Activation of mitochondrial energy metabolism protects against cardiac failure.
about
Transition metals and mitochondrial metabolism in the heartHormesis in aging and neurodegeneration-a prodigy awaiting dissectionOptimization of cardiac metabolism in heart failurePotential biomarkers in mouse myocardium of doxorubicin-induced cardiomyopathy: a metabonomic method and its applicationOverexpression of human and fly frataxins in Drosophila provokes deleterious effects at biochemical, physiological and developmental levelsRhTFAM treatment stimulates mitochondrial oxidative metabolism and improves memory in aged miceHigh-fat feeding-induced hyperinsulinemia increases cardiac glucose uptake and mitochondrial function despite peripheral insulin resistance.Mitochondrial Fe-S cluster biogenesis, frataxin and the modulation of susceptibility to drug-induced cardiomyopathy.The functions of cardiolipin in cellular metabolism-potential modifiers of the Barth syndrome phenotypeIntegromics network meta-analysis on cardiac aging offers robust multi-layer modular signatures and reveals micronome synergism.Doxorubicin and NRG-1/erbB4-Deficiency Affect Gene Expression Profile: Involving Protein Homeostasis in Mouse.Loss of cardiolipin leads to perturbation of mitochondrial and cellular iron homeostasisNRF2 and the Phase II Response in Acute Stress Resistance Induced by Dietary Restriction.Mechanistic or mammalian target of rapamycin (mTOR) may determine robustness in young male mice at the cost of accelerated aging.A proteomic view of isoproterenol induced cardiac hypertrophy: prohibitin identified as a potential biomarker in rats.Mitochondrial hormesis links low-dose arsenite exposure to lifespan extension.Oxidative stress and anti-oxidant enzyme activities in the trophocytes and fat cells of queen honeybees (Apis mellifera)Mitochondria in cardiac hypertrophy and heart failure.Oxidative stress and β-amyloid protein in Alzheimer's disease.Endoplasmic reticulum and the unfolded protein response: dynamics and metabolic integrationHeme Oxygenase-1 and Carbon Monoxide in the Heart: The Balancing Act Between Danger Signaling and Pro-Survival.Diabetes Increases Cryoinjury Size with Associated Effects on Cx43 Gap Junction Function and Phosphorylation in the Mouse Heart.Cardioprotective mIGF-1/SIRT1 signaling induces hypertension, leukocytosis and fear response in miceMössbauer Spectra of Mouse Hearts Reveal Age-dependent Changes in Mitochondrial and Ferritin Iron Levels.Overexpression of Drosophila frataxin triggers cell death in an iron-dependent manner.Transcriptional response of skeletal muscle to a low-protein gestation diet in porcine offspring accumulates in growth- and cell cycle-regulating pathways.A Review on the Effect of Traditional Chinese Medicine Against Anthracycline-Induced Cardiac Toxicity.Drosophila melanogaster Models of Friedreich's Ataxia.Frataxin overexpression in Müller cells protects retinal ganglion cells in a mouse model of ischemia/reperfusion injury in vivo.Tissue-dependent changes in oxidative damage with male reproductive effort in house mice
P2860
Q26999334-32233DF3-001D-4239-B11A-AE8473F08C7BQ27003901-F521A7CF-8376-4F17-B38A-F39A0AE7C2B6Q27023021-9F527C7A-64CC-4066-B2A0-69B2467A2D09Q28478019-82EDED18-D296-4E5B-B1E2-A401EB9239EFQ28479044-F880C13E-6AE3-4D2D-93F8-27638E6E6C4BQ30423960-C2B3357A-8CFA-4692-A6FA-875A57215E43Q33584533-B50BDF22-BDF7-410C-ADB7-BFD53E4F8179Q34424872-2F0FDF69-C947-437A-A0D0-A82EC1DB00DFQ35128445-071AE539-9FBC-42EE-919E-6EAEB5AF67E7Q35200924-B88D3D93-BC76-4413-A8DF-429B66E99991Q36219633-2D781285-7BF5-45CF-B016-F289CBDB0FC5Q36543745-08A124A8-2B5D-4B41-9792-963AC9D51F66Q36678635-1FE820C5-AEBC-4129-A4B0-0566816C646BQ36736362-D39A0416-F031-4856-ADE6-1A256C0796F4Q36885466-24C29481-FD96-4A1F-B616-2B1CB0D16AB6Q37005002-BA0F9AE7-49A8-4297-BDE7-A4C5223D4D63Q37101981-A2FE1465-2B21-41BC-8F43-C74FC6F848EAQ37246892-0864235E-261D-4F3A-A761-02606F7B5B8DQ37928994-0CE70411-A6D5-4B98-ADC5-EBBE5CAFB0AFQ38073952-15B0930F-2B4B-465B-A9D3-35B6BAF76225Q38860810-F688CF22-306B-4F44-802C-D3B0CE6DA41AQ39394316-57F8888B-A097-4ADC-BB0B-FE5F575015F9Q42127258-68FD8AD4-EDF9-4E0E-B628-5EA12CE47F2BQ46417381-3DA06D12-289A-4FC7-8110-7CD85AE8EF1AQ47793738-32CD33A7-42A5-4757-B4A0-4F49F7070037Q50797977-9421F782-17E9-457D-9630-BC0A9142E15BQ54942355-0DD687CB-E684-48D9-9D8B-D1FDFE17C5CFQ55073764-8A12A6B8-CE07-4E42-8DCC-30D6CDB02B1FQ55287152-6583AE5C-CD89-464F-B9F1-3C95E56872F0Q58023411-75817EE1-B833-4035-B697-672418229E65
P2860
Activation of mitochondrial energy metabolism protects against cardiac failure.
description
2010 nî lūn-bûn
@nan
2010 թուականի Նոյեմբերին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի նոյեմբերին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Activation of mitochondrial energy metabolism protects against cardiac failure.
@ast
Activation of mitochondrial energy metabolism protects against cardiac failure.
@en
Activation of mitochondrial energy metabolism protects against cardiac failure.
@nl
type
label
Activation of mitochondrial energy metabolism protects against cardiac failure.
@ast
Activation of mitochondrial energy metabolism protects against cardiac failure.
@en
Activation of mitochondrial energy metabolism protects against cardiac failure.
@nl
prefLabel
Activation of mitochondrial energy metabolism protects against cardiac failure.
@ast
Activation of mitochondrial energy metabolism protects against cardiac failure.
@en
Activation of mitochondrial energy metabolism protects against cardiac failure.
@nl
P2093
P2860
P50
P356
P1433
P1476
Activation of mitochondrial energy metabolism protects against cardiac failure.
@en
P2093
Andreas F H Pfeiffer
Anja Voigt
Beate Laube
Carsten Tschöpe
Dirk Westermann
Frank Isken
Lutz Schomburg
Tim J Schulz
P2860
P304
P356
10.18632/AGING.100234
P577
2010-11-01T00:00:00Z