Christoph Handschin
Handschin, Christoph 1973-
Handschin, Christoph, 19..-....
VIAF ID: 316034185 (Personal)
Permalink: http://viaf.org/viaf/316034185
Preferred Forms
- 100 0 _ ‡a Christoph Handschin
- 100 1 _ ‡a Handschin, Christoph ‡d 1973-
- 100 1 _ ‡a Handschin, Christoph, ‡d 19..-....
4xx's: Alternate Name Forms (5)
5xx's: Related Names (1)
Works
Title | Sources |
---|---|
Anaerobic glycolysis maintains the glomerular filtration barrier independent of mitochondrial metabolism and dynamics | |
ApoE-/- PGC-1α-/- mice display reduced IL-18 levels and do not develop enhanced atherosclerosis | |
BDNF is a mediator of glycolytic fiber-type specification in mouse skeletal muscle | |
Caloric restriction and exercise "mimetics'': Ready for prime time? | |
Complex Coordination of Cell Plasticity by a PGC-1α-controlled Transcriptional Network in Skeletal Muscle | |
A conserved nuclear receptor consensus sequence (DR-4) mediates transcriptional activation of the chicken CYP2H1 gene by phenobarbital in a hepatoma cell line. | |
Contrôle de la masse des cellules bêta et de l'homéostasie du glucose par CaMK1 D. | |
Coordinated balancing of muscle oxidative metabolism through PGC-1α increases metabolic flexibility and preserves insulin sensitivity. | |
Coregulator-mediated control of skeletal muscle plasticity - A mini-review | |
The corepressor NCoR1 antagonizes PGC-1α and estrogen-related receptor α in the regulation of skeletal muscle function and oxidative metabolism | |
CXR, a chicken xenobiotic-sensing orphan nuclear receptor, is related to both mammalian pregnane X receptor (PXR) and constitutive androstane receptor (CAR) | |
Differential response of skeletal muscles to mTORC1 signaling during atrophy and hypertrophy. | |
Distinct and additive effects of calorie restriction and rapamycin in aging skeletal muscle | |
Effect of carnitine, acetyl-, and propionylcarnitine supplementation on the body carnitine pool, skeletal muscle composition, and physical performance in mice | |
Electric pulse stimulation of cultured murine muscle cells reproduces gene expression changes of trained mouse muscle | |
Endocrine Crosstalk Between Skeletal Muscle and the Brain | |
Erralpha and Gabpa/b specify PGC-1alpha-dependent oxidative phosphorylation gene expression that is altered in diabetic muscle | |
Exercise-linked improvement in age-associated loss of balance is associated with increased vestibular input to motor neurons | |
Exploring the Role of PGC-1α in Defining Nuclear Organisation in Skeletal Muscle Fibres | |
External physical and biochemical stimulation to enhance skeletal muscle bioengineering | |
For a pragmatic approach to exercise studies | |
A functional motor unit in the culture dish: co-culture of spinal cord explants and muscle cells. | |
A fundamental system of cellular energy homeostasis regulated by PGC-1alpha | |
The Genomic Context and Corecruitment of SP1 Affect ERRα Coactivation by PGC-1α in Muscle Cells. | |
A high-mobility, low-cost phenotype defines human effector-memory CD8+ T cells. | |
How Epigenetic Modifications Drive the Expression and Mediate the Action of PGC-1α in the Regulation of Metabolism | |
Hyperlipidemic effects of dietary saturated fats mediated through PGC-1beta coactivation of SREBP. | |
In silico approaches, and in vitro and in vivo experiments to predict induction of drug metabolism. | |
Injected Human Muscle Precursor Cells Overexpressing PGC-1α Enhance Functional Muscle Regeneration after Trauma. | |
Loss of Renal Tubular PGC-1α Exacerbates Diet-Induced Renal Steatosis and Age-Related Urinary Sodium Excretion in Mice | |
LXR deficiency and cholesterol feeding affect the expression and phenobarbital-mediated induction of cytochromes P450 in mouse liver | |
Magnetic stimulation supports muscle and nerve regeneration after trauma in mice | |
MicroRNAs emerge as modulators of NAD+-dependent energy metabolism in skeletal muscle | |
Moderate Modulation of Cardiac PGC-1α Expression Partially Affects Age-Associated Transcriptional Remodeling of the Heart. | |
Modulation of PGC-1α activity as a treatment for metabolic and muscle-related diseases. | |
Molecular cloning and characterization of chicken orphan nuclear receptor cTR2. | |
Morphological and functional remodelling of the neuromuscular junction by skeletal muscle PGC-1α | |
mTORC2 sustains thermogenesis via Akt-induced glucose uptake and glycolysis in brown adipose tissue | |
Multiple enhancer units mediate drug induction of CYP2H1 by xenobiotic-sensing orphan nuclear receptor chicken xenobiotic receptor | |
Muscle PGC-1α is required for long-term systemic and local adaptations to a ketogenic diet in mice | |
Muscle PGC-1α modulates satellite cell number and proliferation by remodeling the stem cell niche. | |
Muscle Wasting Diseases: Novel Targets and Treatments | |
Myoblasts inhibit prostate cancer growth by paracrine secretion of tumor necrosis factor-α. | |
Myopathy caused by mammalian target of rapamycin complex 1 (mTORC1) inactivation is not reversed by restoring mitochondrial function | |
The neuromuscular junction is a focal point of mTORC1 signaling in sarcopenia | |
Noninvasive PET Imaging and Tracking of Engineered Human Muscle Precursor Cells for Skeletal Muscle Tissue Engineering | |
NUBIScan, an in silico approach for prediction of nuclear receptor response elements | |
Nutritional regulation of hepatic heme biosynthesis and porphyria through PGC-1alpha | |
Over-expression of a retinol dehydrogenase (SRP35/DHRS7C) in skeletal muscle activates mTORC2, enhances glucose metabolism and muscle performance. | |
Partnership of PGC-1alpha and HNF4alpha in the regulation of lipoprotein metabolism | |
PDE2 activity differs in right and left rat ventricular myocardium and differentially regulates β2 adrenoceptor-mediated effects. | |
The peroxisome proliferator-activated receptor γ coactivator 1α/β (PGC-1) coactivators repress the transcriptional activity of NF-κB in skeletal muscle cells. | |
The PGC-1 coactivators promote an anti-inflammatory environment in skeletal muscle in vivo | |
PGC-1alpha regulates the neuromuscular junction program and ameliorates Duchenne muscular dystrophy. | |
PGC-1α affects aging-related changes in muscle and motor function by modulating specific exercise-mediated changes in old mice. | |
PGC-1α and exercise in the control of body weight. | |
PGC-1α and myokines in the aging muscle - a mini-review. | |
PGC-1α determines light damage susceptibility of the murine retina | |
PGC-1α expression in murine AgRP neurons regulates food intake and energy balance. | |
PGC-1α improves glucose homeostasis in skeletal muscle in an activity-dependent manner. | |
PGC-1α modulates necrosis, inflammatory response, and fibrotic tissue formation in injured skeletal muscle | |
Pharmacological targeting of exercise adaptations in skeletal muscle: Benefits and pitfalls. | |
Plasticity of the Muscle Stem Cell Microenvironment. | |
RANTES (regulated on activation, normal T cell expressed and secreted), inflammation, obesity, and the metabolic syndrome | |
Regulatory network of lipid-sensing nuclear receptors: roles for CAR, PXR, LXR, and FXR. | |
Relation of nNOS isoforms to mitochondrial density and PGC-1alpha expression in striated muscles of mice. | |
Remodeling of calcium handling in skeletal muscle through PGC-1α: impact on force, fatigability, and fiber type | |
Rôle des co-régulateurs PGC-1ß et TIF2 dans la fonction du muscle squelettique chez la souris. | |
Role of Nuclear Receptors in Exercise-Induced Muscle Adaptations. | |
Skeletal muscle as an endocrine organ: PGC-1α, myokines and exercise | |
Skeletal muscle fiber-type switching, exercise intolerance, and myopathy in PGC-1alpha muscle-specific knock-out animals | |
Skeletal muscle PGC-1α modulates systemic ketone body homeostasis and ameliorates diabetic hyperketonemia in mice | |
Skeletal muscle PGC-1α1 reroutes kynurenine metabolism to increase energy efficiency and fatigue-resistance | |
Species-specific mechanisms for cholesterol 7alpha-hydroxylase (CYP7A1) regulation by drugs and bile acids. | |
Suppression of mitochondrial respiration through recruitment of p160 myb binding protein to PGC-1alpha: modulation by p38 MAPK | |
Suppression of reactive oxygen species and neurodegeneration by the PGC-1 transcriptional coactivators | |
Transcriptional coactivator PGC-1 alpha controls the energy state and contractile function of cardiac muscle. | |
The transcriptional coactivator PGC-1α is dispensable for chronic overload-induced skeletal muscle hypertrophy and metabolic remodeling | |
Transcriptional network analysis in muscle reveals AP-1 as a partner of PGC-1α in the regulation of the hypoxic gene program |