User:Eric Martz/Hemoglobin Quiz

Hemoglobin QuizHemoglobin Quiz

You will get immediate feedback when you click Submit. The quiz below is offered to accompany the interactive tutorial Hemoglobin Molecular Structure.

Suggestions to emartz at microbio dot umass dot edu.

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Answers to Questions in the TutorialAnswers to Questions in the Tutorial

Here are answers to the questions posed in green within the Hemoglobin Molecular Structure Tutorial.

1. The main function of hemoglobin is to transport oxygen from the lungs to tissues throughout the body.
2. Each hemoglobin molecule is made up of four protein chains.
3. Each chain in the hemoglobin molecule has a pocket to hold one heme-iron complex. Thus, there are four heme-iron complexes in each hemoglobin molecule.
4. Each of the heme-iron complexes can bind one O₂ molecule. Thus, each hemoglobin molecule can bind up to eight atoms of oxygen.
5. The four chains that make up one hemoglobin molecule are held together by non-covalent interactions (non-covalent bonds).
6. Each iron atom is held by five nitrogen atoms: four nitrogens in heme, plus one nitrogen in the sidechain of a histidine amino acid.
7. Molecular oxygen binds between iron (Fe⁺⁺) and a nitrogen in the sidechain of histidine. The oxygen-binding histidine is on the opposide side of the iron from the iron-binding histidine.
8. Alpha helices and loops (including turns) make up the alpha and beta chains of hemoglobin. They contain no beta strands or sheets.
9. Hydrogen bonds stabilize the conformation of an alpha helix.
10. Hydrogen bonds are non-covalent bonds.
11. Amphipathic means having one part that is hydrophobic, and another part that is hydrophilic.
12. Hydrophobic (literally "water fearing") means structures that avoid contact with water because such contact is energetically unfavorable. Hydrophobic structures are apolar. In contrast, hydrophilic structures favor contact with water molecules, usually because they can form hydrogen bonds with water. Hydrophilic structures include polar and charged structures.
13. The protein pocket that holds heme is predominantly hydrophobic, as is heme itself. Thus, the avoidance of contact with water is partly what holds the heme in the pocket. The histidine that contacts the iron in heme is an exception, since its sidechain is hydrophilic.
14. Protein chains or domains that are soluble in water, such as the alpha and beta chains of hemoglobin, have hydrophobic cores. Amino acids with hydrophilic sidechains are mostly on the surfaces of these chains.
15. The hydrophobic cores of proteins are devoid of water. It is the avoidance of water that drives amino acids with hydrophobic sidechains to pack together in the core, while the attraction of hydrophilic amino acids to water favors their locations on the surface of the folded protein chain.
16. A slightly acidic pH, around 6.5, increases the partial charges on the sidechains of histidines. This is because their sidechain [pKa's are about 6.5. In contrast, lysine and arginine have full positive charges at any physiological pH because their sidechain pKa's are 11-12, while aspartic acid and glutamic acid have full negative charges at any physiological pH because their sidechain pKa's are about 4.