Hemoglobin function in the vertebrates: an evolutionary model
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Summary
Vertebrate hemoglobin evolved from a monomer to a tetramer, gaining cooperativity and Bohr effect. Organic phosphate regulation shifted from ATP to DPG and IP5, adapting to red blood cell metabolic changes.
Area of Science:
- Biochemistry
- Evolutionary Biology
- Physiology
Background:
- Hemoglobin's quaternary structure, cooperativity, Bohr effect, and organic phosphate regulation vary across vertebrates.
- Understanding hemoglobin's functional evolution provides insights into vertebrate adaptation.
Purpose of the Study:
- To deduce a phylogeny of hemoglobin function in vertebrates.
- To propose evolutionary pathways for hemoglobin structure and function.
Main Methods:
- Comparative analysis of existing data on vertebrate hemoglobins.
- Phylogenetic reconstruction based on functional characteristics.
Main Results:
- A proposed evolutionary path from monomeric to dimeric (e.g., lamprey) and finally tetrameric hemoglobin.
- Early tetrameric hemoglobins likely dissociated into dimers upon oxygenation.
- Organic phosphate binding sites evolved early, with ATP as the initial regulator, later switching to DPG and IP5.
Conclusions:
- Hemoglobin's functional complexity evolved through a series of amino acid substitutions and gene duplications.
- Changes in red blood cell metabolism influenced the evolution of hemoglobin's allosteric effectors.
- The shift from ATP to DPG/IP5 regulation reflects adaptation to varying metabolic conditions in vertebrates.