Description
1. X-ray allows one to determine the 3D coordinates of every atom in the crystal to within Angstroms.
2. Nuclear magnetic resonance (NMR) is a technique that uses the spin of certain nuclei, such as protons to study structure. It has the advantage of providing structural information about molecules in aqueous solution, instead of in crystal form.
Highlights Hemoglobin
1. Myoglobin and hemoglobin are related proteins involved in storing and carrying oxygen in the body.
2. Myoglobin is a single subunit protein with high affinity for oxygen. It holds oxygen tighter than hemoglobin and serves in a battery-like capacity in tissues to release oxygen when tissue oxygen concentration is very low. Myoglobin can take oxygen from hemoglobin.
3. Hemoglobin is a four-subunit protein complex (two alpha subunits and two beta subunits) that serves to carry oxygen from the lungs to the tissues where it is needed. Hemoglobin is genetically related to myoglobin and is evolutionarily derived from it.
4. Myoglobin and hemoglobin both have porphyrin rings (like in chlorophyll) to hold ferrous (Fe++) iron. Ferrous iron is the form of iron involved in carrying oxygen. Heme is a term used to describe the protoporphyrin IX complexed with iron.
5. The iron in hemoglobin and myoglobin is held in place by four nitrogens of the protoporphyrin IX ring and a histidine. Oxygen is carried between the iron and an additional histidine not involved in holding the iron.
6. If one plots the percentage of oxygen sites bound versus partial pressure for myoglobin, a hyperbolic curve is generated, consistent with a molecule with a single binding site and a high affinity for oxygen. The P50, which is the partial pressure of oxygen necessary to fill 50% of the myoglobins with oxygen, is very low for myoglobin, consistent with high affinity. Because myoglobin has high affinity for oxygen, it doesn't release much oxygen until it is in an environment with very low oxygen pressure. For this reason, it would be a poor oxygen transport protein.
7. Hemoglobin is much better designed to meet an organism's physiological needs for carrying oxygen than myoglobin. This is due to its four-subunit organization (one heme per subunit and one oxygen carried per subunit) which behaves in a cooperative fashion in binding oxygen.
8. Binding of oxygen by the iron atom causes it to be pulled 'up' slightly. This, in turn, causes the histidine attached to it to change position slightly, which causes all the other amino acids in the subunit to change slightly. The changes in shape (different 'states') result in the protein gaining affinity for oxygen as more oxygen is bound. The phenomenon is referred to as cooperativity.
9. Hemoglobin can exist in a "tight" state, called 'T', which exhibits low oxygen binding affinity. Hemoglobin in the T state will tend to release oxygen.
10. A second state of hemoglobin is the "relaxed" or R state, which exhibits increased oxygen binding affinity. Binding of oxygen by hemoglobin flips it from the T to the R state and release of oxygen by hemoglobin helps it to flip from R to T.
11. 2,3-bisphosphoglycerate (2,3 BPG) is produced by actively respiring tissues. It can bind in the gap in the center of the hemoglobin molecule and in doing so, stabilize the T state and favor the release of oxygen. Thus, tissues that are actively respiring get more oxygen. 2,3 BPG is in higher concentration in the blood of smokers.
12. Fetal hemoglobin differs from adult hemoglobin in having two gamma subunits in place of the two beta subunits that adults have. This changes the hemoglobin molecule such at 2,3BPG can't bind, so fetal hemoglobin exists more in the R state and thus has a higher affinity for oxygen than adult hemoglobin. Thus, the fetus can take oxygen from the mother's hemoglobin.
13. The Bohr effect describes physiological and molecular responses to changes in pH with respect to oxygen and carbon dioxide in the body. The oxygen effects arise from changes in the tertiary structure of hemoglobin arising from binding of protons to histidines in the molecule when under low pH.
14. Rapidly metabolizing tissues (such as muscle) generate low pHs, due to release of carbon dioxide and the conversion of this to carbonic acid by carbonic anhydrase. Carbonic acid readily loses a proton, becoming bicarbonate.
15. Thus, rapidly metabolizing tissues generate protons, which get absorbed by hemoglobin, which releases oxygen to feed the tissues.
16. CO2 can also be taken up by hemoglobin at amine residues, causing protons to be released. Note that CO2 binds hemoglobin at a site other than what oxygen binds. CO, however, can compete with oxygen for binding to the heme.
17. In the lungs, a reversal of this process occurs.
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