Mitochondrial oxidative phosphorylation is regulated by fructose 1,6-bisphosphate. A possible role in Crabtree effect induction?
about
The Warburg effect revisited--lesson from the Sertoli cellBioenergetic function in cardiovascular cells: the importance of the reserve capacity and its biological regulationPhosphate and succinate use different mechanisms to inhibit sugar-induced cell death in yeast: insight into the Crabtree effectProteomic and metabolomic analysis of the carotenogenic yeast Xanthophyllomyces dendrorhous using different carbon sourcesGlycolysis for Microbiome Generation.Integration of cellular bioenergetics with mitochondrial quality control and autophagy.Inhibition of Non-flux-Controlling Enzymes Deters Cancer Glycolysis by Accumulation of Regulatory Metabolites of Controlling StepsThe platelet isoform of phosphofructokinase contributes to metabolic reprogramming and maintains cell proliferation in clear cell renal cell carcinoma.The Randle cycle revisited: a new head for an old hat.Genetic polymorphisms in glycolytic pathway are associated with the prognosis of patients with early stage non-small cell lung cancerCancer as a metabolic disease: implications for novel therapeutics.Mitochondrial respiratory chain complexes: apoptosis sensors mutated in cancer?A flux-sensing mechanism could regulate the switch between respiration and fermentation.Defining the molecular basis of tumor metabolism: a continuing challenge since Warburg's discovery.Tumor glycolysis as a target for cancer therapy: progress and prospects.Coordination of microbial metabolism.Multi-tasking of biosynthetic and energetic functions of glycolysis explained by supply and demand logic.Hallmarks of Pulmonary Hypertension: Mesenchymal and Inflammatory Cell Metabolic Reprogramming.Hyperglycemia induced damage to mitochondrial respiration in renal mesangial and tubular cells: Implications for diabetic nephropathy.Using Gene Essentiality and Synthetic Lethality Information to Correct Yeast and CHO Cell Genome-Scale Models.Glucose modulates respiratory complex I activity in response to acute mitochondrial dysfunction.Frataxin depletion in yeast triggers up-regulation of iron transport systems before affecting iron-sulfur enzyme activitiesAssessing bioenergetic function in response to oxidative stress by metabolic profiling.Can metabolic plasticity be a cause for cancer? Warburg-Waddington legacy revisited.The trehalose pathway regulates mitochondrial respiratory chain content through hexokinase 2 and cAMP in Saccharomyces cerevisiae.Extensive exometabolome analysis reveals extended overflow metabolism in various microorganismsShort-term starvation is a strategy to unravel the cellular capacity of oxidizing specific exogenous/endogenous substrates in mitochondria.Metabolic intermediates selectively stimulate transcription factor interaction and modulate phosphate and purine pathways.Long-term adaptation of Saccharomyces cerevisiae to the burden of recombinant insulin production.Effect of fructose 1,6-bisphosphate on the iron redox state relating to the generation of reactive oxygen species.Effects of ubiquinone derivatives on the mitochondrial unselective channel of Saccharomyces cerevisiae.Fermentative metabolism impedes p53-dependent apoptosis in a Crabtree-positive but not in Crabtree-negative yeast.Metabolic Reprogramming and Redox Signaling in Pulmonary Hypertension.A genome-wide screen identifies yeast genes required for protection against or enhanced cytotoxicity of the antimalarial drug quinine.Revisiting the Crabtree/Warburg effect in a dynamic perspective: a fitness advantage against sugar-induced cell death.Inhibition by fructose 1,6-bisphosphate of transaldolase from Escherichia coli.Comparison of sildenafil with strontium fructose diphosphate in improving erectile dysfunction against upregulated cavernosal NADPH oxidase, protein kinase Cε, and endothelin system in diabetic rats.A common mechanism explains the induction of aerobic fermentation and adaptive antioxidant response in Phaffia rhodozyma.Cancer; an induced disease of twentieth century! Induction of tolerance, increased entropy and 'Dark Energy': loss of biorhythms (Anabolism v. Catabolism).Evaluation of Artificial Intelligence Architectures for Optimization of Recombinant Glucoamylase Production in a Microbioreactor
P2860
Q27025749-8152F930-2BCC-49DA-9D2A-C82C2898721AQ34961101-174C960F-609C-489C-8A71-C46EA31E5BA3Q35063325-3754E2D1-7EC4-4AE1-818B-D3E483E6A22AQ35607263-51EE7C17-AD3A-478A-9DE0-DB0BC0059A72Q35694201-4AC1A249-C7D1-4B75-BB4C-57A4D2B3639AQ36675381-341E11D1-487F-498F-96F5-212355BA5F71Q37277390-79060295-4677-4C4D-9EAE-1E25C3FE4235Q37317189-3B3EAA30-A94F-4197-B403-8002B541FE59Q37337283-D200C034-6F0E-4D15-9CE9-597DE08CFD93Q37355438-E5A66CC1-70F1-4BA4-9C6F-5678ADC1A74AQ37616057-ECF10524-A5F3-4F59-A3BA-CC1249B3A948Q37882392-A51255F5-615D-46C4-9E15-BBE7CAB212CBQ37962993-D91091AF-E7E2-4B2A-9ADE-1F9F808C6C77Q37969537-3D5F7A62-2DC0-4398-B32D-A861262303AAQ38168262-6F16A596-CD72-45F2-8052-AC6B4C00AF18Q38198495-67B9221C-7A9E-496E-9BE9-3227ADAC3BC6Q38263318-D94C8C4B-21FB-480A-9CA5-9FF492EF807FQ38668387-6D7B071D-6E6D-4739-800B-190D8EF11C52Q39316856-A2C34F63-A77F-46DA-B02B-B6EE5BE0208AQ40478667-B247C90C-D0D3-4CCD-84C4-BDD8A150FADBQ41311660-0DF76CF1-F300-482B-9232-094BE13779F8Q41466989-2D5C733C-844A-40FD-80E7-99E3941EC7C1Q41816998-46645806-ACAB-42A0-902D-A9DC5F70AB63Q41982167-32461DE0-04A9-4221-9D0B-60C661538B7CQ42188633-BE9B243A-2C1A-4819-B2BD-51B6660BFE6AQ42420527-94BD2650-8779-4AD2-B286-66880687FCE6Q42511783-F803D8C9-A213-42F6-A65E-02EC116B05A4Q43106464-0538CDDB-09DE-44B7-8AC6-7CF8F158A54FQ45324768-7B4B61A1-2759-4E7D-B039-B8CC9E53CCFBQ46733735-9C465EC5-49BB-47BC-A620-9095DB60F934Q46804140-8CBFBAB3-21FA-462F-BB6A-E8827F85791DQ47304701-F948744B-BE77-4B04-8E83-EF9E8DF31C9FQ47631019-2F75A0DF-D6B1-4B52-99D8-A122917CFE64Q47991392-B6ECE214-2421-4DBD-9CCE-68E4A2AA7445Q51149489-88407FD1-E5CF-41DC-9CB0-42A86300EB23Q52983958-C18D2928-907B-4CA2-915C-1B8A4A218E99Q54330771-1E75511F-E719-4F9C-8E9E-E2BA442ADB44Q55340047-2C2CCA0E-7287-4384-A2FF-D4688BA85B50Q55709806-0A6B8B9B-4535-491A-A2D5-A63A96737006Q58166485-1A813C1F-66CE-438E-AFC9-E6A99FAF5D37
P2860
Mitochondrial oxidative phosphorylation is regulated by fructose 1,6-bisphosphate. A possible role in Crabtree effect induction?
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年学术文章
@wuu
2008年学术文章
@zh-cn
2008年学术文章
@zh-hans
2008年学术文章
@zh-my
2008年学术文章
@zh-sg
2008年學術文章
@yue
2008年學術文章
@zh
2008年學術文章
@zh-hant
name
Mitochondrial oxidative phosph ...... in Crabtree effect induction?
@en
Mitochondrial oxidative phosph ...... in Crabtree effect induction?
@nl
type
label
Mitochondrial oxidative phosph ...... in Crabtree effect induction?
@en
Mitochondrial oxidative phosph ...... in Crabtree effect induction?
@nl
prefLabel
Mitochondrial oxidative phosph ...... in Crabtree effect induction?
@en
Mitochondrial oxidative phosph ...... in Crabtree effect induction?
@nl
P2093
P356
P1476
Mitochondrial oxidative phosph ...... in Crabtree effect induction?
@en
P2093
Anne Devin
Daniela Araiza
Michel Rigoulet
Nicole Avéret
Rodrigo Díaz-Ruiz
P304
26948-26955
P356
10.1074/JBC.M800408200
P407
P577
2008-08-05T00:00:00Z