Protein thermal denaturation — Interpreting the midpoint (Tm) of a temperature transition curve
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Ahalf of the protein is denatured
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BKeq = 1.0 and ΔG = 0
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C[Native] = [Unfolded]
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DAll of these
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EHeat capacity change is zero at Tm
Answer
Correct Answer: All of these
Explanation
Introduction:Thermal unfolding of proteins is often monitored by spectroscopy or calorimetry and summarized by a sigmoidal temperature transition. The midpoint temperature, Tm, has precise thermodynamic meaning that connects populations and free energy.
Given Data / Assumptions:
- Two state unfolding model: Native ⇌ Unfolded.
- Definition of Tm as the temperature where the transition is halfway complete.
- Equilibrium constant Keq defined as [Unfolded] / [Native].
Concept / Approach:At the midpoint of a two state transition, populations of the native and unfolded states are equal. Therefore Keq = 1, and ΔG = -RTln(Keq) equals zero. This also means that exactly half of the protein molecules are denatured in a macroscopic sense.
Step-by-Step Solution:
1) At Tm, by definition, the unfolding curve passes through 50 percent transition.2) Equal populations imply [Native] = [Unfolded].3) Therefore Keq = [U]/[N] = 1.0.4) Substituting into ΔG = -RTln(Keq) gives ΔG = 0 at Tm.Verification / Alternative check:Differential scanning calorimetry shows peak heat absorption near Tm. Although heat capacity changes can be nonzero across the transition, the free energy criterion at Tm remains ΔG = 0 for a two state system with Keq = 1.
Why Other Options Are Wrong:
- Individual statements (a), (b), and (c) are each correct; the combined answer that includes all of them is most complete.
- Heat capacity change is zero at Tm: not a general rule; ΔCp can be significant and does not necessarily vanish at Tm.
Common Pitfalls:Assuming that half denatured means half of every molecule is unfolded. The interpretation is population based: about half the molecules are native and half unfolded.
Final Answer:All of these.