about
A New Role for Browning as a Redox and Stress Adaptive Mechanism?RSK phosphorylates SOS1 creating 14-3-3-docking sites and negatively regulating MAPK activationAn enhanced immune response of Mclk1⁺/⁻ mutant mice is associated with partial protection from fibrosis, cancer and the development of biomarkers of aging.Plasticity of adipose tissue: a promising therapeutic avenue in the treatment of cardiovascular and blood diseases?Identification of the ectoenzyme CD38 as a marker of committed preadipocytes.ERK1/2 phosphorylate Raptor to promote Ras-dependent activation of mTOR complex 1 (mTORC1).Regionalization of browning revealed by whole subcutaneous adipose tissue imaging.The age of heterozygosity.Inhibition of preadipocyte proliferation by mitochondrial reactive oxygen species.[Recruitment and activation of brown and/or BRITE adipocytes : potential therapeutic against metabolic diseases].Control of mitochondrial volume by mitochondrial metabolic water.Site specific alterations of adipose tissue mitochondria in 3'-azido-3'-deoxythymidine (AZT)-treated rats: an early stage in lipodystrophy?Adipose tissue proadipogenic redox changes in obesity.Differentiation of human induced pluripotent stem cells into brown and white adipocytes: role of Pax3.Mitochondrial reactive oxygen species are required for hypothalamic glucose sensing.Lactate induces FGF21 expression in adipocytes through a p38-MAPK pathway.Opioids prevent regeneration in adult mammals through inhibition of ROS productionLactate induces expression and secretion of fibroblast growth factor-21 by muscle cellsHuman adipose stromal-vascular fraction self-organizes to form vascularized adipose tissue in 3D cultures3D analysis of the whole subcutaneous adipose tissue reveals a complex spatial network of interconnected lobules with heterogeneous browning abilitySite specific changes of redox metabolism in adipose tissue of obese Zucker rats[Physiological and physiopathological consequences of mitochondrial reactive oxygen species]Preconditioning by mitochondrial reactive oxygen species improves the proangiogenic potential of adipose-derived cells-based therapyBrowning of white adipose cells by intermediate metabolites: an adaptive mechanism to alleviate redox pressureThe emerging roles of lactate as a redox substrate and signaling molecule in adipose tissuesShort exposure to cold atmospheric plasma induces senescence in human skin fibroblasts and adipose mesenchymal stromal cells
P50
Q26779252-8B3DD94F-EC45-48A3-ABA3-F643902341DFQ28271724-FCB02589-4865-4442-8FC2-7A9CBD90A705Q34482592-D613DB3B-68E9-44D7-8A5F-F98ABDEF68D6Q36289215-58CCEFFE-0449-491A-A14D-40B249171890Q38726949-9E8BFAA6-BEBE-4550-BD2F-12BBD37E90DCQ39632887-27A83583-A1FC-4D4E-B4CC-2BB77CC4493EQ39901726-CCA0EBFF-D21F-44AB-8C8A-9ACF1DEB0635Q40278596-1C24E7D7-CB4C-4A66-8444-34961F015EEFQ42797861-77F9D463-2449-4FDE-9795-C70C265A8A8AQ44995001-BD094728-BEAF-4CF7-8FEA-D299B961E637Q46104618-108E628B-0B4D-4CBC-98B7-0357589C7952Q46490877-B91C7292-EB4B-424A-BDF6-2A89124E4002Q46868123-5658EB22-799E-47C9-A04E-1C22E72E9E48Q46988067-E039D10B-A6FE-46EC-80AE-002438464F96Q48486223-EFBC7492-E4B0-4F44-AAF4-CA66B6DDAF13Q51290945-3BB23366-F379-42B1-946B-44ECBD7F48CBQ58778611-44D71FAF-2FE0-4780-884E-944EA0564B09Q60636787-9EDDD69E-EF6E-4B9D-9F7D-3A2841DBE619Q64059040-1B63468C-B073-4CC5-BDB6-3E4A90531F2FQ64080396-94B1D906-902B-4047-B121-3D551CADBE61Q79349171-39EAAD34-B4E1-4905-B94D-DB39DF9D0386Q82136537-516EA96B-2554-44C3-ABEC-842C5F068438Q83787143-6B07CE98-3D11-4456-BB4B-BC66C9365B5EQ87798042-AC107EC7-238E-4BD7-8EFB-CAD227AB1C3AQ92388645-BA7D7E69-BBC6-421D-9078-76A69CDF1C00Q92826446-314E2A6A-BA15-4EFF-A1F7-0A99D2D9405B
P50
description
researcher
@en
wetenschapper
@nl
name
Audrey Carrière
@en
Audrey Carrière
@nl
type
label
Audrey Carrière
@en
Audrey Carrière
@nl
prefLabel
Audrey Carrière
@en
Audrey Carrière
@nl
P106
P108
P31
P496
0000-0002-4277-7905