The effect of in utero ethanol exposure on hippocampal mossy fibers: an HRP study

Ethanol exposure during the third trimester equivalent does not affect GABAA or AMPA receptor-mediated spontaneous synaptic transmission in rat CA3 pyramidal neurons

Background

Ethanol exposure during the rodent equivalent to the 3^rd trimester of human pregnancy (i.e., first 1–2 weeks of neonatal life) has been shown to produce structural and functional alterations in the CA3 hippocampal sub-region, which is involved in associative memory. Synaptic plasticity mechanisms dependent on retrograde release of brain-derived neurotrophic factor (BDNF) driven by activation of L-type voltage-gated Ca²⁺ channels (L-VGCCs) are thought to play a role in stabilization of both GABAergic and glutamatergic synapses in CA3 pyramidal neurons. We previously showed that ethanol exposure during the first week of life blocks BDNF/L-VGCC-dependent long-term potentiation of GABA_A receptor-mediated synaptic transmission in these neurons. Here, we tested whether this effect is associated with lasting alterations in GABAergic and glutamatergic transmission.

Methods

Rats were exposed to air or ethanol for 3 h/day between postnatal days three and five in vapor inhalation chambers, a paradigm that produces peak serum ethanol levels near 0.3 g/dl. Whole-cell patch-clamp electrophysiological recordings of spontaneous inhibitory and excitatory postsynaptic currents (sIPSCs and sEPSCs, respectively) were obtained from CA3 pyramidal neurons in coronal brain slices prepared at postnatal days 13–17.

Results

Ethanol exposure did not significantly affect the frequency, amplitude, rise-time and half-width of either sIPSCs or sEPSCs.

Conclusions

We show that an ethanol exposure paradigm known to inhibit synaptic plasticity mechanisms that may participate in the stabilization of GABAergic and glutamatergic synapses in CA3 pyramidal neurons does not produce lasting functional alterations in these synapses, suggesting that compensatory mechanisms restored the balance of excitatory and inhibitory synaptic transmission.

Choline supplementation and DNA methylation in the hippocampus and prefrontal cortex of rats exposed to alcohol during development

BACKGROUND

Some of the most frequent deficits seen in children with fetal alcohol spectrum disorders (FASD) and in animal models of FASD are spatial memory impairments and impaired executive functioning, which are likely related to alcohol-induced alterations of the hippocampus and prefrontal cortex (PFC), respectively. Choline, a nutrient supplement, has been shown in a rat model to ameliorate some of alcohol's teratogenic effects, and this effect may be mediated through choline's effects on DNA methylation.

METHODS

Alcohol was given by intragastric intubation to rat pups during the neonatal period (postnatal days 2 to 10) (ET group), which is equivalent to the third trimester in humans and a period of heightened vulnerability of the brain to alcohol exposure. Control groups included an intubated control group given the intubation procedure without alcohol (IC) and a nontreated control group (NC). Choline or saline was administered subcutaneously to each subject from postnatal days 2 to 20. On postnatal day 21, the brains of the subjects were removed and assayed for global DNA methylation patterning as measured by chemiluminescence using the cpGlobal assay in both the hippocampal region and PFC.

RESULTS

Alcohol exposure caused hypermethylation in the hippocampus and PFC, which was significantly reduced after choline supplementation. In contrast, control animals showed increases in DNA methylation in both regions after choline supplementation, suggesting that choline supplementation has different effects depending upon the initial state of the brain.

CONCLUSIONS

This study is the first to show changes in global DNA methylation of the hippocampal region and PFC after neonatal alcohol exposure. Choline supplementation impacts global DNA methylation in these 2 brain regions in alcohol-exposed and control animals in a differential manner. The current findings suggest that both alcohol and choline have substantial impact on the epigenome in the PFC and hippocampus, and future studies will be needed to describe which gene families are impacted in such a way that function of the nervous system is changed.

Ethanol neurotoxicity and dentate gyrus development

Maternal alcohol ingestion during pregnancy adversely affects the developing fetus, often leading to fetal alcohol syndrome (FAS). One of the most severe consequences of FAS is brain damage that is manifested as cognitive, learning, and behavioral deficits. The hippocampus plays a crucial role in such abilities; it is also known as one of the brain regions most vulnerable to ethanol-induced neurotoxicity. Our recent studies using morphometric techniques have further shown that ethanol neurotoxicity appears to affect the development of the dentate gyrus in a region-specific manner; it was found that early postnatal ethanol exposure causes a transitory deficit in the hilus volume of the dentate gyrus. It is strongly speculated that such structural modifications, even transitory ones, appear to result in developmental abnormalities in the brain circuitry and lead to the learning disabilities observed in FAS children. Based on reports on possible factors deciding ethanol neurotoxicity to the brain, we review developmental neurotoxicity to the dentate gyrus of the hippocampal formation.

Critical periods for ethanol-induced cell loss in the hippocampal formation

Rodent models of fetal alcohol syndrome (FAS) have revealed discrepant findings in ethanol's (EtOH) ability to alter the survival of principal neurons within hippocampal areas CA1, CA3 and the dentate gyrus (DG). One issue is the lack of systematic examination of the timing of EtOH exposure over key periods of hippocampal cell development. The present study examined whether systematic developmental EtOH exposure produces long-term hippocampal cell loss that is related to a specific time course in which either generation, migration or synaptogenic events in this neural region occurs. EtOH treatment occurred during the periods equivalent to the first, second, third and all three trimesters in humans using similar administration procedures for both mothers and pups. Unbiased stereological estimates of the total number of pyramidal and granule cells within hippocampal regions CA1, CA3 and DG were performed when rats reached adulthood. The findings confirm previous reports that area CA1 is highly susceptible to EtOH exposure that occurs during either the early neonatal period or all three trimesters equivalent, while areas CA3 and DG are more resistant to EtOH-induced insult during all periods of hippocampal development examined.

Alcohol reduces neurofilament protein levels in primary cultured hippocampal neurons

High concentrations of alcohol (> or = 1.8%) were shown previously to impair health and viability of cultured hippocampal neurons. Because neurofilament proteins are essential for neuronal process outgrowth and differentiation, the effects of alcohol on these proteins were determined in the neuronal processes of primary cultured gestational day 18 rat hippocampal neurons. At the relatively lower concentrations used in the present study, alcohol caused a concentration-dependent reduction (< or = 47%) in 68 and 200 kDa neurofilament proteins (p < 0.05). Alcohol caused a 32% downward trend in 160 kDa neurofilament protein levels. Alcohol up to 1% (72-h exposure) produced no obvious alterations in neurite extension or explant morphology, and there were no visual signs of cell death. The sensitive MTT dye reduction assay showed no biochemical evidence of decreased cell viability at < or = 0.5% alcohol. The 32-47% reductions in neurofilament protein levels in vitro may hold implications for later hippocampal neuronal differentiation events in animals prenatally exposed to alcohol.

Alcohol exposure during brain development reduces 3H-MK-801 binding and enhances metabotropic-glutamate receptor-stimulated phosphoinositide hydrolysis in rat hippocampus

Glutamate receptors play important roles during brain development. We have investigated the effect of chronic maternal alcohol intake on the ontogenic profile of hippocampal glutamate receptor subtypes in their offspring. Binding of 3H-MK-801 to N-methyl-D-aspartate (NMDA) receptor was measured in isolated membranes from the hippocampus of the offspring of pair-fed control and alcohol-fed rats at different times during the postnatal life. Phosphatidylinositol triphosphate (PIP2) hydrolysis was also assayed to provide a measure of the possible effect of ethanol on the metabotropic glutamate receptor (mGluR). In pair-fed control rats, at postnatal day (PND) 3, the 3H-MK-801 binding represents 60% of adult values. Binding then rises to 170% at PND 11, and gradually decreases to adult levels. A transient overshoot in the mGluR-coupled PIP2 hydrolysis was also observed during postnatal development in rat hippocampus. Alcohol-exposed rats showed a similar pattern, but a significant decrease in the specific binding for NMDA receptor was observed on all the postnatal days analyzed. In addition, alcohol exposure significantly decreases the number of specific 3H-MK-801 binding sites, with no change in the affinity of the sites for 3H-MK-801. Moreover, this treatment enhanced the mGluR-activated PIP2 hydrolysis in hippocampus of alcohol-exposed rats. These results may contribute to an understanding of the toxic effects of ethanol on the developing central nervous system (CNS) and help explain the cognitive deficits associated with prenatal alcohol exposure.

A neurogenetic and morphogenetic approach to hippocampal functions based on individual differences and neurobehavioral covariations

To investigate the neural substrate of information processing, the within group inter-individual behavioral differences were related to the fine variations in some components of the architecture of the intact hippocampus by multivariate analyses of variance and correlative analyses. For, the extent of the intra/infrapyramidal mossy fibers, covering the hippocampal CA3-regio inferior (IIP-MF, revealed by Timm-staining), and the individual high-affinity maximal glucocorticoid receptor binding (HCB, measured by in vitro cytosol preparations with [3H]corticosterone as ligand), were assessed in adult male albino rats of the Naples High-Excitability (NHE) and Naples Low-Excitability (NLE) psychogenetically selected lines, and of a Sprague-Dawley random-bred stock (NRB) as unselected controls. The IIP-MF and the HCB were assumed as hippocampal hardware and software traits, respectively, and entered in a matrix with activity and defecation scores in a Làt-maze as behavioral covariates. Two dimensions were identified by discriminant function analyses tentatively labelled as "spatial" and "non-spatial" by the nature of the variables contributing with a high loading to the dimension. The IIP-MF and HCB contributed mostly to spatial processes and to a lower extent to emotional processes. The neuro-behavioral covariations of IIP-MF with arousal (A) and long-term habituation (LTH), computed by correlative analyses on the overall population (all rats combined), turned out to be of inverted-U type (quadratic function), i.e. positive in NLE, negative in NHE with no correlation in NRB. For HCB receptors, the covariations were quadratic with A, and of the S-type (cubic function), i.e. positive in NLE, negative in NRB and positive in NHE with LTH. Since these rat lines are located along a "continuum" with NLE < RB < NHE, they are assumed to represent entirely this subpopulation. For, the non-linear neuro-behavioral relationships might reveal (i) constraints on the expression of arousal and habituation to novelty; and (ii) that the hippocampus appears to be one such device exerting a modulatory role in the processing of "spatial" and "non-spatial" behavioral components.

Role of noradrenergic innervation of brown adipose tissue in thermoregulatory deficits following prenatal alcohol exposure

The development of thermoregulation in newborns is delayed by prenatal alcohol exposure in an animal model of moderate maternal drinking. Newborn mammals generate heat primarily via nonshivering thermogenesis in brown adipose tissue (BAT), which is activated by the sympathetic nervous system. In this study, the effects of prenatal alcohol exposure on the development of the sympathetic innervation of BAT was investigated by assessing the concentration of norepinephrine (NE) in interscapular BAT. Pregnant dams were given either a liquid diet with 35% of the calories derived from alcohol, a liquid diet without alcohol to control for any effects of the liquid diet administration, or ad libitum food and water. Interscapular brown adipose tissue was excised from 5-, 10-, and 20-day-old male and female offspring. At 5 days of age, alcohol-exposed pups had significantly lower NE concentrations than did pups in either control group. However, 20-day-old alcohol-exposed pups had significantly higher NE concentrations than either control group. These results suggest a delay in the development of the sympathetic activation of BAT thermogenesis, followed by a compensatory overactivation. These findings may have important implications for understanding the mechanisms underlying thermoregulatory deficits seen after prenatal alcohol exposure. In addition, these results suggest that maternal alcohol consumption may increase the risk of sudden infant death syndrome, which has been linked to inappropriate BAT thermogenesis.

When should we expect prenatally damaged human brains to have abnormal neuronal connections?

Abnormal function in prenatally damaged brains may occur as the result of loss of neuronal an/or glial elements, abnormal morphology of neurons, or abnormal and inappropriate connections. By abnormal connection I mean projections from a given nucleus to a nucleus or cortical region in the brain which does not normally receive such a projection. In the present paper it is proposed that focal brain damage, i.e. that damage involving circumscribed regions of the developing brain on one side of the body, is more likely to induce abnormal connections, than diffuse brain damage, affecting most of the brain bilaterally. This proposition is based on the available evidence from animal studies, albeit scanty, and is presented as a working hypothesis for future studies of human congenital brain damage.

Prenatal ethanol exposure decreases hippocampal mossy fiber zinc in 45-day-old rats

The long-term consequences of prenatal ethanol exposure on histochemically detectable hippocampal mossy fiber zinc was examined using a recently developed quantitative histofluorescence procedure. Pregnant Sprague-Dawley rats were maintained throughout gestation on one of three dietary regimens: (a) a liquid diet containing either 3.35% ethanol, (b) an isocalorically matched liquid diet pair-fed to the 3.35% ethanol group, or (c) lab chow ad libitum. At 45 days of age, offspring from each of the three diet groups were sacrificed for determination of hippocampal mossy fiber zinc and zinc analysis of selected tissues by atomic absorption spectroscopy. Hippocampal mossy fiber zinc was reduced by 36% in dorsal and 20% in ventral hippocampal formation stratum lucidum of rats exposed to the 3.35% ethanol diet compared to the offspring of the pair-fed control and ad libitum control dams. No significant differences in zinc:TS-Q histofluorescence were observed between the ad libitum and pair-fed control groups. No significant differences were observed among groups in tissue wet weight or tissue zinc concentration in any of the brain or other body regions analyzed. These results indicate a long lasting prenatal ethanol exposure-induced reduction in hippocampal mossy fiber zinc in the absence of changes in any indices of total body zinc nutriture. These results suggest that prenatal exposure to relatively low blood ethanol levels (30-40 mg/dl) has subtle, yet long-lasting effects in the hippocampal formation, a brain region important in the process of memory consolidation.

Prenatal ethanol exposure reduces the effects of excitatory amino acids in the rat hippocampus

Chronic alcohol ingestion during pregnancy can lead to the Fetal Alcohol Syndrome (FAS), a disorder marked by learning disabilities. A rat model of FAS was used by introducing pregnant Sprague-Dawley rats to a liquid diet containing 35% ethanol-derived calories (E), while a second group was pair-fed an isocaloric liquid diet without ethanol (P). A third group of pregnant dams received ad libitum lab chow (C). At parturition, pups from the E and P groups were cross-fostered by C mothers and all groups received lab chow. During adulthood, male offspring were sacrificed and hippocampal and prefrontal cortical slices were prelabeled with [3H] inositol. Phosphoinositide (PI) hydrolysis was determined by measuring the accumulation of [3H]inositol phosphates in the presence of LiCl in response to activation of various excitatory amino acid (EAA) receptors. In hippocampal slices, ibotenate- and quisqualate-induced PI hydrolysis was reduced in E compared to P and C animals. Moreover, the inhibitory effect of N-methyl-D-aspartate (NMDA) on carbachol-induced PI hydrolysis, evident in P and C animals, was completely abolished in the hippocampus of E animals. In contrast, in the prefrontal cerebral cortex, this inhibitory effect of NMDA prevailed even in the E animals. The evidence suggest that prenatal ethanol exposure alters the activity of EAA receptors in the hippocampal generation of 2nd messengers.

Effects of chronic ethanol consumption beginning at adolescence: increased numbers of dendritic spines on cortical pyramidal cells in the adulthood

To increase our understanding of the effects of chronic ethanol consumption beginning at adolescence, 25% ethanol in drinking water (v/v) was administered daily to young rats aged 45-50 days for 5 months. Increased numbers of dendritic spines on the apical dendrite of layer V pyramidal neurons of the somatosensory cortex (U-Mann-Whitney test, P less than 0.01-0.05) were found in almost every 50-micron-long segment over a distance of 500 microns from the cell body in ethanol-treated rats at the age of 195-200 days when compared with age-matched controls. Although the mechanisms leading to this unusual finding are not know, it is suggested that impairment of the naturally occurring elimination of redundant synapses can not be ruled out.

Prenatal ethanol exposure decreases hippocampal 3H-vinylidene kainic acid binding in 45-day-old rats

The effect of prenatal ethanol exposure on the kainate-sensitive subtype of glutamate receptor binding sites was studied using in vitro 3H-vinylidene kainic acid (VKA) autoradiography. Pregnant Sprague-Dawley rats were fed a liquid diet containing either 3.35% or 6.7% ethanol throughout gestation. Pair-fed dams received isocalorically matched liquid diets and a lab chow ad lib group served as control for paired feeding. At 45 days of age, the offspring were sacrificed and their brains analyzed for specific 3H-VKA binding. Compared to pair-fed controls, specific 3H-VKA binding was reduced by 13% to 32% in dorsal and ventral hippocampal CA3 stratum lucidum, entorhinal cortex and cerebellum of 45-day-old rats whose mothers consumed either 3.35% or 6.7% ethanol diets. The binding site reductions were statistically significant only in the ventral hippocampal formation and entorhinal cortex of the 3.35% ethanol diet group rats. Saturation of binding studies in the ventral hippocampal formation of 3.35% ethanol rats indicated that the decrease in specific 3H-VKA binding was due to a decrease in the total number of binding sites. Given the excitatory effect of kainic acid on the spontaneous firing rate of hippocampal CA3 pyramidal neurons, the reduction of kainate-sensitive glutamate binding in this region is consistent with the electrophysiological observation of decreased spontaneous activity of CA3 pyramidal neurons in fetal alcohol rats.

Neuron development in the superior colliculus of the fetal mouse following maternal alcohol exposure

Pregnant Swiss Webster mice were given a liquid diet with ethanol (EtOH) or isocaloric amounts of maltose dextrin on gestation day (GD) 0 through 18. On GD 18, maternal blood samples were obtained. Fetuses were then removed and fetal brains were prepared for light microscopy. Fetal weight was reduced in the EtOH-exposed group. The ratio of midbrain cross sectional area to cerebral aqueduct was reduced in the ethanol group, while the density of neuronal nuclear population in both the dense outer layer (DS) and sparse inner layer (SS) of the developing superior colliculus was increased. Mean nuclear volume was decreased in the SS.

Synaptogenesis in the hippocampal dentate gyrus: effects of in utero ethanol exposure

In animal models of Fetal Alcohol Syndrome, ethanol causes a number of changes in brain development, with many of these changes being very transient. This is especially true for the process of synaptogenesis in different brain areas. Our quantitative electron microscopic study of synaptogenesis in the molecular layer of the rat dentate gyrus supports the above statement, by demonstrating that ethanol has no effect on the appearance of synapses in the dentate gyrus during early postnatal life (10-30 days old). However, prenatal ethanol exposure does appear to affect the process of synapse turnover, which is indicated by the significantly delayed appearance of complex (curved) synapses and multiple synaptic contacts on single axonal terminals. Efficient synapse turnover is thought to be required for the normal maintenance of neuronal plasticity, which in turn ensures an animal's ability to respond to novel environments, tasks and injuries. It would seem that the prenatal neurotoxicology of ethanol may manifest itself by more subtle mechanisms at sites of structural and functional importance.

Effect of prenatal exposure to ethanol on the development of cerebral cortex: I. Neuronal generation

Prenatal exposure to ethanol causes profound disruptions in the development of the cerebral cortex. Therefore, the effect of in utero ethanol exposure on the generation of neurons was determined. Pregnant rats were fed a liquid diet in which ethanol constituted 37.5% of the total caloric content (Et) or pair-fed an isocaloric control diet (Ct) from gestational day (GD) 6 to the day of birth. The time of origin of cortical neurons was determined in the mature pups of females injected with [3H]thymidine on one day during the period from GD 10 to the day of birth. The brains were processed by standard autoradiographic techniques. Ethanol exposure produced multiple defects in neuronal ontogeny. The period of generation was 1-2 days later for Et-treated rats than for rats exposed prenatally to either control diet. Moreover, the generation period was 1-2 days longer in Et-treated rats. The numbers of neurons generated on a specific day was altered; from GD 12-19 significantly fewer neurons were generated in Et-treated rats than in Ct-treated rats, whereas after GD 19 more neurons were born. The distribution of neurons generated on a specific day was disrupted; most notable was the distribution of late-generated neurons in deep cortex of Et-treated rats rather than in superficial cortex as they are in controls. Cortical neurons in Et-treated rats tended to be smaller than in Ct-treated rats, particularly early generated neurons in deep cortex. The late-generated neurons in Et-treated rats were of similar size to those in Ct-treated rats despite their abnormal position in deep cortex. Neurons in Ct-treated rats tended to be rounder than those in Et-treated rats which were more polarized in the radial orientation. A proliferation index, which was based on the amount of autoradiographic signal over each labeled neuron, indicated that an additional, late surge in proliferative activity occurred in Et-treated rats on GD 20-21. The amount of [3H]thymidine incorporated each day was determined by biochemical analyses. In Ct-treated rats, incorporation increased to a maximum on GD 17 and decreased thereafter. In Et-treated rats, there were two maxima, the first on GD 18 and the second on GD 20. These data fully support the findings of the autoradiographic analyses. The present data show that neuronal generation is profoundly affected by ethanol. Such disturbances result from ethanol-induced abnormalities in neuronal proliferation and migration.

Prenatal ethanol exposure decreases hippocampal 3H-glutamate binding in 45-day-old rats

The effect of prenatal ethanol exposure on putative glutamate receptor binding sites in rat brain was studied using radiohistochemical techniques. Pregnant Sprague-Dawley rats were fed a liquid diet containing either 3% or 6% (vol./vol.) ethanol throughout gestation. Pair-fed dams received isocalorically matched liquid diets and a lab chow ad lib group served as control for paired feeding. At 45 days of age, the offspring were sacrificed and their brains analyzed by in vitro 3H-glutamate autoradiography. Compared to pair-fed controls, specific 3H-glutamate binding was reduced by 49-53% in regions of the dorsal hippocampal formation of 45-day-old rats whose mothers consumed either 3% or 6% ethanol diets. Specific 3H-glutamate binding was decreased also in the ventral hippocampal formation, entorhinal and posterior neocortex, but to a less consistent degree and magnitude than in dorsal hippocampal formation of fetal alcohol rats. The reduction in hippocampal 3H-glutamate binding 45 days after prenatal ethanol exposure suggests a long-lasting net decrease in glutamate-mediated excitatory neurotransmission within the hippocampal formation of fetal alcohol rats. This glutamate receptor binding site alteration may be one factor contributing to a decrease in long-term potentiation of hippocampal CA1 pyramidal neurons in fetal alcohol rats. In addition, this alteration may underlie learning and other behavioral deficits associated with functional defects of the hippocampal formation.

Morphological recovery of hippocampal pyramidal neurons in the adult rat exposed in utero to ethanol

Reduced numbers of dendritic spines on the secondary apical dendritic branches and basilar dendrites of CA1 and CA3 pyramidal neurons were observed in ethanol-treated rats during embryonic life aged 15 days when compared with age-matched controls. However, differences were no longer present at the age of 90 days. These results suggest that recovery of some morphological parameters of pyramidal hippocampal neurons may occur in rats exposed in utero to ethanol.

Microencephaly and hyperactivity in adult rats can be induced by neonatal exposure to high blood alcohol concentrations

To investigate whether or not blood alcohol concentration during the brain growth spurt has an influence on the permanency of alcohol-induced central nervous system damage, an artificial rearing technique was used to administer a daily dose of alcohol (6.6 g/kg/day) to neonatal rats during postnatal days 4 to 10. The alcohol was administered either in a condensed pattern over 8 h resulting in cyclic blood alcohol concentrations with high peaks, or uniformly over each 24-h period resulting in stable, but low peaks. The condensed alcohol exposure resulted in considerable microencephaly (20% to 25%), with significant growth deficits in the cerebrum, cerebellum, and brain stem of rats of either sex at day 10; there still was significant microencephaly (16% to 19%) in adult rats that received the condensed alcohol exposure as neonates. Furthermore, activity at day 90 in rats of either sex that had condensed alcohol exposure was elevated compared with that of the gastrostomy control group. In contrast, the rats having uniform alcohol exposure had only nonsignificant changes in brain weight both on day 10 and day 90 and did not exhibit hyperactivity at day 90. Thus, neonatal alcohol exposure producing high blood alcohol concentrations caused permanent deficits in brain growth and significant changes in activity, whereas the same daily dose of alcohol administered in a pattern that resulted in consistently low blood alcohol concentrations failed to produce either permanent microencephaly or increased activity. These data support the hypothesis that patterns of alcohol exposure that produce high concentrations in the blood, such as "binge-drinking," increase the risk of permanent damage to the developing brain.

Effect of prenatal exposure to alcohol on the distribution and time of origin of corticospinal neurons in the rat

The distribution and the time of origin of corticospinal neurons were examined in rats prenatally exposed to ethanol and in control rats. The distribution of corticospinal neurons was determined by tracing the retrograde transport of horseradish peroxidase (HRP) from an injection site in the cervical spinal cord. In control rats, HRP-positive neurons were distributed in layer Vb throughout motor area 4, rostral motor area 6/8, dorsal somatosensory area 3, caudal somatosensory area 2, and various "association" regions including parietal areas 14, 39, and 40, occipital areas 18a and 18b, cingulate areas 24a and 24b, and prefrontal area 32. In ethanol-exposed rats, the distribution of retrogradely labeled neurons was similar to control animals with three notable exceptions: (1) HRP-positive neurons were evident throughout the rostrocaudal extent of area 6/8; (2) occasionally ectopic labeled neurons were identified in the supragranular layers, layers Va and Vc, and superficial layer VI; and (3) the density of HRP-labeled neurons and the ratio of labeled neurons to the total number of neurons in areas 4, 6/8, 3 and 2 were significantly greater (20-48%) in ethanol-exposed rats than in controls. There was, however, no intergroup difference in the area of the cell bodies of HRP-positive neurons. Taken together, these findings indicate that ethanol exposure resulted in an increased number of corticospinal neurons. The time of origin of corticospinal neurons was determined by using a technique that combined tritiated thymidine autoradiography and retrograde transport of HRP. In control animals, HRP-positive neurons were double labeled by an injection of tritiated thymidine on gestational day (GD) 15, 16, or 17. In ethanol-exposed rats, corticospinal neurons were generated on GD 16, 17, and 18, the late-generated ones being distributed in caudal area 6/8. These intergroup differences represent a persisting ethanol-induced alteration of cortical structure that may underlie motor dysfunction and mental retardation in fetal alcohol-affected offspring. Moreover, the increase in the number and the delay in the time of origin of corticospinal neurons suggest that the normal process of paring down exuberant corticospinal projections may be affected by prenatal exposure to ethanol.

Differential deficits in regional brain growth induced by postnatal alcohol

Neonatal rats were exposed to alcohol during a period of brain development equivalent to part of the human third trimester. Rat pups were fed a milk formula containing either alcohol (9.8 g/kg/day) or isocaloric maltose/dextrin using artificial rearing techniques from postnatal days 4-10. Blood alcohol concentrations reached 345.8 +/- 15.6 mg/dl on postnatal day 6. All animals, including a group of normally reared suckle controls, were sacrificed on postnatal day 10, and the brains were perfused and processed for the Timm histochemical technique. Significant microencephaly (30% reduction in brain growth) was found in the alcohol-exposed animals. Growth deficits also were found in specific brain regions of the alcohol-exposed rats. The overall area of the hippocampus proper at a midtemporal level was reduced by 26.1% compared to controls. Sublaminae within the hippocampus were stunted as much as 40.5%. An overall reduction of 14.5% was found in the midsagittal (vermal) cerebellum. In contrast, growth of the dentate gyrus appeared much less affected (6.8% deficit) by the alcohol exposure. These data indicate that not all regions of the brain are affected equally by alcohol exposure during the third trimester equivalent.

Effects of alcohol on the generation and migration of cerebral cortical neurons

Prenatal exposure to alcohol produces many developmental defects of the central nervous system, such as microcephaly, mental retardation, motor dysfunction, and cognitive deficiencies. Therefore, the generation of neurons in the cerebral cortex was examined in the offspring of female rats fed a diet containing ethanol. Prenatal exposure to ethanol delayed and extended the period during which cortical neurons were generated, reduced the number of neurons in the nature cortex with the same time of origin, and altered the distribution of neurons generated on a particular day. Thus, the proliferation and migration of cortical neurons are profoundly affected by in utero exposure to ethanol.

A light and electron microscopic analysis of the mossy fibers of the rat dentate gyrus

The axon collaterals of dentate granule cells have been analyzed with the aid of a computerized microscope, following intracellular injections of horseradish peroxidase in hippocampal slice preparations. The axon of each granule cell gives rise to approximately seven primary collaterals; these collaterals usually divide into secondary and tertiary branches, which form an extensive plexus within the hilar region of the dentate gyrus. Individual axon collaterals vary greatly in length, but most have been found to be between 100 and 300 microns long. On average, the summed lengths of the collaterals (exclusive of the parent mossy fiber) are approximately 2,300 microns. Except for an occasional collateral that is given off by a mossy fiber in the proximal part of field CA3 of the hippocampus, the collaterals of the granule cell axons are confined to the hilar region; they are rarely seen in the granule cell layer itself and have never been observed in the molecular layer. In the longitudinal dimension of the dentate gyrus, most of the collaterals are contained within a zone about 400 microns wide. The distribution of the collaterals within the hilar region is correlated with the location of the granule cell body. Those that arise from cells near the tip of the suprapyramidal blade tend to be confined to the region above field CA3; those from cells nearer the crest and from the infrapyramidal blade ramify widely throughout the hilus. Two types of varicosities are present on the collaterals. Numerous small (approximately 2 microns), round varicosities are distributed unevenly along the collaterals; in electron micrographs these varicosities can be seen to make asymmetric synaptic contacts with dendritic shafts. On average, each granule cell collateral plexus has about 160 of these varicosities. The second type of varicosity is irregular in shape and ranges from 2 to 4 microns in diameter; there is usually only one such varicosity per collateral. In all respects except size, these varicosities resemble the expansions found on the parent mossy fibers. Mossy fiber trajectories in the proximal part of field CA3 were studied after extracellular injections of HRP into localized regions of the granule cell layer. Granule cells at different locations around the blade send their mossy fibers to different depths within the pyramidal cell layer in the proximal part of field CA3. However, further distally, mossy fibers from all parts of the granule cell layer contribute to the suprapyramidal bundle that occupies the stratum lucidum.

Dendritic arbors and dendritic excrescences of abnormally positioned neurons in area CA3c of mice carrying the mutation "hippocampal lamination defect"

BALB/cJ and BALB/cByJ mice are homozygous for the autosomal gene "hippocampal lamination defect" (provisional gene symbol: Hld) which produces an abnormality in the lamination of the pyramidal cell layer of area CA3c of the hippocampus such that early-generated neurons are superficial and late-generated neurons are deep. Other inbred strains of mice are wild-type (+/+) at the Hld locus and do not have this inversion in cell position in area CA3c. The Golgi method was used to analyze the dendritic arbors of the abnormally positioned pyramidal cells and to compare the distribution of dendritic excrescences (i.e., the termination sites of the mossy fibers) in +/+ and Hld/Hld mice. It was found that in +/+ mice the late-generated pyramidal cells (whose cell bodies are positioned just below the suprapyramidal mossy fiber layer) have one set of dendritic excrescences on their apical dendrites as they extend through the suprapyramidal mossy fiber layer and a second set on their basal dendrites as they pass through the infrapyramidal mossy fiber layer. In contrast, in Hld/Hld mice the late-generated pyramidal cells (whose cell bodies are abnormally positioned just below the intrapyramidal mossy fiber layer) have two sets of dendritic excrescences on their apical dendrites, as they pass through the intrapyramidal and suprapyramidal mossy fiber layers, and none on their basal dendrites. In addition, in the vicinity of the apparent point of contact of the intrapyramidal mossy fibers, the apical dendrites of some of the abnormally positioned pyramidal cells have several fine-caliber branches.(ABSTRACT TRUNCATED AT 250 WORDS)

Prenatal exposure to ethanol retards the development of kindling in adult rats

The development of kindling was examined in adult rats exposed to ethanol prenatally. Pregnant Wistar rats were fed a liquid diet containing either 6.7% ethanol or pair fed an isocaloric equivalent. At birth, the litters were cross fostered to surrogate mothers. At 80 days of age, a bipolar electrode was placed either in the right basolateral amygdala or the right angular bundle of entorhinal cortex. Kindling stimulations were administered three times a day until each rat had exhibited three class 5 kindled motor seizures. The total number of kindling stimulations required to exhibit class 1 through class 5 motor seizures was significantly greater in the rats exposed to ethanol prenatally. Further, the retardation in kindling development was due to a slower progression from class 0 to class 1 kindled motor seizures. Progression between other stages was not different between the two groups. Similar results were obtained in both amygdala and angular bundle kindling experiments. Kindling is retarded in a similar fashion by partial destruction of the dentate granule cells of the hippocampal formation. Further, the pattern of dentate granule cell axonal projections to hippocampal CA3 pyramidal neurons is altered in rats exposed to ethanol prenatally. Taken together, these data suggest the possibility that a defect in the neuronal circuitry within the hippocampal formation of fetal alcohol rats may underlie a retardation in their kindling progression. This proposed defect may have functional implications related to learning deficiencies in rats and children exposed to ethanol prenatally.

Organization of the commissural projection to the dentate gyrus is unaltered by heavy ethanol exposure during gestation

The anterograde horseradish peroxidase method was used to determine if prenatal exposure to ethanol affected the development of the characteristic afferent lamination pattern of the commissural projection to the dentate gyrus. Mean ethanol consumption for the ethanol-consuming dams was 12.7 g/kg +/- 0.3 g per day. Adult offspring of rats that consumed a liquid diet containing 35% ethanol-derived calories during days 1-21 of gestation, and both pair-fed and normal controls were examined. Brain weights and volumes of the ethanol and pair-fed control rats did not differ significantly from normal controls. However, body weights of ethanol-exposed rats were significantly reduced compared to normal controls. Computer-assisted image analysis of the HRP-labeling revealed that in spite of the heavy ethanol exposure there was no evidence of alterations in the spatial distribution of the commissural terminal field.

Direct evidence for enhanced axon sprouting in adult rats exposed to ethanol in utero

The anterograde transport of horseradish peroxidase (HRP) was utilized to examine the post-lesion expansion of the commissural projection to the molecular layer of the dentate gyrus in adult rats prenatally exposed to ethanol, and in normal and pair-fed controls. Mean daily ethanol consumption by the pregnant dams was 12.0 +/- 1.6 g/kg. Similar consumption in a separate group of pregnant dams produced mean blood ethanol concentrations of 102.8 +/- 5.2 mg/dl of blood. The commissural terminal field of rats exposed to ethanol in utero and given unilateral entorhinal lesions as adults exhibited a significantly greater expansion compared to controls. There were no differences in the HRP-labeled terminal fields between normal and pair-fed animals with similar lesions, suggesting that the effect in the ethanol-exposed rats was due to ethanol teratogenicity rather than reduced caloric intake. Furthermore, the effect was not a function of altered organization of commissural and perforant path terminal fields (terminal field overlap). These data demonstrate that exposure to ethanol in utero produces long-lasting alterations in lesion-induced axon sprouting.

Perforant pathway lamination in the dentate gyrus is unaffected by prenatal ethanol exposure

The entorhinal (perforant path) projection to the dentate gyrus was labeled with an anterograde horseradish peroxidase method to test whether prenatal exposure to ethanol affected the normal development of afferent lamination. Mean ethanol consumption of the ethanol-consuming dams was 12.7 g/kg +/- 0.3 g per day during days 1-21 of gestation. Adult offspring of normal and pair-fed controls as well as ethanol-exposed rats were analyzed. Computer-assisted image analysis of the entorhinal terminal field organization revealed no permanent changes in the development of the afferent lamination pattern in the dentate gyrus molecular layer in spite of the heavy in utero ethanol exposure.

Effects of alcohol exposure during different periods of development: changes in hippocampal mossy fibers

Exposure to 10-12 g/kg/day of alcohol either during days 1-10 or 11-21 of gestation had no detectable effect on hippocampal mossy fiber development. Exposing artificially reared rat pups to 7.0-7.5 g/kg/day of alcohol during days 1-10 postpartum dramatically altered the organization of the Timm-stained mossy fiber terminal field when the animals were examined as adults, suggesting that alcohol exposure during a period equivalent to the human third trimester is more deleterious to brain development than exposure during periods equivalent to either the first or second trimesters.

Delay in brain growth induced by alcohol in artificially reared rat pups

The effect of alcohol on body and brain growth of the neonatal rat was examined. An artificial rearing procedure was used to administer a milk formula containing 2.8% alcohol to rat pups during days 4-10 postpartum. Mean blood alcohol levels taken at hourly intervals between feelings at the end of the second day of exposure ranged between 151 and 163 mg/dl. Body growth in both groups of artificially reared pups was similar to that of the suckle control pups. Gross measurements indicated that while alcohol exposure did not arrest body growth, it did arrest several parameters of brain growth. There were deficits in brain weight and volume and in the brain weight to body weight ratio. Furthermore, there were sex-related differences. The brain weight to body weight ratio was significantly decreased in females and there was also a trend toward a greater deficit in brain volume as well. However, deficits in gross measures were not reflected in the development of the hippocampal formation. Areal measurements of the hippocampus and dentate gyrus failed to indicate any differential effects on the growth of the pyramidal and granule cell layers, or their dendritic fields and corresponding Timm-stained sublaminae, due to the alcohol exposure. These data suggest that the blood alcohol concentrations reached in the present study may be near the threshold dose for producing deficits in brain growth, and that the females have a lower threshold than the males.