User:Michael Roberts/BIOL115 Myo: Difference between revisions
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This next view simplifies things, and just shows a <scene name='User:Michael_Roberts/BIOL115_Myo/Secondary_structure/1'>cartoon representation </scene>of the secondary structure of the protein. | This next view simplifies things, and just shows a <scene name='User:Michael_Roberts/BIOL115_Myo/Secondary_structure/1'>cartoon representation </scene>of the secondary structure of the protein. | ||
Here, I've added in the <scene name='User:Michael_Roberts/BIOL115_Myo/ | Here, I've added in the <scene name='User:Michael_Roberts/BIOL115_Myo/H-bonds/1'>hydrogen bonds</scene> that maintain the secondary structure of the protein. | ||
'''THE GLOBIN FOLD''': | '''THE GLOBIN FOLD''': | ||
Revision as of 19:59, 12 April 2013
The heme group and oxygen binding in myoglobin.
Myoglobin is a protein whose function is to store oxygen in muscle tissues. Like heamoglobin, it is red in colour, and it is myoglobin that gives muscle its strong red colour.
Myoglobin was the first globular protein for which the 3-dimensional structure was solved, back in the late 1950s. It gives its name to the 'globin fold', a common alpha domain motif. An alpha domain is a structural region composed entirley of alpha-helix.
Click on the 'green links' in the text in the scrollable section below to examine this molecule in more detail.
MOLECULAR MODEL: The initial view here is a ball-and-stick representation of the molecular structure of myoglobin.
SECONDARY STRUCTURE: This next view simplifies things, and just shows a of the secondary structure of the protein. Here, I've added in the that maintain the secondary structure of the protein. THE GLOBIN FOLD: In this next view, the eight are each coloured differently. This gives you an impression of the classic globion fold. The α-helices pack together tightly, and there is very little space in the centre of the protein.
HYDROPHOBICITY: Globular folds like this are characterised by a polar, , which interacts with the aqueous solvent, and a hydrophobic core. Hydrophobic, Polar The next view shows a section through the protein that highlights the better. This view has been produced in the software by a process known as 'slabbing'. You can still rotate the molecule around - whatever view you see will the the front part of the view of the protein cut off.
THE HEME GROUP: Now let's turn our attention to the main function of myoglobin - oxygen binding. Oxygen is bound by a , which sits in a hydrophobic pocket in the myoglobin protein. Central to the heme group is an .
PROXIMAL AND DISTAL HISTIDINES: The iron atom sits either side of the side chains of two . One of these (coloured cyan) is attached to the iron atom, and is known as the proximal histidine. The other (green) is called the distal histidine.
OXYGEN: The space between the iron and the distal histidine is where the binds.
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