Renalase is an α-NAD(P)H oxidase/anomerase

被引:0
|
作者
机构
[1] Beaupre, Brett A.
[2] Carmichael, Brenton R.
[3] Hoag, Matthew R.
[4] Shah, Dhara D.
[5] Moran, Graham R.
来源
Moran, G.R. (moran@uwm.edu) | 1600年 / American Chemical Society卷 / 135期
关键词
Renalase is a protein hormone secreted into the blood by the kidney that is reported to lower blood pressure and slow heart rate. Since its discovery in 2005; renalase has been the subject of conjecture pertaining to its catalytic function. While it has been widely reported that renalase is the third monoamine oxidase (monoamine oxidase C) that oxidizes circulating catecholamines such as epinephrine; there has been no convincing demonstration of this catalysis in vitro. Renalase is a flavoprotein whose structural topology is similar to known oxidases; lysine demethylases; and monooxygenases; but its active site bears no resemblance to that of any known flavoprotein. We have identified the catalytic activity of renalase as an α-NAD(P)H oxidase/anomerase; whereby low equilibrium concentrations of the α-anomer of NADPH and NADH initiate rapid reduction of the renalase flavin cofactor. The reduced cofactor then reacts with dioxygen to form hydrogen peroxide and releases nicotinamide dinucleotide product in the β-form. These processes yield an apparent turnover number (0.5 s-1 in atmospheric dioxygen) that is at least 2 orders of magnitude more rapid than any reported activity with catechol neurotransmitters. This highly novel activity is the first demonstration of a role for naturally occurring α-NAD(P)H anomers in mammalian physiology and the first report of a flavoprotein catalyzing an epimerization reaction. © 2013 American Chemical Society;
D O I
暂无
中图分类号
学科分类号
摘要
Journal article (JA)
引用
收藏
相关论文
共 50 条
  • [21] Human placental NAD(P)H oxidase: Solubilization and properties
    Manes, C
    PLACENTA, 2001, 22 (01) : 58 - 63
  • [22] Metabolic Function for Human Renalase: Oxidation of Isomeric Forms of β-NAD(P)H that Are Inhibitory to Primary Metabolism
    Beaupre, Brett A.
    Hoag, Matt R.
    Roman, Joseph
    Foersterling, F. Holger
    Moran, Graham R.
    BIOCHEMISTRY, 2015, 54 (03) : 795 - 806
  • [23] An NAD(P)H oxidase regulates growth and transcription in melanoma cells
    Brar, SS
    Kennedy, TP
    Sturrock, AB
    Huecksteadt, TP
    Quinn, MT
    Whorton, AR
    Hoidal, JR
    AMERICAN JOURNAL OF PHYSIOLOGY-CELL PHYSIOLOGY, 2002, 282 (06): : C1212 - C1224
  • [24] The interrelation of the angiotensin and endothelin systems on the modulation of NAD(P)H oxidase
    Laplante, MA
    De Champlain, J
    CANADIAN JOURNAL OF PHYSIOLOGY AND PHARMACOLOGY, 2006, 84 (01) : 21 - 28
  • [25] Diphenyliodonium, an NAD(P)H oxidase inhibitor, also induces apoptosis
    Li, NY
    Ragheb, K
    Lawler, G
    Robinson, P
    FASEB JOURNAL, 2001, 15 (04): : A314 - A314
  • [26] AMPEROMETRIC ENZYME ELECTRODE WITH THE USE OF DEHYDROGENASE AND NAD(P)H OXIDASE
    MIZUTANI, F
    YABUKI, S
    KATSURA, T
    SENSORS AND ACTUATORS B-CHEMICAL, 1993, 14 (1-3) : 574 - 575
  • [27] NAD(P) H oxidase isoforms as therapeutic targets for diabetic complications
    Gray, Stephen P.
    Jha, Jay C.
    Di Marco, Elyse
    Jandeleit-Dahm, Karin A. M.
    EXPERT REVIEW OF ENDOCRINOLOGY & METABOLISM, 2014, 9 (02) : 111 - 122
  • [28] EVIDENCE FOR AN ALLOSTERIC TRANSITION OF HUMAN NEUTROPHILIC NAD(P)H OXIDASE
    DECHATELET, LR
    MCPHAIL, LC
    SHIRLEY, PS
    IVERSON, DB
    JOURNAL OF THE RETICULOENDOTHELIAL SOCIETY, 1977, 22 : A7 - A7
  • [29] To activate NAD(P)H oxidase with a brief pulse of photodynamic action
    Xie, Xiao Bing
    Shu, Yu
    Cui, Zong Jie
    FASEB JOURNAL, 2024, 38 (23):
  • [30] Quantitative measurement of superoxide generated by vascular NAD(P)H oxidase
    Souza, HP
    Liu, XP
    Samouilov, A
    Laurindo, FRM
    Zweler, JL
    CIRCULATION, 2000, 102 (18) : 233 - 233
12345