Adrenal hormonal indices of stress in laboratory rats

Pituitary-adrenal axis responses to acute amphetamine in the rat

After acute administration of amphetamine (AMPH), a characteristic behavioral response occurs in the rat, involving increased locomotion and stereotyped licking, grooming, and biting. AMPH administration also activates several neuroendocrine systems, including the pituitary-adrenal axis. Because recent evidence has supported a role for glucocorticoids in modulating the behavioral response to AMPH, the purpose of the present study was to examine the relationship between behavioral and hypothalamic-pituitary-adrenal (HPA) responses to AMPH and determine the physiological substrates responsible for the AMPH-induced release of adrenal steroids. AMPH administration produced the often-reported "inverted-U" shaped behavioral response. Specifically, locomotion was increased by low doses (0.5-1.0 mg/kg, SC) significantly more so than by the highest dose (5.0 mg/kg, SC), which instead elicited intense focused stereotyped movements. Plasma levels of adrenocorticotropic hormone (ACTH) and corticosterone were increased by AMPH in a monotonic dose-response function, with highest levels measured in rats exhibiting the most intense stereotyped behaviors. Plasma ACTH levels then declined 10-30 min after AMPH administration, while AMPH-induced locomotion and stereotyped behavior persisted well beyond this period. In a parallel study, AMPH failed to elevate plasma levels of vasopressin, an important ACTH secretagogue, and AMPH reduced levels of corticotropin-releasing factor (CRF) immunoreactivity in the median eminence, providing indirect evidence of CRF release from this region. AMPH-stimulated ACTH and corticosterone release were prevented by immunoneutralization of CRF.(ABSTRACT TRUNCATED AT 250 WORDS)

Stress and dexfenfluramine: effects on the immune response and energy balance in the rat

The effects of stress, dexfenfluramine (d-Fen), and a combination of both were investigated on ingestive behavior, body weight, and the humoral immune response in the rat. Three-hundred and 84 male Sprague-Dawley rats were split into four groups of 96 animals. In a balanced design, each group was submitted or not to repeated intense stress for 20 consecutive days. Animals were also treated with 5 mg/kg/day d-Fen (IP, 1 ml/kg) or an equal volume of placebo (saline) for 28 days. The humoral immune response of rats to sheep red blood cells (50% solution, 1 ml IP at day 0) was assessed from the antibody titer on days 4, 8, 12, 16, 20, and 28. Antibodies were assayed by direct hemagglutination and by the Coombs' test. Plasma corticosterone was also measured on days 0 and 12. The effects of stress and d-Fen on ingestive behavior and body weight were consistent with previously published results. In addition, rats treated with d-Fen had a significantly reduced body weight (-20 g) 5 weeks after the end of the treatment, whereas the loss in body weight induced by stress had totally disappeared. Stress did not decrease animals' immune response despite a massive corticosterone secretion on day 0, with a marked response lasting for at least 12 days. d-Fen reduced the corticosterone levels determined on day 12. Antibody production was slightly but significantly reduced in rats receiving d-Fen.(ABSTRACT TRUNCATED AT 250 WORDS)

Stress-induced hypertension in the borderline hypertensive rat: stimulus duration

Blood pressure and circulating catecholamines were evaluated in borderline hypertensive rats (BHR) that were exposed to daily sessions of either short (20 min) or long (120 min) duration air-jet stimulation. Indirect measures of systolic blood pressure indicated that within 2 weeks both experimental groups developed stress-induced hypertension in comparison to home cage controls. Animals exposed to 120 min stress sessions had significantly higher systolic blood pressure relative to the 20 min group. However, direct measures of blood pressure taken after 5 weeks of daily stress did not reveal any differences between the stress groups. Daily measurements indicated that acute changes in blood pressure during stress were modest and transient, suggesting little contribution to the chronic elevation in blood pressure observed as a consequence of stress. Circulating catecholamines were significantly increased by the stressor. Epinephrine returned to baseline within 60 min, although norepinephrine remained elevated throughout the 120 min session. The results indicate that increasing the duration of daily air jet stimulation did not impact the development of stress-induced hypertension over the 5-week measurement period.

Effects of acute treadmill exercise and delayed access to food on food selection in rats

Total energy intake and macronutrient self-selection were examined in rats following forced exercise (2 h treadmill, 15 m/min) or after a similar period of food deprivation without exercise. Acute exercise was realized at the end of the daytime. Return to the home cage for food access after exercise or after the same period of fasting was delayed for 0, 30, and 90 min. It has been shown that rats decreased body weight after all exercise situations. Food intake after deprivation was decreased in the first 3 h but was not modified over 24 h. The 24-h energy intake after exercise was identically reduced in the three situations. Carbohydrate and protein intakes were significantly reduced just after exercise. Protein decrease persisted all through the night and, to a lesser extent, during the following nycthemere. Fat decrease appeared later and was significant in the last part of the night. Increasing the delay to food access after exercise did not modify the total energy intake, but it significantly reduced carbohydrate intake. Those results show that exercise has a longer influence on food intake and, specifically, on macronutrient selection, than just food deprivation. Various hypotheses regarding central (cerebral neurotransmitters) and peripheral factors could be evoked in order to explain these modifications in the self-selected diet after an acute exercise.

Selective activation of mesoamygdaloid dopamine neurons by conditioned stress: attenuation by diazepam

Populations of dopamine (DA) neurons in the rat brain are selectively activated by stress, and the response is attenuated by the administration of anxiolytics. Given the role of the component nuclei of the amygdaloid complex in conditioned associations, stress responses and the anxiolytic effects of benzodiazepines, we hypothesized that particular mesoamygdaloid DA projections might be especially sensitive to the effects of conditioned stress and to diazepam (DZ). We mapped the effect of a conditioned stressor on the concentration of the DA metabolite homovanillic acid (HVA) in distinct amygdaloid nuclei and other brain nuclei and areas and the effect of DZ (1 or 3 mg/kg) on the conditioned response in drug-experienced subjects. The conditioned stress paradigm resulted in significant elevations in classical indices of stress, including serum corticosterone and plasma epinephrine. Conditioned stress-induced increases in the estimated activity of DA neurons were specific for DA neurons projecting to the central, basolateral and lateral amygdaloid nuclei, and for DA projections to the dorsal septal nucleus. Conditioned stress-induced increases in the HVA concentration of responsive amygdaloid nuclei were antagonized by low, anxiolytic doses of DZ. These results indicate a role for a subset of mesoamygdaloid DA projections in transducing the impact of perceived stressors on the output of the amygdaloid complex. A role for particular amygdaloid DA projections in the formation of conditioned fear or anticipatory anxiety and its modulation by anxiolytics is also suggested.

Plasma corticosterone response of rats with sociopsychological stress in the communication box

The purpose of present study was to investigate the physiological characteristics of sociopsychological stress induced by the communication box method. In this method, the nonfoot shocked rats were used as the psychologically stressed experimental group. In acute stress experiments, nonfoot shocked rats were exposed to emotional responses from foot shocked rats for 6 h in the light (0900-1500) or in the dark phase (2100-0300). In the light phase, the induced increase in plasma corticosterone levels of nonfoot shocked and foot shocked rats returned to corresponding control levels 6 h following the initiation of stress session, whereas those in the dark phase were significantly higher. Although there were some differences in corticosterone responses between both phases, the acute effect of sociopsychological stress was unclear. Chronic stress experiment with daily exposure for 1 h to sociopsychological stress caused the plasma corticosterone levels of nonfoot shocked rats to increase significantly not only in the postexposure level (just after stress exposure) but also in the preexposure level (before stress exposure) when naive rats were used daily as foot shocked animals. These results suggest that the repeated exposure of sociopsychological stress can induce physiological changes, and stressful situation can be established with only emotional responses from foot shocked rats.

A chronic stress state in rats: effects of repeated stress on basal corticosterone and behavior

The chronic stress state has previously been defined as persistent visceral arousal coupled with behavioral abnormalities. To determine the number of stressor exposures necessary to induce a chronic stress state, male rats were given 2 hours of inescapable shock on 10, 7, 4, or 3 consecutive days. The 3-day stress group had the most pervasive changes in the variables measured: persistently elevated basal plasma corticosterone (CORT), continued weight loss in the post-stressor period, and abnormal behavior. More exposures to the stress regimen did not produce higher CORT levels or greater behavioral changes. Acutely stressed rats, exposed to 1 day of inescapable shock, had persistent CORT elevations without the other changes seen in the 3-day stress group. The data suggest that 3 days of our stress regimen are sufficient to produce a state of chronic stress and that some signs of this state begin to appear as early as the first exposure to our inescapable stress regimen.

Classical aversive conditioning of catecholamine and corticosterone responses

Some earlier work, not rigorously controlled, suggested that conditional increases in sympathoadrenal stress hormones could occur. The purpose of this experiment was to test this idea further using an appropriately controlled design. To do this, we subjected rats living in a tether-type apparatus to differential fear conditioning. Chronic catheterization allowed us to sample blood before and after conditional stimulus probes without having to touch the rats. No evidence for conditional changes in norepinephrine and corticosterone was found. In contrast, differential conditioning of epinephrine responses was found. The conditional response, however, was not a simple one in that conditional increases in epinephrine following CS+ probes were not always seen. These data support the idea that learned changes in hormonal stress respondents can occur. But they leave open the question of why clear cut conditional changes in these visceral systems are so difficult to obtain.

Effects of adinazolam on plasma catecholamine, heart rate and blood pressure responses in stressed and non-stressed rats

Adinazolam (ADI) is a new benzodiazepine with anxiolytic and antidepressant properties. To assess its effects on the acute stress response, rats were given a single intraperitoneal injection of 2.5 or 5.0 mg/kg of ADI and stressed for 1 hr by restraint. Neither dose of ADI had any effect on heart rate, blood pressure or norepinephrine (NE) and epinephrine (EP) in plasma in the resting rats. In the stressed animal, 2.5 and 5.0 mg/kg of ADI did not affect stress-induced increases in heart rate or blood pressure but both significantly reduced the stress-induced increases in plasma NE and EP. During certain stressful experiences in patients with abnormally-increased sympathetic drive, ADI may be therapeutically useful in reducing high levels of catecholamines.

Plasma catecholamine responses to acute motion stress in laboratory rats

Plasma levels of norepinephrine (NE) and epinephrine (EPI) were measured in adult male Fischer 344 (F-344) laboratory rats exposed to acute motion stress. Two days prior to testing, rats were prepared with chronic tail artery catheters to permit remote sampling of blood from conscious, freely behaving animals. Animals remained in their home cages during the entire testing protocol. After collection of basal blood samples, cages were rotated at 45 revolutions per minute for a 10-minute period each hour for 5 consecutive hours. Additional blood samples were collected immediately after each of the 10-minute rotation stress sessions. Plasma levels of NE remained unchanged from baseline immediately following each of the rotation stress sessions. In contrast, plasma EPI increased significantly above baseline levels following each of the 5 rotation stress sessions. These data indicate that rotation stress provides a selective activation of epinephrine-containing adrenal chromaffin cells as reflected in an increase in plasma EPI but not NE. This stress model could prove valuable in examining the physiological and behavioral consequences of adrenal EPI release in freely behaving animals without the confounding effects of increases in circulating norepinephrine.

Situation specific effects of stressor controllability on plasma corticosterone changes in mice

The immediate and proactive effects of controllable and uncontrollable stressors on plasma corticosterone were assessed in CD-1 mice. A progressive increase of plasma corticosterone concentrations was associated with graded increases in stressor severity. When a footshock stressor was employed, however, the magnitude of the glucocorticoid response, as well as the decay of plasma corticosterone concentrations, was independent of stressor controllability. This was the case regardless of the number of escapable vs. yoked inescapable shock trials mice received, the spacing of shock trials (i.e., applied within a single session or spaced over days), or the degree to which the escape response had been established. In contrast, in a swim task stressor controllability influenced plasma corticosterone concentrations provided that the escape response required of the animal was a highly prepared one (i.e., swim to an illuminated region). When mice were required to emit a contraprepared response (swim to dark) corticosterone concentrations did not differ between escapable and inescapable swim. It is suggested that glucocorticoid secretion is a fundamental response to stressors, and the differential effects of controllable and uncontrollable stressors will be most apparent when the response required of the animal is a highly prepared one.

Coping with social conflict, and short-term changes of plasma cortisol titers in familiar and unfamiliar environments

Each of 27 male guinea pigs was confronted with a strange opponent a) in its familiar home cage (CHC) and b) in the unfamiliar cage of the opponent (CSC) and was c) exposed to an unfamiliar open-field area without a conspecific present (OFA). The behavior displayed during confrontations was recorded in detail and plasma-cortisol-titers (PCT) were measured immediately before and after each test. The main findings were: 1) PCT increased significantly in response to the tests carried out in unfamiliar environments (OFA and CSC) compared with the response to the home-cage confrontation. 2) In both confrontation tests "offensive" males could be distinguished from "defensive" males according to marked differences in their agonistic behavior. Offensive males approached and threatened their opponents. Defensive males retreated and did not perform elements of threat behavior. 3) Offensive males showed significantly lower increases in PCT than defensive males in the home-cage confrontations. Increases in PCT did not differ significantly between the two categories of male in the strange-cage confrontations. The results show a) that different intensities of adrenocortical responses depend on the behavioral coping pattern and b) that this behavioral effect can be masked by environmental factors.

Plasma catecholamine, corticosterone and glucose responses to repeated stress in rats: effect of interstressor interval length

Plasma noradrenaline (NA), adrenaline (A), corticosterone (CS) and glucose concentrations were determined in blood frequently sampled via a cardiac catheter from freely behaving rats exposed to five successive trials of water-immersion stress (WIS) with an interval between successive trials (interstressor interval; ISI) of either 24 hr or 72 hr. The first, acute exposure to WIS was accompanied by increased levels of plasma NA, A, CS and glucose which were substantially higher than those associated with handling or placement into a new cage. The magnitudes of the WIS-induced plasma NA, A, CS and glucose responses gradually declined across trials. However, five WIS exposures at a 24-hr ISI resulted in a faster and greater decrement of the plasma A, CS and glucose responses than five exposures at a 72-hr ISI. The data indicate that frequency of stressor presentation (i.e., length of interstressor interval) affects the adaptation pattern of neuroendocrine and metabolic responses to chronic intermittent stress. This finding supports the hypothesis that neuroendocrine adaptation to stress is (at least partly) similar to the process of behavioral or neurophysiological habituation to a sensory stimulus.

Habituation and sensitization of plasma catecholamine responses to chronic intermittent stress: effects of stressor intensity

Adult male Sprague-Dawley rats were exposed acutely (1 time for 30 minutes) or chronically (30 minutes per day for 27 days) to swim stress in water maintained at either 18 degrees C, 24 degrees C or 34 degrees C. Each rat was prepared with an indwelling tail artery catheter to allow for direct measures of mean arterial pressure (MAP, mmHg) and heart rate (HR, beats per minute) and for remote collection of blood samples before, during and after the 1st or 27th swim stress session. Blood samples were later analyzed for plasma levels of norepinephrine and epinephrine to serve as an assessment of sympathetic-adrenal medullary activity. Compared to handled controls, body weight gain was reduced significantly in rats exposed chronically to swim stress at any of the 3 temperatures. However, baseline values of MAP and HR and plasma levels of norepinephrine and epinephrine were similar in chronically stressed rats compared to their handled controls. The plasma norepinephrine response of rats exposed chronically to either 18 degrees C or 24 degrees C swim stress was significantly greater than that of matched controls stressed for the first time. In contrast, the plasma epinephrine response of chronically stressed rats from these two groups was slightly but not significantly reduced compared to matched controls. For swim stress at 34 degrees C, the plasma norepinephrine and epinephrine responses of chronically stressed rats were reduced significantly compared to controls stressed for the first time. These findings demonstrate that stressor intensity affects sensitization and habituation of plasma catecholamine responses in laboratory rats exposed to chronic intermittent stress.(ABSTRACT TRUNCATED AT 250 WORDS)

Dynamics of plasma catecholamine and corticosterone concentrations during reinforced and extinguished operant behavior in rats

Plasma noradrenaline (NA), adrenaline (A) and corticosterone (CS) concentrations were determined simultaneously in permanently heart-cannulated rats before and during the performance of reinforced and nonreinforced (extinguished) operant behavior. Shortly before the experimental food-reinforced (VI 15-sec schedule) lever-pressing task, anticipatory elevations of plasma NA and CS contents were observed. During reinforced lever responding plasma NA increased, A did not change and CS declined. Extinction was associated with a transient increase in A, decreasing NA and elevated CS concentrations. In addition, a relationship was found between individual lever-pressing rate, neurosympathetic and adrenomedullary reactivity and the degree of schedule-induced polydipsia. The results indicate that presence and absence of expected behavioral consequences (controllability and loss of control, respectively) are attended by selective, but highly dissociated patterns of neurosympathetic, adrenomedullary and adrenocortical output. Collectively, the findings reinforce the concept that distinctive emotional and/or motivational states are associated with different patterns of neuroendocrine responses. The reactivity of the sympathoadrenomedullary component is heavily dependent upon a rat's individual behavioral strategy.

Predictability of chronic intermittent stress: effects on sympathetic-adrenal medullary responses of laboratory rats

This experiment involved an examination of sympathetic-adrenal medullary responses of laboratory rats following exposure to chronic intermittent stress. Animals were assigned at random to one of three groups: (i) controls, handled briefly each day; (ii) restraint stress (RS), restrained for 30 min per day; or (iii) variable stress (VS), exposure to restraint, cold swim, or intermittent footshock during one of five time periods each day. On the 26th day, rats were prepared with chronic tail artery catheters for remote sampling of blood and direct measurement of mean arterial pressure and heart rate. On Day 28, rats of each group were exposed to 30 min of restraint stress and timed blood samples were collected and later analyzed for content of norepinephrine (NE) and epinephrine (EPI). VS rats gained significantly less body weight compared to control and RS rats. Basal measures of blood pressure and heart rate and of plasma NE and EPI were comparable for rats of the three groups. The plasma catecholamine responses to restraint stress on Day 28 were significantly reduced in RS and VS rats compared to first-time stressed controls. These findings suggest that predictability of the type of stressor and the time of its occurrence does not influence the pattern of diminished sympathetic-adrenal medullary responses of animals exposed to chronic intermittent stress.

The serum glucose response to acute stress is sensitive to the intensity of the stressor and to habituation

The reliability of serum glucose concentrations as an index of habituation to chronic stress was evaluated in adult male rats. The glucose response to immobilization was attenuated by six days of previous chronic exposure to the same stressor, the degree of reduction being related to the duration (15 min, 1 hr or 4 hr) of the daily exposure to immobilization. In another experiment, three groups of rats were exposed to one of three stressors (handling plus change of room, restraint in tubes, or immobilization by wood boards), 1 hr daily for 27 days. On day 28, when faced with the same acute stressor to which they were chronically exposed, the rats showed a consistent reduction in glucose response, regardless of the type of stressor used. In addition, in stress-naive rats serum glucose levels were related to the intensity of the stressor as assessed by three independent measures (food intake, body weight changes, and adrenal weight after chronic exposure to the stressor). These data indicate that, under appropriate conditions, glucose levels can be a good index of both the intensity of acute stress experienced by the rats and their habituation to repeated stress.

Sensitization of sympathetic-adrenal medullary responses to a novel stressor in chronically stressed laboratory rats

Studies from this and other laboratories have demonstrated that sympathetic-adrenal medullary responses are reduced in laboratory rats exposed to chronic intermittent stress. To extend these findings, we have conducted three experiments in which laboratory rats were exposed daily for 26 consecutive days to the same (homotypic) stressor and then challenged with a novel (heterotypic) stressor. Each stress session lasted for 30 minutes and the following homotypic/heterotypic treatments were included: Experiment 1--restraint/footshock; Experiment 2--cold swim/restraint; and Experiment 3--footshock/cold swim. Controls were exposed to the heterotypic stressor only. Plasma levels of norepinephrine (NE) and epinephrine (EPI) were measured in blood samples taken from control and chronically stressed rats to provide an assessment of sympathetic-adrenal medullary activity. In each experiment, chronically stressed rats gained significantly less weight than handled controls. Basal plasma levels of NE and EPI were similar for chronically stressed and control rats. In contrast, plasma catecholamine responses to the heterotypic stressor were significantly greater in stressed rats compared to controls that were stressed for the first time. This pattern of exaggerated responses was especially evident for the cold swim/restraint and footshock/cold swim groups. These findings provide evidence for a sensitization of sympathetic-adrenal medullary responses to a novel stressor in animals previously exposed to chronic intermittent stress.

Alprazolam but not diazepam protects hamsters with heart disease from the medical consequences of stress

We have previously shown that subjecting cardiomyopathic hamsters in the lesion-developing period of their heart disease to cold-immobilization stress had lethal consequences which could be blocked by alprazolam treatment. This experiment replicated that finding and also examined the efficacy of diazepam in this paradigm. In contrast to alprazolam, diazepam did not prevent the cardiomyopathic subjects from succumbing to the stressor. Thus, the effect of alprazolam in reducing stress-induced mortality did not reflect a generic benzodiazepine action.

Plasma catecholamine and corticosterone responses to predictable and unpredictable noise stress in rats

Plasma noradrenaline (NA), adrenaline (A) and corticosterone (CS) increases were determined in individual rats subjected to either 20 regularly or irregularly scheduled white-noise stimulations (4 min, 100 dBA). Blood was frequently sampled during the first and twentieth noise exposure, and during a reexposure after 24 hr. During the sampling periods, behavioral activities of the rats were recorded. The initial noise-induced CS release was partially reduced following the regular noise presentations. The increase after irregular presentations remained high. The difference in adrenocortical responsiveness between regular and irregular exposure persisted for 24 hr. The NA response to noise was partially attenuated following irregular administration of noise. However, regular exposure produced increased NA levels prior to noise presentation and a subsequent decrease during stimulation. After 24 hr, noise evoked an exaggerated initial NA release in the regular group. The noise-elicited rise in A was completely abolished after 20 noise presentations irrespective of whether these were applied regularly or irregularly. Reexposure after 24 hr evoked again a significant A response in both groups. No differences were observed in the habituation pattern of behavioral reactions among the regular and irregular groups. The results show that the sympathetic neural, adrenomedullary and adrenocortical systems differ in degree and speed of adaptation to intermittent stressful stimuli and in sensitivity to the predictability of stressors.

Habituation of sympathetic-adrenal medullary responses following exposure to chronic intermittent stress

Two experiments examined sympathetic-adrenal medullary responses of laboratory rats after exposure to a brief period of stressful stimulation daily for 26 consecutive days. In the first experiment, rats were exposed to restraint stress for 30 minutes per day and in the second experiment, rats were exposed to inescapable footshock for 10 minutes per day. For each experiment, handled controls were stressed acutely to provide a basis for comparison with chronically stressed animals. In both experiments, chronically stressed rats gained less weight than controls. Basal plasma levels of norepinephrine (NE) and epinephrine (EPI) were similar in control and chronically stressed rats. However, there was a substantial attenuation of the plasma catecholamine response to the 27th episode of restraint or footshock compared to acutely stressed controls. These findings indicate that sympathetic-adrenal medullary responses are dampened considerably in animals exposed to a highly predictable regimen of chronic intermittent stress.

Effect of maternal presence on the fear response to an unfamiliar environment as measured by heart rate in rats as a function of age

Rats 16 to 60 days of age were placed in an unfamiliar environment either alone or in the presence of an anesthetized lactating dam. Rats of all ages show a dramatic increase in fear, as measured by heart rate (HR), when placed alone in an unfamiliar environment. Adult rats, however, show a rapid decline in heart rate during the course of a 90-min session, whereas 16-day-old rats show no significant decrease in HR during the same period. These results suggest that the adult rats become less fearful of the test environment over time, but that the 16-day-olds maintain a high level of fear throughout the 90-min test period. Twenty-three- and 30-day-old rats show an adultlike pattern of adaptation to the unfamiliar environment, i.e., their heart rates return partially but not completely to baseline levels within the 90-min session. When an anesthetized lactating dam is present in the test environment, a strikingly different pattern of results is obtained. Heart rate in the 16-day-old rat is immediately reduced to near baseline levels whereas in the young adult (60-day-old) rat the presence of the anesthetized dam has no effect on either initial HR or rate of adaptation. Again the 23- and 30-day-old rats showed an intermediate pattern of adaptation. In two follow-up experiments the effects of adding (Expt. 2) or removing (Expt. 3) an anesthetized dam on the 16-day-old rats' response to an unfamiliar environment was examined. Both experiments showed that animals were more fearful when the dam was absent from the environment than when it was present.

Changes in plasma corticosterone and catecholamine contents induced by low doses of deltamethrin in rats

The effects of low doses of (S)-alpha-cyano-3-phenoxybenzyl (1R)-cis-3-(2,2-dibromovinyl)-2,2-dimethylcyclopropanecarboxylate (Roussel UCLAF, Paris, France), (deltamethrin) upon sympathetic-adrenomedullary and pituitary-adrenocortical activity were investigated in rats by measuring plasma noradrenaline (NA), adrenaline (A) and corticosterone (CS) concentrations. Blood was sampled from freely-moving animals provided with heart catheters at short intervals up to 60 min after intravenous administration of deltamethrin (0.05, 0.15 and 0.45 mg/kg) or vehicle. Behavioral activity was recorded shortly after the sampling times. Time course and magnitude of the biochemical changes were compared with the effects of exposure to uncontrollable white noise in a similar sampling and recording procedure. Dose-dependent increases were observed for NA and A as well as for CS contents. The dose-response relations however, were different among the neuro-edocrine respondents. Discrete step-wise increases were observed for plasma CS only, indicating greater sensitivity for neurotoxical actions. Already at a dose of 0.15 mg/kg of deltamethrin, CS contents rose to values that were considerably higher than those found during noise exposure. In contrast, plasma CA concentrations increased to noise stress values only after the 0.45 mg/kg dose. The behavioral activity pattern appeared to resemble both CA patterns. The results suggest that rather low doses of deltamethrin elicit vigorous autonomic and neuro-endocrine responses that indicate high levels of stress, presumably caused by the neurotoxic effect of the insecticide.

Analgesia in defeated mice: evidence for mediation via central rather than pituitary or adrenal endogenous opioid peptides

Mice subjected to defeat in a social conflict paradigm display an analgesic response that is apparently mediated by endogenous opioids. It is blocked by naloxone and shows full cross-tolerance to and from morphine. The present study investigated the contribution of sources of endogenous opioids outside of the central nervous system, namely the pituitary and adrenal glands. Treatment known to enhance (metyrapone pretreatment), reduce (2% saline in the drinking water) or block (dexamethasone pretreatment) the release of beta-endorphin from the anterior pituitary did not affect the display of analgesia in defeated mice. Similarly, treatments known to enhance (reserpine pretreatment) or block release of enkephalins (removal of the adrenals or hexamethonium pretreatment) from the adrenal medulla also failed to influence defeat-induced analgesia in the expected manner. If anything, adrenalectomy enhanced and reserpine pretreatment suppressed the analgesic response to defeat. The data are discussed in terms of providing evidence that defeat-induced analgesia is mediated primarily by endogenous opioids released and acting within the central nervous system.

Structural changes in nuclear chromatin in rat pituitary after chronic stress of low intensity

Acute, intense sources of "psychogenic" stress clearly modify the structure and function of the hypophysis, and there are concomitant changes in many peripheral physiological systems. Less dramatic sources of stress yield more equivocal results. An experiment is reported in which nuclear morphology of adenohypophyseal cells from 49 male rats exposed to a chronic, low-intensity stressor was examined both by conventional histological and computer-assisted-image-processing methods. The hypothesis tested was that an unequivocal pattern of morphological changes in the nucleus and nuclear chromatin would be revealed by image processing. Rats were killed after living for a year in a relatively low-stress environment, "crowded" in groups of five animals per cage. The control condition was a minimal stress environment of two rats per cage. Results suggested few signs of pathology from peripheral measures of hypophyseal activity, and direct light microscopic examination of the gland revealed no differences between the two groups. Analysis of computer-enhanced images of the pars distalis nuclei from the adenohypophysis, on the other hand, generated findings that were statistically and biologically significant. Nuclear size increased in the stress condition, the number of chromatin and area occupied by the particles increased, and the position of chromatin shifted toward the periphery of the nucleus. Perhaps more important, optical density analysis indicated that chromatin was less tightly packed in the experimental animals. Implications are that chronic, low-intensity stress modulates nuclear structural changes from a dormant to an active state that portend changes in the peripheral systems influenced by the hypophysis.

An assessment of prolactin's value as an index of stress

On an every other day basis, chronically catheterized male rats were subjected to a 30 sec grid shock in either an ascending (0.0, 0.25, 1.0, 4.0 mA) or descending order. A third group was repeatedly subjected to 1.0 mA shock over the same time frame. In 85% of the shock trials, plasma prolactin increased from baseline levels, thus indicating that prolactin is a relatively reliable index of stress. However prolactin did not change in a step-wise fashion with stressor intensity for a significant number of rats. Data from the group given repeated exposure to the 1 mA stressor showed no evidence of habituation--a process which might have explained the findings. This study indicates that prolactin levels do not sensitively track stressor intensity for individual rats.

Adaptation of plasma catecholamine and corticosterone responses to short-term repeated noise stress in rats

Plasma noradrenaline (NA), adrenaline (A) and corticosterone (CS) concentrations were determined in blood frequently sampled via a cardiac catheter from freely moving rats exposed to three successive trials of white-noise stimulation (10 min, 100 dBA) with an intertrial interval of 30 min. During the sampling period, behavioral activities of the rats were recorded. It was demonstrated that the first exposure to noise induced a specific temporal pattern of neuroendocrine changes: Plasma A and NA contents increased rapidly and peaked early after stimulus onset but their peak-latencies were different (1 and 5 min, respectively). Noise offset was followed by quick return to basal levels. The changes in plasma CS concentrations were considerably slower in onset and slower in decline. The second and third exposure to this type of stressor resulted in attenuated hormonal responses and a reduced decrement of the NA/A-ratio, concurrent with a gradually less intense behavioral reaction. This differential pattern of plasma NA, A and CS responses following repetitive exposure to identical stressors, referred to as adaptation, is discussed with regard to the biochemical changes at various levels of the neuroendocrine systems involved.

Chronic stress and sympathetic-adrenal medullary responsiveness

Acute exposure of animals to stressful stimulation is attended by a significant activation of the sympathetic-adrenal medullary system. If animals are exposed to the same stressful stimulus each day for several weeks, a number of adaptive changes occur in the sympathetic-adrenal medullary system, including increased synthesis and storage of catecholamines, increased basal levels of circulating catecholamines, and decreased release of catecholamines into the circulation following exposure to the identical (homotypic) stressful stimulus. If chronically stressed animals are exposed to a novel (heterotypic) stressful stimulus, there is an exaggerated response of the sympathetic-adrenal medullary system compared to animals exposed to the same stressful stimulus for the first time. Other neuroendocrine systems share some characteristics with the sympathetic-adrenal medullary system in its pattern of adaptation to chronic stress. Several variables appear to influence this pattern of neuroendocrine adaptation to stressful stimulation, including predictability of the stressor, the intensity and duration of the stressor, the interval between each episode of stress, and the number of presentations of the stressor. The pattern of neuroendocrine adaptation to chronic intermittent stressful stimulation resembles in some respects the processes of habituation and sensitization.

Urinary excretion of free glucocorticosteroids and testosterone in the Mongolian gerbil (Meriones unguiculatus): effects of long-acting corticotrophin and human gonadotrophin

1. Methods for the quantitative collection of 24-hr urines of small laboratory animals and for the measurement of urinary free glucocorticosteroids and testosterone are described. 2. Urinary glucocorticosteroids and testosterone were determined in 0.1-0.5 ml-aliquots of 1/100 diluted urines after kieselgur mini-column extraction. 3. Excretion of glucocorticosteroids and testosterone in undisturbed Mongolian gerbils was 329 and 13 ng/day, respectively. 4. Administration of long-acting (1-24)ACTH (20 IU/animal) increased glucocorticosteroid and testosterone excretion to about 2000 ng/day (glucocorticosteroids) and to about 30 ng/day (testosterone) over 3 days. 5. In animals injected with 100 IU/animal HCG, testosterone excretion was elevated to about 35-50 ng/day over 3 days. 6. As the results show, the measurement of urinary excretion of free glucocorticosteroids and testosterone is a reliable index of adrenal-gonadal function in the Mongolian gerbil. 7. Furthermore, in small laboratory animals, steroid measurements in 24-hr urines may be superior to determinations in plasma, since amounts of urinary steroid are relatively high and 24-hr urines can be collected over longer time periods without stressing the animals.

Differential plasma catecholamine and neuropeptide Y responses to acute stress in rats

Neuropeptide Y (NPY) is a vasoconstrictor present in the sympatho-adrenomedullary system and may be co-released with norepinephrine (NE) and epinephrine (EPI) during sympathetic activation. We studied plasma NPY-immunoreactivity (-ir, radioimmunoassay) and catecholamine (radioenzymatic) responses during two acute stress paradigms that differ in character, intensity, and duration. The intermittent stress of footshock (0.75 and 1.5 mA, 0.5 sec duration, at 5-sec intervals, for 5 min) evoked intensity-dependent immediate increments in plasma NE and EPI, and a delayed NPY-ir response (+0.6 +/- 0.1 pmol/ml). Prolonged (60 min) immobilization caused greater increases in plasma NE and EPI levels and no changes in plasma NPY-ir until the end of the stress session (+0.3 +/- 0.1 pmol/ml). Plasma NPY-ir responses correlated with those of NE but not with EPI suggesting a sympathetic origin for the release of the peptide. Relatively greater NPY-ir responses to footshock than to immobilization may be consistent with a preferential release of the peptide by a bursting but not continuous mode of sympathetic activation. However, it may also be due to a differential activation of the sympathetic nerves and adrenal medulla by these two stress situations.