rats, plasma testosterone levels were reduced, but not significantly, following ethanol treatment. Furthermore, testicular enzyme activity was not significantly reduced following ethanol treatment in these same older animals. These results suggest that the newborn rat testis is especially sensitive to the effects of ethanol.

Prenatal ethanol exposure alters steroidogenic enzyme activity in newborn rat testes

We have examined the in utero effects of ethanol exposure on testicular steroidogenesis in newborn male pups. Pregnant Sprague-Dawley rats were fed a liquid ethanol diet (35% ethanol-derived calories), a pair-fed isocaloric liquid diet, or a standard laboratory rat chow and water diet beginning on Day 12 of gestation and continuing through parturition. Although there were no significant differences in the enzymatic activity of 5-ene-3 beta-hydroxysteroid dehydrogenase/isomerase or C17,20-lyase, the enzymatic activity of 17 alpha-hydroxylase was significantly (p less than 0.01) reduced (i.e., approximately 36%) in the ethanol-exposed pups compared to those from the pair-fed and chow treatment groups. This lesion in testicular steroidogenic enzyme activity in newborn male pups exposed to alcohol in utero was transient as 17 alpha-hydroxylase activity from the ethanol-exposed animals returned to control levels by postnatal Day 20 and remained at control levels through adulthood (postnatal Day 60). These data suggest that the suppression of the perinatal testosterone surge in male rats exposed to alcohol in utero and the associated long term demasculinizing effects of prenatal ethanol exposure might be the result of reduced testicular steroidogenic enzyme activity in the perinatal animal.

Effects of chronic and acute ethanol treatment during prenatal and early postnatal ages on testosterone levels and sexual behaviors in rats

This study was prompted by previous findings that prenatal ethanol exposure may interfere with the differentiation of the sexual behavior in rats. Ethanol (6 g/kg) administered daily from day 15 postconception, resulted in elevated testosterone (T) levels on Day 18 in male and female fetuses. No alterations of sexual behavior in the ethanol-treated male offspring were seen under these conditions. However, in ethanol-treated female offspring the onset of regular estrous cycling was significantly delayed. Acute treatment with doses of ethanol, 2, 4 or 6 g/kg, was ineffective in influencing plasma T levels of the fetuses. Acute treatment with 3 g/kg ethanol did not prevent the rise of T levels normally occurring immediately after birth. In adulthood, but not at prepubertal age (Day 30), treatment of male rats with 2 g/kg ethanol caused a depression of plasma T levels. Possible mechanisms affected by ethanol exposure and influencing on the fetal development were discussed.

Prenatal ethanol and stress in mice: 1. Pup behavioral development and maternal physiology

On days 12 to 17 of pregnancy, B6D2F1 mice were pair-fed liquid diets containing either 25% ethanol-derived calories or an isocaloric amount of maltose-dextrin. During this period, half the mice in each dietary condition also underwent two daily one-hour periods of restraint stress. A fifth group, given lab chow and water ad lib, was left undisturbed throughout gestation. Neither treatment affected offspring body weight on days 22 or 32 postconception, but undernutrition produced by the pair feeding procedure reduced day 32 body weight in all groups relative to the ad lib-fed group. Both prenatal ethanol and pair feeding led to delayed neurobehavioral development on day 32, while prenatal stress significantly reduced the degree of developmental delay caused by these factors. In a second study, restraint stress significantly reduced blood alcohol concentrations in pregnant dams on day 15 of gestation while elevating plasma corticosterone concentrations, and this elevation was consistent regardless of the dietary condition of the dam. The pair feeding procedure also produced corticosterone elevations but the effect of ethanol was not significant. These results suggest that prenatal stress in the presence of other physiological insults may act to counter the actions of those insults.

Lack of prenatal testosterone surge in fetal rats exposed to alcohol: alterations in testicular morphology and physiology

Pregnant Sprague-Dawley rats were administered a liquid alcohol diet (35% ethanol-derived calories), a pair-fed isocaloric diet, or dry food pellets beginning on Day 14 of gestation and continuing until parturition. Testosterone levels in male fetuses were measured on Days 17 through 20 of gestation. The normal surge of testosterone on Days 18 and 19 was present in controls, but notably absent in male fetuses exposed to alcohol. Light microscopic examination of the testes at birth revealed a reduction in the number of leydig cells in the alcohol exposed group and the presence of a large number of vacuoles in the seminiferous tubules. In vitro studies of fetal testes at 18 and 22 days of gestation revealed that this in utero alcohol exposure regimen produced a marked insensitivity to rat LH (10 ng/ml) stimulation of testosterone secretion compared to controls. The response to ethanol (160 mg/dl) in alcohol exposed testes was characterized by a long-lasting suppression of testosterone compared to a large increase observed in control testes. No differences in anogenital distance were observed among the groups. Together, these data may explain some of the long-term feminizing and demasculinizing effects on reproductive and nonreproductive sexually dimorphic behaviors observed in adult males prenatally exposed to alcohol.

Impaired spatial navigation in adult female but not adult male rats exposed to alcohol during the brain growth spurt

Two groups of male and female rats were given the same dose of alcohol using an artificial rearing procedure on postnatal days 4-10. One group received the alcohol in a condensed manner each day which caused cyclic blood alcohol concentrations (BACs) with high peaks. A second group received the alcohol in a uniform manner over each day which resulted in moderate, stable BACs. Two control groups consisted of male and female rats artificially reared but not exposed to alcohol and rats reared normally by dams. All rats were raised to 90 days of age and then tested for spatial navigation ability in the Morris water maze, which involved locating a hidden underwater platform using distal extramaze cues. Neither the alcohol treatments nor the artificial rearing had any effects on performance of adult male rats relative to suckle controls in this task. In contrast, the condensed alcohol exposure but not the uniform alcohol exposure resulted in detrimental performance in the Morris water maze by adult female rats. When the ability to locate and escape onto a visible platform was examined, there were no differences between the female groups given condensed alcohol exposure or artificially reared on milk solution alone. Thus, exposure to high BACs during the brain growth spurt has a lasting and selective detrimental effect on spatial navigation learning in adult female but not adult male rats.

Effects of prenatal alcohol exposure on the sexually dimorphic nucleus of the preoptic area of the hypothalamus in male and female rats

Prenatal alcohol exposure can produce a variety of behavioral and physiological alterations, including changes in sexually dimorphic behaviors. It has been proposed that alcohol alters these behaviors by altering prenatal androgen and/or other steroid levels. This study was designed to examine the effects of prenatal alcohol exposure on a sexually dimorphic neuroanatomical structure, namely, the sexually dimorphic nucleus of the preoptic area of the hypothalamus (SDN-POA). This nucleus is larger in males than females and is sensitive to perinatal sex steroid exposure. The SDN-POA was examined in 70-80-day-old male and female rats whose mothers received on days 6-20 of pregnancy either a liquid diet containing 35% ethanol-derived calories (EDC) or a 0% EDC isocaloric pair-fed liquid diet. An ad libitum lab chow control group was also included (LC). Both volume and average cell size of the SDN-POA were markedly smaller in alcohol-exposed males relative to 0% EDC and LC controls. In contrast, prenatal alcohol exposure did not appear to affect SDN-POA volume or cell size in females. Prenatal alcohol exposure did not significantly alter the volume of a nearby nucleus, the nucleus of the anterior commissure, in either sex. These findings support the hypothesis that prenatal alcohol exposure alters sexual differentiation in males, perhaps by altering some aspect of the prenatal androgen environment. The absence of any effect in 35% EDC females suggests that males and females may be differentially sensitive to alcohol's effects on this nucleus.

Influence of prenatal exposure to cimetidine and alcohol on selected morphological parameters of sexual differentiation: a preliminary report

Pregnant rats were administered ethanol, cimetidine or a combination of both drugs from day 14 of gestation until parturition. Ano-genital (AG) distance measured at birth was significantly reduced in males exposed to cimetidine, but not in males or females exposed to alcohol. AG distance in males exposed to both ethanol and cimetidine also was not reduced, indicating a possible protective influence of ethanol against this effect of cimetidine. Birthweights in both sexes were reduced by prenatal ethanol exposure, both alone and with cimetidine exposure. Prenatal cimetidine exposure, both alone and in combination with ethanol significantly reduced seminal vesicle weights of adult males. However, no long-term effects of ethanol or cimetidine were observed on adrenal, testicular or ovarian weights. These results indicate that when fetal alcohol exposure is restricted to the critical prenatal period for hormonal actions on sexual differentiation, testosterone levels are maintained at an adequate level for normal morphological development of the genitalia.

Effects of prenatal testosterone propionate treatment on saccharin preference of adult rats exposed to ethanol in utero

Prenatal exposure to alcohol feminizes saccharin consumption patterns in adult male rats. To study the involvement of testosterone in this effect, testosterone propionate (TP) was administered to pregnant dams in an attempt to reverse that feminized saccharin consumption pattern in the male offspring. Female offspring were also studied to determine the effect of TP on saccharin preference in normal males and females. During the last week of gestation, dams were administered a liquid diet containing 35% ethanol derived calories, an isocaloric liquid diet containing no ethanol, or Purina Lab Chow. Half of the dams in each group received twice daily injections of TP, the other half were injected with the oil vehicle. Saccharin consumption of adult fetal alcohol exposed (FAE) males from dams administered oil or TP was significantly greater than controls, indicating that the feminized pattern of saccharin consumption of FAE males cannot be overcome with TP administration during the prenatal period. In controls, prenatal TP exposure alone was found to increase adult saccharin consumption in both sexes. Prenatal administration of TP was also found to markedly depress body weight of offspring of dams receiving the liquid diets compared to offspring from dams receiving the same diets plus oil injections. Body weights of offspring from TP or oil injected dams receiving the chow fed diets during pregnancy did not differ.

Postnatal or in utero ethanol exposure reduction of the volume of the sexually dimorphic nucleus of the preoptic area in male rats

Adult male rats exposed to alcohol in utero results in reduction of the volume of the sexually dimorphic nucleus of the preoptic area (SND-POA). Reduction of the volume of this nucleus is also significantly reduced in rats exposed to ethanol postnatally compared to the volume in animals not exposed to ethanol (P less than 0.05). The results indicate that ethanol exposure during the postnatal period of brain development in rats is equally effective as in utero ethanol exposure in development of the SDN-POA volume. This report substantiates others demonstrating the deleterious effects of ethanol consumption during the 'critical' period of brain development.

Morphometric changes in alcoholic mice of neurons of areas 6 and 17 and ependyma of the subcommissural organ

We have performed a karyometric study of the postnatal development of the subcommissural organ (SOC), the subjacent thalamic ependyma, and the pyramidal neurons of layer V of the motor and visual cortical areas, in alcoholic male albino mice, aged 25-100 days. Ethyl alcohol was added to the drinking water at a concentration of 20%, from birth until the day of sacrifice. Our results show that alcoholism affects the SOC ependyma and the motor cortex, and, apparently, does not affect the ventricular thalamic ependyma and the visual cortex. We suggest a neuroendocrine mechanism to explain the SOC answer, and a functional deprivation to explain the changes in the motor cortex.

Impaired maternal behaviour and altered central serotonergic activity in the adult offspring of chronically ethanol treated dams

Female rats were given 16% ethanol solution as the sole liquid during the entire period of gestation. At birth the offspring was removed and reared by foster dams consuming normal tap water. At adult age the female offspring showed deficiencies in their maternal behaviour; they built nests of poor quality and they displayed prolonged times for retrieving pups placed outside the nest. In the whole brains of the prenatally ethanol-exposed females a decreased serotonin synthesis was observed. The offspring of the prenatally ethanol exposed mothers did not show any signs of disturbances in physical or behavioural development.

Effects of maternal ethanol consumption on the offspring sensory-motor development, ultrasonic vocalization, audiogenic immobility reaction and brain monoamine synthesis

Female rats were given 16% ethanol solution as the sole liquid during the entire period of gestation. At birth the offspring was removed and reared by foster dams consuming normal tap water. The development of sensory motor behaviour and emotional reactions was delayed by 1-2 days in the prenatally ethanol exposed pups as assessed by tests on body righting, acoustic startle response, air righting, rearing and ultrasonic vocalization. In the open-field test the normally occurring behavioural difference between the sexes was not found in the prenatally ethanol exposed pups. Both sexes of the ethanol exposed pups behaved like the female controls suggesting deficient masculinization of the ethanol exposed male pups during foetal age. Biochemical analysis of the brains showed a decreased synthesis of serotonin and dopamine.