Ethanol teratogenesis in the C57BL/6J, DBA/2J, and A/J inbred mouse strains

Differential teratogenic effect of alcohol on embryonic development between C57BL/6 and DBA/2 mice: a new view

BACKGROUND

Alcohol exposure during the fetal stage generates variable severity in different organs, as seen in fetal alcohol syndrome and fetal alcohol effect. Whether genetic factors or conditions of alcohol exposure influence the susceptibility to alcohol-related developmental impairment remains a question.

METHODS

To investigate the contribution of genotype to the susceptibility to alcohol-induced toxicity during development beyond confounding maternal factors and variables of alcohol exposures, the authors tested the effect of alcohol exposure under definitive concentration using a whole embryonic culture of two inbred strains previously known to be vulnerable (C57BL/6 [C6]) or resistant (DBA/2 [D2]) to alcohol. On gestational day 8, embryos from each group bearing three to six somites were collected and then cultured for 44 hr in a medium added with 400 mg/dl of ethanol. The viability and morphological malformations, as well as developmental staging of the embryos, were all scored at the end of the culture.

RESULTS

The authors found, in contrast to previous reports, that alcohol treatment retarded embryonic growth and induced abnormalities, including the neural tube opening and the hypoplasia of the optic vesicle in both strains. However, alcohol specifically compromised the heart and caudal neural tube in C6, whereas it specifically decreased the number of somites and the development of branchial bars among others in D2.

CONCLUSIONS

These results demonstrated that both strains of embryos are vulnerable to the same amount and pattern of alcohol exposures at the same developmental stage, but each with unique vulnerability in specific organs, with alcohol having greater teratogenic effects in D2 than in C6. These differential vulnerabilities are results of greater genetic influence, rather than the maternal influence or conditions of alcohol.

Gene-expression analysis after alcohol exposure in the developing mouse

Exposure to alcohol in the embryonic mouse can lead to structural and neurophysiologic changes. The cause of these changes is poorly understood, but they are likely the result of numerous mechanisms. Here we investigate ethanol-induced alterations in gene expression in the fetal brain. Using complementary-DNA microarrays, we identified 25 genes that were down-regulated by prenatal ethanol exposure on days 7 and 9 of gestation. None were found to be up-regulated. Of those that were repressed, 6 (Timp4, Bmp15, Rnf25, Akt1, Tulp4, Dexras1) have been identified, and they are discussed here in the context of the developing fetus. The identified genes have been shown to be involved in cell proliferation, differentiation, and apoptosis, and they contribute to tissue growth and remodeling, as well as neuronal growth and survival. Microarray studies may be useful in the identification of a genetic marker for fetal alcohol syndrome, the discovery of novel pathways that may be involved in its origin, or both.

Genetic polymorphisms: Impact on the risk of fetal alcohol spectrum disorders

Clinical reports on monozygotic and dizygotic twins provided the initial evidence for the involvement of genetic factors in risk vulnerability for fetal alcohol spectrum disorders (FASD) including fetal alcohol syndrome (FAS). Research with selectively bred and inbred rodents, genetic crosses of these lines and strains, and embryo culture studies have further clarified the role of both maternal and fetal genetics in the development of FASD. Research to identify specific polymorphisms contributing to FASD is still at an early stage. To date, polymorphisms of only one of the genes for the alcohol dehydrogenase enzyme family, the ADH1B, have been demonstrated to contribute to FASD vulnerability. In comparison with ADH1B*1, both maternal and fetal ADH1B*2 have been shown to reduce risk for FAS in a mixed ancestry South African population. ADH1B*3 appears to afford protection for FASD outcomes in African-American populations. Other candidate genes should be examined with respect to FASD risk, including those for the enzymes of serotonin metabolism, in particular the serotonin transporter. By its very nature, alcohol teratogenesis is the expression of the interaction of genes with environment. The study of genetic factors in FASD falls within the new field of ecogenetics. Understanding of the array of genetic factors in FASD will be enhanced by future genetic investigations, including case-control, family association, and linkage studies.

Strain-dependent effects of developmental ethanol exposure in zebrafish

Developmental ethanol exposure from maternal consumption of alcoholic beverages and many other consumer products has been linked to developmental abnormalities in humans and animal models. The sensitivity of an individual to ethanol-induced perturbation of developmental processes is strongly influenced by genetic factors. In this study, we show that there are strain- and dose-dependent differences in sensitivity to developmental ethanol exposure in zebrafish (Danio rerio), suggesting that genetic variation within regulatory factors, influencing critical developmental pathways, is responsible for these differences. Embryos/larvae from genetically distinct strains of zebrafish [Ekkwill (EK), AB, and Tuebingen (TU)] were treated with different concentrations of ethanol. Embryo/larval survival, neurocranial and craniofacial skeletal development, and CNS cell death were analyzed. EK was the most resistant strain to the embryolethal effects of ethanol exposure but had the greatest increase in ethanol-induced cell death. AB survival was affected moderately, as were the neurocranial and craniofacial skeletal structures and ethanol-induced cell death. TU had the lowest survival rate but was the most resistant to alterations in neurocranial and craniofacial skeletal elements. No single strain is the most sensitive or the most resistant to any of the phenotypes examined, suggesting that alcohol influences each of these pathways independently. Further analysis of the molecular and biochemical pathways underlying the strain-dependent differences reported herein could lead to a significant advancement in our mechanistic understanding of the teratogenic effects of ethanol in humans.

Differential vulnerability to motor deficits in second replicate HAS and LAS rats following neonatal alcohol exposure

Children exposed prenatally to alcohol suffer from a variety of behavioral alterations. However, variation exists in the pattern and severity of these alcohol-related neurodevelopmental disorders. We examined the influence of alcohol sensitivity in the etiology of fetal alcohol effects by studying rat lines selectively bred for extremes in alcohol-induced sleep time: high-alcohol-sensitive (HAS) and low-alcohol-sensitive (LAS) rats. Using subjects from the first replicate, we previously reported that HAS rats exposed to alcohol during development were more vulnerable to ethanol-induced hyperactivity and motor deficits compared to LAS rats. To determine if these effects were, in fact, related to the trait for which these subjects were selected, the present study examined the consequences of developmental alcohol exposure in second replicate HAS and LAS rats. Second replicate HAS and LAS rats, as well as Sprague-Dawley rats, were exposed to 6.0 g/kg/day ethanol on Postnatal Days (PD) 4-9, a period of brain development equivalent to the third trimester, via an artificial rearing procedure. Artificially and normally reared controls were included. Activity was measured on PD 18-21 and parallel bar motor coordination on PD 30-32. Ethanol exposure produced hyperactivity in all genetic groups, and there were no differences among HAS and LAS rats. In contrast, consistent with findings from the first replicate, ethanol-exposed HAS rats were more impaired on the motor coordination task compared with LAS rats. These data suggest that genetically mediated responses to alcohol may relate to behavioral vulnerability to motor deficits following developmental alcohol exposure. They also provide evidence that genetic factors play a role in fetal alcohol effects and suggest that phenotypic markers may indicate individuals at high risk for some fetal alcohol effects.

Neonatal alcohol exposure produces more severe motor coordination deficits in high alcohol sensitive rats compared to low alcohol sensitive rats

Prenatal exposure to alcohol can produce a number of behavioral alterations, including hyperactivity, learning deficits and motor impairments. However, the severity and nature of behavioral alterations varies markedly among children of women who drink during pregnancy. One important determinant of this variation may be genetic differences in the response to alcohol. Recently, we demonstrated that exposure to alcohol during development produced hyperactivity in rats bred for high alcohol sensitivity (HAS), but not in rats bred for low alcohol sensitivity (LAS). These lines were selectively bred for extremes in alcohol-induced "sleep time." The present study investigated the effects of ethanol exposure during development on motor coordination later in life in both HAS and LAS rats. Using an artificial rearing procedure, neonatal pups from each line were exposed to a binge-like alcohol treatment on postnatal days (PD) 4-9. Within each line, one group was exposed to ethanol (6.0 g/kg/day), one group served as an artificially reared control, and a third served as a normally reared control group. On PD 30, parallel bar motor performance was evaluated. Exposure to ethanol during development severely impaired motor performance in the HAS rats compared to their controls. In LAS rats, early ethanol exposure produced only mild and nonsignificant effects on motor performance. Thus, HAS rats were more vulnerable to ethanol-induced motor deficits compared to the LAS rats. Importantly, there were no differences in peak blood alcohol level between the lines, indicating that vulnerability to ethanol's teratogenic effects was not due to differences in metabolic rate. These results suggest that genetic differences in response to alcohol may serve as a predictor for susceptibility to ethanol's teratogenic effects.

Alcohol plus cocaine prenatally is more deleterious than either drug alone

A C57BL/6J mouse model was used to examine the coteratology of alcohol and cocaine. Plugged female mice were assigned to one of four treatment groups: control, cocaine only, alcohol only, or alcohol-cocaine. Experimental animals were treated from gestation day (GD) 6-18 and were killed the morning of GD 19. Alcohol was administered in a liquid diet containing 25% ethanol-derived calories (25% EDC), and cocaine was administered daily in subcutaneous injections of 60 mg/kg. All groups were pair-fed to the alcohol-cocaine group. The results showed that the cocaine-only and the alcohol-cocaine group had fewer successful pregnancies. The alcohol-only group had the lowest maternal weight gain from GD 1-19. There were no treatment group effects on litter size, sex ratio, or prenatal mortality. Importantly, fetuses in the alcohol-cocaine group weighed less than all other groups and had the greatest occurrence of fetal anomalies. These data confirm the teratogenic effects of alcohol and cocaine and suggest that the combination of the two drugs, if administered chronically, is more deleterious to pregnancy and fetal outcome than either drug alone.

Physiological stresses increase mouse short interspersed element (SINE) RNA expression in vivo

The possible functionality of short interspersed elements (SINEs) is investigated by assaying the effects of physiological stress on their RNA polymerase-III-directed transcriptional expression in vivo. B2 RNA is expressed at moderately high levels in all mouse tissues investigated, namely liver, spleen, kidney and testis. B1 RNA is expressed in testis but is nearly undetectable in the other tissues. Following hyperthermic shock, the amounts of B1 and B2 SINE RNAs transiently increase in all tissues by as much as 40-fold in certain cases. The kinetics of these increases resemble those of heat shock protein mRNAs. An acute dose of ethanol also transiently increases the abundance of B1 and B2 RNA in liver, showing that other physiological stresses increase SINE RNA expression. The constitutive expression of B2 RNA in all tissues and tissue-specific differences in expression of B1 RNA imply that these transcripts serve a normal physiological function(s). Moreover, increased SINE RNA expression is a vital response to stress and by the criterion of their inducibility, mammalian SINEs behave like regulated cell stress genes.

Neonatal alcohol exposure produces hyperactivity in high-alcohol-sensitive but not in low-alcohol-sensitive rats

Children of women who consume high amounts of alcohol during their pregnancies vary greatly in physical and behavioral outcomes. Although many factors, such as dose and timing of exposure, undoubtedly contribute to this variation, one important determinant may be genetic differences in the response to alcohol. The present study examined activity levels in high alcohol sensitivity (HAS) and low alcohol sensitivity (LAS) rats following neonatal alcohol exposure. These lines were selectively bred for extremes in ethanol-induced "sleep times." The HAS and LAS offspring were exposed to alcohol via an artificial rearing procedure using the "pup-in-the-cup" technique. Rat pups were exposed to ethanol (6 g/kg/day) from postnatal day (PD) 4 through 7 and faded to a dose of 3 g/kg/day on PD 8 and 9. An artificially reared gastrostomy control group (GC) and a normally reared suckle control group (SC) were also included. Activity level was measured on PD 18 through PD 21 for 30 min daily in automated activity monitors. Neonatal ethanol exposure produced overactivity in HAS rats, relative to their controls, but the same ethanol treatment had no effect on the LAS rats. Importantly, there were no differences in blood alcohol concentrations (around 420 mg/dl) between the two lines during the treatment period. These data suggest that genetic differences in response to alcohol may be a predictor for some of the behavioral teratogenic effects of alcohol.