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)

The brain's energy metabolism is considered to be completely aerobic, with glucose as the major energy substrate for neurons during both rest and activation. This view has now been challenged, as other energy metabolites are shown to play a more important role in the brain's energy metabolism. During development of the brain both lactate and ketone bodies are used as energy substrates. Lactate and ketone bodies are shown to be important energy metabolites in situations of starvation, hypoglycemia and diabetes. During intense physical activity the brain uses lactate from the circulating blood. Lactate and other monocarboxylates cross cell membranes by interaction with specific proteins; the monocarboxylate transporters (MCTs). MCTs are trans-membrane proteins that facilitate cotransport of a monocarboxylate ion with a proton. Whether the transport goes in or out of a brain cell depends on the concentration gradient for the monocarboxylates and the pH-gradient. The brain has been shown to express three different MCTs: MCT1, MCT2 and MCT4. MCT1 is expressed in astrocytes and in microvessel endothelial cells, whilst MCT2 is concentrated in neurons and MCT4 is preferentially expressed in astrocytes. Neurons are considered to be the lactate consuming cells whereas astrocytes are the lactate producers. Lactate may be an important energy substrate for neurons, e.g. in tissue surviving ischemia.
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PMID:[Lactate in the brain--without turning sour]. 1708 41

Mesenchymal stem cells (MSCs) have been proposed for the repair of damaged tissue including bone, cartilage, and heart tissue. Upon in vivo transplantation, the MSCs encounter an ischemic microenvironment characterized by reduced oxygen (O2) tension and nutrient deprivation that may jeopardize viability of the tissue construct. The aim of this study was to assess the effects of serum deprivation and hypoxia on the MSC survival rates in vitro. As expanded MSCs are transferred from plastic to a scaffold in most tissue engineering approaches, possibly inducing loss of survival signals from matrix attachments, the effects of a scaffold shift on the MSC survival rates were also assessed. Human MSCs were exposed for 48 hours to (i) a scaffold substrate shift, (ii) serum deprivation, and (iii) O2 deprivation. MSCs were also exposed to prolonged (up to 120 hours) hypoxia associated with serum deprivation. Cell death was assessed by Live/Dead staining and image analysis. The MSC death rates were not affected by the shift to scaffold or 48-hour hypoxia, but increased with fetal bovine serum (FBS) starvation, suggesting that between the two components of ischemia, nutrient deprivation is the stronger factor. Long-term hypoxia combined with serum deprivation resulted in the complete death of MSCs (99 +/- 1%), but this rate was reduced by half when MSCs were exposed to hypoxia in the presence of 10% FBS (51 +/- 31%). These results show that MSCs are sensitive to the concurrent serum and O2 deprivation to which they are exposed when transplanted in vivo, and call for the development of new transplantation methods.
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PMID:Prolonged hypoxia concomitant with serum deprivation induces massive human mesenchymal stem cell death. 1751 49

Extracellular ATP is elevated by transient ischemia and is a potent signaling molecule in the central nervous system. ATP promotes neuron survival from serum starvation by activating P2Y purinergic receptors. ATP also activates IL-6 production and phosphorylation of Stat3 that promotes neuron survival. The transcription cofactor LMO4 is a positive mediator of IL-6/Stat3 signaling. Here, we found that LMO4 and the pro-survival factor cIAP2 (cellular inhibitor of apoptosis protein 2) are rapidly upregulated in neurons exposed to elevated extracellular ATP. Blocking LMO4 upregulation using siRNA in F11 cells blunted cIAP2 upregulation and abolished the early protective effect of ATP. Similar results were obtained using primary cortical neurons from LMO4 null mice, suggesting that LMO4 is required for ATP to protect neurons from hypoxia-induced apoptosis. Whereas increased Stat3 phosphorylation occurs after LMO4 and cIAP2 induction, the rapid upregulated phosphorylation of ERK and CREB may account for increased LMO4 and cIAP2 by ATP. ATP signaling through ERK and CREB activated LMO4 promoters and ERK activation increased LMO4 protein stability in F11 cells. Taken together, our studies reveal that LMO4 is a rapidly induced downstream effector of ATP signaling that promotes neuron survival from hypoxia.
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PMID:Extracellular ATP-dependent upregulation of the transcription cofactor LMO4 promotes neuron survival from hypoxia. 1752 92

Autophagy is a major mechanism for degrading long-lived cytosolic proteins and the only known pathway for degrading organelles. Autophagy is activated by many forms of stress, including nutrient and energy starvation, oxidative stress, mitochondrial dysfunction, endoplasmic reticulum stress, and infections. Although autophagy recycles amino acids and fatty acids to produce energy and removes damaged organelles, thereby playing an essential role in cell survival, inappropriate activation of autophagy leads to cell death. In the heart, activation of autophagy can be observed in response to nutrient starvation, ischemia/reperfusion, and heart failure. In this review, the signaling mechanism and the functional significance of autophagy during myocardial ischemia and reperfusion are discussed.
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PMID:The role of autophagy in mediating cell survival and death during ischemia and reperfusion in the heart. 1762 77

Schwannomas, particularly of vestibular origin, often accompany degenerative hypocellular areas known as Antoni B patterns; however, the detailed mechanism is uncertain. Eosinophilic hyaline droplets (EHD), the substantial nature of which are autophagic vacuoles, preferentially appear in acoustic schwannomas and distribute around areas of Antoni B. We investigated their common background using schwannomas with (15 cases) or without (10 cases) EHD, and demonstrated that EHD showed selective immunoreactivity with an anti-nitrotyrosine antibody, suggesting the overproduction of nitric oxide in this condition. The expression of inducible nitric oxide synthase was emphasized in infiltrating macrophages around hyalinized vessels. Protein-bound 4-hydroxy 2-nonenal, another oxidative stress marker, was detected in Antoni B tissue, but not in EHD. Antibodies to cleaved caspase-3 and single strand DNA, indicators of apoptosis, did not label tumors cells in Antoni B areas as well as EHD-bearing cells. The morphology and the mitotically static state of EHD-laden cells are phenotypically similar to autophagic cell death; however, autophagy in normal cells is a cell survival strategy against starvation, so the possibility remains that EHD are formed in that context. In either case, schwannomas may show a characteristic autophagic change by an endogenous mechanism. Tumor growth in a narrow intracranial space and resultant ischemia by self-oppression were postulated to be an initial event, because ischemia-reperfusion injury is a major source of reactive oxygen species and ischemia is also a potent trigger of autophagy as well as of tissue degeneration. Moreover, potential roles of chemokines and hemosiderosis are discussed.
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PMID:Oxidative stress is related to the formation of Antoni B patterns and eosinophilic hyaline droplets in schwannomas. 1764 38

The developing central nervous system has the capacity to metabolize ketone bodies. It was once accepted that on weaning, the 'post-weaned/adult' brain was limited solely to glucose metabolism. However, increasing evidence from conditions of inadequate glucose availability or increased energy demands has shown that the adult brain is not static in its fuel options. The objective of this review is to summarize the body of literature specifically regarding cerebral ketone metabolism at different ages, under conditions of starvation and after various pathologic conditions. The evidence presented supports the following findings: (1) there is an inverse relationship between age and the brain's capacity for ketone metabolism that continues well after weaning; (2) neuroprotective potentials of ketone administration have been shown for neurodegenerative conditions, epilepsy, hypoxia/ischemia, and traumatic brain injury; and (3) there is an age-related therapeutic potential for ketone as an alternative substrate. The concept of cerebral metabolic adaptation under various physiologic and pathologic conditions is not new, but it has taken the contribution of numerous studies over many years to break the previously accepted dogma of cerebral metabolism. Our emerging understanding of cerebral metabolism is far more complex than could have been imagined. It is clear that in addition to glucose, other substrates must be considered along with fuel interactions, metabolic challenges, and cerebral maturation.
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PMID:Cerebral metabolic adaptation and ketone metabolism after brain injury. 1768 14

Glial cell line-derived neurotrophic growth factor (GDNF), a member of the transforming growth factor family, is necessary for renal organogenesis and exhibits changes in expression in models of renal disease. Nestin is an intermediate filament protein originally believed to be a marker of neuroepithelial stem cells and recently proposed as a marker of mesenchymal stem cells (MSC). Having demonstrated the participation of nestin-expressing cells in renoprotection during acute renal ischemia, we hypothesized that growth factors and transcription factors similar to those operating in the nervous system should be also operant in the kidney and may be induced after noxious stimuli, such as an ischemic episode. Using cultured kidney-derived MSC, which abundantly express nestin, we confirmed expression of GDNF by these cells and demonstrated the GDNF-induced expression of GDNF. The cellular expression of nestin paralleled that of GDNF: serum starvation decreased the expression, whereas application of GDNF resulted in a dose-dependent increase in nestin expression. Immunohistochemical and Western blot analyses of kidneys obtained from control and postischemic mice showed that expression of GDNF was much enhanced in the renal cortex, a pattern similar to the previously reported expression of nestin. Based on the observed GDNF-induced GDNF expression, we next explored the effect of supplemental GDNF administered early after ischemia on renal function postischemia. GDNF-treated mice were protected against acute ischemia. To address potential mechanisms of the observed renoprotection, in vitro studies showed that GDNF accelerated MSC migration in a wound-healing assay. Hypoxia did not accelerate, but rather slightly reduced, the motility of MSC and reduced the expression of GDNF in MSC by approximately twofold. Furthermore, GDNF was cytoprotective against oxidative stress-induced apoptotic death of MSC. Collectively, these data establish 1) an autoregulatory circuit of GDNF-induced GDNF expression in renal MSC; 2) induction of GDNF expression in postischemic kidneys; 3) the ability of exogenous GDNF to ameliorate ischemic renal injury; and 4) a possible contribution of GDNF-induced motility and improved survival of MSC to renoprotection.
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PMID:Glial cell line-derived neurotrophic growth factor increases motility and survival of cultured mesenchymal stem cells and ameliorates acute kidney injury. 1800 56

During food shortage, organisms activate defense mechanisms to maximize their chance of survival. At least in part, these responses are triggered by changes in hormonal status and neural status during starvation. The hypothalamus is organized as a collection of distinct autonomously active nuclei and is considered to play crucial roles in these survival responses. To isolate factors involved in these pathways, we carried out suppression subtractive hybridization analyses using complementary DNAs (cDNA) from the hypothalami of fasted and fed rats. We identified four genes, namely ubiquitin-conjugating enzyme E2D 3 (UBE2D3), cAMP-dependent protein kinase C beta subunit (PKCbeta), excitatory amino acid carrier 1 (EAAC1), and ferritin heavy polypeptide 1 (Fth1), that were upregulated after a 48-h fast compared to the fed status. According to previous reports, these genes have been implicated in protection against neuronal cell death under various neurodegenerative stresses, such as hypoxia-ischemia and oxidative stress. Thus, the increased expressions of the genes identified in the present study may have protective effects against neural damage that could otherwise result in cell death.
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PMID:Identification of fasting-induced genes in the rat hypothalamus: relationship with neuroprotection. 1805 70

Oxygen-regulated protein 150 (ORP150) is an inducible endoplasmic reticulum (ER) chaperone molecule that is upregulated after numerous cellular insults and has a cytoprotective role in renal, neural, and cardiac models of ischemia-reperfusion injury. ORP150 also has been shown to play a role in cellular Ca(2+) homeostasis, and in turn, regulating calpain activity. In this study, we identified ORP150 in whole rat renal cortical mitochondria and matrix fractions, demonstrated the targeting of an ORP150-GFP construct to the mitochondria of NIH-3T3 cells, and showed that the NH(2)-terminal 13 amino acids of ORP150 are sufficient for this translocation. ORP150 expression was found to be regulated by the anti-C/enhancer-binding protein homologous protein (CHOP)/GADD153 transcription factor and ORP150 levels increased in the mitochondria and ER of COS-7 cells after diverse stresses, including hypoxia, serum starvation, prolyl hydroxylase inhibition with dimethyloxaloylglycine, and exposure to tunicamycin, ethidium, bromide, and 2-deoxyglucose. Induction of the mitochondrial specific stress response in COS-7 cells through expression of an ornithine transcarbamylase mutant (Delta OTC) increased mitochondrial ORP150 levels and mitochondrial calpain activity. To determine whether mitochondrial ORP150 and mitochondrial calpain 10 interact, rat cortical mitochondria exposed to Ca(2+) resulted in ORP150 cleavage in a calpain inhibitor-dependent manner, revealing that ORP150 is a substrate and may be regulated by calpain 10. These data reveal a novel cellular localization for ORP150 and that mitochondrial ORP150 is upregulated by CHOP/GADD153 in response to mitochondrial and ER stress. Our data also reveal that ORP150 is a substrate for mitochondrial calpain 10.
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PMID:Targeting of the molecular chaperone oxygen-regulated protein 150 (ORP150) to mitochondria and its induction by cellular stress. 1809 45

After stroke or traumatic damages, both necrotic and apoptotic neuronal death cause a loss of functions including memory, sensory perception, and motor skills. From the fact that necrosis has a nature to expand, while apoptosis to cease the cell death cascade in the brain, it is considered that the promising target for the rapid treatment for stroke is the necrosis. In this study, I introduce the discovery of prothymosin alpha (ProTalpha), which inhibits neuronal necrosis, and propose its potentiality of clinical use for stroke. First of all, it should be noted that ProTalpha inhibits the neuronal necrosis induced by serum-free starvation or ischemia-reperfusion stress, which causes a rapid internalization of GLUT1/4, leading a decrease in glucose uptake and cellular ATP levels. Underlying mechanisms are determined to be through an activation of Gi/o, phospholipase C and PKCbetaII. ProTalpha also causes apoptosis later through a similar mechanism. However, we found that ProTalpha-induced apoptosis is completely inhibited by the concomitant treatment with neurotrophins, which are up-regulated by ischemic stress in the brain. Of most importance is the finding that the systemic injection of ProTalpha completely inhibits the brain damages, motor dysfunction and learning memory defect induced by cerebral ischemia-reperfusion stress. As ProTalpha almost entirely prevents the focal ischemia-induced motor dysfunction 4 h after the start of ischemia, this protein seems to have a promising potentiality for clinical use.
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PMID:Prothymosin alpha plays a key role in cell death mode-switch, a new concept for neuroprotective mechanisms in stroke. 1817 98

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