TY - JOUR
T1 - Bioenergetics of the heart at high altitude
T2 - Environmental hypoxia imposes profound transformations on the myocardial process of ATP synthesis
AU - Reynafarje, Baltazar D.
AU - Marticorena, Emilio
PY - 2002/12
Y1 - 2002/12
N2 - The low concentration of O2 in the thin air at high altitude is undoubtedly the reason for the remarkable modifications in the structure and function of the heart, lung, and blood of humans permanently living under these conditions. The effect of natural hypoxia on the energy metabolism of the cell is however not well understood. Here we study the proces of ATP synthesis in the heart of guinea pigs native to high altitude (4500 m) as compared with those native to sea level. The following are the novel findings of this study. (1) The rates and extents of ATP synthesis in the presence of low concentrations of ADP (50, i.e. the concentration of ADP at which 50% of the catalytic sites are filled with ADP and/or ATP, is the same (∼74.7 μM). (4) In the physiological range of ADP concentrations, the phosphorylation potential ΔGP is significantly higher at high altitude than at sea level. It is concluded that the molecular mechanism of energy transduction is profoundly modified at high altitude in order to readily and efficiently generate ATP in the presence of low concentrations of O2 and ADP.
AB - The low concentration of O2 in the thin air at high altitude is undoubtedly the reason for the remarkable modifications in the structure and function of the heart, lung, and blood of humans permanently living under these conditions. The effect of natural hypoxia on the energy metabolism of the cell is however not well understood. Here we study the proces of ATP synthesis in the heart of guinea pigs native to high altitude (4500 m) as compared with those native to sea level. The following are the novel findings of this study. (1) The rates and extents of ATP synthesis in the presence of low concentrations of ADP (50, i.e. the concentration of ADP at which 50% of the catalytic sites are filled with ADP and/or ATP, is the same (∼74.7 μM). (4) In the physiological range of ADP concentrations, the phosphorylation potential ΔGP is significantly higher at high altitude than at sea level. It is concluded that the molecular mechanism of energy transduction is profoundly modified at high altitude in order to readily and efficiently generate ATP in the presence of low concentrations of O2 and ADP.
KW - ATP synthesis
KW - Hypoxia
KW - Mitochondria
KW - Oxidative phosphorylation
KW - Oxygen
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U2 - 10.1023/A:1022597523483
DO - 10.1023/A:1022597523483
M3 - Article
C2 - 12678432
AN - SCOPUS:0036964469
SN - 0145-479X
VL - 34
SP - 407
EP - 412
JO - Journal of Bioenergetics and Biomembranes
JF - Journal of Bioenergetics and Biomembranes
IS - 6
ER -