Specificity constant

In the field of biochemistry, the specificity constant (${\displaystyle k_{cat}/K_{M}}$), sometimes referred to as kinetic efficiency, is a measure of how efficiently an enzyme converts substrates into products. A comparison of specificity constants can also be used as a measure of the preference of an enzyme for different substrates (i.e., substrate specificity). The higher the specificity constant, the more the enzyme "prefers" that substrate.^[1]

The Michaelis constant (${\displaystyle K_{M}}$) is equal to the substrate concentration at which the enzyme converts substrates into products at half its maximal rate and hence is related to the affinity of the substrate for the enzyme. The catalytic constant (${\displaystyle k_{cat}}$) is the rate of product formation when the enzyme is saturated with substrate and therefore reflects the enzyme's maximum rate of product formation. The rate of product formation is dependent on both how well the enzyme binds substrate and how fast the enzyme converts substrate into product once substrate is bound. With a kinetically perfect enzyme, every encounter between enzyme and substrate leads to product and hence the reaction velocity is only limited by the rate the enzyme encounters substrate in solution. Hence the upper limit for ${\displaystyle k_{cat}/K_{M}}$ is equal to rate of substrate diffusion which is between10⁸ and 10⁹ s⁻¹M⁻¹.

${\displaystyle E+S\,{\overset {k_{f}}{\underset {k_{r}}{\rightleftharpoons }}}\,ES\,{\overset {k_{cat}}{\longrightarrow }}\,E+P}$

In Michaelis-Menten kinetics the steady-state assumption is that the rate of [ES] formation equals the rate of [ES] destruction (${\displaystyle k_{f}[E][S]=\left(k_{r}+k_{cat}\right)[ES]}$). This assumption is made to make it easier to write a dissociation constant: ${\displaystyle {\frac {[E][S]}{[ES]}}={\frac {k_{r}+k_{cat}}{k_{f}}}=K_{M}}$. The maximum velocity (${\displaystyle V_{max}}$) of an enzyme is the maximum product formation times the total concentration of enzyme available (${\displaystyle V_{max}=k_{cat}[E_{T}]}$). The velocity of a reaction (${\displaystyle v}$) is the maximum velocity times the fraction of enzymes that are saturated (that are actually binding and converting substrate). The fractional saturation is equal to :${\displaystyle {\frac {[S]}{K_{M}+[S]}}}$. Consequently ${\displaystyle v=V_{max}{\frac {[S]}{K_{M}+[S]}}}$. We can now derive ${\displaystyle v=k_{cat}[E_{T}]{\frac {[S]}{K_{M}+[S]}}}$. From this equation one can write the most useful form of the Michaelis-Menten equation: ${\displaystyle {\frac {v}{[E_{T}]}}=k_{cat}{\frac {[S]}{K_{M}+[S]}}}$

• Enzyme kinetics
• Michaelis-Menten kinetics
• Turnover number.

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