Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0848237 (acute stress)
 4,619 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Evidence is accumulating that acute stress situations such as ischemia, adrenergic dominance, and ouabain intoxication enhance production of endogenous substances (PgI2, adenosine, NO) which may protect the myocardium from harmful consequences of these stress situations. PgI2 and its stable analogue 7-oxo-PgI2 exert an early direct- and induce a delayed indirect antiischemic, antiarrhythmic, and cytoprotective effect. The direct action is shortlasting; it protects from myocardial ischemia and arrhythmias, at least partly, by its vasodilating, antiaggregatory, and "membrane-stabilizing" effects. The delayed, long-lasting PgI2-induced protection from postocclusion, reperfusion- and ouabain-arrhythmias is dose- (optimal 50 micrograms/kg) and time- (optimal 48 h after treatment) dependent. Its mechanism is probably based on a 7-oxo-PgI2 induced increase in the activity of Na/K-ATP-ase, and further, on a reduced sensitivity to beta-adrenergic agonists and to changes at the cardiac membrane level, resulting in a prolongation of the action potential duration and the effective refractory period.
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PMID:Cardioprotection: endogenous protective mechanisms promoted by prostacyclin. 178 66

It is apparent from the above discussion that acute stress, such as ischemia and reperfusion, hypoxia and reoxygenation, hyperthermia and oxidative stress, can rapidly potentiate the induction of genes for certain members of the HSP families and for antioxidants/antioxidant enzymes. Whether the stress response and induction of these genes have a direct role in myocardial protection is not known, but the induction of the expression of these genes are mostly associated with the preservation of myocardial cells from subsequent injury resulting from ischemia, hypoxia and reperfusion. The ubiquitous presence of some of these stress genes, such as for HSP 70 and catalase, in normal unstressed myocardium further suggests a role of these genes in many basic and essential biochemical and metabolic pathways. It is reasonable to speculate that the cells respond to the stress as a consequence of perturbations of one or more of the metabolic pathways by stimulating the induction of the stress genes of that particular pathway in which they participate. Thus, these genes are likely to be involved both in the protection and recovery/repair mechanisms. The precise mechanism by which myocardial cell recognizes and responds to a particular stress agent such as ischemia, hypoxia, hyperthermia or oxidative stress is not clear. While it is tempting to speculate that a generalized mechanism exists, applying to all different modes of stress response and gene induction, whether these agents induce the response via independent pathways or converge within a single point is entirely unclear. However, from the striking resemblance between the pattern of gene expression, especially with regard to HSP and antioxidant genes, it is reasonable to hypothesize the existence of a common and essential pathway of molecular signaling that leads to the expression of these stress genes (Fig. 2). The identification and characterization of the transcription factors that regulate the expression of the genes induced by these forms of stress should greatly facilitate our future understanding of the mechanism of stress response.
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PMID:Gene expression in acute myocardial stress. Induction by hypoxia, ischemia, reperfusion, hyperthermia and oxidative stress. 776 Mar 41

Successful adaptation to stress is a prerequisite for the survival of all organisms living in an environment in which noxious stimuli are constantly present. Higher organisms, including human beings, have developed complex mechanisms to tolerate the myriad of insults that occur to cellular constituents and organ systems after trauma with its resultant blood loss and tissue injury. Surgical stress can be conceptualized in this context, and it is therefore not surprising that human beings have developed an array of integrated stress-response axes that work in concert to return the host to a sustainable homeostatic plateau. The most important aspects of these axes are depicted in Figure 24. Surgical stress activates the higher cortical center of the brain and the spinal and baroreceptor reflexes that stimulate the hypothalamus to secrete CRH. CRH stimulates the release of ACTH from the pituitary gland, which causes the release of glucocorticoids from the adrenal cortex. Simultaneously, in a parallel fashion, surgical stress activates the sympathetic system to release catecholamines. Glucocorticoids and catecholamines are the major effectors of stress adaptation and interact at multiple levels in a synergistic fashion. They bind to specific receptors that are present in virtually every organ, although the number and affinity of a given tissue's receptor vary dramatically for individual ligands. Receptor occupancy results in short-term and long-term effects that ultimately improve the host's prospects of tolerating the stressful event. The short-term effects result in rapid actions, such as cardiovascular and metabolic responses that benefit the host in a "fight or flight" reaction. The long-term effects generally occur through alterations in gene transcription that prepare the host for, or adapt the host to, repetitive or chronic stress. Changes in the phosphorylation state of intracellular proteins are a common mode of action for both the short-term and long-term responses. These stress-responsive proteins have an enormous functional capacity: they alter enzymatic pathways, modulate hormone levels, and act as transcription factors to modify the expression of stress-responsive genes. During the last decade considerable progress has been made in explaining the complex signal transduction pathways mediating these responses. The importance of the HSPs in the host response to acute stress and their intimate association with activation of the HPA axis and sympathetic nervous system have recently been appreciated. The HSPs are likely to be induced early during organ rejection or ischemia and thus serve as diagnostic indicators.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Endocrine and molecular responses to surgical stress. 804 59

Gastrointestinal complications including acute stress ulcerations occur after burn injury. The causes of acute gastric derangements are multiple, and tissue ischemia in the acute period of burn shock may promote breakdown of the gastric mucosal protective barrier. We compared gastric pH in mice after 25% total body surface area, full-thickness murine burn injury with that in unburned control animals. Animals were anesthetized with methoxyflurane and were resuscitated with 1 ml normal saline solution immediately after burn. Animals were killed at intervals up to 24 hours after burn injury, stomachs were removed and opened, and gastric mucosal pH was measured by use of a surface pH probe. In other animals mixed venous blood was obtained via direct inferior vena cava puncture, and blood gas analysis was performed at intervals up to 24 hours after burn injury. Unexpectedly, gastric mucosal pH increased in burned mice compared with that in controls. The peak difference, greater than one log pH unit, occurred at 3 hours after burn injury (pH 4.45 burn vs pH 3.34 control, p < 0.00001), and this difference was maintained through 12 hours (pH 4.88 burn vs pH 3.20 control, p < 0.005). In this model, shock was observed to begin as early as 1 hour after burn injury and reached its maximal period (base deficit, -27.8 mEq/L) at 12 hours after burn injury. In view of the higher gastric pH in burned mice with concomitant profound shock, gastric acid production appears to be impaired during this time, which suggests acute postburn gastrointestinal ulcerations may be primarily due to ischemia. Prevention of organ ischemia may play a key role in the prevention of acute gastric ulcerations after burn injury.
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PMID:Burn injury results in decreased gastric acid production in the acute shock period. 858 42

To test the authors' hypothesis that cellular antioxidant enzymes constitute a cellular defense against acute stress, myocardial ischemia reperfusion injury in transgenic mice overexpressing the cellular glutathione peroxidase (GSHPx-1) was studied. Transgenic mice were generated using the entire mouse GSHPx-1 gene including approximately 2.0 kb 5'flanking sequence. A 400% increase of GSHPx activity was found in the hearts of transgenic mice compared with non-transgenic controls. Isolated perfused hearts were prepared from two groups of mice: transgenic overexpressed; non-transgenic controls. Hearts were perfused by Langendorff mode, and after 10 min of stabilization subjected to 30 min of ischemia followed by 20 min of reperfusion. In addition, a group of hearts were perfused for 50 min without subjecting them to ischemia and reperfusion to demonstrate the stability of heart preparation. Transgenic mouse hearts demonstrated significantly improved recovery of contractile force and the rate of contraction, compared to non-transgenic control mouse hearts. The infarct size was also lower in transgenic mouse hearts compared to those of non-transgenic controls. In concert, following ischemia, release of creatine kinase from the transgenic hearts was significantly lower than the control group. The results of this study indicate that increased GSHPx-1 expression renders the heart more resistant to myocardial ischemia reperfusion injury.
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PMID:Transgenic mice overexpressing glutathione peroxidase are resistant to myocardial ischemia reperfusion injury. 887 85

We have previously shown that the acute phase reaction of the pancreas is a powerful emergency mechanism which protects the organism against further pancreatic aggression. In an attempt to understand the mechanisms involved in this protective effect we tried to characterize at the molecular level the phenotypic changes of the pancreatic cell during acute stress. Using a systematic approach, we identified the PC3/TIS21/BTG2 mRNA as strongly overexpressed in pancreas during the acute phase of pancreatitis. PC3/TIS21/BTG2 mRNA is also overexpressed in liver and kidney during acute pancreatitis but not in the other tissues analyzed. In addition, PC3/TIS21/BTG2 mRNA is overexpressed in kidney after a 30-min ischemia. Since acute pancreatitis and kidney ischemia-reperfusion-induced injury were associated with apoptosis, and PC3/TIS21/BTG2 has an antiapoptotic activity, we speculate that this protein may play a role in the control of apoptosis progression in these tissues.
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PMID:Overexpression of the PC3/TIS21/BTG2 mRNA is part of the stress response induced by acute pancreatitis in rats. 971 37

Metabolic differences between cardiomyopathic hamsters (CMHs), as they progress through various physiologic phases before reaching end-stage heart failure (HF), and healthy hamsters (HHs) are often difficult to demonstrate. We suggest that metabolic differences, magnified by application of chronic stress (S: cold immobilization 2 hr/day for 5 days) followed by acute stress (AS: 55 min global ischemia /30 min reperfusion), can be used to characterize different stages in this cardiomyopathic process. High performance liquid chromatography (HPLC) and 31P NMR methods were used to monitor the effects of acute stress applied to nonstressed (NS) and previously stressed CMHs (NS-2.5-month NS-5-month; S-2.5-month, S-5-month) and HHs (NS-HH, S-HH). Cardiac tissue extracts from nonstressed and stressed hamsters were analyzed for ATP and PCr at baseline and after completion of ischemia/reperfusion (AS) using HPLC. In nonstressed hamsters, ATP and PCr were 12% lower in CMHs (both NS-2.5- and NS-5-month) than in NS-HHs. After exposure to stress, ATP was 26% lower in CMHs (S-2.5- and S-5-month) compared to S-HHs, whereas there were minimal differences in PCr between the groups. 31P NMR monitoring of metabolism in the perfused beating heart during application of acute stress produced similar changes (%) in ATP and PCr in all groups (NS and S), whereas Pi increase was less in NS-5-month (118%) compared to NS-2.5-month (179%) and NS-HHs (306.8%), P < 0.05; and in S-5-month (148%) compared to S-2.5-month (216%) and S-HHs (222%). The changes in myocardial pH were inversely related to changes in Pi: NS-5-month (-13.5%); NS-2.5-month (-9.7%); NS-HH (-17.7%). pH changes in stressed cardiomyopathic hamsters were similar to those of S-HHs. The postischemic recovery of ATP and Pi return closer to baseline values in cardiomyopathic hamsters (both NS and S) compared to healthy hamsters. The data suggest that cardiomyopathic hamsters have baseline metabolic abnormalities, and their responses to chronic cold immobilization stress, acute ischemia, and chronic cold immobilization stress plus acute ischemia are different from those in HHs. These responses may help to characterize specific stages of disease.
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PMID:Metabolic abnormalities and differential responses to stress associated with hamster cardiomyopathy. 975 Dec 22

Little is known concerning the effect of oxidative stress on the expression of antioxidative enzymes in the decompensated cardiac hypertrophy of spontaneously hypertensive rats (SHR), considered as a model of dilative cardiomyopathy in man. Superoxide dismutase (SOD), catalase, and glutathione peroxidase (GPx) were characterized in isolated perfused hearts of 18 month old SHR and the age-matched normotensive control Wistar-Kyoto (WKY) rats, before and after 30 min infusion of 25 microM H(2)O(2). After infusion of H(2)O(2), aortic flow decreased in WKY from 26.2 +/- 2.2 to 16.0 +/- 0.8 ml/min (p <.05) but not in SHR (18.2 +/- 1.9 vs. 20.7 +/- 2.2 ml/min). This protection was related to the higher myocardial activities of GPx, MnSOD and CuZnSOD in SHR, compared with those of the WKY group. Although total SOD activity in the SHR fell after H(2)O(2) exposure (to 1.81 +/- 0.13 from 3.56 +/- 0.49 U/mg of protein), catalase activity increased (to 2.46 +/- 0.34 from 1.56 +/- 0.29 k min(-1)mg(-1)protein), compared with the pre-infusion period (p <.05 in each case). In additional studies, hearts were subjected to 30 min of global ischemia followed by 30 min of reperfusion. The results obtained in ischemic/reperfused hearts show the same changes in enzyme activities measured as it was observed in H(2)O(2) perfused hearts, indicating that oxidative stress is independent of the way it was induced. The higher catalase activity derived from elevated mRNA synthesis. The antioxidative system in dilative cardiomyopathic hearts of SHR is induced, probably due to episodes of oxidative stress, during the process of decompensation. This conditioning of the antioxidative potential may help overcome acute stress situations caused by reactive oxygen species in the failing myocardium.
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PMID:Effects of oxidative stress on the expression of antioxidative defense enzymes in spontaneously hypertensive rat hearts. 1103 13

Relocation stress may be one factor increasing the mortality rate of people who are severely and profoundly retarded (S/P MR) when they transfer from institutional to community living arrangements. However, no research exists concerning acute stress effects with groups who are S/P MR. In this project, 28 residents of a state facility for those with S/P MR were exposed to five-minute structured educational tasks. Venous blood samples were drawn before and after the stressor. Granulocytes, red blood cells, hemoglobin, and plasma protein increased while monocytes decreased after stress. Immune cell subsets did not change significantly. Hemoconcentration, an important factor in thrombosis and ischemia, may relate to relocation stress in S/P MR populations. Methodological factors limit generalization but additional research with larger samples, more indices of stress, more poststress blood samples, and additional stressors are encouraged.
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PMID:Hematological and immunological acute mental stress responses of people who are severely and profoundly mentally retarded. 1110 Jul 98

Heat shock proteins (HSPs) play a critical role in maintaining cellular homeostasis and protecting cells during episodes of acute stress. Specifically, HSPs of the 70 kDa family (i.e., HSP72) are important in preventing ischemia-reperfusion induced apoptosis, necrosis, and oxidative injury in a variety of cell types including the cardiac myocyte. Evidence indicates that HSP72 may contribute to cellular protection against a variety of stresses by preventing protein aggregation, assisting in the refolding of damaged proteins, and chaperoning nascent polypeptides along ribosomes. Endurance exercise is a physiological stress that can be used to elevate myocardial levels of HSP72. It is now clear that endurance exercise training can elevate myocardial HSP72 by 400-500% in young adult animals. Importantly, an exercise-induced elevation in myocardial HSPs is associated with a reduction in ischemia-reperfusion (I-R) injury in the heart. Although it seems likely that exercise-induced elevations in myocardial levels of HSPs play an important role in this protection against an I-R insult, new evidence suggests that other factors may also be involved. This is an important area for future research.
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PMID:Exercise, heat shock proteins, and myocardial protection from I-R injury. 1125 64


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