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Cellular Respiration and Fermentation
Chapter 9 Unit 3
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Catabolic Pathways Fermentation Cell Respiration
Partial breakdown of sugars anaerobic Cell Respiration Most prevalent and efficient Complete breakdown of sugars aerobic
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Redox Reactions: Oxidation and Reduction
Transfer of e- from one reactant to another Oxidation: loss of electrons Reduction: addition of electrons to another substance Reducing agent: electron donor (C6H12O6) Glucose reduces oxygen which accepts the e- Oxidizing agent: electron acceptor (6O2) Oxidizes glucose by accepting the e- oxidation C6H12O O2 6H2O + 6CO2 reduction
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Energy Harvest via NAD+
Energy is released as electrons “fall” from organic molecules to O2 Broken down into steps: Coenzyme NAD+ = electron acceptor NAD+ picks up 2e- and 2H+ NADH (stores E) NADH carries electrons to the electron transport chain (ETC) ETC: transfers e- to O2 to make H2O ; releases energy
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Substrate-Level Phosphorylation
Phosphorylation: enzyme transfers a phosphate from a substrate to ADPother compounds Mode of ATP synthesis ADP + Pi ATP
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Stages of Cellular Respiration
Glycolysis Pyruvate oxidation and krebs Oxidative Phosphorylation: ETC and chemiosmosis
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Glycolysis “sugar splitting”
Believed to be ancient (early prokaryotes) Occurs in cytosol Partially oxidizes glucose (6C) to 2 pyruvates (3C) Net gain: 2 ATP + 2NADH Also makes 2H2O Anaerobic
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Occurs in two Phases Energy-investment phase: uses two molecules of ATP (5 steps) Energy yielding phase: produces four ATP molecules and reduces two molecules of NAD+ to NADH The junction between Glycolysis and the Krebs cycle is the oxidation of pyruvate to acetyl CoA. two acetyl fragments are produced
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Mitochondrion Structure
Citric Acid Cycle (matrix) ETC (inner membrane)
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Oxidation of Pyruvate Eukaryote-> mitochondria
Prokaryotes-> cytosol Pyruvate is converted to coenzyme A (acetyl CoA)
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Krebs Cycle (Citric acid cycle)
Occurs in the mitochondrial matrix aerobic Completes glucose oxidation by breaking down acetyl CoA into 3 molecules of carbon dioxide Net gain: 2 ATP, 6 NADH, 2 FADH2
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Krebs cycle Evolution Evolved later than glycolysis
bacteria 3.5 billion years ago (glycolysis) free O2 2.7 billion years ago (photosynthesis) eukaryotes 1.5 billion years ago (aerobic respiration = organelles mitochondria) Hans Krebs
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The Electron Transport Chain
electron-carrier molecules built into the inner mitochondrial membrane Does not make ATP directly Eases the fall of e- from food to oxygen Oxygen final electron acceptor
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Sequence of electron transfers along the electron transport chain
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Chemiosmosis ATP production
This is accomplished by creating a proton gradient ATP synthase Cristae H+ ADP + Pi
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How chemiosmosis works:
the electron transport chain creates the proton gradient by pumping H+ from the mitochondrial matrix the membrane’s phospholipid bilayer is impermeable to H+s and prevents back flow As protons diffuse through the ATP synthase complex phosphorylation of ADP occurs H+ ADP + Pi
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Anaerobic Respiration
Prokaryotes who live in environments w/o Oxygen Generate ATP using other electron acceptors besides O2 EX: sulfur reducing bacteria use sulfate ions at the end of their ETC Hydrogen sulfide is produced Rotten egg odor in salt marshes or mud flats
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Types of Fermentation Extension of glycolysis that allows continuous generation of ATP Types: Alcoholic Fermentataion: Pyruvate is converted to ethanol CO2 is released as it is converted to acetaldehyde Acetaldehyde is reduced by NADH to ethanol Regenerates NAD+ needed for glycolysis
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Lactic Acid Fermentation
Pyruvate is reduced by NADH to form lactate as an end product Lactate that accumulates in muscle cells was thought to cause muscle fatigue and pain, but now it is suggested that pain comes from increased levels of K+ Lactate appears to enhance muscle performance Lactate is carried by the blood to the liver where it is converted back to pyruvate.
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Anaerobes Obligate Anaerobes: carry out fermentation or anaerobic respiration Cannot survive in presence of Oxygen EX: vertebrate brain cells cannot carry out fermentation Facultative Anaerobes: use either fermentation or respiration Consumes more sugar when fermenting than respiring to make same amt. of ATP EX: yeast, bacteria, muscle cells
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Glycolysis Fermentation Respiration
Without O2 O2 present Fermentation Respiration Keep glycolysis going by regenerating NAD+ Occurs in cytosol No oxygen needed Creates ethanol [+ CO2] or lactate 2 ATP (from glycolysis) Release E from breakdown of food with O2 Occurs in mitochondria O2 required (final electron acceptor) Produces CO2, H2O and up to 32 ATP
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