de Sietse Boer

Neuroendocrinology of coping styles : towards understanding the biology of individual variation

Individual variation in behavior and physiology is a widespread and ecologically functional phenomenon in nature in virtually all vertebrate species. Due to domestication of laboratory animals, studies may suffer from a strong selection bias. This paper summarizes behavioral, neuroendocrine and neurobiological studies using the natural individual variation in rats and mice. Individual behavioral characteristics appear to be consistent over time and across situations. The individual variation has at least two dimensions in which the quality of the response to a challenging condition (coping style) is independent from the quantity of that response (stress reactivity). The neurobiology reveals important differences in the homeostatic control of the serotonergic neuron and the neuropeptides vasopressin and oxytocin in relation to coping style. It is argued that a careful exploitation of the broad natural and biologically functional individual variation in behavior and physiology may help in developing better animal models for understanding individual disease vulnerability.

Long-lasting deficient dexamethasone suppression of hypothalamic-pituitary-adrenocortical activation following peripheral CRF challenge in socially defeated rats

The present study focuses on the long‐term changes in the regulation of the hypothalamic‐pituitary‐adrenocortical (HPA) axis following two short‐lasting episodes of intensive stress in the rat stress model of social defeat and the possible similarities with HPA functioning in human affective disorders. Male Wistar rats experienced social defeats on 2 consecutive days by an aggressive male conspecific. The long‐term effect of these defeats on resting and ovine corticotropin‐releasing factor (oCRF; intravenous (i.v.) 0.5 μg/kg) induced levels of plasma ACTH and corticosterone (CORT) were measured 1 and 3 weeks later. In a second experiment the glucocorticoid feedback regulation of HPA function was tested in a combined dexamethasone (DEX)/CRF test (DEX; 25 μg/kg s.c., 90 min before oCRF injection, 0.5 μg/kg). The oCRF challenges were performed between 11.00 and 13.00 h (about three hours after start of the light phase). One week after defeat the ACTH response to CRF was significantly enhanced in defeated rats as compared to controls. Three weeks after defeat the ACTH response was back to control levels. The increased ACTH response 1 week after the stressor was not reflected in higher CORT levels. Neither were baseline ACTH and CORT levels affected by the prior stress exposure. DEX pretreatment inhibited pituitary adrenocortical activity, reflected both in reduced baseline and response values of ACTH and CORT. The ACTH response to CRF following DEX administration was significantly higher in defeated rats as compared to controls both at one and three weeks after defeat. A reduced DEX suppression of baseline secretion of ACTH appeared 3 weeks after defeat. The same tendency was apparent in response and baseline values of CORT. The differences in CORT between socially stressed and control treated rats, however, did not reach significance. The possible role of changes in glucocorticoid‐(GR) and mineralocorticoid receptor (MR) binding in the altered regulation of HPA activity following defeat were studied in brain and pituitary of male Wistar rats 1 and 3 weeks after defeat. One week after defeat GR‐binding decreased in hippocampus and hypothalamus. No changes were observed in GR‐binding in the pituitary nor in MR‐binding in any of the regions analysed. Three weeks after defeat GR‐binding recovered in hippocampus and hypothalamus but at this time MR‐binding in hippocampal tissue was seriously decreased. In a fourth experiment vasopressin (AVP) and CRF stores in the external zone of the median eminence (ZEME) were measured by quantitative immunocytochemistry one and three weeks after defeat and compared with controls. Social defeat failed to induce a change in the immunocytochemical stores of AVP or CRF. The present findings show that in rats short‐lasting stressors like defeat induce long‐lasting, temporal dynamic changes in the regulation of the HPA axis. Since these changes in time are reflected in GRs and MRs in different brain areas an altered corticosteroid receptor binding might play an important role in the affected HPA activity following defeat.

Incidence of arrhythmias and heart rate variability in wild-type rats exposed to social stress

Psychological stressors of different natures can induce different shifts of autonomic control on cardiac electrical activity, with either a sympathetic or a parasympathetic prevalence. Arrhythmia occurrence, R-R interval variability, and plasma catecholamine elevations were measured in male wild-type rats exposed to either a social stressor (defeat) or a nonsocial challenge (restraint). Electrocardiograms were telemetrically recorded, and blood samples were withdrawn through jugular vein catheters from normal, freely moving animals. Defeat produced a much higher incidence of arrhythmias (mostly ventricular premature beats), which were mainly observed in the 60-s time periods after attacks. The social challenge also induced a much stronger reduction of average R-R interval, a lower R-R interval variability (as estimated by the time-domain parameters standard deviation of mean R-R interval duration, coefficient of variance, and root mean square of successive differences in R-R interval duration), and higher elevations of venous plasma catecholamines compared with restraint. These autonomic and/or neuroendocrine data indicate that a social stressor such as defeat is characterized by both a higher sympathetic activation and a lower parasympathetic antagonism compared with a nonsocial restraint challenge, which results in a higher risk for ventricular arrhythmias.

Social stress, autonomic neural activation, and cardiac activity in rats

Animal models of social stress represent a useful experimental tool to investigate the relationship between psychological stress, autonomic neural activity and cardiovascular disease. This paper summarizes the results obtained in a series of experiments performed on rats and aimed at verifying whether social challenges produce specific modifications in the autonomic neural control of heart rate and whether these changes can be detrimental for cardiac electrical stability. Short-term electrocardiographic recordings were performed via radiotelemetry and the autonomic input to the heart evaluated by means of time-domain heart rate variability measures. Compared to other stress contexts, a social defeat experience produces a strong shift of autonomic balance toward sympathetic dominance, poorly antagonized by vagal rebound, and associated with the occurrence of cardiac tachyarrhythmias. These effects were particularly severe when a wild-type strain of rats was studied. The data also suggest that the cardiac autonomic responses produced by different types of social contexts (dominant-subordinate interaction, dominant-dominant confrontation, social defeat) are related to different degrees of emotional activation, which in turn are likely modulated by the social rank of the experimental animal and the opponent, the prior experience with the stressor, and the level of controllability over the stimulus.

Behavioral and physiological consequences of repeated daily intracerebroventricular injection of corticotropin-releasing factor in the rat

The present study was conducted to investigate the long-term consequences of repeated daily bolus injections of corticotropin-releasing factor (CRF) intracerebroventricularly (ICV) on ongoing locomotor activity and physiology in the home cage of individually housed rats. For this purpose ovine CRF (1 microgram/3 microliters) was injected once daily during the early resting phase into the lateral ventricle for a period of 10 days. Changes in daily rhythms in heart rate, body temperature and motor activity were recorded telemetrically before and during the treatment period. Daily central CRF injection delayed the body weight gain, increased adrenal weight, and decreased the weight of the thymus at the end of the experiment. The acute behavioral and physiological responses to CRF did not habituate with repetition of treatment. CRF treatment also failed to affect the long-term regulation of baseline heart rate, body temperature and motor activity during the light phase, as measured during the hour preceding the daily CRF injection. Mean heart rate during the dark phase was, however, significantly decreased in CRF-treated rats during the whole experimental 10-day period, without any sign of habituation. The failure of episodic CRF to affect long-term regulation of baseline body temperature during the light as well as the dark phase was noteworthy because an increased daytime body temperature lasting for several days is a characteristic marker of various behavioral stressors. Since a previous study showed that the temperature response during chronic CRF infusion was similar to the long-term effects of behavioral stress it is hypothesized that chronic but not episodic increases in central CRF levels are related to the induction and persistence of part of the stress-related behavioral and physiological disorders.

Social stress in rats : An animal model of depression?

Our current understanding of the physiological mechanisms underlying depressive disorders is not only based on behavioral, neuroendocrine and pharmacological studies in depressed humans, but also on experimental studies in a wide variety of animal models of depression. Ideally, the two approaches should operate in close interaction, each providing additional information to the other approach. However, in practice the animal model approach seems to be rather independent from the human studies. In a critical evaluation of the available animal models of depression, Willner concluded that none of the models fulfilled the criteria of a sufficient face, construct and predictive validity. Although this evaluation was made ten years ago, we feel that the situation has improved very little since that time. Most animal models fail to sufficiently mimic both the etiology and the symptomatology of human depressive disorders. With respect to the etiology, stress and major life events are generally considered to be an important factor in the development of depression. Most of the animal models however use stressors which bear little or no relationship to the biology of the species, i.e. to the situations an animal may meet in its everyday life in a natural habitat. Moreover, these models do not pay attention to the temporal dynamics of the disease. In humans, the disease is characterized by its gradual onset, which is often preceded by symptoms of anxiety. Moreover, a relatively large number of patients suffers from recurrent episodes of depression, which tend to occur with decreasing intervals and increasing duration and severity. If we want to improve our knowledge of the causal mechanisms of depression, animal models which allow an experimental analysis of the temporal dynamics of the disease are essential.