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

BACKGROUND: Alcohol exposure during development has been shown to alter a variety of social behaviors in both humans and rodents. Sexual behavior in rodents has been well characterized and lends itself to a detailed investigation of the manner in which ethanol impacts this particular social behavior. METHODS: Rats were exposed to ethanol during both the prenatal and early postnatal period (ET). Control groups included rats exposed to the administration procedures alone (intubated-control) and nontreated controls (NC). Sexual behavior of intact naïve female rats in estrus was assessed in adulthood (approximately postnatal day 90) and activity was measured by the number of crossings between chambers in the 3-chamber test apparatus. A separate study examined the olfactory preferences for 4 odors by intact naïve female rats in all 3 groups. The 4 odors were the odors resulting from 1 hour of occupation of the test chamber by an intact male, 1 hour of occupation of the test chamber by a gonadectomized male, 0.5 ml of urine from an intact male, and 0.5 ml of urine from a gonadectomized male. RESULTS: ET female rats showed a reduced return latency after ejaculation compared to both control groups. There was a trend toward a reduction in percent exits after all forms of male behavior in the ET animals compared to the control groups. No significant differences across groups were seen in the lordosis quotient, activity, or the behavior of the nonexperimental male. ET female rats showed a reduced preference for the odor from the intact male compared to both control groups and a reduced preference for the odor from the gonadectomized male compared to NC females only. CONCLUSIONS: These data suggest that ethanol exposure during the prenatal and postnatal period in females alters sexual motivation and changes the processing of olfactory cues and possibly coital cues from male rats.

Ethanol exposure during development reduces resident aggression and testosterone in rats.

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

Genetic reduction of noradrenergic function alters social memory and reduces aggression in mice.

Aberrant social behavior is a hallmark of many cognitive, mood, and neurological disorders, although the specific molecular mechanisms underlying the behavioral deficits are not well understood. The neurotransmitter noradrenaline (NA) has been implicated in some of these disorders, as well as in several aspects of social behavior in humans and animals. We tested dopamine beta-hydroxylase knockout (Dbh -/-) mice that lack NA in various social behavior paradigms. Dbh -/- mice have relatively normal performance in the elevated plus maze, light/dark box, and open field test - three measures of anxiety - and a social recognition test. In contrast, Dbh -/- mice displayed a specific deficit in a social discrimination task and had a nearly complete absence of resident-intruder aggression. These results indicate that intact NA signaling is required for some types of social memory and aggression, but that a lack of NA does not greatly affect anxiety in mice. Further exploration of NA deficits in neurological disease may reveal mechanisms of aberrant social behavior.

Vitamin E protects against alcohol-induced cell loss and oxidative stress in the neonatal rat hippocampus.

Oxidative stress has been proposed as a possible mechanism underlying nervous system deficits associated with Fetal Alcohol Syndrome (FAS). Current research suggests that antioxidant therapy may afford some level of protection against the teratogenic effects of alcohol. This study examined the effectiveness of antioxidant treatment in alleviating biochemical, neuroanatomical, and behavioral effects of neonatal alcohol exposure. Neonatal rats were administered alcohol (5.25 g/kg) by intragastric intubation on postnatal days 7, 8, and 9. A subset of alcohol-exposed pups were co-administered a high dose of Vitamin E (2 g/kg, or 71.9 IU/g). Controls consisted of a non-treated group, a group given the administration procedure only, and a group given the administration procedure plus the Vitamin E dose. Ethanol-exposed animals showed impaired spatial navigation in the Morris water maze, a decreased number of hippocampal CA1 pyramidal cells, and higher protein carbonyl formation in the hippocampus than controls. Vitamin E treatment alleviated the increase in protein carbonyls and the reduction in CA1 pyramidal cells seen in the ethanol-exposed group. However, the treatment did not improve spatial learning in the ethanol-exposed animals. These results suggest that while oxidative stress-related neurodegeneration may be a contributing factor in FAS, the antioxidant protection against alcohol-induced oxidative stress and neuronal cell loss in the rat hippocampus does not appear to be sufficient to prevent the behavioral impairments associated with FAS. Our findings underscore the complexity of the pathogenesis of behavioral deficits in FAS and suggest that additional mechanisms beyond oxidative damage of hippocampal neurons also contribute to the disorder.

Ultrasonic vocalizations and maternal-infant interactions in a rat model of fetal alcohol syndrome.

When isolated from their dams and littermates, rat pups emit ultrasonic vocalizations to elicit attention and retrieval from their dams. This study examined the effects of perinatal alcohol exposure on ultrasonic vocalizations and maternal-infant interactions. Alcohol was administered throughout gestation to the dams and during the early postnatal period to the pups. Control groups consisted of a nontreated control and an intubated, pair-fed control. Ultrasonic vocalizations were measured on postnatal day (PD) 5 under varying conditions of isolation. Maternal behaviors were examined on PD2, 4, 6, 8, and 10. Maternal behaviors were not significantly affected by prior alcohol administration to either the dams or the pups. However, ethanol-exposed rat pups vocalized more on PD5 than controls regardless of condition. The heightened vocalization response of the ethanol-exposed pups might be an underlying factor in the persistent effects of perinatal ethanol exposure on social behavior.