High-altitude adaptations in vertebrate hemoglobins

Abstract Vertebrates at high altitude are subjected to hypoxic conditions that challenge aerobic metabolism. O2 transport from the respiratory surfaces to tissues requires matching between the O2 loading and unloading tensions and the O2 -affinity of blood, which is an integrated function of hemoglo...

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Veröffentlicht in:	Respiratory physiology & neurobiology 2007-09, Vol.158 (2), p.132-142
1. Verfasser:	Weber, Roy E
Format:	Artikel
Sprache:	eng
Schlagworte:	Acclimatization - physiology Allosteric interactions Altitude Amino acid substitutions Amphibians Animals Atmospheric Pressure Birds Body Temperature Regulation - physiology Erythrocytes Hemoglobin Hemoglobins - chemistry Hemoglobins - metabolism High altitude Humans Mammals Medical Education Molecular adaptations Oxygen - blood Oxygen-affinity Protein Conformation Pulmonary Gas Exchange Pulmonary/Respiratory Reptiles Structure-Activity Relationship Vertebrates - physiology
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container_title	Respiratory physiology & neurobiology
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creator	Weber, Roy E
description	Abstract Vertebrates at high altitude are subjected to hypoxic conditions that challenge aerobic metabolism. O2 transport from the respiratory surfaces to tissues requires matching between the O2 loading and unloading tensions and the O2 -affinity of blood, which is an integrated function of hemoglobin's intrinsic O2 -affinity and its allosteric interaction with cellular effectors (organic phosphates, protons and chloride). Whereas short-term altitudinal adaptations predominantly involve adjustments in allosteric interactions, long-term, genetically-coded adaptations typically involve changes in the structure of the haemoglobin molecules. The latter commonly comprise substitutions of amino acid residues at the effector binding sites, the heme-protein contacts, or at intersubunit contacts that stabilize either the low-affinity (‘Tense’) or the high-affinity (‘Relaxed’) structures of the molecules. Molecular heterogeneity (multiple isoHbs with differentiated oxygenation properties) can further broaden the range of physico-chemical conditions where Hb functions under altitudinal hypoxia. This treatise reviews the molecular and cellular mechanisms that adapt haemoglobin-oxygen affinities in mammals, birds and ectothermic vertebrates at high altitude.
doi_str_mv	10.1016/j.resp.2007.05.001
format	Article
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O2 transport from the respiratory surfaces to tissues requires matching between the O2 loading and unloading tensions and the O2 -affinity of blood, which is an integrated function of hemoglobin's intrinsic O2 -affinity and its allosteric interaction with cellular effectors (organic phosphates, protons and chloride). Whereas short-term altitudinal adaptations predominantly involve adjustments in allosteric interactions, long-term, genetically-coded adaptations typically involve changes in the structure of the haemoglobin molecules. The latter commonly comprise substitutions of amino acid residues at the effector binding sites, the heme-protein contacts, or at intersubunit contacts that stabilize either the low-affinity (‘Tense’) or the high-affinity (‘Relaxed’) structures of the molecules. Molecular heterogeneity (multiple isoHbs with differentiated oxygenation properties) can further broaden the range of physico-chemical conditions where Hb functions under altitudinal hypoxia. 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O2 transport from the respiratory surfaces to tissues requires matching between the O2 loading and unloading tensions and the O2 -affinity of blood, which is an integrated function of hemoglobin's intrinsic O2 -affinity and its allosteric interaction with cellular effectors (organic phosphates, protons and chloride). Whereas short-term altitudinal adaptations predominantly involve adjustments in allosteric interactions, long-term, genetically-coded adaptations typically involve changes in the structure of the haemoglobin molecules. The latter commonly comprise substitutions of amino acid residues at the effector binding sites, the heme-protein contacts, or at intersubunit contacts that stabilize either the low-affinity (‘Tense’) or the high-affinity (‘Relaxed’) structures of the molecules. Molecular heterogeneity (multiple isoHbs with differentiated oxygenation properties) can further broaden the range of physico-chemical conditions where Hb functions under altitudinal hypoxia. This treatise reviews the molecular and cellular mechanisms that adapt haemoglobin-oxygen affinities in mammals, birds and ectothermic vertebrates at high altitude.</abstract><cop>Netherlands</cop><pub>Elsevier B.V</pub><pmid>17561448</pmid><doi>10.1016/j.resp.2007.05.001</doi><tpages>11</tpages></addata></record>
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subjects	Acclimatization - physiology Allosteric interactions Altitude Amino acid substitutions Amphibians Animals Atmospheric Pressure Birds Body Temperature Regulation - physiology Erythrocytes Hemoglobin Hemoglobins - chemistry Hemoglobins - metabolism High altitude Humans Mammals Medical Education Molecular adaptations Oxygen - blood Oxygen-affinity Protein Conformation Pulmonary Gas Exchange Pulmonary/Respiratory Reptiles Structure-Activity Relationship Vertebrates - physiology
title	High-altitude adaptations in vertebrate hemoglobins
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