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Cellular Respiration Cell Respiration Chapter 5 • Release of energy in biomolecules (food) and use of that energy to generate ATP ENERGY (food) + ADP + Pi → ATP • Two methods of breaking down food – Aerobic Respiration: oxygen utilizing – Anaerobic Respiration: no oxygen used Aerobic Respiration • Uses oxygen in breakdown of materials and release of energy – C6H12O6 (glucose) + 6O2 → 6CO2 + 6H2O + Energy • Energy is released in small increments via long metabolic pathways – Allows cells to efficiently release and use energy contained in food molecules Aerobic Respiration: Overview • Glycolysis – glucose → pyruvate • Krebs Cycle – formation of electron carriers and CO2 • Oxidative Phosphorylation – electron carriers used to generate ATP Glycolysis Glycolysis • Occurs in cytoplasm of the cell • Breakdown of one glucose molecule into two pyruvate molecules • Yields 2 ATP molecules (net) and 2 NADH molecules NAD+ NADH 2ADP 2ATP Pyruvate (3C) Glucose (6C) 2ATP 2ADP Pyruvate (3C) NAD+ NADH 2ADP 2ATP NADH = high-energy electron carrier 1 Glycolysis Kreb’s Cycle • Glucose → pyruvate • 2 NAD+ + 2H+ + 4e- → 2 NADH • 2 ADP + 2 Pi→ 2 ATP • Occurs in the mitochondrial matrix • Cyclical series of reactions Krebs Cycle: Acetyl-CoA Formation Krebs Cycle (The Cycle Itself) • Acetyl-CoA (2C) linked to oxaloacetic acid (4C), to form citric acid (6C) • Citric acid ultimately converted into oxaloacetic acid + 2CO2 • 1 GTP, 3 NADH and 1 FADH per each acetylCoA • Pyruvate transported into mitochondrial matrix • CO2 cleaved off of pyruvate, forming acetate • Acetate linked to Coenzyme A (CoA) to form acetyl-CoA • One NADH formed for each pyruvate Krebs Cycle Citrate (6C) NAD+ NADH Pyruvate (3C) Krebs Cycle Acetyl-CoA (2C) CO2 Oxaloacetate (4C) CO2 • 3 CO2, 1 GTP, 4 NADH and 1 FADH2 produced for each pyruvate molecule. 3NAD+ 3NADH FAD+ FADH2 • Total: 6CO2, 2 GTP, 8 NADH, 2FADH2 GDP GTP CO2 FADH2 – high energy electron carrier GTP – similar to ATP, can be converted to ATP 2 Oxidative Phosphorylation • Occurs across the inner mitochondrial membrane • Electrons from NADH and FADH2 are transported along an electron transport chain • Energy released used to produce ATP Oxidative Phosphorylation • H+ pumped from inside the membrane to the outside – forms [H+] gradient (more outside than inside) • H+ flows back in through ATP synthase – generates ATP • Electrons and H+ received by O2 – forms H2O Overall Reaction for Aerobic Respiration C6H12O6 + 6O2 → 6CO2 + 6H2O How Much ATP is Produced Per Glucose Molecule? Glycolysis Krebs Cycle (2 GTP) Oxidative Phosphorylation TOTAL Triglyceride Catabolism • Fatty acids are converted into acetyl-CoA • Large amounts of ATP produced per fatty acid 2 ATP 2 ATP 26 ATP 30 ATP Amino Acid Catabolism Different amino acids can be converted into various Krebs Cycle intermediates 3 Anaerobic Respiration Glycolysis in Anaerobiosis • Produce ATP in the absence of O2 • Glucose → Pyruvate • Used regularly by skeletal muscle fibers and RBCs • Net 2 ATP produced • NAD+ → NADH • Two steps: • Need NAD+ to drive glycolysis! – Glycolysis - produce ATP – Lactate Formation – regenerate NAD+ Lactate Formation • Pyruvate → Lactate • NADH → NAD+ • Glycolysis can continue How Much ATP is Produced Per Glucose Molecule? Glycolysis 2 ATP TOTAL 2 ATP • Most of the energy from glucose is still present in the lactate • Lactate accumulation leads to ↓ pH 4