Q.104. The graph below shows the activity of enzyme pepsin in the presence of inhibitors aliphatic
alcohols (P) or N-acetyl-1-phenylalanine (Q). Which ONE of the following represents the nature of
inhibition by P and Q , respectively?
(A) Non-competitive and competitive
(B) Competitive and non-competitive
(C) Non-competitive and uncompetitive
(D) Competitive and uncompetitive
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In enzyme kinetics, understanding inhibition types is crucial for biochemistry students and researchers. This article breaks down a classic Lineweaver-Burk plot question on pepsin enzyme activity in the presence of inhibitors P (aliphatic alcohols) and Q (N-acetyl-phenylalanine). We’ll reveal the correct answer, explain why, and analyze all options to clarify nature of inhibition by P and Q.
What the Lineweaver-Burk Plot Reveals About Pepsin Inhibition
The double-reciprocal plot (1/V vs 1/[S]) shows three lines:
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No inhibitor: Standard line with X-intercept -1/Km and Y-intercept 1/Vmax.
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P (aliphatic alcohols): Line intersects Y-axis at the same point as no inhibitor but has a different slope and X-intercept.
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Q (N-acetyl-phenylalanine): Line has the same X-intercept as no inhibitor but a higher Y-intercept.
This pattern directly indicates inhibition types:
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P affects Km (changes X-intercept) but not Vmax (same Y-intercept) → Competitive inhibition.
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Q reduces Vmax (higher Y-intercept) but Km unchanged (same X-intercept) → Non-competitive inhibition.
Correct Answer: A) Non-competitive and competitive
Aliphatic alcohols (P) compete with substrate for the active site, increasing apparent Km. N-acetyl-phenylalanine (Q), a pepsin substrate analog, binds elsewhere, lowering Vmax without altering Km.
Detailed Explanation of All Options
Let’s evaluate each MCQ option based on standard enzyme kinetics principles.
Option A: Non-competitive and Competitive
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Matches the plot: Q (non-competitive, same Km, reduced Vmax); P (competitive, increased Km, same Vmax).
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Why correct? Lineweaver-Burk signatures align perfectly—Q shifts Y-intercept up; P shifts X-intercept rightward.
Option B: Competitive and Non-Competitive
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Reverses P and Q: Would mean P (non-competitive) has same Km (wrong, plot shows changed Km for P); Q (competitive) has changed Km (wrong).
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Incorrect: Plot data contradicts this swap.
Option C: Competitive and Uncompetitive
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Uncompetitive inhibition shows parallel lines (same slope, different intercepts).
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Incorrect: Q’s line isn’t parallel—slope changes, ruling out uncompetitive.
Option D: Non-Competitive and Uncompetitive
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No competitive pattern (P clearly changes Km).
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Incorrect: Fails to account for P’s X-intercept shift; uncompetitive doesn’t fit Q.
| Inhibition Type | Effect on Km | Effect on Vmax | Lineweaver-Burk Pattern |
|---|---|---|---|
| Competitive (P) | Increases | No change | Same Y-intercept, different X-intercept/slope |
| Non-competitive (Q) | No change | Decreases | Same X-intercept, higher Y-intercept |
| Uncompetitive | Decreases | Decreases | Parallel lines |
| No Inhibitor | Baseline | Baseline | Reference line |
Why This Matters for Pepsin and Enzyme Studies
Pepsin, a stomach protease, digests proteins optimally at low pH. Inhibitors like Q mimic substrates to study specificity, while P tests active site binding. Mastering nature of inhibition by P and Q helps in drug design, like HIV protease inhibitors (competitive mimics).
