József Halász

Corticosterone response to the plus-maze: High correlation with risk assessment in rats and mice

Exposure to the elevated plus-maze induces behavioural and physiological effects in rodents consistent with fear/anxiety. Maze-naive animals display high levels of risk assessment towards the open arms, and explore these areas less extensively than other parts of the maze while, immediately following the test, pain latencies, skin conductance levels, and plasma corticosterone titres (CORT) are significantly elevated. Although previous research has suggested a link between the plasma CORT response and open-arm exploration, significant elevations in CORT have also been found with restricted exposure to the closed arms. The present study employed ethological measures in an attempt to further characterise the relationship between behavioural and CORT responses to this widely used animal model of anxiety. Our results confirm that, relative to home-cage controls, 5-min exposure to the plus-maze significantly increases plasma CORT levels in test-naive male Wistar rats and male Swiss-Webster mice. Furthermore, in both species, the CORT response was found to be highly correlated with measures of risk assessment (mice: rs = +0.87; rats: rs = +0.58), but not with measures of open-arm activity (entries, time), general locomotor activity, rearing, or head dipping. Findings are discussed in relation to the functional significance of risk assessment in potentially dangerous situations and the potential involvement of glucocorticoids in this process. All rights reserved.

Defeat is a major stressor in males while social instability is stressful mainly in females: towards the development of a social stress model in female rats

Social stress models appear useful in elucidating the interrelationship between stress, mood disorders, and drug efficacy. However, reliable social stress models for females are virtually lacking. The aim of this study was to determine stress-related consequences of (a) defeat in aggressive encounters and (b) social instability, in male and female rats. Defeat in male and female subjects was induced by aggressive male residents and female residents made aggressive by surgery (mediobasal hypothalamic lesion [MBHL]), respectively. Aggressiveness of resident males and resident MBHL females was remarkably similar. Alternating isolation and mixed-sex crowding phases with membership rotation were used to induce social instability. Aggression was kept low in the latter paradigm by manipulating crowding group composition. Defeat stress reduced weight gain, and increased both adrenals and plasma corticosterone in males. Only adrenal weight was affected in females. Social instability reduced weight gain, and induced thymus involution, adrenal hypertrophy and elevated plasma corticosterone levels in females. Only weight gain and thymus weights were affected in males. It is concluded that defeat stresses males more than females, while social instability is more stressful for females than for males, if aggressive contacts are low. It is suggested that the social instability model is a good model of social stress in females.

Fast positive feedback between the adrenocortical stress response and a brain mechanism involved in aggressive behavior.

Aggressive behavior induces an adrenocortical stress response, and sudden stressors often precipitate violent behavior. Experiments in rats revealed a fast, mutual, positive feedback between the adrenocortical stress response and a brain mechanism controlling aggression. Stimulation of the aggressive area in the hypothalamus rapidly activated the adrenocortical response, even in the absence of an opponent and fighting. Hypothalamic aggression, in turn, was rapidly facilitated by a corticosterone injection in rats in which the natural adrenocortical stress response was prevented by adrenalectomy. The rapidity of both effects points to a fast, mutual, positive feedback of the controlling mechanisms within the time frame of a single conflict. Such a mutual facilitation may contribute to the precipitation and escalation of violent behavior under stressful conditions.

Chronic glucocorticoid deficiency-induced abnormal aggression, autonomic hypoarousal, and social deficit in rats

Certain aggression‐related psychopathologies are associated with decreased glucocorticoid production and autonomic functions in humans. We have previously shown that experimentally‐induced chronic glucocorticoid deficiency leads to abnormal forms of attack in rats. Here, we compared the effects of acute and chronic glucocorticoid deficiency on aggressive behaviour, autonomic responses to challenges, and anxiety. Glucocorticoid synthesis was blocked acutely by the glucocorticoid synthesis blocker metyrapone or chronically by adrenalectomy and low glucocorticoid replacement (ADXr). As shown previously, chronic glucocorticoid deficiency facilitated aberrant attacks directed towards the most vulnerable parts of the opponents body. The acute inhibition of glucocorticoid synthesis lowered aggressive behaviour without affecting attack targeting. In a different experiment, ADXr rats and their sham‐operated controls were exposed to different challenges whereas their heart rate and locomotion were telemetrically recorded. Autonomic responses to social challenges were lowered by chronic, but not by acute glucocorticoid deficiency. Autonomic responses to the elevated plus‐maze were only slightly affected by chronic glucocorticoid deficiency. Locomotor behaviour was not affected in either challenge; thus, the altered autonomic reactions were not due to interference from workload. The behaviour of ADXr rats was similar to that of sham‐operated controls in the elevated plus‐maze, but ADXr rats showed reduced social interactions in the social interaction test. Our data demonstrate that, in rats, chronic but not acute glucocorticoid deficiency induces abnormal attack patterns, deviant cardiovascular responses and social deficits that are similar to those seen in abnormally violent humans. Thus, the similar correlations found in humans probably cover a causal relationship. Experimentally‐induced glucocorticoid deficiency may be used to assess the mechanisms underlying glucocorticoid deficiency‐induced abnormal forms of aggressiveness.

‘One‐trial sensitization’ to the anxiolytic‐like effects of cannabinoid receptor antagonist SR141716A in the mouse elevated plus‐maze

Significant variability in the effects of cannabinoid CB1 receptor ligands on emotional reactivity in animals and humans suggests that the endocannabinoid system may selectively modulate certain types of anxiety. In view of substantial evidence for qualitative differences in the nature of anxiety elicited on initial and subsequent exposures to the elevated plus‐maze, the present studies contrasted the behavioural effects of the selective CB1 receptor antagonist SR141716A (0.1–10.0 mg/kg) and the reference benzodiazepine chlordiazepoxide (CDP, 15 mg/kg) both in maze‐naive mice (trial 1) and in mice that had been given a single undrugged exposure to the maze 24 h prior to testing (trial 2). Results confirmed the anxioselective effect of CDP on trial 1 but a complete absence of such activity on trial 2 (i.e. one trial tolerance). In marked contrast, SR141716A had no behavioural effects in maze‐naive mice but, at doses of 1.0–3.0 mg/kg (effect maximal at 1.0 mg/kg), significantly reduced anxiety‐like responses in maze‐experienced animals. Like the effect of CDP on trial 1, the antianxiety profile of SR141716A on plus‐maze trial 2 was observed in the absence of any change in general activity levels. The apparent experientially induced ‘sensitization’ to the anxiolytic‐like effects of SR141716A in the plus‐maze contrasts markedly with the widely reported loss of benzodiazepine efficacy in test‐experienced animals. Data are discussed in relation to the recently described phenotypes of CB1 receptor knockout mice and, in particular, to mounting evidence for the existence of a novel SR141716A‐sensitive neuronal cannabinoid receptor.

Acute effects of glucocorticoids: behavioral and pharmacological perspectives

There has been evidence since the early eighties that glucocorticoids, apart from their well known chronic effects, may have acute, short-term effects. However, a lack of understanding of the molecular mechanisms of action has hampered appreciation of these observations. Mounting evidence over the years has continued to confirm the early observations on a fast corticosterone control of acute behavioral responses. We summarize experimental data obtained mainly in rats but also in other species which show: (1) that glucocorticoid production is sufficiently quick to affect ongoing behavior; (2) that there exist molecular mechanisms that could conceivably explain the fast neuronal effects of glucocorticoids (although these are still insufficiently understood); (3) that glucocorticoids are able to stimulate a wide variety of behaviors within minutes; and (4) that acute glucocorticoid production (at least in the case of aggressive behavior) is linked to the achievement of the behavioral goal (winning). The achievement of the behavioral goal reduces glucocorticoid production. It is argued that glucocorticoids are regulatory factors having a well-defined behavioral role. Both the acute (stimulatory) effects and the chronic (inhibitory) effects are adaptive in nature. The acute control of behavior by corticosterone is a rather unknown process that deserves further investigation. The pharmacologic importance of the acute glucocorticoid response is that it may readily affect the action of pharmacologic agents. An interaction between acute glucocorticoid increases and noradrenergic treatments has been shown in the case of offensive and defensive agonistic behavior. Non-behavioral data demonstrate that acute increases in glucocorticoids may interfere with other neurotransmitter systems (e.g., with the 5HT system) as well. These observations show the importance of taking into account endocrine background and endocrine responsiveness in behavior pharmacological experiments.

Neural background of glucocorticoid dysfunction‐induced abnormal aggression in rats: involvement of fear‐ and stress‐related structures

Glucocorticoid hypofunction is associated with persistent aggression in some psychologically disordered human subjects and, as reported recently, induces abnormal forms of aggression in rats. Here we report on the effects of glucocorticoid hypofunction on aggression‐induced neural activation. Rats were adrenalectomized, and implanted with low‐release glucocorticoid pellets. After one week recovery, they were challenged by an unfamiliar intruder in their home‐cage. Neural activation was studied by c‐Fos protein immunocytochemistry. Aggressive encounters in controls induced c‐Fos activation in all brain areas relevant for the control of aggression (cortex, amygdala, septum, hypothalamus, periaqueductal grey and the locus coeruleus). Very intense c‐Fos activation was observed in the medial amygdala, the hypothalamic attack area and the periaqueductal grey matter which constitute a downward stimulatory stream that activates attack behaviour. The experimentally induced glucocorticoid hypofunction dramatically increased attacks targeted towards vulnerable parts of the opponents body (mainly the head). This abnormal behaviour was not associated with changes in the activation of brain centres involved in the control of aggression. However, the activation of brain centres involved in both the stress response (the parvocellular part of the hypothalamic paraventricular nucleus) and fear reactions (central amygdala) were markedly increased. An acute glucocorticoid treatment abolished both behavioural and neural consequences of glucocorticoid hypofunction. Our data suggest that glucocorticoid hypofunction‐induced abnormal forms of aggressiveness are related to increased sensitivity to stressors and fear‐eliciting stimuli. This assumption is supported by the finding that fearful situations induce attack patterns in intact rats that are similar to those induced by glucocorticoid hypofunction.

Early social deprivation induces disturbed social communication and violent aggression in adulthood.

Disturbed social relations during childhood (e.g., social neglect) often lead to aggression-related psychopathologies in adulthood. Social isolation also increased aggressiveness in laboratory animals. Here the authors show in rats, that social isolation from weaning not only increases the level of aggressiveness, but results in abnormal attack patterns and deficits in social communication. In socially deprived rats, the share of attacks aimed at vulnerable body parts of opponents (head, throat, and belly) dramatically increased and the attack/threat ratio was shifted toward attacks, suggesting a decrease in intention signaling. Moreover, a Multiple Regression Analysis showed that the nonassociation of attacks with offensive threats predicted the occurrence of vulnerable attacks with 81.1% accuracy. The authors suggest that the social deprivation-induced abnormal aggression models the aggression-related problems resulting from early social neglect in humans, and studies on its brain mechanisms may increase our understanding of the mechanisms underlying psychopathologies resulting from early social problems.

Social stress of variable intensity: physiological and behavioral consequences

Stress effects in humans depend on stress type, intensity, and duration. Animal models of social stress serve as good ways to mimic stress experienced in humans. However, the available stress paradigms pay little attention to the relationship between the intensity and the type of social stressors. The aim of the present work is to study behavioral and endocrinological consequences of social stress by varying the intensity and type of agonistic social contacts. Subjects were exposed to the attacks of an experienced fighter resident rat once a day for 4 consecutive days. Mild versus strong effects were studied by varying the length of daily confrontations (30 min vs. 4 h). The type of social confrontations was varied by ceasing or maintaining sensory contacts among contestants between encounters. Endocrinological variables were measured on the 5th day. Anxiety was assessed by means of the elevated plus-maze. The stress state depended on the length of daily encounters: 30-min encounters did not, whereas 4-h encounters did result in weight loss and chronic elevation of plasma corticosterone. The type of contacts between subjects and dominants also affected the resulting stress state: adrenal hypertrophy was obtained only when contacts between contestants were maintained between encounters. Although the mildest stress procedure (30-min encounters on 4 consecutive days) did not affect endocrinological variables, it resulted in subtle behavioral modifications that changed the anxiety-related effects of additional acute stressors. Thus, anxiety-related behavioral changes resulting from repeated mild stressors may be hidden factors that can have long-term consequences on the development of anxiety-like behavioral deficits. Results outline the necessity of studying the effects of social stressors of different intensities and different types.

The activation of prefrontal cortical neurons in aggression : A double labeling study

Violence is associated with prefrontal deficits in humans, suggesting that this brain area inhibits aggressiveness. Its role, however, remains controversial, as certain subdivisions of the prefrontal cortex become activated by fights in rodents. Disparate human findings also show that this area is acutely activated by aggression under certain conditions. We explored prefrontal neuronal activation patterns in resident rats exposed to psychosocial (sensory contact with the intruder) and aggressive encounters. Both psychosocial and aggressive encounters increased c-Fos activation in the prelimbic (PrL), anterior cingular (Cg1), agranular insular (AI), ventral (VO) and lateral orbital (LO) cortices. The infralimbic (IL) and medial orbital (MO) cortices were activated significantly by aggressive encounters only. No other prefrontal regions were activated by psychosocial or aggressive encounters. The overwhelming majority of activated cells were pyramidal (glutamatergic) cells in the Cg1, IL, PrL, MO, and VO, whereas interneuron and pyramidal cell activation was similar in AI and LO. When rats showed violent aggression, the activation of GABAergic inhibitory cells decreased in these two, and two other areas (IL and MO). Notably, the latter two areas appeared to be specifically involved in aggressive behavior. The change occurred in a recently developed model of violent aggression. In this model, pyramidal cell activation in the above mentioned four areas (IL, MO, AI, and LO) predicted over 95% of variation in attack counts in general and violent attacks in particular. Based on these data, we present a tentative hypothesis on the involvement of the prefrontal cortex in the control of aggression.