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Cellular Biochemistry and Metabolism (CLS 333 ) Dr. Samah Kotb Nasr Eldeen
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The Oxidative Degradation of Fatty Acids in Animal Tissues Chapter 10
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INTRODUCTION
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Lipids are a group of naturally occurring molecules that include fats, waxes, sterols, fat-soluble vitamins (such as vitamins A, D, E, andK),monoglycerides,diglycerides,triglycerides, phospholipids and others.
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The main biological functions of lipids include storing energy, signaling, and acting as structural components of cell membranes.
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The Oxidative Degradation of Fatty Acids in Animal Tissues There are 2 major lipid molecules that are regarded as rich sources of energy in animal tissues. These are: 1. Triglycerides 2. Free fatty acids
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Triglycerides have the highest energy content of the major nutrients (9 kcal/g ). Triglycerides are deposited in cells as fat droplets present in adipose tissue. 40% of the daily energy requirements in humans are met by dietary triglycerides.
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The Oxidative Degradation of Fatty Acids in Animal Tissues The liver, heart & skeletal muscle obtain half of their energy requirements from the catabolism of triglycerides. Excess carbohydrates after glycogen storage are converted into triglycerides.
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Chemistry of triglycerides: - fatty acid esters of glycerol
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95% of the biologically available energy of triglycerides is derived from the 3 fatty acid molecules. Only 5% is provided by the glycerol backbone.
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Chemistry of fatty acids: Fatty acids are long hydrocarbon acyl chains that terminate with a carboxyl group at one end and a methyl group at the other:-
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Chemistry of fatty acids:
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Different fatty acids differ in: 1. Length of chain. 2. Presence or absence of double bonds (saturated & unsaturated). 3. Number and positions of double bonds.
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Degradation of fatty acids: 1. Degradation of fatty acids involves a process of fragmentation starting at the β carboxyl group of fatty acids. There is successive removed of 2 C units that appear as acetyl- CoA molecules. This process of fragmentation is repeated sufficient number of times until all the fatty acid is fragmented into acetyl- CoA.
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2. The process of fragmentation requires ATP. The fatty acid chain is changed into a fatty acyl-CoA derivative in an enzymatically catalyzed reaction that requires ATP.
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Degradation of fatty acids: The enzyme is present on the outer mitochondrial membrane. As a result of this reaction:- A. The fatty acid becomes activated (ready for fragmentation). B. Is able to cross the double mitochondrial membrane into the matrix where the process of fragmentation occurs.
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Degradation of fatty acids: 3. The process of fragmentation involves oxidative removal of successive 2 C units by a catabolic pathway made of 4 reactions known as β-oxidation.
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β-oxidation will repeat it self sufficient member of times (known as PASSES) until all the fatty acid chain becomes fragmented into acetyl-CoA molecules.
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4. Finally the acetyl-CoA molecules will enter the TCA cycle for complete degradation into CO 2
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Degradation of fatty acids:
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Reactions of β-oxidation:- 1.The First Dehydrogenation Step. 2.The Hydration Step. 3.The Second Dehydrogenation Step. 4.The Cleavage Step.
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Degradation of fatty acids:
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Bioenergetics of fatty acid oxidation As seen from pathway every pass (turn) of β-oxidation will yield 5 ATP molecules. Thus complete degradation of 1 molecule of palmitic acid (C:16) will produce:- Stage 1: (16/2) -1 = 7 Passes of β-oxidation. = 7 × 5 = 35 ATP molecules. Stage 2: (16/2) = 8 acetyl-CoA molecules. = 8 × 12 = 96 ATP molecules. Thus Net ATP gain = 35 + 96 = 131 ATP molecules.
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Bioenergetics of fatty acid oxidation The longer the fatty acid chain the higher the number of ATP molecules synthesized.
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If the fatty acid is unsaturated auxillary enzyme are required to remove the double bond. Once this is done the normal β- oxidation enzymes will come into play. Number of ATP molecules synthesized still depends on the number of C atoms making up the fatty acid.
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