Vascular alterations in rats with high blood pressure induced by social deprivation stress

Blood pressure regulation in stress: focus on nitric oxide-dependent mechanisms

Stress is considered a risk factor associated with the development of various civilization diseases including cardiovascular diseases, malignant tumors and mental disorders. Research investigating mechanisms involved in stress-induced hypertension have attracted much attention of physicians and researchers, however, there are still ambiguous results concerning a causal relationship between stress and long-term elevation of blood pressure (BP). Several studies have observed that mechanisms involved in the development of stress-induced hypertension include increased activity of sympathetic nervous system (SNS), glucocorticoid (GC) overload and altered endothelial function including decreased nitric oxide (NO) bioavailability. Nitric oxide is well known neurotransmitter, neuromodulator and vasodilator involved in regulation of neuroendocrine mechanisms and cardiovascular responses to stressors. Thus NO plays a crucial role in the regulation of the stress systems and thereby in the BP regulation in stress. Elevated NO synthesis, especially in the initial phase of stress, may be considered a stress-limiting mechanism, facilitating the recovery from stress to the resting levels via attenuation of both GC release and SNS activity as well as by increased NO-dependent vasorelaxation. On the other hand, reduced levels of NO were observed in the later phases of stress and in subjects with genetic predisposition to hypertension, irrespectively, in which reduced NO bioavailability may account for disruption of NO-mediated BP regulatory mechanisms and accentuated SNS and GC effects. This review summarizes current knowledge on the role of stress in development of hypertension with a special focus on the interactions among NO and other biological systems affecting blood pressure and vascular function.

Adolescent vulnerability to cardiovascular consequences of chronic social stress: Immediate and long-term effects of social isolation during adolescence

It has been demonstrated that disruption of social bonds and perceived isolation (loneliness) are associated with an increased risk of cardiovascular morbidity and mortality. Adolescence is proposed as a period of vulnerability to stress. Nevertheless, the impact of chronic social stress during this ontogenic period in cardiovascular function is poorly understood. Therefore, the purpose of this study was to compare the impact in cardiovascular function of social isolation for 3 weeks in adolescent and adult male rats. Also, the long-term effects of social isolation during adolescence were investigated longitudinally. Social isolation reduced body weight in adolescent, but not in adult animals. Disruption of social bonds during adolescence increased arterial pressure without affecting heart rate and pulse pressure (PP). Nevertheless, social isolation in adulthood reduced systolic arterial pressure and increased diastolic arterial pressure, which in turn decreased PP without affecting mean arterial pressure. Cardiovascular changes in adolescents, but not adults, were followed by facilitation of both baroreflex sensitivity and vascular reactivity to the vasodilator agent acetylcholine. Vascular responsiveness to either the vasodilator agent sodium nitroprusside or the vasoconstrictor agent phenylephrine was not affected by social isolation. Except for the changes in body weight and baroreflex sensitivity, all alterations evoked by social isolation during adolescence were reversed in adulthood after moving animals from isolated to collective housing. These findings suggest a vulnerability of adolescents to the effects of chronic social isolation in cardiovascular function. However, results indicate minimal cardiovascular consequences in adulthood of disruption of social bonds during adolescence.

Acute episodes of predator exposure in conjunction with chronic social instability as an animal model of post-traumatic stress disorder

People who are exposed to horrific, life-threatening experiences are at risk for developing post-traumatic stress disorder (PTSD). Some of the symptoms of PTSD include persistent anxiety, exaggerated startle, cognitive impairments and increased sensitivity to yohimbine, an alpha(2)-adrenergic receptor antagonist. We have taken into account the conditions known to induce PTSD, as well as factors responsible for long-term maintenance of the disorder, to develop an animal model of PTSD. Adult male Sprague-Dawley rats were administered a total of 31 days of psychosocial stress, composed of acute and chronic components. The acute component was a 1-h stress session (immobilization during cat exposure), which occurred on Days 1 and 11. The chronic component was that on all 31 days the rats were given unstable housing conditions. We found that psychosocially stressed rats had reduced growth rate, reduced thymus weight, increased adrenal gland weight, increased anxiety, an exaggerated startle response, cognitive impairments, greater cardiovascular and corticosterone reactivity to an acute stressor and heightened responsivity to yohimbine. This work demonstrates the effectiveness of acute inescapable episodes of predator exposure administered in conjunction with daily social instability as an animal model of PTSD.

Stress susceptibility as a determinant of the response to adrenergic stimuli in mesenteric resistance arteries of the rat

Characterized by the behavioral response to apomorphine, two outbred lines of Wistar rats can be recognized with constitutionally determined high (apomorphine susceptible, APO-SUS) or low (apomorphine unsusceptible, APO-UNSUS) adrenal responses to similar environmental stress. Within the accumbens nucleus, the APO-SUS and APO-UNSUS rats differ in alpha -adrenergic receptor responsiveness. This study explored whether these differences in adrenergic receptor sensitivity also exist in mesenteric resistance arteries. A Mulvany myograph was used to study the vasomotor responses of isolated mesenteric resistance arteries to adrenergic receptor stimulation. Phenylephrine (alpha1-agonist)-induced vasoconstriction did not differ between the two lines (pEC : 5.8 +/- 0.05 microM versus 5.8 +/- 0.04 microM and Emax: 36 +/- 2 kPa versus 33 +/- 1 kPa for APO-SUS, n = 9, and APO-UNSUS, n = 11, respectively, p > 0.1). After precontraction with phenylephrine, salbutamol (beta -agonist)-induced relaxation was less in APO-SUS rats (pEC50 4.9 +/- 0.06 versus 5.3 +/- 0.06M for APO-SUS, n = 9, and APO-UNSUS, n = 7, respectively, p < 0.001). Likewise, clonidine (alpha2-agonist)-induced relaxation was reduced in APO-SUS rats (pEC50: 6.7 +/- 0.07 versus 7.0 +/- 0.04, for APO-SUS, n = 9, and APO-UNSUS, n = 8, respectively; p < 0.01). In conclusion, constitutionally determined high susceptibility to stress is accompanied by an impaired vasorelaxation to adrenergic stimuli whereas vasoconstriction is unaffected. An unopposed vasoconstrictor action of norepinephrine may place the APO-SUS rats at increased risk for the development of hypertension, insulin resistance, and atherosclerosis.

Stressful animal housing conditions and their potential effect on sympathetic neurotransmission in mice

Although the sympathetic nervous system (SNS) plays a major role in mediating the peripheral stress response, due consideration is not usually given to the effects of prolonged stress on the SNS. The present study examined changes in neurotransmission in the SNS after exposure of mice (BALB/c) to stressful housing conditions. Focal extracellular recording of excitatory junction currents (EJCs) was used as a relative measure of neurotransmitter release from different regions of large surface areas of the mouse vas deferens. Mice were either group housed (control), isolation housed (social deprivation), group housed in a room containing rats (rat odor stress), or isolation housed in a room containing rats (concurrent stress). Social deprivation and concurrent stressors induced an increase of 30 and 335% in EJC amplitude, respectively. The success rate of recording EJCs from sets of varicosities in the concurrent stressor group was greater compared with all other groups. The present study has shown that some common animal housing conditions act as stressors and induce significant changes in sympathetic neurotransmission.

Effects of restraint stress on responsiveness of atria and vas deferens in Sprague-Dawley rats

1 The effects of stress in rats were evaluated by measuring changes in body weight and in responsiveness to noradrenaline (NA) in the isolated vas deferens and atria after the animals had been exposed to restraint or restraint and isolation. 2 Animals which were subjected to restraint alone (1 h day-1 for 3, 7 or 28 days) had a significantly reduced rate of body weight gain. This effect was not potentiated by the additional stress of isolation. 3 Restraint alone did not produce significant changes in the responsiveness of the vas deferens to NA. However, adding isolation to restraint, as an additional stress, produced a further leftward shift of the NA dose-response curve for the vas deferens, so that there was a significant increase in sensitivity compared with control. 4 There was a significant rightward shift in the NA dose-response curves or reduction in sensitivity in the atria from animals which had been restrained for 7 or 28 days. Isolation did not produce a further rightward shift in the NA dose-response curve. 5 The results from this study indicate that the stress associated with repeated restraint reduces the rate of weight gain and reduces the responsiveness of the atria to NA. The responsiveness of the vas deferens to NA was increased by stress, but the combined effect of isolation and restraint was required to produce a significant effect. The differences in the effects of stress on these tissues could be associated with differences in presynaptic receptor populations.

Vascular and hemodynamic effects of behavioral stress in borderline hypertensive and Wistar-Kyoto rats

In borderline hypertensive rats (BHR), behavioral stress produces hypertension, which has been attributed to increases in sympathetic nervous system activity and peripheral changes in vascular structure. However, the mechanisms mediating development of stress-induced hypertension have not been well defined. Experiments were designed to determine hemodynamic effects and changes in small mesenteric artery (approximately 300 microns) vascular reactivity in response to 10 days of air-jet stress (2 h/day) in BHR and in Wistar-Kyoto (WKY) rats. The acute stress-induced increase in mean arterial pressure (AP) was impaired in WKY rats compared with BHR on day 1, and habituation developed to the increase in AP in BHR, but not WKY rats. Conversely, WKY rats adapted to the stress-induced tachycardia to a larger extent than BHR. The mechanisms mediating endothelium-dependent relaxation to acetylcholine (ACh) were altered in small mesenteric arteries isolated from WKY rats and BHR after 10 days of air-jet stress. Inhibition of nitric oxide synthase activity had a significantly larger inhibitory effect on ACh-induced relaxation in vessels from stressed compared with control BHR. Also, cyclooxygenase products contributed to ACh-induced relaxation of small mesenteric arteries from stressed WKY rats, but not control WKY rats. Endothelium-independent relaxation to nitroprusside was impaired in vessels from stressed WKY rats, but not stressed BHR. Finally, contraction to phenylephrine was impaired in vessels from stressed BHR, but not WKY rats. In conclusion, changes in vascular reactivity induced by air-jet stress appear to correlate with, and may contribute to, the differential hemodynamic adaptations to stress observed in WKY rats and BHR.

Social deprivation stress induces adaptative changes of opioid mechanisms in the rat tail artery

Brief (7-14 days) social deprivation stress has been found to increase blood pressure in Wistar rats, an effect dependent on activation of opioid function. The role of central opioids in this and other responses to stress has been repeatedly determined, but the possible involvement of modifications of peripheral opioid mechanisms is poorly understood. To further increase this knowledge, we have examined the opioid sensitivity of tail arteries taken from social deprived Wistar rats by studying the effect of beta-endorphin and DADLE "in vitro". Both opioids inhibited the electrically-induced constriction of the preparations in a dose-dependent manner, but these actions were significantly attenuated after 7-14 days of social deprivation. When the rats were isolated for 30-35 days, the hypertensive response was still present but the arteries from group-housed and isolated animals no longer showed differential sensitivity to opioids. This difference with respect to 7-14 days of isolation could be related to age-dependent changes of opioid function, which were observed among group-housed animals. The results suggest that social deprivation stress induces an adaptation of the tail arteries to the opioid effects on contractility. It is suggested that this endogenous adaptation could be contributing to the hypertensive response observed after social deprivation.