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Query: UMLS:C0022116 (
ischemia
)
91,303
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We have cloned and sequenced a full length rabbit
GLUT
1 and partial rabbit
GLUT
3 cDNAs. The derived rabbit
GLUT
3 peptide revealed 84% homology to the mouse, 82% to the rat, human, dog, and sheep, and 69% to the chicken
GLUT
3 peptides. Using Northern blot analysis, we investigated the tissue and brain cellular distribution of
GLUT
1 and
GLUT
3 expression. In addition, we examined the effect of development and hypoxic-
ischemia
upon brain
GLUT
1 and
GLUT
3 mRNA levels. While
GLUT
1 mRNA was observed in most tissues,
GLUT
3 was expressed predominantly in the brain, placenta, stomach, and lung with minor amounts in the heart, kidney and skeletal muscle. In the brain, both
GLUT
1 and
GLUT
3 were noted in neuron- and glial-enriched cultures. Both
GLUT
1 and
GLUT
3 mRNA levels demonstrated a similar developmental progression (p<0.05) secondary to post-transcriptional mechanisms. Further, while hypoxic-
ischemia
did not significantly affect brain
GLUT
1 mRNA and protein, it altered
GLUT
3 mRNA levels in a region-specific manner, with a three-fold increase in the cerebral cortex, a two-fold increase in the hippocampus, and a 50% increase in the caudate nucleus (p<0.05). We conclude, that the rabbit
GLUT
3 peptide sequence exhibits 82-84% homology to that of other species in the coding region with a 62-89% sequence identity in the 3'-untranslated region. The tissue-specific expression of rabbit
GLUT
3 mimics that of the human closely. Postnatal development and hypoxic-
ischemia
with reperfusion injury cause an increase in brain
GLUT
3 expression, as a response to synaptogenesis and substrate deprivation, respectively.
...
PMID:Effect of development and hypoxic-ischemia upon rabbit brain glucose transporter expression. 1009 18
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.
...
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.
...
PMID:Myocardial glucose transporter GLUT1: translocation induced by insulin and ischemia. 1040 51
Myocardial glucose utilization increases in response to the energetic stress imposed on the heart by exercise, pressure overload, and myocardial ischemia. Recruitment of glucose transport proteins is the cellular mechanism by which the heart increases glucose transport for subsequent metabolism. Moderate regional
ischemia
leads to the translocation of both glucose transporters, GLUT4 and
GLUT1
, to the sarcolemma in vivo. Myocardial ischemia also stimulates 5'-adenosine monophosphate-activated protein kinase, which may be a fuel gauge in the heart and other tissues signaling the need to turn on energy-generating metabolic pathways. Pharmacologic stimulation of this kinase increases cardiac glucose uptake and transporter translocation, suggesting that it may play an important role in augmenting glucose entry in the setting of ischemic or energetic stress. Thus, recent work has provided insight into the cellular and molecular mechanisms responsible for glucose uptake during energetic stress, which may lead to new approaches to the treatment of patients with coronary artery disease.
...
PMID:Regulation of myocardial glucose uptake and transport during ischemia and energetic stress. 1075 May 83
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.
...
PMID:Glucose metabolism in the developing brain. 1080 66
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
.
...
PMID:Expression of glucose transporter GLUT3 by endotoxin in cultured rat astrocytes: the role of nitric oxide. 1159 53
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
.
...
PMID:Glucose uptake and adenoviral mediated GLUT1 infection decrease hypoxia-induced HIF-1alpha levels in cardiac myocytes. 1223 75
Recent studies indicate a key role of aquaporin (AQP) 4 in astrocyte swelling and brain edema and suggest that AQP4 inhibition may be a new therapeutic way for reducing cerebral water accumulation. To understand the physiological role of AQP4-mediated astroglial swelling, we used 21-nucleotide small interfering RNA duplexes (siRNA) to specifically suppress AQP4 expression in astrocyte primary cultures. Semiquantitative RT-PCR experiments and Western blot analysis showed that AQP4 silencing determined a progressive and parallel reduction in AQP4 mRNA and protein. AQP4 gene suppression determined the appearance of a new morphological cell phenotype associated with a strong reduction in cell growth. Water transport measurements showed that the rate of shrinkage of AQP4 knockdown astrocytes was one-half of that of controls. Finally, cDNA microarray analysis revealed that the gene expression pattern perturbed by AQP4 gene silencing concerned
ischemia
-related genes, such as
GLUT1
and hexokinase. Taken together, these results indicate that 1) AQP4 seems to be the major factor responsible for the fast water transport of cultured astrocytes; 2) as in skeletal muscle, AQP4 is a protein involved in cell plasticity; 3) AQP4 alteration may be a primary factor in
ischemia
-induced cerebral edema; and 4) RNA interference could be a new potent tool for studying AQP pathophysiology in those organs and tissues where they are expressed.
...
PMID:Inhibition of aquaporin-4 expression in astrocytes by RNAi determines alteration in cell morphology, growth, and water transport and induces changes in ischemia-related genes. 1282 87
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.
...
PMID:Glucose transport in the heart. 1476 60
Hibernating myocardium refers to chronically dysfunctional myocardium in patients with coronary artery disease in which cardiac viability is maintained and whose function improves after coronary revascularization. It is our hypothesis that long-term adaptive genomic mechanisms subtend the survival capacity of this ischemic myocardium. Therefore, the goal of this study was to determine whether chronic repetitive
ischemia
elicits a gene program of survival protecting hibernating myocardium against cell death. Accordingly, we measured the expression of survival genes in hibernating myocardium, both in patients surgically treated for hibernation and in a chronic swine model of repetitive
ischemia
reproducing the features of hibernation. Human hibernating myocardium was characterized by an upregulation of genes and corresponding proteins involved in anti-apoptosis (IAP), growth (VEGF, H11 kinase), and cytoprotection (HSP70, HIF-1alpha,
GLUT1
). In the swine model, the same genes and proteins were upregulated after repetitive
ischemia
, which was accompanied by a concomitant decrease in myocyte apoptosis. These changes characterize viable tissue, because they were not found in irreversibly injured myocardium. Our report demonstrates a novel mechanism by which the activation of an endogenous gene program of cell survival underlies the sustained viability of the hibernating heart. Potentially, promoting such a program offers a novel opportunity to salvage postmitotic tissues in conditions of
ischemia
.
...
PMID:Program of cell survival underlying human and experimental hibernating myocardium. 1524 71
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