UMLS:C0022116 - FACTA Search

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Query: UMLS:C0022116 (ischemia)
91,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Oxidation of biological membranes has been suggested as a major pathological process in a variety of disease states including intestinal ischemia and inflammatory bowel disease. Previous studies on the small intestinal brush border membrane have shown that part of the decrease in the activity of the Na(+)-dependent glucose transporter (SGLT1) observed after oxidation could be secondary to the derangement in membrane fluidity that accompanied oxidative damage. The present study examined the relationship between oxidative-induced hemileaflet fluidity alterations and the resultant change in Na(+)-dependent glucose transport activity. To address this issue, in vitro oxidation of guinea pig brush border membrane vesicles was induced by incubation of the vesicles with ferrous sulfate and ascorbate. We found that oxidation decreased the fluidity of both the outer and inner hemileaflets, the decrease being greater in the outer leaflet. Moreover, the preferential alteration in hemileaflet fluidity was accompanied by a decrease in glucose transport. However, when membrane perturbing agents such as hexanol and A(2)C were used to restore membrane fluidity to levels comparable to controls, rates of glucose transport could not be interpreted in terms of variation of bulk membrane fluidity or variation in fluidity of any specific membrane leaflet. On the basis of these experiments, we propose that previous studies that reported coincidental alteration in membrane fluidity and glucose transport cannot be interpreted on the basis of bulk fluidity or hemileaflet fluidity.
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PMID:Oxidative and drug-induced alterations in brush border membrane hemileaflet fluidity, functional consequences for glucose transport. 1134 71

Hypoxic preconditioning induces tolerance to hypoxic-ischemic injury in neonatal rat brain and is associated with changes in gene expression. Hypoxia-inducible factor-1 (HIF-1) is a transcription factor that is strongly induced by hypoxia or the hypoxia-mimetic compound cobalt chloride (CoCl(2)). Hypoxia-inducible factor-1 modulates the expression of several target genes including the glycolytic enzymes, glucose transporter-1 (GLUT-1), and erythropoietin. Recently, HIF-1 expression was shown to increase after hypoxic and CoCl(2) preconditioning in newborn rat brain. To study the involvement of HIF-1 target genes in neonatal hypoxia-induced ischemic tolerance, the authors examined the brains of newborn rats after exposure to hypoxia (8% O(2) for 3 hours) or injection of CoCl(2) (60 mg/kg). Preconditioning with hypoxia or CoCl(2) 24 hours before hypoxia-ischemia afforded a 96% and 76% brain protection, respectively, compared with littermate control animals. Hypoxic preconditioning increased the expression of GLUT-1 mRNA and protein, and of aldolase, phosphofructokinase, and lactate dehydrogenase proteins but not mRNA. This suggests that the modulation of glucose transport and glycolysis by hypoxia may contribute to the development of hypoxia-induced tolerance. In contrast, preconditioning with CoCl(2) did not produce any change in HIF-1 target gene expression suggesting that different molecular mechanisms may be involved in the induction of tolerance by hypoxia and CoCl(2) in newborn brain.
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PMID:Hypoxic preconditioning induces changes in HIF-1 target genes in neonatal rat brain. 1152 15

The induction of nitric oxide (NO) synthase in astrocytes by endotoxin and/or cytokine treatment is associated with increased glucose consumption and glycolysis, but the mechanism whereby this phenomenon occurs remains obscure. In this work, we have addressed this issue and found that incubation of cultured rat astrocytes with lipopolysaccharide (LPS; 1 microg/mL) for 24 h increased the level of constitutively expressed GLUT1 glucose transporter mRNA, and triggered GLUT3 mRNA expression, which was absent in normal astrocytes. The occurrence of GLUT3 protein after LPS treatment was corroborated by western blotting and immunocytochemistry. A 4-h incubation of astrocytes in the absence of glucose, or under an oxygen-poor (3%) atmosphere also resulted in GLUT3 mRNA overexpression. Experiments performed with 2-deoxy-D-[U-14C]glucose (at 0.1 mM of D-glucose) confirmed that LPS (0.1-10 microg/mL) dose-dependently increased the rate of glucose uptake (by a factor of 1.6 at 1 microg/mL of LPS), which was paralleled with the increase in NO synthesis. Furthermore, blockade of NO synthase with 2-amino-5,6-dihydro-6-methyl-(4H)-1,3-thiazine (AMT; 50 microM) partially (by 45%) prevented the LPS-mediated increase in glucose uptake. Finally, incubation of astrocytes with the NO donor 1-[2-(2-aminoethyl)-N-(2-ammonioethyl)amino]diazen-1-ium-1,2-diolate (DETA; 100 microM) increased by a factor of 1.4 the rate of glucose uptake. We conclude that the increase in GLUT3-driven glucose uptake in astrocytes would have a neuroprotective role under conditions in which NO formation is combined with hypoglycaemia, such as in brain ischemia.
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PMID:Expression of glucose transporter GLUT3 by endotoxin in cultured rat astrocytes: the role of nitric oxide. 1159 53

Repetitive myocardial ischemia increases glucose uptake, but the effect on glycogen is unclear. Thirteen swine instrumented with a hydraulic occluder on the circumflex (Cx) artery underwent 10-min occlusions twice per day for 4 days. After 24 h postfinal ischemia and in the fasted state, echocardiogram and positron emission tomography imaging for blood flow ([(13)N]-ammonia) and 2-[(18)F]fluoro-2-deoxy-D-glucose (FDG) uptake were obtained. Tissue was then collected for ATP, creatine phosphate (CP), glycogen, and glucose transporter-4 content, and hexokinase activity. After reperfusion, regional function and CP-to-ATP ratios in the Cx and remote regions were similar. Despite the absence of stunning, the Cx region demonstrated higher glycogen levels (33 +/- 11 vs. 24 +/- 11 micromol/g; P < 0.05), and this increase correlated well with the increase in FDG uptake (r(2) = 0.78; P < 0.01). Hexokinase activity was also increased relative to remote regions (0.62 +/- 0.29 vs. 0.37 +/- 0.19 IU/g; P < 0.05), with no difference in GLUT-4 content. In summary, 24 h after repetitive ischemia, glucose uptake and glycogen levels are increased at a time that functional and bioenergetic markers of stunning have recovered. The significant correlation between glycogen content and FDG accumulation in the postischemic region suggests that increased rates of glucose transport and/or phosphorylation are linked to increased glycogen levels in hearts subjected to repetitive bouts of ischemia.
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PMID:Glucose uptake and glycogen levels are increased in pig heart after repetitive ischemia. 1174 64

HIF-1 is composed of HIF-1alpha and HIF-1beta protein subunits. HIF-1 is induced by hypoxia and binds to promoter/enhancer elements and stimulates the transcription of hypoxia-inducible target genes. Because HIF-1 activation might promote cell survival in hypoxic tissues, we studied the effect of stroke on the expression of HIF-1alpha, HIF-1beta and several HIF-1 target genes in adult rat brain. After focal cerebral ischemia, mRNAs encoding HIF-1alpha, glucose transporter-1 and several glycolytic enzymes including lactate dehydrogenase were up-regulated in the areas around the infarction. HIF and its target genes were induced by 7.5 hours after the onset of ischemia and increased further at 19 and 24 hours. Since hypoxia induces HIF in other tissues, systemic hypoxia (6% O2 for 4.5 h) was also shown to increase HIF-1alpha protein expression in the adult rat brain. It is proposed that decreased blood flow to the penumbra decreases the supply of oxygen and that this induces HIF-1 and its target genes. Because HIF-1 activation may promote cell survival in hypoxic tissues, we studied the effect of hypoxic preconditioning on HIF-1 expression in neonatal rat brain. Hypoxic preconditioning (8% O2/3 hrs), a treatment known to protect the newborn rat brain against hypoxic-ischemic injury, markedly increased HIF-1alpha and HIF-1beta expression. We also studied the effect of two other known HIF-1 inducers, cobalt chloride (CoCl2) and desferrioxamine (DFX), on HIF-1 expression and neuroprotection in newborn brain. HIF-1alpha and HIF-1beta protein levels were markedly increased after i.p. injection of CoCl2 and DFX. Preconditioning with CoCl2 or DFX 24 hours before the stroke decreased infarction by 75% and 56% respectively, compared with vehicle-injected, littermate controls. Thus, HIF-1 activation could contribute to protective brain preconditioning.
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PMID:Hypoxia-inducible factor in brain. 1195 Jan 44

Hypoxia causes a large array of adaptive and physiological responses in all cells including cardiac myocytes. In order to elucidate the molecular effects of increased glucose flux on hypoxic cardiac myocytes we focused on the basic helix-loop-helix transcription factor, hypoxia inducible factor 1 alpha (HIF-1alpha), which is rapidly upregulated in hypoxic cells and elicits a number of responses including augmentation of glucose uptake. Primary cultures of neonatal rat cardiac myocytes as well as embryonic rat heart-derived myogenic H9c2 cells demonstrated a significant upregulation of HIF-1alpha when subjected to hypoxia of 6-8h in the absence of glucose. Re-addition of extracellular glucose to the medium resulted in a decrease of HIF-1alpha levels by almost 50%. This glucose effect was blocked by addition of glycolytic inhibitors. In addition, glucose uptake and glycolysis resulted in substantial decreased levels of p53, which is regulated by HIF-1alpha. Adenoviral infection of cultures of cardiac myocytes with the facilitative glucose transporter, GLUT1 followed by hypoxia of 24h also resulted in a significant reduction in the protein expression of HIF-1alpha compared to control vector-infected cultures. GLUT1 infected cultures also demonstrated fewer apoptotic cells and a reduction in the release of cytochrome c after hypoxia. Inhibition of the ubiquitin-proteasomal pathway by a variety of 26S proteasomal inhibitors increased HIF-1alpha to similar levels under both normoxic and hypoxic conditions and in the presence or absence of glucose. This result suggested that glucose induces HIF-1alpha degradation via a proteasomal pathway. This conclusion was substantiated by immunoprecipitation experiments of total cell extracts, which demonstrated an increase of ubiquitinated HIF-1alpha relative to total HIF-1alpha in the presence of glucose during hypoxia. Thus, glucose as well as GLUT1 overexpression diminishes hypoxia-induced HIF-1alpha protein via an ubiquitin-proteasomal pathway in hypoxic cardiac myocytes. This represents a novel feedback mechanism that may play an important role in adaptation of cardiac myocytes to hypoxia and ischemia.
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PMID:Glucose uptake and adenoviral mediated GLUT1 infection decrease hypoxia-induced HIF-1alpha levels in cardiac myocytes. 1223 75

The stimulation of heart glycolysis by insulin and ischemia involves the recruitment of the glucose transporter GLUT4 to the plasma membrane and the activation of 6-phosphofructo-2-kinase (PFK-2), which in turn increases the concentration of fructose 2,6-bisphosphate, a well-known stimulator of glycolysis. This review focuses on the mechanisms responsible for PFK-2 activation by insulin and ischemia in heart. Heart PFK-2 is phosphorylated by various protein kinases, including protein kinase B (PKB), thought to mediate most, if not all, short-term effects of insulin, and the AMP-activated protein kinase (AMPK), known to be activated under anaerobic conditions. We found that PKB is not required for PFK-2 activation by insulin and we partially purified an insulin-sensitive PFK-2 kinase, that differs from PKB and from other insulin-stimulated protein kinases. We also demonstrated that AMPK mediates PFK-2 activation by ischemia. Finally, our study of the interaction between the signaling pathways of insulin and ischemia revealed opposite effects on signaling. Intracellular acidosis induced by ischemia inhibited insulin signaling, whereas insulin pretreatment antagonized AMPK activation by ischemia.
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PMID:Insulin and ischemia stimulate glycolysis by acting on the same targets through different and opposing signaling pathways. 1239 81

The high energy demands of myocardium are met through the metabolism of lipids and glucose. Importantly, enhanced glucose utilization rates are crucial adaptations of the cardiac cell to some pathological conditions, such as hypertrophy and ischemia, but the effects of undernutrition on heart glucose metabolism are unknown. Our previous studies have shown that undernutrition increases insulin-induced glucose uptake by skeletal muscle. Consequently, we considered the possibility of a similar adaptation in the heart. With this aim, undernourished rats both in the basal state and after euglycemic hyperinsulinemic clamps were used to determine the following parameters in myocardium: glucose uptake, glucose transporter (GLUT) content, and some key components of the insulin signaling cascade. Heart membranes were prepared by subcellular fractionation in sucrose gradients. Although GLUT-4, GLUT-1, and GLUT-3 proteins and GLUT-4/1 mRNAs were reduced by undernutrition, basal and insulin-stimulated 2-deoxyglucose uptake were significantly enhanced. Phosphoinositol 3-kinase activity remained greater than control values in both conditions. The abundance of p85alpha and p85beta regulatory subunits of phosphoinositol 3-kinase was increased as was phospho-Akt during hyperinsulinemia. These changes seem to improve the insulin stimulus of GLUT-1 translocation, as its content was increased at the surface membrane. Such adaptations associated with undernutrition must be crucial to improvement of cardiac glucose uptake.
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PMID:Effects of chronic undernutrition on glucose uptake and glucose transporter proteins in rat heart. 1239 25

We examined the effect of hypoxic ischemia and hypoxia vs. normoxia on postnatal murine brain substrate transporter concentrations and function. We detected a transient increase in the neuronal brain glucose transporter isoform (GLUT-3) in response to hypoxic ischemia after 4 h of reoxygenation. This increase was associated with no change in GLUT-1 (blood-brain barrier/glial isoform), monocarboxylate transporter isoforms 1 and 2, synapsin I (neuronal marker), or Bax (proapoptotic protein) but with a modest increase in Bcl-2 (antiapoptotic mitochondrial protein) protein concentrations. At 24 h of reoxygenation, the increase in GLUT-3 disappeared but was associated with a decline in Bcl-2 protein concentrations and the Bcl2:Bax ratio, an increase in caspase-3 enzyme activity (apoptotic effector enzyme), and extensive DNA fragmentation, which persisted later in time (48 h) only in the hippocampus. Hypoxia alone in the absence of ischemia was associated with a transient but modest increase in GLUT-3 and synapsin I protein concentrations, which did not cause significant apoptosis and/or necrosis. Assessment of glucose transporter function by 2-deoxyglucose (2-DG) uptake using two distinct techniques, namely positron emission tomography (PET) and the modified Sokoloff method, revealed a discrepancy due to glucose uptake by extracranial Harderian glands that masked the accurate detection of intracranial brain glucose uptake by PET scanning. The modified Sokoloff method assessing 2-DG uptake revealed that the transient increase in GLUT-3 was critical in protecting against a decline in brain glucose uptake. We conclude that hypoxic-ischemic brain injury is associated with transient compensatory changes targeted at protecting glucose delivery to fuel cellular energy metabolism, which then may delay the processes of apoptosis and cell necrosis.
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PMID:Postnatal hypoxic-ischemic brain injury alters mechanisms mediating neuronal glucose transport. 1452 22

The heart is a unique organ in many ways. It consists of specialized muscle cells (cardiomyocytes), which are adapted to contract constantly in a coordinated fashion. This is vital to the survival of the organism given the central role of the heart in the maintenance of the cardiovascular system that delivers oxygen, metabolic substrates and hormones to the rest of the body. In order for the heart to maintain its function it must receive a constant supply of metabolic substrates, to generate ATP to maintain contractile function, without fatigue. Thus the heart is capable of utilizing a variety of metabolic substrates and is able to rapidly adapt its substrate utilization in the face of changes in substrate supply. The major metabolic substrate for the heart is fatty acids. However, up to 30% of myocardial ATP is generated by glucose and lactate, with smaller contributions from ketones and amino acids. Although glucose is not the major metabolic substrate in the heart at rest, there are many circumstances in which it assumes greater importance such as during ischemia, increased workload and pressure overload hypertrophy. Like all other cells, glucose is transported into cardiac myocytes by members of the family of facilitative glucose transporters (GLUTs). In this regard, cardiomyocytes bear many similarities to skeletal muscle, but there are also important differences. For example, the most abundant glucose transporter in the heart is the GLUT4 transporter, in which translocation to the plasma membrane represents an important mechanism by which the net flux of glucose into the cell is regulated. Because cardiomyocytes are constantly contracting it is likely that contraction mediated GLUT4 translocation represents an important mechanism that governs the entry of glucose into the heart. While this is also true in skeletal muscle, because many muscles are often at rest, insulin mediated GLUT4 translocation represents a quantitatively more important mechanism regulating skeletal muscle glucose uptake than is the case in the heart. In contrast to skeletal muscle, where most GLUT1 is in perineural sheaths (1), in the heart there is significant expression of GLUT1 (2), which under certain circumstances is responsible for a significant component of basal cardiac glucose uptake. This review will summarize the current state of knowledge regarding the regulation of glucose transporter expression, and the regulation of glucose transport into myocardial cells.
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PMID:Glucose transport in the heart. 1476 60

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