Adrenovascular lesions from neurogenic stress modified by suppression of nervous centres in rat

Adrenovascular lesions (hemorrhages and/or edema) caused by neurogenic stress, are modified by suppression of different nervous centres. Spinal transection at Th5 abolishes the adrenovascular response to neurogenic stress. Destruction of the anterior or posterior hypothalamus decreases this vascular response; the greatest effect was obtained by destruction of the hypothalamus medius or by hemidecortication. This effect was bilateral but more manifest contralaterally in cases with unilateral destruction. These results show that the adrenovascular reaction to neurogenic stress is regulated by the central nervous system, mainly by the hypothalamus and cerebral cortex.     

Mammalian DNA damage-inducible genes associated with growth arrest and apoptosis

Mammalian cells are exposed to a wide variety of genotoxic stresses from both endogenous and exogenous sources. Cells typically exhibit cell cycle delays, or checkpoints, in response to acute genotoxic stress. Other types of cellular responses to DNA damage include apoptosis and probably increases in DNA repair levels. These response pathways are altered in cancer cells, by genetic alterations such as overexpression or mutation of oncogenes, or loss of tumor suppressor gene functions. As cancer chemotherapy relies primarily on the selective killing of cancer cells by DNA-damaging agents, genetic alterations affecting cellular stress response pathways may affect the outcome of cancer treatment.     

Heat stress protection against mesenteric I/R-induced alterations in intestinal mucosa in rats.

Prior induction of heat shock protein 70 (HSP70) protects against ischemia-reperfusion (I/R) mucosal injury, but the ability of HSP70 to affect I/R-induced alterations in epithelial cell function is unknown. Rats subjected to whole body hyperthermia (41.5-42 degrees C for 6 min) increased HSP70 and heat shock factor 1 mRNA expression, reaching a maximum 2 h after heat stress and declining thereafter. HSP70 production was maximally elevated at 4 h after heat stress and remained elevated until after 12 h. Heat stress alone had no effect on mucosal function except to enhance secretion in response to ACh. Heat stress provided complete morphological protection against I/R-induced mucosal injury but did not confer a similar protection against I/R-induced decreases in mucosal resistance, sodium-linked glucose absorption, or tachykinin-mediated chloride secretion. Heat stress, however, attenuated the I/R-induced suppression of ACh response, and this effect was dependent on enteric nerves. Thus induction of heat shock protein 70 is associated with the preservation of mucosal architecture and attenuation of some specific functional alterations induced by I/R.     

Pain-induced alteration of glutamate in periaqueductal central gray and its reversal by morphine

Experiments were performed to evaluate alterations of glutamate levels in the periaqueductal central gray matter (CG) of mice following various treatments. Pain, but not stress, significantly reduced CG glutamate levels. Morphine, evaluated at its time of peak analgesic effect, not only reversed pain-induced depression of CG glutamate levels but significantly increased glutamate above control levels. Pentobarbital and chlorpromazine were without effect on CG glutamate levels suggesting a drug-specific response for this brain area. Evidence supporting a CG-specific morphine response is provided by comparison with alterations of glutamate levels in hypothalamus. In hypothalamus, morphine was without effect in reversing a pain-induced depression of glutamate levels.     

Pain-induced alteration of glutamate in periaqueductal central gray and its reversal by morphine

Experiments were performed to evaluate alterations of glutamate levels in the periaqueductal central gray matter (CG) of mice following various treatments. Pain, but not stress, significantly reduced CG glutamate levels. Morphine, evaluated at its time of peak analgesic effect, not only reversed pain-induced depression of CG glutamate levels but significantly increased glutamate above control levels. Pentobarbital and chlorpromazine were without effect on CG glutamate levels suggesting a drug-specific response for this brain area. Evidence supporting a CG-specific morphine response is provided by comparison with alterations of glutamate levels in hypothalamus. In hypothalamus, morphine was without effect in reversing a pain-induced depression of glutamate levels.     

Cold-induced increases in phenylethanolamine N-methyltransferase (PNMT) mRNA are mediated by non-cholinergic mechanisms in the rat adrenal gland

Previously, we reported that cold stress induces a rapid increase in adrenomedullary PNMT mRNA levels, followed by concomitant increases in PNMT immunoreactivity (10). In the present study, the extracellular signals mediating this adaptive response to stress were investigated using northern analysis and RNA slot-blot hybridization. Although adrenal denervation significantly diminished cold-induced increments in adrenomedullary PNMT mRNA levels, it did not completely abolish the cold stress response. In contrast to these results, splanchnectomy completely inhibited cold-induced increments in TH mRNAs in the same tissue samples. These findings indicate that the effects of cold exposure on PNMT mRNA levels are mediated by both neural and non-neural mechanisms, and that adrenal PNMT and TH are differentially regulated in response to cold stress. Surprisingly, the neural component of the PNMT stress response could not be attenuated by peripheral administration of chlorisondamine, a powerful nicotinic ganglionic blocking agent. In contrast, chlorisondamine was effective in inhibiting sympathetic neural activity, as judged by the drug's ability to completely block increases in blood pressure, heart rate, and plasma catecholamines resulting from spinal cord stimulation in pithed rats. The administration of atropine, a muscarinic receptor antagonist, also failed to inhibit cold-induced alterations in adrenal PNMT mRNA. These results suggest that the trans-synaptic induction of adrenal PNMT mRNA involves a non-cholinergic component, and that cold-induced increases in PNMT mRNA are not coupled to acetylcholine-mediated adrenal catecholamine release.     

Social stress adapts signaling pathways involved in stimulation of the hypothalamic-pituitary-adrenal axis.

In socially organized mammals the predominating stressors are not physical events but arise from the immediate social environment of the animal. Crowding typically evokes social stress reactions with prominent psychosocial components mimicking emotional state alterations. Depending on the nature, intensity and duration of the initial stimuli, they can either reduce or increase the response of the hypothalamic-pituitary adrenal (HPA) axis. In homologous desensitization only stimulation by desensitizing hormone is attenuated, in heterologous desensitization diminished responsiveness to additional activators occurs. Social stress of crowding (21 rats in a cage for 7) for 3, 7, 14 and 21 days considerably reduced the corticosterone response to intracerebroventricular (icv) administration of carbachol, a cholinergic muscarinic receptor agonist due to a homologous desensitization and down-regulation of central muscarinic receptors by an increased secretion of acetylcholine. Crowding stress significantly reduced the HPA response to icv isoprenaline, a beta-adrenergic agonist and clonidine, an alpha2-adrenergic agonist and only moderately diminished the response to phenylephrine -- an alpha1-adrenergic agonist. The stimulatory effect of dimaprit, a nonselective histamine H2-receptor agonist on HPA axis was considerably impaired in crowded rats while the response to 2-pyridylethylamine, a H1-receptor agonist was moderately affected. Social crowding stress did not substantially alter the CRH-induced ACTH and corticosterone response while it suppressed the vasopressin-induced responses. Indomethacin did not change basal plasma ACTH and corticosterone levels, indicating that prostaglandins are not involved in basal regulation of the HPA activity. Inhibition of prostaglandins synthesis by indomethacin significantly diminished the vasopressin-induced HPA response under both basal and social stress conditions, whereas it did affect the CRH-elicited HPA stimulation under both these circumstances. Social stress inhibits the nitric oxide effect on the CRH-induced ACTH response but it does not alter the AVP-induced responses. These results indicate a specific and distinct influences of social crowding stress on the neurotransmitters- neurohormones- prostaglandins- and nitric oxide-induced HPA responses.     

Adaptation to stress in yeast: to translate or not?

For most eukaryotic organisms, including Saccharomyces cerevisiae, the rapid inhibition of protein synthesis forms part of a response to stress. In order to balance the changing conditions, precise stress-specific alterations to the cell's proteome are required. Therefore, in the background of a global down-regulation in protein synthesis, specific proteins are induced. Given the level of plasticity required to enable stress-specific alterations of this kind, it is surprising that the mechanisms of translational regulation are not more diverse. In the present review, we summarize the impact of stress on translation initiation, highlighting both the similarities and distinctions between various stress responses. Finally, we speculate as to how yeast cells generate stress-responsive programmes of protein production when regulation is focused on the same steps in the translation pathway.     

Eight weeks of streptozotocin-induced diabetes influences the effects of cold stress on immunoreactive beta-endorphin levels in female rats

Cold stress produced a significant reduction in the concentration of immunoreactive beta-endorphin (IR-BE) in the anterior pituitary of diabetic female rats. IR-BE levels in the anterior pituitary of non-diabetic female rats were not affected by exposure to the cold. The effects of cold stress on IR-BE levels in the neurointermediate lobe of the pituitary and the hypothalamus were attenuated in diabetic as compared to control animals. These data suggest that in female rats, eight weeks of diabetes produced alterations in the neuroendocrine mechanisms which modulate IR-BE levels in the pituitary and hypothalamus in response to cold stress.     

Tethering of CpxP to the inner membrane prevents spheroplast induction of the cpx envelope stress response

The Cpx envelope stress response of Escherichia coli is controlled by a two-component regulatory system that senses misfolded proteins in extracytoplasmic compartments and responds by inducing the expression of envelope protein folding and degrading factors. We have proposed that in the absence of envelope stress the pathway is maintained in a downregulated state, in part through interactions between the periplasmic inhibitor molecule CpxP and the sensing domain of the histidine kinase CpxA. In this study, we show that depletion of the periplasmic contents of the cell by spheroplast formation does indeed lead to induction of the Cpx envelope stress response. Further, removal of CpxP is an important component of this induction because tethering an MBP-CpxP fusion protein to the spheroplast inner membranes prevents full activation by this treatment. Spheroplast formation has previously been demonstrated to induce the expression of a periplasmic protein of unknown function, Spy. Analysis of spy expression in response to spheroplast formation by Western blot analysis and by lacZ operon fusion in various cpx mutant backgrounds demonstrated that spy is a member of the Cpx regulon. Interestingly, although the only known spy homologue is cpxP, Spy does not appear to perform the same function as CpxP as it is not involved in inhibiting the Cpx envelope stress response. Rather, deletion of spy leads to activation of the sigmaE stress response. Because the sigmaE response is specifically affected by alterations in outer membrane protein biogenesis, we think it possible that Spy may be involved in this process.     

Effect of Gravity Changes on the Cyanobacterium Synechocystis sp. PCC 6803

The impact of hypergravity and simulated weightlessness were studied to check whether cyanobacteria perceive changes of gravity as stress. Hypergravity generated by a low-speed centrifuge increased slightly the overall activity of dehydrogenases, but the increase was the same for 90 g and 180 g. The protein pattern did not show qualitative alterations during hypergravity treatment up to 180 g. Cells of Synechocystis PCC 6803 subjected to common stressors like salt, heat, and light clearly accumulated at least four general stress proteins (25, 31, 34, and 63 kDa, respectively). Three of these proteins could also be detected after hypergravity, but in such small amounts that their occurrence could only be taken as a weak indication of stress. Low-molecular-weight stress metabolites were not synthesized in response to hypergravity, indicating that this gravity change was unable to activate the osmotic signal transduction chain. Gravity-dependent alterations were observed only during simulated weightlessness (generated by a fast-rotating clinostat). The glutamate/glutamine ratio was significantly shifted toward a higher glutamine portion. Altogether, the results may indicate that moderate changes of gravity were hardly, if ever, sensed as stress by cyanobacteria. Received: 20 May 1997 / Accepted: 25 June 1997     

Nitric oxide mediates the interleukin-1beta- and nicotine-induced hypothalamic-pituitary-adrenocortical response during social stress.

We investigated the role of nitric oxide (NO) in the interleukin 1beta (IL-1beta) and nicotine induced hypothalamic-pituitary-adrenal axis (HPA) responses, and a possible significance of CRH and vasopressin in these responses under basal and social stress conditions. Male Wistar rats were crowded in cages for 7 days prior to treatment. All compounds were injected i.p., nitric oxide synthase (NOS) inhibitors, alpha-helical CRH antagonist and vasopressin receptor antagonist 15 min before IL-1beta or nicotine. Identical treatment received control non-stressed rats. Plasma ACTH and serum corticosterone levels were measured 1 h after IL-1beta or nicotine injection. L-NAME (2 mg/kg), a general nitric oxide synthase (NOS) inhibitor, considerably reduced the ACTH and corticosterone response to IL-1beta (0.5 microg/rat) the same extent in control and crowded rats. CRH antagonist almost abolished the nicotine-induced hormone responses and vasopressin antagonist reduced ACTH secretion. Constitutive endothelial eNOS and neuronal nNOS inhibitors substantially enhanced the nicotine-elicited ACTH and corticosterone response and inducible iNOS inhibitor, aminoguanidine, did not affect these responses in non-stressed rats. Social stress significantly attenuated the nicotine-induced ACTH and corticosterone response. In crowded rats L-NAME significantly deepened the stress-induced decrease in the nicotine-evoked ACTH and corticosterone response. In stressed rats neuronal NOS antagonist did not alter the nicotine-evoked hormone responses and inducible NOS inhibitor partly reversed the stress-induced decrease in ACTH response to nicotine. These results indicate that NO plays crucial role in the IL-1beta-induced HPA axis stimulation under basal and social stress conditions. CRH and vasopressin of the hypothalamic paraventricular nucleus may be involved in the nicotine induced alterations of HPA axis activity. NO generated by eNOS, but not nNOS, is involved in the stress-induced alterations of HPA axis activity by nicotine.     

Microsomal Phospholipid Molecular Species Alterations during Low Temperature Acclimation in Dunaliella

A detailed analysis of the low temperature-induced alterations of Dunaliella salina (UTEX 1644) microsomal membrane lipids was carried out. Microsomal membranes were isolated from cells grown at 30 degrees C, from cells shifted to 12 degrees C for 12 hours, and from cells acclimated to 12 degrees C. Fatty acid analyses of the major lipid classes demonstrated significant changes in the fatty acid composition of phosphatidylcholinemine (PE) and phosphatidylglycerol (PG) but not phosphatidylcholine (PC) during the initial 12 hours at low temperature. These changes did not entail enhanced desaturation of linoleic acid. Subsequent to 12 hours, the proportions of linolenic acid increased in all phospholipids.Molecular species analyses of the phospholipids demonstrated that the most immediate changes following a shift to low temperature were limited to several molecular species of PE and PG. The changes observed in PE included a decrease in C(30) species and concomitant increases in C(34) and C(36) species. Compositional changes associated with PG entailed the emergence of a new molecular species (18:1/18:1) not found at 30 degrees C. The retailoring of molecular species resulted in an increase in the number of species having two unsaturated acyl chains and did not reflect a simple enhancement of desaturase activity as suggested by the fatty acid analysis. We conclude that the initial alterations in response to low temperature stress involve discrete changes in certain molecular species. These and further alterations of molecular species following acclimation to low temperature would appear to augment increases in acyl chain desaturation as a means of modifying membrane properties in response to low temperature stress.     

Rapid pacing of embryoid bodies impairs mitochondrial ATP synthesis by a calcium-dependent mechanism--a model of in vitro differentiated cardiomyocytes to study molecular effects of tachycardia

Tachycardia may cause substantial molecular and ultrastructural alterations in cardiac tissue. The underlying pathophysiology has not been fully explored. The purpose of this study was (I) to validate a three-dimensional in vitro pacing model, (II) to examine the effect of rapid pacing on mitochondrial function in intact cells, and (III) to evaluate the involvement of L-type-channel-mediated calcium influx in alterations of mitochondria in cardiomyocytes during rapid pacing. In vitro differentiated cardiomyocytes from P19 cells that formed embryoid bodies were paced for 24 h with 0.6 and 2.0 Hz. Pacing at 2.0 Hz increased mRNA expression and phosphorylation of ERK1/2 and caused cellular hypertrophy, indicated by increased protein/DNA ratio, and oxidative stress measured as loss of cellular thiols. Rapid pacing additionally provoked structural alterations of mitochondria. All these changes are known to occur in vivo during atrial fibrillation. The structural alterations of mitochondria were accompanied by limitation of ATP production as evidenced by decreased endogenous respiration in combination with decreased ATP levels in intact cells. Inhibition of calcium inward current with verapamil protected against hypertrophic response and oxidative stress. Verapamil ameliorated morphological changes and dysfunction of mitochondria. In conclusion, rapid pacing-dependent changes in calcium inward current via L-type channels mediate both oxidative stress and mitochondrial dysfunction. The in vitro pacing model presented here reflects changes occurring during tachycardia and, thus, allows functional analyses of the signaling pathways involved.     

Age-related alterations in superoxide anion generation in mouse peritoneal macrophages studied by repeated stimulations and heat shock treatment.

The ability of thioglycollate-elicited peritoneal macrophages (PM) from young and senescent mice to generate superoxide anions (O2-) under repeated stimulation or thermal stress was studied using either zymosan, opsonized zymosan (OZ), or phorbol myristate acetate (PMA). A diminished capacity to recover from repeated stimulation was found with aging. When stimulated for a second time 24 hours after the primary stimulation, PM from young animals generated 80% of the initial O2- responses to either zymosan, or OZ. Under the same conditions, PM from senescent mice generated 62% of the initial O2- produced in response to zymosan, and 45% in response to OZ. In both age groups the response to a second PMA stimulation comprised only 10% of the primary response. A considerably diminished capacity to generate O2- was also demonstrated in PM from senescent mice after recovery from exposure to thermal stress. Exposure to 42.5 degrees C for 20 minutes was found to be the threshold temperature for irreversible loss of activity in senescent PM, whereas at this temperature, PM from young animals recovered up to 70% of their O2- generating activity. Since NADPH oxidase and superoxide dismutase activities were only mildly affected by the hyperthermia in all age groups, they could not account for the age-related decline in the recovery from stress. Age-related alterations in signal transduction or receptor alterations could possibly play a primary role in this decline.     

Changes in astrocyte mitochondrial function with stress: effects of Bcl-2 family proteins

Mitochondria are central to both apoptotic and necrotic cell death, as well as to normal physiological function. Astrocytes are crucial for neuronal metabolic, antioxidant, and trophic support, as well as normal synaptic function. In the setting of stress, such as during cerebral ischemia, astrocyte dysfunction may compromise the ability of neurons to survive. Despite their central importance, the response of astrocyte mitochondria to stress has not been extensively studied. Limited data already suggest clear differences in the response of neuronal and astrocytic mitochondria to oxygen-glucose deprivation (GD). Prominent mitochondrial alterations during stress that can contribute to cell death include changes in production of reactive oxygen species (ROS) and release of death regulatory and signaling molecules from the intermembrane space. In response to stress mitochondrial respiratory function and membrane potential also change, and these changes appear to depend on cell type. Bcl-2 family proteins are the best studied regulators of cell death, especially apoptosis, and mitochondria are a major site of action for these proteins. Although much data supports the role of Bcl-2 family proteins in the regulation of some of these mitochondrial alterations, this remains an area of active investigation. This mini-review summarizes current knowledge regarding mitochondrial control of cell survival and death in astrocytes and the effects of anti-apoptotic Bcl-2 proteins on astrocyte mitochondrial function.