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QUESTION IMAGE

environmental factors affect enzyme reaction rates reactants, products,…

Question

environmental factors affect enzyme reaction rates
reactants, products, and activation energy. underneath the curve, in the box summarize the meaning of the graph.

table columns: environmental factors (high temperature, increasing temperature from cold to warm, lowering temperature, normal temperature, low ph (<6), high ph (>8), neutral ph (6-8), competitive inhibitor, non-competitive inhibitor), affect on enzyme activity (increases (↑), decreases (↓), no change (↔)), denature enzyme? (y/n)

graph: x-axis labeled \energy\ (reversed), y-axis \direction of reaction\, box: \summary of graph:\

Explanation:

Response

To fill the table about how environmental factors affect enzyme reaction rates, we analyze each factor:

1. High Temperature
  • Increases Activity?: No (enzyme activity peaks at optimal temp, high temp denatures it).
  • Decreases Activity?: Yes (denaturation reduces activity).
  • No Change?: No.
  • Denature Enzyme?: Y (high temp breaks enzyme’s 3D structure).
2. Increasing Temperature (Cold to Warm)
  • Increases Activity?: Yes (up to optimal temp, kinetic energy of molecules increases, more collisions).
  • Decreases Activity?: No (before optimal temp, activity rises).
  • No Change?: No.
  • Denature Enzyme?: N (cold to warm is below denaturation temp).
3. Lowering Temperature
  • Increases Activity?: No (lower temp reduces molecular motion, fewer collisions).
  • Decreases Activity?: Yes (slower reaction rate).
  • No Change?: No.
  • Denature Enzyme?: N (low temp slows activity, not denature).
4. Normal Temperature
  • Increases Activity?: No (at optimal temp, activity is stable, not increasing further).
  • Decreases Activity?: No.
  • No Change?: Yes (enzyme works at optimal efficiency).
  • Denature Enzyme?: N (normal temp is optimal, no denaturation).
5. Low pH (<6)
  • Increases Activity?: No (most enzymes have optimal pH ~7, low pH disrupts structure).
  • Decreases Activity?: Yes (acidic conditions reduce activity).
  • No Change?: No.
  • Denature Enzyme?: Y (extreme pH denatures enzymes).
6. High pH (>8)
  • Increases Activity?: No (alkaline conditions disrupt enzyme structure).
  • Decreases Activity?: Yes (reduced activity).
  • No Change?: No.
  • Denature Enzyme?: Y (extreme pH denatures enzymes).
7. Neutral pH (6 - 8)
  • Increases Activity?: No (at optimal pH, activity is stable).
  • Decreases Activity?: No.
  • No Change?: Yes (optimal pH for most enzymes, activity is max and stable).
  • Denature Enzyme?: N (neutral pH is optimal, no denaturation).
8. Competitive Inhibitor
  • Increases Activity?: No (competes with substrate for active site, reduces effective enzyme - substrate interactions).
  • Decreases Activity?: Yes (slows reaction rate).
  • No Change?: No.
  • Denature Enzyme?: N (binds reversibly to active site, doesn’t denature enzyme).
9. Non - competitive Inhibitor
  • Increases Activity?: No (binds to allosteric site, changes enzyme’s shape, reducing activity).
  • Decreases Activity?: Yes (reduces enzyme’s catalytic efficiency).
  • No Change?: No.
  • Denature Enzyme?: N (allosteric binding, not denaturation).

For the energy - reaction graph (assuming it’s a typical enzyme - catalyzed reaction energy profile):

  • X - axis: Energy.
  • Y - axis: Direction of Reaction (from reactants to products).
  • The graph shows that the enzyme - catalyzed reaction has a lower activation energy (the “hump” is smaller) than the uncatalyzed reaction. Reactants have higher energy than products in an exergonic reaction (or vice versa in endergonic, but enzyme - catalyzed reactions often show reduced activation energy). The curve with the enzyme has a lower peak (activation energy) because enzymes lower the activation energy required for the reaction to occur, speeding up the rate of conversion from reactants to products.

Answer:

To fill the table about how environmental factors affect enzyme reaction rates, we analyze each factor:

1. High Temperature
  • Increases Activity?: No (enzyme activity peaks at optimal temp, high temp denatures it).
  • Decreases Activity?: Yes (denaturation reduces activity).
  • No Change?: No.
  • Denature Enzyme?: Y (high temp breaks enzyme’s 3D structure).
2. Increasing Temperature (Cold to Warm)
  • Increases Activity?: Yes (up to optimal temp, kinetic energy of molecules increases, more collisions).
  • Decreases Activity?: No (before optimal temp, activity rises).
  • No Change?: No.
  • Denature Enzyme?: N (cold to warm is below denaturation temp).
3. Lowering Temperature
  • Increases Activity?: No (lower temp reduces molecular motion, fewer collisions).
  • Decreases Activity?: Yes (slower reaction rate).
  • No Change?: No.
  • Denature Enzyme?: N (low temp slows activity, not denature).
4. Normal Temperature
  • Increases Activity?: No (at optimal temp, activity is stable, not increasing further).
  • Decreases Activity?: No.
  • No Change?: Yes (enzyme works at optimal efficiency).
  • Denature Enzyme?: N (normal temp is optimal, no denaturation).
5. Low pH (<6)
  • Increases Activity?: No (most enzymes have optimal pH ~7, low pH disrupts structure).
  • Decreases Activity?: Yes (acidic conditions reduce activity).
  • No Change?: No.
  • Denature Enzyme?: Y (extreme pH denatures enzymes).
6. High pH (>8)
  • Increases Activity?: No (alkaline conditions disrupt enzyme structure).
  • Decreases Activity?: Yes (reduced activity).
  • No Change?: No.
  • Denature Enzyme?: Y (extreme pH denatures enzymes).
7. Neutral pH (6 - 8)
  • Increases Activity?: No (at optimal pH, activity is stable).
  • Decreases Activity?: No.
  • No Change?: Yes (optimal pH for most enzymes, activity is max and stable).
  • Denature Enzyme?: N (neutral pH is optimal, no denaturation).
8. Competitive Inhibitor
  • Increases Activity?: No (competes with substrate for active site, reduces effective enzyme - substrate interactions).
  • Decreases Activity?: Yes (slows reaction rate).
  • No Change?: No.
  • Denature Enzyme?: N (binds reversibly to active site, doesn’t denature enzyme).
9. Non - competitive Inhibitor
  • Increases Activity?: No (binds to allosteric site, changes enzyme’s shape, reducing activity).
  • Decreases Activity?: Yes (reduces enzyme’s catalytic efficiency).
  • No Change?: No.
  • Denature Enzyme?: N (allosteric binding, not denaturation).

For the energy - reaction graph (assuming it’s a typical enzyme - catalyzed reaction energy profile):

  • X - axis: Energy.
  • Y - axis: Direction of Reaction (from reactants to products).
  • The graph shows that the enzyme - catalyzed reaction has a lower activation energy (the “hump” is smaller) than the uncatalyzed reaction. Reactants have higher energy than products in an exergonic reaction (or vice versa in endergonic, but enzyme - catalyzed reactions often show reduced activation energy). The curve with the enzyme has a lower peak (activation energy) because enzymes lower the activation energy required for the reaction to occur, speeding up the rate of conversion from reactants to products.