Age-related alterations in the cardiovascular response to adrenergic mediated stress

Cardiovascular adaptation to stress is highly dependent on adrenergic stimulation. It may be hypothesized that the diminished cardiovascular response to acute stress that occurs in advanced age may result in part from an age-related decrease in the effectiveness of adrenergic stimulation. Studies employing beta-adrenergic agonists and antagonists in both man and animals provide support for this hypothesis. In addition, a postsynaptic decrement in sympathetic responsiveness is indicated from in vitro studies in both cardiac and vascular tissue. However, while a strong case for diminished adrenergic responsiveness of the aged cardiovascular system can be made from these data, further information at both the tissue and the organismal level is required to fully elucidate the nature of this age-related decline.     

Adrenergic response patterns in vas deferens isolated from rats under diurnal rhythms. Influence of stress

The aim of this study was to verify, by means of functional methods, whether the circadian rhythm changes adrenergic response patterns in the epididymal half of the vas deferens isolated from control rats as well as from rats submitted to acute stress. The experiments were performed at 9:00 a.m., 3:00 p.m., 9:00 p.m., and 3:00 a.m. The results showed a light-dark dependent variation of the adrenergic response pattern on organs isolated from control as well as from stressed rats. In the control group, only the phenylephrine sensitivity was changed throughout the circadian rhythm. Under the stress condition, both norepinephrine and phenylephrine response patterns were changed, mainly during darkness. The maximal contractile response to both alpha- and beta-agonist and alpha1-agonist was increased in the dark phase, corresponding to high plasmatic concentrations of endogenous melatonin. The vas deferens isolated from stressed rats during the light phase simultaneously incubated with exogenous melatonin showed the same pattern of response obtained in the dark phase, thus indicating a peripheric action of melatonin on this organ. Therefore, the circadian rhythms are important to the adrenergic response pattern in rat vas deferens from both control and stressed rats. In conclusion, we suggest a melatonin modulation on alpha1-postsynaptic adrenergic response in the rat vas deferens.     

Glial proteome changes in response to moderate hypothermia

Reactive glia plays a central role in neuroinflammation associated with secondary damage after brain injury. In order to understand the global effects of therapeutic hypothermia on glial activation and neuroinflammation, we performed proteomic profiling of glial cultures following inflammatory stimulation and hypothermic exposure. Primary mixed glial cultures prepared from mouse brains were stimulated with lipopolysaccharide and interferon-γ under normothermic (37°C) or moderate hypothermic (29°C) conditions, and their proteome profiles were compared by LC-ESI-MS/MS. Differentially expressed proteins were determined by high-throughput label-free quantification. Under hypothermic conditions, 64 and 16 proteins were upregulated (≥1.5-fold) and downregulated (≤ 0.7-fold), respectively, compared to normothermic conditions. More importantly, hypothermia altered the abundance of 143 proteins that were either increased or decreased by inflammatory stimulation. The results were validated for several proteins (ICAM-1, STAT-1, YWHAB, and IFIT-3) by Western blot analysis. Pathway and network analysis indicate that hypothermia influences various biological functions of glia such as molecular transport, cell movement, immune response, cell death, and stress response. In conclusion, moderate hypothermia seems to have a significant effect on the protein expression profiles of brain glia and possibly ensuing neuroinflammation. These proteins may be involved in the protective mechanism of hypothermia against brain injuries.     

Adrenocorticotropic hormone and corticosterone responses to acute hypoxia in the neonatal rat: effects of body temperature maintenance

The corticosterone response to acute hypoxia in neonatal rats develops in the 1st wk of life, with a shift from ACTH independence to ACTH dependence. Acute hypoxia also leads to hypothermia, which may be protective. There is little information about the endocrine effects of body temperature maintenance during periods of neonatal hypoxia. We hypothesized that prevention of hypothermia during neonatal hypoxia would augment the adrenocortical stress response. Rat pups separated from their dams were studied at postnatal days 2 and 8 (PD2 and PD8). In one group of pups, body temperature was allowed to spontaneously decrease during a 30-min prehypoxia period. Pups were then exposed to 8% O(2) for 3 h and allowed to become spontaneously hypothermic or externally warmed (via servo-controlled heat) to maintain isothermia. In another group, external warming was used to maintain isothermia during the prehypoxia period, and then hypoxia with or without isothermia was applied. Plasma ACTH and corticosterone and mRNA expression of genes for upstream proteins involved in the steroidogenic pathway were measured. Maintenance of isothermia during the prehypoxia period increased baseline plasma ACTH at both ages. Hypothermic hypoxia caused an increase in plasma corticosterone; this response was augmented by isothermia at PD2, when the response was ACTH-independent, and at PD8, when the response was ACTH-dependent. In PD8 rats, isothermia also augmented the plasma ACTH response to hypoxia. We conclude that maintenance of isothermia augments the adrenocortical response to acute hypoxia in the neonate. Prevention of hypothermia may increase the stress response during neonatal hypoxia, becoming more pronounced with increased age.     

Distribution of biogenic amines in rat brain with hypothermia

Distribution of catecholamines and serotonin in the thalamus and hypothalamus of the brain was studied as affected by hypothermia. Both single and double hypothermia are found to induce considerable shifts in distribution of these amines. In the both regions of the brain the content of serotonin increases greatly, that of dopamine and adrenaline rises to a less extent. The amount of norepinephrine as compared to the control in unchanged.     

The QseC Adrenergic Signaling Cascade in Enterohemorrhagic E. coli (EHEC)

The ability to respond to stress is at the core of an organism''s survival. The hormones epinephrine and norepinephrine play a central role in stress responses in mammals, which require the synchronized interaction of the whole neuroendocrine system. Mammalian adrenergic receptors are G-coupled protein receptors (GPCRs); bacteria, however, sense these hormones through histidine sensor kinases (HKs). HKs autophosphorylate in response to signals and transfer this phosphate to response regulators (RRs). Two bacterial adrenergic receptors have been identified in EHEC, QseC and QseE, with QseE being downstream of QseC in this signaling cascade. Here we mapped the QseC signaling cascade in the deadly pathogen enterohemorrhagic E. coli (EHEC), which exploits this signaling system to promote disease. Through QseC, EHEC activates expression of metabolic, virulence and stress response genes, synchronizing the cell response to these stress hormones. Coordination of these responses is achieved by QseC phosphorylating three of the thirty-two EHEC RRs. The QseB RR, which is QseC''s cognate RR, activates the flagella regulon which controls bacteria motility and chemotaxis. The QseF RR, which is also phosphorylated by the QseE adrenergic sensor, coordinates expression of virulence genes involved in formation of lesions in the intestinal epithelia by EHEC, and the bacterial SOS stress response. The third RR, KdpE, controls potassium uptake, osmolarity, and also the formation of lesions in the intestine. Adrenergic regulation of bacterial gene expression shares several parallels with mammalian adrenergic signaling having profound effects in the whole organism. Understanding adrenergic regulation of a bacterial cell is a powerful approach for studying the underlying mechanisms of stress and cellular survival.     

Catecholamine concentration in adrenergic plexuses of the spleen and intestine during cold-induced and emotional stress

Computer analysis and histochemical techniques were used to investigate catecholamine concentration in the adrenergic plexuses of the spleen and small intestine in rats. The concentration was found to increase during both emotional and short-term cold-induced stress. Injection of 10 mg/kg guanethidine i.p. does not counteract cold-induced accumulation of catecholamines in the adrenergic plexuses of the spleen and small intestine. During emotional stress, by contrast, an accumulation of this sort does take place. The mechanisms potentially underlying catecholamine accumulation in the adrenergic plexus of these organisms associated with different types of stress are discussed. Cold-induced stress is thought to produce catecholamine synthesis in the adrenergic nerve endings of the prevertebral ganglia, whereas emotional stress leads to catecholamine uptake by adrenergic terminals from the blood.Institute of Physiology, Academy of Sciences of the Byelorussian SSR, Minsk. Translated from Neirofiziologiya, Vol. 22, No. 3, pp. 347–354, May–June, 1990.     

Interaction between clozapine and a lipophilic alpha 1-adrenergic agonist

Acute intraperitoneal injection of clozapine produced marked hypothermia and ataxia in Swiss-Webster mice. These two effects were almost completely blocked by the lipophilic alpha 1-adrenergic agonist, St 587, but not by the peripherally-acting alpha 1 agonist methoxamine. It was inferred that these effects of clozapine are central in origin and probably resulted from alpha 1 adrenergic blockade. However, since prazosin, a selective alpha 1-adrenergic antagonist did not elicit either hypothermia or ataxia in mice it became clear that the alpha 1 adrenergic blocking effect of clozapine is not entirely responsible for these effects, but has a major contributory role in their production. Both clozapine and prazosin inhibited the d-amphetamine-induced locomotor stimulation in mice. St 587 did not significantly reduce this amphetamine-blocking effect of clozapine. It was inferred that this response to d-amphetamine involving the release of mesolimbic dopamine is distinct from the other two St 587-sensitive responses. The hypothermic and ataxic effects of clozapine developed complete tolerance after just four days of treatment, but ten days of such treatment was required for the development of tolerance to the amphetamine-blocking effect of clozapine. The possible relationships between St 587-sensitive and insensitive effects of clozapine and its antipsychotic property are discussed.     

Effects of hypothermia on neuronal-vascular function after cerebral ischemia in piglets

We determined whether cerebral arteriolar dilation to N-methyl-d-aspartate (NMDA), a response dependent on stimulation of cortical neurons and inhibited by anoxic stress, would be preserved by hypothermia during and following ischemia. Pial arteriolar diameters in anesthetized piglets were determined via intravital microscopy. Arteriolar responses to NMDA (10, 50, and 100 micromol/l) were measured before and 1 h after 10 min of global ischemia. Piglets were exposed to either total body or selective brain cooling (33-34 degrees C). Arteriolar dilation to lower doses or to 100 micromol/l NMDA was not affected by hypothermia alone (51 +/- 3 vs. 46 +/- 7%, normothermia vs. hypothermia; n = 7) in nonischemic animals. However, arteriolar responses to 100 micromol/l NMDA were clearly attenuated after ischemia despite body cooling during ischemia (53 +/- 3 vs. 32 +/- 6%; n = 8), hypothermia during ischemia and early reperfusion (49 +/- 10 vs. 20 +/- 3%; n = 8), or selective brain cooling (48 +/- 5 vs. 20 +/- 5%; n = 10). In contrast, pretreatment with indomethacin resulted in complete preservation of NMDA-induced vasodilation after ischemia. Thus, hypothermia fails to protect against neuronal dysfunction during ischemia.     

Olfactory bulbectomy modifies photic entrainment and circadian rhythms of body temperature and locomotor activity in a nocturnal primate

Studies on rodents have emphasized that removal of the olfactory bulbs modulates circadian rhythmicity. Using telemetric recordings of both body temperature (Tb) and locomotor activity (LA) in a male nocturnal primate, the gray mouse lemur, the authors investigated the effects of olfactory bulbectomy on (1) the circadian periods of Tb and LA in constant dim light condition, and (2) photic re-entrainment rates of circadian rhythms following 6-h phase shifts of entrained light-dark cycle (LD 12:12). Under free-running condition, bulbectomized males had significantly shorter circadian periods of Tb and LA rhythms than those of control males. However, the profiles of Tb rhythms, characterized by a phase of hypothermia at the beginning of the subjective day, and Tb parameters were not modified by olfactory bulbectomy. Under a light-dark cycle, olfactory bulbectomy significantly modified the expression of daily hypothermia, especially by an increase in the latency to reach minimal daily Tb, suggesting a delayed response to induction of daily hypothermia by light onset. Reentrainment rates following both a 6-h phase advance and a 6-h phase delay of entrained LD were also delayed in bulbectomized males. Olfactory bulbectomy led to significant fragmentation of locomotor activity and increased locomotor activity levels during the resting period. The shortening of circadian periods in bulbectomized males could partly explain the delayed responses to photic stimuli since in control males, the longer the circadian period, the better the response to light entrainment. This experiment shows for the 1st time that olfactory bulbs can markedly modify the circadian system in a primate.     

Involvement of histamine H1 and H2 receptors in hypothermia induced by ionizing radiation in guinea pigs

Radiation-induced hypothermia was examined in guinea pigs. Exposure to the head alone or whole-body irradiation induced hypothermia, whereas exposure of the body alone produced a small insignificant response. Systemic injection of disodium cromoglycate (a mast cell stabilizer) and cimetidine (H2-receptor antagonist) had no effect on radiation-induced hypothermia, whereas systemic and central administration of mepyramine (H1-receptor antagonist) or central administration of disodium cromoglycate or cimetidine attenuated it, indicating the involvement of central histamine through both H1 and H2 receptors in this response. Serotonin is not involved, since the serotonin antagonist methysergide had no effect on radiation-induced hypothermia. These results indicate that central histaminergic systems may be involved in radiation-induced hypothermia.     

Metabolic level and the function of the peripheral catecholaminergic systems in immobilization hypothermia in rats

Metabolic peculiarities were studied on the model of prolonged immobilization hypothermia in rats (body temperature +20 degrees C for 24 h). Stress reactions and the state of peripheral catecholaminergic systems were compared in hypo- and normothermia. A direct correlation was established between the intensity of metabolism and the mediator activity in adrenergic nerve structures.     

The influence of deep hypothermia on inflammatory status,tissue hypoxia and endocrine function of adipose tissue during cardiac surgery

Changes in endocrine function of adipose tissue during surgery, such as excessive production of proinflammatory cytokines, can significantly alter metabolic response to surgery and worsen its outcomes and prognosis of patients. Therapeutic hypothermia has been used to prevent damage connected with perioperative ischemia and hypoperfusion. The aim of our study was to explore the influence of deep hypothermia on systemic and local inflammation, adipose tissue hypoxia and adipocytokine production. We compared serum concentrations of proinflammatory markers (CRP, IL-6, IL-8, sIL-2R, sTNFRI, PCT) and mRNA expression of selected genes involved in inflammatory reactions (IL-6, TNF-α, MCP-1, MIF) and adaptation to hypoxia and oxidative stress (HIF1-α, MT3, GLUT1, IRS1, GPX1, BCL-2) in subcutaneous and visceral adipose tissue and in isolated adipocytes of patients undergoing cardiosurgical operation with hypothermic period. Deep hypothermia significantly delayed the onset of surgery-related systemic inflammatory response. The relative gene expression of the studied genes was not altered during the hypothermic period, but was significantly changed in six out of ten studied genes (IL-6, MCP-1, TNF-α, HIF1-α, GLUT1, GPX1) at the end of surgery. Our results show that deep hypothermia suppresses the development of systemic inflammatory response, delays the onset of local adipose tissue inflammation and thus may protect against excessive expression of proinflammatory and hypoxia-related factors in patients undergoing elective cardiac surgery procedure.     

Characterization of alpha-adrenoceptors involved in central thermoregulation in rabbits

Intracerebroventricular (icv) injection of methyldopa induced body temperature changes in the rabbits. The dose of 100 micrograms/kg did not produce any significant change on body temperature whereas 250 micrograms/kg of the drug induced hyperthermia. Higher dose of 500 micrograms/kg produced initial hypothermia which was followed by hyperthermia. On further increase of the dose to 1 mg/kg, consistent hypothermia was evident. Prazosin, a specific post-synaptic alpha 1 adrenoceptor blocker, induced hypothermia whereas piperoxan (presynaptic alpha 2 antagonist) produced hyperthermia. The pretreatment with prazosin, blocked the hyperthermic response of methyldopa. The initial hypothermia by 500 micrograms/kg of methyldopa was also potentiated. The pretreatment with piperoxan completely blocked the hypothermia but had no effect on hyperthermic response of methyldopa. Pretreatment of rabbits with both prazosin and piperoxan completely blocked the hypothermia as well as hyperthermic response of methyldopa. Thus it appeared that both presynaptic alpha 2 and postsynaptic alpha 1 adrenoceptors are involved in central thermoregulation in rabbits.     

Characterization of cold-induced heat shock protein expression in neonatal rat cardiomyocytes

Cardiac surgery is usually performed under conditions of cardioplegicischemic arrest. To protect the heart during the ischemic period, themyocardium is exposed to varying degrees of hypothermia. Althoughhyperthermia is known to induce the heat shock response, the moleculareffects of hypothermia on the myocardium have not been investigated. We havestudied the effect of hypothermia on the induction of heat shock proteins inprimary cultures of neonatal cardiomyocytes. Cold stress in cardiomyocytesinduced a 6 fold increase in the heat shock protein HSP70 as compared tocontrol. Increased HSP70 protein levels correlated with induction of HSP70mRNAs. Maximal levels of HSP70 protein appeared 4-6 h following recoveryfrom cold shock, indicating the transient nature of the response. Inductionof HSP25 mRNA was also observed in cold-shocked cardiomyocytes, even thoughincreased HSP25 protein levels were not detected. Our results indicate thathypothermia is capable of inducing the heat shock response in neonatalcardiomyocytes.     

Vitamin E and selenium regulate balance between beta-adrenergic and muscarinic responses in rat lungs

The effects of hydrogen peroxide on the beta-adrenergic and muscarinic responses of the rat trachea muscle were studied in vitro, after feeding rats, for 6 weeks, either a diet deficient in vitamin E and selenium or a control diet. In the control situation after incubation with 1 mM hydrogen peroxide for 30 min, a reduction of the maximal response to methacholine of 39% occurred whereas no pD2 shift could be demonstrated. Moreover, no response to isoprenaline after precontraction with 3 x 10(-7) M methacholine was left. In the deficient situation, we found a reduction to 64% of the response to methacholine after incubation with 1 mM hydrogen peroxide. Again isoprenaline became inactive, i.e. no relaxation with isoprenaline was observed after precontraction with 3 x 10(-7) M methacholine. We therefore conclude that vitamin E and selenium protect against oxidative stress in lung tissue and thus regulate the (patho-) physiological balance between adrenergic and muscarinic responses.     

Endothelial ultrastructure of myocardium microvessels affected by various methods of artificial hypothermia

A comparative analysis of the endothelial ultrastructure of myocardium microvessels affected by various methods of artificial hypothermia was carried out. Tissue samples were harvested in children with a congenital ventricular septum defect after cooling the whole body under the conditions of hypothermic artificial circulation and perfusionless (immersion) hypothermia. It was found out that the shifts in population composition of endothelial cells, as well as the changes in the ultrastructure of organelles participating in endocellular syntheses and transendothelial transfer of macromolecules depended upon the rate body cooling. Under perfusionless hypothermia and of moderately low cooling rate, morphological signs of inhibition of endothelial cells metabolism were observed alongside with quantitative reduction of their micropinocytic transport indicators. Under hypothermic artificial circulation these reactions tended to lag behind due to the high cooling rate that initiates a heterogenic response of various endothelial processes to the changes of body temperature.     

Bombesin produces hypothermia in hypophysectomized rats

Intracerebroventricular administration of bombesin, a naturally-occurring peptide, produces hypothermia in the rat. To determine whether a pituitary-dependent step is necessary for this effect, the thermoregulatory response was followed in hypophysectomized and intact rats maintained at room temperature. Significant hypothermia was produced in both experimental groups. This study supports an extra-pituitary mechanism for bombesin-induced hypothermia.     

A microarray analysis of the effects of moderate hypothermia and rewarming on gene expression by human hepatocytes (HepG2)

The gene expression changes produced by moderate hypothermia are not fully known, but appear to differ in important ways from those produced by heat shock. We examined the gene expression changes produced by moderate hypothermia and tested the hypothesis that rewarming after hypothermia approximates a heat-shock response. Six sets of human HepG2 hepatocytes were subjected to moderate hypothermia (31°C for 16 h), a conventional in vitro heat shock (43°C for 30 min) or control conditions (37°C), then harvested immediately or allowed to recover for 3 h at 37°C. Expression analysis was performed with Affymetrix U133A gene chips, using analysis of variance-based techniques. Moderate hypothermia led to distinct time-dependent expression changes, as did heat shock. Hypothermia initially caused statistically significant, greater than or equal to twofold changes in expression (relative to controls) of 409 sequences (143 increased and 266 decreased), whereas heat shock affected 71 (35 increased and 36 decreased). After 3 h of recovery, 192 sequences (83 increased, 109 decreased) were affected by hypothermia and 231 (146 increased, 85 decreased) by heat shock. Expression of many heat shock proteins was decreased by hypothermia but significantly increased after rewarming. A comparison of sequences affected by thermal stress without regard to the magnitude of change revealed that the overlap between heat and cold stress was greater after 3 h of recovery than immediately following thermal stress. Thus, while some overlap occurs (particularly after rewarming), moderate hypothermia produces extensive, time-dependent gene expression changes in HepG2 cells that differ in important ways from those induced by heat shock.     

Beta-adrenergic stimulation enhances the heat-shock response in fish

We have taken advantage of the unique properties of nucleated rainbow trout (Oncorhynchus mykiss) red blood cells (rbcs) to demonstrate that beta-adrenergic stimulation with the agonist, isoproterenol, significantly enhanced the heat-induced induction of heat-shock proteins (Hsps) in trout rbcs without affecting hsp expression on its own. Furthermore, this beta-adrenergic potentiation of hsp expression occurred only at physiologically relevant concentrations of adrenergic stimulation. In further experiments, we found that adrenaline increased 100-fold and noradrenaline increased 50-fold in trout after a 1-h heat shock at 25 degrees C, approximately 12 degrees C above acclimation temperature. This is the first time the adrenergic heat-shock response has been described for a temperate fish species. We conclude that beta-adrenergic stimulation enhances hsp expression in trout rbcs following heat stress, indicating physiological regulation of the cellular stress response in fish.