Effects Of Fetal Ethanol Exposure Research Articles

Learning experiences comprising central ethanol exposure in rat neonates: Impact upon respiratory plasticity and the activity of brain catalase.

Fetal ethanol exposure represents a risk factor for sudden infant death syndrome, and the respiratory effects of fetal ethanol exposure promote hypoxic ischemic consequences. This study analyzes central ethanol's effects upon breathing plasticity during an ontogenetic stage equivalent to the human third gestational trimester. Ethanol's unconditioned breathing effects and their intervention in learning processes were examined. Since central ethanol is primarily metabolized via the catalase system, we also examined the effects of early history with the drug upon this system. During postnatal days 3, 5, and 7 (PDs 3-7), pups were intracisternally administered with vehicle or ethanol (300mg%). They were tested in a plethysmograph scented or not scented with ethanol odor. The state of intoxication attenuated the onset of apneas, a phenomenon that is suggestive of ethanol's anxiolytic effects given the state of arousal caused by the novel environment and the stress of ethanol administration. At PD9, pups were evaluated when sober under sequential air conditions (initial-normoxia, hypoxia, and recovery-normoxia), with or without the presence of ethanol odor. Initial apneic episodes increased when ethanol intoxication was previously associated with the odor. Pups then ingested ethanol, and brain catalase activity was determined. Pre-exposure to ethanol intoxication paired with the odor of the drug resulted in heightened enzymatic activity. Central ethanol exposure appears to exert antianxiety effects that attenuate apneic disruptions. However, during withdrawal, the cues associated with such effects elicit an opposite reaction. The activity of the catalase system was also dependent upon learning processes that involved the association of environmental stimuli and ethanol intoxication.

Examination of Age‐dependent effects of fetal ethanol exposure on behavior, hippocampal cell counts, and doublecortin immunoreactivity in rats

Ethanol is known as a potent teratogen having adverse effects on brain and behavior. However, some of the behavioral deficits caused by fetal alcohol exposure and well expressed in juveniles ameliorate with maturation may suggest some kind of functional recovery occurring during postnatal development. The aim of this study was to reexamine age-dependent behavioral impairments in fetal-alcohol rats and to investigate the changes in neurogenesis and gross morphology of the hippocampus during a protracted postnatal period searching for developmental deficits and/or delays that would correlate with behavioral impairments in juveniles and for potential compensatory processes responsible for their amelioration in adults. Ethanol was delivered to the pregnant dams by intragastric intubation throughout 7-21 gestation days at daily dose of 6 g/kg. Isocaloric intubation and intact control groups were included. Locomotor activity, anxiety, and spatial learning tasks were applied to juvenile and young-adult rats from all groups. Unbiased stereological estimates of hippocampal volumes, the total number of pyramidal and granular cells, and double cortin expressing neurons were carried out for postnatal days (PDs) PD1, PD10, PD30, and PD60. Alcohol insult during second trimester equivalent caused significant deficits in the spatial learning in juvenile rats; however, its effect on hippocampal morphology was limited to a marginally lower number of granular cells in dentate gyrus (DG) on PD30. Thus, initial behavioral deficits and the following functional recovery in fetal-alcohol subjects may be due to more subtle plastic changes within the hippocampal formation but also in other structures of the extended hippocampal circuit. Further investigation is required.

Delayed neonatal lung macrophage differentiation in a mouse model of in utero ethanol exposure

We have previously demonstrated that fetal ethanol exposure deranges the function and viability of the neonatal alveolar macrophage. Although altered differentiation of the alveolar macrophage contributes to pulmonary disease states within the adult lung, the effects of fetal ethanol exposure on the normal differentiation of interstitial to alveolar macrophage in the newborn lung are unknown. In the current study, using a mouse model of fetal ethanol exposure, we hypothesized that altered terminal differentiation of the neonatal interstitial to alveolar macrophage contributes to the observed cellular dysfunction in the ethanol-exposed newborn mouse. Control alveolar macrophage differentiation was characterized by increased expression of CD32/CD11b (P < or = 0.05) and increased in vitro phagocytosis of Staphylococcus aureus (P < or = 0.05) compared with interstitial macrophage. After in utero ethanol exposure, both alveolar and interstitial macrophage lacked the acquisition of CD32/CD11b (P < or = 0.05) and displayed impaired in vitro phagocytosis (P < or = 0.05). Ethanol significantly increased transforming growth factor-beta(1) (TGF-beta(1)) in the bronchoalveolar lavage fluid (P < or = 0.05), as well as in both interstitial and alveolar macrophages (P < or = 0.05). Oxidant stress contributed to the ethanol-induced changes on the interstitial and alveolar cells, since maternal supplementation with the glutathione precursor S-adenosylmethionine during ethanol ingestion normalized CD32/CD11b (P < or = 0.05), phagocytosis (P < or = 0.05), and TGF-beta(1) in the bronchoalveolar lavage fluid and macrophages (P < or = 0.05). Contrary to our hypothesis, fetal ethanol exposure did not solely impair interstitial to alveolar macrophage differentiation. Rather, fetal ethanol exposure impaired both neonatal interstitial and alveolar macrophage phagocytic function and differentiation. Increased oxidant stress and elevated TGF-beta(1) contributed to the impaired differentiation of both interstitial and alveolar macrophage.

Repeated ethanol exposure during late gestation alters the maturation and innate immune status of the ovine fetal lung

Little is known about the effects of fetal ethanol exposure on lung development. Our aim was to determine the effects of repeated ethanol exposure during late gestation on fetal lung growth, maturation, and inflammatory status. Pregnant ewes were chronically catheterized at 91 days of gestational age (DGA; term approximately 147 days). From 95-133 DGA, ewes were given a 1-h daily infusion of either 0.75 g ethanol/kg (n = 9) or saline (n = 8), with tissue collection at 134 DGA. Fetal lungs were examined for changes in tissue growth, structure, maturation, inflammation, and oxidative stress. Between treatment groups, there were no differences in lung weight, DNA and protein contents, percent proliferating and apoptotic cells, tissue and air-space fractions, alveolar number and mean linear intercept, septal thickness, type-II cell number and elastin content. Ethanol exposure caused a 75% increase in pulmonary collagen I alpha1 mRNA levels (P < 0.05) and a significant increase in collagen deposition. Surfactant protein (SP)-A and SP-B mRNA levels were approximately one third of control levels following ethanol exposure (P < 0.05). The mRNA levels of the proinflammatory cytokines interleukin (IL)-1beta and IL-8 were also lower (P < 0.05) in ethanol-exposed fetuses compared with controls. Pulmonary malondialdehyde levels tended to be increased (P = 0.07) in ethanol-exposed fetuses. Daily exposure of the fetus to ethanol during the last third of gestation alters extracellular matrix deposition and surfactant protein gene expression, which could increase the risk of respiratory distress syndrome after birth. Changes to the innate immune status of the fetus could increase the susceptibility of the neonatal lungs to infection.

Fetal Ethanol Exposure Disrupts the Daily Rhythms of Splenic Granzyme B, IFN‐γ, and NK Cell Cytotoxicity in Adulthood

Circadian (and daily) rhythms are physiological events that oscillate with a 24-hour period. Circadian disruptions may hamper the immune response against infection and cancer. Several immune mechanisms, such as natural killer (NK) cell function, follow a daily rhythm. Although ethanol is known to be a potent toxin for many systems in the developing fetus, including the immune system, the long-term effects of fetal ethanol exposure on circadian immune function have not been explored. Daily rhythms of cytotoxic factors (granzyme B and perforin), interferon-gamma (IFN-gamma), and NK cell cytotoxic activity were determined in the spleens of adult male rats obtained from mothers who were fed during pregnancy with chow food or an ethanol-containing liquid diet or pair-fed an isocaloric liquid diet. We found that adult rats exposed to ethanol during their fetal life showed a significant alteration in the physiological rhythms of granzyme B and IFN-gamma that was associated with decreased NK cell cytotoxic activity. These data suggest that fetal ethanol exposure causes a permanent alteration of specific immune rhythms that may in part underlie the immune impairment observed in children prenatally exposed to alcohol.

Effects of Fetal Ethanol Exposure on Pituitary‐Adrenal Sensitivity to Secretagogues

Rodents prenatally exposed to ethanol demonstrate hormonal hyper-responsiveness to stressors in adulthood. The present study examined the hypothesis that an increased sensitivity of the adrenal to ACTH and/or the pituitary to corticotropin releasing hormone (CRH) after dexamethasone suppression, may play a role in the hormonal hyper-responsiveness seen in fetal ethanol-exposed rats. Sprague-Dawley males and females from prenatal ethanol-exposed (E), pair-fed (PF), and ad libitum-fed control (C) groups were tested in adulthood (90-120 days). Testing was done in a series of two experiments carried out during the trough of the corticosterone rhythm, the time of greatest sensitivity to feedback inhibition. Twenty-four to 48 hr before testing, jugular cannulae were implanted for hormone infusion and blood sample collection. In both experiments, animals were injected intraperitoneally with dexamethasone-21-phosphate (DEX) (15 microg/100 g body weight for males or 30 microg/100 g body weight for females) 3 hr before testing to suppress endogenous hypothalamic-pituitary-adrenal (HPA) activity. Animals were given a bolus infusion of ACTH (0-0.10 mg/rat) and blood samples (0.2 cc) were drawn at 60-min intervals over 240 min for determination of plasma corticosterone (CORT) levels (Experiment 1), or were given a bolus infusion of CRH (0-20 microg/kg body wt) and samples drawn at 0, 5, 15, and 30 min for determination of plasma ACTH and CORT levels (Experiment 2). As expected, sex differences in adrenal response to ACTH and pituitary response to CRH were observed; females had higher CORT and ACTH levels than males at all concentrations of ACTH and CRH. In addition, dose-response relationships between exogenously administered ACTH or CRH and plasma CORT were demonstrated; increasing concentrations of secretagogues resulted in higher and/or more prolonged CORT responses in both males and females. There were no significant differences among E, PF, and C males or females in adrenal sensitivity to ACTH. However, prenatal ethanol exposure altered pituitary sensitivity to CRH in both males and females. E and PF males demonstrated increased plasma ACTH but not CORT compared with C males, whereas E females demonstrated increased plasma ACTH and CORT levels compared with PF and C females after CRH infusion. Together these data suggest that (1) E animals do not show increased adrenal sensitivity to ACTH compared with controls; (2) the insult of prenatal ethanol exposure may result in altered pituitary sensitivity to CRH after DEX suppression; and (3) there may be a sex-specific difference in sensitivity of the mechanism(s) underlying HPA hyper-responsiveness.

Effects of Fetal Ethanol Exposure on Pituitary-Adrenal Sensitivity to Secretagogues

Effects of Fetal Ethanol Exposure on Pituitary-Adrenal Sensitivity to Secretagogues

Reduced Gene Expression for Dopamine Biosynthesis and Transport in Midbrain Neurons of Adult Male Rats Exposed Prenatally to Ethanol

Prenatal ethanol exposure affects brain dopaminergic neuronal systems, and many of these alterations are permanent. The primary objective of this study was to determine the effects of prenatal ethanol exposure on adult mRNA expression for two key regulatory proteins in the mesolimbic and nigrostriatal dopaminergic cell groups which mediate behavioral responses to alcohol and other drugs of abuse: tyrosine hydroxylase (TH) and dopamine transporter (DAT) in the substantia nigra pars compacta (SNpc) and ventral tegmental area (VTA). To also address the effects on noradrenergic regulation, we quantitated mRNA expression for TH and norepinephrine transporter (NET) in the noradrenergic loci of the locus coeruleus (LC). Daily dietary ethanol consumption by female Sprague-Dawley rats for 3 weeks before, and continuing throughout, pregnancy decreased both DAT (approximately 68%,p < 0.002) and TH (approximately 45%,p < 0.002) mRNA expression in the VTA of adult male offspring. This prenatal exposure also suppressed DAT mRNA expression in the SNpc (approximately 81 %;p < 0.03), although TH mRNA expression in this region was not significantly altered. Prenatal ethanol exposure did not alter significantly either TH or NET mRNA expression in the LC of adult male offspring, which suggests that this brain catecholaminergic response may be limited to DA neurons. These results demonstrated that prenatal maternal ethanol consumption suppresses mRNA expression for important regulatory proteins in the mesolimbic and nigrostriatal dopaminergic systems of adult male rat offspring. These persistent prenatal ethanol-induced changes in mRNA expression may thus contribute to the persistent effects of fetal ethanol exposure on the diverse behavioral and/or metabolic responses mediated by the mesolimbic and nigrostriatal dopaminergic systems in the adult.

Reduced Gene Expression for Dopamine Biosynthesis and Transport in Midbrain Neurons of Adult Male Rats Exposed Prenatally to Ethanol

Background: Prenatal ethanol exposure affects brain dopaminergic neuronal systems, and many of these alterations are permanent. Methods: The primary objective of this study was to determine the effects of prenatal ethanol exposure on adult mRNA expression for two key regulatory proteins in the mesolimbic and nigrostriatal dopaminergic cell groups which mediate behavioral responses to alcohol and other drugs of abuse: tyrosine hydroxylase (TH) and dopamine transporter (DAT) in the substantia nigra pars compacta (SNpc) and ventral tegmental area (VTA). To also address the effects on noradrenergic regulation, we quantitated mRNA expression for TH and norepinephrine transporter (NET) in the noradrenergic loci of the locus cocruleus (LC). Results: Daily dietary ethanol consumption by female Sprague-Dawley rats for 3 weeks before, and continuing throughout, pregnancy decreased both DAT (∼ 68%, p < 0.002) and TH (∼ 45%, p < 0.002) mRNA expression in the VTA of adult male offspring. This prenatal exposure also suppressed DAT mRNA expression in the SNpc (∼ 81%; p < 0.03), although TH mRNA expression in this region was not significantly altered. Prenatal ethanol exposure did not alter significantly either TH or NET mRNA expression in the LC of adult male offspring, which suggests that this brain catecholaminergic response may be limited to DA neurons. Conclusion: These results demonstrated that prenatal maternal ethanol consumption suppresses mRNA expression for important regulatory proteins in the mesolimbic and nigrostriatal dopaminergic systems of adult male rat offspring. These persistent prenatal ethanol-induced changes in mRNA expression may thus contribute to the persistent effects of fetal ethanol exposure on the diverse behavioral and/or metabolic responses meditated by the mesolimbic and nigrostriatal dopaminergic systems in the adult.

Nerve Growth Factor and Basic Fibroblast Growth Factor Protect Rat Cerebellar Granule Cells in Culture against Ethanol‐Induced Cell Death

Neuronal cell loss is one of the most debilitating effects of fetal ethanol exposure. Cultures of cerebellar granule cells are a useful model to investigate ethanol neurotoxicity, because ethanol depletes cell numbers in these cultures, which also occurs in vivo. The primary goal of the present study was to identify and characterize agents that can ameliorate the ethanol-induced cell death that occurs in this culture system. Growth factors, such as nerve growth factor (NGF), basic fibroblast growth factor (bFGF), epidermal growth factor (EGF), and insulin-like growth factor-I (IGF-I) can prevent neuronal degeneration after toxic insult in various experimental paradigms. These growth factors were investigated in the current study to determine whether or not they can mitigate ethanol-induced death of cerebellar granule cells in culture. Results indicate that NGF and bFGF significantly reduced the ethanol-induced cell loss. Both the NGF- and bFGF-mediated neuroprotection required protein and RNA synthesis, because actinomycin D (RNA synthesis inhibitor) and cycloheximide (protein synthesis inhibitor) blocked their neuroprotective effects. In addition to its neuroprotective effect, bFGF also had a neurotrophic effect and could enhance cell survival in the absence of ethanol exposure. NGF did not have a neurotrophic effect. Neither EGF nor IGF-I was neuroprotective, although the latter did have a substantial neurotrophic effect. In conclusion, bFGF and NGF have long been recognized for their role in enhancing neuronal cell survival and differentiation. This study suggests that these growth factors can also provide neuroprotection against ethanol-induced cell death.

Nerve Growth Factor and Basic Fibroblast Growth Factor Protect Rat Cerebellar Granule Cells in Culture against Ethanol-Induced Cell Death

Neuronal cell loss is one of the most debilitating effects of fetal ethanol exposure. Cultures of cerebellar granule cells are a useful model to investigate ethanol neurotoxicity, because ethanol depletes cell numbers in these cultures, which also occurs in vivo. The primary goal of the present study was to identify and characterize agents that can ameliorate the ethanol-induced cell death that occurs in this culture system. Growth factors, such as nerve growth factor (NGF), basic fibroblast growth factor (bFGF), epidermal growth factor (EGF), and insulin-like growth factor-I (IGF-I) can prevent neuronal degeneration after toxic insult in various experimental paradigms. These growth factors were investigated in the current study to determine whether or not they can mitigate ethanol-induced death of cerebellar granule cells in culture. Results indicate that NGF and bFGF significantly reduced the ethanol-induced cell loss. Both the NGF- and bFGF-mediated neuroprotection required protein and RNA synthesis, because actinomycin D (RNA synthesis inhibitor) and cyclohex-imide (protein synthesis inhibitor) blocked their neuroprotective effects. In addition to its neuroprotective effect, bFGF also had a neurotrophic effect and could enhance cell survival in the absence of ethanol exposure. NGF did not have a neurotrophic effect. Neither EGF nor IGF-I was neuroprotective, although the latter did have a substantial neurotrophic effect. In conclusion, bFGF and NGF have long been recognized for their role in enhancing neuronal cell survival and differentiation. This study suggests that these growth factors can also provide neuroprotection against ethanol-induced cell death.

Metabolic and mitotic changes associated with the fetal alcohol syndrome.

In the USA, fetal alcohol syndrome (FAS) is the leading known cause of mental retardation. FAS is estimated to affect 4000 infants yearly in the USA with an additional 7000 children suffering various forms of fetal alcohol effects in the absence of the full syndrome. A comparable incidence would be expected in other industrialized countries, but essentially no data are available from either developing or third world countries. An understanding of the biochemical causes of FAS has been slow to develop, but progress has been made toward a molecular causation theory of FAS. This paper summarizes much of the current work as to the effects of fetal ethanol exposure on mitotic and metabolic parameters as well as ethanol's effect on the cellular signalling pathways thought to regulate these processes. Based upon these studies, it is apparent that exposure of embryonic tissue to ethanol results in decreased growth and that alcohol adversely affects a multitude of cellular functions critical for the growth of the developing organism, including inhibition of protein and DNA synthesis. In addition, ethanol alters the uptake of critical nutrients such as glucose and amino acids and causes changes in several kinase-mediated signal transduction pathways that regulate these biochemical processes.

Early handling can attenuate adverse effects of fetal ethanol exposure

The effects of early handling on physiological and hormonal responses of rats exposed to ethanol prenatally were studied. Male and female Sprague-Dawley rats from prenatal ethanol (E), pair-fed (PF), and ad lib-fed control (C) prenatal treatment groups were either handled (H) or nonhandled (NH) during the preweaning period and tested in adulthood. Early handling eliminated the deficit in preweaning weight gain observed in E compared to PF and C offspring. In adulthood, early handling eliminated the increased hypothermia observed in E and PF compared to C males following an ethanol challenge (2.0 g/kg, IP). In addition, H males displayed marginally less hypothermia overall than NH males. In contrast, handling accelerated the return to preinjection temperature in PF and C females but had no effect on E females. There were no significant differences among E, PF, and C rats in corticosterone (CORT) responses to ethanol challenge (1.5 g/kg, IP), but both males (marginally) and females in the H condition displayed higher CORT levels overall than NH rats. Early handling also eliminated the increased peak CORT response to restraint stress in E compared to C females, but did not affect the more prolonged elevation of CORT in E compared to PF and C females. There were no differences among E., PF, and C females in hippocampal type I and type II glucocorticoid receptor density or affinity. However, binding affinity of type II receptors was slightly but significantly increased in H compared to NH females. Together, these data indicate that early handling may modulate or attenuate some, but not all, of the adverse effects of fetal ethanol exposure on offspring growth and physiological responsiveness.

Reduced sensitivity of hypothalamic-preoptic area norepinephrine and dopamine to testosterone feedback in adult fetal ethanol-exposed male rats

Endocrine feedback of testosterone (T) in regulation of the hypothalamus is via the effects of T on the noradrenergic system. The current experiment was performed to determine the effects of fetal ethanol exposure (FEE) on the norepinephrine (NE) and dopamine (DA) content in the hypothalamic-preoptic area (HPOA) of adult male rats, and the response of NE and DA to T administration. Pregnant rats were exposed to diets containing either a liquid diet containing ethanol, a liquid diet containing sucrose isocalorically substituted for ethanol, or a chow and water diet. Male offspring were castrated or sham-operated at 45 days of age. The animals received either testosterone propionate (TP) or an oil vehicle. HPOA was collected at 55 days of age from each animal and NE and DA content was measured by HPLC-EC. There was no significant alteration of NE or DA content in the HPOA in FEE animals compared to catecholamine levels in animals derived from dams on the control diets. Castration had no significant effect on NE and DA content in the chow-fed or pair-fed animals. TP administration significantly reduced NE content only in the chow- and pair-fed animals but not in the FEE animals. DA content in the HPOA was not affected by castration, but TP administration also resulted in significantly reducing DA content in chow- and pair-fed castrate male rats but not in FEE castrate male rats. The results indicate that FEE alters the response of the noradrenergic and dopaminergic neurons in the HPOA to T administration. The inhibition of HPOA NE and DA content in castrated rats given high doses of TP is significantly diminished in fetal ethanol-exposed rats that is indicative of a reduction of neuronal responsiveness to steroid feedback regulation of the hypothalamus.

Altered stress responsiveness in adult rats exposed to ethanol in utero: neuroendocrine mechanisms.

In our first studies the activity of the hypothalamo-pituitary-adrenal (HPA) axis was found to be significantly greater in response to certain stressors, including ethanol, in adult rats exposed to ethanol as fetuses (fetal ethanol-exposed [FEE] rats) than in pair-fed-derived or normal controls. Stress responsiveness in FEE rats was examined further by measuring stress-induced analgesia after inescapable footshock. Analgesia was enhanced in adult FEE rats by a prolonged/intermittent naloxone-reversible form of footshock, but not by a brief/continuous naloxone-insensitive form, suggesting that the effect was opioid-mediated. Adult FEE rats showed greater analgesic and plasma corticosterone responses to morphine challenges than control rats. Preliminary results also indicated that when adult FEE rats were exposed daily to the intermittent footshock stress (10 min/day) they consumed significantly more ethanol than controls. Whether the altered stress responsiveness reflects fetal ethanol-induced effects on the development of the HPA axis was determined by measuring brain and plasma content of corticosterone in FEE and control neonates. At birth, in FEE pups, whole brain and plasma corticosterone levels are significantly raised. On postnatal day 7, when basal plasma corticosterone concentrations have attained normal values, FEE rats display blunted corticosterone responses to ethanol administration, indicating persistent effects of the fetal ethanol exposure despite its termination one week previously. The precise contribution of these neonatal hormonal alterations to the long-term effects of fetal ethanol exposure on stress responsiveness remains to be determined.

Long-term effects of fetal ethanol exposure on pituitary-adrenal response to stress

Pregnant female rats were fed either a 5.0–5.5% w/v ethanol-containing liquid diet ad lib or pair-fed the isocaloric control diet during gestation weeks 2 and 3. At 75–105 days of age, female offspring of the ethanol-treated dams showed significantly greater corticosterone responses than pair-fed- or normally-derived offspring to the stress of cardiac puncture or of noise and shaking, while pituitary-adrenal responses to exposure to a novel environment, cold or 2–3 days of fasting were normal. Adrenal sensitivity to ACTH in dexamethasone-suppressed adult offspring was unaffected by the prenatal treatment. The results demonstrate that fetal ethanol exposure enhances adult pituitary-adrenal responses to certain stressors, including alcohol as demonstrated previously, and suggest that the long-term effects may be mediated by developmental actions of alcohol on central neural mechanisms involved in the regulation of this neuroendocrine system.