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Integration of Metabolism: Review of Roles of Systems in Muscle Contraction

Integration of Metabolism: Review of Roles of Systems in Muscle Contraction. CARDIAC AND SKELETAL MUSCLE. Cardiac muscle is continuously active (always contracting) Cardiac muscle has completely aerobic metabolism Cardiac muscle contains negligible energy stores, e.g. glycogen and lipid).

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Integration of Metabolism: Review of Roles of Systems in Muscle Contraction

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  1. Integration of Metabolism:Review of Roles of Systems in Muscle Contraction

  2. CARDIAC AND SKELETAL MUSCLE • Cardiac muscle is continuously active (always contracting) • Cardiac muscle has completely aerobic metabolism • Cardiac muscle contains negligible energy stores, e.g. glycogen and lipid)

  3. CARBOHYDRATE METABOLISM • Glucose transport into muscle is increased after a carbohydrate-rich meal providing that insulin is secreted properly. Glucose is then readily phosphorylated to G-6-phosphate by hexokinase and subsequently is metabolized to provide energy needs. • During fasting (starvation) ketone bodies and fatty acids become the major fuels.

  4. Increased glycogen synthesis is more significant for the skeletal muscle rather than for the cardiac muscle.

  5. FAT METABOLISM • Ketone bodies and fatty acids released from chylomicrons and VLDL by lipoprotein lipase (in the well-fed state) become the major sources for fuels only when glucose levels and/or insulin release is/are inadequate.

  6. Synthesis of ketone bodies from acetyl CoA • Ketone bodies are synthesized from acetyl CoA. • Ketone body synthesis from acetyl CoA occurs in hepatic mitochondria. • First, acetoacetate is produced in a three-step process. • Acetoacetate can be reduced to β-hydroxybutyrate. • Acetone also arises in small amounts as a biologically inert side product.

  7. Synthesis from acetyl CoA: Step 1 • The first step is formation of acetoacetyl CoA in a reversal of the thiolase step of beta-oxidation.

  8. Synthesis from acetyl CoA: Step 2 • In the second step, a third molecule of acetyl CoA condenses with the acetoacetyl CoA, forming 3-hydroxy-3-methylglutaryl CoA (HMG CoA) in a reaction catalyzed by HMG CoA synthase.

  9. Synthesis from acetyl CoA: Step 3 • In the third step HMG CoA is cleaved to yield acetoacetate (a ketone body) in a reaction catalyzed by HMG CoA lyase (HMG CoA cleavage enzyme). One molecule of acetyl CoA is also produced.

  10. Synthesis from acetyl CoA: Acetoacetate • Subsequently acetoacetate can be reduced to beta-hydroxybutyrate by beta-hydroxybutyrate dehydrogenase in a NADH-requiring reaction. The extent of this reaction depends on the state of the NADpool of the cell; when it is highly reduced, most or all of the ketones can be in the form of beta-hydroxybutyrate. • Near-total reduction of acetoacetate to beta-hydroxybutyrate can occur in severe ethanol toxicity.

  11. Synthesis from acetyl CoA: Acetone • Some acetoacetate spontaneously decarboxylates to yield acetone. • Some acetoacetate spontaneously decarboxylates to yield acetone. The odor of acetone can be smelled on the breath of individuals with severe ketosis. ( Uncontrolled DM)

  12. Extrahepatic tissues • Ketone bodies are utilized exclusively by extrahepatic tissues; heart ,skeletal muscle and renal cortex use them particularly effectively. • If the ketone is beta-hydroxybutyrate, the first step must be reoxidation to acetoacetate, in a reversal of the reaction described previously. • Acetoacetate is activated by transfer of CoA from succinyl CoA in a reaction catalyzed by succinyl CoA β-ketoacid CoA transferase.

  13. The enzyme catalyzing this reaction is absent from liver; hence liver, which synthesizes ketone bodies, cannot use them. This places liver in the role of being a net producer of ketones. • The resulting acetoacetylCoA can be cleaved by thiolase to form two molecules of acetyl CoA, which can then be oxidized by the tricarboxylic acid cycle.

  14. Lactate Metabolism • During anaerobic glycolysis, that period of time when glycolysis is proceeding at a high rate (or in anaerobic organisms), the oxidation of NADH occurs through the reduction of an organic substrate. Erythrocytes and skeletal muscle (under conditions of exertion) derive all of their ATP needs through anaerobic glycolysis. The large quantity of NADH produced is oxidized by reducing pyruvate to lactate. This reaction is carried out by lactate dehydrogenase, (LDH).

  15. The lactate produced during anaerobic glycolysis diffuses from the tissues and is transproted to highly aerobic tissues such as cardiac muscle and liver. The lactate is then oxidized to pyruvate in these cells by LDH and the pyruvate is further oxidized in the TCA cycle. If the energy level in these cells is high the carbons of pyruvate will be diverted back to glucose via the gluconeogenesis pathway.

  16. Mammalian cells contain two distinct types of LDH subunits, termed M and H. Combinations of these different subunits generates LDH isoenzymes with different characteristics. The H type subunit predominates in aerobic tissues such as heart muscle (as the H4 tetramer) while the M subunit predominates in anaerobic tissues such as skeletal muscle as the M4 tetramer).

  17. H4 LDH has a low KM for pyruvate and also is inhibited by high levels of pyruvate. The M4 LDH enzyme has a high KM for pyruvate and is not inhibited by pyruvate. This suggests that the H-type LDH is utilized for oxidizing lactate to pyruvate and the M-type the reverse.

  18. Every LDH molecule consists of four subunits, where each subunit is either H or M (based on their electrophoreticproperties.) There are, therefore, five LDH isotypes: • LDH-1 (4H) - in the heart • LDH-2 (3H1M) - in the reticuloendothelial system • LDH-3 (2H2M) - in the lungs • LDH-4 (1H3M) - in the kidneys • LDH-5 (4M) - in the liver and striated muscle

  19. Usually LDH-2 is the predominant form in the serum. An LDH-1 level higher than the LDH-2 level (a "flipped pattern"), suggests myocardial infarction(damage to heart tissues releases heart LDH, which is rich in LDH-1, into the bloodstream). The use of this pheonomenon to diagnose infarction has been largely superseded by the use of Troponin I or T measurement.

  20. AMINO ACID METABOLISM • Following protein-rich meals, amino acid uptake and protein synthesis occur to replace protein degraded during the time before meals. • Branched-chain amino acids (leu, ile and val) escape metabolism in the liver to provide for protein synthesis and for fuels as well.

  21. Energy for Skeletal Muscle Contraction • ATP & ADP • Phosphocreatine • Aerobic pathways • Anaerobic pathways • (glycolytic metabolism) In resting muscle, fatty acids are the major fuel, meeting 85% of the energy needs.

  22. Sustaining Muscle contractions: ATP Sources/Time • Phosphocreatine: Short bursts at maximal effort • Anaerobic: Intermediate duration intense effort • Aerobic: Long duration at reduced effort

  23. Hormonal regulation of Energy Source for ATP Production • Metabolic Shifts • Glucagon • Cortisol • Epinephrine/NE • GH • (insulin)

  24. Hormonal regulation of Energy Source for ATP Production Figure 25-3: Use of carbohydrates and fats with increasing exercise

  25. Oxygen Consumption: Factors Sustaining or Limiting Exercise

  26. Cardiovascular Response to Exercise • Cardiac output •  5 to 25 L/min • Rate  2-3 X • Blood distribution •  muscles to 88% of all blood •  other tissues (except brain)

  27. Cardiovascular Response to Exercise

  28. END

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