Ruben Stam

The Role of the CRH Type 1 Receptor in Autonomic Responses to Corticotropin- Releasing Hormone in the Rat

The involvement of the corticotropin-releasing hormone (CRH) type 1 receptor in CRH-induced cardiac responses was studied in freely moving rats. Intracerebroventricular (icv) infusion of 2 μg CRH under resting conditions resulted in a significant increase in heart rate (HR), but did not significantly affect the PQ interval of the electrocardiogram. This effect involves sympathetic nervous system (SNS) activation, since CRH-treatment resulted in a marked increase in plasma norepinephrine (NE) and epinephrine (E), and sympathetic blockade by subcutaneously injected atenolol (1 mg/kg), a β1-selective adrenergic antagonist, completely prevented the CRH-induced tachycardia. CRH infusion after sympathetic blockade resulted in an elongation of the PQ interval, indicating CRH-induced vagal activation. Gross locomotor activity (GA) was determined to study its possible indirect effects on cardiac activity. Although CRH induced a marked increase in GA, this effect followed the tachycardiac response, indicating that the HR response was not a consequence of increased locomotor activity, but was a direct effect of icv CRH. Treatment with CP-154,526 (icv, 10 or 25 μg), a selective CRH type 1 receptor antagonist, did not affect baseline HR, plasma NE and E, whereas it partially blocked the CRH-induced increase in HR, plasma NE and E levels. CP-154,526 treatment had no significant effects on baseline or CRH-induced changes in GA. These results indicate that CRH activates the sympathetic nervous system at least in part via the CRH type 1 receptor.

Conditioned fear-induced tachycardia in the rat; vagal involvement

The effects of conditioned fear on gross activity, heart rate, PQ interval, noradrenaline and adrenaline were studied in freely moving rats. Subcutaneous (s.c.) injections of atropine methyl nitrate (0.5 mg/kg) during rest resulted in a significant shortening of the PQ interval, indicating that the PQ interval can be used as a measure of vagal activity. Conditioned fear was induced by 10-min forced exposure to a cage in which the rat had previously experienced footshocks (5 x 0.5 mA x 3 s). In non-shocked controls, an increase in gross activity was found and a pronounced tachycardia, without changes in PQ interval. Conditioned fear rats showed immobility behaviour, associated with a less pronounced tachycardia and an increase in PQ interval. Noradrenaline was similarly increased in both groups, whereas adrenaline was increased in conditioned fear rats only. To further evaluate the role of the vagus, rats were exposed to conditioned fear after pre-treatment with atropine methyl nitrate (0.5 mg/kg, s.c.). Again, immobility was observed with a concomitant tachycardia, but without an increase in PQ interval. These results indicate that the autonomic nervous system is differentially involved in heart rate regulation in conditioned fear rats and in non-shocked controls: in non-shocked controls a predominant sympathetic nervous system activation results in an increase in heart rate, whereas in conditioned fear rats the tachycardiac response is attenuated by a simultaneous activation of sympathetic nervous system and parasympathetic nervous system.

Long-term sensitization of Fos-responsivity in the rat central nervous system after a single stressful experience

There is considerable evidence for a role of stressful experiences in psychosomatic disorders in humans, but the mechanisms leading to altered responsivity and the relative contributions of central and peripheral neuronal changes, however, are still under debate. To investigate the contribution of specific brain areas to sensitized responsivity, rats were exposed to a single brief session of inescapable footshocks (preshocked) or no shocks (control) in a gridcage. Two weeks later, an electrified prod was inserted in the home cage for 15 min and the behaviour recorded. One hour later rats were perfused and brain sections were stained for Fos protein immunoreactivity. The number of Fos positive neurons was quantified in 27 brain areas. No significant difference in behaviour was found between the groups during the shock prod challenge. A significantly higher number of Fos positive neurons was found in preshocked rats compared to controls in the following brain areas: agranular insular cortex, frontal cortex, nucleus accumbens, bed nucleus of the stria terminalis, basolateral amygdala, CA1 area of the hippocampus, paraventricular hypothalamic nucleus, dorsolateral central grey, locus coeruleus, nucleus of the solitary tract and lateral paragigantocellular nucleus. We conclude that altered reactivity to stressful challenges in brain areas involved in neuroendocrine and autonomic control may play a role in long-term sensitization of neuroendocrine and autonomic responses in preshocked rats under conditions where behavioural sensitization is not expressed.

Long-term sensitization of cardiovascular stress responses after a single stressful experience.

There is evidence that the experience of traumatic events may play a role in the pathogenesis of somatic diseases, including cardiovascular disorders. In this study, telemetry was used to investigate the long-term effects of a single stressful experience on cardiovascular and behavioral responses to novel challenges 2 weeks later. Rats were exposed to footshocks and tested for sensitization using the following challenges: novel cylinder (Day 14); shock prod acquisition test (Day 15); and shock prod retention test (Day 16). No difference in basal somatomotor activity (SA), heart rate (HR) and blood pressure between preshocked rats and control rats was found. However, preshocked rats displayed an enhanced blood pressure response compared to controls during the shock prod acquisition test and the shock prod retention test. No differential increase in HR response between both groups was found. During the novel cylinder test, the preshocked rats displayed less SA while no behavioral differences were found in the shock prod acquisition test and the shock prod retention test. We conclude that a single stressful experience induces long-term sensitization of blood pressure responses to novel challenges that are not necessarily linked to sensitized behavioral responses. The footshock model may be a useful model to study autonomic hyperresponsivity found in posttraumatic stress disorder (PTSD).

Behavioural and intestinal responses to novelty in rats selected for diverging reactivity in the open field test.

There are indications that the severity of functional gastrointestinal disturbances in humans is linked to individual coping styles. In rodents, the open field test can be used to assess individual differences in behavioural responsivity to novel challenges. Two groups of Wistar rats were selected for high (HA) and low (LA) locomotor activity in a novel open field and fitted with electrodes on the proximal colon. During subsequent exposure to a novel box, a smaller locomotor activation in LA was accompanied by a greater increase in colonic spike burst activity compared to HA rats, even though this novel stressful challenge did not result in a clear defecation response in either group. In contrast, no marked behavioural differences between HA and LA were seen in the shock prod paradigm. Although detection of divergent behavioural responsivity in HA and LA rats may depend on stimulus quality or intensity, combined use of behavioural selection and intestinal motility recording in freely moving rats may offer a model to study individual vulnerability to stress-related disturbances of intestinal function.

Effects of novelty and conditioned fear on small intestinal and colonic motility and behaviour in the rat

Novelty and conditioned fear were used to investigate the effects of psychological stress on fasting small intestinal and colonic myoelectric activity and their relation with behaviour in freely moving rats fitted with bipolar electrodes on proximal jejunum and colon. Rats in both novelty and conditioned fear groups spent a 15 min session in a novel box, where only rats in the fear group received unescapable, repeated foot shock (10 x 6 s, 0.5 mA). Behaviour in groups reexposed to the box on day 1 or day 7 indicated a profound difference in emotional state. Conditioned fear rats remained largely immobile, while novelty rats displayed active exploratory behaviour. Behaviour during conditioned fear did not differ significantly between rats reexposed to the box either 1 or 7 days after foot shock, while novelty animals appeared more aroused on day 7. Conditioned fear on day 1 caused a significant increase in colonic spike burst frequency compared to basal values in the home cage. A smaller but significant increase was found in novelty rats. In groups tested after 7 days, both novelty and conditioned fear resulted in small increases in colonic burst frequency that did not differ significantly from each other. No effects were found on the incidence of the fasting jejunal Migrating Motility Complex. Defecation was see only in conditioned fear rats, but did not differ quantitatively between day 1 and day 7. We conclude that, in the rat, colonic myoelectric spike burst activity is highly responsive to psychological stress, while the fasting pattern of small intestinal activity is more resistant.(ABSTRACT TRUNCATED AT 250 WORDS)

Sex differences in long-term stress-induced colonic, behavioural and hormonal disturbances

Functional bowel disorders are more prevalent in women than in men, but the reason for this is unclear. Stressful experiences can increase the risk for or precipitate intestinal dysfunction. Using a model for long-term stress-induced sensitisation in rats, it was investigated whether male and female rats differ in susceptibility for long-term colonic, behavioural and hormonal disturbances following brief but intense stress. Male and female Wistar rats were fitted with chronic electrodes on proximal colon and given either a 15-minute session of foot shocks or no shocks. Two weeks later, rats were exposed to two different novel stressful challenges in the home cage: an electrified prod (day 14) and an 85 dB noise stressor (day 15). Digitalised colonic myoelectric spike burst activity was quantified automatically. Behaviour during prod and noise exposure was scored blindly from videotape. Resting plasma hormone concentrations at the end of the study were determined by radio-immuno assay. Following prod stress on day 14, both male and female preshocked rats showed a greater increase in colonic spike burst frequency than controls, but similar behaviour, and the dynamics of colonic motility differed between sexes. Following noise stress on day 15, only a small change in burst frequency was seen in all rats, but preshocked rats showed less self-grooming behaviour and there was a tendency for preshocked females to show increased noise-induced immobility. Preshocked rats also had lower levels of plasma free thyroxine. While both male and female rats show long-term stress-induced colonic sensitisation and hormonal changes, females show a different activation pattern of colonic motility, and may be more vulnerable for altered behavioural reactivity, following stress.

Computer analysis of the Migrating Motility Complex of the small intestine recorded in freely moving rats.

Myoelectric activity of the small intestine was recorded digitally in fasted, freely moving rats fitted with multiple pairs of electrodes in the antimesenterial smooth muscle. The electrodes were implanted under strict aseptic conditions to safeguard the animals health and thereby benefit experimental results. As in many other mammalian species, the fasted electrical and mechanical activity of the small intestine in the rat consists of alternating periods of activity and quiescence jointly called the Migrating Motility Complex (MMC). Existing methods for the analysis of small bowel myoelectric activity either integrate spike activity over longer periods of time or describe characteristics of single bursts. We have developed a computer program for fast, automated analysis that distinguishes the three characteristic phases of the MMC. The computer program recognizes periods of varying spike burst frequency and then produces a graphical and numerical output of the length and mean burst frequency of the different phases of each MMC that correlates well with the results of visual evaluation. The techniques used are discussed in relation to existing recording and analysis methods, and specific decisions in the program are motivated. The system will be a useful tool in assessing the effects of drugs, peptides, or stress on small bowel motility.

Psychoneurogastroenterology: Interrelations in Stress-Induced Colonic Motility and Behavior

Individual differences in behavioral and physiological response patterns to stress may contribute to vulnerability for stress-related illnesses such as functional gastrointestinal disorders. Animal models could give clues about specific individual determinants of intestinal reactivity to stress and stress-induced sensitization. Rats fitted with permanent electrodes on the proximal colon were exposed to a single session of foot shocks (10 x 6 s in 15 min, preshocked) or no shocks (control). Two weeks later, the preshocked group showed a significantly greater colonic spike burst response to a novel shock-prod stressor in the home cage than controls. The increase in burst frequency was positively correlated with the duration of active burying of the threatening prod in both experimental groups, but not with other behavioral components. Basal colonic burst frequency at rest was negatively correlated with the increase in burst frequency due to shock-prod stress in both groups, but the degree of sensitization in preshocked rats vs. controls was of similar magnitude in rats with low and high basal colonic burst frequency. The results indicate that colonic responsivity to stress is related to both basal motility status and individual coping strategies.

In vitro contractile responses to acetylcholine in jejunal and colonic tissue from stressed rats

In order to investigate the mechanism for stress-induced sensitization of colonic motility responses in vivo, rats were exposed to a 15-minute session of repeated foot shocks, and contractile responses of proximal jejunal and colonic strips to non-cumulative doses of acetylcholine measured in vitro 14 days or 28 days later. No differences in dose-response relationships were found between intestinal strips from foot shocked rats and controls. Responses to the highest dose (10−4 M) of acetylcholine in the absence and presence of tetrodotoxin did not differ for any of the three experimental groups. Changes in cholinergic sensitivity in the gut are unlikely to underlie the increased colonic motility response to stress previously reported after a single foot shock experience.