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Understand the key concepts of cellular respiration including glycolysis, citric acid cycle, electron transport chain, and ATP synthesis. Learn about redox reactions, energy pathways, and the role of enzymes in energy production.
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Chapter 9 Warm-Up Define: • Glycolysis • Respiration • Chemiosmosis • Phosphorylation • Fermentation • ATP (draw and label) • Electrochemical gradient • FAD FADH2 • NAD+ NADH • What is the role of phosphofructokinase? How does it “work”? • Explain “glycolysis”. Where does it occur? How does it “work”?
Chapter 9 Warm-Up • What is the chemical equation for cellular respiration? • Remember: OILRIG • In the conversion of glucose and oxygen to CO2 and H2O, which molecule is reduced? • Which is oxidized? • What happens to the energy that is released in this redox reaction? • NAD+ is called a(n) ________________. Its reduced form is _______.
Chapter 9 Warm-Up • Why is glycolysis considered an ancient metabolic process? • Where in the cell does glycolysis occur? • What are the reactants and products of glycolysis? • Which has more energy available: • ADP or ATP? • NAD+ or NADH? • FAD+ or FADH2?
Chapter 9 Warm-Up • What is 1 fact you remember from yesterday’s sugar article? • Where does the Citric Acid Cycle occur in the cell? • What are the main products of the CAC?
AP Lab Warm-Up • What are 3 ways respiration can be measured? • What is the purpose of using KOH (potassium hydroxide) in this lab? • What are the Independent and Dependent Variables for Graph 5.1?
Chapter 9 Warm-Up • How is the proton gradient generated? • What is its purpose? • Describe how ATP synthase works. • In cellular respiration, how many ATP are generated through: • Substrate-level phosphorylation? • Oxidative phosphorylation?
Chapter 9 Warm-Up • In fermentation, how is NAD+ recycled? • What is the function of the enzyme phosphofructokinase? • You eat a steak and salad. Which macromolecule cannot be broken down to make ATP? • Explain where the fat goes when you lose weight.
What you need to know: • The summary equation of cellular respiration. • The difference between fermentation and cellular respiration. • The role of glycolysis in oxidizing glucose to two molecules of pyruvate. • The process that brings pyruvate from the cytosol into the mitochondria and introduces it into the citric acid cycle. • How the process of chemiosmosis utilizes the electrons from NADH and FADH2 to produce ATP.
In open systems, cells require E to perform work (chemical, transport, mechanical) E flows into ecosystem as Sunlight Autotrophs transform it into chemical E O2 released as byproduct Cells use some of chemical E in organic molecules to make ATP E leaves as heat
Catabolic Pathway Simpler waste products with less E Complex organic molecules Some E used to do work and dissipated as heat
Respiration: exergonic (releases E) C6H12O6 + 6O2 6H2O + 6CO2 + ATP(+ heat) Photosynthesis: endergonic (requires E) 6H2O + 6CO2 + Light C6H12O6 + 6O2
Redox Reactions (oxidation-reduction) oxidation (donor) lose e- Xe- + Y X + Ye- • Oxidation = lose e- • Reduction = gain e- C6H12O6 + 6O2 6H2O + 6CO2 + OiLRiG or LeoGer oxidation ATP reduction (acceptor) gain e- reduction
Energy Harvest • Energy is released as electrons “fall” from organic molecules to O2 • Broken down into steps: Food (Glucose) NADH ETC O2 • 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
Substrate-Level Phosphorylation • Generate small amount of ATP • Phosphorylation: enzyme transfers a phosphate to other compounds • ADP + Pi ATP P compound
Stages of Cellular Respiration • Glycolysis • Pyruvate Oxidation + Citric Acid Cycle (Krebs Cycle) • Oxidative Phosphorylation (electron transport chain (ETC) & chemiosmosis)
Cellular Respiration Stage 1: Glycolysis
Glycolysis • “sugar splitting” • Believed to be ancient (early prokaryotes - no O2 available) • Occurs in cytosol • Partially oxidizes glucose (6C) to 2 pyruvates (3C) • Net gain: 2 ATP +2NADH • Also makes 2H2O • No O2 required
Glycolysis Stage 1: Energy Investment Stage • Cell uses ATP to phosphorylate compounds of glucose Stage 2: Energy Payoff Stage • Two 3-C compounds oxidized • For each glucose molecule: • 2 Net ATP produced by substrate-level phosphorylation • 2 molecules of NAD+ NADH
Glycolysis (Summary) glucose 2 NAD+ 2 NADH + 2H+ 2 ATP 2H2O ADP P 2 pyruvate (3-C) C3H6O3
Mitochondrion Structure Citric Acid Cycle (matrix) ETC (inner membrane)
Cellular Respiration Stage 2: Pyruvate Oxidation + Citric Acid Cycle
Pyruvate Oxidation • Pyruvate Acetyl CoA (used to make citrate) • CO2 and NADH produced
Citric Acid Cycle (Krebs) • Occurs in mitochondrial matrix • Acetyl CoA Citrate • Net gain: 2 ATP,6 NADH, 2 FADH2(electron carrier) • ATP produced by substrate-level phosphorylation CO2
Cellular Respiration Stage 3: Oxidative Phosphorylation
http://multimedia.mcb.harvard.edu/anim_mitochondria.html BioVisions at Harvard:The Mitochondria
Oxidative Phosphorylation Electron Transport Chain Chemiosmosis H+ ions pumped across inner mitochondrial membrane H+ diffuse through ATP synthase (ADP ATP) • Occurs in inner membrane of mitochondria • Produces 26-28 ATP by oxidative phosphorylation via chemiosmosis
Electron Transport Chain (ETC) • Collection of molecules embedded in inner membrane of mitochondria • Tightly bound protein + non-protein components • Alternate between reduced/oxidized states as accept/donate e- • Does not make ATP directly • Ease fall of e- from food to O2 • 2H+ + ½ O2 H2O
As electrons move through the ETC, proton pumps move H+ across inner mitochondrial membrane
Chemiosmosis: Energy-Coupling Mechanism • Chemiosmosis = H+ gradient across membrane drives cellular work • Proton-motive force: use proton (H+) gradient to perform work • ATP synthase: enzyme that makes ATP • Use E from proton (H+) gradient – flow of H+ back across membrane
oxidative phosphorylation uses which couples chemiosmosis generates proton gradient ATP uses E to produce called redox reactions H+ pumped from matrix to intermembrane space proton motive force of ETC drives in which H+ e- passed down E levels through ATP synthase to final e- acceptor O2 H2O
ATP yield per molecule of glucose at each stage of cellular respiration
Anaerobic Respiration: generate ATP using other electron acceptors besides O2 • Final e- acceptors: sulfate (SO4), nitrate, sulfur (produces H2S) • Eg. Obligate anaerobes: can’t survive in O2 • Facultative anaerobes: make ATP by aerobic respiration (with O2 present) or switch to fermentation (no O2 available) • Eg. human muscle cells
Glycolysis Without O2 O2 present Fermentation Respiration Release E from breakdown of food with O2 Occurs in mitochondria O2 required(final electron acceptor) Produces CO2, H2O and up to 32 ATP • Keep glycolysis going by regenerating NAD+ • Occurs in cytosol • No oxygenneeded • Creates ethanol [+ CO2]or lactate • 2 ATP (from glycolysis)
Types of Fermentation Alcoholic fermentation Lactic acid fermentation Pyruvate Lactate Ex. fungi, bacteria, human muscle cells Used to make cheese, yogurt, acetone, methanol Note: Lactate build-up does NOT cause muscle fatigue and pain (old idea) • Pyruvate Ethanol + CO2 • Ex. bacteria, yeast • Used in brewing, winemaking, baking
Various sources of fuel • Carbohydrates, fats and proteins can ALL be used as fuel for cellular respiration • Monomers enter glycolysis or citric acid cycle at different points
Phosphofructokinase: • Allosteric enzyme that controls rate of glycolysis and citric acid cycle • Inhibited by ATP, citrate • Stimulated by AMP • AMP+ P + P ATP
ENERGY aerobic cellular respiration (with O2) anaerobic (without O2) glycolysis (cytosol) mitochondria Fermentation (cytosol) pyruvate oxidation ethanol + CO2 (yeast, some bacteria) substrate-level phosphorylation citric acid cycle lactic acid (animals) ETC oxidative phosphorylation chemiosmosis
