If Vmax for a reaction is 10 μM-s1 and the KM is 0.5 µM, what is the reaction velocity when the substrate concentration is 2 µM? 2 μM 5 μM 12 μM 8 μη

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**Question:**

If \( V_{max} \) for a reaction is 10 µM·s⁻¹ and the \( K_M \) is 0.5 µM, what is the reaction velocity when the substrate concentration is 2 µM?

**Options:**
1. 2 µM
2. 5 µM
3. 12 µM
4. 8 µM

---

In enzyme kinetics, the Michaelis-Menten equation describes the rate of enzymatic reactions by relating reaction rate \( V \) to the concentration of substrate \( [S] \).

The Michaelis-Menten equation is: 
\[ V = \frac{V_{max} [S]}{K_M + [S]} \]

Where:
- \( V \) is the reaction velocity.
- \( V_{max} \) is the maximum reaction velocity.
- \( [S] \) is the substrate concentration.
- \( K_M \) is the Michaelis constant, which indicates the substrate concentration at which the reaction velocity is half of \( V_{max} \).

Using the provided values \( V_{max} = 10 \) µM·s⁻¹, \( K_M = 0.5 \) µM, and \( [S] = 2 \) µM, we can calculate the reaction velocity \( V \):

\[ V = \frac{10 \text{ µM·s}⁻¹ \times 2 \text{ µM}}{0.5 \text{ µM} + 2 \text{ µM}} \]
\[ V = \frac{20 \text{ µM}²\text{s}⁻¹}{2.5 \text{ µM}} \]
\[ V = 8 \text{ µM·s}⁻¹ \]

Therefore, the correct answer is: 
- 8 µM
Transcribed Image Text:**Question:** If \( V_{max} \) for a reaction is 10 µM·s⁻¹ and the \( K_M \) is 0.5 µM, what is the reaction velocity when the substrate concentration is 2 µM? **Options:** 1. 2 µM 2. 5 µM 3. 12 µM 4. 8 µM --- In enzyme kinetics, the Michaelis-Menten equation describes the rate of enzymatic reactions by relating reaction rate \( V \) to the concentration of substrate \( [S] \). The Michaelis-Menten equation is: \[ V = \frac{V_{max} [S]}{K_M + [S]} \] Where: - \( V \) is the reaction velocity. - \( V_{max} \) is the maximum reaction velocity. - \( [S] \) is the substrate concentration. - \( K_M \) is the Michaelis constant, which indicates the substrate concentration at which the reaction velocity is half of \( V_{max} \). Using the provided values \( V_{max} = 10 \) µM·s⁻¹, \( K_M = 0.5 \) µM, and \( [S] = 2 \) µM, we can calculate the reaction velocity \( V \): \[ V = \frac{10 \text{ µM·s}⁻¹ \times 2 \text{ µM}}{0.5 \text{ µM} + 2 \text{ µM}} \] \[ V = \frac{20 \text{ µM}²\text{s}⁻¹}{2.5 \text{ µM}} \] \[ V = 8 \text{ µM·s}⁻¹ \] Therefore, the correct answer is: - 8 µM
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