Chemical Basis of Bioengineering I

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Enzyme

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Chemical Basis of Bioengineering I

Definition

An enzyme is a biological catalyst that accelerates chemical reactions in living organisms by lowering the activation energy required for the reactions to occur. Enzymes are usually proteins and play crucial roles in various metabolic processes, enabling life-sustaining reactions to happen efficiently and at a pace that supports cellular functions.

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5 Must Know Facts For Your Next Test

  1. Enzymes are highly specific, meaning each type of enzyme only catalyzes one particular reaction or type of reaction.
  2. Enzyme activity can be affected by factors such as temperature, pH, and the concentration of substrates and products, which can enhance or inhibit their function.
  3. Some enzymes require cofactors, which can be metal ions or organic molecules, to be active and perform their catalytic functions.
  4. Enzymes do not get consumed in reactions; they can be used repeatedly for multiple rounds of catalysis.
  5. The shape and structure of an enzyme are critical for its function, as any alteration can lead to reduced activity or complete loss of function.

Review Questions

  • How do enzymes facilitate chemical reactions in biological systems?
    • Enzymes facilitate chemical reactions by acting as catalysts that lower the activation energy needed for the reactions to proceed. This allows reactions to occur more rapidly than they would without the enzyme. Each enzyme has a unique active site that fits specific substrate molecules, ensuring that only particular reactions are catalyzed efficiently.
  • What role do factors like temperature and pH play in enzyme activity?
    • Temperature and pH significantly influence enzyme activity by affecting the enzyme's shape and functionality. Each enzyme has an optimal temperature and pH range where it operates best. If conditions fall outside this range, enzymes may become denatured or less effective, leading to a decrease in reaction rates and potential disruption of metabolic processes.
  • Evaluate how understanding enzyme mechanisms can aid in drug development and treatment strategies.
    • Understanding enzyme mechanisms is crucial for drug development because many drugs are designed to inhibit or enhance specific enzymatic activities. By knowing how enzymes work at a molecular level, scientists can create targeted therapies that effectively regulate metabolic pathways associated with diseases. This knowledge enables the design of more effective drugs with fewer side effects by focusing on specific enzymes involved in pathological conditions.
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