Effects of ethanol on postnatal cell acquisition in the rat cerebellum

Cell cycle analysis in the rat external granular layer evaluated by several bromodeoxyuridine immunoperoxidase staining protocols

An important step in bromodeoxyuridine (BrdU) immunohistochemistry is the production of single-stranded DNA to make the incorporated BrdU accessible to the antibodies. This paper examines the effect of distinct DNA denaturation pretreatments (DNase I, sodium citrate buffer, endonuclease Eco RI and exonuclease III, and HCl hydrolysis) on detection of BrdU. We found that all the methods used in the partial denaturation of DNA combined good nuclear immunostaining with acceptable tissue integrity. We also observed that these immunohistochemical protocols revealed a spatial pattern in the distribution of DNA-synthesizing cells within the cerebellar external granular layer (EGL) of 10-day-old rats, allowing us to estimate the fraction of S-phase cells. Our results indicate that detection of BrdU-stained cells is affected by the distinct histological procedures used in such detection. Additionally, as the duration and phases of the cell cycle in EGL neuroblasts are estimated in accordance with BrdU detection, an effect on this detection can render the measurement of cell cycle inaccurate. The present work shows that DNase I and citrate buffer, at appropriate conditions, may be good alternatives for acid denaturation. However, they are less sensitive than autoradiographic techniques that use ³H-thymidine administration. Finally, current data reveal that short survival times after a single BrdU exposure do not seem to affect the cell cycle progression of the EGL neuroblasts.

Downregulation in the human and mice cerebella after ketamine versus ketamine plus ethanol treatment

To study the deleterious effects of ketamine and the potential interaction effects between ethanol and ketamine on the cerebellum, functional magnetic resonance imaging (fMRI) tests were performed on the habitual ketamine users (n = 3) when they flexed and extended their upper limbs. Another fMRI test was performed on the same participants in which they consumed alcohol (12%, 200 mL) 1 h before the test. Downregulation on the activity of cerebellum was observed and the level of activation in the cerebellum decreased dramatically in habitual ketamine users with alcohol consumption before the test. Further studies were performed by using male ICR mice receiving treatment of ketamine only [30 mg kg(-1) intraperitoneally (i.p.)] or ethanol only everyday (0.5 mL 12% orally) and those with coadministration of the above dosages of ketamine and ethanol for 3 months. Fewer Purkinje cells were observed in the cerebellar sections of ketamine treated mice under silver staining. For TUNEL test, a significant increase in the apoptotic cells were observed in the cerebella of the ketamine treated mice (P = 0.016) and of those with co-administration of ketamine and ethanol (P < 0.001), when compared with the control. A statistical significance (P < 0.001) in two-way ANOVA test indicated that there might be an interactive mechanism between ethanol and ketamine acting on the cerebellum.

Inhibition of cerebellar granule cell turning by alcohol

Ectopic neurons are often found in the brains of fetal alcohol spectrum disorders (FASD) and fetal alcohol syndrome (FAS) patients, suggesting that alcohol exposure impairs neuronal cell migration. Although it has been reported that alcohol decreases the speed of neuronal cell migration, little is known about whether alcohol also affects the turning of neurons. Here we show that ethanol exposure inhibits the turning of cerebellar granule cells in vivo and in vitro. First, in vivo studies using P10 mice demonstrated that a single intraperitoneal injection of ethanol not only reduces the number of turning granule cells but also alters the mode of turning at the EGL-ML border of the cerebellum. Second, in vitro analysis using microexplant cultures of P0-P3 mouse cerebella revealed that ethanol directly reduces the frequency of spontaneous granule cell turning in a dose-dependent manner. Third, the action of ethanol on the frequency of granule cell turning was significantly ameliorated by stimulating Ca(2+) and cGMP signaling or by inhibiting cAMP signaling. Taken together, these results indicate that ethanol affects the frequency and mode of cerebellar granule cell turning through alteration of the Ca(2+) and cyclic nucleotide signaling pathways, suggesting that the abnormal allocation of neurons found in the brains of FASD and FSA patients results, at least in part, from impaired turning of immature neurons by alcohol.

Hippocampal cell loss and neurogenesis after fetal alcohol exposure: insights from different rodent models

Prenatal ethanol exposure is invariably detrimental to the developing central nervous system and the hippocampus is particularly sensitive to the teratogenic effects of ethanol. Prenatal ethanol exposure has been shown to result in hippocampal cell loss, altered neuronal morphology and impaired performance on hippocampal-dependent learning and memory tasks in rodents. The dentate gyrus (DG) of the hippocampus is one of the few brain regions where neurogenesis continues into adulthood. This process appears to have functional significance and these newly generated neurons are believed to play important functions in learning and memory. Recently, several groups have shown that adult hippocampal neurogenesis is compromised in animal models of fetal alcohol spectrum disorders (FASD). The direction and magnitude of any changes in neurogenesis, however, appear to depend on a variety of factors that include: the rodent model used; the blood alcohol concentration achieved; the developmental time point when alcohol was administered; and the frequency of ethanol exposure. In this review we will provide an overview of the different rodent models of FASD that are commonly used in this research, emphasizing each of their strengths and limitations. We will also present an up-to-date summary on the effects of prenatal/neonatal ethanol exposure on adult hippocampal neurogenesis and cell loss, highlighting some of the possible molecular mechanisms that might be involved.

Timing of moderate level prenatal alcohol exposure influences gene expression of sensory processing behavior in rhesus monkeys

Sensory processing disorder, characterized by over- or under-responsivity to non-noxious environmental stimuli, is a common but poorly understood disorder. We examined the role of prenatal alcohol exposure, serotonin transporter gene polymorphic region variation (rh5-HTTLPR), and striatal dopamine (DA) function on behavioral measures of sensory responsivity to repeated non-noxious sensory stimuli in macaque monkeys. Results indicated that early gestation alcohol exposure induced behavioral under-responsivity to environmental stimuli in monkeys carrying the short (s) rh5-HTTLPR allele compared to both early-exposed monkeys homozygous for the long (l) allele and monkeys from middle-to-late exposed pregnancies and controls, regardless of genotype. Moreover, prenatal timing of alcohol exposure altered the relationship between sensory scores and DA D₂R availability. In early-exposed monkeys, a positive relationship was shown between sensory scores and DA D₂R availability, with low or blunted DA function associated with under-responsive sensory function. The opposite pattern was found for the middle-to-late gestation alcohol-exposed group. These findings raise questions about how the timing of prenatal perturbation and genotype contributes to effects on neural processing and possibly alters neural connections.

Cerebellar granule cell migration and the effects of alcohol

In the developing brain the majority of neurons migrate from their birthplace to their final destination. This active movement is essential for the formation of cortical layers and nuclei. The impairment of migration does not affect the viability of neurons but often results in abnormal differentiation. The proper migration of neurons requires the orchestrated activities of multiple cellular and molecular events, such as pathway selection, the activation of specific receptors and channels, and the assembly and disassembly of cytoskeletal components. The migration of neurons is very vulnerable to exposure to environmental toxins, such as alcohol. In this article, we will focus on recent developments in the migration of cerebellar granule cells. First, we will describe when, where and how granule cells migrate through different cortical layers to reach their final destination. Second, we will present how internal programs control the sequential changes in granule cell migration. Third, we will review the roles of external guidance cues and transmembrane signals in granule cell migration. Finally, we will reveal mechanisms by which alcohol exposure impairs granule cell migration.

How does alcohol impair neuronal migration?

Maternal alcohol consumption during pregnancy can cause serious birth defects, of which fetal alcohol syndrome (FAS) is the most devastating. Recognized by characteristic craniofacial abnormalities and growth deficiency, this condition produces severe alcohol-induced damage in the developing brain. FAS children experience ataxia; deficits in intellectual functioning; and difficulties in learning, memory, problem solving, and attention. Multiple aspects of central nervous system development can be affected by alcohol exposure, but the most striking abnormalities are neuronal and glial migration. Little is known about cellular mechanisms by which alcohol affects the migration of immature neurons. Recently, it has been found that Ca(2+) signaling and cyclic nucleotide signaling are the central targets of the action of alcohol in neuronal cell migration. Most importantly, the aberrant migration of immature neurons caused by alcohol exposure is significantly ameliorated by controlling the activity of these second-messenger pathways. In this Mini-Review, we first describe how alcohol exposure impairs the migration of cerebellar granule cells and then discuss the signaling mechanisms involved.

Reversal of neuronal migration in a mouse model of fetal alcohol syndrome by controlling second-messenger signalings

The brains of fetal alcohol syndrome patients exhibit impaired neuronal migration, but little is known about the mechanisms underlying this abnormality. Here we show that Ca2+ signaling and cyclic nucleotide signaling are the central targets of alcohol action in neuronal cell migration. Acute administration of ethanol reduced the frequency of transient Ca2+ elevations in migrating neurons and cGMP levels and increased cAMP levels. Experimental manipulations of these second-messenger pathways, through stimulating Ca2+ and cGMP signaling or inhibiting cAMP signaling, completely reversed the action of ethanol on neuronal migration in vitro as well as in vivo. Each second messenger has multiple but distinct downstream targets, including Ca2+/calmodulin-dependent protein kinase II, calcineurin, protein phosphatase 1, Rho GTPase, mitogen-activated protein kinase, and phosphoinositide 3-kinase. These results demonstrate that the aberrant migration of immature neurons in the fetal brain caused by maternal alcohol consumption may be corrected by controlling the activity of these second-messenger pathways.

Moderate-level prenatal alcohol exposure alters striatal dopamine system function in rhesus monkeys

BACKGROUND

Moderate prenatal alcohol exposure can cause impairments even in the absence of gross morphological defects associated with fetal alcohol syndrome. The basal ganglia, which include the dopamine-rich striatum, are sensitive to fetal alcohol-induced injury. In this study, we manipulated the timing of moderate-level alcohol exposure and compared the risk of adverse effects on striatal dopamine (DA) system function in rhesus monkeys.

METHODS

Thirty-five young adult rhesus monkeys (Macaca mulatta) from four groups of females were assessed: (1) an early alcohol-exposed group (n=9), in which mothers voluntarily consumed 0.6 g/kg alcohol solution on gestational days 0 through 50; (2) a middle-to-late gestation alcohol-exposed group (n=7), in which mothers voluntarily consumed 0.6 g/kg alcohol solution on gestational days 50 through 135; (3) a continuous-exposure group (n=9), in which mothers voluntarily consumed 0.6 g/kg alcohol solution on days 0 through 135; and (4) controls (n=10), in which mothers voluntarily consumed an isocaloric control solution on gestational days 0 through 50, 50 through 135, or 0 through 135. We studied striatal DA system function by positron emission tomography in separate scans for trapping of [(18)F]fallypride and 6-[(18)F]fluoro-m-tyrosine to assess striatal DA D2 receptor (D2R) binding and DA synthesis, respectively, via dopadecarboxylase activity.

RESULTS

Moderate-level alcohol exposure during early gestation and continuous exposure throughout gestation (early + middle-to-late exposure) reduced the striatal D2R binding to DA synthesis ratio, whereas middle-to-late alcohol gestation exposure increased the striatal D2R binding to DA synthesis ratio. The continuous-exposure group showed the largest effect. Moreover, the D2R binding/DA synthesis ratio was related to neonatal neurobehavior measures in control monkeys, but these relationships were disrupted in the fetal alcohol-exposed monkeys.

CONCLUSION

These results suggest that the vulnerability of the DA system to the effects of moderate doses of alcohol during gestation depend on the timing of the alcohol exposure. Early-gestation moderate alcohol exposure resulted in a reduction or blunting of dopaminergic function in adulthood, whereas middle to late exposure (without early exposure) either induced the opposite pattern or heightened dopaminergic function. Continuously exposed monkeys showed the largest effect, suggesting that the sooner women stop drinking, the better it is for the fetus.

Protective effects of erythropoietin against ethanol-induced apoptotic neurodegenaration and oxidative stress in the developing C57BL/6 mouse brain

The developing central nervous system is extremely sensitive to ethanol, with well-defined temporal periods of vulnerability. Recent studies have shown that administration of ethanol to infant rats during the synaptogenesis period triggers extensive apoptotic neurodegeneration throughout many regions of the developing brain. Furthermore, acute ethanol administration produces lipid peroxidation in the brain as an indicator of oxidative stress. In recent years, it has been shown that erythropoietin (EPO) has a critical role in the development, maintenance, protection, and repair of the nervous system. In the present study, we investigated the effect of EPO against ethanol-induced neurodegeneration and oxidative stress in the developing C57BL/6 mouse brain. Seven-day-old C57BL/6 mice were divided into three groups: control group, saline-treated group, EPO-treated group. Ethanol was administered to mice at a dosage of 2.5 g/kg for two times with a 2-h interval. Recombinant human EPO (rhEPO) was given 1000 U/kg. Twenty-four hours after the first dose of ethanol, all the animals were killed. Neuronal cell death, apoptosis, thiobarbituric acid substance (TBARS) levels, superoxide dismutase (SOD), and glutathione peroxidase (Gpx) enzymes activities were evaluated. Histopathological evaluation demonstrated that EPO significantly diminished apoptosis in the cerebellum, prefrontal cortex, and hippocampus and also spared hippocampal CA1, CA2, and CA3 neurons. Simultaneous administration of EPO along with ethanol attenuated the lipid peroxidation process and restored the levels of antioxidants. Regarding the wide use of erythropoietin in premature newborns, this agent may be potentially beneficial in treating ethanol-induced brain injury in the perinatal period.

Modeling developmental processes in animals: applications in neurodevelopmental toxicology

Biologically based dose-response models can provide a framework for incorporating mechanistic information into our assessments of neurotoxicity considering both kinetic and dynamic processes. We have constructed models for normal midbrain and neocortex development and we have extended these models to evaluate the neurodevelopmental toxicity of ethanol and methyl mercury. Using such modeling approaches, we have been able to test hypothesized modes of action for these neurodevelopmental toxicants. Specifically, we have compared ethanol's effects on neocortical neurogenesis and exacerbation of apoptosis during the synaptogenesis period. We have used methylmercury as an example of how one can link toxicokinetic and toxicodynamic models and also as an example of how mechanistic data on gene expression can support model development. In summary, using examples from our research group, this paper illustrates the need for models that evaluate both qualitative and quantitative kinetic and dynamic factors in order to understand the potential impacts of neurodevelopmental toxicants.

Ethanol inhibits brain-derived neurotrophic factor-mediated intracellular signaling and activator protein-1 activation in cerebellar granule neurons

Developmental exposure to ethanol causes profound damage to the cerebellum, ranging from aberration in neuronal differentiation to cell loss. As a major neurotrophic factor, brain-derived neurotrophic factor (BDNF) and its receptor TrkB are expressed in the developing, as well as adult, cerebellum. Many neurotrophic effects of BDNF are mediated by gene transcription. We hypothesized that ethanol interfered with BDNF signaling and disrupted BDNF-regulated transcriptional activity. Using a transgenic mouse model expressing an activator protein-1 (AP-1) luciferase reporter construct, we demonstrated that BDNF stimulated AP-1 transactivation in cultured cerebellar granule neurons. This observation was validated by the study using a human neuronal cell line expressing inducible TrkB (TB8 neuroblastoma cells). BDNF induced AP-1 transactivation, as well as increased the binding activity of AP-1 protein complex to a DNA sequence containing AP-1 sites in TB8 cells. BDNF-mediated AP-1 activation was mediated by PI3K/Akt and JNK pathways; BDNF activated Akt and JNKs, and blocking these pathways significantly inhibited BDNF-stimulated AP-1 transactivation. More importantly, ethanol inhibited BDNF-mediated activation of PI3K/Akt and JNKs, and blocked BDNF-stimulated AP-1 activation. Since ethanol did not affect either the expression or autophosphorylation of TrkB, it could be concluded that the site of ethanol action was downstream of TrkB. The present study establishes that this AP-1 reporter transgenic mouse model is valuable for assessing AP-1 activity in the CNS neurons. Our results provide an insight into molecular mechanism(s) of ethanol action.

Selective vulnerability of cerebellar granule neuroblasts and their progeny to drugs with abuse liability

Cerebellar development is shaped by the interplay of genetic and numerous environmental factors. Recent evidence suggests that cerebellar maturation is acutely sensitive to substances with abuse liability including alcohol, opioids, and nicotine. Assuming substance abuse disrupts cerebellar maturation, a central question is: what are the basic mechanisms underlying potential drug-induced developmental defects? Evidence reviewed herein suggests that the maturation of granule neurons and their progeny are intrinsically affected by several classes of substances with abuse liability. Although drug abuse is also likely to target directly other cerebellar neuron and glial types, such as Purkinje cells and Bergmann glia, findings in isolated granule neurons suggest that they are often the principle target for drug actions. Developmental events that are selectively disrupted by drug abuse in granule neurons and/or their neuroblast precursors include proliferation, migration, differentiation (including neurite elaboration and synapse formation), and programmed cell death. Moreover, different classes of drugs act through distinct molecular mechanisms thereby disrupting unique aspects of development. For example, drug-induced perturbations in: (i) neurotransmitter biogenesis; (ii) ligand and ion-gated receptor function and their coupling to intracellular effectors; (iii) neurotrophic factor biogenesis and signaling; and (iv) intercellular adhesion are all likely to have significant effects in shaping developmental outcome. In addition to identifying therapeutic strategies for drug abuse intervention, understanding the mechanisms by which drugs affect cellular maturation is likely to provide a better understanding of the neurochemical events that normally shape central nervous system development.

Brain-derived neurotrophic factor mitigates chronic ethanol-induced attenuation of gamma-aminobutyric acid responses in cultured cerebellar granule cells

This study examined the effect of chronic exposure to ethanol and brain-derived neurotrophic factor (BDNF) on the responsiveness of cerebellar granule cells to gamma-aminobutyric acid (GABA). Cerebellar granule cell cultures were chronically exposed to ethanol (100 mM), BDNF (20 ng/ml), or the combination of ethanol and BDNF. Whole-cell current responses of granule cells to exogenously applied GABA were monitored following at least 5 days of chronic exposure. In the ethanol-treated cultures, granule cell responsiveness to GABA was attenuated. Concomitant exposure of cultures to ethanol and BDNF mitigated the ethanol-induced attenuation of GABA response, although BDNF, by itself, did not affect responsiveness to GABA. BDNF increased the expression of the GABA(A) receptor alpha6 subunit, whereas ethanol had no effect, in chronically treated granule cell cultures. In addition, concomitant treatment with BDNF and ethanol did not increase the expression of the GABA(A) receptor alpha6 subunit, so the subunit expression alone could not account for the mitigating effect of BDNF. We propose that different mechanisms regulating responsiveness to GABA underlie the effects induced by ethanol and BDNF, with the former influencing the expression of functional GABA(A) receptors and the latter involving the activation of the TrkB receptor and its downstream signaling pathways.

Second trimester prenatal alcohol exposure alters development of rat corpus callosum

Prenatal alcohol exposure produces many developmental defects of the central nervous system (CNS), such as in the corpus callosum (CC). This study was designed to observe the effect of prenatal alcohol exposure during the second trimester equivalent on the development of dendritic arbors of CC projection neurons (CCpn) in rat visual cortex. In addition, the effect of second trimester equivalent prenatal alcohol exposure on brain weight was determined. Pregnant dams received 1.2-6.0 g/kg ethanol (EtOH) during gestational day (G) 11-20. Controls consisted of normal and nutritionally matched pairfed (PF) dams. Pups were sacrificed on the day of birth, G26, G29 and G33. DiI crystals were placed in the midsagittal CC bundle to retrogradely label CCpn. Images of visual cortex were obtained from tissue slices using a confocal laser scanning microscope. The number and length of apical and basilar dendrite branches were determined. The results show that prenatal alcohol exposure restricted to the second trimester equivalent alters the development of the CCpn dendritic arbor and the brain weight in a blood alcohol concentration (BAC)-dependent manner. The alteration in the EtOH CCpn is manifested as an increase in the number and length of CCpn apical and basilar dendrite branches, while brain weight is reduced compared with Controls.

Pituitary adenylate cyclase-activating polypeptide protects rat cerebellar granule neurons against ethanol-induced apoptotic cell death

Alcohol exposure during development can cause brain malformations and neurobehavioral abnormalities. In view of the teratogenicity of ethanol, identification of molecules that could counteract the neurotoxic effects of alcohol deserves high priority. Here, we report that pituitary adenylate cyclase-activating polypeptide (PACAP) can prevent the deleterious effect of ethanol on neuronal precursors. Exposure of cultured cerebellar granule cells to ethanol inhibited neurite outgrowth and provoked apoptotic cell death. Incubation of granule cells with PACAP prevented ethanol-induced apoptosis, and this effect was not mimicked by vasoactive intestinal polypeptide, suggesting that PAC1 receptors are involved in the neurotrophic activity of PACAP. Ethanol exposure induced a strong increase of caspase-2, -3, -6, -8, and -9 activities, DNA fragmentation, and mitochondrial permeability. Cotreatment of granule cells with PACAP provoked a significant inhibition of all of the apoptotic markers investigated although the neurotrophic activity of PACAP could only be ascribed to inhibition of caspase-3 and -6 activities. These data demonstrate that PACAP is a potent protective agent against ethanol-induced neuronal cell death. The fact that PACAP prevented ethanol toxicity even when added 2 h after alcohol exposure, suggests that selective PACAP agonists could have potential therapeutic value for the treatment of fetal alcohol syndrome.

Therapeutic motor training ameliorates cerebellar effects of postnatal binge alcohol

We have used training on complex motor tasks to ameliorate effect of neonatal alcohol exposure. On postnatal days 4-9, alcohol-exposed (AE) rats were given 4.5 g/kg/day of alcohol by artificial rearing; gastrostomy control (GC) rats were given an isocaloric mixture of maltose/dextrin; suckling control (SC) rats were suckled normally. At 6 months of age, animals from the three groups underwent either rehabilitation training on a series of complex motor tasks, motor conditioning on a flat runway, or an inactive home cage condition. Subsequently, animals were either tested on three tests of balance and coordination, or were used for cerebellar morphology. After rehabilitation, but not after motor conditioning, male and female AE rats exhibited significant improvement in independent tests of motor skills. Using unbiased stereological morphological techniques, rehabilitated SC and AE animals were found to exhibit significantly more parallel fiber synapses per Purkinje cell in the paramedian lobule.

Transforming growth factor beta1-regulated cell proliferation and expression of neural cell adhesion molecule in B104 neuroblastoma cells: differential effects of ethanol

The expression and activity of factors influencing early neuronal development are altered by ethanol. Such factors include growth factors, for example, platelet-derived growth factor and basic fibroblast growth factor (for cell proliferation), and cell adhesion molecules (for neuronal migration). One agent, transforming growth factor beta1 (TGFbeta1), may affect both events. We tested the hypothesis that ethanol alters myriad TGFbeta1-mediated activities [i.e., cell proliferation and neural cell adhesion molecule (N-CAM) expression] using B104 neuroblastoma cells. TGFbeta1 inhibited the proliferation of B104 cells as evidenced by decreases in cell number and [3H]thymidine ([3H]dT) incorporation. TGFbeta1 induced sustained activation of extracellular signal-regulated kinases (ERKs), which are part of the family of mitogen-activated protein kinases (MAPKs). Treatment with PD98059 (a MAPK kinase blocker) abolished TGFbeta1-regulated inhibition of [3H]dT incorporation. TGFbeta1-mediated growth inhibition was potentiated by ethanol exposure. Ethanol also produced prolonged activation of ERK, an effect that was partially eliminated by treatment with PD98059. On the other hand, TGFbeta1 up-regulated N-CAM expression, and this up-regulation was not affected by treatment with PD98059. Ethanol inhibited the TGFbeta1-induced up-regulation of N-CAM expression in a concentration-dependent manner. Thus, TGFbeta1 affects ERK-dependent cell proliferation and ERK-independent N-CAM expression in B104 cells. Both activities are sensitive to ethanol and may underlie the ethanol-induced alterations in the proliferation and migration of CNS neurons.

Expression of p53 and ALZ-50 immunoreactivity in rat cortex: effect of prenatal exposure to ethanol

Neuronal death is an active process that results in the upregulation of antigens recognized by ALZ-50 and p53. Since prenatal exposure to ethanol can induce the postnatal death of cortical neurons, we examined the effects of ethanol on the in vivo expression of both the ALZ-50-positive antigen and p53. Pregnant rats were fed one of three diets, a liquid diet containing ethanol (Et), an isocaloric and isonutritive diet (Ct), or chow and water (Ch). Segments of frontoparietal cortex from fetuses and pups were examined for ethanol-induced changes (a) in the expression of ALZ-50 and p53 immunoreactivity using a quantitative immunoblotting assay and (b) in the distribution of ALZ-50- and p53-positive cells using immunohistochemistry. In control rats, ALZ-50 identified a 56-kDa peptide that was transiently expressed postnatally and peak expression occurred on postnatal day (P) 6 to P12. In Et-treated rats, peak expression was attained earlier (on P3) and was about three times of that achieved in the controls. The anti-p53 antibody identified three proteins (28, 56, and 58 kDa). Peak expression in control rats occurred during the second postnatal week and only the 58-kDa protein was expressed in appreciable amounts in adult cortex. Each p53-positive protein was affected by ethanol exposure. The 28- and 56-kDa p53-positive proteins were affected by ethanol much in the same way as was the ALZ-50-positive antigen. That is, the timing and amount of peak expression were earlier and lower, respectively, in the Et-treated rats. The postnatal expression of the 58-kDa protein was halved following prenatal exposure to ethanol. Both ALZ-50 and anti-p53 immunoprecipitated proteins are p53- and ALZ-50-positive, respectively. Thus, ethanol alters the expression of the ALZ-50- and p53-positive proteins and presumably the timing of neuronal death in the developing cortex. The parallel effects of prenatal ethanol exposure on the 56-kDa ALZ-50-positive antigen and the 28- and 56-kDa p53-positive proteins and the coprecipitation of the proteins are consistent with the notion that ALZ-50 recognizes a form of p53.

Effect of ethanol on neurotrophin-mediated cell survival and receptor expression in cultures of cortical neurons

The interaction of ethanol and neurotrophin-mediated cell survival was examined in primary cultures of cortical neurons. Cells were obtained from rat fetuses on gestational day 16 and maintained in a medium supplemented with either 10% or 1.0% fetal calf serum (FCS). Exogenous nerve growth factor (NGF; 20 ng/ml), brain-derived neurotrophic factor (BDNF; 20 ng/ml) or neurotrophin 3 (NT-3; 20 ng/ml) was added to the cultures alone, or in combination with ethanol (400 mg/dl). The number of viable neurons was determined after a 48 h treatment with a growth factor and/or ethanol. The effects of ethanol on the expression of high affinity neurotrophin receptors (trkA, trkB, and trkC) and the low-affinity receptor (p75), were analyzed using Western immunoblots. In untreated cultures, 22.7% and 26.3% of the cells raised in a medium containing 10% and 1.0% FCS, respectively, were lost. Only NGF prevented the death of the cultured cortical neurons. Ethanol was toxic; it caused a 23.5% and 16.7% loss of cells (for cells grown in a medium containing 10% and 1.0% FCS, respectively) beyond that occurring 'naturally' in an untreated culture. Ethanol completely blocked the NGF-mediated cell survival. In general, BDNF and NT-3 did not offset the toxic effect of ethanol. Immunoblotting studies showed that the expression of p75 was significantly (p < 0.05) lower (40%) in ethanol-treated cultures, but ethanol did not affect trk expression. Thus, ethanol has specific effects upon NGF-mediated cell survival and the effects on the low affinity receptor imply that p75 specifically plays an important role in NGF signaling.

Prenatal effects of drugs of abuse on brain development

Drugs of abuse modify signaling of neurotransmitter systems and intracellular messengers. Recent studies of central nervous system development show that these same neurotransmitters may serve as molecules that regulate specific aspects of cell proliferation, survival, migration, circuit formation and establishment of topography. Moreover, the convergence of neurotransmitter, growth factor and hormone activity on similar intracellular signaling systems suggests the potential for significant interactions among molecular components that regulate development. The application of modern strategies used by developmental and cell biologists to the question of whether prenatal drug exposure alters brain structure and function has led to discoveries of specific, targeted changes. Studies of the mechanisms of drug action that lead to altered neural development are now reality.

Neuroanatomical and neurophysiological mechanisms involved in central nervous system dysfunctions induced by prenatal alcohol exposure

One of the most severe consequences of maternal ethanol consumption is the damage to the developing central nervous system, which is manifested by long-term cognitive and behavioral deficits in the offspring. Prenatal exposure to ethanol affects many crucial neurochemical and cellular components of the developing brain. Ethanol interferes with all of the stages of brain development, and the severity of the damage depends on the amount of ethanol intake and level of exposure. Experimental observations also indicate that the toxic effects of ethanol are not uniform: some brain regions are more affected than others and, even within a given region, some cell populations are more vulnerable than others. The neocortex, the hippocampus, and the cerebellum are the regions in which the neurotoxic effects of ethanol have been associated with the behavioral deficits. At the cellular level, ethanol disrupts basic developmental processes, including interference with division and proliferation, cell growth, and differentiation and the migration of maturing cells. Alterations in astroglia development and in neuronal-glial interactions may also influence the development of the nervous system. An impairment of several neurotransmitter systems and/or their receptors, as well as changes in the endocrine environment during brain development, are also important factors involved in the behavioral dysfunctions observed after prenatal ethanol exposure. Finally, some molecular mechanisms of ethanol-induced behavioral dysfunctions will be discussed.

Basic fibroblast growth factor- and platelet-derived growth factor-mediated cell proliferation in B104 neuroblastoma cells: effect of ethanol on cell cycle kinetics

In vivo studies show (a) that early exposure to ethanol depletes neurons in the central nervous system (CNS) and (b) that a primary target of ethanol in the developing nervous system is proliferating neuronal precursors. We used a neuronal cell line (B 104 neuroblastoma cells) as an in vitro model for the effects of ethanol on the proliferation of neuronal precursors to test the hypothesis that ethanol interferes with growth factor-regulated proliferation of neuron-like precursors. The effects of ethanol on the mitogenic activity of two growth factors, basic fibroblast growth factor (bFGF) and platelet-derived growth factor AA and BB (PDGF-AA and PDGF-BB), were examined. Cell proliferation was monitored by tracing the change in the numbers of cultured cells over 4-5 days and in the cell cycle kinetics was determined using a cumulative labeling technique with bromodeoxyuridine (BrdU). Western immunoblots and immunohistochemical preparations show that B104 cells expressed the high affinity receptors for bFGF, PDGF-AA and PDGF-BB. The three growth factors were potent mitogens for the B104 cells; they promoted an increase in cell number even when the cells were grown in serum-free medium. Ethanol depressed the bFGF-, PDGF-AA- and PDGF-BB-mediated cell proliferation without altering the incidence of cell death. These changes in proliferation were concentration-dependent; at a concentration of 100 mg/dl, ethanol partially, but significantly inhibited growth factor-stimulated proliferation and higher ethanol concentrations (400 mg/dl or more) completely abolished growth factor-regulated cell proliferation. The effects of ethanol on cell growth were a result of ethanol-induced changes in growth factor-regulated cell cycle kinetics, principally the total length of the cell cycle and the fraction of the population that was actively cycling (the growth fraction). Ethanol completely negated the action of bFGF, but only partially blocked PDGF-promoted cycling activity. Thus, B104 cells are a suitable model for studying the effects of ethanol on neuronal proliferation. The blockage of bFGF- and PDGF-mediated cell proliferation by ethanol supports the hypothesis that growth factors are a target of ethanol neurotoxicity. Furthermore, the differential actions and effects of ethanol on the two growth factors mirror effects observed in vivo.

Purkinje cell deficits in nonhuman primates following weekly exposure to ethanol during gestation

The most serious features of fetal alcohol syndrome (FAS) are mental retardation and other behavioral problems resulting from alcohol-induced damage to the developing central nervous system (CNS). The mechanism by which alcohol induces its neuroteratogenic effects is unknown. One hypothesis is that gestational alcohol exposure results in a reduction in neuronal number. This study demonstrates that gestational exposure to ethanol in a non-human primate species induces permanent dose-related deficits in the number of cerebellar Purkinje cells. Ethanol was administered via nasogastric tube once per week to 15 gravid pigtailed macaques (Macaca nemistrina) in one of the following doses: 0.0 (intubated controls), 1.2, 1.8, 2.5, 3.3, and 4.1 g/kg/dose. Offspring were reared with parental surrogates and were sacrificed at 6 months of age; 8-microns-thick, parasagittal sections were cut through the paraffin-embedded cerebellar vermis. Purkinje cells were quantified, the length of the Purkinje cell line was determined stereologically, and Purkinje cell linear frequency was calculated. The number of Purkinje cells and their linear frequencies were significantly reduced in the alcohol-treated subjects, and the deficits were dose-dependent. The groups receiving 2.5 g/kg/dose and above were most severely affected and had an average deficit in Purkinje cell number of 11.8%, relative to controls. Alcohol had no effect on the length of the Purkinje cell line. The findings suggest that alcohol-induced reduction in neuronal number may be an important factor underlying the CNS dysfunction in FAS.

Limited ethanol exposure selectively alters the proliferation of precursor cells in the cerebral cortex

The present in vivo study tests the hypothesis that limited (4-day) exposure to ethanol differentially affects the proliferation of cortical precursors in the two cortical germinal zones [the ventricular zone (VZ) and the subventricular zone (SZ)] and their descendants in the mature brain. The offspring of pregnant rats fed a liquid diet containing 6.7% (v/v) ethanol when prosencephalic stem cells [gestation day (G) 6-69], VZ cells (G12-G15), and SZ cells were proliferating (G18- G21) throughout much of gestation (G6-G21). In addition, the offspring of rats pair-fed a liquid control diet or fed chow were examined. The pregnant dams were administered with bromodeoxyuridine (BrdU) on either G15 or G21. The ratio of the number of cells that incorporated BrdU to the total number (the labeling index) was determined 1-hr postinjection (i.e., on G15 or G21) or on postnatal day 60, Ethanol treatment between G6 and G21 reduced the ratio of cells labeled by an injection of BrdU on G15 in the fetus and in the adult, and increased the ratio of cells labeled on G21. Regardless of when the injection was placed, ethanol treatment between G6 and G9 had no effect upon the ratio of BrdU-labeled cells in the fetus or mature cortex. Exposure from G12 to G15 decreased the number of VZ cells in the fetus and the number of immunolabeled cells in the adult cortex labeled by an injection on G15. This exposure had no effect on the incorporation by SZ cells. In contrast, ethanol exposure from G18 to G21 increased the labeling indices for fetal SZ cells and for cells in the adult, but it had no effect on the ratio of labeled VZ cells. Although ethanol had no apparent effect on the proliferation of stem cells, it did alter the proliferation of cells in the VZ and SZ. These effects are time-dependent and underlie the ethanol-induced changes in the number of cells in the adult.

Generation of neurons in the rat dentate gyrus and hippocampus: effects of prenatal and postnatal treatment with ethanol

Neurons in the rat hippocampal formation (the dentate gyrus and the hippocampus) are born over a protracted period, from gestational day (G) 15 into adulthood. Dentate gyral neurons born prenatally are generated from the ventricular zone, whereas those born postnatally are derived from a secondary proliferative zone, the intrahilar zone. In contrast, hippocampal pyramidal neurons are generated only prenatally from the ventricular zone. In the neocortex, ethanol depresses the proliferation of cells in the ventricular zone and stimulates the proliferation of cells in the secondary proliferative zone. The present study tests the hypotheses that prenatal treatment with ethanol has a different effect on the generation of dentate gyral neurons than does postnatal ethanol treatment, and that these differences are determined by the timing of the ethanol exposure relative to the period and site of neuronal generation. Rats were treated with ethanol between G6 and G21 or between postnatal day (P) 4 and P12. They were given an injection of [3H]thymidine on G15, G18, G21, P6, P9, or P12. Rats were killed on P30-P35. The tissue was processed by standard autoradiographic methods and assessed using rigorous stereological procedures. The total number of neurons and the density of radiolabelled neurons in both the dentate gyrus and the CA1 region of the hippocampus were determined. Prenatal ethanol treatment decreased the total number of neurons in the CA1 segment of the hippocampus and had little impact on neuronal number in the dentate gyrus. Likewise, the number of hippocampal and dentate gyral neurons generated daily was significantly lower in ethanol-treated rats than in controls. Postnatal treatment to ethanol, however, significantly increased the total number of dentate gyral neurons and the density of neurons generated postnatally. These postnatal changes depended on the blood ethanol concentration (BEC). At moderate BECs, the total number of neurons in the dentate gyrus and the number of neurons generated was increased. At high BECs, however, neuronal number and neuronal generation were decreased. Postnatal ethanol treatment had no effect on the number of (total or radiolabeled) CA1 neurons. Thus, pre- and postnatal exposure to ethanol have opposite effects both on the number of neurons in the dentate gyrus and on the generation of neurons. These paradoxical effects likely result from three causes: the differential effects of ethanol on the two proliferative zones, the critical period of neuronal development, and the potentially opposite effects of moderate and high BEC.

Permanent neuronal cell loss in the cerebellum of rats exposed to continuous low blood alcohol levels during the brain growth spurt: a stereological investigation

This study demonstrates that exposure to an alcohol regimen that resulted in low, uniform blood alcohol concentrations during a period of rapid brain growth can lead to a permanent deficit in the number of Purkinje cells and granule cells in the floccular-parafloccular region of the cerebellum. Sprague-Dawley rat pups were artificially reared and were administered alcohol over postnatal days 4 through 9, a period of brain development similar to that of the human third trimester. Two groups received a daily alcohol dose of 4.5 g/kg, administered either as a 10.2% solution in two of the 12 daily feedings (10.2% group) or as a 5.1% solution in four of the 12 feedings (5.1% group). A third group received a daily dose of 6.6 g/kg administered as a 2.5% solution in every feeding (2.5% group). The condensed patterns of alcohol administration resulted in high peak blood alcohol concentrations with near total clearance while the higher daily dose (6.6 g/kg), administered continuously, resulted in low but continuous blood alcohol concentrations. Pups were allowed to grow to adulthood and killed on postnatal day 115. The total number of Purkinje cells and granule cells in the floccular-parafloccular region of the cerebellum was estimated using unbiased stereological methods. Exposure to alcohol resulted in significant deficits in the number of both Purkinje cells and granule cells at 115 days of age in all three treatment groups. Most importantly a significant deficit of Purkinje cells and granule cells was found following continuous exposure to low blood alcohol concentrations, i.e., in the 2.5% group. The total number of Purkinje cells in the 2.5% group was 2.33 +/- 0.31 x 10(4) compared with 3.18 +/- 0.30 x 10(4) in the artificially reared controls. The total number of granule cells in the 2.5% group and the controls was 1.24 +/- 0.10 x 10(7) and 1.64 +/- 0.19 x 10(7), respectively. These results support the hypothesis that exposure to a continuous, low blood alcohol concentration can result in the death of developing neurons and lead to permanent neuronal deficits. The degree of neuronal loss does not correlate with the magnitude of the peaks of blood alcohol concentration.

Effect of pre- or postnatal exposure to ethanol on the total number of neurons in the principal sensory nucleus of the trigeminal nerve: cell proliferation and neuronal death

Early exposure to ethanol reduces the number of neurons in many CNS structures in vivo. The present study determined whether such reductions are caused by the death of neurons. Three groups of ethanol-treated rats were prepared: those exposed to ethanol from gestational day (G) 11 to G19 (during the period of neuronal generation and migration), from postnatal day (P) 4 to P12 (during the period of synaptogenesis), or from P31 to P39 [after the mature structure and function of neurons in the principal sensory nucleus (PSN) of the trigeminal nerve was established]. During these times, pregnant dams or pups were fed a liquid ethanol-containing diet that produced peak blood ethanol concentrations of 137-157 mg/dl. The number of PSN neurons in mature rats exposed to ethanol pre- or postnatally was determined using stereological procedures. The number of PSN neurons was also calculated for rats pair-fed an isocaloric liquid control diet or fed chow and water and libitum. The volume of the PSN was not affected by pre- or postnatal ethanol exposure. The number of PSN neurons, however, was significantly affected by ethanol exposure in a time-dependent manner. Prenatal exposure lead to a 27.1% decrease in neuronal number. Early postnatal exposure led to a smaller decrease (-15.1%), and late postnatal exposure had no affect on the number of PSN neurons. These data show not only that ethanol directly depresses the proliferation of neuronal precursors, but also that ethanol causes the death of neurons during the period of synaptogenesis.

NMDA prevents alcohol-induced neuronal cell death of cerebellar granule cells in culture

Neuronal cell loss is one of the most debilitating effects of alcohol exposure during development of the nervous system. In this study, primary cultures of neuronal cells (cerebellar granule cells) were used to examine mechanisms of alcohol-induced neuronal cell death. Previously, we established that (Pantazis et al., Alcohol Clin Exp Res 17:1014-1021, 1993): (1) alcohol exposure caused neuronal cell death in cultures of cerebellar granule cells and this cell loss was both time-dependent and dose-dependent; and (2) the vulnerability of cerebellar granule cells to alcohol-induced loss changed with the length of time the cells were in culture before initiating alcohol exposure-that is, younger cultures (1 day in vitro) were much more susceptible to alcohol-induced neuronal cell death than older cultures (4 or 7 days in vitro). The primary goal of the present study was to examine the potential role of the NMDA receptor in alcohol-induced death of cerebellar granule cells in culture. Experiments were performed to test the hypothesis that the alcohol-induced death of cerebellar granule cells can be prevented or reduced by NMDA treatment. Our results indicate that stimulation of the NMDA receptor has a neuroprotective effect and can significantly reduce the alcohol-induced neuronal cell death of newly established cerebellar granule cell cultures. This neuroprotective effect of NMDA is blocked by 2-amino-5-phosphonovalerate, a competitive inhibitor of the NMDA receptor, confirming that this neuroprotective effect is mediated via the NMDA receptor. This is the first report that alcohol's neurotoxic effect can be ameliorated by activation of the NMDA receptor.

Cell cycle kinetics in fetal rat cerebral cortex: effects of prenatal treatment with ethanol assessed by a cumulative labeling technique with flow cytometry

The effects of ethanol on the cell cycle kinetics of cortical precursor cells during the period of cortical neuronogenesis [between gestational day (G) 12 and G21] was systematically examined. Samples of dissociated cortical cells were harvested from the cerebral cortices of 13-, 15-, 17-, 19-, and 21-day-old fetuses. The fetuses were obtained from pregnant rats: (a) fed a liquid diet containing 6.7% (v/v) ethanol (Et) ad libitum, (b) pair-fed an isocaloric liquid control diet (Ct), or (c) fed chow and water (Ch) ad libitum. Before harvesting the cells, the fetuses were administered a series of 1-5 injections of bromodeoxyuridine (BrdU). The proportion of cells that incorporated the BrdU was assessed. Using these raw data, the S-phase length (Ts), total cell cycle length (Tc), and the growth fraction (GF; the fraction of the total population that was actively cycling) were determined with a cumulative labeling procedure. The Ts was approximately 8-9 hr, regardless of either the date of the injection or the dietary treatment of the dam. On the other hand, the Tc for the Ct- and Ch-treated rats increased over the gestational period. That is, the Tc was shortest on G13 and longest on G21. The Tc for Et-treated rats, however, did not change between G13 and G21. For the Ch- and Ct-treated groups, the GF decreased > 15-fold between G13 and G21. The decline (5-fold) for the Et-treated group over the same period, however, was not as great as it was for the Ct-treated fetuses.(ABSTRACT TRUNCATED AT 250 WORDS)

Combined pre- and postnatal ethanol exposure alters the development of Bergmann glia in rat cerebellum

The development and maturation of Bergmann glial cells in the rat cerebellum was evaluated on postnatal day 15 by glial fibrillary acidic protein (GFAP) immunocytochemistry, following combined gestational and 10-day postnatal ethanol exposure (a full three trimester human equivalency). GFAP-positive Bergmann glial fibers of lobules I, III, VIb, VII and X of the cerebellar vermis were examined and counted in the molecular layer (ML), the external granular layer (EGL) and the external limiting membrane (ELM). Ethanol exposure reduced: (1) the number of GFAP-positive fibers (per unit length of folia surface) at all three levels; (2) the percentage of mature fibers; and (3) the cross-sectional area in all lobules examined. When data from the five lobules were pooled, there were 7% fewer GFAP-positive fibers in the ML, 15% fewer in the EGL and 20% fewer in the ELM; the percentage of mature fibers was reduced by 16%; and the cross-sectional areas of lobules were reduced by 16%. The altered development of Bergmann glia could be one of the factors causing delayed migration of granular neurons and reductions in the number of granule cells reported in other studies following developmental ethanol exposures and could help to explain some of the motor dysfunctions reported in FAS victims.

Developing rat Purkinje cells are more vulnerable to alcohol-induced depletion during differentiation than during neurogenesis

This study compared the extent of cerebellar Purkinje cell depletion induced by administering alcohol to rats during two temporally distinct periods of Purkinje cell development--neurogenesis and early differentiation. One group received alcohol (5 g/kg/day) during and shortly after Purkinje cell neurogenesis (gestational days 13-18) via oral intubation of pregnant dams. A second group received alcohol (2.5 g/kg/day) during early Purkinje cell differentiation (postnatal days 4-9) via artificial rearing of pups. The two alcohol treatment protocols were designed to match the cyclic daily blood alcohol profiles of the two groups as closely as possible. Pair-fed intubated controls, artificially reared gastrostomy controls, and normally reared ad lib/suckle controls were also evaluated. Mean peak blood alcohol concentrations (BACs) were 266 mg/dl for the intubated pregnant dams and 205 mg/dl for the pups exposed postnatally. Purkinje cell profiles were counted from single, 2-microns-thick midsaggital sections on postnatal day 10. Alcohol exposure during neurogenesis resulted in no significant change in Purkinje cell profile densities. Exposure during differentiation produced significant reductions in Purkinje cell profile densities, predominantly in the early maturing regions of the vermis (lobules I-IV and IX-X). These results indicate that Purkinje cells are more vulnerable to alcohol-induced population depletion during differentiation than during neurogenesis.

Vulnerability of cerebellar granule cells to alcohol-induced cell death diminishes with time in culture

This study examined the effects of alcohol exposure on the viability of cerebellar granule cells in culture. Continuous alcohol exposure, starting 1 day after the cultures were established, significantly reduced granule cell numbers, even with a single day of exposure to an alcohol concentration as low as 100 mg/dl. The depletion of cerebellar granule cells by alcohol was concentration-dependent (greater loss of cells at higher alcohol concentrations) and duration-dependent (greater loss of cells at longer exposure durations). The loss of granule cells also depended on the number of days the granule cells were in culture before alcohol exposure. Alcohol was significantly more effective in reducing the cell numbers of newly established granule cell cultures (1 day in vitro) compared with older cultures (4 or 7 days in vitro). Cell cycle analysis established that the cerebellar granule cells did not proliferate in culture, indicating that alcohol exposure did not reduce cell numbers by interfering with cell proliferation in this system. Instead, alcohol-induced killing of the granule cells was the most likely mechanism to account for the depletion of granule cells in vitro. Granule cell cultures are a useful in vitro model system to study the cellular and molecular aspects of neuronal cell depletion associated with fetal alcohol exposure. The potential role of the N-methyl-D-aspartate receptor in this alcohol-induced neuronal cell death is discussed.

The effects of the timing of ethanol exposure during the brain growth spurt on the number of cerebellar Purkinje and granule cell nuclear profiles

Ethanol exposure during development is particularly deleterious to cerebellar Purkinje cells and granule cells, but the mechanism(s) underlying this sensitivity and the variables which affect it remain unknown. One important variable that has not been fully investigated, is the timing of the ethanol exposure. Ethanol exposure during the brain growth spurt causes a differential loss of Purkinje cells across the 10 lobules of the vermal cerebellum. However, whether or not changing the timing of the ethanol exposure during the brain growth spurt alters the extent and location of the loss of Purkinje cells within the cerebellar vermis has not been investigated. Moreover, the loss of cerebellar granule cells has been shown to parallel the loss of Purkinje cells, leading to the conclusion that the loss of granule cells occurred as a function of the loss of their targets, the Purkinje cells. The purpose of this study was to address both issues. Male rat pups were exposed to ethanol, via an artificial-rearing method, during one of the following 2-day time periods: postnatal days (PD) 4-5, 5-6, 6-7, 7-8, 8-9, 9-10, or 12-13. Gastrostomy control (GC) and suckle control (SC) groups also were included. All pups were sacrificed on PD21. The number of Purkinje cell nuclear profiles from three vermal sections were counted in all groups, while the number of granule cell nuclear profiles in the ten lobules was estimated from pups in selected groups. No loss of Purkinje cells was observed in pups exposed to ethanol on PD7-8 or at any of the later exposure times. Additionally, among the three exposure groups in which significant Purkinje cell loss was observed (PD4-5, PD5-6 and PD6-7), seven lobules exhibited significant differences particularly between the PD4-5 and PD6-7 groups. The group with the greatest loss of Purkinje cells (PD4-5) also was the group with the greatest loss of granule cells. A significant loss of granule cells did not occur without a corresponding loss of Purkinje cells. The loss of both the Purkinje and granule cells was affected by the timing of the ethanol exposure, and that the extent and the location of Purkinje cell loss were extremely sensitive to the effects of the timing of the ethanol exposure.

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

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

Circadian rhythm of cell proliferation in the telencephalic ventricular zone: effect of in utero exposure to ethanol

The neocortical ventricular zone is composed of a desynchronized population of proliferating cells. These cells give rise to neurons in the infragranular laminae of neocortex. The present study documents a diurnal rhythmicity of cell proliferation in the ventricular zone and examines the effects of ethanol on this biological clock. Pregnant rats were fed one of 3 diets. They were provided an ethanol-containing (6.7% v/v) liquid diet ad libitum between gestational day (G) 6 and G18, pair-fed an isocaloric liquid control diet, or fed chow and water. Throughout the experiments, the rats were fed either at 08.00 h (E.S.T) or at 17.00 h (lights on 06.00 to 18.00 h). Rats were given a single injection of bromodeoxyuridine (BrdU) on G17 at one point during a 24 h period (03.00, 06.00, 09.00 h, etc.). The fraction of ventricular cells that incorporated the BrdU was determined using quantitative immunohistochemical methods. Pair-fed control rats (fed at 08.00 or 17.00 h) consumed their food within 4 h of presentation. The ratio of cells passing through the S-phase of the cell cycle changed diurnally; the ratio was highest during the day (0.52 +/- 0.01 at 12.00 h) and lowest during the night (0.40 +/- 0.02 at 03.00 h). In contrast, the ethanol-fed rats grazed on their food throughout the dark cycle regardless of when the food was presented. The mean peak blood ethanol concentration was 142 +/- 13 mg/dl during the dark phase and less than 25 mg/dl during the light phase. Prenatal exposure to ethanol eliminates the fetal circadian rhythm in cell proliferation (mean labeling index of 0.45 +/- 0.03).(ABSTRACT TRUNCATED AT 250 WORDS)

Early postnatal alcohol exposure acutely and permanently reduces the number of granule cells and mitral cells in the rat olfactory bulb: a stereological study

This study demonstrates that exposure to alcohol during a period of rapid brain growth can lead to severe and permanent deficits in the number of granule cells and mitral cells in the main olfactory bulb. Sprague-Dawley rat pups were reared artificially and were administered alcohol over postnatal days (PD) 4 through 9, a period of brain development comparable to part of the human third trimester. The daily alcohol dose of 6.6 g/kg was concentrated into two of the twelve daily feedings, producing high peak blood alcohol concentrations followed by near total clearance. Pups were either sacrificed on PD10 or were allowed to grow to adulthood and sacrificed on PD115. The total number of granule cells and mitral cells in the main olfactory bulb were estimated with the aid of unbiased stereological principles and systematic sampling techniques. Exposure to alcohol resulted in significant reductions in the number of both granule cells and mitral cells on PD10. Significant deficits in both neuronal populations remained on PD115. The results support the hypothesis that alcohol exposure can kill developing neurons and lead to permanent neuronal deficits. Substantial developmental changes also occurred in the total number of mitral cells and granule cells between PD10 and PD115 in the control groups. In untreated rats, the number of granule cells increased from 2.20 x 10(6) on PD10 to 5.06 x 10(6) on PD115, while the number of mitral cells decreased from 5.30 x 10(4) to 4.33 x 10(4) over the same time period. These results demonstrate that there is a natural loss of mitral cells during postnatal development at the same time that granule cell number is increasing.

Effects of prenatal ethanol exposure on the development of Bergmann glia and astrocytes in the rat cerebellum: an immunohistochemical study

The consequences of prenatal ethanol exposure on the postnatal development of Bergmann glia and astrocytes in the rat cerebellum were investigated by using glial fibrillary acidic protein (GFAP) immunolabeling. Pregnant rats were either fed with an ethanol containing liquid diet (6.7% v/v) or pair-fed with an isocaloric diet throughout gestation. On postnatal day (PD) 15 and 22, parasagittal sections of the cerebellar vermis from female offspring were processed for GFAP immunohistochemistry to assess the development of Bergmann glia and astrocytes in lobules I, VII, and X and astrocytes in the central core of white matter. On PD 15, compared to control animals, ethanol exposed animals had fewer GFAP positive Bergmann glial fibers per unit length of molecular layer; a significantly greater percentage of morphologically immature Bergmann fibers; a significantly greater GFAP positive astrocytic area per unit area of internal granular layer and central white matter; and the astrocytic processes were wider and more closely packed. These glial changes were associated with significantly thicker external granular layer in all 3 lobules. However, no significant differences were seen between the ethanol exposed and control animals on PD 22, indicating "catch-up growth" in the ethanol exposed animals during the third postnatal week. These results suggest that prenatal ethanol exposure causes (1) delayed maturation of Bergmann glia, which in turn contributes to the delayed migration of granule cells; and (2) alterations in the normal postnatal development of astrocytes.

Acute and long-term neuronal deficits in the rat olfactory bulb following alcohol exposure during the brain growth spurt

This study demonstrates that there is a relative recovery in the number of olfactory bulb granule cells following an initial alcohol-induced deficit, while the number of mitral cells remains permanently and severely depressed. The importance of pattern of exposure in influencing the severity of alcohol-induced neuronal loss in the olfactory bulb is also demonstrated. Sprague-Dawley rat pups were reared artificially and were administered alcohol over postnatal days (PD) 4 through 9, a period of rapid brain growth comparable to part of the human third trimester. Two groups received a daily alcohol dose of 4.5 g/kg, administered either as a 5.1% or 10.2% solution. A third group received a higher daily alcohol dose of 6.6 g/kg administered continuously as a 2.5% solution. Pups were either sacrificed on PD 10 or were allowed to grow to adulthood and sacrificed on PD 90. The number of mitral cells and granule cells and the area of the subependymal zone were determined from single sections. On PD 10, immediately following the alcohol exposure, both the mitral cells and the granule cells were significantly reduced in number, relative to controls, in both of the groups receiving the concentrated (5.1% and 10.2%) alcohol treatments. On PD 90, however, only the mitral cell number remained significantly reduced in the groups receiving the concentrated solutions, while the number of granule cells no longer differed significantly from that of controls. The group receiving the higher daily dose (6.6 g/kg) in continuous fractions had no significant cell loss at 10 or 90 days of age.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of prenatal exposure to ethanol on the cell cycle kinetics and growth fraction in the proliferative zones of fetal rat cerebral cortex

Prenatal exposure to ethanol produces profound changes in the number of neurons in the mature cortex. These changes in neuronal number may reflect ethanol-induced disturbances in early developmental processes, that is in the proliferation of neuronal precursors. Hence, the present study examined the effect of ethanol on cell proliferation in the two neocortical proliferative zones, the ventricular zone (VZ) and subventricular zone (SZ). From gestational day 5 to 21, pregnant rats were fed an ethanol diet (6.7% v/v), pair-fed an isocaloric control diet, or fed chow and water. Pregnant rats were given a series of one to nine injections of bromodeoxyuridine (BrdU). After immunohistochemical processing, the ratio of cells in each proliferative zone that were labeled with BrdU to the total population was determined. The portion of the population that was cycling (growth fraction), the total length of the cell cycle, and the length of the S-phase of the cell cycle were calculated for VZ and SZ cells. Exposure to moderate levels of ethanol has markedly different effects upon the two neocortical proliferative zones. In the VZ, the length of the total cell cycle was significantly greater in ethanol-treated rats than in controls; however, the growth fraction and the length of the S-phase were unaffected by ethanol. In contrast, in the SZ, the growth fraction was significantly greater in ethanol-treated rats, but ethanol had no effect on the length of the total cell cycle or of the S-phase. These differences may underlie the ethanol-induced abnormalities in neuronal generation.

Changes in brain microvasculature resulting from early postnatal alcohol exposure

The microvasculature in selected brain regions in rats was examined on postnatal day 10 following exposure to alcohol on postnatal days 4 to 10. The alcohol-exposed rats were artificially reared and given 6.6 g/kg of ethanol condensed into 8 hr of each 24-hr period. A gastrostomy-control group was reared in the same manner but maltose-dextrin was substituted for ethanol in the formula. A suckle-control group was reared normally by dams. Measurements were taken from midsagittal sections of the cerebellum and sections of the hippocampal formation at a midtemporal level. Although the overall area of the vermal cerebellum was decreased as a consequence of the alcohol exposure, the capillary density was unchanged. However, cerebellar capillary diameters were increased in some lobules in the alcohol-exposed rats. In the dentate gyrus, there was a trend toward a decrease in capillary numerical density but no change in regional area or capillary diameter in the alcohol-exposed rats. In the hippocampus proper, there was a decrease in regional area, no change in capillary density, and an increase in capillary diameter due to alcohol. These results indicate that alcohol exposure during the early postnatal period affects the microvasculature differentially in the cerebellum, hippocampus proper and dentate gyrus.

Effects of prenatal exposure to ethanol on neocortical development: II. Cell proliferation in the ventricular and subventricular zones of the rat

Prenatal exposure to ethanol alters the generation of neocortical neurons; ethanol reduces the numbers of neurons generated between gestational day (G) 12 and G19 but paradoxically increases neuronogenesis after G19. The present study used [3H]thymidine autoradiography to examine the effects of ethanol on the proliferation of cells in the two cortical germinal zones, the ventricular and subventricular zones. Pregnant rats were fed one of three diets: a liquid ethanol-containing (6.7% v/v) diet (Et), a nutritionally matched isocaloric liquid diet (Ct), or chow and water (Ch). Fetuses were administered with [3H]thymidine on G13, G17, or G20 and killed 45-60 minutes later. Autoradiographs were prepared to identify radiolabeled and mitotic cells. Additional brains from 13-23-day-old fetuses were processed for cytoarchitectonic analyses. The size of the lateral ventricles in the fetuses was not significantly affected by the prenatal exposure. Both the ventricular and subventricular zones were evident throughout the period from G13 to G23. In all three groups, the ventricular zone was thickest from G13 to G17, but from G15 on, the ventricular zone of Et-treated fetuses was significantly thinner than those of either controls. On G13, G17, and G20, the labeling index (the ratio of radiolabeled cells to the total population) was significantly less in Et-treated fetuses. The mitotic index was similar in Et-, Ch-, and Ct-treated fetuses. The subventricular zone of all fetuses was most prominent during later fetal ages and it was thicker in Et-treated fetuses than in controls. Moreover, the labeling and mitotic indices for the subventricular zone of Et-treated rats were significantly greater than for controls. Thus, ethanol had different effects on the two neocortical germinal zones: the proliferation of ventricular cells was inhibited, whereas the proliferation of subventricular cells was stimulated. These data suggest that ethanol-induced changes in neuronogenesis result from alterations in proliferative activity.

Differential neuronal loss following early postnatal alcohol exposure

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