about
Control of Appetite and Food Preference by NMDA Receptor and Its Co-Agonist d-SerineAge-Associated Weight Gain, Leptin, and SIRT1: A Possible Role for Hypothalamic SIRT1 in the Prevention of Weight Gain and Aging through Modulation of Leptin SensitivityExpanding frontiers in weight-control research explored by young investigatorsEctopic osteogenesis using adenoviral bone morphogenetic protein (BMP)-4 and BMP-6 gene transfer.Major vault protein/lung resistance-related protein (MVP/LRP) expression in nervous system tumors.Comparison of gene expression profiles between frozen original meningiomas and primary cultures of the meningiomas by GeneChip.Osteogenic potential of five different recombinant human bone morphogenetic protein adenoviral vectors in the rat.DeltaNp53 or p44: priming the p53 pump.Phosphorylation regulates SIRT1 function.Identification of the deleted in liver cancer 1 gene, DLC1, as a candidate meningioma tumor suppressor.Dnmt3a in Sim1 neurons is necessary for normal energy homeostasisSirt1 rescues the obesity induced by insulin-resistant constitutively-nuclear FoxO1 in POMC neurons of male mice.Genetic defect in phospholipase Cδ1 protects mice from obesity by regulating thermogenesis and adipogenesisHypothalamic SIRT1 prevents age-associated weight gain by improving leptin sensitivity in mice.Elevated mitochondrial biogenesis in skeletal muscle is associated with testosterone-induced body weight loss in male mice.ATF3 expression is induced by low glucose in pancreatic α and β cells and regulates glucagon but not insulin gene transcription.Miglitol prevents diet-induced obesity by stimulating brown adipose tissue and energy expenditure independent of preventing the digestion of carbohydrates.Necdin controls Foxo1 acetylation in hypothalamic arcuate neurons to modulate the thyroid axis.Neurosecretory protein GL stimulates food intake, de novo lipogenesis, and onset of obesity.A critical role of fatty acid binding protein 4 and 5 (FABP4/5) in the systemic response to fasting.Neural and Molecular Mechanisms Involved in Controlling the Quality of Feeding Behavior: Diet Selection and Feeding Patterns.Miglitol protects against age-dependent weight gain in mice: A potential role of increased UCP1 content in brown adipose tissue.N-methyl-d-aspartate receptor coagonist d-serine suppresses intake of high-preference food.Intraperitoneal injection of d-serine inhibits high-fat diet intake and preference in male mice.Protection against high-fat diet-induced obesity in Helz2-deficient male mice due to enhanced expression of hepatic leptin receptor.Overexpression of insulin receptor partially improves obese and diabetic phenotypes in db/db mice.A central-acting connexin inhibitor, INI-0602, prevents high-fat diet-induced feeding pattern disturbances and obesity in mice.Overexpression of Nmnat3 efficiently increases NAD and NGD levels and ameliorates age-associated insulin resistanceNeuronal SIRT1 regulates macronutrient-based diet selection through FGF21 and oxytocin signalling in miceSGLT1 in pancreatic α cells regulates glucagon secretion in mice, possibly explaining the distinct effects of SGLT2 inhibitors on plasma glucagon levels
P50
Q26741317-CFB20A30-0C8F-4AC0-B1C0-29E138F10F05Q26800025-862054D0-9133-4C92-955C-B3E5430EABACQ28077983-85F9C3B7-589B-421C-A200-B6832339AAF9Q30310120-6D458A57-39CE-48D1-92AF-BEC6C1306E8DQ30310605-679713A0-E431-46DA-A283-A7AD90AF1457Q30310702-F5400566-47B1-4F6F-8CB2-980032068D18Q30311167-8D8DA08E-6BBA-4A48-BBBA-F4820069D14BQ30436098-EA7037A4-F6C5-4A0E-A793-21682057002DQ30440595-84857147-FCBB-4817-B375-86DEE8A56FF2Q30447293-4591D17A-EBAB-4B5D-9B5B-BC3BEC763936Q34491670-FCB78C2A-B6B8-4384-A8D4-F6AEF515D8F5Q34693297-4FC7EB52-2753-4532-8A30-BB8FAEC0FA2FQ35063259-25D32E5C-3FF6-4D62-8C6C-E78B021E786DQ37614501-0215C213-832B-4A06-B529-D09528F04B89Q39004898-45D002B5-7404-4747-A1D4-8459C15225A9Q39076626-44867CC9-8CB0-4E94-B41C-3FD1602A9B98Q39101520-3EFA45B1-72B1-4EDC-A0A9-AACAE9771339Q39362556-82B6F9F0-FF0C-4FDF-8576-94CAB7B09291Q41364728-5CCD7C66-F01D-4FBA-8F36-9F4EC37B7E84Q42906682-4F6A157B-E340-454F-BD6C-BB2B702C14DFQ43830693-1B5B9117-71D8-4673-8167-59AB5F37AB03Q47396391-6668EBF1-1033-4AC8-A766-9F831C4D8A49Q48088970-0A29C0E9-F3F8-4A45-AD49-14923B77BD8CQ48156057-591C78B7-2CAD-4869-99ED-9DB824B86749Q51711834-4B9A81F1-F8EB-4D21-9B8A-EB4AB9412129Q53836883-75232017-A8F5-4023-8CCC-34CA5AE050BBQ55020293-08A88A1A-6FD0-4385-89C7-666331DBED2AQ57444273-31F04CBA-1684-407F-933F-2515FFFD6400Q58617550-06C0BF86-9D80-4D39-B61A-36AD61A514E8Q92984551-77455166-A99A-44F8-AA76-30EDECEAEA88
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Tsutomu Sasaki
@ast
Tsutomu Sasaki
@en
Tsutomu Sasaki
@es
Tsutomu Sasaki
@nl
type
label
Tsutomu Sasaki
@ast
Tsutomu Sasaki
@en
Tsutomu Sasaki
@es
Tsutomu Sasaki
@nl
prefLabel
Tsutomu Sasaki
@ast
Tsutomu Sasaki
@en
Tsutomu Sasaki
@es
Tsutomu Sasaki
@nl
P106
P31
P496
0000-0001-8041-1915