PUBLICATION

N-myc downstream regulated gene 1 (ndrg1) functions as a molecular switch for cellular adaptation to hypoxia

Authors
Park, J.S., Gabel, A.M., Kassir, P., Kang, L., Chowdhary, P.K., Osei-Ntansah, A., Tran, N.D., Viswanathan, S., Canales, B., Ding, P., Lee, Y.S., Brewster, R.
ID
ZDB-PUB-221018-20
Date
2022
Source
eLIFE   11: (Journal)
Registered Authors
Brewster, Rachel
Keywords
NDRG1, anoxia, cell biology, developmental biology, hypometabolism, hypoxia, lactate, sodium-potassium pump, zebrafish
MeSH Terms
  • Sodium/metabolism
  • Animals
  • Oxygen/metabolism
  • Lactates
  • Sodium-Potassium-Exchanging ATPase/metabolism
  • Adenosine Triphosphate/metabolism
  • Potassium/metabolism
  • Zebrafish*/metabolism
  • Hypoxia*/genetics
  • Sodium Azide/metabolism
(all 10)
PubMed
36214665 Full text @ Elife
Abstract
Lack of oxygen (hypoxia and anoxia) is detrimental to cell function and survival and underlies many disease conditions. Hence, metazoans have evolved mechanisms to adapt to low oxygen. One such mechanism, metabolic suppression, decreases the cellular demand for oxygen by downregulating ATP-demanding processes. However, the molecular mechanisms underlying this adaptation are poorly understood. Here, we report on the role of ndrg1a in hypoxia adaptation of the anoxia-tolerant zebrafish embryo. ndrg1a is expressed in the kidney and ionocytes, cell types that use large amounts of ATP to maintain ion homeostasis. ndrg1a mutants are viable and develop normally when raised under normal oxygen. However, their survival and kidney function is reduced relative to WT embryos following exposure to prolonged anoxia. We further demonstrate that Ndrg1a binds to the energy-demanding sodium-potassium ATPase (NKA) pump under anoxia and is required for its degradation, which may preserve ATP in the kidney and ionocytes and contribute to energy homeostasis. Lastly, we show that sodium azide treatment, which increases lactate levels under normoxia, is sufficient to trigger NKA degradation in an Ndrg1a-dependent manner. These findings support a model whereby Ndrg1a is essential for hypoxia adaptation and functions downstream of lactate signaling to induce NKA degradation, a process known to conserve cellular energy.
Genes / Markers
Figures
Figure Gallery (7 images)
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Expression
Phenotype
Fish Conditions Stage Phenotype Figure
ABchemical treatment by environment: sodium azidePrim-5
ABchemical treatment by environment: sodium azidePrim-5
ABhypoxia30%-epiboly
ABhypoxiaPrim-5
ABhypoxiaPrim-5
ABhypoxiaPrim-5
ABhypoxiaPrim-5
ABhypoxiaPrim-5
ABhypoxiaPrim-5
ABhypoxiaPrim-5
1 - 10 of 35
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Mutations / Transgenics
Allele Construct Type Affected Genomic Region
mbc1
    		Complex
    1 - 1 of 1
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    Human Disease / Model
    No data available
    Sequence Targeting Reagents
    Target Reagent Reagent Type
    ndrg1aCRISPR1-ndrg1aCRISPR
    ndrg1aCRISPR2-ndrg1aCRISPR
    ndrg1aCRISPR3-ndrg1aCRISPR
    ndrg1aMO2-ndrg1aMRPHLNO
    1 - 4 of 4
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    Fish
    Fish
    AB
    AB + MO2-ndrg1a
    ndrg1ambc1/mbc1
    1 - 3 of 3
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    Antibodies
    Name Type Antigen Genes Isotypes Host Organism
    Ab1-atp1amonoclonal
      		IgG1Mouse
      Ab4-ndrg1apolyclonal
        		Rabbit
        Ab4-tjp1polyclonal
          		IgG1Rabbit
          Ab21-gapdhpolyclonal
            		IgGRabbit
            1 - 4 of 4
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            Orthology
            No data available
            Engineered Foreign Genes
            No data available
            Mapping
            No data available
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            Citation
            Park, J.S., Gabel, A.M., Kassir, P., Kang, L., Chowdhary, P.K., Osei-Ntansah, A., Tran, N.D., Viswanathan, S., Canales, B., Ding, P., Lee, Y.S., Brewster, R. (2022) N-myc downstream regulated gene 1 (ndrg1) functions as a molecular switch for cellular adaptation to hypoxia. eLIFE. 11:.