Cortisol secretion and clearance in the rhesus monkey.

Cortisol secretory patterns were studied in two chair-adapted rhesus monkeys by simultaneous measurement of plasma concentration and specific activity of cortisol after an iv bolus of 14C-labeled hormone. The results indicated that fluctuating plasma cortisol concentrations are the result of episodic secretion by the adrenal cortex. Specific activity changes during these spontaneous secretory bursts indicated occasional submaximal activity. In addition, cortisol secretory rates calculated during basal (20.4 mug/min) and ACTH-stimulated (28.4mug/min) conditions in a total of seven monkeys were significantly different (P less than 0.05), further demonstrating that spontaneous secretory bursts were usually sub-maximal. From plasma samples collected at 10 min intervals, a cortisol distribution t1/2 of 6 min and a clearance t1/2 of 66 min were found. The apparent volume of distribution for this hormone was 4.8 liters, a value far in excess of extracellular fluid volume estimates. The circadian pattern of plasma cortisol in these monkeys resembled that reported for man, but monkeys had twice as many episodic bursts and over twice the mean cortisol levels as man. However, the 24 h production rate was 10.5 mg, a value within the range of human production.

Plasma cyclic AMP increases in hamsters following exposure to a graded footshock stressor.

To assess the utility of plasma cyclic AMP (cAMP) as a sensitive physiological index of an animal's arousal level, we exposed male hamsters to various intensities (0.0-2.0 mA) of a footshock stressor. The plasma cAMP response was directly related to stimulus intensity. Ratings of behavioral arousal were positively correlated with plasma cAMP values. We conclude that plasma cAMP may be a useful index of arousal.

Hyperresponsiveness of the rat neuroendocrine system due to repeated exposure to stress.

Sequential exposure to stressors may elicit a period of endocrine hyperresponsiveness during which plasma hormone concentrations reach higher levels after repeated exposure to a stressor compared to levels after initial exposure. The present study was designed to further characterize hyperresponsiveness to repeated stress and determine if hyperresponsiveness is dependent upon repeated exposure to the same stressful stimuli. In Experiment 1, rats were stressed by inescapable tailshock, immobilization or exposure to shock chamber without shock for one, two, three, four or five consecutive days (15 min/day). In rats exposed to tailshock, corticosterone (CS) levels in plasma collected on days 2, 3, 4 and 5 were higher than CS levels following acute tailshock on day 1, demonstrating hyperresponsiveness to repeated tailshock. Hyperresponsiveness of CS secretion also occurred in groups of rats restrained for four or five days. No changes occurred in the CS response of animals repeatedly exposed to immobilization. Prolactin (PRL) levels were not affected by repeated exposure to the stressors. However, PRL values were different between the stress conditions and indicated that the order of stressor severity was tailshock greater than immobilization greater than exposure to shock chamber without shock. In Experiment 2, rats were exposed to either one or two consecutive days of tailshock or immobilization. Other rats were exposed to either tailshock or immobilization on the first day, then switched to the other stressor on the next day. Hyperresponsiveness to repeated tailshock, but not immobilization, was reflected in plasma levels of CS and adrenocorticotropic hormone (ACTH), but not PRL. Hyperresponsiveness of CS and ACTH secretion also was found in rats first stressed by immobilization then switched to tailshock, demonstrating that hyperresponsiveness is not dependent upon reexposure to familiar stressful stimuli. However, hyperresponsiveness did not occur in rats first exposed to tailshock then switched to immobilization. The data suggest that both immobilization and tailshock primed the organism to hyperrespond, but only the more severe stressor (tailshock) elicited hyperresponsiveness of the neuroendocrine system.

Comparison of stress response in male and female rats: pituitary cyclic AMP and plasma prolactin, growth hormone and corticosterone.

Three potent stressors (forced running, immobilization, and footshock) were found to increase levels of cyclic AMP in the pituitaries of both female and male rats. The pituitary cyclic AMP response in females was generally similar to that observed in males. The tested stressors elevated both plasma corticosterone and prolactin and decreased plasma growth hormone. Plasma corticosterone rose more rapidly in females than in males following stress. Control growth hormone levels were higher in male rats. There was no clear cause and effect relationship between elevations of pituitary cyclic AMP and changes in plasma levels of prolactin, corticosterone, and growth hormone.

Brief, high-frequency stimulation of the corticomedial amygdala induces a delayed and prolonged increase of aggressiveness in male Syrian golden hamsters.

Brief 200-Hz stimulation of the corticomedial amygdala (CMA) increases the aggressiveness of male Syrian golden hamsters for about 30 min; the effect peaks 10-15 min after stimulation. This effect is sensitive to stimulation amplitude and frequency. Stimulation at the parameters that reduce attack latency increases flank marking but does not affect copulation latency or general activity. Immunocytochemical analysis suggests that stimulation effects may be coupled to c-fos expression and that unilateral stimulation has bilateral effects. CMA stimulation effects appear to mimic part of the time course of behaviorally induced attack priming. The temporal persistence of aggression may result from long-term potentiation-like changes within CMA-related neural circuitry.

Reduced isolation-induced aggressiveness in mice following NAALADase inhibition.

RATIONALE: Long-term individual housing increases aggressive behavior in mice, a condition termed isolation-induced aggression; this aggressiveness is reduced by some antidepressants and anxiolytics. NMDA antagonists also inhibit isolation-induced aggression in mice. The enzyme N-acetylated-alpha-linked acidic dipeptidase (NAALADase) hydrolyzes the neurotransmitter N-acetylaspartylglutamate (NAAG) to form glutamate and N-acetylaspartate; NAAG acts as a partial NMDA agonist as well as a full agonist at the presynaptic metabotropic glutamate receptor 3 (mGluR3), where it acts to reduce glutamate release. OBJECTIVE: We postulated that NAALADase inhibition would reduce isolation-induced aggression in mice. METHODS: We tested whether acute exposure to the NAALADase inhibitor 2-[[hydroxy[2,3,4,5,6-pentafluorophenyl)methyl]phosphinyl]methyl] pentanedioic acid (GPI-5232), administered 30 min prior to a social interaction test, would inhibit aggressive behavior in SJL mice that had been individually housed long term. RESULTS: Administration of GPI-5232 (30 mg/kg, IP) inhibited initiation of aggressive behavior, indicated by greater latencies to display tail-rattling, attack and biting, and by fewer mice initiating aggressive behavior, compared to mice that received vehicle. In addition, GPI-5232 treated mice had fewer tail-rattling responses to a non-aggressive conspecific. CONCLUSIONS: The effectiveness of GPI-5232 in this animal model suggests that NAALADase inhibition may be a novel therapeutic approach to reduce or inhibit heightened aggressiveness, and possibly to treat aggressive behavior associated with psychiatric disorders.

Accelerated Barnes maze test in mice for assessment of stress effects on memory.

Repeated restraint stress in rodents impairs spatial memory in a Y-maze test and induces hippocampal neuronal changes that last up to 5 d after the stressor ends. Our goal was to implement a Barnes maze spatial memory test in mice that could be used to validate our findings of social stress induced Y-maze impairment. We measured performance of mice in 5- and 9-day test paradigms previously used in rats and mice, respectively. Selecting features from each paradigm, we implemented a 5-d test (pre-training, training (4 trials/d/3 d) and probe testing for assessment of spatial memory in mice. Stress consisted of placing each test mouse in a stainless steel perforated box (25.5 cm x 21.5 cm x 16.5 cm) within an aggressor's home cage for 6 h/d for 21 d; direct agonistic encounters occurred randomly throughout stress periods. Barnes maze pre-training (habituation) was on day 21 of the stress exposures. In a preliminary experiment, mice that habituated following their last stressor performed poorly relative to unstressed and to those not habituated prior to the last stressor, as demonstrated by a greater latency to escape and more errors. We conclude that acute stress in a chronic stress paradigm may impair spatial memory acquisition.

Electroconvulsive shock activates endogenous opioid systems: behavioral and biochemical correlates.

From the evidence reviewed above, there is little doubt that ECS activates endogenous opioids and modifies their receptors. Thus, this form of SIA is accompanied by many other corollaries of opioid-like actions, including catalepsy, similar EEG patterns, common autonomic effects, and increases in opioid receptor binding sites. Investigations have further indicated that the amnestic effects of ECS can also be attenuated by naloxone, and that pituitary-derived opioids may play an important role as a predominant source of opioids that contribute to these opioid-like effects following ECS. It is hoped that these many attempts to correlate SIA with other behavioral and physiological endpoints following ECS will provide a more global perspective on the role of endogenous opioid systems in ECS. From these results, it is suggested that other forms of SIA may also share many of these properties in common with ECS-induced SIA. Nonetheless, ECS and other forms of SIA, such as cold water exposure and restraint, share with ECS a common history of clinical use in the treatment of human depression. It is possible that the common thread linking these experimental observations to endogenous opioid systems may provide new insights into the cause and treatment of mental disorders as well as the perception of pain.

A CRH1 antagonist into the amygdala of mice prevents defeat-induced defensive behavior.

Corticotropin-releasing hormone (CRH) is believed to play an important role in the regulation of behavioral responses to stress. CRH(1) receptor antagonists may reduce stress responsivity. Stress increases CRH in the amygdala, important in memory consolidation. We hypothesized that infusion of a CRH(1) antagonist into the amygdala following social defeat would prevent the development of generalized fear responses. Acute social defeat in mice increases defense towards intruders, even nonaggressive intruders, placed within their home cage. We infused the CRH(1) antagonist antalarmin (0.25 microg/125 nl) bilaterally into the amygdala of mice immediately after defeat and measured their response to a nonaggressive intruder stimulus mouse placed within their home cage 24 h after defeat. Defeated mice that received vehicle displayed high levels of crouch defensive posture and numerous flights from intruders, relative to nondefeated mice that received vehicle. Defeated mice that received antalarmin into the amygdala exhibited significantly less defensive posture than did vehicle-treated defeated mice. Display of defensive posture in antalarmin-treated mice approached that of vehicle-treated nondefeated mice. These findings support a role for CRH in the amygdala to promote consolidation of emotional memory and indicate that antagonism of CRH(1) receptors in the amygdala may prevent the development of exaggerated fear responses in stressed mice.

N-acetyl-aspartyl-glutamate (NAAG) elicits rapid increase in intraneuronal Ca2+ in vitro.

N-acetyl-aspartylglutamate (NAAG) is an acidic dipeptide found at high concentrations almost exclusively in the brain and spinal cord. There is evidence that NAAG is an excitatory neurotransmitter/neuromodulator. On the other hand, the identification and characterization of an enzyme in the nervous system which hydrolyzes NAAG to liberate glutamic acid (Glu) has led to an alternative hypothesis that the dipeptide might serve as a precursor of the excitatory amino acid. Using an interactive laser cytometer to quantitate changes in intraneuronal Ca2+ in individual neurons, we demonstrate that NAAG, at the concentrations at which it is found in the brain, promotes a rapid increase in intraneuronal Ca2+. NAAG-induced effects are completely dependent on the presence of Ca2+ in the bathing medium and are inhibited by NMDA receptor and channel antagonists. Several factors have led us to conclude that it is NAAG itself, and not NAAG-derived Glu, which is responsible for the observed effects in this system.

Treadmill exercise training blunts suppression of splenic natural killer cell cytolysis after footshock.

This study extended to treadmill exercise training our prior report (Dishman RK, Warren JM, Youngstedt SD, Yoo H, Bunnell BN, Mougey EH, Meyerhoff JL, Jaso-Friedmann L, and Evans DL. J Appl Physiol 78: 1547-1554, 1995) that activity wheel running abolished the suppression of footshock-induced natural killer (NK) cell cytolysis. Twenty-four male Fischer 344 rats were assigned to one of three groups (n = 8, all groups): 1) a home-cage control group, 2) a sedentary treatment group, or 3) a treadmill-running group (0 degrees incline, 25 m/min, 35 min/day, 6 days/wk). After 6 wk, the treadmill and sedentary groups received 2 days of footshock. Splenic NK cytotoxicity was determined by standard 4-h (51)Cr release assay. Percentages of lymphocytes were determined by flow cytometry. Plasma levels of ACTH, corticosterone, and prolactin concentration were measured by radioimmunoassay. After footshock, percentage of lysis relative to home-cage controls was 40% and 80% for sedentary and treadmill-trained animals, respectively (P < 0.05). Our results indicate that the protective effect of chronic exercise on innate cellular immunity in the Fischer 344 male rat is not restricted to activity wheel running, nor is it explained by elevations in basal NK activity, increased percentages of splenic NK and cytotoxic T cells, or increased plasma levels of ACTH, corticosterone, and prolactin.

Treadmill exercise training and estradiol increase plasma ACTH and prolactin after novel footshock.

We examined whether rats that were treadmill exercise trained (Tr) or chronically immobilized (CI) had similar responses by the hypothalamic-pituitary-adrenal (HPA) cortical axis to acute stress and whether the HPA responses interacted with the hypothalamic-pituitary-gonadal (HPG) axis. After 6 wk (1 h/day, 6 days/wk) of Tr or CI, plasma concentrations of adrenocorticotropic hormone ([ACTH]), [prolactin], and [corticosterone] were measured after familiar (treadmill running or immobilization) or novel (footshock) stress. Ovariectomized Sprague-Dawley females (n = 72) were implanted with capsules containing estradiol benzoate (E2) and randomly assigned in a 2-group (E2 vs. no E2) x 3 treatment (Tr vs. CI vs. sedentary) x 4 acute stressor [footshock vs. treadmill running (Run) vs. immobilization (Im) vs. no stress] x 3 recovery time (1 vs. 15 vs. 30 min) mixed-model analysis of variance. E2 capsules were removed from one-half of the animals 48 h before the first stressor session. After 10 min of acute stress, blood was drawn from a jugular catheter at 1, 15, and 30 min of recovery. [ACTH] and [prolactin] after footshock were higher in Tr rats with E2 compared with CI and sedentary rats without E2; recovery levels for sedentary animals were higher after Run compared with Im. The elevation in [corticosterone] from minute 1 to 15 of recovery was higher after the familiar Run and Im conditions. Our findings are consistent with an increased responsiveness of the HPA axis to novel footshock after treadmill exercise training that is additionally modulated by the HPG axis.

Activity-wheel running attenuates suppression of natural killer cell activity after footshock.

We studied whether voluntary running in an activity wheel moderates splenic natural killer (NK) cell cytotoxicity after footshock. Young (50-day) male Fischer 344 rats were randomly assigned to 1) sedentary (n = 16) or 2) activity-wheel (n = 16) groups that each received controllable or uncontrollable footshock on 2 consecutive days or 3) a sedentary home-cage control group (n = 8). Spleens and trunk blood were collected 30 min after the second footshock session. Cytotoxicity was determined by a standard 4-h 51Cr release assay. Percentages of OX6+ (B), OX8+ [T suppressor/cytotoxic (Ts/c)], W3/25+ (T helper), Thy-1.1 (Pan T cell marker), and 5C6+ (NK) cells were determined by flow cytometry. Plasma adrenocorticotropic hormone, corticosterone, and prolactin concentrations were measured by radioimmunoassay as modulators of NK activity. Percentage of specific lysis after footshock was approximately 52% of control values for sedentary animals compared with approximately 96% of control values for activity-wheel animals. The groups did not differ in percentages of NK or Ts/c cells. We conclude that voluntary activity-wheel running protects against the suppression of splenic NK activity induced by footshock. This protective effect of wheel running is not explained by an elevation in baseline NK activity; increased percentages of splenic NK or Ts/c cells; or plasma levels of adrenocorticotropic hormone, corticosterone, and prolactin.

Comparison of the effects of CRF and stress on levels of pituitary cyclic AMP and plasma ACTH in vivo.

We have previously reported that acute stress increases levels of rat pituitary cyclic AMP in vivo. The present study was conducted to test the hypothesis that stress-induced increases in pituitary cyclic AMP in vivo were mediated via CRF. We compared the effects of various stressors with the effects of CRF or epinephrine administration on pituitary cyclic AMP and plasma ACTH responses in vivo. Stressors, epinephrine or CRF increased levels of pituitary cyclic AMP. Pituitary cyclic AMP response to either immobilization or CRF was much greater at light onset than at lights off in rats maintained on a 12 hr light:12 hr dark lighting regimen. In rats with pituitary stalk transections, footshock did not increase levels of pituitary cyclic AMP, suggesting that some factor of central origin was required for this stress response. Exogenous CRF administration did increase levels of pituitary cyclic AMP in stalk-transected rats, while epinephrine increased levels in sham-operated but not in stalk-transected rats. Antisera to CRF markedly decreased pituitary cyclic AMP response to exogenous CRF administered 6 min following antisera and partially attenuated pituitary cyclic AMP response to forced running. Taken as a whole these data support a major role for CRF in the pituitary cyclic AMP response to stress.

In vitro neuroprotection against glutamate-induced toxicity by pGlu-Glu-Pro-NH(2) (EEP).

EEP is a tripeptide structurally similar to thyrotropin releasing hormone (TRH) and, like TRH, it is found in the mammalian brain. TRH has been found to increase in brain regions after seizures and to be neuroprotective. EEP has also been shown to increase in brain regions following seizure activity. We therefore sought to determine whether the similarities between these two peptides might be extended to include neuroprotection. Both TRH and EEP were found to be neuroprotective in vitro against an excitotoxic insult. Interestingly, the two tripeptides appeared to have different mechanisms of action. Even though EEP was as much as four times more neuroprotective than TRH, its ability to reduce glutamate-stimulated increases in intraneuronal Ca(2+) was about half that of TRH.

The prolonged increase in thyrotropin-releasing hormone in rat limbic forebrain regions following electroconvulsive shock.

We have previously demonstrated substantial increases in thyrotropin-releasing hormone (TRH) in specific regions of rat forebrain two days after single or repeated alternate-day electroconvulsive shock (ECS). To determine longer term effects of ECS-induced seizures on forebrain TRH content, we extended the time of the post-ECS observations to 6 and 12 days following 1 (ECS x 1) or 3 (ECS x 3) alternate-day ECS. Previous observations at 2 days post-ECS were confirmed except that hippocampal content of TRH was higher after ECS x 1. In pyriform cortex TRH remained elevated for 6 days after ECS x 1 and 3, and for 12 days after ECS x 3. In hippocampus TRH was elevated for 6 days after ECS x 1 and tended to remain elevated beyond 2 days after ECS x 3. In anterior cortex the increase persisted 6 days after ECS x 1 and 12 days after ECS x 3. These data show that convulsive seizures can induce sustained elevations of TRH beyond 48 h. This finding may be especially important in pyriform cortex and hippocampus where TRH may function as an endogenous anti-epileptic. Our data are also consistent with a possible role for TRH in affective regulation in the hippocampus, amygdala, pyriform and other cortical regions. Moreover, the present results further advance the analogy of the time-course of the TRH changes in rat to the course of the antidepressant response to electroconvulsive treatment in humans.

Combined treatment with muscarinic and nicotinic cholinergic antagonists slows development of kindled seizures.

Rats were given daily injections of atropine, mecamylamine or both drugs in combination, 1 h prior to daily electrical amygdaloid kindling stimulation. Neither drug was effective alone, but the two drugs in combination significantly increased the latency to develop stage 5 kindled seizures.

Electroconvulsive seizures modulate levels of thyrotropin releasing hormone and related peptides in rat hypothalamus, cingulate and lateral cerebellum.

We have studied the neuroanatomic extent of electroconvulsive (ECS)-responsive prepro-TRH and TRH-related gene expression and its possible interaction with forced swimming. Young adult male Wistar rats were treated in a 2x2 Latin square protocol of swimming, no swimming, three daily ECS or sham ECS. Sixteen different brain regions were dissected and immunoreactivity measured for TRH (pGlu-His-Pro-NH(2)); TRH-Gly, a TRH precursor; Ps4, a prepro-TRH-derived TRH-enhancing decapeptide, and EEP (pGlu-Glu-Pro-NH(2)). ECS, in addition to elevating TRH-immunoreactivity (TRH-IR), TRH-Gly-IR, Ps4-IR and EEP-IR levels in the limbic regions, as we have previously reported, also significantly increased Ps4-IR levels in hypothalamus, posterior cingulate and lateral cerebellum, and increased TRH-Gly-IR levels in hypothalamus. Interestingly, the combination of ECS and swimming significantly reduced the levels of TRH-Gly-IR in the anterior cingulate compared to the sham ECS-no swim group. The combined use of high-pressure liquid chromatography and the EEP radioimmunoassay (RIA) revealed that pGlu-Tyr-Pro-NH(2) and/or pGlu-Phe-Pro-NH(2) occur in amygdala, anterior cingulate, frontal cortex, entorhinal cortex, lateral cerebellum and striatum and make a substantial contribution to the EEP-IR and TRH-IR. We conclude that ECS can alter the expression and secretion of TRH-related peptides in the hypothalamus, cingulate and lateral cerebellum. Such effects have not previously been reported in these limbic and extra-limbic regions which are increasingly implicated in the autonomic, behavioral and volitional changes which accompany severe depression and its treatment.

Norepinephrine-stimulated phosphatidylinositol metabolism in genetically epilepsy-prone and kindled rats.

Genetically epilepsy-prone rats (GEPR-9) and kindled rats have reduced noradrenergic function. In the present study, norepinephrine-stimulated accumulation of inositol phosphates was reduced in cerebral cortex of GEPR-9 and kindled rats when compared to control and non-kindled rats, respectively. No such reduction was found in amygdala/pyriform cortex and hippocampus. These results support the hypothesis that cortical noradrenergic and associated second messenger systems are impaired in epilepsy.

Thyrotropin-releasing hormone (TRH) attenuates glutamate-stimulated increases in calcium in primary neuronal cultures.

Thyrotropin-releasing hormone (TRH) has been found to be widely distributed in the mammalian central nervous system. Further, the concentration of the tripeptide increases following seizure activity, and TRH is known to have anticonvulsant effects. We have investigated the possibility that the anticonvulsant activity of TRH may be due, at least in part, to an attenuation of the glutamate-stimulated increases in intraneuronal Ca2+ ([Ca]i) that occur with epileptic activity. We find that the tripeptide does not itself excite neurons and that it is able to significantly reduce glutamate-stimulated increases in [Ca]i in cultured neurons derived from fetal rat forebrain. Increases in the concentration of TRH following seizure activity may represent an endogenous homeostatic mechanism for reducing glutamate-induced elevations in intraneuronal Ca2+.