UMLS:C0027651 - FACTA Search

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Query: UMLS:C0027651 (tumor)
685,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Basal antioxidant defense levels are often aberrant in tumor cells; however, less attention has been given to differences in the way that normal and transformed cells respond to changes in oxidative stress. This study evaluated differences in the responses of various normal and transformed cell lines to different oxygen tensions. Exposure to hyperoxia generally failed to induce either the activity of GSH peroxidase (GPx) or the manganese-containing form of superoxide dismutase (MnSOD) after 48 h, although at 605 mm Hg oxygen, small inductions of MnSOD activity were observed in adult lung fibroblasts and amelanotic melanoma. Exposure to 605 mm Hg O2 for 48 h was inhibitory to GPx activity. MnSOD activity was strongly induced in virally transformed WI-38 cells by treatment with the herbicide paraquat or inhibition of GSH synthesis with BSO. In normal cells GSH concentration was proportional to ambient oxygen tension. Tumor cells exhibited greater GSH concentrations at low oxygen tensions than normal cells but were unable to increase GSH in response to elevation of oxygen tension. These results reveal differences in tumor and normal cell responses to changes in ambient oxygen tension and show that MnSOD activity is inducible when an appropriate stimulus is applied.
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PMID:Effects of oxygen on the antioxidant responses of normal and transformed cells. 1449 31

The purpose of this study was to compare the results from oxygen-induced MR-signal intensity changes with polarographic pO2 measurements in tumors. Balb-c mice with an intramuscular transplanted osteosarcoma were examined. To study the response of tumors to changes in oxygen supply, hyperoxia was induced by breathing pure oxygen for a short period. The examination of each animal started with T2* weighted MRI followed by the pO2 measurements (Eppendorf Histograph). During oxygen inhalation in all tumors, when the hypoxic tumor fraction drops, both areas of significant MR-signal intensity increase and decrease were observed in each animal.
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PMID:Comparison study of oxygen-induced MRI-signal changes and pO2 changes in murine tumors. 1456 41

Because meningiomas tend to recur after (partial) surgical resection, radiotherapy is increasingly being applied for the treatment of these tumors. Radiation dose levels are limited, however, to avoid radiation damage to the surrounding normal tissue. The radiosensitivity of tumors can be improved by increasing tumor oxygen levels. The aim of this study was to investigate if breathing a hyperoxic hypercapnic gas mixture could improve the oxygenation of meningiomas. Blood oxygen level-dependent magnetic resonance imaging and dynamic Gadolinium (Gd)-DTPA contrast-enhanced MRI were used to assess changes in tumor blood oxygenation and vascularity, respectively. Ten meningioma patients were each studied twice; without and with breathing a gas mixture consisting of 2% CO(2) and 98% O(2). Values of T(2)* and the Gd-DTPA uptake rate k(ep) were calculated under both conditions. In six tumors a significant increase in the value of T(2)* in the tumor was found, suggesting an improved tumor blood oxygenation, which exceeded the effect in normal brain tissue. Contrarily, two tumors showed a significant T(2)* decrease. The change in T(2)* was found to correlate with both k(ep) and with the change in k(ep). The presence of both vascular effects and oxygenation effects and the heterogeneous response to hypercapnic hyperoxia necessitates individual assessment of the effects of breathing a hyperoxic hypercapnic gas mixture on meningiomas. Thus, the current MRI protocol may assist in radiation treatment selection for patients with meningiomas.
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PMID:BOLD MRI response to hypercapnic hyperoxia in patients with meningiomas: correlation with Gadolinium-DTPA uptake rate. 1523 44

Chronic inflammation predisposes toward many types of cancer. Chronic bronchitis and asthma, for example, heighten the risk of lung cancer. Exactly which inflammatory mediators (e.g., oxidant species and growth factors) and lung wound repair processes (e.g., proangiogenic factors) enhance pulmonary neoplastic development is not clear. One approach to uncover the most relevant biochemical and physiological pathways is to identify genes underlying susceptibilities to inflammation and to cancer development at the same anatomic site. Mice develop lung adenocarcinomas similar in histology, molecular characteristics, and histogenesis to this most common human lung cancer subtype. Over two dozen loci, called Pas or pulmonary adenoma susceptibility, Par or pulmonary adenoma resistance, and Sluc or susceptibility to lung cancer genes, regulate differential lung tumor susceptibility among inbred mouse strains as assigned by QTL (quantitative trait locus) mapping. Chromosomal sites that determine responsiveness to proinflammatory pneumotoxicants such as ozone (O3), particulates, and hyperoxia have also been mapped in mice. For example, susceptibility QTLs have been identified on chromosomes 17 and 11 for O3-induced inflammation (Inf1, Inf2), O3-induced acute lung injury (Aliq3, Aliq1), and sulfate-associated particulates. Sites within the human and mouse genomes for asthma and COPD phenotypes have also been delineated. It is of great interest that several susceptibility loci for mouse lung neoplasia also contain susceptibility genes for toxicant-induced lung injury and inflammation and are homologous to several human asthma loci. These QTLs are described herein, candidate genes are suggested within these sites, and experimental evidence that inflammation enhances lung tumor development is provided.
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PMID:Susceptibility to neoplastic and non-neoplastic pulmonary diseases in mice: genetic similarities. 1535 60

Acute hypoxia (transient cycles of hypoxia-reoxygenation) is known to occur in solid tumors and is generally believed to be caused by tumor blood flow instabilities. It was recently demonstrated that T2*-weighted (T2*w) gradient echo (GRE) MRI is a powerful non-invasive method for investigating periodic changes in tumor pO2 and blood flow associated with acute hypoxia. Here, the possible correlation between tumor vessel immaturity, vessel functionality and T2*w GRE signal fluctuations was investigated. Intramuscularly implanted FSa II fibrosarcoma-bearing mice were imaged at 4.7 T. Maps of spontaneous fluctuations of MR signal intensity in tumor tissue during air breathing were obtained using a T2*w GRE sequence. This same sequence was also employed during air-5% CO2 breathing (hypercapnia) and carbogen breathing (hypercapnic hyperoxia) to obtain parametric maps representing vessel maturation and vessel function, respectively. Vascular density, vessel maturation and vessel perfusion were also assessed histologically by using CD31 labeling, alpha-smooth muscle actin immunoreactivity and Hoechst 33242 labeling, respectively. About 50% of the tumor fluctuations occurred in functional tumor regions (responsive to carbogen) and 80% occurred in tumor regions with immature vessels (lack of response to hypercapnia). The proportion of hypercapnia-responsive voxels were found to be twice as great in fluctuating than in non-fluctuating tumor areas (P: 0.22 vs 0.13). Similarly, the proportion of functional voxels was somewhat greater in fluctuating tumor areas (P: 0.54 vs 0.43). The mean values of MR signal changes during hypercapnia (VD) and during carbogen breathing (VF) (significant voxels only) were also larger in fluctuating than in non-fluctuating tumor areas (P < 0.05). This study demonstrated that adequate vessel functionality and advanced vessel maturation could explain at least in part the occurrence of spontaneous T2*w GRE signal fluctuations. Functionality and maturation are not required for signal fluctuations, however, because a large fraction of fluctuations could still occur in non-perfused and/or immature vessels.
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PMID:The role of vessel maturation and vessel functionality in spontaneous fluctuations of T2*-weighted GRE signal within tumors. 1641 Nov 70

Inspired oxygen, an essential therapy for cardiorespiratory disorders, has the potential to generate reactive oxygen species that damage cellular DNA. Although DNA damage is implicated in diverse pulmonary disorders, including neoplasia and acute lung injury, the type and magnitude of DNA lesion caused by oxygen in vivo is unclear. We used single-cell gel electrophoresis (SCGE) to quantitate two distinct forms of DNA damage, base adduction and disruption of the phosphodiester backbone, in the lungs of mice. Both lesions were induced by oxygen, but a marked difference between the two was found. With 40 h of oxygen exposure, oxidized base adducts increased 3- to 4-fold in the entire population of lung cells. This lesion displayed temporal characteristics (a progressive increase over the first 24 h) consistent with a direct effect of reactive oxygen species attack upon DNA. DNA strand breaks, on the other hand, occurred in < 10% of pulmonary cells, which acquired severe levels of the lesion; dividing cells were preferentially affected. Characteristics of these cells suggested that DNA strand breakage was secondary to cell death, rather than a primary effect of reactive oxygen species attack on DNA. By analysis of IL-6- and IL-11-overexpressing transgenic animals, which are resistant to hyperoxia, we found that DNA strand breaks, but not base damage, correlated with acute lung injury. Analysis of purified alveolar type 2 preparations from hyperoxic mice indicated that strand breaks preferentially affected this cell type.
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PMID:DNA damage induced by hyperoxia: quantitation and correlation with lung injury. 1657 45

NAD(P)H/NRH:quinone oxidoreductases (NQO1 and NQO2) protect against oxidative stress and neoplasia. Cross-breeding of NQO1-/- with NQO2-/- mice generated double-knockout (DKO) mice. DKO mice were born normal yet showed myelogenous hyperplasia as observed in single-knockout mice. DKO mice also showed bronchial-associated lymphoid tissue (BALT) that increased in number and size with age. BALT was absent in wild-type and single-knockout mice. Further analysis demonstrated infiltration of neutrophils and macrophages in BALT and significant increases in the serum cytokines TNFalpha, IL-6, and IL-1beta and increased expression of iNOS and higher nitric oxide in lung macrophages. The development of BALT in DKO mice presumably led to the release of cytokines and higher lung macrophage activation, because histologically spleen, thymus, and blood cultures and urine analysis showed absence of infection. Additionally, the DKO mice upon exposure to hyperoxia demonstrated severe intra-alveolar edema and perivascular inflammation and massive infiltration with neutrophils, compared with wild-type mice. These results suggest that NQO1 and NQO2 combined protect mice against lung inflammation, BALT, and hyperoxic lung injury.
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PMID:BALT development and augmentation of hyperoxic lung injury in mice deficient in NQO1 and NQO2. 1667 22

One unique feature of tumors is the presence of hypoxic regions, which occur predominantly at the tumor center. Hypoxia has a major impact on various aspects of tumor cell function and proliferation. Hypoxic tumor cells are relatively insensitive to conventional therapy owing to cellular adaptations effected by the hypoxic microenvironment. Recent efforts have aimed to alter the hypoxic state and to reverse these adaptations to improve treatment outcome. One way to increase tumor oxygen tensions is by hyperbaric oxygen (HBO) therapy. HBO therapy can influence the tumor microenvironment at several levels. It can alter tumor hypoxia, a potent stimulus that drives angiogenesis. Hyperoxia as a result of HBO also produces reactive oxygen species, which can damage tumors by inducing excessive oxidative stress. This review outlines the importance of oxygen to tumors and the mechanisms by which tumors survive under hypoxic conditions. It also presents data from both experimental and clinical studies for the effect of HBO on malignancy.
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PMID:Hyperbaric oxygen therapy for malignancy: a review. 1710 15

This study describes the biological effects of hyperoxic treatment on BT4C rat glioma xenografts in vivo with special reference to tumor growth, angiogenesis, apoptosis, general morphology and gene expression parameters. One group of tumor bearing animals was exposed to normobaric hyperoxia (1 bar, pO(2) = 1.0) and another group was exposed to hyperbaric hyperoxia (2 bar, pO(2) = 2.0), whereas animals housed under normal atmosphere (1 bar, pO(2) = 0.2) served as controls. All treatments were performed at day 1, 4 and 7 for 90 min. Treatment effects were determined by assessment of tumor growth, vascular morphology (immunostaining for von Willebrand factor), apoptosis by TUNEL staining and cell proliferation by Ki67 staining. Moreover, gene expression profiles were obtained and verified by real time quantitative PCR. Hyperoxic treatment caused a approximately 60% reduction in tumor growth compared to the control group after 9 days (p < 0.01). Light microscopy showed that the tumors exposed to hyperoxia contained large "empty spaces" within the tumor mass. Moreover, hyperoxia induced a significant increase in the fraction of apoptotic cells ( approximately 21%), with no significant change in cell proliferation. After 2 bar treatment, the mean vascular density was reduced in the central parts of the tumors compared to the control and 1 bar group. The vessel diameters were significantly reduced (11-24%) in both parts of the tumor tissue. Evidence of induced cell death and reduced angiogenesis was reflected by gene expression analyses.Increased pO(2)-levels in experimental gliomas, using normobaric and moderate hyperbaric oxygen therapy, caused a significant reduction in tumor growth. This process is characterized by enhanced cell death, reduced vascular density and changes in gene expression corresponding to these effects.
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PMID:Hyperoxia retards growth and induces apoptosis, changes in vascular density and gene expression in transplanted gliomas in nude rats. 1755 37

The mitochondrial succinate dehydrogenase (SDH) is an essential component of the electron transport chain and of the tricarboxylic acid cycle. Also known as complex II, this tetrameric enzyme catalyzes the oxidation of succinate to fumarate and reduces ubiquinone. Mutations in the human SDHB, SDHC, and SDHD genes are tumorigenic, leading to the development of several types of tumors, including paraganglioma and pheochromocytoma. The mechanisms linking SDH mutations to oncogenesis are still unclear. In this work, we used the yeast SDH to investigate the molecular and catalytic effects of tumorigenic or related mutations. We mutated Arg(47) of the Sdh3p subunit to Cys, Glu, and Lys and Asp(88) of the Sdh4p subunit to Asn, Glu, and Lys. Both Arg(47) and Asp(88) are conserved residues, and Arg(47) is a known site of cancer causing mutations in humans. All of the mutants examined have reduced ubiquinone reductase activities. The SDH3 R47K, SDH4 D88E, and SDH4 D88N mutants are sensitive to hyperoxia and paraquat and have elevated rates of superoxide production in vitro and in vivo. We also observed the accumulation and secretion of succinate. Succinate can inhibit prolyl hydroxylase enzymes, which initiate a proliferative response through the activation of hypoxia-inducible factor 1alpha. We suggest that SDH mutations can promote tumor formation by contributing to both reactive oxygen species production and to a proliferative response normally induced by hypoxia via the accumulation of succinate.
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PMID:Ubiquinone-binding site mutations in the Saccharomyces cerevisiae succinate dehydrogenase generate superoxide and lead to the accumulation of succinate. 1763 59

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