5 Must Know Facts For Your Next Test

1. Glycogen is composed of glucose units linked by α(1→4) glycosidic bonds, with branching points created by α(1→6) bonds occurring approximately every 8-12 glucose units.
2. In humans, the liver stores about 100 grams of glycogen, while muscle tissues can store around 400 grams, making it a significant energy reservoir during physical activities.
3. The breakdown of glycogen (glycogenolysis) is stimulated by hormones like glucagon and epinephrine, which signal the body to release glucose when blood sugar levels are low.
4. Glycogen storage diseases are a group of genetic disorders characterized by abnormal glycogen metabolism, leading to issues with energy production and storage in the body.
5. During prolonged exercise or fasting, the body first uses blood glucose, then glycogen stores, and eventually turns to fat stores for energy.

Review Questions

• How does the structure of glycogen relate to its function as an energy storage molecule?
  • The highly branched structure of glycogen allows for rapid mobilization of glucose when the body needs energy quickly. The numerous terminal ends created by branching enable enzymes to access and break down glycogen efficiently during glycogenolysis. This design ensures that glucose can be released into the bloodstream promptly, supporting energy demands during exercise or between meals.
• Discuss the processes of glycogenesis and glycogenolysis and their significance in regulating blood glucose levels.
  • Glycogenesis is the process by which excess glucose is converted into glycogen for storage, primarily in the liver and muscles. In contrast, glycogenolysis is the breakdown of glycogen back into glucose when the body needs immediate energy. These two processes work together to regulate blood glucose levels: after meals, insulin promotes glycogenesis to lower blood sugar, while glucagon triggers glycogenolysis during fasting or stress to raise blood sugar levels.
• Evaluate how dysfunction in glycogen metabolism can lead to health issues and provide examples of conditions associated with this dysfunction.
  • Dysfunction in glycogen metabolism can result in various health issues, particularly glycogen storage diseases. For instance, Pompe disease results from a deficiency in the enzyme responsible for breaking down glycogen, leading to excessive accumulation in muscle tissues, causing weakness and respiratory problems. Similarly, McArdle disease affects muscle metabolism due to a lack of enzyme needed for glycogen breakdown, resulting in exercise intolerance. Understanding these conditions highlights the importance of proper glycogen metabolism for maintaining energy homeostasis.

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