about
Cyclophilin D-dependent mitochondrial permeability transition regulates some necrotic but not apoptotic cell deathSIRT5 Deacetylates carbamoyl phosphate synthetase 1 and regulates the urea cycleOncogenic osteomalacia secondary to nasal tumor with decreased urinary excretion of cAMP.SIRT1-Mediated eNAMPT Secretion from Adipose Tissue Regulates Hypothalamic NAD+ and Function in Mice.Nmnat3 Is Dispensable in Mitochondrial NAD Level Maintenance In Vivo.NMNAT1 inhibits axon degeneration via blockade of SARM1-mediated NAD+ depletion.Hypothalamic SIRT1 prevents age-associated weight gain by improving leptin sensitivity in mice.Targeting metabolic pathways for head and neck cancers therapeutics.Deficiency of nicotinamide mononucleotide adenylyltransferase 3 (nmnat3) causes hemolytic anemia by altering the glycolytic flow in mature erythrocytes.CD206+ M2-like macrophages regulate systemic glucose metabolism by inhibiting proliferation of adipocyte progenitors.Sirtuins at a glance.HIF-1α in Myeloid Cells Promotes Adipose Tissue Remodeling Toward Insulin Resistance.Urea cycle regulation by mitochondrial sirtuin, SIRT5.SnapShot: sirtuins, NAD, and aging.Simultaneous Measurement of NAD Metabolome in Aged Mice Tissue Using Liquid Chromatography Tandem-Mass Spectrometry (LC/MS/MS).Novel role of serine racemase in anti-apoptosis and metabolism.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 miceNAD Metabolism in Cancer TherapeuticsImplications of altered NAD metabolism in metabolic disordersPapillary cystadenocarcinoma arising from minor salivary glands in the anterior portion of the tongue: a case reportA Bax/Bak-independent mechanism of cytochrome c releaseNAD metabolism: Implications in aging and longevityAstaxanthin stimulates mitochondrial biogenesis in insulin resistant muscle via activation of AMPK pathwayMetabolism and biochemical properties of nicotinamide adenine dinucleotide (NAD) analogs, nicotinamide guanine dinucleotide (NGD) and nicotinamide hypoxanthine dinucleotide (NHD)Sirt1 activator induces proangiogenic genes in preadipocytes to rescue insulin resistance in diet-induced obese miceBofutsushosan improves gut barrier function with a bloom of Akkermansia muciniphila and improves glucose metabolism in mice with diet-induced obesityDeletion of SIRT1 in myeloid cells impairs glucose metabolism with enhancing inflammatory response to adipose tissue hypoxiaDeletion of PHGDH in adipocytes improves glucose intolerance in diet-induced obese miceThe microRNAs miR-302b and miR-372 regulate mitochondrial metabolism via the SLC25A12 transporter, which controls MAVS-mediated antiviral innate immunityImplications of NAD metabolism in pathophysiology and therapeutics for neurodegenerative diseasesMacrophage-specific hypoxia-inducible factor-1α deletion suppresses the development of liver tumors in high-fat diet-fed obese and diabetic mice
P50
Q28242641-A8C5E568-9FE5-4D5A-B10B-086C6A86FF55Q28592294-9949603B-19B7-4909-B305-F7ECB11E289CQ31825357-8A3E3B1B-9F56-4F58-B4B4-0DEBCD4FC55CQ35588961-89D6D6BD-33AA-455D-A859-8D188EDADF4DQ35891449-DB65103E-ADF5-4FDB-AD60-BA316BCCCC8CQ37338158-CA781A63-2580-43BE-AE6C-76E04782A051Q37614501-07681A0D-D297-469E-8506-9C93BB9354F1Q38640439-45937C52-E0D9-46CF-91DC-D0E53A38BDC6Q39886081-242503BA-AB0F-45A8-ACA6-3FFF08F83A35Q40089118-F4332787-01DB-4074-AB4F-345A219BBED3Q42650245-4AAC303B-FDF1-4A62-9C75-1BBFA483A544Q42807373-54BC8A41-75D8-4D51-8C4D-D2AB6F4F52F1Q42937895-9D6641DD-8A34-4C99-90D1-93F12A539CC8Q46871443-BBFDB2AA-D71C-4E0A-9367-C616B1AE6815Q50100669-D8AF3853-8EAC-4212-83F9-39D9374EFED7Q51538192-7F835B1F-FAFC-4EC1-B28D-CF9F8EB04A3CQ57444273-1B4E20D6-9EB0-4B0D-A381-929253451356Q58617550-BCEF3EED-91F8-4449-AC91-985DD5B419E1Q60958368-2891A981-9324-4ED3-B64E-7DD4A24A97D6Q64057672-BEF4BCDC-448A-48B1-BBC2-95EAE4171A3DQ77436625-6F220D5A-0E6D-4362-BF5F-FBF0427B0177Q80099045-6C9C4819-8A07-4882-A440-8599A1D96A31Q89043777-171F4B32-B7FF-420A-928A-996DF02DD4AEQ89463933-EDD8B567-8038-4422-9078-033908DBFC67Q90069416-1FC0FC6A-E0E8-4B21-AE86-7A62736F96F7Q90581137-60F064A3-4C72-4056-AD4C-39409B68D7BFQ90695647-FCF49245-8047-4AB1-BD24-53842573669AQ90856462-B440BB58-4E7E-4C62-AF79-6E817599319EQ91287074-CDFB3476-0956-4279-9FD7-B06BDEEA601EQ91450602-33832FD0-C8E9-4217-8F4E-EF2490789026Q91683329-361621CE-8271-4229-91FF-339045B8D504Q92527657-FCD3EC1A-3070-47E9-8588-1342EBE27E7C
P50
description
researcher ORCID ID = 0000-0001-5539-7605
@en
name
Takashi Nakagawa
@ast
Takashi Nakagawa
@en
Takashi Nakagawa
@es
Takashi Nakagawa
@nl
type
label
Takashi Nakagawa
@ast
Takashi Nakagawa
@en
Takashi Nakagawa
@es
Takashi Nakagawa
@nl
prefLabel
Takashi Nakagawa
@ast
Takashi Nakagawa
@en
Takashi Nakagawa
@es
Takashi Nakagawa
@nl
P31
P496
0000-0001-5539-7605