Extremophile
From Proteopedia
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<StructureSection load='1mbn' size='350' side='right' caption='Structure of Myoglobin (PDB entry [[1mbn]])' scene='55/557585/Align_test/5'> | <StructureSection load='1mbn' size='350' side='right' caption='Structure of Myoglobin (PDB entry [[1mbn]])' scene='55/557585/Align_test/5'> | ||
| - | Myoglobin was the first solved protein structure and continues to be a classic in protein structure research, which has revealed much about protein dynamics, where myoglobin the protein breaths, if you will, as it changed conformations to take up oxygen and release it, in molecular imitation of our lungs movement. The <scene name='55/557585/Align_test/5'>classic myoglobin structure | + | Myoglobin was the first solved protein structure and continues to be a classic in protein structure research, which has revealed much about protein dynamics, where myoglobin the protein breaths, if you will, as it changed conformations to take up oxygen and release it, in molecular imitation of our lungs movement. The <scene name='55/557585/Align_test/5'>classic myoglobin structure</scene> was solved by John Kendrew in the mid-1900s. Myoglobin is a relatively small protein at 153(sometimes 154) amino acids, and immidiately one appreciates how the polypeptide <scene name='55/557585/Align_test/4'>chain folds over the heme ligand</scene>, cradling it between halves of the protein chain. |
Now, in a fascinating article<ref>DOI:10.1126/science.1234192</ref>, a team of researchers illuminate how behavior of animals across evolutionary time has been influenced by this <scene name='55/557585/Align_test/5'>classic protein</scene>. The researchers demonstrate that across the animal kingdom, aquatic animals have myoglobin protein with a great net positive charge than terrestrial animals. The calculate that for every increase in one positive net charge, the animal can accumulate a incredible additional ten times the amount of myoglobin in its cells (muscle cells, in fact), and for two more positive amino acids, the animal can actually accumulate 100 times more myoglobin. More myoglobin translates to more oxygen, which allows aquatic animals to hold their breath for long periods during dives underwater. While the exact mechanism is a fascinating area of ongoing research, it is apparent that myoglobin protein with a greater net positive charge remain soluble at much higher concentrations. | Now, in a fascinating article<ref>DOI:10.1126/science.1234192</ref>, a team of researchers illuminate how behavior of animals across evolutionary time has been influenced by this <scene name='55/557585/Align_test/5'>classic protein</scene>. The researchers demonstrate that across the animal kingdom, aquatic animals have myoglobin protein with a great net positive charge than terrestrial animals. The calculate that for every increase in one positive net charge, the animal can accumulate a incredible additional ten times the amount of myoglobin in its cells (muscle cells, in fact), and for two more positive amino acids, the animal can actually accumulate 100 times more myoglobin. More myoglobin translates to more oxygen, which allows aquatic animals to hold their breath for long periods during dives underwater. While the exact mechanism is a fascinating area of ongoing research, it is apparent that myoglobin protein with a greater net positive charge remain soluble at much higher concentrations. | ||
Revision as of 19:39, 23 November 2013
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- ↑ Mirceta S, Signore AV, Burns JM, Cossins AR, Campbell KL, Berenbrink M. Evolution of mammalian diving capacity traced by myoglobin net surface charge. Science. 2013 Jun 14;340(6138):1234192. doi: 10.1126/science.1234192. PMID:23766330 doi:http://dx.doi.org/10.1126/science.1234192
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Joseph M. Steinberger, Joel L. Sussman, Alexander Berchansky, Michal Harel
