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Green River BIOL 211 - CELLULAR RESPIRATION

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Biol 211 – K. Marr Revised – Fall 2010 Page 1 of 6 Cellular Respiration Tutorial and Practice Problems The process by which your cells transfer the energy in organic compounds (glucose, starch, carbohydrates) to ATP, the byproduct of this reaction is water and carbon dioxide. It occurs in the cell's cytosol (cytoplasm) and the cell's mitochondria, the energy producer or "powerhouse" of the cell. Cellular Respiration occurs in three stages 1. Glycolysis 2. Krebs Cycle 3. Electron Transport Chain (oxidative phosphorylation) 1. Glycolysis (anaerobic: does not require oxygen) a. Occurs in the cytoplasm (cytosol) b. Glycolysis has 10 steps, each step is catalyzed by a different enzyme c. Glucose (6 carbons) is broken down into two pyruvate molecules (3 carbons each) d. ATP consuming phase: 2 ATP are consumed e. ATP producing phase: 4 ATP are produced f. NET GAIN OF 2 ATP g. NET GAIN OF 2 NADH o If O2 is available, each NADH can be used to make 3 ATP in oxidative phosphorylation (Electron Transport) Animation of Glycolysis - If you remember one thing about glycolysis, remember that starting with one molecule of glucose, C6H12O6, glycolysis yields 2 molecules of the 3-carbon acid, pyruvate (i.e. pyruvic acid) , 2 ATP, 2 NADH and does not require O2Biol 211 – K. Marr Revised – Fall 2010 Page 2 of 6 2. Krebs Cycle (also known as the CITRIC ACID CYCLE) (aerobic—requires oxygen!) a. Occurs in the matrix of the mitochondria b. The breakdown of glucose is completed and CO2 is produced c. In the presence of oxygen, the two pyruvate molecules produced by glycolysis travel to the mitochondria d. Krebs Cycle has 8 steps, each step is catalyzed by a different enzyme e. Each turn of the Krebs cycle requires the input of one 2-carbon acetyl-CoA and two carbons are released as CO2 o One glucose molecule entering glycolysis results in the production of 2 pyruvate molecules which are converted to 2 molecules of acetyl-CoA, o Each turn of the Krebs cycle uses only one acetyl-coA, so it takes two complete turns of the Krebs cycle per glucose f. The NADH and FADH2 created in the Krebs cycle are used by electron transport system to create large amounts of ____________ o 3 ATP per NADH and 2 ATP per FADH2 that enter electron transport Animation of Krebs Cycle - If you remember one thing about the Krebs cycle, remember each pyruvate molecule yields 4 NADH, 1 FADH2, 1 ATP and 3 CO2 molecules - Double this number, for each glucose molecule that enters glycolysis because the Krebs cycle makes 2 turns, one for each pyruvateBiol 211 – K. Marr Revised – Fall 2010 Page 3 of 6 3. The Electron Transport Chain (also known as oxidative phosphorylation) a. Produces the chemiosmotic energy that drives the synthesis of ATP in oxidative phosphorylation b. The E.T.C consists of molecules (mostly proteins) that are embedded in the inner membrane of the mitochondria c. Cofactors are attached to these proteins. The cofactors are alternately reduced and oxidized as they accept and donate electrons d. The initial electron acceptor in the chain is a flavoprotein (FMN) and it accepts 2 electrons from NADH. The electrons are then passed down a series of carrier protein molecules to oxygen gas, O2, which is the final electron acceptor. It is then combined with a two hydrogen ions, H+, to form water. E.T.C. will not function in the absence of oxygen . e. NADH and FADH2 both donate electrons to the chain f. The electron transport chain doesn't make any ATP itself, instead these reactions are coupled to others to produce ATP, a process called CHEMIOSMOSIS Inner membrane of the mitochondrion Intermembrane Space Mitochondrial Matrix View both of these animations! They will totally help you understand! Animation of Electron Transport Chain Another Animation of Electron Transport Chain The NET RESULTS of the Aerobic Respiration 1. Each NADH produces 3 ATP o Remember 8 NADH were created in the Krebs Cycle and 2 in Glycolysis 2. Each FADH2 produces 2 ATP (since FADH2 enters the ETC at a lower step) o Remember 2 FADH2 were created in the Krebs Cycle per glucose 3. Do the math: 34 ATP produced in the ETC + 2 from glycolysis + 2 from Krebs = 38 total ATP from each glucose 4. However....In some cells 2 ATP are used to move NADH into the mitochondria from the cytoplasm. Therefore, a grand total of 36 ATP produced from each glucose moleculeBiol 211 – K. Marr Revised – Fall 2010 Page 4 of 6 Anaerobic Respiration In the absence of oxygen the ETC cannot function (remember that oxygen, O2, is the final electron acceptor). Hence, under anaerobic conditions cells go through a process called FERMENTATION Fermentation takes place under anaerobic conditions (no oxygen present). There are two types of fermentation, alcoholic fermentation and lactic acid fermentation. Alcoholic Fermentation: occurs in yeasts, fungi and some bacteria. Pyruvate (C3)  Acetaldehyde (C2) + CO2 Acetaldehyde (C2) + NADH  2 Ethanol (C2) + NAD+ Lactic Acid Fermentation: occurs in some bacteria and oxygen deprived human muscle cells where lactate is produced as a waste product. Muscle cramps are caused by increased acidity caused by the lactate build up. NADH + Pyruvate (C3)  Lactic Acid (C3) + NAD+ Anaerobic Respiration 1. Glycolysis occurs, and pyruvate is produced. If pyruvate were to enter the Krebs cycle it would produce the H-carriers NADH and FADH2, CO2 and some ATP 2. The problem occurs in the ETC, because under anaerobic conditions there is no oxygen to be the final electron acceptor. 3. The ETC carrier proteins become saturated with electrons which prevent NADH from unloading the 2 electrons it carries—hence, NAD+ cannot be regenerated and NADH levels increase, while NAD+ levels decrease. 4. The primary goal of fermentation is to regenerate NAD+ since it is required for Glycolysis to function. Fermentation does not generate any ATP: Only 2 ATP per glucose are produced by glycolysis. Fermentation serves the sole purpose of regenerating NAD+ to keep glycolysis functioning.Biol 211 – K. Marr Revised – Fall 2010 Page 5 of 6 Cellular Respiration Self-Check Questions Source: Animations of Glycolysis, Krebs Cycle and Electron Transport: http://www.sumanasinc.com/webcontent/animations/content/cellularrespiration.html 1. 6. 2. 7.


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