[Amygdaloid control over interspecies and shock-induced aggression in the rat (author's transl)]

Hormone-dependent aggression in male and female rats: experiential, hormonal, and neural foundations

Hormone-dependent aggression in both male and female rats includes the distinctive behavioral characteristics of piloerection and lateral attack. In males the aggression is dependent on testicular testosterone and is commonly known as intermale aggression. In females, the aggression is most commonly observed as maternal aggression and is dependent on hormones whose identity is only beginning to emerge. The present review examines the experiential events which activate hormone-dependent aggression, the relation of the aggression to gonadal hormones, and the neural structures that participate in its modulation. In males and females, the aggression is activated by cohabitation with a conspecific of the opposite sex, by competitive experience, and by repeated exposure to unfamiliar conspecifics. In the female, the presence of pups also activates aggression. In both males and females, hormones are necessary for the full manifestation of the aggression. The essential hormone appears to be testosterone in males and a combination of testosterone and estradiol in females. The information available suggests the neural control systems for hormone-dependent aggression may be similar in males and females. It is argued that hormone-dependent aggression is behaviorally and biologically homologous in male and female rats.

Aggressive behavior inhibition by serotonin and quipazine injected into the amygdala in the rat

The effects on aggressive behavior, open-field activity, and pain threshold of bilateral microinjections of serotonin (20 micrograms) and quipazine (20 micrograms), the direct serotonergic receptor agonist, into the cortico-medial amygdala were investigated in Wistar rats. Both drugs significantly prolonged the attack latency in isolated killer rats (predatory aggression model), and suppressed the incidence of aggressive postures/attacks in shock-induced fighting test (affective aggression). The only difference in the open-field behavior was the lower number of central square entries in drug-treated compared to saline-injected rats. None of the substances produced any significant change in jump threshold. It is concluded that stimulation of serotonin receptors within the amygdala produces inhibition of affective and muricidal behavior in isolated rats. The effect does not seem to be dependent on changes in general activity and pain sensitivity.

Neural systems and the inhibitory modulation of agonistic behavior: a comparison of mammalian species

The olfactory bulb, lateral septum, medial accumbens, medial hypothalamus, dorsal and median raphe, and amygdala are known from experiments in rats to participate in the inhibitory modulation of defensiveness and predation but not social aggression. The present paper surveys the influence of these structures in the inhibitory control of these same dimensions of agonistic behavior in other species. The existing evidence suggests that lesions in the lateral septum, medial accumbens, medial hypothalamus, or the dorsal and median raphe (or PCPA-induced depletion or serotonin) induce hyperreactivity to the experimenter in mice, rats, cats, dogs, and humans in every instance where they have been tested with one exception. The exception is that lesions in the medial hypothalamus of mice do not induce heightened reactivity. The same lesions do not cause this dramatic increase in reactivity to the experimenter in gerbils, hamsters, guinea pigs, or rabbits but do heighten some other species typical patterns of defensiveness such as alarm calls and avoidance of contact with conspecifics. Lesions in these same areas in monkeys have not been observed to heighten defensive behaviors. Predatory killing or killing of young conspecifics has been observed in hamsters, mice, rats, and cats in every instance where they have been examined following lesions of the olfactory bulbs, lateral septum, medial accumbens, medial hypothalamus, or the dorsal and median raphe nuclei (or PCPA-induced depletion of serotonin). Social aggression has been decreased with these same lesions in each case where they have been examined except for septal lesions in hamsters which have been reported to heighten social aggression. Across species, the consistency with which lesions of the olfactory region, lateral septum, medial accumbens, medial hypothalamus, and dorsal and median raphe nuclei alter defensiveness and predation but not social aggression supports the inference that neural systems exist which subserve the inhibitory modulation of these dimensions of behavior. Finally, the evidence that the disruption of functioning within these structures in humans results in increased agonistic responses to environmental stimuli serves to further establish the important role of this neural circuitry in the normal inhibitory modulation of agonistic behavior in humans.

The inhibitory modulation of agonistic behavior in the rat brain: a review

Neural regions which exercise an inhibitory influence on agonistic behavior are identified by the enhancement of agonistic behavior that follows their removal. The specific kinds of agonistic behaviors altered by each region are then examined. Increased reactivity to the experimenter and enhanced shock-induced fighting are produced by lesions of the region ventral to the anterior septum, the lateral septum, the medial hypothalamus, and the dorsal and median raphe nuclei. It is argued that the increased reactivity and shock-induced fighting correspond to an enhancement of defensive behavior. Mouse killing is induced by lesions of the anterior olfactory nucleus, the region ventral to the anterior septum, the lateral septum, the medial hypothalamus, the dorsal and median raphe nuclei, and the medial amygdala. Because the lesion-induced mouse killing is similar to that emitted by spontaneous mouse killers, it is argued that these regions normally exert an inhibitory control over predatory killing. The available evidence on social attack behavior has not convincingly identified regions exerting an inhibitory control over this dimension of behavior. Our conclusion is that separate brain systems exert an inhibitory control over defensive behavior, predatory killing, and social attack behavior. To a substantial extent, the regions modulating these behaviors appear to act independently of one another. The only neurotransmitter that is clearly active in these inhibitory systems is serotonin, and has only been directly implicated in the control of mouse killing by neurons originating in the dorsal and median raphe nuclei.

Tryptophan deprivation: effects on mouse-killing and reactivity in the rat

Following a 5-week maintenance on a low-tryptophan diet, brain 5-HT content was reduced to 75%, whereas NA and DA levels remained unchanged as compared to controls. Reactivity to air-puffs as well as to the novelty of the open-field was increased. Incidence of mouse-killing was examined in 2 groups of Wistar rats maintained on the tryptophan-deficient diet for 2 and 4 weeks, respectively, before being tested with a mouse: 70% and 60% of them killed mice, compared to 20% killers in rats given free access to standard food, and 20% killers in rats given a limited access to standard food so as to reproduce the suppression of weight gain observed in the tryptophan-deficient animals. Prior non-aggressive interactions with mice significantly reduced later incidence of mouse-killing following a 4-week tryptophan-poor diet, thus confirming the suppressant effect of prior familiarization with mice on elicitation of mouse-killing as a result of brain 5-HT depletion. Once initiated, mouse-killing persisted even when the rats were returned to standard food, demonstrating that reduced 5-HT activity is not necessary for the maintenance of this behavior.