AltitudeOmics: Red Blood Cell Metabolic Adaptation to High Altitude Hypoxia

Red blood cells (RBCs) are key players in systemic oxygen transport. RBCs respond to in vitro hypoxia through the so-called oxygen-dependent metabolic regulation, which involves the competitive binding of deoxyhemoglobin and glycolytic enzymes to the N-terminal cytosolic domain of band 3. This mecha...

Full description

Saved in:
Bibliographic Details
Published in:Journal of proteome research 2016-10, Vol.15 (10), p.3883-3895
Main Authors: D’Alessandro, Angelo, Nemkov, Travis, Sun, Kaiqi, Liu, Hong, Song, Anren, Monte, Andrew A, Subudhi, Andrew W, Lovering, Andrew T, Dvorkin, Daniel, Julian, Colleen G, Kevil, Christopher G, Kolluru, Gopi K, Shiva, Sruti, Gladwin, Mark T, Xia, Yang, Hansen, Kirk C, Roach, Robert C
Format: Article
Language:English
Subjects:
Acclimatization - physiology
Adaptation, Physiological
Adult
Altitude
Altitude Sickness - metabolism
Altitude Sickness - physiopathology
Arginine - metabolism
Erythrocytes - metabolism
Glutathione - metabolism
Glycolysis
Healthy Volunteers
Humans
Pentose Phosphate Pathway
Purines - metabolism
Sulfur - metabolism
Time Factors
Young Adult
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Red blood cells (RBCs) are key players in systemic oxygen transport. RBCs respond to in vitro hypoxia through the so-called oxygen-dependent metabolic regulation, which involves the competitive binding of deoxyhemoglobin and glycolytic enzymes to the N-terminal cytosolic domain of band 3. This mechanism promotes the accumulation of 2,3-DPG, stabilizing the deoxygenated state of hemoglobin, and cytosol acidification, triggering oxygen off-loading through the Bohr effect. Despite in vitro studies, in vivo adaptations to hypoxia have not yet been completely elucidated. Within the framework of the AltitudeOmics study, erythrocytes were collected from 21 healthy volunteers at sea level, after exposure to high altitude (5260 m) for 1, 7, and 16 days, and following reascent after 7 days at 1525 m. UHPLC–MS metabolomics results were correlated to physiological and athletic performance parameters. Immediate metabolic adaptations were noted as early as a few hours from ascending to >5000 m, and maintained for 16 days at high altitude. Consistent with the mechanisms elucidated in vitro, hypoxia promoted glycolysis and deregulated the pentose phosphate pathway, as well purine catabolism, glutathione homeostasis, arginine/nitric oxide, and sulfur/H2S metabolism. Metabolic adaptations were preserved 1 week after descent, consistently with improved physical performances in comparison to the first ascendance, suggesting a mechanism of metabolic memory.
ISSN:1535-3893
1535-3907
DOI:10.1021/acs.jproteome.6b00733