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Ketone bodies Liver mitochondria have the capacity to convert acetyl CoA derived from fatty acid oxidation into ketone bodies which are: 1- Acetoacetic acid 2- β- hydroxy butyric acid 3- Acetone Functions of ketone bodies:
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Ketone bodies Liver mitochondria have the capacity to convert acetyl CoA derived from fatty acid oxidation into ketone bodies which are: 1- Acetoacetic acid 2- β-hydroxy butyric acid 3- Acetone Functions of ketone bodies: 1-Used as source of energy. They are reconverted into acetyl CoA which is oxidized in Kreb's cycle to give energy. 2- In prolonged fasting and starvation, ketone bodies can be used as source of energy by most tissues except liver. N.B. In fasting, most tissues get energy from oxidation of both ketone bodies and fatty acids, but the brain gets its energy from oxidation of ketone bodies. Brain never oxidizes fatty acids.
Synthesis of ketone bodies by the liver (Ketogenesis) Site of ketogenesis:Mitochondria of livercells due to high activity of HMG-CoAsynthase, HMG- CoA- lyase. Stepsof ketogenesis:See Figure (not required) 1- 3 molecules of acetyl CoA are condensed to give 3-hydroxy 3-glutaryl CoA (HMG CoA). This step is catalyzed by HMG CoAsynthase (the key enzyme) 2- HMG CoA is then broken by HMG CoAlyase enzyme to acetoacetate. 3- Part of acetoacetate is converted into acetone and part is converted into β-hydroxy butyric acid Notes on ketogenesis: 1- HMG- CoAsynthase is the rate limiting enzyme in the synthesis of ketone bodies and is present in significant amounts only in the liver. 3- Acetone is a volatile, nonmetabolized product that can be released in the breath.
Regulation of ketogenesis: Regulation of HMG-CoA synthase A- Inhibited after CHO diet (after meal): CHO diet inhibits HMG-CoA synthase. In addition, after meal, insulin is released and inhibits HMG-CoA synthase B- Simulated in fasting & starvation, low CHO diet, and in severe (uncontrolled) DM (insulin decrease): all these factors stimulate HMG-CoA synthase
For illustration HMG CoA → to extrahepatic tissues
Ketolysis (Use of Ketone bodies by peripheral tissues) Def. It is the complete oxidation (breakdown) of ketone bodies (β- hydroxybutyrate) into energy + CO2 + H2O Site: Mitochondria of the extrahepatic tissues. Oxidation not occurs in liver due to the absence of thiophorase in the liver. Ketolysis also not occur in RBCs due to lack of mitochondria. Briefly, ketolysis occur as follow: β- hydroxybutyrate ↔ Acetoacetate Acetoacetate + succinylCoA→acetoacetylCoA acetoacetylCoA + CoASH (Thiolysis reaction) → 2 Acetyl CoA→Kreb’s
1- The first step in ketolysis is the conversion of β- hydroxybutyrate into acetoacetate. 2- The second step is the activation of acetoacetate into acetoacetyl CoA. The source of CoA is succinyl CoA. This reaction needs enzyme called Thiophorase or called also Succinyl CoA-Acetoacetate CoA Transferase (meaning the enzyme that transfer CoA from succinyl CoA to acetoacetate). Thiophorase is present sufficiently in extra-hepatic tissues including brain. In contrast, the liver does not contain thiophorase, and therefore can’t oxidize ketone bodies or use them as a fuel. 3-The third step is thiolysis reaction involving the breakdown of acetoacetyl CoA into 2 acetyl CoA in the presence of CoASH and ketothiolase enzyme
Ketolysis (oxidation of ketonbodies) in extrahepatic tissues Thiophorase This enzyme is absent in liver
Ketosis Ketone bodies formed in the liver must be passed to blood to be oxidized. Normal blood ketone bodies must not exceed 1.5-2 mg%. Ketosis: is the increase of blood ketone bodies above normal levels. It occurs if the rate of ketogenesis increases and exceeds the rate of ketolysis. The excess ketone bodies pass to urine (ketonuria). Both acetoacetate and beta-hydroxybutyrate are acidic, and, if levels of these ketone bodies are too high, the pH of the blood drops, resulting in ketoacidosis. In severe cases of ketosis as in uncontrolled D.M. coma may be developed and the condition may be fatal.