Learning Objectives

• Explain the reciprocal regulation of Glycogen Synthase and Glycogen Phosphorylase.
• Differentiate between the signaling pathways of Glucagon, Epinephrine, and Insulin.
• Identify the role of Calcium-Calmodulin in muscle glycogenolysis during contraction.
• Understand the importance of Protein Phosphatase-1 in the fed state.

1. Hormonal Control of Glycogen

Glycogen metabolism is tightly regulated to ensure that the body either stores energy (fed state) or releases glucose (fasted/stress state).

• The Fasted State (Glucagon/Epinephrine):
  • Glucagon (liver) and Epinephrine (liver/muscle) bind to G-protein-coupled receptors, increasing cAMP.
  • cAMP activates Protein Kinase A (PKA).
  • PKA phosphorylates enzymes. In glycogen metabolism, Phosphorylation = Activation of Breakdown and Inhibition of Synthesis.
• The Fed State (Insulin):
  • Insulin binds to its Tyrosine Kinase receptor.
  • This activates Protein Phosphatase-1 (PP1).
  • PP1 dephosphorylates enzymes. Dephosphorylation = Activation of Synthesis and Inhibition of Breakdown.

2. The Glycogen “Switch.”

Regulation occurs through two key enzymes that act like a see-saw. They are never fully active at the same time.

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3. Muscle-Specific Regulation

Muscles do not respond to glucagon; they respond to local signals to ensure energy is available during exercise.

• Calcium-Calmodulin: During muscle contraction, $Ca^{2+}$ is released from the sarcoplasmic reticulum. $Ca^{2+}$ binds to calmodulin, which directly activates Glycogen Phosphorylase Kinase without needing cAMP or PKA.
• AMP: In extreme exercise, ↑ AMP levels directly activate Glycogen Phosphorylase.

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