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*Not actual electric plug. For illustrative purposes only. CELLULAR RESPIRATION Chapter 9 Getting energy out of glucose! Adenosine Triphosphate (ATP) Adenine + ribose + phosphates Energy stored in high energy bonds between phosphates (typically last bond used) RNA Nucleotide! (+ 2 Pi) ATP = source of energy in cell Energy + (H /electron) carriers NAD+/NADH, FAD+/FADH2, NADP+/NADPH Can gain & lose hydrogen and electrons Remember: H for HIGH ENERGY! Oxidation & Reduction Oxidizing a molecule decreases the amount of energy in the molecule Remove H, remove electrons, add oxygen Reducing a molecule increases the amount of energy in the molecule Add H, add electrons, remove oxygen Cellular Respiration Releasing energy stored in glucose Used to charge up ATP (for cell to use) Series of reactions (can’t release all at once) Glycolysis, Fermentation (anaerobic repiration) Glycolysis, Krebs Cycle, Electron Transport Chain Glycolysis Decomposition of glucose to pyruvic acid (pyruvate) Releasing some of the stored energy from glucose Occurs in cytoplasm Requires input of 2 ATP Charges up 2 NADH Charges up 4 ATP Net: 2 NADH & 2 ATP PGAL = G3P INVESTMENT PHASE ENERGY HARVESTED Aerobic vs. Anaerobic Aerobic = in presence of oxygen Pyruvate travels to mitochondria for cellular respiration More ATP can be generated via Krebs & ETC Anaerobic = no oxygen present used to regenerate NAD+ No additional ATP made, but allows Glycolysis to continue Pyruvate Cellular Respiration (aerobic) Mitochondrion Krebs Cycle Remaining energy extracted from pyruvate Exhale CO2 as waste Occurs in matrix of mitochondria Generates ATP Generates NADH & FADH2, will go to Electron Transport Chain to generate ATP Preprocessing Step (before Krebs) Energy required to transport into mitochondria Oxidation of pyruvate to acetyl-CoA Generates 1 NADH & 1 CO2 Krebs Cycle (Citric Acid Cycle) Acetyl-CoA + OAA → citric acid Citric acid → OAA Series of oxidizing reactions CO2 exhaled as waste product Generates ATP Generates NADH & FADH2 OAA rengenerated to accept new acetyl-CoA Electron Transport Chain Uses energy from NADH & FADH2 to generate ATP Occurs in inner mitochondrial membrane Chemiosmosis (proton gradient & ATP synthase) Oxygen is final electron acceptor (generates water) Substrate Level vs. Oxidative Phosphorylation ATP Accounting Each NADH → 3 ATP & each FADH2 → 2 ATP Glycolysis 2 ATP (substrate level phosphorylation) 2 NADH → 4 ATP (oxidative phosphorylation in ETC) costs 2 to transport pyruvate into mitochondria! Pyruvate → acetyl-CoA 2 NADH → 6 ATP (oxidative phosphorylation in ETC) Krebs Cycle 2 ATP (substrate level phosphorylation) 6 NADH → 18 ATP (oxidative phosphorylation in ETC) 2 FADH2 → 4 ATP (oxidative phosphorylation in ETC) TOTAL THEORETICAL: 36 ATP (actual ~30 ATP) Fermentation Anaerobic: in ABSENCE of oxygen No electron acceptor at the end of ETC NADH accumulates, NAD+ depleted Krebs & glycolysis stop w/o NAD+ No ATP production (will cause cell death) Regenerates NAD+ so that glycolysis can continue Fermentation produces NO ATP Glycolysis uses NAD+ to produce 2 ATP Occurs in cytoplasm (alongside glycolysis) 2 types: Alcohol & Lactic Acid Alcohol Fermentation Occurs in plants, fungi (yeast), & bacteria Produces CO2, NAD+, and ethyl alcohol (ethanol) Lactic Acid Fermentation Produces NAD+ and lactic acid (lactate) In animals, most lactate is transported to the liver (converted to glucose when extra ATP available) Fermented Beverages Respiration of other molecules Cell can respire proteins and fats when sugars are not readily available Proteins are broken down to create pyruvate, acetylCoA, or other Krebs intermediates; ammonia (NH3) is generated as waste Fats are broken down into G3P and acetyl-CoA