about
Adipocytes arise from multiple lineages that are heterogeneously and dynamically distributed.Highly selective in vivo labeling of subcutaneous white adipocyte precursors with Prx1-CrePTEN loss in the Myf5 lineage redistributes body fat and reveals subsets of white adipocytes that arise from Myf5 precursors.Adipose tissue mTORC2 regulates ChREBP-driven de novo lipogenesis and hepatic glucose metabolismEmerging Complexities in Adipocyte Origins and Identity.Role of LXR in trout adipocytes: target genes, hormonal regulation, adipocyte differentiation and relation to lipolysis.Rictor/mTORC2 loss in the Myf5 lineage reprograms brown fat metabolism and protects mice against obesity and metabolic diseaseEndocrine control of oleic acid and glucose metabolism in rainbow trout (Oncorhynchus mykiss) muscle cells in culture.Growth and nutrient utilisation of blackspot seabream (Pagellus bogaraveo) under different feeding regimes.Brown Fat AKT2 Is a Cold-Induced Kinase that Stimulates ChREBP-Mediated De Novo Lipogenesis to Optimize Fuel Storage and Thermogenesis.IGF-I binding and receptor signal transduction in primary cell culture of muscle cells of gilthead sea bream: changes throughout in vitro development.Insulin, IGF-I, and muscle MAPK pathway responses after sustained exercise and their contribution to growth and lipid metabolism regulation in gilthead sea bream.Adiponectin effects and gene expression in rainbow trout: an in vivo and in vitro approach.Regulation of lipid metabolism and peroxisome proliferator-activated receptors in rainbow trout adipose tissue by lipolytic and antilipolytic endocrine factors.Regulation of LXR by fatty acids, insulin, growth hormone and tumor necrosis factor-α in rainbow trout myocytes.Brown Adipose Tissue Development and MetabolismEnzyme promiscuity drives branched-chain fatty acid synthesis in adipose tissuesGlycemic and insulin responses in white sea bream Diplodus sargus, after intraperitoneal administration of glucoseBrown fat organogenesis and maintenance requires AKT1 and AKT2A Brain-Melanocortin-Vagus Axis Mediates Adipose Tissue Expansion Independently of Energy Intake.mTORC1 gRABs the GolgiInflammation and Immunity: From an Adipocyte's PerspectiveNon-canonical mTORC2 Signaling Regulates Brown Adipocyte Lipid Catabolism through SIRT6-FoxO1Adaptive Thermogenesis in Mice Is Enhanced by Opsin 3-Dependent Adipocyte Light Sensing
P50
Q33788728-D400054F-DCA6-453B-8C29-DEDD7DCB849FQ35453571-58541198-BD46-4195-BE18-286541B8B99FQ36368511-83EA5149-3586-4CF2-AC4A-8DBE2275FD46Q36834656-941FA84E-57C9-4C8A-AFB8-265CB3D23BFCQ36835032-CEC5B143-660C-469C-83D3-D8B27958C490Q42506947-4E7CB5BA-BEBF-401D-BB3E-DE4A1607E1ECQ42734497-53066780-7C0B-4DA9-B47A-E1E9718F6E35Q43059423-6FB1B864-B836-410C-AD67-B63FCA4BF621Q43129953-F9F6253D-D98F-4497-963C-3CD6AE347ABEQ46164742-8B5CDA67-9FA8-4B34-9B8C-EAA8049DB941Q46947086-1E41FD39-9826-49FB-9403-DDD9489872A9Q50486381-75C60AC2-E1FA-4B66-A11C-1556F6B3D651Q50514628-047A008D-72FF-4E8C-B078-91E5A343DFE2Q51309303-01E3C526-0CF3-47EC-8344-E9F28E6FE688Q51865418-58AF5D9D-6931-45B1-862F-5D2725CE77F3Q57158403-87B91464-0A08-4515-894B-5A55B54F9B20Q57452396-EFA7BE91-1F19-4268-B2FD-5E0EA82743F1Q60330517-D702ED3D-4D1B-4306-A43F-84E2A4745322Q64040124-76F48CAE-C58C-4944-8E4B-14066B7588EFQ64912883-05237722-C502-4707-A1AF-C09FCD66CF50Q86320347-210D9BDD-0FDB-44D3-BDF9-C63199CC8030Q92670244-A3689869-6CCA-469F-896D-D906733DAE8AQ92817679-C4782A18-D45B-4B16-B9D3-79313F449D78Q92851807-830E4176-6B16-4FE5-9283-D515370A51B8
P50
description
researcher (ORCID 0000-0003-1854-7832)
@en
wetenschapper
@nl
name
Juan Sánchez-Gurmaches
@en
Juan Sánchez-Gurmaches
@nl
type
label
Juan Sánchez-Gurmaches
@en
Juan Sánchez-Gurmaches
@nl
prefLabel
Juan Sánchez-Gurmaches
@en
Juan Sánchez-Gurmaches
@nl
P106
P31
P496
0000-0003-1854-7832