CO2-dependent metabolic modulation in red blood cells stored under anaerobic conditions

Transfusion

Volumn 56, Issue 2, 2016, Pages 392-403

  Dumont, Larry J ^a   D'Alessandro, Angelo ^b,c   Szczepiorkowski, Zbigniew M ^a,d   Yoshida, Tatsuro ^e  

^a DARTMOUTH MEDICAL SCHOOL   (United States)

^b UNIVERSITY OF COLORADO SCHOOL OF MEDICINE   (United States)

^c UNIVERSITY OF COLORADO   (United States)

^d DARTMOUTH HITCHCOCK MEDICAL CENTER   (United States)

^e New Health Sciences Inc   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

2,3 DIPHOSPHOGLYCERIC ACID; ADENOSINE TRIPHOSPHATE; ARGININE; CARBON DIOXIDE; FRUCTOSE BISPHOSPHATE; GLUTATHIONE; GLUTATHIONE DISULFIDE; LACTIC ACID; OXYGEN; PHOSPHOENOLPYRUVATE; PURINE; RIBOSE PHOSPHATE; TRIOSE;

AMBIENT AIR; ANAEROBIC METABOLISM; ARTICLE; BIOCHEMICAL ANALYSIS; BLOOD ANALYSIS; BLOOD STORAGE; CARBON METABOLISM; CLINICAL ASSESSMENT; CONTROLLED STUDY; DEOXYGENATION; DEPLETION; ERYTHROCYTE; GAS EXCHANGE; GLUCOSE INTAKE; HEMOLYSIS; HUMAN; IN VITRO STUDY; MASS SPECTROMETRY; METABOLOMICS; OXYGEN DEPLETION; ANAEROBIC GROWTH; CYTOLOGY; GLYCOLYSIS; METABOLISM; PH;

2,3-DIPHOSPHOGLYCERATE; ADENOSINE TRIPHOSPHATE; ANAEROBIOSIS; BLOOD PRESERVATION; CARBON DIOXIDE; ERYTHROCYTES; GLYCOLYSIS; HUMANS; HYDROGEN-ION CONCENTRATION; OXYGEN;

EID: 84958908094     PISSN: 00411132     EISSN: 15372995     Source Type: Journal    
DOI: 10.1111/trf.13364     Document Type: Article

References (38)

1. Yoshida T, AuBuchon JP, Tryzelaar L, et al., Extended storage of red blood cells under anaerobic conditions. Vox Sang 2007; 92: 22-31.
2. Yoshida T, AuBuchon JP, Dumont LJ, et al., The effects of additive solution pH and metabolic rejuvenation on anaerobic storage of red cells. Transfusion 2008; 48: 2096-105.
3. Dumont LJ, Yoshida T, AuBuchon JP., Anaerobic storage of red blood cells in a novel additive solution improves in vivo recovery. Transfusion 2009; 49: 458-64.
4. Erecińska M, Deas J, Silver IA., The effect of pH on glycolysis and phosphofructokinase activity in cultured cells and synaptosomes. J Neurochem 1995; 65: 2765-72.
5. Hess JR., Storage of red blood cells under anaerobic conditions. Vox Sang 2007; 93: 183; author reply 184.
6. D'Alessandro A, Gevi F, Zolla L., Red blood cell metabolism under prolonged anaerobic storage. Mol Biosyst 2013; 9: 1196-209.
7. Longo V, D'alessandro A, Zolla L., Deoxygenation of leucofiltered erythrocyte concentrates preserves proteome stability during storage in the blood bank. Blood Transfus 2014; 12: 599-604.
8. Zolla L, D'Alessandro A., An efficient apparatus for rapid deoxygenation of erythrocyte concentrates for alternative banking strategies. J Blood Transfus 2013; 2013: 896537.
9. Roback JD, Josephson CD, Waller EK, et al., Metabolomics of ADSOL (AS-1) red blood cell storage. Transfus Med Rev 2014; 28: 41-55.
10. D'Alessandro A, Nemkov T, Kelher M, et al., Routine storage of red blood cell (RBC) units in additive solution-3: a comprehensive investigation of the RBC metabolome. Transfusion 2015; 55: 1155-68.
11. Van 't Erve TJ, Doskey CM, Wagner BA, et al., The heritability of glutathione and related metabolites in stored red blood cells. Free Radic Biol Med 2014; 76: 107-13.
12. Van 't Erve TJ, Wagner BA, Martin SM, et al., The heritability of metabolite concentrations in stored human red blood cells. Transfusion 2014; 54: 2055-63.
13. D'Alessandro A, Hansen KC, Silliman CC, et al., Metabolomics of AS-5 RBC supernatants following routine storage. Vox Sang 2015; 108: 131-40.
14. D'Alessandro A, D'Amici GM, Vaglio S, et al., Time-course investigation of SAGM-stored leukocyte-filtered red blood cell concentrates: from metabolism to proteomics. Haematologica 2012; 97: 107-15.
15. Nishino T, Yachie-Kinoshita A, Hirayama A, et al., In silico modeling and metabolome analysis of long-stored erythrocytes to improve blood storage methods. J Biotechnol 2009; 144: 212-23.
16. Nishino T, Yachie-Kinoshita A, Hirayama A, et al., Dynamic simulation and metabolome analysis of long-term erythrocyte storage in adenine-guanosine solution. PLoS One 2013; 8: e71060.
17. Högman CF, Löf H, Meryman HT., Storage of red blood cells with improved maintenance of 2,3-bisphosphoglycerate. Transfusion 2006; 46: 1543-52.
18. McAteer MJ, Dumont LJ, Cancelas J, et al., Multi-institutional randomized control study of haemolysis in stored red cell units prepared manually or by an automated system. Vox Sang 2010; 99: 34-43.
19. Yoshida T, Shevkoplyas SS., Anaerobic storage of red blood cells. Blood Transfus 2010; 8: 220-36.
20. Yachie-Kinoshita A, Nishino T, Shimo H, et al., A metabolic model of human erythrocytes: practical application of the E-cell Simulation Environment. J Biomed Biotechnol 2010; 2010: 642420.
21. Yoshida T, et al., Extended storage of red blood cells under anaerobic conditions. Vox Sang 2007; 92: 22-31.
22. Rapoport I, Berger H, Elsner R, et al., PH-dependent changes of 2,3-bisphosphoglycerate in human red cells during transitional and steady states in vitro. Eur J Biochem FEBS 1977; 73: 421-7.
23. Rose ZB, Dube S., Rates of phosphorylation and dephosphorylation of phosphoglycerate mutase and bisphosphoglycerate synthase. J Biol Chem 1976; 251: 4817-22.
24. Rose ZB, Liebowitz J., 2,3-diphosphoglycerate phosphatase from human erythrocytes. General properties and activation by anions. J Biol Chem 1970; 245: 3232-41.
25. Oski FA, Travis SF, Miller LD, et al., The in vitro restoration of red cell 2,3-diphosphoglycerate levels in banked. Blood 1971; 37: 52-8.
26. Raftos JE, Whillier S, Kuchel PW., Glutathione synthesis and turnover in the human erythrocyte alignment of a model based on detailed enzyme kinetics with experimental data. J Biol Chem 2010; 285: 23557-67.
27. van 't Erve TJ, Lih FB, Kadiiska MB, et al., Reinterpreting the best biomarker of oxidative stress: the 8-iso-PGF2α/PGF2α ratio distinguishes chemical from enzymatic lipid peroxidation. Free Radic Biol Med 2015; 83: 245-51.
28. Zimring JC, Smith N, Stowell SR, et al., Strain-specific red blood cell storage, metabolism, and eicosanoid generation in a mouse model. Transfusion 2014; 54: 137-48.
29. Crawford JH, Isbell TS, Huang Z, et al., Hypoxia, red blood cells, and nitrite regulate NO-dependent hypoxic vasodilation. Blood 2006; 107: 566-74.
30. Kleinbongard P, Schulz R, Rassaf T, et al., Red blood cells express a functional endothelial nitric oxide synthase. Blood 2006; 107: 2943-51.
31. Rogers SC, Said A, Corcuera D, et al., Hypoxia limits antioxidant capacity in red blood cells by altering glycolytic pathway dominance. FASEB J 2009; 23: 3159-70.
32. Castagnola M, Messana I, Sanna MT, et al., Oxygen-linked modulation of erythrocyte metabolism: state of the art. Blood Transfus 2010; 8 Suppl 3: s53-8.
33. Lewis IA, Campanella ME, Markley JL, et al., Role of band 3 in regulating metabolic flux of red blood cells. Proc Natl Acad Sci U S A 2009; 106: 18515-20.
34. Messana I, Ferroni L, Misiti F, et al., Blood bank conditions and RBCs: the progressive loss of metabolic modulation. Transfusion 2000; 40: 353-60.
35. Cohen P, Rosemeyer MA., Human glucose-6-phosphate dehydrogenase: purification of the erythrocyte enzyme and the influence of ions on its activity. Eur J Biochem 1969; 8: 1-7.
36. Meyer EK, Dumont DF, Baker S, et al., Rejuvenation capacity of red blood cells in additive solutions over long-term storage. Transfusion 2011; 51: 1574-9.
37. Lentner C., Geigy scientific tables. West Caldwell (NJ): CIBA-GEIGY Corporation; 1984.
38. Toth EA, Yeates TO., The structure of adenylosuccinate lyase, an enzyme with dual activity in the de novo purine biosynthetic pathway. Structure 2000; 8: 163-74.