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Query: UMLS:C0017638 (
glioma
)
30,880
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Nitrous oxide irreversibly inactivates cob(I)alamin, which serves as a cofactor of the enzyme
methionine synthase
catalyzing the remethylation of homocysteine to methionine. In patients exposed to nitrous oxide, increase in plasma homocysteine is a responsive indicator of cob(I)alamin inactivation. In the present work, we measured the inactivation of
methionine synthase
and the concurrent homocysteine export rate of two murine and four human cell lines during nitrous oxide exposure. When cultured in a standard medium with high content (2.3 microM) of folic acid, the
methionine synthase
of all cell types was inactivated at an initial rate of 0.05 to 0.14 h-1. The inactivation curves leveled off, and a residual activity of 15 to 45% was observed after 48 h of nitrous oxide exposure. The rate and extent of the nitrous oxide-induced inactivation were markedly reduced when the cells were transferred and cultured (greater than 10 days) in a medium containing low concentration (10 nM) of 5-methyltetrahydrofolate. The
methionine synthase
inactivation increased in a dose-dependent manner when the 5-methyltetrahydrofolate content of the medium was increased from 3 nM to 2.3 microM. The inactivation of
methionine synthase
was associated with a marked enhancement of homocysteine export rate of murine fibroblasts and a moderate increase in export from two human
glioma
cell lines. In contrast, in three leukemic cell lines (murine T-lymphoma R 1.1 cells, human promyelocytic leukemia HL-60 cells and human acute myelogenous leukemia KG-1a cells), the homocysteine export rates were not increased during nitrous oxide exposure. In the responsive murine fibroblasts and the
glioma
cells, the homocysteine export rate varied inversely to the changes in
methionine synthase
activity induced by nitrous oxide exposure at different concentrations of folate in the medium. The enhancement of homocysteine export rate of some cell types during nitrous oxide exposure probably reflects inhibition of homocysteine remethylation in intact cells, and highlights the utility of extracellular homocysteine as an indicator of metabolic flux through the
methionine synthase
pathway. No enhancement of homocysteine export despite inactivation of
methionine synthase
in three leukemic cell lines questions the functional state of the enzyme in these cells.
...
PMID:Homocysteine remethylation during nitrous oxide exposure of cells cultured in media containing various concentrations of folates. 160 76
We investigated the biochemical changes which accompanied the development and reversion of methionine dependence in a human
glioma
cell line GaMg. This cell line attained a higher proliferation rate and more malignant morphology with increasing passages in vitro. Early passages (P10, P25, and P45) were able to grow in a methionine-deficient medium supplemented with homocysteine (Met-Hcy+), while a later passage (P60) had lost this ability, i.e., it had become methionine-dependent. From P60 cells, a methionine-independent revertant (P60R) was established by exposing the cells to 5-aza-2-deoxycytidine, followed by culture in a Met-Hcy+ medium. In these genetically related cell lines, we investigated homocysteine remethylation and the functional state of cobalamin-dependent methionine synthase, the enzyme responsible for remethylation of homocysteine to methionine. The
methionine synthase
activity in cell extracts was similar in all cell sublines. Intact cell methionine biosynthesis and nitrous oxide-dependent homocysteine export reflect homocysteine remethylation in cells cultured in a Met-Hcy+ and methionine-containing (Met+Hcy-) medium, respectively. Both of these parameters, as well as the cellular content of the substrate 5-methyltetrahydrofolate, and the cofactor methylcobalamin, in addition to adenosylcobalamin, were high in P10, declined progressively in P45 and P60, and were restored in P60R. P25 cells had some unique features among the methionine-independent phenotypes because both homocysteine remethylation and the level of 5-methyltetrahydrofolate were low in Met+Hcy- medium. The maximal homocysteine export rate in the presence of nitrous oxide, which reflects the overall transmethylation rate, was high in P60 and even higher in P60R compared to the lower passages. The basis for development of methionine dependence during culture of this
glioma
cell line seems related to the combined effects of reduced methionine biosynthesis and an increased overall transmethylation rate. The single parameter which most closely correlated to the ability to use homocysteine for growth was methylcobalamin. These data support a model for methionine dependence, which implies impaired provision of cobalamin to
methionine synthase
.
...
PMID:Development and reversion of methionine dependence in a human glioma cell line: relation to homocysteine remethylation and cobalamin status. 806 55
Cobalamin metabolism and function were investigated at the levels from transcobalamin II (TCII) receptor to the cobalamin-dependent enzymes,
methionine synthase
and methylmalonyl-CoA mutase, in a methionine-dependent (P60) and a methionine-independent (P60H)
glioma
cell line. Using P60H as reference, the P60 cells cultured in a methionine medium had slightly lower TCII receptor activity and normal total cobalamin content, a moderately reduced microsomal and mitochondrial cobalamin(III) reductase activity but only trace amounts of the methylcobalamin and adenosylcobalamin cofactors. When transferred to a homocysteine medium without methionine, P60H cells showed a slightly enhanced TCII receptor activity, but the other cobalamin-related functions were essentially unchanged. In contrast, the methionine-dependent P60 cells responded to homocysteine medium with a nearly 6-fold enhancement of TCII receptor expression and a doubling of both the hydroxycobalamin content and the microsomal reductase activity. The mitochondrial reductase and the cobalamin-related processes further down the pathway did not change markedly. In both cell lines, TCII receptor activity was further increased when growth in homocysteine medium was combined with N2O exposure. These data suggest that low methionine and/or high homocysteine exert a positive feedback control on TCII receptor activity. The concurrent increase in hydroxycobalamin content and in microsomal reductase activity are either subjected to similar regulation or secondary to increased cobalamin transport. This regulatory network is most prominent in the methionine-dependent P60 cells harboring a disruption of the network in the proximity of cobalamin(III) reductase.
...
PMID:Disruption of a regulatory system involving cobalamin distribution and function in a methionine-dependent human glioma cell line. 968 64
We investigated the co-ordinate variations of the two cobalamin (Cbl)-dependent enzymes,
methionine synthase
(MS) and methylmalonyl-CoA mutase (MCM), and measured the levels of their respective cofactors, methylcobalamin (CH3Cbl) and adenosylcobalamin (AdoCbl) in cultured human
glioma
cells during nitrous oxide exposure and during a subsequent recovery period of culture in a nitrous oxide-free atmosphere (air). In agreement with published data, MS as the primary target of nitrous oxide was inactivated rapidly (initial rate of 0.06 h(-1)), followed by reduction of CH3Cbl (to <20%). Both enzyme activity and cofactor levels recovered rapidly when the cells were subsequently cultured in air, but the recovery was completely blocked by the protein-synthesis inhibitor, cycloheximide. During MS inactivation, there was a reduction of cellular AdoCbl and holo-MCM activity (measured in the absence of exogenous AdoCbl) to about 50% of pre-treatment levels. When the cells were transferred to air, both AdoCbl and holo-MCM activity recovered, albeit more slowly than the MS system. Notably, the regain of the holo-MCM and AdoCbl was enhanced rather than inhibited by cycloheximide. These findings confirm irreversible damage of MS by nitrous oxide; hence, synthesis of the enzyme is required to restore its activity. In contrast, restoration of holo-MCM activity is only dependent on repletion of the AdoCbl cofactor. We also observed a synchronous fluctuation in AdoCbl and the much larger hydroxycobalamin pool during the inactivation and recovery phase, suggesting that the loss and repletion of AdoCbl reflect changes in intracellular Cbl homoeostasis. Our data demonstrate that the nitrous oxide-induced changes in MS and CH3Cbl are associated with reversible changes in both MCM holoactivity and the AdoCbl level, suggesting co-ordinate distribution of Cbl cofactors during depletion and repletion.
...
PMID:Co-ordinate variations in methylmalonyl-CoA mutase and methionine synthase, and the cobalamin cofactors in human glioma cells during nitrous oxide exposure and the subsequent recovery phase. 1037 54
Folate metabolism plays an important role in carcinogenesis. To test the hypothesis that polymorphic variation in the folate metabolism genes 5,10-methylenetetrahydrofolate reductase (MTHFR),
methionine synthase
(MTRR), and methionine synthase reductase (MTR) influences the risk of primary brain tumors, we genotyped 1,005
glioma
cases, 631 meningioma cases, and 1,101 controls for the MTHFR C677A and A1298C, MTRR A66G, and MTR A2756G variants. MTHFR C677T-A1298C diplotypes were associated with risk of meningioma (P = 0.002) and
glioma
(P = 0.02); risks were increased with genotypes associated with reduced MTHFR activity. The highest risk of meningioma was associated with heterozygosity for both MTHFR variants [odds ratio (OR), 2.11; 95% confidence interval (95% CI), 1.42-3.12]. The corresponding OR for
glioma
was 1.23 (95% CI, 0.91-1.66). A significant association between risk of meningioma and homozygosity for MTRR 66G was also observed (OR, 1.41; 95% CI, 1.02-1.94). Our findings provide support for the role of folate metabolism in the development of primary brain tumors. In particular, genotypes associated with increased 5,10-methylenetetrahydrofolate levels are associated with elevated risk.
...
PMID:Functional polymorphisms in folate metabolism genes influence the risk of meningioma and glioma. 1848 42
