(SEPT 2022-11)
72. An enzyme has a K_m of 5 x 10^-5 M and a V_max of 100 µmoles.lit^-1. min^-1(K_m is the Michaelis constant and V_max is the maximal velocity). What is the velocity in the presence of 1 x 10^-4 M substrate and 2 x 10^-4 M competitive inhibitor, given that the K_i for the inhibitor is 2 x 10^-4 M?
(1) 0.005 µmoles. Lit^-1. Min^-1
(2) 50 µmoles. Lit^-1. Min^-1,
(3) 5 µmoles. Lit^-1. Min^-1,
(4) 500 µmoles. Lit^-1. Min^-1

The correct answer is (2) 50 µmoles. Lit⁻¹. Min⁻¹.

Introduction

Enzyme kinetics is fundamental for understanding how enzymes catalyze reactions and how inhibitors affect these rates. In competitive inhibition, the inhibitor competes with substrate for binding at the enzyme’s active site, modifying the apparent affinity but not the maximal velocity ( $V_{ma x}$ ). This article walks through a practical example calculation to determine enzyme velocity in the presence of competitive inhibitor using the Michaelis-Menten framework.

Problem Data

$K_{m} = 5 \times 1 0^{-5} M$
$V_{ma x} = 100 μ m o l \cdot L^{-1} \cdot mi n^{-1}$
Substrate concentration $[S] = 1 \times 1 0^{-4} M$
Inhibitor concentration $[I] = 2 \times 1 0^{-4} M$
Inhibitor constant $K_{i} = 2 \times 1 0^{-4} M$

Formula for Velocity with Competitive Inhibition

$v = K ^{m} ( 1 + K ^{i} [ I ] ) + [ S ] V ^{ma x} [ S ]$

Calculation Details

Calculate the apparent $K_{m}$ :

$K_{m, a pp} = K_{m} (1 + K ^{i} [ I ]) = 5 \times 1 0^{-5} \times (1 + 2 \times 10 ^{-4} 2 \times 10 ^{-4}) = 5 \times 1 0^{-5} \times 2 = 1 \times 1 0^{-4} M$

Plug values into velocity formula:

$v = 1 \times 10 ^{-4} + 1 \times 10 ^{-4} 100 \times 1 \times 10 ^{-4} = 2 \times 10 ^{-4} 100 \times 10 ^{-4} = 2100 = 50 μ m o l \cdot L^{-1} \cdot mi n^{-1}$

Interpretation

The presence of inhibitor increases the apparent $K_{m}$ to $1 \times 1 0^{-4} M$ , decreasing substrate affinity.
Since substrate concentration is equal to the new $K_{m}$ , initial velocity is half the maximum.
This aligns with the expected competitive inhibition kinetics.

Summary Table

Parameter	Value
$K_{m}$	$5 \times 1 0^{-5} M$
$V_{ma x}$	100 µmol/L/min
Substrate concentration	$1 \times 1 0^{-4} M$
Inhibitor concentration	$2 \times 1 0^{-4} M$
$K_{i}$	$2 \times 1 0^{-4} M$
Apparent $K_{m}$	$1 \times 1 0^{-4} M$
Velocity $v$	50 µmol/L/min

Conclusion

Competitive inhibition changes enzyme kinetics by increasing the apparent $K_{m}$ without affecting $V_{ma x}$ . The enzyme velocity reduced to 50 µmol/L/min from 100 µmol/L/min when the inhibitor was present, demonstrating the principle of substrate-inhibitor competition in enzyme catalysis.

18 Comments

yashika
September 12, 2025

Competitive inhibition increase km without affecting vmax

Reply
Varsha Tatla
September 13, 2025

Clear

Reply
Aakansha sharma Sharma
September 13, 2025

50 µmol/L/min is answer

Reply
- Pallavi Ghangas
  September 14, 2025
  
  50 µmol/L/min
  
  Reply
Rishita
September 13, 2025

Done sir 👍🏻

Reply
Pratibha Jain
September 14, 2025

correct answer is (2)
50 µmoles Lit⁻¹. Min⁻¹.

Reply
Pallavi Ghangas
September 14, 2025

50 µmol/L/min

Reply
Palak Sharma
September 14, 2025

50 µmol/L/min

Reply
Priya dhakad
September 14, 2025

50 µmol/L/min is correct option.

Reply
Sakshi Kanwar
September 14, 2025

50

Reply
Soniya Shekhawat
September 15, 2025

Done from explanation.

Reply
priya khandal
September 17, 2025

50

Reply
Khushi Agarwal
September 17, 2025

correct answer is (2) 50 µmoles. Lit⁻¹. Min⁻

Reply
Savita Garwa
September 17, 2025

50 µmol/L/min is correct option.

Reply
Tanvi Panwar
September 17, 2025

50 µmoles Lit⁻¹. Min⁻¹.

Reply
Asha Gurzzar
September 19, 2025

50 is correct

Reply
Minal Sethi
September 19, 2025

first new km is calculated by alpha*km
where alpha = 1+I/km
then applying MM equation
V=VmaxS/km+S
50 µmoles Lit⁻¹. Min⁻¹.

Reply
Kajal
September 25, 2025

Answer is (2)- 50 µmoles. Lit⁻¹. Min⁻¹

Reply