The Michaelis-Menten equation models the hyperbolic relationship between [S] and the initial reaction rate Vo for an enzyme-catalyzed, single-substrate reaction E +S ES –E+ P. The model can be more readily understood when comparing three conditions: [S] << Km, [S] = Km, and [S] >> Km- Match each statement with the condition that it describes. Note that "rate" refers to initial velocity V where steady state conditions are assumed. [E1otal] refers to the total enzyme concentration and [Efree] refers to the concentration of free enzyme. [S] << Km [S] = Km [S] >> Km Not true for any of these %3D conditions Almost all active sites will [ES] is much lower than [Efree)- be filled. Increasing [Etal] will lower Km- Reaction rate is independent of [S]. [Efree] is about equal to [Etotal]. [Efree] is equal to [ES].

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The Michaelis-Menten equation models the hyperbolic relationship between [S] and the initial reaction rate Vo for an enzyme-catalyzed, single-substrate reaction E + S = ES E+ P. The model can be more readily understood when comparing three conditions: [S] << Km, [S] = Km, and [S] >> Km- Match each statement with the condition that it describes. Note that "rate" refers to initial velocity Vo where steady state conditions are assumed. [Etotal] refers to the total enzyme concentration and [Efree] refers to the concentration of free enzyme. [S] << Km [S] = Km [S] >> Km Not true for any of these conditions Almost all active sites will [ES] is much lower than [Efree]. be filled. Reaction rate is independent of Increasing [Eotal] will lower Km- [S]. [Efree] is about equal to [Etotal ]. [Efree] is equal to [ES]. Answer Bank MacBook Pro'