Chapter 5 - Part 2 PDF
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Summary
This chapter details the human perspective on anaerobic and aerobic metabolism. It also explores oxidative phosphorylation and redox reactions. It is best suited to high school biology students.
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The Human Perspective: The Role of Anaerobic and Aerobic Metabolism in Exercise • ATP hydrolysis increases 100-fold during exercise, quickly exhausting ATP available. • Muscles used stored creatine phosphate (CrP) to rapidly generate but must rely on aerobic or anaerobic synthesis of new ATP for sus...
The Human Perspective: The Role of Anaerobic and Aerobic Metabolism in Exercise • ATP hydrolysis increases 100-fold during exercise, quickly exhausting ATP available. • Muscles used stored creatine phosphate (CrP) to rapidly generate but must rely on aerobic or anaerobic synthesis of new ATP for sustained activity. CrP + ADP Cr + ATP 93 Oxidative Phosphorylation in the Formation of ATP Summery of key events taking place in mitochondria • Mitochondria extract energy from organic materials and store it, temporarily, in the form of electrical energy (ionic gradient) • Mitochondria utilize an ionic gradient across their inner membrane to drive numerous energy-requiring activities, the synthesis of ATP • When ATP formation is driven by energy that is released from electrons removed during substrate oxidation, the process is called oxidative phosphorylation • Oxidative phosphorylation accounts for the production of more than 2x1026 (>60) kg of ATP in our bodies per day! 94 Redox Refresher • Redox Reactions: It is an electron transfer reactions where reduction and oxidation occurs simultaneously • • • In terms of oxygen: – Oxidation is the gain of oxygen – Reduction is the loss of oxygen In terms of hydrogen: – Oxidation is the loss of hydrogen – Reduction is the gain of hydrogen In terms of electrons: – Oxidation is the loss of electrons – Reduction is the gain of electrons Loss of electron OXIDATION Gain of electron REDUCTION A is oxidized because it lost electrons B is reduced because it gains electrons (REDUCING AGENT) (OXIDIZING AGENT) A e e Oxidation A Oxidize d Reduci ng agent B Oxidizi ng agent Reductio n e e B Reduce d 95 Oxidative Phosphorylation in the Formation of ATP Oxidation Reduction Potentials • Strong oxidizing agents have a high affinity for electrons; strong reducing agents have a weak affinity for electrons • Reducing agents are ranked according to electron-transfer potential – A high electron-transfer potential means a strong reducing agent • Oxidizing and reducing agents occur as couples (see next slide), such as NAD+ and NADH, which differ in their number of electrons Strong reducing agents are coupled with weak oxidizing agents and vice versa. For e.g. NAD + (of the NAD + -NADH couple) is a weak oxidizing agent-loss electrons, whereas O 2 (of the O 2 -H 2 O couple) is a strong oxidizing agent-gains electrons. • • The transfer of electrons between a couple causes charge separation that can be measured as an oxidation-reduction, or redox, potential by instruments that detect voltage. • Redox reactions are accompanied by a decrease in free energy. 96 Oxidative Phosphorylation in the Formation of ATP Oxidation Reduction Potentials Redox potential is the potential for a species to acquire or to donate electrons At pH 7, the standard redox potential is indicated by Eo’ rather than Eo. Those couples whose reducing agents are better donors of electrons are assigned more negative redox potentials (NAD+ NADH couple is -0.32) Acetaldehyde is a stronger reducing agent than NADH , Acetate-acetaldehyde couple has a standard redox potential of -0.58V. The couples whose oxidizing agents are better electron acceptors than NAD + have greater affinity for electrons and have more positive redox potentials. Redox potential of some reaction couples 97 Oxidative Phosphorylation in the Formation of ATP Electron Transport Five of the reactions from glycolysis to TCA cycle is catalyzed by dehydrogenases, enzymes that transfer pairs of electrons from substrates to coenzymes (such as NAD+ and FAD): & – Coenzymes: are organic molecules that bind loosely to the active site of an enzyme and aid in substrate recruitment. – Cofactors: a non-protein compound (inorganic) that is needed for an enzymes biological activity & Pyruvate dehydrogenase 1.Citrate synthase 2.Aconitase 3.Isocitrate dehydrogenase 4. -ketoglutarate dehydrogenase 5.Succinyl-CoA synthetase 6.Succinate dehydrogenase 7.Fumarase 8.Malate dehydrogenase Four of these reactions generate NADH and one produces FADH2 High-energy electrons associated with NADH or FADH2 are transferred through a series of specific electron carriers that constitute the 98 electron-transport chain of the inner mitochondrial membrane What are cofactors and coenzymes Enzyme Inorganic (Metal ions) Non protein component Cofactors Organic (Helper molecules) Not tightly bound with enzyme and release after catalysis the catalysis called coenzyme Mg+2 Holoenzyme Holoenzyme Tightly bound organic factor is called a prosthetic group Apoenzyme Coenzymes are derived from vitamins 99NADH, NADPH, FAD etc. Examples: Q) Name the active form of enzyme Holoenzyme Q)Name the inactive form of enzyme Apoenzyme 100 Select True/ False Without coenzymes or cofactors, enzymes cannot catalyze reactions effectively. True What do you called an enzyme when it loses its cofactor? apoenzyme 101 Oxidative Phosphorylation in the Formation of ATP Types of Electron Carrier • In the ETC, there are 5 types of membrane-bound electron carriers: • Flavoproteins • Cytochromes • Copper atoms • Ubiquinone • Iron-sulfur proteins • All their redox centres are prosthetic groups, except for ubiquinone • Most of these carriers are parts of larger complexes in the ETC 102 Oxidative Phosphorylation in the Formation of ATP Types of Electron Carrier 1. Flavoproteins are polypeptides bound to one of two prosthetic groups: – Flavin adenine dinucleotide (FAD) or – Flavin mononucleotide (FMN) – Prosthetic group is derived from Vit B2 (riboflavin) – FMN and FAD are capable of accepting and donating two protons and two electrons. Major flavoproteins of the mitochondria are NADH dehydrogenase of the electron-transport chain and succinate dehydrogenase of the TCA cycle. H+ + eH+ + eQuinone Semiquinone Hydroquinone 103 Fig 5.12 a Oxidative Phosphorylation in the Formation of ATP Types of Electron Carrier 2. Cytochromes contain heme prosthetic groups bearing Fe or Cu metal ions. The iron atom of a heme undergoes reversible transition between the Fe3+ and Fe2+ oxidation states as a result of the acceptance and loss of a single electron There are three distinct cytochrome types (a, b, and c) present in the electron-transport chain, which differ from one another by substitutions within the heme group Cytochrome c is a soluble protein in the intermembrane space 104 Fig 5.12 b Oxidative Phosphorylation in the Formation of ATP Types of Electron Carrier 4. Ubiquinone (coenzyme Q) is a lipid-soluble molecule. Each ubiquinone is able to accept and donate two electrons and two protons The partially reduced molecule is the free radical ubisemiquinone, and the fully reduced molecule is ubiquinol ( UQH 2 ). H+ + eUbiquinone H+ + eUbisemiquinone Ubiquinol Fig 5.12 c 105 Types of Electron Carrier 1.Flavoproteins (accept and donate 2e- and 2 H+) – derived from Vit B2 2. Cytochromes (accept and donate 1e- ) – soluble protein in the intermembrane space 3. Copper atoms (accept and donate 1e- ) 4.Ubiquinone (accept and donate 2e- and 2 H+) – lipid soluble molecule 5. Iron-sulfur proteins (accept and donate 1e- ) – iron atoms are linked 106 Oxidative Phosphorylation in the Formation of ATP How Did We Figure Out the Sequence of Events of the ETC? The specific sequence of carriers that constitute the electron-transport chain was worked out using a variety of inhibitors that blocked electron transport at specific sites along the route. After an inhibitor was added to cells, the oxidation state of the various electron carriers in the inhibited cells was determined. Thus, by identifying reduced and oxidized components in the presence of different inhibitors, the sequences of the carriers could be determined. Reduced state Oxidized state Fig 5.15: Inhibitors to determine the ETC carrier sequence 107 Practice Question Q) You are trying to figure out an electron transport pathway including the following electron transport molecules: B, K, T, Q and X. You do so by employing inhibitors for various steps in the process. When you do, you get the following results: Inhibitor Ticin Digitin Estin Lucin Electron Transport Molecules Trapped in Reduced Form Q&K K T, K, Q & B Q, K & T What is the order of the molecules (the pathway) in the electron transport chain suggested by the above data from the most reduced to the least reduced molecule? a) K —> T —> B —> Q —> X b) K —> X —> B —> Q —> T c) K —> Q —> T —> B —> X d) X —> B —> T —> Q —> K e) T —> B —> K —> Q —> X 108