Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0022116 (ischemia)
 91,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

It is known that ischemia commonly increases exogenous glucose utilization by accelerating glucose uptake and flux rates through the Embden-Meyerhof pathway. Constitutive enzymes regulate the rate of glycolysis and in turn are regulated by product inhibition and allosteric controls. The purpose of this report was to test whether mRNA abundance for select glycolytic enzymes, and glucose transport proteins, is also modified. Six intact working pig hearts with coronary flow controlled by extracorporeal perfusion were compared at the following conditions: (1) aerobic control perfusion; (2) ischemia affected by a 60% decrease in left anterior descending (LAD) coronary perfusion: (3) ischemia again affected by a 60% decrease in LAD flow followed by a 40-min interval of aerobic reflow; (4) an intermittent ischemia and reflow protocol including four cycles of similar LAD flow reductions (5 min per cycle) interspersed with 15-20 min of aerobic reperfusion; (5) a 4-day model designed to produce myocardial chronic hibernation: and (6) mild ischemia induced by a 40% decrease in LAD flow for 85 min to produce certain adaptations compatible with short-term hibernation. In each heart, mRNA abundance was measured from LAD and circumflex (LCF) perfused myocardium for hexokinase, phosphofructokinase, glyceraldehyde-3-phosphate dehydrogenase and the two glucose transporter isomers, GLUT 4 and GLUT 1. mRNA data from LAD myocardium in intervention hearts were normalized to those from LAD tissue in the control heart (LADc) and with LCF values in the same intervention hearts. Signal variance around unity in the LAD tissue, with respect to that of the LCF myocardium, in the control heart compared closely (44 and 41% in two separate runs, respectively). GLUT 1/GLUT 4 ratios in the LAD and LCF beds of this heart also agreed closely. LAD/LADc ratios were increased for hexokinase (1.69), phosphofructokinase (3.69), and glyceraldehyde-3-phosphate dehydrogenase (2.29) in the ischemia heart and for phosphofructokinase (3.90), glyceraldehyde-3-phosphate dehydrogenase (2.20), GLUT 4 (1.55) and GLUT 1 (2.20) in the ischemia/reflow heart. There was no evidence of excess signal in the intermittent ischemia/reflow, chronic hibernation, or mild ischemia hearts. Altered signal from LCF myocardium was also suggested. These data indicate that mRNA abundance for select glycolytic enzymes and transporter proteins is increased in ischemic myocardium with or without reperfusion and offers a possible mechanism for increased protein activity in settings of diminished regional coronary flow.
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PMID:mRNA expression of glycolytic enzymes and glucose transporter proteins in ischemic myocardium with and without reperfusion. 992 82

To gain insights into the pathogenesis and management of perinatal hypoxic-ischemic brain damage, the authors have used an immature rat model which they developed many years ago. The model entails ligation of one common carotid artery followed thereafter by systemic hypoxia. The insult produces permanent hypoxic-ischemic brain damage limited to the cerebral hemisphere ipsilateral to the carotid artery occlusion. The mini-review describes recently accomplished research pertaining to the use of the immature rat model, specifically, investigations involving energy metabolism, glucose transporter proteins, free radical injury, and seizures superimposed upon cerebral hypoxia-ischemia. Future research will focus on molecular mechanisms of neuronal injury with a continuing focus on therapeutic strategies to prevent or minimize hypoxic-ischemic brain damage.
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PMID:Rat model of perinatal hypoxic-ischemic brain damage. 997 18

Previous studies from our laboratory have demonstrated that chronic stress produces molecular, morphological, and ultrastructural changes in the rat hippocampus that are accompanied by cognitive deficits. Glucocorticoid attenuation of glucose utilization is proposed to be one of the causative factors involved in stress-induced changes in the hippocampus, producing an energy-compromised environment that may make hippocampal neuronal populations more vulnerable to neurotoxic insults. Similarly, diabetes potentiates neuronal damage in acute neurotoxic events, such as ischemia and stroke. Accordingly, the current study examined the regulation of the neuron-specific glucose transporter, GLUT-3, in the hippocampus of streptozotocin-induced diabetic rats subjected to restraint stress. Diabetes leads to significant increases in GLUT-3 mRNA and protein expression in the hippocampus, increases that are not affected by stress. Collectively, these results suggest that streptozotocin-induced increases in GLUT-3 mRNA and protein expression in the hippocampus may represent a compensatory mechanism to increase glucose utilization during diabetes and also suggest that modulation of GLUT-3 expression is not responsible for glucocorticoid impairment of glucose utilization.
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PMID:Regulation of GLUT-3 glucose transporter in the hippocampus of diabetic rats subjected to stress. 1032 82

A number of observations indicate that myocardial glucose utilization is increased late during post-ischemic reperfusion. The present study was designed to examine whether transient ischemia elicits altered expression of glucose transporters GLUT-1 and GLUT-4. In rats, the left anterior descending coronary artery was occluded for 20 min followed by reperfusion for 1, 3 or 7 days. Regional myocardial uptake and phosphorylation of glucose was determined based on myocardial accumulation of 2-deoxy-D-[2, 6-3H]glucose-6-phosphate. In hearts from fasted rats, after 3 days of reperfusion, myocardial uptake and phosphorylation of glucose was 48% higher in the reperfused region compared to a remote control region. No regional difference in myocardial glucose uptake and phosphorylation was detectable in hearts from fed rats. After 1 day of reperfusion, expression of myocardial glucose transporter GLUT-1 mRNA was increased to 195+/-24% (mean+/-SEM) of the value measured in the remote region and the expression of GLUT-4 mRNA was decreased to 58+/-7%. After 3 days of reperfusion both mRNA and protein of GLUT-1 were higher in the reperfused region, averaging 133+/-23% and 249+/-36%, respectively. The corresponding values for GLUT-4 mRNA and protein were 77+/-7% and 62+/-6%, respectively. The results indicate that a short period of ischemia alters the expression of glucose transporter isoforms GLUT-1 and GLUT-4. Observed changes may be involved in the mechanisms underlying late changes of substrate metabolism during reperfusion.
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PMID:Effect of transient ischemia on the expression of glucose transporters GLUT-1 and GLUT-4 in rat myocardium. 1033 52

The intracellular signaling mechanism of the ischemia-stimulated glucose transporter (GLUT) translocation in the heart is not yet characterized. It has been suggested that catecholamines released during ischemia may be involved in this pathway. The purpose of this study was to evaluate the contribution of alpha-adrenoceptors and beta-adrenoceptors to ischemia-mediated GLUT4 and GLUT1 translocation in the isolated, Langendorff-perfused rat heart. Additionally, GLUT translocation was studied in response to catecholamine stimulation with phenylephrine (Phy) and isoproterenol (Iso). The results were compared with myocardial uptake of glucose analogue [18F]fluorodeoxyglucose (FDG). Subcellular analysis of GLUT4 and GLUT1 protein on plasma membrane vesicles (PM) and intracellular membrane vesicles (IM) using membrane preparation and immunoblotting revealed that alpha- and beta-receptor agonists stimulated GLUT4 translocation from IM to PM (2.5-fold for Phy and 2.1-fold for Iso, P<0.05 versus control), which was completely inhibited by phentolamine (Phe) and propranolol (Pro), respectively. Plasmalemmal GLUT1 moderately rose after Iso exposure, and this was prevented by Pro. In contrast, ischemia-stimulated GLUT4 translocation (2.2-fold, P<0.05 versus control) was only inhibited by alpha-adrenergic antagonist Phe but not by beta-adrenergic antagonist Pro. Similarly, Phe but not Pro inhibited ischemia-stimulated GLUT1 translocation. GLUT data were confirmed by FDG uptake monitored using bismuth germanate detectors. The catecholamine-stimulated FDG uptake (6.9-fold for Phy and 8.9-fold for Iso) was significantly inhibited by Phe and Pro; however, only Phe but not Pro significantly reduced the ischemia-induced 2.5-fold increase in FDG uptake (P<0.05 versus ischemia). This study suggests that alpha-adrenoceptor stimulation may play a role in the ischemia-mediated increase in glucose transporter trafficking leading to the stimulation of FDG uptake in the isolated, perfused rat heart, whereas beta-adrenergic activation does not participate in this signaling pathway.
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PMID:Contribution of alpha-adrenergic and beta-adrenergic stimulation to ischemia-induced glucose transporter (GLUT) 4 and GLUT1 translocation in the isolated perfused rat heart. 1038 93

Myocardial glucose transport is not only facilitated by the insulin sensitive glucose transporter (GLUT) 4 but also by GLUT1. It was recently demonstrated that ischemia induces GLUT4 translocation by a mechanism distinct from the insulin-induced signaling pathway. However, the role of ischemia-mediated GLUT1 translocation and the signaling pathway involved is not yet defined. This study investigated the effects of wortmannin, a phosphatidylinositol-3 kinase (PI3kinase) inhibitor, on basal, ischemia- and insulin-stimulated GLUT1 redistribution. PI3kinase is known to participate in insulin-mediated GLUT4 translocation. Rat hearts were perfused with Krebs-Henseleit buffer containing 10 mmol/l glucose according to Langendorff and treated with/without 1 micromol/l wortmannin, 100 nmol/l insulin and 15 min no-flow ischemia. Relative subcellular distribution of GLUT1 protein was analysed using membrane fractionation and subsequent Western blotting. Both ischemia and insulin significantly increased the relative amount of GLUT1 in the plasma membrane (PM) compared to controls (41.6+/-2.8% in controls v 46.0+/-2.3% in ischemic and 51.4+/-3.9% in insulin hearts, both P<0.05) with a concomitant decrease of GLUT1 in intracellular membranes. However, the increases were moderate in view of the more than 2-fold stimulated GLUT4 translocation shown for ischemia and insulin. Although wortmannin completely inhibited insulin-induced GLUT1 translocation (42.0+/-2.0% GLUT1 on PM), it had no effect on the ischemia-induced translocation of GLUT1 (45. 4+/-1% GLUT1 on PM). Treatment with the inhibitor alone did not influence basal GLUT1 distribution. Results show that in the perfused rat heart, PI3 kinase is involved in the insulin-induced signaling leading to GLUT1 translocation but not in the ischemia-mediated signaling and basal GLUT1 trafficking. This suggests two different pathways for ischemia- and insulin-induced GLUT1 translocation as recently shown for GLUT4.
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PMID:Myocardial glucose transporter GLUT1: translocation induced by insulin and ischemia. 1040 51

As in adults, glucose is the predominant cerebral energy fuel for the fetus and newborn. Studies in experimental animals and humans indicate that cerebral glucose utilization initially is low and increases with maturation with increasing regional heterogeneity. The increases in cerebral glucose utilization with advancing age occurs as a consequence of increasing functional activity and cerebral energy demands. The levels of expression of the 2 primary facilitative glucose transporter proteins in brain, GLUT1 (blood-brain barrier and glia) and GLUT3 (neuronal), display a similar maturational pattern. Alternate cerebral energy fuels, specifically the ketone bodies and lactate, can substitute for glucose, especially during hypoglycemia, thereby protecting the immature brain from potential untoward effects of hypoglycemia. Unlike adults, glucose supplementation during hypoxia-ischemia is protective in the immature brain, whereas hypoglycemia is deleterious. Accordingly, glucose plays a critical role in the developing brain, not only as the primary substrate for energy production but also to allow for normal biosynthetic processes to proceed.
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PMID:Glucose metabolism in the developing brain. 1080 66

The morphological changes in the brain of diabetic rats were examined up to 8 weeks after transient forebrain ischemia produced by transient occlusion of both carotid arteries. Using histochemistry, we also examined the extent and rate of development of atrophic changes in the brain, appearance of astrocytes, activated microglia, and glucose transporter 1 (GLUT1) in streptozotocin-treated rat brains after forebrain ischemia. Atrophic changes appeared in the hippocampus in both non-diabetic-- and diabetic--ischemic groups 4 weeks after ischemia. In diabetic--ischemic rats, the atrophic changes were more severe and progressed more rapidly in the hippocampus, and were also observed in the frontal, temporal and parietal cortices, but not in any cortical areas of the non-diabetic--ischemic rats and non-ischemic--diabetic rats. We observed reduced density of GLUT1 in all cortical regions and hippocampus in ischemic-diabetic rats at 4--8 weeks, when the number of activated microglias and astroglias increased in all cortical regions. Although severe atrophic changes were observed in the gray matter, no serious injury was noted in the white matter in the diabetic-ischemic group. Our results indicate that brain ischemia in the presence of diabetes causes more severe late-onset damage culminating in brain atrophy, compared with non-diabetics.
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PMID:Progressive cortical atrophy after forebrain ischemia in diabetic rats. 1124 74

In order to gain a better understanding of tissue plasticity with aging, we investigated the adaptive responses of young and adult animals to both 7 and 28 days of hypobaric hypoxia. Senescence is associated with a decreased tolerance to hypoxia that may be related to an age-associated decline in glucose transporter system plasticity. In addition, elucidation of the factors contributing to the decreased hypoxia tolerance with aging may provide insights into ischemia for older individuals. Following 7 days of hypobaric hypoxia, soleus and plantaris muscle Glut-4 contents were increased 23-45% with a greater increase in the soleus muscle for both ages. A parallel decline in insulin receptor content was observed in both the young (soleus 56%; plantaris 74%) and adult (soleus 26%; plantaris 37%) animals over 7 days. Similar responses were observed in cardiac muscle over 7 days, with increases in content for both Glut-4 (young 25%; adult 23%) and Glut-1 (young 33%; adult 44%) and a decline in insulin receptor (young 27%; adult 15%). Following 28 days of hypobaric hypoxia, adult soleus, and both age groups plantaris muscle Glut-4 and insulin receptor contents were similar to control. However, the young soleus muscle Glut-4 and insulin receptor contents were still significantly different from control but only altered about half as much as following 7 days of exposure to hypobaric hypoxia. In contrast to what was observed for skeletal muscle, cardiac Glut-4 content was further elevated in both young (33%) and adult (44%) animals with longer exposure to hypobaric hypoxia. The young animals also showed a further decrease in heart insulin receptor content, while the adult did not. Interestingly, cardiac Glut-1 levels returned to normal values for both young and adult animals with prolonged exposure. An adaptive coregulation of Glut-4 and insulin receptor content appears to optimize the use of glucose during chronic hypobaric hypoxia within these tissues. Differences are apparent in the magnitude and time course of the response between young and adult animals.
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PMID:Aging and glucose transporter plasticity in response to hypobaric hypoxia. 1129 70

Ischemic preconditioning (IPC) refers to the ability of short periods of ischemia to make the myocardium more resistant to a subsequent ischemic insult. It is the most powerful form of endogenous protection against myocardial infarction and has been demonstrated in all species evaluated to date. However, the cellular mechanisms that drive IPC remain poorly understood. This hypothesis describes an important role for alpha(1)-adrenoreceptors in mediating IPC and discusses the underlying mechanisms by which this is likely achieved. alpha(1)-Adrenoreceptors are present in the myocardium of all mammalian species, and several lines of evidence suggest that they play an important role in mediating IPC. During periods of myocardial hypoxia/ischemia, cardiomyocytes have to rely solely on anaerobic glycolysis for energy production; for this, the cells have to depend on increased glucose entry inside the cell as well as increased glycolysis. Stimulation of alpha(1)-adrenoreceptors increases glucose transport inside the cardiomyocytes by translocating glucose transporter (GLUT)-1 and GLUT-4 from the cytoplasm to the plasma membrane, enhances glycogenolysis by activating phosphorylase kinase, increases the rate of glycolysis by activating the enzyme phosphofructokinase, reduces intracellular acidity produced during excessive glycolysis by activating the Na(+)/H(+) exchanger, and inhibits apoptosis by increasing the levels of the antiapoptotic protein Bcl-2. Myocardial ischemia produces an increase in the expression of alpha(1)-adrenoreceptors in cardiomyocytes, as well as increases the levels of its agonist norepinephrine by several fold. During ischemic states, upregulation of alpha(1)-adrenoreceptors and increase in norepinephrine release could be a powerful adaptive mechanism that drives IPC. An understanding into the role of alpha(1)-adrenoreceptors in mediating IPC could not only point to newer treatments for limiting myocardial damage during myocardial infarction or heart surgery, but could also help in avoiding the use of alpha(1)-antagonists in patients with ischemic heart disease.
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PMID:Protecting the myocardium from ischemic injury: a critical role for alpha(1)-adrenoreceptors? 1129 92


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