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Given a pH-dependent kinetic mechanism, derive an initial velocity equation and sketch the plot of kinetic constants as a function of pH. [BIOC 4701]
Given the kinetic mechanism (with or without inhibition), derive an initial velocity equation using either the steady-state assumption or the rapid equilibrium approach. [multiple courses]
Show how entropic contributions lead to huge intramolecular rate enhancements. [BIOC 4701]
Given the kinetic parameters for an enzyme-catalyzed reaction and the corresponding nonenzymatic reaction, calculate the efficiency, rate enhancement, proficiency, and extent of transition state stabilization. [BIOC 4701]
Given the steady-state velocity expression for a multisubstrate enzyme, predict the product inhibition pattern and binding order in the presence of fixed and variable substrate concentrations. [BIOC 4701]
Derive the steady-state velocity equation for a given kinetic mechanism for a multisubstrate enzyme using the King-Altman method. [BIOC 4701]
Explain the biophysics of the non-covalent forces and kinetics and mechanisms governing protein folding and stability. [BIOC 4700]

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