4: Energy, Metabolism, and the Central Dogma

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Energy is the driving force of life, and every physiological process depends on how cells acquire, transfer, and use it. In the human body, energy is stored in large biomolecules such as fats, carbohydrates (like glycogen), and proteins. Through metabolism, this stored energy is extracted and often transferred into ATP (adenosine triphosphate), the cell’s main “energy currency.” ATP acts like money—you earn it from one process and spend it on another. This cycle supports essential biological work, including building molecules, transporting substances, and producing movement.

Energy exists in different forms, such as kinetic energy (movement, like muscle contraction or blood flow) and potential energy (stored, like glycogen in the liver or the high-energy bonds in ATP). Converting one form into another follows the principles of thermodynamics. No conversion is 100% efficient, so some energy is always released as heat, which also contributes to maintaining body temperature.

The chapter also highlights two structure-function themes:

Molecular interactions: Enzymes interact with substrates, lowering activation energy so chemical reactions can proceed rapidly. Similarly, nucleic acids direct the assembly of proteins, ensuring accuracy in molecular processes.
Compartmentation: Specific pathways occur in specific locations. For example, glycolysis occurs in the cytosol, while the citric acid cycle takes place inside mitochondria. Separating processes into compartments allows better regulation and efficiency of energy flow.

Metabolism includes both catabolism (breaking down molecules to release energy) and anabolism (building larger molecules, which requires energy input). Aerobic metabolism, which requires oxygen, produces far more ATP than anaerobic metabolism, which functions without oxygen but yields less energy.

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