about
Adiponectin, C1Q and collagen domain containingA disintegrin-like and metallopeptidase (reprolysin type) with thrombospondin type 1 motif, 5 (aggrecanase-2)Activin receptor IIBLeucyl/cystinyl aminopeptidaseForkhead box C2Interleukin 15A disintegrin and metallopeptidase domain 17Toll-like receptor 4Nuclear receptor subfamily 1 group D member 1Nuclear receptor subfamily 1, group D, member 1Acyl-CoA thioesterase 11Acyl-CoA thioesterase 13Actinin alpha 3Aldehyde dehydrogenase 1 family member A1Activating transcription factor 4Abhydrolase domain containing 6, acylglycerol lipaseNatriuretic peptide receptor 3Arrestin domain containing 3Inhibitor of DNA binding 1, HLH proteinMitogen-activated protein kinase kinase 6Homeobox C10Laminin subunit alpha 4Serine/threonine kinase 11Aryl hydrocarbon receptor nuclear translocator likeRB transcriptional corepressor 1Nuclear receptor subfamily 1 group H member 3Dedicator of cytokinesis 7Nuclear receptor subfamily 1 group H member 2Cell death inducing DFFA like effector aDNA damage inducible transcript 3Ras homolog, mTORC1 bindingInterleukin 18 receptor 1Leucine rich repeat containing G protein-coupled receptor 4PGAM family member 5, mitochondrial serine/threonine protein phosphataseWnt family member 10BNOVA alternative splicing regulator 2Phospholipase C like 1 (inactive)Phospholipase C like 2Transcription factor binding to IGHM enhancer 3NOVA alternative splicing regulator 1
P682
The arrestin domain-containing 3 protein regulates body mass and energy expenditureMice lacking Pctp /StarD2 exhibit increased adaptive thermogenesis and enlarged mitochondria in brown adipose tissueLkb1 controls brown adipose tissue growth and thermogenesis by regulating the intracellular localization of CRTC3FOXC2 is a winged helix gene that counteracts obesity, hypertriglyceridemia, and diet-induced insulin resistanceCidea-deficient mice have lean phenotype and are resistant to obesityThe nuclear receptor Rev-erbα controls circadian thermogenic plasticityCritical roles of nardilysin in the maintenance of body temperature homoeostasisInhibition of Notch signaling promotes browning of white adipose tissue and ameliorates obesityBoth liver-X receptor (LXR) isoforms control energy expenditure by regulating brown adipose tissue activity.Altered Ca2+ kinetics associated with α-actinin-3 deficiency may explain positive selection for ACTN3 null allele in human evolutionThe adipocyte clock controls brown adipogenesis through the TGF-β and BMP signaling pathwaysCardiac natriuretic peptides act via p38 MAPK to induce the brown fat thermogenic program in mouse and human adipocytesDeficiency of Interleukin-15 Confers Resistance to Obesity by Diminishing Inflammation and Enhancing the Thermogenic Function of Adipose Tissues.Blockade of the activin receptor IIb activates functional brown adipogenesis and thermogenesis by inducing mitochondrial oxidative metabolismActivation of Toll-like receptor 4 (TLR4) attenuates adaptive thermogenesis via endoplasmic reticulum stress.Phospholipase C-related Catalytically Inactive Protein Is a New Modulator of Thermogenesis Promoted by β-Adrenergic Receptors in Brown AdipocytesThe Ablation of Mitochondrial Protein Phosphatase Pgam5 Confers Resistance Against Metabolic Stress.Adipose subtype-selective recruitment of TLE3 or Prdm16 by PPARγ specifies lipid storage versus thermogenic gene programs.Thioesterase superfamily member 1 suppresses cold thermogenesis by limiting the oxidation of lipid droplet-derived fatty acids in brown adipose tissueChronic AMPK activation via loss of FLCN induces functional beige adipose tissue through PGC-1α/ERRα.Altered thermogenesis and impaired bone remodeling in Misty miceRetinaldehyde dehydrogenase 1 regulates a thermogenic program in white adipose tissue.An alternative splicing program promotes adipose tissue thermogenesisThioesterase superfamily member 2/Acyl-CoA thioesterase 13 (Them2/Acot13) regulates adaptive thermogenesis in mice.Deficiency of TNFalpha converting enzyme (TACE/ADAM17) causes a lean, hypermetabolic phenotype in mice.Loss of ADAMTS5 enhances brown adipose tissue mass and promotes browning of white adipose tissue via CREB signaling.Cold-induced thermogenesis in humans.Effects of ATF4 on PGC1α expression in brown adipose tissue and metabolic responses to cold stress.Zfp423 Maintains White Adipocyte Identity through Suppression of the Beige Cell Thermogenic Gene ProgramAdipocyte-specific deletion of Ip6k1 reduces diet-induced obesity by enhancing AMPK-mediated thermogenesis.HOXC10 suppresses browning of white adipose tissuesMKK6 controls T3-mediated browning of white adipose tissue.IRAP deficiency attenuates diet-induced obesity in mice through increased energy expenditure.α/β-Hydrolase Domain 6 Deletion Induces Adipose Browning and Prevents Obesity and Type 2 Diabetes.TFE3 controls lipid metabolism in adipose tissue of male mice by suppressing lipolysis and thermogenesis.Haploinsufficiency of the retinoblastoma protein gene reduces diet-induced obesity, insulin resistance, and hepatosteatosis in mice.Ablation of LGR4 promotes energy expenditure by driving white-to-brown fat switch.Wnt10b inhibits development of white and brown adipose tissues.The Absence of Laminin α4 in Male Mice Results in Enhanced Energy Expenditure and Increased Beige Subcutaneous Adipose Tissue.Rheb Inhibits Beiging of White Adipose Tissue via PDE4D5-Dependent Downregulation of the cAMP-PKA Signaling Pathway.
P921
Q14864062-5EC497E2-06C9-4925-B43F-F3756F471F81Q14865291-AC59605E-0DD8-48A9-A94C-59B8B8E24702Q14905181-F37E0C68-0704-4EE9-A0FC-22613F39BD1FQ14905507-1A16579D-E52C-4C64-9368-6803051A2B01Q14905611-A651F4B8-E076-4779-B94F-670B88E7B444Q14905611-E833953E-8438-44DB-B530-B2568C64755FQ14907170-DA7DA65F-38FA-4347-8764-F237A82A5712Q14907944-91B376FD-447D-41FA-B171-3431CB0EE2CAQ14914104-0049AE5E-48A3-4192-8F7C-B1D5FD3A6E9BQ15323346-19D8672C-FEA3-413D-9D5F-9B914E7D34A2Q15323383-97A43DB5-6AAE-4204-9B09-9A0838457D64Q21096337-CA4ADAFA-35A3-4B6E-87C2-96593FF6B6DFQ21096343-1DA7581D-B651-42A5-BAFD-45C5DF8B0530Q21096435-6AA397B8-FB18-4D43-A49B-60F1FC543FA9Q21101832-55E15749-BE87-423A-9187-062FF39AD193Q21102119-AE9E71BB-DA53-46CC-A3A7-9E1424ED8381Q21104871-A2DAFD7D-C753-4DA9-A09C-EBCBA7C6821DQ21105146-FF357E0D-E118-4B8E-BAB1-4FF5A774FBA0Q21105275-38BE9038-BE6B-4655-B1A6-17F4D9C84215Q21106745-D552EB38-9DBB-4623-B6CE-8834498225FAQ21107535-FAE58E4B-91E6-4A59-8AE2-DF31FBD09406Q21107648-0526ACBD-3496-494D-9E41-0F1DFD585CE4Q21107904-EBD28D73-2FC4-45A3-8CC0-E3AB719683DAQ21109306-0AAEBC04-882F-4295-91E7-A60367D402FAQ21109585-FDF8F1D9-22FE-4865-86A4-CFC445311214Q21111463-46DEDC32-0D73-4251-A831-67C85A0D594BQ21112289-42EE2A6E-2433-47DD-9966-30EB7690E2CFQ21114277-CA20C78C-7CCE-4CA4-9A1B-FB79B59D32BBQ21115219-5FAA1B77-F205-47AB-B110-450FDEBBD657Q21115219-79E91D63-858A-4B8D-A8BD-1C43C620B6DFQ21115661-A6DFAF34-EAE2-4810-9511-ED21580D75E3Q21116814-5D1D4EA6-63F9-46B3-A795-985F4D204EA4Q21117636-D536339B-38AF-4CF3-BF7B-2DE61510713FQ21120642-0AE67DF3-D123-46C5-AAF8-BEA14BBAB4B2Q21121566-F5FA7E5E-6BD8-41E5-B2AE-008826CD5F5AQ21121880-3A1156DC-B196-405B-819C-D6108BB1DF34Q21123958-617CD920-9786-430A-A071-419A1AEBC7D9Q21124903-1F971D61-5FED-45C9-B00B-CD06707F00BFQ21125871-EE331284-08F9-498D-9432-E1812A49C1A3Q21125902-601037EE-D6D1-4A9A-A2F9-D83BE214ECDE
P682
Q24339493-2A104A4A-32FC-4A9B-A9F6-C1D6A378F768Q24655101-87F74B6D-ECFC-43B5-8915-7B8484F1A912Q27335445-D8EBB7FF-ACAA-478E-8EBC-EF0F9B78DCA3Q28215944-5B5C95E8-445B-440B-AC5C-E5E9B8A5FA30Q28504440-CF8BF543-ACC6-47A6-AA5B-9D22F7F957D3Q28587326-56511A73-DA37-492E-9A4E-FEDFC8A8FCD1Q30571991-78BC5886-46DF-4985-B18A-45C8E2A4E482Q34275062-C6468900-89B4-4064-8ABC-147B722F1B1AQ34471849-BFD5F173-53C0-445B-9562-423BC79E5FF2Q34973567-FC1C463D-1948-4B45-A484-69B313C65995Q35657960-3409A529-1DAA-4D8D-8DB7-037B1845650FQ35780260-060ACC58-7008-4FF2-B15A-9D9D452B8843Q36147727-347D370A-F08B-4F6F-87D6-D5709199591FQ36155073-83A99AC0-A339-4238-A499-71D51F49510BQ36283676-6DC1D595-B02C-4AE5-B1A1-939C199DD95AQ36594725-367CE622-64B5-4680-96AE-B7F9F68226D3Q36754187-2ADF4741-A041-4C7B-B770-E62360C5B22AQ36766735-D1706AA1-C65E-411D-BD63-7E14546D093FQ36814649-86137B7E-863A-4F4A-B09B-03A1162E43F6Q36891685-F135F496-7B6E-4535-A941-16A934313ED9Q37096282-2DF8CE5E-B237-44B4-9E2B-F3290F636F16Q37220951-BF97C4F2-49DA-451B-A772-7D99D9008648Q37262475-7C544CA6-6D60-458C-835B-0F93BA9478B2Q37311451-810FDB44-F4E4-4411-904D-3B469BC07696Q37325289-590A1D2D-A03F-47C9-A777-F91AA118A323Q38681810-343D0C11-AFEF-43A8-A788-8627DD2EA403Q39017193-5A9991EC-2CBC-437B-A5FE-897669DDBF25Q39278558-F8B62A87-784A-4F25-B45A-84E715F822E4Q39726997-8684C14D-77EE-4229-A0B5-13BBDB46A4B6Q41679412-2384A397-7C6F-4487-8EFB-70124F73ED74Q42098607-63DA1741-AC4C-4D1F-95A0-F178B7DC2FBBQ42261935-5E7A9217-420E-4DBB-8CBC-BA8A8832484AQ42470692-A2E98400-AA56-43A8-81FB-2774C29710C9Q42812581-038125F6-C91D-4FB0-B2E1-048F6598BD73Q42816032-A7431D1C-BA29-4835-8E60-BA9AE1F19589Q46024728-57BCA959-3641-4AFC-9C08-6AA1E703748CQ46519761-2593405C-4F0C-49F5-A9CA-336936D09234Q47364038-E8BEA68E-F7D6-4472-8C1A-710E26EA2320Q47605958-F066C2CE-1821-474E-A79B-A23172B8635AQ48289477-42278B8D-BDC6-4803-AB14-9418DD793238
P921
description
Any process that stops, prevents, or reduces the rate of cold-induced thermogenesis
@en
biologisch proces
@nl
name
negative regulation of cold-induced thermogenesis
@en
type
label
negative regulation of cold-induced thermogenesis
@en
altLabel
GO:0120163
@en
prefLabel
negative regulation of cold-induced thermogenesis
@en
P279
P279
P2888
P686
GO:0120163