1 / 26

Sept. 20 , 2013

Harvesting Chemical Energy from Sugar, Part 2. Sept. 20 , 2013. Agenda. Administrative Stuff A Quick Review: ATP, Glycolysis , Enzymes , NAD + /NADH Oxidation and Reduction Breaking Down Sugar Further (Citric Acid Cycle) Harvesting High-Energy Electrons (Electron Transport Chain)

tex
Télécharger la présentation

Sept. 20 , 2013

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Harvesting Chemical Energy from Sugar, Part 2 Sept. 20, 2013

  2. Agenda • Administrative Stuff • A Quick Review: ATP, Glycolysis, Enzymes, NAD+/NADH • Oxidation and Reduction • Breaking Down Sugar Further (Citric Acid Cycle) • Harvesting High-Energy Electrons (Electron Transport Chain) • Wrap-up

  3. Test Yourself On your index card, briefly answer the following: What is the function of glycolysis? Does glycolysis happen inside or outside of the mitochondria? What is ATP, and what is it for?

  4. ATP: A Cellular “Battery”

  5. Understanding Glycolysis

  6. Glycolysis: Inputs and Outputs ?????

  7. NAD+: An Electron Carrier NAD+ is a molecule that can be used to carry electrons and store chemical energy. Not as generally useful as ATP, though. Two electrons are transferred together with an H+ to turn NAD+ into NADH. FYI: The “A” in NADH is adenine, the “A” DNA base (in GTAC) and the A in ATP! Evolution re-uses chemicals a lot!

  8. Getting the Most out of Glucose At the end of glycoysis, we were left with two molecules each of NADH and pyruvic acid. In bacteria, fermentation might follow to get rid of the NADH. But eukaryotic cells can harvest more energy by pulling electrons off of these molecules. Which substance is used to grab electrons from these molecules? Make a guess!

  9. Burn the Pyruvic Acid with Oxygen! … but don’t burn it suddenly. Respiration is a kind of “slow burn,” a gradual transfer of electrons to oxygen. By passing electrons from glucose and its pieces to oxygen gradually, we can harvest the chemical energy it stores. We use NADH to pass these electrons!

  10. Two Useful Terms for “Electron Grabbing” If something gains an electron, will its charge become more positive or negative? Its charge becomes negative, so we say it is reduced. If something loses electrons (like sugar being burned in oxygen), we say it is oxidized. Oxygen is good at oxidizing nutrients! Mnemonic: LEO says GER GER… Lossof Electrons = Oxidation Gainof Electrons = Reduction

  11. Examples of Oxidation + Reduction Iron + Oxygen -> Iron Oxide (Rust) Batteries use the oxidation of metal to move electrons!

  12. Practice! GER… Lossof Electrons = Oxidation Gainof Electrons = Reduction 1) Is NAD+oxidized or reduced during glycolysis? 2) Which atom is oxidized here?

  13. Respiration = A Reduction + Oxidation Reaction

  14. Don’t Forget the Big Picture:

  15. Oxidizing Some Carbon (and harvesting NADH) Follow the carbon! This is the first place where we released any CO2 waste!

  16. The Citric Acid Cycle: Don’t Panic!

  17. The Citric Acid Cycle: Don’t Panic! What are the most important things to know about the citric acid cycle? A two-carbon compound (acetyl CoA) goes into the mitochondrion. Two carbons are oxidized to CO2. Carbon is balanced! It only makes a little ATP compared to later stages. Makes NADH and FADH2! FADis an electron carrier… just like NAD+.

  18. How are these processes similar? How are these processes different?

  19. Harvesting Electrons

  20. When substances move from higher concentration to lower concentration, we call that “moving down a concentration gradient.” This movement releases energy, which can be used to do work! In mitochondria, differences in H+ across the “folds” are used to drive the making of ATP from ADP.

  21. The Electron Transport Chain: A Molecular “Waterwheel”

  22. Simplified Version:

  23. How Much ATP Do We Get from One Molecule of Glucose?

  24. On Wednesday: Essay due! Lab practical for Wednesday section! Lecture exam on Friday the 27th. Special class: Putting It All Together – real-world research and applications of what we’ve doneso far. Review + Activities + Real Science.

More Related